Digital Signal Processing and Its Applications

Digital Signal Processing and Its Applications

IIT Bombay July 2018 via YouTube Direct link

Lecture 33A: Recap And Review of Lattice Structure, Realization of FIR Function.

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90 of 95

Lecture 33A: Recap And Review of Lattice Structure, Realization of FIR Function.

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Digital Signal Processing and Its Applications

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  1. 1 Course Introduction - Digital Signal Processing and its Applications
  2. 2 Lecture 1: Introduction: Digital signal processing and its objectives
  3. 3 Lecture 2A: Introduction to sampling and Fourier Transform
  4. 4 Lecture 2B: Sampling of sine wave and associate complication
  5. 5 Lecture 3A: Review of Sampling Theorem
  6. 6 Lecture 3B: Idealized Sampling, Reconstruction
  7. 7 Lecture 3C: Filters And Discrete System
  8. 8 Lecture 4A: Answering questions from previous lectures.
  9. 9 Lecture 4B: Desired requirements for discrete system
  10. 10 Lecture 4C: Introduction to phasors
  11. 11 Lecture 4D: Advantages of phasors in discrete systems
  12. 12 Lecture 5A: What do we want from a discrete system?
  13. 13 Lecture 5B: Linearity - Homogeneity and Additivity
  14. 14 Lecture 5C: Shift Invariance and Characterization of LTI systems
  15. 15 Lecture 6A: Characterization of LSI system using it’s impulse response
  16. 16 Lecture 6B: Introduction to convolution
  17. 17 Lecture 6C: Convolution:deeper ideas and understanding
  18. 18 Lecture 7A: Characterisation of LSI systems, Convolution-properties
  19. 19 Lecture 7B: RESPONSE OF LSI SYSTEMS TO COMPLEX SINUSOIDS
  20. 20 Lecture 7C: CONVERGENCE OF CONVOLUTION AND BIBO STABILITY
  21. 21 Lecture 8A: Commutativity & Associativity
  22. 22 Lecture 8B: BIBO Stability of an LSI system
  23. 23 Lecture 8C: Causality and memory of an LSI system.
  24. 24 Lecture 8D: Frequency response of an LSI system.
  25. 25 Lecture 9A: Introduction and conditions of Stability
  26. 26 Lecture 9B: Vectors and Inner Product.
  27. 27 Lecture 9C: Interpretation of Frequency Response as Dot Product
  28. 28 Lecture 9D: Interpretation ofFrequency Responseas Eigenvalues
  29. 29 Lecture 10A: Discrete time fourier transform
  30. 30 Lecture 10B: DTFT in LSI System and Convolution Theorem.
  31. 31 Lecture 10C: Definitions of sequences and Properties of DTFT.
  32. 32 Lecture 11A: Introduction to DTFT, IDTFT
  33. 33 Lecture 11B: Dual to convolution property
  34. 34 Lecture 11C: Multiplication Property, Introduction to Parseval’s theorem
  35. 35 Lecture 12A: Introduction And Property of DTFT
  36. 36 Lecture 12B: Review of Inverse DTFT
  37. 37 Lecture 12C: Parseval’s Theorem and energy and time spectral density
  38. 38 Lecture 13A: Discussion on Unit Step
  39. 39 Lecture 13B: Introduction to Z transform
  40. 40 Lecture 13C: Example of Z transform
  41. 41 Lecture 13D: Region of Convergence
  42. 42 Lecture 13E: Properties of Z transform
  43. 43 Lecture 14A: Z- Transform
  44. 44 Lecture 14B: Rational System
  45. 45 Lecture 15A: INTRODUCTION AND EXAMPLES OF RATIONAL Z TRANSFORM AND THEIR INVERSES
  46. 46 Lecture 15B: DOUBLE POLE EXAMPLES AND THEIR INVERSE Z TRANSFORM
  47. 47 Lecture 15C: PARTIAL FRACTION DECOMPOSITION
