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==Introduction== | ==Introduction== | ||
This page will go over some of my conclusions about properties of the z-transform and discuss some examples of how they may | This page will go over some of my conclusions about properties of the z-transform and discuss some examples of how they may | ||
| − | be used to draw conclusions about LTI systems. This topic assumes some basic knowledge of the z-transform and signal processing, however some definitions are provided below as a refresher or for reference. The information provided is intended to clarify or | + | be used to draw conclusions about LTI systems and digital filters. This topic assumes some basic knowledge of the z-transform and signal processing, however some definitions are provided below as a refresher or for reference. The information provided is intended to clarify or augment some of the z-transform properties presented in class. Some of the information includes statements or arguments to validate or clarify claims; these are intended to aid understanding but not substitute for a proof. |
| + | |||
==definitions== | ==definitions== | ||
| − | z-transform: <math> X(z) = \sum_{n=-\infty}^{\infty} x[n]z^{-n} </math> | + | z-transform: <math> X(z) = \sum_{n=-\infty}^{\infty} x[n]z^{-n} </math> z ∈ ℂ |
| + | |||
| + | DTFT: <math> X(\omega) = \sum_{n=-\infty}^{\infty} x[n]e^{-j\omega n} </math> | ||
| + | |||
| + | right sided: <math>x[n]</math> such that <math>x[n] = 0</math> ∀ n < n<sub>0</sub> | ||
| + | |||
| + | left sided: <math>x[n]</math> such that <math>x[n] = 0</math> ∀ n > n<sub>0</sub> | ||
| + | |||
| + | both sided: <math>x[n]</math> such that <math>x[n] = 0</math> ∀ n > n<sub>1</sub> and n < n<sub>2</sub> ,n<sub>1</sub> < n<sub>2</sub> | ||
| + | |||
| + | neither sided: <math>x[n]</math> has finite duration, meaning <math>x[n] = 0</math> ∀ n < n<sub>1</sub> and n > n<sub>2</sub>, n<sub>1</sub> < n<sub>2</sub> | ||
| + | |||
| + | Absolutely Summable: <math>x[n]</math> is absolutely summable if: <math> \sum_{n=-\infty}^{\infty} |x[n]| = c</math>, | ||
| + | where <math>c</math> is a constant. | ||
| + | |||
| + | z-plane: the complex plane. | ||
| + | |||
| + | |||
| + | ==Relationship Between Fourier Transform and Z Transform== | ||
| + | In the z-transform definition above, z is any complex number, which can be represented in polar coordinates by | ||
| + | <math> z = re^{j\omega} </math> | ||
| + | Then the z-transform can be written as: | ||
| + | <math> X(z) = X(re^{j\omega}) = \sum_{n=-\infty}^{\infty} x[n](re)^{-j \omega n} </math>. | ||
| + | Thus if r = 1, meaning that z is constrained to z = <math>e^{j\omega}</math>, then the z-transform is equivalent to the DTFT, and the DTFT is the z-transform with z constrained to the unit circle in the z-plane. | ||
| + | |||
| + | Since the z-transform exists outside the unit circle, it is useful for analyzing signal that don't have a DTFT, analyzing LTI system stability, and looking at the transfer function characteristics among other uses. | ||
| + | |||
| + | ==Summary of Z Transform Properties== | ||
| + | :(a) The DTFT(x[n]) converges if the ROC of X(z) contains the unit circle on the z-plane. | ||
| + | :(b) No poles of X(z) are included in the ROC of X(z), poles of X(z) shape the ROC. E.g. if X(z) has a pole at 0, then z = 0 is not included in the ROC. | ||
| + | :(c) For Right Sided x[n], the ROC of X(z): | ||
| + | ::(i) is generally defined by |z| > z<sub>0</sub> (outside a circle in the z-plane) | ||
| + | ::(ii) includes <math>\infty</math> if n<sub>0</sub> ≥ 0 | ||
| + | ::(iii) z = 0 could possibly be included in the ROC | ||
| + | :: (iv) the farthest pole from the origin lies just inside |z<sub>0</sub>| | ||
| + | :(d) For Left Sided x[n], the ROC of X(z): | ||
| + | ::(i) is generally defined by |z| < z<sub>0</sub> (inside a circle in the z-plane) | ||
| + | ::(ii) includes z = 0 if n<sub>0</sub> ≤ 0 | ||
| + | ::(iii) z = <math>\infty</math> could possibly be included | ||
| + | ::(iv) the nearest pole to the origin lies just outside of |z<sub>0</sub>| | ||
| + | :(e) For Both Sided x[n], the ROC of X(z): | ||
