org.das2.math.fft.jnt.RealDoubleFFT
Abstract Class representing FFT's of real, double precision data.
Concrete classes are typically named RealDoubleFFT_method, implement the
FFT using some particular method.
The physical layout of the mathematical data d[i] in the array data is as follows:
d[i] = data[i0 + stride*i]
The FFT (D[i]) of real data (d[i]) is complex, but restricted by symmetry:
D[n-i] = conj(D[i])
It turns out that there are still n `independent' values, so the transformation
can still be carried out in-place.
However, each Real FFT method tends to leave the real and imaginary parts
distributed in the data array in its own unique arrangment.
You must consult the documentation for the specific classes implementing
RealDoubleFFT for the details.
Note, however, that each class's backtransform and inverse methods understand
thier own unique ordering of the transformed result and can invert it correctly.
RealDoubleFFT( int n )
Create an FFT for transforming n points of real, double precision data.
backtransform
backtransform( org.das2.math.fft.ComplexArray.Double data ) → void
Compute the (unnomalized) inverse FFT of data, leaving it in place.
Parameters
data - a ComplexArray.Double
Returns:
void (returns nothing)
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backtransform
backtransform( org.das2.math.fft.ComplexArray.Double data, int i0, int stride ) → void
Compute the (unnomalized) inverse FFT of data, leaving it in place.
Parameters
data - a ComplexArray.Double
i0 - an int
stride - an int
Returns:
void (returns nothing)
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inverse
inverse( org.das2.math.fft.ComplexArray.Double data ) → void
Compute the (nomalized) inverse FFT of data, leaving it in place.
Parameters
data - a ComplexArray.Double
Returns:
void (returns nothing)
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inverse
inverse( org.das2.math.fft.ComplexArray.Double data, int i0, int stride ) → void
Compute the (nomalized) inverse FFT of data, leaving it in place.
Parameters
data - a ComplexArray.Double
i0 - an int
stride - an int
Returns:
void (returns nothing)
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normalization
normalization( ) → double
Return the normalization factor.
Multiply the elements of the backtransform'ed data to get the normalized inverse.
Returns:
double
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transform
transform( org.das2.math.fft.ComplexArray.Double data ) → void
Compute the Fast Fourier Transform of data leaving the result in data.
Parameters
data - a ComplexArray.Double
Returns:
void (returns nothing)
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transform
transform( org.das2.math.fft.ComplexArray.Double data, int i0, int stride ) → void
Compute the Fast Fourier Transform of data leaving the result in data.
Parameters
data - a ComplexArray.Double
i0 - an int
stride - an int
Returns:
void (returns nothing)
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