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Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
Video Lecture Series by IIT Professors ( Not Available in NPTEL)
VLSI Broadband Communication Circuits
By Prof. Nagendra Krishnapura
For more video Lectures .... www.satishkashyap.com
For free ebooks ...... www.ebook29.blogspot.com
1. Introduction to broadband digital communication
2. Introduction to broadband digital communication
3. Serializers and deserializers
4. Forgot to hit "record"!
5. CMOS logic, single ended data transmission, limitations
6. Current mode logic-basic circuit design
7. Current mode logic-MUX, XOR, latch
8. Current mode logic-latch design
9. Current mode logic-latch characteristics
10. Low pass transmission channel-Intersymbol interference, error rate
11. First order channel model, ISI
12. ISI, jitter, eye opening
13. Channel characteristics-Intersymbol interference, Crosstalk
14. Equalizer design
15. Equalizer design-minimizing the residual error
16. Equalization-Effect on noise and crosstalk
17. Tradeoffs between equalization at Tx and Rx; Design of Tx equalizers
18. Design of Transmit equalizers using flip-flops and transconductors
19. Tx equalizer-design considerations
20. Tx equalizer-design considerations; realizing variable coefficients
21. Differential pair-effect of tail node capacitance; Continuous time equalization
22. Continuous-time equalizer realization; replica biasing for the tail current source
23. Assignment 2 discussion
24. Replica biasing, optimizing transmitter swing
25. Replica biasing, optimizing transmitter swing
26. Analog layout optimization; Equalization at the receiver
27. Equalization at the receiver; Basics of adaptation
28. LMS adaptation
29. Sign-sign LMS adaptation
30. LMS implementation details
31. Adaptive equalizer implementation, S/H based equalizer, obtaining the gradients
32. Mid term discussion; Multiplexed and demultiplexed PRBS sequences; Latch vs. amplifier; Zeros for pre- and post- cursor equalization; Echo cancellation
33. Decision feedback equalizers-elimination of noise enhancement; Error propagation
34. Decision feedback equalizers-bit error rate
35. Decision feedback equalizers-implementation issues
36. Assignment 3 discussion
37. Decision feedback equalizers-implementation issues
38. Introduction to clock and data recovery-Frequency multiplication using a phase locked loop
39. Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
40. (continued) Type I PLL; derivation of the phase model of the PLL; Tri state phase detector
41. Type I PLL; Reference feedthrough; Tradeoff between reference feedthrough and lock range
42. Stability of feedback loops; Derivation of the type II PLL
43. Realization of type II PLLs-charge pump, loop filter
44. Reference feedthrough in a type II PLL; Phase detector for random data
45. Linear phase detector for random data
46. Linear phase detector; Transfer functions in a PLL
47. PLL review
48. Binary phase detectors; bang bang jitter
49. Miscellaneous topics-Optimal equalizers; Linearity assumption of PLL model; PLL capture phenomenon; Hogge phase detector offset correction
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video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on
fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on
fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on
fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on
fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on
fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on
fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on
fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion onfixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on
fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
video lectures from iit professors.... not available in NPTEL.....
video Lectures on "Active Filter Design" by Dr.Shanthi Pavan , IIT Madras
for more videos .... www.satishkashyap.com
for free ebooks.....www.ebook29.blogspot.com
Lecture 1 - Course overview and introduction.
Lecture 2 - The Butterworth approximation
Lecture 3 - The Chebyshev approximation
Lecture 4 - The Chebyshev approximation (contd)
Lecture 5 - The Chebyshev approximation (contd), the Inverse Chebyshev approximation
Lecture 6 - The Inverse Chebyshev approximation (contd).
Lecture 7 - Synthesis of doubly terminated all-pole LC ladders filters
Lecture 8 - Synthesis of doubly terminated LC ladders (contd).
Lecture 9 - Synthesis of doubly terminated LC ladders with finite zeros of transmission.
Lecture 10 - Network sensitivity - low sensitivity of doubly terminated ladders
Lecture 11 - Introduction to frequency transformations.
Lecture 12 - Frequency (reactance) transformations (contd) - properties of the driving
impedance of lossless LC networks- Tellegen's theorem and positive real functions.
Lecture 13 - Driving point impedance of LC networks (contd), Low Pass-to-Low Pass, Low
Pass-to-Band Pass, Low Pass-to-High Pass and Low Pass-to-Band Stop transformations
Lecture 14 - The Richard's Transformation, RC-CR transformation
Lecture 15 - Emulation of an inductor with a capacitor and controlled sources, the
gyrator, a second order transconductor capacitor filter.
Lecture 16 - Cascade of biquads realization of high order low pass filters, equivalence
of the parallel RLC and series RLC circuits with their Gm-C counterparts.
