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Signals and Systems Fall 2003 Lecture #12 16 October 2003 1. Linear and Nonlinear Phase 2. Ideal and Nonideal Frequency-Selective Filters 3. CT & DT Rational.

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Presentation on theme: "Signals and Systems Fall 2003 Lecture #12 16 October 2003 1. Linear and Nonlinear Phase 2. Ideal and Nonideal Frequency-Selective Filters 3. CT & DT Rational."— Presentation transcript:

1 Signals and Systems Fall 2003 Lecture #12 16 October 2003 1. Linear and Nonlinear Phase 2. Ideal and Nonideal Frequency-Selective Filters 3. CT & DT Rational Frequency Responses 4. DT First- and Second-Order Systems

2 Linear Phase CT Result:Linear phase ⇔ simply a rigid shift in time, no distortion Nonlinear phase ⇔ distortion as well as shift DT Question: What about H (e jw ) = e -jwα, α ≠ integer?

3 All-Pass Systems CT DTDT Linear phase Nonlinear phase Linear phase Nonlinear phase

4 Demo:Impulse response and output of an all-pass system with nonlinear phase Principal PhaseInput to Allpass System Unwrapped Phase Impulse Response Output of Allpass System Phase (rad) Group Delay (sec) Frequency (Hz) Time (sec) Group Delay

5 How do we think about signal delay when the phase is nonlinear? Group Delay φ When the signal is narrow-band and concentrated near ω 0,  H (jw) ~ linear with ω near ω 0, then instead of reflects the time delay. For frequencise “near” ω 0 For w “near” ω 0

6 Ideal Lowpass Filter CTCT Noncausal h(t <0) ≠ 0 Oscillatory Response — e.g. step response Overshoot by 9%, Gibbs phenomenon

7 Nonideal Lowpass Filter Sometimes we don’t want a sharp cutoff, e.g. Often have specifications in time and frequency domain ⇒ Trade-offs Step response Freq. Response Passband Transition Stopband signalnoise

8 CT Rational Frequency Responses CT: If the system is described by LCCDEs, then Prototypical System — First-order system, has only one energy storing element, e.g. L or C — Second-order system, has two energy storing elements, e.g. L and C

9 DT Rational Frequency Responses If the system is described by LCCDE’s (Linear-Constant-Coefficient Difference Equations), then First- or Second-order

10 DT First-Order Systems Frequency domain Time Domain initial rest

11 Demo: Unit-sample, unit-step, and frequency response of DT first-order systems Impulse Response Step Response Magnitude of Frequency Response Phase of Frequency Response (rad) n (samples) ω (rad/sec)

12 DT Second-Order System decaying oscillations where

13 Demo:Unit-sample, unit-step, and frequency response of DT second-order systems Impulse Response Step Response Phase of Frequency Response (rad) n (samples) ω (rad/sec)

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