edu.emory.mathcs.jtransforms.fft

Class FloatFFT_2D

java.lang.Object

edu.emory.mathcs.jtransforms.fft.FloatFFT_2D

public class FloatFFT_2D
extends Object

Computes 2D Discrete Fourier Transform (DFT) of complex and real, single precision data. The sizes of both dimensions can be arbitrary numbers. This is a parallel implementation of split-radix and mixed-radix algorithms optimized for SMP systems.

Part of the code is derived from General Purpose FFT Package written by Takuya Ooura (http://www.kurims.kyoto-u.ac.jp/~ooura/fft.html)

Author:

Piotr Wendykier (piotr.wendykier@gmail.com)

Constructor Summary

Constructors

Constructor and Description
FloatFFT_2D(int rows, int columns) Creates new instance of FloatFFT_2D.

Method Summary

Modifier and Type	Method and Description
void	complexForward(float[] a) Computes 2D forward DFT of complex data leaving the result in a.
void	complexForward(float[][] a) Computes 2D forward DFT of complex data leaving the result in a.
void	complexInverse(float[][] a, boolean scale) Computes 2D inverse DFT of complex data leaving the result in a.
void	complexInverse(float[] a, boolean scale) Computes 2D inverse DFT of complex data leaving the result in a.
void	realForward(float[] a) Computes 2D forward DFT of real data leaving the result in a .
void	realForward(float[][] a) Computes 2D forward DFT of real data leaving the result in a .
void	realForwardFull(float[] a) Computes 2D forward DFT of real data leaving the result in a .
void	realForwardFull(float[][] a) Computes 2D forward DFT of real data leaving the result in a .
void	realInverse(float[][] a, boolean scale) Computes 2D inverse DFT of real data leaving the result in a .
void	realInverse(float[] a, boolean scale) Computes 2D inverse DFT of real data leaving the result in a .
void	realInverseFull(float[][] a, boolean scale) Computes 2D inverse DFT of real data leaving the result in a .
void	realInverseFull(float[] a, boolean scale) Computes 2D inverse DFT of real data leaving the result in a .

Methods inherited from class java.lang.Object

clone, equals, finalize, getClass, hashCode, notify, notifyAll, toString, wait, wait, wait

Constructor Detail

FloatFFT_2D

public FloatFFT_2D(int rows,
                   int columns)

Creates new instance of FloatFFT_2D.

Parameters:

rows - number of rows

columns - number of columns

Method Detail

complexForward

public void complexForward(float[] a)

Computes 2D forward DFT of complex data leaving the result in a. The data is stored in 1D array in row-major order. Complex number is stored as two float values in sequence: the real and imaginary part, i.e. the input array must be of size rows*2*columns. The physical layout of the input data has to be as follows:

 a[k1*2*columns+2*k2] = Re[k1][k2], 
 a[k1*2*columns+2*k2+1] = Im[k1][k2], 0<=k1<rows, 0<=k2<columns,
 

Parameters:

a - data to transform

complexForward

public void complexForward(float[][] a)

Computes 2D forward DFT of complex data leaving the result in a. The data is stored in 2D array. Complex data is represented by 2 float values in sequence: the real and imaginary part, i.e. the input array must be of size rows by 2*columns. The physical layout of the input data has to be as follows:

 a[k1][2*k2] = Re[k1][k2], 
 a[k1][2*k2+1] = Im[k1][k2], 0<=k1<rows, 0<=k2<columns,
 

Parameters:

a - data to transform

complexInverse

public void complexInverse(float[] a,
                           boolean scale)

Computes 2D inverse DFT of complex data leaving the result in a. The data is stored in 1D array in row-major order. Complex number is stored as two float values in sequence: the real and imaginary part, i.e. the input array must be of size rows*2*columns. The physical layout of the input data has to be as follows:

 a[k1*2*columns+2*k2] = Re[k1][k2], 
 a[k1*2*columns+2*k2+1] = Im[k1][k2], 0<=k1<rows, 0<=k2<columns,
 

Parameters:

a - data to transform

scale - if true then scaling is performed

complexInverse

public void complexInverse(float[][] a,
                           boolean scale)

Computes 2D inverse DFT of complex data leaving the result in a. The data is stored in 2D array. Complex data is represented by 2 float values in sequence: the real and imaginary part, i.e. the input array must be of size rows by 2*columns. The physical layout of the input data has to be as follows:

 a[k1][2*k2] = Re[k1][k2], 
 a[k1][2*k2+1] = Im[k1][k2], 0<=k1<rows, 0<=k2<columns,
 

Parameters:

a - data to transform

scale - if true then scaling is performed

realForward

public void realForward(float[] a)

Computes 2D forward DFT of real data leaving the result in a . This method only works when the sizes of both dimensions are power-of-two numbers. The physical layout of the output data is as follows:

 a[k1*columns+2*k2] = Re[k1][k2] = Re[rows-k1][columns-k2], 
 a[k1*columns+2*k2+1] = Im[k1][k2] = -Im[rows-k1][columns-k2], 
       0<k1<rows, 0<k2<columns/2, 
 a[2*k2] = Re[0][k2] = Re[0][columns-k2], 
 a[2*k2+1] = Im[0][k2] = -Im[0][columns-k2], 
       0<k2<columns/2, 
 a[k1*columns] = Re[k1][0] = Re[rows-k1][0], 
 a[k1*columns+1] = Im[k1][0] = -Im[rows-k1][0], 
 a[(rows-k1)*columns+1] = Re[k1][columns/2] = Re[rows-k1][columns/2], 
 a[(rows-k1)*columns] = -Im[k1][columns/2] = Im[rows-k1][columns/2], 
       0<k1<rows/2, 
 a[0] = Re[0][0], 
 a[1] = Re[0][columns/2], 
 a[(rows/2)*columns] = Re[rows/2][0], 
 a[(rows/2)*columns+1] = Re[rows/2][columns/2]
 

This method computes only half of the elements of the real transform. The other half satisfies the symmetry condition. If you want the full real forward transform, use realForwardFull. To get back the original data, use realInverse on the output of this method.

Parameters:

a - data to transform

realForward

public void realForward(float[][] a)

Computes 2D forward DFT of real data leaving the result in a . This method only works when the sizes of both dimensions are power-of-two numbers. The physical layout of the output data is as follows:

 a[k1][2*k2] = Re[k1][k2] = Re[rows-k1][columns-k2], 
 a[k1][2*k2+1] = Im[k1][k2] = -Im[rows-k1][columns-k2], 
       0<k1<rows, 0<k2<columns/2, 
 a[0][2*k2] = Re[0][k2] = Re[0][columns-k2], 
 a[0][2*k2+1] = Im[0][k2] = -Im[0][columns-k2], 
       0<k2<columns/2, 
 a[k1][0] = Re[k1][0] = Re[rows-k1][0], 
 a[k1][1] = Im[k1][0] = -Im[rows-k1][0], 
 a[rows-k1][1] = Re[k1][columns/2] = Re[rows-k1][columns/2], 
 a[rows-k1][0] = -Im[k1][columns/2] = Im[rows-k1][columns/2], 
       0<k1<rows/2, 
 a[0][0] = Re[0][0], 
 a[0][1] = Re[0][columns/2], 
 a[rows/2][0] = Re[rows/2][0], 
 a[rows/2][1] = Re[rows/2][columns/2]
 

This method computes only half of the elements of the real transform. The other half satisfies the symmetry condition. If you want the full real forward transform, use realForwardFull. To get back the original data, use realInverse on the output of this method.

Parameters:

a - data to transform

realForwardFull

public void realForwardFull(float[] a)

Computes 2D forward DFT of real data leaving the result in a . This method computes full real forward transform, i.e. you will get the same result as from complexForward called with all imaginary part equal 0. Because the result is stored in a, the input array must be of size rows*2*columns, with only the first rows*columns elements filled with real data. To get back the original data, use complexInverse on the output of this method.

Parameters:

a - data to transform

realForwardFull

public void realForwardFull(float[][] a)

Computes 2D forward DFT of real data leaving the result in a . This method computes full real forward transform, i.e. you will get the same result as from complexForward called with all imaginary part equal 0. Because the result is stored in a, the input array must be of size rows by 2*columns, with only the first rows by columns elements filled with real data. To get back the original data, use complexInverse on the output of this method.

Parameters:

a - data to transform

realInverse

public void realInverse(float[] a,
                        boolean scale)

Computes 2D inverse DFT of real data leaving the result in a . This method only works when the sizes of both dimensions are power-of-two numbers. The physical layout of the input data has to be as follows:

 a[k1*columns+2*k2] = Re[k1][k2] = Re[rows-k1][columns-k2], 
 a[k1*columns+2*k2+1] = Im[k1][k2] = -Im[rows-k1][columns-k2], 
       0<k1<rows, 0<k2<columns/2, 
 a[2*k2] = Re[0][k2] = Re[0][columns-k2], 
 a[2*k2+1] = Im[0][k2] = -Im[0][columns-k2], 
       0<k2<columns/2, 
 a[k1*columns] = Re[k1][0] = Re[rows-k1][0], 
 a[k1*columns+1] = Im[k1][0] = -Im[rows-k1][0], 
 a[(rows-k1)*columns+1] = Re[k1][columns/2] = Re[rows-k1][columns/2], 
 a[(rows-k1)*columns] = -Im[k1][columns/2] = Im[rows-k1][columns/2], 
       0<k1<rows/2, 
 a[0] = Re[0][0], 
 a[1] = Re[0][columns/2], 
 a[(rows/2)*columns] = Re[rows/2][0], 
 a[(rows/2)*columns+1] = Re[rows/2][columns/2]
 

This method computes only half of the elements of the real transform. The other half satisfies the symmetry condition. If you want the full real inverse transform, use realInverseFull.

Parameters:

a - data to transform

scale - if true then scaling is performed

realInverse

public void realInverse(float[][] a,
                        boolean scale)

Computes 2D inverse DFT of real data leaving the result in a . This method only works when the sizes of both dimensions are power-of-two numbers. The physical layout of the input data has to be as follows:

 a[k1][2*k2] = Re[k1][k2] = Re[rows-k1][columns-k2], 
 a[k1][2*k2+1] = Im[k1][k2] = -Im[rows-k1][columns-k2], 
       0<k1<rows, 0<k2<columns/2, 
 a[0][2*k2] = Re[0][k2] = Re[0][columns-k2], 
 a[0][2*k2+1] = Im[0][k2] = -Im[0][columns-k2], 
       0<k2<columns/2, 
 a[k1][0] = Re[k1][0] = Re[rows-k1][0], 
 a[k1][1] = Im[k1][0] = -Im[rows-k1][0], 
 a[rows-k1][1] = Re[k1][columns/2] = Re[rows-k1][columns/2], 
 a[rows-k1][0] = -Im[k1][columns/2] = Im[rows-k1][columns/2], 
       0<k1<rows/2, 
 a[0][0] = Re[0][0], 
 a[0][1] = Re[0][columns/2], 
 a[rows/2][0] = Re[rows/2][0], 
 a[rows/2][1] = Re[rows/2][columns/2]
 

This method computes only half of the elements of the real transform. The other half satisfies the symmetry condition. If you want the full real inverse transform, use realInverseFull.

Parameters:

a - data to transform

scale - if true then scaling is performed

realInverseFull

public void realInverseFull(float[] a,
                            boolean scale)

Computes 2D inverse DFT of real data leaving the result in a . This method computes full real inverse transform, i.e. you will get the same result as from complexInverse called with all imaginary part equal 0. Because the result is stored in a, the input array must be of size rows*2*columns, with only the first rows*columns elements filled with real data.

Parameters:

a - data to transform

scale - if true then scaling is performed

realInverseFull

public void realInverseFull(float[][] a,
                            boolean scale)

Computes 2D inverse DFT of real data leaving the result in a . This method computes full real inverse transform, i.e. you will get the same result as from complexInverse called with all imaginary part equal 0. Because the result is stored in a, the input array must be of size rows by 2*columns, with only the first rows by columns elements filled with real data.

Parameters:

a - data to transform

scale - if true then scaling is performed