1. The Fourier Transform

2. Contents Complex numbers etc. Impulses Fourier Transform (+examples)
Convolution theorem
Fourier Transform of sampled functions
Sampling theorem
Aliasing
Discrete Fourier Transform
Application Examples

3. Introduction Jean Baptiste Joseph Fourier (*1768-†1830)
French Mathematician
La Théorie Analitique de la Chaleur (1822)

4. Fourier Series Fourier Series
Any periodic function can be expressed as a sum of sines and/or cosines
Fourier Series

5. Fourier Transform Even functions that
are not periodic
have a finite area under curve
can be expressed as an integral of sines and cosines multiplied by a weighing function
Both the Fourier Series and the Fourier Transform have an inverse operation:
Original Domain Fourier Domain

6. Contents Complex numbers etc. Impulses Fourier Transform (+examples)
Convolution theorem
Fourier Transform of sampled functions
Sampling theorem
Aliasing
Discrete Fourier Transform
Application Examples

7. Complex numbers
Complex number
Its complex conjugate

8. Complex numbers polar
Complex number in polar coordinates

9. Euler’s formula ?
Sin (θ) ?
Cos (θ)

10. Vector Im Re

11. Complex math Complex (vector) addition Multiplication with I
is rotation by 90 degrees

12. Contents Complex number etc. Impulses Fourier Transform (+examples)
Convolution theorem
Fourier Transform of sampled functions
Sampling theorem
Aliasing
Discrete Fourier Transform
Application Examples

13. Unit impulse (Dirac delta function)
Definition
Constraint
Sifting property
Specifically for t=0

14. Discrete unit impulse Definition Constraint Sifting property
Specifically for x=0

15. Impulse train
What does this look like?
ΔT = 1

16. Contents Complex number etc. Impulses Fourier Transform (+examples)
Convolution theorem
Fourier Transform of sampled functions
Sampling theorem
Aliasing
Discrete Fourier Transform
Application Examples

17. Series of sines and cosines, see Euler’s formula
Fourier Series
Periodic with period T
with
Series of sines and cosines, see Euler’s formula

18. Fourier Transform Continuous Fourier Transform (1D)
Inverse Continuous Fourier Transform (1D)

19. Symmetry: The only difference between the Fourier Transform and its inverse is the sign of the exponential.

20. Fourier and Euler
Fourier
Euler

21. If f(t) is real, then F(μ) is complex
F(μ) is expansion of f(t) multiplied by sinusoidal terms
t is integrated over, disappears
F(μ) is a function of only μ, which determines the frequency of sinusoidals
Fourier transform frequency domain

22. Examples – Block 1 A
-W/2
W/2

23. Examples – Block 2

24. Examples – Block 3 ?

25. Examples – Impulse
constant

26. Examples – Shifted impulse
Euler

27. Examples – Shifted impulse 2
constant
Real part
Imaginary part

28. Examples - Impulse train

29. Examples - Impulse train 2

30. Intermezzo: Symmetry in the FT

32. Contents Complex number etc. Impulses Fourier Transform (+examples)
Convolution theorem
Fourier Transform of sampled functions
Sampling theorem
Aliasing
Discrete Fourier Transform
Application Examples

33. Fourier + Convolution
What is the Fourier domain equivalent of convolution?

34. What is

35. Intermezzo 1
What is ?
Let , so

36. Intermezzo 2
Property of Fourier Transform

37. Fourier + Convolution cont’d

38. Recapitulation 1
Convolution in one domain is multiplication in the other domain
And (see book)

39. Recapitulation 2
Shift in one domain is multiplication with complex exponential in the other domain
And (see book)

40. Contents Complex number etc. Impulses Fourier Transform (+examples)
Convolution theorem
Fourier Transform of sampled functions
Sampling theorem
Aliasing
Discrete Fourier Transform
Application Examples

41. Sampling Sampled function can be written as
Obtain value of arbitrary sample k as

42. Sampling - 2

43. Sampling - 3

44. Sampling - 4

45. FT of sampled functions
Fourier transform of sampled function
Convolution theorem
From FT of impulse train
(who?)

46. FT of sampled functions

47. Sifting property

48. Contents Complex number etc. Impulses Fourier Transform (+examples)
Convolution theorem
Fourier Transform of sampled functions
Sampling theorem
Aliasing
Discrete Fourier Transform
Application Examples

49. Sampling theorem Band-limited function Sampled function
lower value of 1/ΔT would cause triangles to merge

50. Sampling theorem 2 Sampling theorem:
“If copy of can be isolated from the periodic sequence of copies contained in , can be completely recovered from the sampled version.
Since is a continuous, periodic function with period 1/ΔT, one complete period from is enough to reconstruct the signal.
This can be done via the Inverse FT.

