华南理工大学电子与信息学院：《数字信号与处理》（英文版）Lecture 9 LTI Discrete-Time Systems in the Transform domain

The Frequency Response Then we can write yn]=h(e/o)e! Thus for a complex exponential input signal eJon, the output of an Lti discrete-time system is also a complex exponential signal of the same frequency multiplied by a complex constant H(eJ) Thus eJon is an eigen function of the system Copyright C 2001, S K. Mitra

Copyright © 2001, S. K. Mitra 11 The Frequency Response • Then we can write • Thus for a complex exponential input signal , the output of an LTI discrete-time system is also a complex exponential signal of the same frequency multiplied by a complex constant • Thus is an eigen function of the system j j n y n H e e   [ ] = ( ) ( ) j H e j n e  j n e 

The Frequency Response response of the llt discrete-time systel 3 The quantity H(eo)is called the frequen H(eu) provides a frequency-domai description of the system H(e/o) is precisely the dtft of the impulse response hin of the system Copyright C 2001, S K. Mitra

Copyright © 2001, S. K. Mitra 12 The Frequency Response • The quantity is called the frequency response of the LTI discrete-time system • provides a frequency-domain description of the system • is precisely the DTFT of the impulse response {h[n]} of the system ( ) j H e ( ) j H e ( ) j H e

The Frequency Response H(es), in general, is a complex function of o with a period2丌 It can be expressed in terms of its real and Imaginary parts H(e u)= hre(e o)+j him(eo) or, in terms of its magnitude and phase H(e/o )=H(e10)e/(o) where 0(o)=arg H(e/o) Copyright C 2001, S K. Mitra

Copyright © 2001, S. K. Mitra 13 The Frequency Response • , in general, is a complex function of  with a period 2p • It can be expressed in terms of its real and imaginary parts or, in terms of its magnitude and phase, where ( ) j H e ( ) ( ) ( )    = + j im j re j H e H e j H e ( ) ( ) ( )     = j j j H e H e e ( ) arg ( )    = j H e

The Frequency Response The function H(e/@ is called the magnitude response and the function 0(o) is called the phase response of the lt discrete-time system Design specifications for the lti discrete time system, in many applications, are given in terms of the magnitude response or the phase response or both 14 Copyright C 2001, S K. Mitra

Copyright © 2001, S. K. Mitra 14 The Frequency Response • The function is called the magnitude response and the function is called the phase response of the LTI discrete-time system • Design specifications for the LTI discrete￾time system, in many applications, are given in terms of the magnitude response or the phase response or both ( ) j H e ()

The Frequency Response In some cases, the magnitude function is specified in decibels as G(o)=20log1o H(e/o)dB where G(o) is called the gain function The negative of the gain function A(o)=-G(0) is called the attenuation or loss function 15 Copyright C 2001, S K. Mitra

Copyright © 2001, S. K. Mitra 15 The Frequency Response • In some cases, the magnitude function is specified in decibels as where G() is called the gain function • The negative of the gain function is called the attenuation or loss function H e dB j ( ) 20log ( ) 10  G  = A () = −G ()