| + | ::(i) is generally a ring in the z-plane such as z<sub>1</sub> < |z| < z<sub>2</sub> | ||
| + | ::(ii) does not include z = 0 or z = <math>\infty</math> | ||
| + | :(f) For finite duration x[n] (neither sided), the ROC of X(z): | ||
| + | ::(i) includes the entire complex plane | ||
| + | ::(ii) x[n] has no poles except maybe z = 0 or z = <math>\infty</math> | ||
| + | ::(iii) if for x[n], n<sub>1</sub> ≥ 0, z = <math>\infty</math> is included | ||
| + | ::(iv) if for x[n], n<sub>2</sub> ≤ 0, z = 0 is included | ||
| + | ::(v) if n<sub>1</sub> < 0 and n<sub>2</sub> > 0, then neither z = 0 or z = <math>\infty</math> is included | ||
| + | |||
| + | ==LTI Systems and Z Transform Properties== | ||
| + | (1) System Stability | ||
| + | |||
| + | An LTI System with impulse response h[n] is BIBO stable if h[n] is absolutely summable. | ||
| + | :(a) This is a condition for the DTFT to exist, so it must also be true that the ROC of H(z) contains the unit circle in the z-plane. | ||
| + | :(b) This implies that the poles of a right sided h[n] must be inside the unit circle and poles of a left sided h[n] must be outside of the unit circle in the z-plane for h[n] to be BIBO stable. | ||
| + | |||
| + | (2) Causal LTI Systems | ||
| + | From statements in (1) and (c) above, a few conclusions about causal system can be made: | ||
| + | :(a) The ROC of H(z) includes z = <math>\infty</math> and |z| > z<sub>0</sub> | ||
| + | :(b) For H(z) to be BIBO stable, it must have poles inside the unit circle in the z-plane. | ||
| + | :(c) H(z) must have more poles than zeros. | ||
| + | : One possible reasoning: Assuming that a causal system has the ROC defined in (a), then assuming H(z) has more zeros than poles would be a contradiction, since H(z) can could then be decomposed by long division or partial fractions into a function of z that diverges in the region |z| > z<sub>0</sub> and <math>\infty</math>. Simply taking the limit of H(z) as z approaches <math>\infty</math> would show a contradiction since the ROC would not include z = <math>\infty</math>. | ||
| + | |||
| + | ==Z Transform and Digital Filters== | ||
| + | The z-transform properties above can also give insight into characteristics of FIR and IIR filters | ||
| + | :(a) FIR filters: | ||
| + | ::(i) since h[n] is of finite duration, it has no poles except possibly z = 0 or z = <math>\infty</math> | ||
| + | ::(ii) The ROC of H(z) includes the entire z-plane besides possibly z = 0 or z = <math>\infty</math> | ||
| + | (from (b) above) | ||
| + | :(b) IIR filters: | ||
| + | ::(i) H(z) has non-zero poles in the finite z-plane | ||
| + | ::(ii) The denominator of H(z) must have a degree > 1 | ||
| + | ::Reasoning: the ROC of H(z) for a neither sided signal is a ring, implying that there must be two non-zero poles to bound the ROC. | ||
Latest revision as of 23:57, 1 December 2019
Contents
Z Transform and LTI System Properties Study Guide
Introduction
This page will go over some of my conclusions about properties of the z-transform and discuss some examples of how they may be used to draw conclusions about LTI systems and digital filters. This topic assumes some basic knowledge of the z-transform and signal processing, however some definitions are provided below as a refresher or for reference. The information provided is intended to clarify or augment some of the z-transform properties presented in class. Some of the information includes statements or arguments to validate or clarify claims; these are intended to aid understanding but not substitute for a proof.
definitions
z-transform: $ X(z) = \sum_{n=-\infty}^{\infty} x[n]z^{-n} $ z ∈ ℂ
DTFT: $ X(\omega) = \sum_{n=-\infty}^{\infty} x[n]e^{-j\omega n} $
right sided: $ x[n] $ such that $ x[n] = 0 $ ∀ n < n0
left sided: $ x[n] $ such that $ x[n] = 0 $ ∀ n > n0
both sided: $ x[n] $ such that $ x[n] = 0 $ ∀ n > n1 and n < n2 ,n1 < n2
neither sided: $ x[n] $ has finite duration, meaning $ x[n] = 0 $ ∀ n < n1 and n > n2, n1 < n2
Absolutely Summable: $ x[n] $ is absolutely summable if: $ \sum_{n=-\infty}^{\infty} |x[n]| = c $, where $ c $ is a constant.
z-plane: the complex plane.