51. Sampling theorem 3
Extracting a single period from that is equal to is possible if
Nyquist frequency

52. Contents Complex number etc. Impulses Fourier Transform (+examples)
Convolution theorem
Fourier Transform of sampled functions
Sampling theorem
Aliasing
Discrete Fourier Transform
Application Examples

53. Aliasing
If , aliasing can occur

54. Contents Complex number etc. Impulses Fourier Transform (+examples)
Convolution theorem
Fourier Transform of sampled functions
Sampling theorem
Aliasing
Discrete Fourier Transform
Application Examples

55. Discrete Fourier Transform
Fourier Transform of a sampled function is an infinite periodic sequence of copies of the transform of the original continuous function

56. Discrete Fourier Transform
Continuous transform of sampled function

57. is discrete function
is continuous and infinitely periodic with period /ΔT

58. We need only one period to characterise
If we want to take M equally spaced samples from in the period μ = 0 to μ = 1/Δ, this can be done thus

59. Substituting
Into
yields

60. Contents Complex number etc. Impulses Fourier Transform (+examples)
Convolution theorem
Fourier Transform of sampled functions
Sampling theorem
Aliasing
Discrete Fourier Transform
Application Examples

61. Fourier Transform Table

63. Formulation in 2D spatial coordinates
Continuous Fourier Transform (2D)
Inverse Continuous Fourier Transform (2D) with angular frequencies

64. Contents Fourier Transform of sine and cosine 2D Fourier Transform
Properties of the Discrete Fourier Transform

65. Euler’s formula

66. Recall

67. Recall

68. 1/2
1/2i
Cos(ωt)
Sin(ωt)

69. Contents Fourier Transform of sine and cosine 2D Fourier Transform
Properties of the Discrete Fourier Transform

70. Formulation in 2D spatial coordinates
Continuous Fourier Transform (2D)
Inverse Continuous Fourier Transform (2D) with angular frequencies

71. Discrete Fourier Transform
Forward
Inverse

72. Formulation in 2D spatial coordinates
Discrete Fourier Transform (2D)
Inverse Discrete Transform (2D)

73. Spatial and Frequency intervals
Inverse proportionality
(Smallest) Frequency step depends on largest distance covered in spatial domain
Suppose function is sampled M times in x, with step , distance is covered, which is related to the lowest frequency that can be measured

74. Examples

75. Series of sines and cosines, see Euler’s formula
Fourier Series
Periodic with period T
with
Series of sines and cosines, see Euler’s formula

76. Examples

77. Periodicity
2D Fourier Transform is periodic in both directions

78. Periodicity
2D Inverse Fourier Transform is periodic in both directions

79. Fourier Domain

80. Inverse Fourier Domain
Periodic!
Periodic?

81. Contents Fourier Transform of sine and cosine 2D Fourier Transform
Properties of the Discrete Fourier Transform

82. Properties of the 2D DFT

83. Real
Real
Imaginary
Sin (x)
Sin (x + π/2)

84. Even
Real
Imaginary
F(Cos(x))
F(Cos(x)+k)

85. Odd
Real
Imaginary
Sin (x)Sin(y)
Sin (x)

86. Real
Imaginary
(Sin (x)+1)(Sin(y)+1)

87. Symmetry: even and odd
Any real or complex function w(x,y) can be expressed as the sum of an even and an odd part (either real or complex)

88. Properties
Even function
Odd function

89. Properties - 2

90. Consequences for the Fourier Transform
FT of real function is conjugate symmetric
FT of imaginary function is conjugate antisymmetric

91. Im

92. Re

93. Re

94. Im

95. FT of even and odd functions
FT of even function is real
FT of odd function is imaginary

96. Even
Real
Imaginary
Cos (x)

97. Odd
Real
Imaginary
Sin (x)