Fractional Fourier Transform
- Orange and yellow hues depict the positive-most values within the given frame
- Violet and blue hues depict the negative-most values within the given frame
- Red hues depict (positive or negative) near-infinite to infinite values
The Quadratic Function in the Fractional Fourier Transform Kernel
Demonstration 2: Contour Plot of the Hyperbolic Quadradic Form
The Fractional Fourier Transform
kernel comprises an exponential function with argument that is hyperbolic with respect to x and y :
This can be shown to be a hyperbola whose asymptotes counter-rotate with the power a as it increases through the internal [0, 4) and repeating periodically. This demonstration shows an animation of the contour plot of hyperbolic quadratic form as the power a cycles though its periodic range.
The colors depict relative values of the kernel exponential's quadratic-form argument in each frame as a function of x and y. A color wheel relative color scheme is used to indicate the relative values within each frame of the animation:
Note that at even-integer values of a , the hyperbola itself degenerates into a line:
(that is, where a even-integer multiples of 2) and
(that is, where odd-integer multiples of 2).
At either of these even-integer values of , the fractional Fourier transform kernel becomes one of two types of delta function (in the sense of distributions within Schwartz Space extension of )
 |
(Identity operator) |
α = 4k |
 |
(Reflection operator) |
α = 4k+2. |
Note that the counter-rotating asymptotes converge at angles 45-degrees from the x and y axes. This reflects the fact that the natural cannonical variables for the fractional Fourier transform are
as discussed in Chapter 1, and a fact that is also reflected by the arguments of the delta functions described above.
As discussed in Chapter 5, their are a number of special values worth noting (with caveats of variable changes and limit processes). These are tabulated in Table 1, below
|
Example Value of |
General Value of |
Effect of the operator |
Structure of the Kernal |
Graphical Behavior |
|---|---|---|---|---|
|
0 |
4k |
Identity Operator |
Delta function |
 |
|
1/2 |
4k + 1/2 |
Similar to Bargmann Transform |
Symmetric in x and y |
 |
|
1 |
4k+1 |
Fourier Transform |
Quadratic terms vanish, cross-product term is negative |
 |
|
2 |
4k+2 |
Reflection Operator |
Delta function |
 |
|
3 |
4k+3 |
Inverse Fourier |
Quadratic terms vanish, cross-product term is positive |
 |
|
7/2 |
4k+ 7/2 |
Similar to Inverse Bargmann Transform |
Symmetric in x and (-y) |
 |
REFERENCES
[1] ... roots and zeros of hyperbolic behavior