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Minimum-Phase Systems Quote of the Day Experience is the name everyone gives to their mistakes. Oscar Wilde Content and Figures are from Discrete-Time.

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Presentation on theme: "Minimum-Phase Systems Quote of the Day Experience is the name everyone gives to their mistakes. Oscar Wilde Content and Figures are from Discrete-Time."— Presentation transcript:

1 Minimum-Phase Systems Quote of the Day Experience is the name everyone gives to their mistakes. Oscar Wilde Content and Figures are from Discrete-Time Signal Processing, 2e by Oppenheim, Shafer, and Buck, ©1999-2000 Prentice Hall Inc.

2 Copyright (C) EEE413 Digital Signal Processing 2 Minimum-Phase System A system with all poles and zeros inside the unit circle Both the system function and the inverse is causal and stable Name “minimum-phase” comes from the property of the phase –Not obvious to see with the given definition –Will look into it Given a magnitude square system function that is minimum phase –The original system is uniquely determined A minimum-phase system has an additional useful property that the natural logarithm of the magnitude of the frequency response is related to the phase angle of the frequency response (measured in radians) by the Hilbert transform Minimum-phase and All-pass decomposition –Any rational system function can be decomposed as

3 Copyright (C) EEE413 Digital Signal Processing 3 Example 1: Minimum-Phase System Consider the following system One pole inside the unit circle: –Make part of minimum-phase system One zero outside the unit circle: –Add an all-pass system to reflect this zero inside the unit circle

4 Copyright (C) EEE413 Digital Signal Processing 4 Example 2: Minimum-Phase System Consider the following system One pole inside the unit circle: Complex conjugate zero pair outside the unit circle

5 Copyright (C) EEE413 Digital Signal Processing 5 Example 2 Cont’d

6 Copyright (C) EEE413 Digital Signal Processing 6 Frequency-Response Compensation In some applications a signal is distorted by an LTI system Could filter with inverse filter to recover input signal –Would work only with minimum-phase systems Make use of minimum-phase all-pass decomposition –Invert minimum phase part Assume a distorting system H d (z) Decompose it into Define compensating system as Cascade of the distorting system and compensating system

7 Copyright (C) EEE413 Digital Signal Processing 7 Properties of Minimum-Phase Systems Minimum Phase-Lag Property –Continuous phase of a non-minimum-phase system –All-pass systems have negative phase between 0 and  –So any non-minimum phase system will have a more negative phase compared to the minimum-phase system –The negative of the phase is called the phase-lag function –The name minimum-phase comes from minimum phase-lag Minimum Group-Delay Property –Group-delay of all-pass systems is positive –Any non-minimum-phase system will always have greater group delay

8 Copyright (C) EEE413 Digital Signal Processing 8 Properties of Minimum-Phase System Minimum Energy-Delay Property –Minimum-phase system concentrates energy in the early part Consider a minimum-phase system H min (z) Any H(z) that has the same magnitude response as H min (z) –has the same poles as H min (z) –any number of zeros of H min (z) are flipped outside the unit-circle Decompose one of the zeros of H min (z) Write H(z) that has the same magnitude response as We can write these in time domain

9 Copyright (C) EEE413 Digital Signal Processing 9 Derivation Cont’d Evaluate each sum And the difference is Since |q k |<1

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