Lecture 17 - The idea of Dynamic Range in active filters - impedance scaling and its
effect on dynamic range
Lecture 18 - Introduction to noise in electrical networks.
Lecture 19 - Introduction to noise in electrical networks (contd), the idea of node
scaling.
Lecture 20 - Dynamic range scaling in active filters.
Lecture 21 - Biquad Ordering.
Lecture 22 - Active Ladder Emulation / Leapfrog Filters, Effect of Transconductor
nonidelaities (parasitic capacitance/output resistance).
Lecture 23 - Effect of Transconductor Nonidealities (contd) - parasitic poles.
Lecture 24 - Viewing the Gm-C biquad as a Double Integrator Loop, Revisiting the Effect
of Finite Gain of the Transconductors.
Lecture 25 - Single-ended Versus Differential Filters, Introducing the Differential-pair
Based Fully Differential Transconductor, the Need for Common-mode Feedback
Lecture 26 - Common-mode Feedback (continued).
Lecture 27 - Common-mode Feedback (continued), examples of Common-mode Detectors.
Lecture 28 - Stability of the Common-mode Feedback Loop
Lecture 29 - Common-mode Positive Feedback in Gyrators.
Lecture 30 - Common-mode Positive Feedback in Gyrators (contd), Noise in the
Differential Pair.
Lecture 31 - Noise in the Differential Pair (contd), Linearity of the Differential Pair,
Cascoding to Improve Output Impedance
Lecture 32 - Noise in Cascodes, Layout Considerations and Multi-finger Transistors.
Lecture 33 - Linearizing the Differential Pair, Resistive Degeneration.
Lecture 34 - Noise in Degenerated Transconductors, The Folded Cascode and Noise Analysis
Lecture 35 - Stabilizing filter bandwidth over process and temperature - the resistor
servo loop, master-slave loops.
Lecture 36 - Turning the filter into a VCO to estimate center frequency, example of a
practical precision fixed-gm bias circuit.
Lecture 37 - Introduction to accurate measurement and characterization techniques for
active filters.
Lecture 38 - Introduction to Active-RC filters.
Lecture 39 - Active-RC filters (contd), the use of an OTA instead of an opamp, swing and
noise considerations, single stage OTAs
Lecture 40 - Multistage OTAs for use in CMOS Active-RC filters.
Lecture 41 - The Miller compensated opamp in active-RC filters, noise considerations,
noise in active-RC filters .
Lecture 42 - Distortion and Intermodulation in filters, miscellaneous discussion on fixed gm-bias circuits
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Analog Integrated Circuit Design by Prof.Nagendra Krishnapura sir
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Better Spoken English by Prof. Shreesh Chaudhary, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Geosynthetics and Reinforced Soil Structures by Prof. K. Rajagopal, Department of Civil Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Field Theory by Dr. Prasanta Tripathy, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Select/Special Topics in Atomic Physics by Prof. P.C. Deshmukh, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Real Analysis by Prof. S.H. Kulkarni, Department of Mathematics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Health,Safety and Environmental Management in Petroleum and Offshore Engineering by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Mod-01 Lec-11 Lecture 11 : Attenuation : Continued Sound Propagation Through Inhomogeneous Media - 1
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Acoustic Instabilities in Aerospace Propulsion by Prof. R.I. Sujith, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Quantum Mechanics I by Prof. S. Lakshmi Bala, Department of Physics, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Gas Dynamics by Dr. T.M. Muruganandam, Department of Aerospace Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Analog IC Design by Dr. Nagendra Krishnapura, Department of Electronics & Communication Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Coastal Engineering by Prof. V. Sundar, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Introduction to Film Studies by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Dynamics of Ocean Structures by Dr. Srinivasan Chandrasekaran, Department of Ocean Engineering, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Ship Resistance and Propulsion by Prof. V. Anantha Subramanian,Dr. P. Krishnankutty, Department of Ocean Engineering, IITMadras. For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Semiconductor Device Modeling by Prof. S. Karmalkar,Department of Electrical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Classical Field Theory by Prof. Suresh Govindarajan,Department of Physics,IIT Madras.For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Contemporary Literature by Dr. Aysha Iqbal Viswamohan, Department of Humanities and Social Sciences, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Downstream Processing by Prof. Mukesh Doble, Department of Biotechnology, IIT Madras. For more details on NPTEL visit http://nptel.iitm.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Infrastructure Finance by Dr. A. Thillai Rajan,Department of Management Studies,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Port and Harbour Structures by Prof. R. Sundaravadivelu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
An Introduction to Explosions and Explosion Safety by Prof. K. Ramamurthi,Department of Mechanical Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on
NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Artificial Intelligence by Prof. Deepak Khemani,Department of Computer Science and Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in
Foundation for Offshore Structures by Dr. S. Nallayarasu,Department of Ocean Engineering,IIT Madras.For more details on NPTEL visit http://nptel.ac.in