(Resion of Convergence)
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The Z-plane is a complex plane with an imaginary and real axis referring to the complex-valued variable z. The position on the complex plane is given by rⅇⅈω , and the angle from the positive, real axis around the plane is denoted by ω. X(z) is defined everywhere on this plane. X(ⅇⅈω) on the other hand is defined only where |z|=1, which is referred to as the unit circle. So for example, ω=1 at z=1 and ω=<apply>π</apply> at z=-1. This is useful because, by representing the Fourier transform as the z-transform on the unit circle, the periodicity of Fourier transform is easily seen.
 
The Z-plane is a complex plane with an imaginary and real axis referring to the complex-valued variable z. The position on the complex plane is given by rⅇⅈω , and the angle from the positive, real axis around the plane is denoted by ω. X(z) is defined everywhere on this plane. X(ⅇⅈω) on the other hand is defined only where |z|=1, which is referred to as the unit circle. So for example, ω=1 at z=1 and ω=<apply>π</apply> at z=-1. This is useful because, by representing the Fourier transform as the z-transform on the unit circle, the periodicity of Fourier transform is easily seen.
  
== Resion of Convergence ==
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== Region of Convergence ==

Revision as of 16:17, 3 December 2008

Basic definition of the Z-Transform

The Z-transform of a sequence is defined as $ H(z) = \sum^{\infty}_{n = -\infty} h[n]z^{-n} $

The complex plane

In order to get further insight into the relationship between the Fourier Transform and the Z-Transform it is useful to look at the complex plane or z-plane. Take a look at the complex plane:

Zplane1 ECE301Fall2008mboutin.jpg

The Z-plane is a complex plane with an imaginary and real axis referring to the complex-valued variable z. The position on the complex plane is given by rⅇⅈω , and the angle from the positive, real axis around the plane is denoted by ω. X(z) is defined everywhere on this plane. X(ⅇⅈω) on the other hand is defined only where |z|=1, which is referred to as the unit circle. So for example, ω=1 at z=1 and ω=<apply>π</apply> at z=-1. This is useful because, by representing the Fourier transform as the z-transform on the unit circle, the periodicity of Fourier transform is easily seen.

Region of Convergence

Alumni Liaison

Ph.D. on Applied Mathematics in Aug 2007. Involved on applications of image super-resolution to electron microscopy

Francisco Blanco-Silva