Relationship Between Fourier Transform and Z Transform
In the z-transform definition above, z is any complex number, which can be represented in polar coordinates by $ z = re^{j\omega} $ Then the z-transform can be written as: $ X(z) = X(re^{j\omega}) = \sum_{n=-\infty}^{\infty} x[n](re)^{-j \omega n} $. Thus if r = 1, meaning that z is constrained to z = $ e^{j\omega} $, then the z-transform is equivalent to the DTFT, and the DTFT is the z-transform with z constrained to the unit circle in the z-plane.
Since the z-transform exists outside the unit circle, it is useful for analyzing signal that don't have a DTFT, analyzing LTI system stability, and looking at the transfer function characteristics among other uses.
Summary of Z Transform Properties
- (a) The DTFT(x[n]) converges if the ROC of X(z) contains the unit circle on the z-plane.
- (b) No poles of X(z) are included in the ROC of X(z), poles of X(z) shape the ROC. E.g. if X(z) has a pole at 0, then z = 0 is not included in the ROC.
- (c) For Right Sided x[n], the ROC of X(z):
- (i) is generally defined by |z| > z0 (outside a circle in the z-plane)
- (ii) includes $ \infty $ if n0 ≥ 0
- (iii) z = 0 could possibly be included in the ROC
- (iv) the farthest pole from the origin lies just inside |z0|
- (d) For Left Sided x[n], the ROC of X(z):
- (i) is generally defined by |z| < z0 (inside a circle in the z-plane)
- (ii) includes z = 0 if n0 ≤ 0
- (iii) z = $ \infty $ could possibly be included
- (iv) the nearest pole to the origin lies just outside of |z0|
- (e) For Both Sided x[n], the ROC of X(z):
- (i) is generally a ring in the z-plane such as z1 < |z| < z2
- (ii) does not include z = 0 or z = $ \infty $
- (f) For finite duration x[n] (neither sided), the ROC of X(z):
- (i) includes the entire complex plane
- (ii) x[n] has no poles except maybe z = 0 or z = $ \infty $
- (iii) if for x[n], n1 ≥ 0, z = $ \infty $ is included
- (iv) if for x[n], n2 ≤ 0, z = 0 is included
- (v) if n1 < 0 and n2 > 0, then neither z = 0 or z = $ \infty $ is included
LTI Systems and Z Transform Properties
(1) System Stability
An LTI System with impulse response h[n] is BIBO stable if h[n] is absolutely summable.
- (a) This is a condition for the DTFT to exist, so it must also be true that the ROC of H(z) contains the unit circle in the z-plane.
- (b) This implies that the poles of a right sided h[n] must be inside the unit circle and poles of a left sided h[n] must be outside of the unit circle in the z-plane for h[n] to be BIBO stable.
(2) Causal LTI Systems From statements in (1) and (c) above, a few conclusions about causal system can be made:
- (a) The ROC of H(z) includes z = $ \infty $ and |z| > z0
- (b) For H(z) to be BIBO stable, it must have poles inside the unit circle in the z-plane.
- (c) H(z) must have more poles than zeros.
- One possible reasoning: Assuming that a causal system has the ROC defined in (a), then assuming H(z) has more zeros than poles would be a contradiction, since H(z) can could then be decomposed by long division or partial fractions into a function of z that diverges in the region |z| > z0 and $ \infty $. Simply taking the limit of H(z) as z approaches $ \infty $ would show a contradiction since the ROC would not include z = $ \infty $.
Z Transform and Digital Filters
The z-transform properties above can also give insight into characteristics of FIR and IIR filters
- (a) FIR filters:
- (i) since h[n] is of finite duration, it has no poles except possibly z = 0 or z = $ \infty $
- (ii) The ROC of H(z) includes the entire z-plane besides possibly z = 0 or z = $ \infty $
(from (b) above)
- (b) IIR filters:
- (i) H(z) has non-zero poles in the finite z-plane
- (ii) The denominator of H(z) must have a degree > 1
- Reasoning: the ROC of H(z) for a neither sided signal is a ring, implying that there must be two non-zero poles to bound the ROC.