  48. 48 Lecture 15D: LSI SYSTEM EXAMPLES
  49. 49 Lecture 16A: Why are Rational Systems so important?
  50. 50 Lecture 16B: Solving Linear constant coefficient difference equations
  51. 51 Lecture 16C: Introduction to Resonance in Rational Systems
  52. 52 Lecture 17A: Characterization of Rational LSI system
  53. 53 Lecture 17B: Causality and stability of the ROC of the system function
  54. 54 Lecture 18A: RECAP OF RATIONAL SYSTEMS AND DISCRETE TIME FILTERS
  55. 55 Lecture 18B: SPECIFICATIONS FOR FILTER DESIGN
  56. 56 Lecture 18C: FOUR IDEAL PIECEWISE CONSTANT FILTERS
  57. 57 Lecture 18D: IMPORTANT CHARACTERISTICS OF IDEAL FILTERS
  58. 58 Lecture 19A: Synthesis of Discrete Time Filters, Realizable specifications
  59. 59 Lecture 19B: Realistic Specifications for low pass filter. Filter Design Process
  60. 60 Lecture 20A: Introduction to Filter Design. Analog IIR Filter, FIR and IIR discrete-time filter.
  61. 61 Lecture 20B: Analog to discrete transform
  62. 62 Lecture 20C: Intuitive transforms, Bilinear Transformation
  63. 63 Lecture 21A: Steps for IIR filter design
  64. 64 Lecture 21B: Analog filter design using Butterworth Approximation
  65. 65 Lecture 22A: Butterworth filter Derivation And Analysis of butterworth system function
  66. 66 Lecture 22B: Chebychev filter Derivation
  67. 67 Lecture 23: Midsem paper review discussion
  68. 68 Lecture 24A: The Chebyschev Approximation
  69. 69 Lecture 24B: Next step in design: Obtain poles
  70. 70 Lecture 25A: Introduction to Frequency Transformations in the Analog Domain
  71. 71 Lecture 25B: High pass transformation
  72. 72 Lecture 25C: Band pass transformation
  73. 73 Lecture 26A: Frequency Transformation
  74. 74 Lecture 26B: Different types of filters
  75. 75 Lecture 27A: Impulse invariant method and ideal impulse response
  76. 76 Lecture 27B: Design of FIR of length (2N+1) by the truncation method, Plotting the function V(w)
  77. 77 Lecture 28A: IIR filter using rectangular window, IIR filter using triangular window
  78. 78 Lecture 28B: Proof that frequency response of an fir filter using rectangular window function
  79. 79 Lecture 29A: Introduction to window functions
  80. 80 Lecture 29B: Examples of window functions
  81. 81 Lecture 29C: Explanation of Gibb’s Phenomenon and it’s application
  82. 82 Lecture 30A: Comparison of FIR And IIR Filter’s
  83. 83 Lecture 30B: Comparison of FIR And IIR Filter’s
  84. 84 Lecture 30C: Comparison of FIR And IIR Filter’s
  85. 85 Pseudo-Linear Phase Filter, Signal Flow Graph.
  86. 86 Lecture 31B: Comprehension of Signal Flow Graphs and Achievement of Pseudo Assembly Language Code.
  87. 87 Lecture 32A: Introduction to IIR Filter Realization and Cascade Structure
  88. 88 Lecture 32B: Cascade Parallel Structure
  89. 89 Lecture 32C: Lattice Structure
  90. 90 Lecture 33A: Recap And Review of Lattice Structure, Realization of FIR Function.
  91. 91 Lecture 33B: Backward recursion, Change in the recursive equation of lattice.
  92. 92 Lecture 34A: Lattice structure for an arbitrary rational system
  93. 93 Lecture 34B: Example realization of lattice structure for rational system
  94. 94 Lecture 35A: Introductory Remarks of Discrete Fourier Transform and Frequency Domain Sampling
  95. 95 Lecture 35B: Principle of Duality, The Circular Convolution

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