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The unit step response of an LTI system. Linear constant-coefficient difference equations. +. delay. When n 1,. Causality. Linear constant-coefficient difference equations. +. delay. Determine A by initial condition:. When n = 0 ,. A = 1.
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Linear constant-coefficient difference equations + delay When n 1, Causality
Linear constant-coefficient difference equations + delay Determine A by initial condition: When n = 0, A = 1
Linear constant-coefficient difference equations + delay Two ways: (1) Repeat the procedure (2)
Linear constant-coefficient difference equations + When t>0, Causality Determine A by initial condition:
Linear constant-coefficient difference equations + Determine A by initial condition: A = 1
Fourier series representation of continuous-time periodical signal Periodic signal for all t k is an integer Fourier series form a complete and orthogonal bases Complete: no other basis is needed. Kronecker Delta Orthogonal: Orthogonal:
Fourier series representation of continuous-time periodical signal Periodic signal for all t k is an integer
Fourier series representation of continuous-time periodical signal Periodic signal for all t k is an integer e.g.
Fourier series representation of continuous-time periodical signal 0
The response of system to complex exponentials Band limited channel Bandwidth Bandwidth
Fourier series representation of discrete-time periodical signal Periodic signal for all t
Properties of discrete-time Fourier series (1) Linearity
(2) Time shifting (3) Time reversal
(4) Time scaling (5) multiplication
(6) Conjugation and conjugate symmetry Real signal Even Real & Even
(8) Time difference (9) Running sum
Example N = 4 [1, 2, 2, 1] [1, 1, 1, 1]
Fourier series and LTI system Output periodic? Periodic signal System response doesn’t have to be periodic.
Filtering • Frequency-shaping filters • Frequency-selective filters (1) Frequency-shaping filters
(2) Frequency-selective filters Low-pass high-pass band-pass
Continuous-time Fourier transform Aperiodic signal Periodic signal k is an integer
Continuous-time Fourier transform Aperiodic signal Periodic signal k is an integer
Properties of continuous-time Fourier transform (1) Linearity
Properties of continuous-time Fourier transform (2) Time shifting (3) Time reversal
Properties of continuous-time Fourier transform (4) Time scaling
Properties of continuous-time Fourier transform (5) Conjugation and conjugate summary Real
Example even Even and real
Parseval’srelation for continuous-time Fourier series Parseval’srelation for continuous-time Fourier transfer
Example 1.0 -1.0 0.5 -0.5
Example 1.0 -1.0 0.5 -0.5
Example, P. 4.14 (1) real (2) (3) Solution:
Example, P. 4.14 (1) real (2) (3) Solution:
Example, P. 4.14 Solution:
Example, P. 4.14 (3) Solution: