Difference between revisions of "Z Transform table" - Rhea

Revision as of 06:59, 24 April 2012

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Z Transform Pairs and Properties
Definition Z Transform and its Inverse
(Double-side) Z Transform	$X(z)=\mathcal{L}(x[n])=\sum_{n=-\infty}^{\infty}x[n]z^{-n}$	(info)
Inverse Z Transform	$x[n]=\mathcal{L}^{-1}(X(z))=\frac{1}{2\pi j}\oint_{c}X(z)z^{n-1}dz$

Z Transform Pairs
	Signal $$ x[n] $$	Transform $$ X(z) $$	ROC
Unit impulse signal	$\delta[n]\$	$1\$	$All\ z\$
Unit step signal	$u[n]\$	$\frac{1}{1-z^{-1}}$	$\|z\| > 1\$
	$-u[-n-1]\$	$\frac{1}{1-z^{-1}}$	$\|z\| < 1\$
Shifted unit impulse signal	$\delta[n-m]\$	$z^{-m}\$	$All\ z,\ except\$
			$0\ (if\ m>0)\ or\$
			$\infty \ (if\ m<0)\$
	$\alpha^{n}u[n]\$	$\frac{1}{1-\alpha z^{-1}}$	$\|z\| > \| \alpha \|\$
	$-\alpha^{n}u[-n-1]\$	$\frac{1}{1-\alpha z^{-1}}$	$\|z\| < \| \alpha \|\$
	$n\alpha^{n}u[n]\$	$\frac{\alpha z^{-1}}{(1-\alpha z^{-1})^{2}}$	$\|z\| > \| \alpha \|\$
	$-n\alpha^{n}u[-n-1]\$	$\frac{\alpha z^{-1}}{(1-\alpha z^{-1})^{2}}$	$\|z\| < \| \alpha \|\$
Single-side cosine signal	$[\cos{\omega_{0}n}]u[n]\$	$\frac{1-[\cos{\omega_{0}}]z^{-1}}{1-[2\cos{\omega_{0}}]z^{-1}+z^{-2}}$	$\|z\| > 1\$
Single-side sine signal	$[\sin{\omega_{0}n}]u[n]\$	$\frac{1-[\sin{\omega_{0}}]z^{-1}}{1-[2\cos{\omega_{0}}]z^{-1}+z^{-2}}$	$\|z\| > 1\$
	$[r^{n}\cos{\omega_{0}n}]u[n]\$	$\frac{1-[r\cos{\omega_{0}}]z^{-1}}{1-[2r\cos{\omega_{0}}]z^{-1}+r^{2}z^{-2}}$	$\|z\| > r\$
	$[r^{n}\sin{\omega_{0}n}]u[n]\$	$\frac{1-[r\sin{\omega_{0}}]z^{-1}}{1-[2r\cos{\omega_{0}}]z^{-1}+r^{2}z^{-2}}$	$\|z\| > r\$

Z Transform Properties
	Signal $$ x[n] $$	Transform $$ X(f) $$	ROC
	$x[n]\$	$X(z)\$	$R\$
	$x_{1}[n]\$	$X_{1}(z)\$	$R_{1}\$
	$x_{2}[n]\$	$X_{2}(z)\$	$R_{2}\$
Linearity	$ax_{1}[n]+bx_{2}[n]\$	$aX_{1}(z)+bX_{2}[z]\$	$At\ least\ the\ intersection\ of\ R_{1}\ and\ R_{2}\$
Time shifting	$x[n-n_{0}]\$	$z^{-n_{0}}X(z)\$	$R,\ except\ for\ the\ possible\ addition\$
			$or\ deletion\ of\ the\ origin\$
Scaling in the z-domain	$e^{j\omega_{0}n}x[n]\$	$X(e^{j\omega_{0}}z)\$	$R\$
	$z_{0}^{n}x[n]\$	$X(\frac{z}{z_{0}})\$	$z_{0}R\$
	$a^{n}x[n]\$	$X(a^{-1}z)\$	$Scaled\ version\ of\ R\$
			$(i.e.,\ \|a\|R=\ the\ set\ of\ points\ {\|a\|z}\ for\ z\ in\ R)\$
Time reversal	$x[-n]\$	$X(z^{-1})\$	$R^{1/k}\ (i.e.,\ the\ set\ of\ points\ z^{1/k},\$
			$where\ z\ is\ in\ R)\$
Time expansion	$x^{(k)}= \begin{cases} x[r], &n=rk \\ 0, &n\neq rk \end{cases}$	$X(z^{k})\$	$R^{1/k}\ (i.e.,\ the\ set\ of\ points\ z^{1/k},\$
			$where\ z\ is\ in\ R)\$
Conjugation	$x^{*}[n]\$	$X^{}(z^{})\$	$R\$
Convolution	$x_{1}[n]*x_{2}[n]\$	$X_{1}(z)X_{2}(z)\$	$At\ least\ the\ intersection\ of\ R_{1}\ and\ R_{2}\$
First difference	$x[n]-x[n-1]\$	$(1-z^(-1))X(z)\$	$At\ least\ the\ intersection\ of\ R\ and\ \|z\|>0\$
Accumulation	$\sum_{k=-\infty}^{n}x[k]\$	$\frac{1}{(1-z^(-1))}X(z)\$	$At\ least\ the\ intersection\ of\ R\ and\ \|z\|>1\$
Differentiation in the z-domain	$nx[n]\$	$-z\frac{dX(z)}{dz}\$	$R\$

Other Z Transform Properties
Initial Value Theorem	$If\ x[n]=0\ for\ n<0,\ then\ x[0]=\lim_{z\rightarrow \infty}X(z)\$

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