G. Baribaud/AB-BDI

Digital Signal Processing-2003 The z-transform • The sampling process • The definition and the properties 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 The z-transform • Classification of signals • Sampling of continuous signals • The z-transform: definition • The z-transform: properties • Inverse z-transform • Application to systems • Comments on stability 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Convolution Analogous to Laplace convolution theorem 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

1 k Digital Signal Processing-2003 Apply z-transform 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Discrete Cosine 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Another approach 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Dirac function Digital Signal Processing-2003 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

u(t) 1 t Digital Signal Processing-2003 Sampled step function NB: Equivalent to Exp(-k) as  0 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 T Delayed pulse train t t 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Complete z-transform Example:exponential function 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Addition and substraction 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Multiplication by a constant 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

+ + Digital Signal Processing-2003 -Linearity Application 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

t Digital Signal Processing-2003 Right shifting theorem 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Right shifting theorem Application Unit step function which is delayed by one sampling period Digital Signal Processing-2003 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

t Digital Signal Processing-2003 Left shifting theorem 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Complex translation or damping f(t) is multiplied in continuous domain by Exp(-t) And then sampled at the rate T Laplace transform 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Find the z-transform of sampled at T knowing that Digital Signal Processing-2003 Application 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

S,f t Digital Signal Processing-2003 Sum of a function 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Difference equation 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Example step function kt kt kt Digital Signal Processing-2003 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

u(t) kt -u(t-T) V(t)=u(t)-U(t-T) Digital Signal Processing-2003 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Initial-value theorem If f(t) has a z-transform F(z) and if lim F(z) as z exists Digital Signal Processing-2003 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Final-value theorem 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Initial value Final value Digital Signal Processing-2003 Application:example Expanding F(z) 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Inverse ? -Reference to tables -Practical identification -Analytic methods -Decomposition -Numerical inversion 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Practical identification Discrete exponential g(k) Sum of a function 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Analytic method Laurent series Cauchy theorem Im z x x Re z o x x x x Enclosing all singularities of F(z,) 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Partial fraction expansion With Laplace transform With z-transform no such an expansion, one looks for terms like: The function F(z)/z is developed by partial-fraction expansion 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 The power series method The coefficients of the series expansion represent the values of f(t) (usually a series of numerical values) 13 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Continuous Systems in series with an ideal sampler at each input 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Continuous Systems in series with an ideal sampler at first input In general 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

and by given by Digital Signal Processing-2003 Continuous Systems in series with an ideal sampler at second input 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Discrete and continuous Systems in series with an ideal sampler 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Continuous and discrete Systems in series with an ideal sampler 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Discrete Systems in series with an ideal sampler 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

+ Digital Signal Processing-2003 Continuous Systems in parallel with an ideal sampler 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

+ Digital Signal Processing-2003 Discrete Systems in parallel with an ideal sampler 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

t t Digital Signal Processing-2003 Continuous Systems in series with zero-order hold Transfer function via impulse response 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

Digital Signal Processing-2003 Laplace transform 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

Equal to G(s) with an integrator Digital Signal Processing-2003 Global transfer function Z-transform of G(s) 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

Z-transform Digital Signal Processing-2003 Consequences on the behaviour There are n poles of G(z,), they depend on n the poles of the transfer function of the continuous system 6 March 2003 DISP-2003 G. Baribaud/AB-BDI

G. Baribaud/AB-BDI

G. Baribaud/AB-BDI

Presentation Transcript

G. Baribaud/AB-BDI