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04-04-09(Lecture #08)1 Digital Signal Processing Lecture# 8 Chapter 5.

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Presentation on theme: "04-04-09(Lecture #08)1 Digital Signal Processing Lecture# 8 Chapter 5."— Presentation transcript:

1 04-04-09(Lecture #08)1 Digital Signal Processing Lecture# 8 Chapter 5

2 04-04-09(Lecture #08)2 Transform Analysis of LTI System

3 04-04-09(Lecture #08)3 Overview In Chapter 2 we devolved Fourier transform of DTS&S (Discrete time signal & System). In Chapter 3 we extend the representation to to Z-Transform. In both (Ch 2& 3) Emphasis was on the transform & their properties, with brief preview of their use in analysis of LTI system.

4 04-04-09(Lecture #08)4 Overview In this chapter our main focus is on detailed representation and analysis of LTI Systems using Fourier and Z –Transforms.

5 04-04-09(Lecture #08)5 Overview As devolved in Ch 2,an LTI system can be characterized in the time domain by its impulse response h [n], with output y [n] due to input x [n] is given by Convolution Sum. Then Fourier Transform Provides an equal complete characterization of LTI system

6 04-04-09(Lecture #08)6 Overview In Ch 3 we devolved Z-Transform as Generalization of Fourier Transform and we showed that Y (z) (the z-transform of output of LTI system) is related to X (z) (the z-transform of input of LTI system) and H (z) (the z-transform of system impulse response) by Y (z)= H (z) X (z)

7 04-04-09(Lecture #08)7 Overview We will See in this Chapter that both Frequency and Z- transform are extremely useful in analysis and representation of LTI Systems, because we can readily infer many properties of system from these two transforms.

8 04-04-09(Lecture #08)8 Frequency response of LTI System Convolution Sum is referred to magnitude response or gain. is called phase response or phase shift

9 04-04-09(Lecture #08)9 Linear Phase Means Delay

10 04-04-09(Lecture #08)10 Ideal LPF Frequency Response

11 04-04-09(Lecture #08)11 Group Delay

12 04-04-09(Lecture #08)12 Group Delay

13 04-04-09(Lecture #08)13 Example: Input Signal

14 04-04-09(Lecture #08)14 Frequency Response of Filter

15 04-04-09(Lecture #08)15 Output Signal

16 04-04-09(Lecture #08)16 Problem with IIR System Variable Group Delay Distort the output

17 04-04-09(Lecture #08)17 Rational System Function

18 04-04-09(Lecture #08)18 Inverse System

19 04-04-09(Lecture #08)19 Frequency Response of Rational System Function

20 04-04-09(Lecture #08)20 Any Question?????

21 04-04-09(Lecture #08)21 Real Even (or Odd) SignalsSignals If a signal is even in addition to being real, then its DTFT is also real and even. This follows immediately from the Hermitian symmetry of real signals, and the fact that the DTFT of any even signal is real:DTFT

22 04-04-09(Lecture #08)22 Example

23 04-04-09(Lecture #08)23 Continued… This is true since cosine is even, sine is odd, even times even is even, even times odd is odd, and the sum over all samples of an odd signal is zero. I.e.,

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