The unit step response of an LTI system

1. The unit step response of an LTI system

2. Linear constant-coefficient difference equations + delay When n 1, Causality

3. Linear constant-coefficient difference equations + delay Determine A by initial condition: When n = 0, A = 1

4. Linear constant-coefficient difference equations + delay Two ways: (1) Repeat the procedure (2)

5. Linear constant-coefficient difference equations + When t>0, Causality Determine A by initial condition:

6. Linear constant-coefficient difference equations + Determine A by initial condition: A = 1

7. Linear constant-coefficient difference equations +

8. 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:

9. Fourier series representation of continuous-time periodical signal Periodic signal for all t k is an integer

10. Fourier series representation of continuous-time periodical signal Periodic signal for all t k is an integer e.g.

11. Fourier series representation of continuous-time periodical signal 0

12. The response of system to complex exponentials Band limited channel Bandwidth Bandwidth

13. Fourier series representation of discrete-time periodical signal Periodic signal for all t

14. Example #1

15. Properties of discrete-time Fourier series (1) Linearity

16. (2) Time shifting (3) Time reversal

17. (4) Time scaling (5) multiplication

18. (6) Conjugation and conjugate symmetry Real signal Even Real & Even

19. (7) Parseval’s relation

20. (8) Time difference (9) Running sum

21. Example N = 4 [1, 2, 2, 1] [1, 1, 1, 1]

22. Fourier series and LTI system Output periodic? Periodic signal System response doesn’t have to be periodic.

24. Filtering • Frequency-shaping filters • Frequency-selective filters (1) Frequency-shaping filters

25. (1) Frequency-shaping filters

26. (2) Frequency-selective filters Low-pass high-pass band-pass

27. Discrete-time

28. Example: averaging

29. Continuous-time Fourier transform Aperiodic signal Periodic signal k is an integer

30. Continuous-time Fourier transform Aperiodic signal Periodic signal k is an integer

31. Examples

32. Properties of continuous-time Fourier transform (1) Linearity

33. Properties of continuous-time Fourier transform (2) Time shifting (3) Time reversal

34. Properties of continuous-time Fourier transform (4) Time scaling

35. Properties of continuous-time Fourier transform (5) Conjugation and conjugate summary Real

36. Example even Even and real

37. Differential

38. Integral

39. Example

40. Example

41. Example

42. Example

43. Parseval’s relation

44. Parseval’srelation for continuous-time Fourier series Parseval’srelation for continuous-time Fourier transfer

45. Example 1.0 -1.0 0.5 -0.5

46. Example 1.0 -1.0 0.5 -0.5

47. Example, P. 4.14 (1) real (2) (3) Solution:

48. Example, P. 4.14 (1) real (2) (3) Solution:

49. Example, P. 4.14 Solution:

50. Example, P. 4.14 (3) Solution: