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Stability Revisited

As defined earlier in §5.6 (page [*]), a filter is said to be stable if its impulse response $ h(n)$ decays to 0 as $ n$ goes to infinity. In terms of poles and zeros, an irreducible filter transfer function is stable if and only if all its poles are inside the unit circle in the $ z$ plane (as first discussed in §6.8.6). This is because the transfer function is the z transform of the impulse response, and if there is an observable (non-canceled) pole outside the unit circle, then there is an exponentially increasing component of the impulse response. To see this, consider a causal impulse response of the form

$\displaystyle h(n) = R^n e^{j\omega nT}, \qquad n=0,1,2,\ldots\,. $

This signal is a damped complex sinusoid when $ 0 < R < 1$ . It oscillates with zero-crossing rate $ 2\omega/2\pi=\omega/\pi$ zeros per second, and it has an exponentially decaying amplitude envelope. If $ R>1$ , then the amplitude envelope increases exponentially as $ R^n$ .

The signal $ h(n)=R^n e^{j\omega n T}$ has the z transform

\begin{eqnarray*} H(z) &=& \sum_{n=0}^\infty R^n e^{j\omega nT} z^{-n}\\ &=& \sum_{n=0}^\infty \left(R e^{j\omega T}z^{-1}\right)^{n}\\ &=& \frac{1}{1-Re^{j\omega T}z^{-1}}, \end{eqnarray*}

where the last step holds for $ \left\vert R e^{j\omega T}z^{-1}\right\vert<1$ , which is true whenever $ R < \left\vert z\right\vert$ . Thus, the transfer function consists of a single pole at $ z = Re^{j\omega T}$ , and it exists for $ \vert z\vert>R$ .9.1Now consider what happens when we let $ R$ become greater than 1. The pole of $ H(z)$ moves outside the unit circle, and the impulse response has an exponentially increasing amplitude. (Note $ \left\vert h(n)\right\vert = R^n$ .) Thus, the definition of stability is violated. Since the z transform exists only for $ \left\vert z\right\vert > R$ , we see that $ R\geq 1$ implies that the z transform no longer exists on the unit circle, so that the frequency response becomes undefined!

The above one-pole analysis shows that a one-pole filter is stable if and only if its pole is inside the unit circle. In the case of an arbitrary transfer function, inspection of its partial fraction expansion6.8) shows that the behavior near any pole approaches that of a one-pole filter consisting of only that pole. Therefore, all poles must be inside the unit circle for stability.

In summary, we can state the following:

$\textstyle \parbox{0.8\textwidth}{A necessary and sufficient condition for the \emph{stability}\index{stability of a digital filter\vert textbf} of a finite-order causal LTI digital filter is that all poles of its irreducible transfer function lie strictly inside the unit circle.}$
Isolated poles on the unit circle may be called marginally stable. The impulse response component corresponding to a single pole on the unit circle never decays, but neither does it grow.9.2 In physical modeling applications, marginally stable poles occur often in lossless systems, such as ideal vibrating string models [86].


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``Introduction to Digital Filters with Audio Applications'', by Julius O. Smith III, (September 2007 Edition)
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Center for Computer Research in Music and Acoustics (CCRMA),   Stanford University
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