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5.1 the frequency response of LTI system 5.2 system function 5.3 frequency response for rational system function 5.4 relationship between magnitude and phase 5.5 all-pass system 5.6 minimum-phase system 5.7 linear system with generalized linear phase Chapter 5 transform analysis of linear time-invariant system
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5.1 the frequency response of LTI system magnitude response or gain magnitude square function log magnitude magnitude attenuation magnitude-frequency characteristic :
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log magnitude linear magnitude transform curve from linear to log magnitude
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phase-frequency characteristic : phase response principal phase continuous phase group delay
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Figure 5.7
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Figure 5.1 EXAMPLE understand group delay
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Figure 5.2
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5.2 system function Characteristics of zeros and poles : ( 1 ) take origin and zeros and poles at infinite into consideration, the numbers of zeros and poles are the same. ( 2 ) for real coefficient, complex zeros and poles are conjugated, respectively. ( 3 ) if causal and stable, poles are all in the unit circle. ( 4 ) FIR : have no nonzero poles, called all-zeros type, steady IIR : have nonzero pole; if no nonzero zeros, called all-poles type EXAMPLE Difference about zeros and poles in FIR and IIR
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5.3 frequency response for rational system function 1.formular method
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2. Geometrical method
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EXAMPLE magnitude response in w near zeros is minimum, there are zeros in unit circle, then the magnitude is 0 ; magnitude response in w near poles is maximum ; zeros and poles counteracted each other and in origin does not influence the magnitude.
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EXAMPLE
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B=1 A=[1,-0.5] figure(1) zplane(B,A) figure(2) freqz(B,A) figure(3) grpdelay(B,A,10) EXAMPLE 3.matlab method
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5.4 relationship between magnitude and phase
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Figure 5.20 EXAMPLE Pole-zero plot for , H(z): causal and stable , Confirm the poles and zeros
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5.5 all-pass system Zeros and poles are conjugate reciprocal For real coefficient, zeros are conjugated, poles are conjugated.
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EXAMPLE Y Y Y N
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Characteristics of causal and stable all-pass system: application : 1. compensate the phase distortion 2. compensate the magnitude distortion together with minimum-phase system
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5.6 minimum-phase system inverse system:
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explanation : ( 1 ) not all the systems have inverse system 。 ( 2 ) inverse system may be nonuniform 。 ( 3 ) the inverse system of causal and stable system may not be causal and stable 。 the condition of both original and its inverse system causal and stable : zeros and poles are all in the unit circle , such system is called minimum- phase system, corresponding h[n] is minimum-phase sequence 。 poles are all in the unit circle, zeros are all outside the unit circle, such system is called maximum-phase system 。
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zeros outside the unit circle poles outside the unit circle minimum-phase system: conjugate reciprocal zeros and poles all-pass system: counteracted zeros and poles, zeros and poles outside the circle minimum-phase and all-pass decomposition : If H(z) is rational, then :
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Figure 5.25 Application of minimum-phase and all-pass decomposition : Compensate for amplitude distortion
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Properties of minimum-phase systems: ( 1 ) minimum phase-delay ( 2 ) minimum group-delay Minimum-phase system and some all-pass system in cascade can make up of another system having the same magnitude response, so there are infinite systems having the same magnitude response.
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( 3 ) minimum energy-delay ( i.e. the partial energy is most concentrated around n=0 )
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Figure 5.30 最小相位 maximum phase EXAMPLE minimum phase Systems having the same magnitude response
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Figure 5.31 minimum phase
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Figure 5.32
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5.7 linear system with generalized linear phase 5.7.1 definition 5.7.2 conditions of generalized linear phase system 5.7.3 causal generalized linear phase (FIR)system
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5.7.1 definition Strict: Generalized: Systems having constant group delay phase
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EXAMPLE ideal delay system differentiator : magnitude and phase are all linear EXAMPLE physical meaning : all components of input signal are delayed by the same amount in strict linear phase system , then there is only magnitude distortion, no phase distortion. it is very important for image signal and high-fidelity audio signal to have no phase distortion. when B=0, for generalized linear phase, the phase in the whole band is not linear, but is linear in the pass band, because the phase +PI only occurs when magnitude is 0, and the magnitude in the pass band is not 0.
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square wave with fundamental frequency 100 Hz linear phase filter : lowpass filter with cut-off frequency 400Hz nonlinear phase filter : lowpass filter with cut-off frequency 400Hz EXAMPLE
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Generalized linear phase in the pass band is strict linear phase
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5.7.2 conditions of generalized linear phase system Or:
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Figure 5.35 M:even M:odd M:not integer
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EXAMPLE M:not integer
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determine whether these system is linear phase,generalized or strict?a and ß=? EXAMPLE (1)(2) (3) (4)
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5.7.3 causal generalized linear phase (FIR)system
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Magnitude and phase characteristics of the 4 types :
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III
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IIIIV
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Characteristic of zeros: commonness
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Figure 5.41 Characteristic of every type :
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type I : type II : type III : type IV : characteristic of magnitude get from characteristic of zeros :
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M is evenM is odd low high band pass band stop h[n] is even (I) Y Y Y Y Y N Y N (II) h[n] is odd (III) N N Y N N Y Y N (IV) Application of 4 types of linear phase system:
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5.1 the frequency response of LTI system : 5.2 system function 5.3 frequency response for rational system function: 5.4 relationship between magnitude and phase : 5.5 all-pass system 5.6 minimum-phase system 5.7 linear system with generalized linear phase ( FIR) 5.7.1 definition: 5.7.2 conditions : h[n] is symmetrical 5.7.3 causal generalized linear phase system 1.condition 2.classification 3.characteristics of magnitude and phase, filters in point respectively 4.analyse of characteristic of magnitude from the zeros of system function summary
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requirement: concept of magnitude and phase response, group delay; transformation among system function, phase response and difference equation; concept of all-pass, minimum-phase and linear phase system and characteristic of zeros and poles; minimum-phase and all-pass decomposition; conditions of linear phase system, restriction of using as filters key and difficulty : linear phase system
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exercises 5.17 complementarity : minimum-phase and all-pass decomposition 5.21 5.45 5.53
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the first experiment problem 1 ( D ) problem 11 problem 13 ( C ) problem 22 ( A ) problem 24 ( A )( C ) Get subjects from the experiment instruction book or downloading from network :
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