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Lecture #04

Lecture #04. Fourier representation for continuous-time signals. Fourier representations. Fourier Series (FS) : for periodic signals Fourier-Transform (FT) : for nonperiodic signals Discrete-time Fourier series (DTFS): for discrete-time periodic signals

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Lecture #04

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  1. Lecture #04 Fourier representation for continuous-time signals signals & systems

  2. Fourier representations • Fourier Series (FS) : for periodic signals • Fourier-Transform (FT) : for nonperiodic signals • Discrete-time Fourier series (DTFS): for discrete-time periodic signals • Discrete-time Fourier transform : for discrete-time nonperiodic signals signals & systems

  3. A set of function Is called orthogonal in the interval if where is the complex conjugate of then if in is orthonormal Continuous-time signals Orthogonal function: signals & systems

  4. Euler-Fourier formula The question is how to find Ci For any function We choose a orthogonal function set to be the basis signals & systems

  5. Generalized Fourier series: Fourier series of function f(t) signals & systems

  6. example of orthogonal function : in the interval proof signals & systems

  7. For any function f(t) in the interval signals & systems

  8. If f(t) is real function let let signals & systems

  9. Fourier series: signals & systems

  10. A periodic signal satisfying he following conditions can be extended into an infinite sum of sine and cosine functions. 1.The single-valued function f(t) is bounded, and hence absolutely integrable over the finite period T; that is 2.The function has a finite number of maxima and minima over the period T. 3. The function has a finite number of discountinuity points over the period T. signals & systems

  11. signals & systems MIT signals & systems

  12. Example: signals & systems

  13. signals & systems

  14. Frequency spectrum signals & systems

  15. Fourier transform f(t) is not periodic function if T∞ signals & systems

  16. Fourier transform of f(t) Inverse Fourier transform Comparing with Laplace transform signals & systems

  17. The properties of Fourier transform (i) Linearity (ii) Reversal (iii) Scaling in time signals & systems

  18. (iv) Delay (v) Frequency shifting modulation (vi) Frequency differentiation (vii) Convolution signals & systems

  19. signals & systems

  20. (viii) multiplication (ix) Derivative (x) Integration signals & systems

  21. example signals & systems

  22. signals & systems

  23. example signals & systems

  24. example signals & systems

  25. Cardinal sine function signals & systems

  26. Parseval’s theorem (時域頻域能量守恒) If f(t) is real function signals & systems

  27. Example signals & systems

  28. signals & systems

  29. Example: Fourier series signals & systems

  30. signals & systems

  31. Example : Fourier transform signals & systems

  32. signals & systems

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