ITK  4.9.0
Insight Segmentation and Registration Toolkit
Examples/Filtering/FFTImageFilter.cxx
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*
* Copyright Insight Software Consortium
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0.txt
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*
*=========================================================================*/
// Software Guide : BeginLatex
//
// In this section we assume that you are familiar with Spectral Analysis, in
// particular with the concepts of the Fourier Transform and the numerical
// implementation of the Fast Fourier transform. If you are not familiar with
// these concepts you may want to consult first any of the many available
// introductory books to spectral analysis~\cite{Bracewell1999,Bracewell2004}.
//
// This example illustrates how to use the Fast Fourier Transform filter (FFT)
// for processing an image in the spectral domain. Given that FFT computation
// can be CPU intensive, there are multiple hardware specific implementations
// of FFT. It is convenient in many cases to delegate the actual computation
// of the transform to local available libraries. Particular examples of those
// libraries are fftw\footnote{http://www.fftw.org} and the VXL implementation
// of FFT. For this reason ITK provides a base abstract class that factorizes
// the interface to multiple specific implementations of FFT. This base class
// is the \doxygen{ForwardFFTImageFilter}, and two of its
// derived classes are \doxygen{VnlForwardFFTImageFilter} and
// \doxygen{FFTWRealToComplexConjugateImageFilter}.
//
//
// \index{itk::Forward\-FFT\-Image\-Filter}
// \index{itk::Vnl\-Forward\-FFT\-Image\-Filter}
// \index{itk::FFTW\-Forward\-FFT\-Image\-Filter}
//
// Software Guide : EndLatex
// Software Guide : BeginLatex
//
// A typical application that uses FFT will need to include the following
// header files.
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
#include "itkImage.h"
// Software Guide : EndCodeSnippet
int main( int argc, char * argv [] )
{
if( argc < 5 )
{
std::cerr << "Usage: " << argv[0] << " inputScalarImage outputRealPartOfComplexImage outputRealImaginaryPartOfComplexImage outputComplex" << std::endl;
}
// Software Guide : BeginLatex
//
// The first decision to make is related to the pixel type and dimension of the
// images on which we want to compute the Fourier transform.
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
typedef float PixelType;
const unsigned int Dimension = 2;
// Software Guide : EndCodeSnippet
// Software Guide : BeginLatex
//
// We use the same image type in order to instantiate the FFT filter, in this
// case the \doxygen{VnlForwardFFTImageFilter}. Once the filter type is
// instantiated, we can use it for creating one object by invoking the
// \code{New()} method and assigning the result to a SmartPointer.
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
FFTFilterType::Pointer fftFilter = FFTFilterType::New();
// Software Guide : EndCodeSnippet
// Software Guide : BeginLatex
//
// The input to this filter can be taken from a reader, for example.
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
ReaderType::Pointer reader = ReaderType::New();
reader->SetFileName( argv[1] );
fftFilter->SetInput( reader->GetOutput() );
// Software Guide : EndCodeSnippet
// Software Guide : BeginLatex
//
// The execution of the filter can be triggered by invoking the \code{Update()}
// method. Since this invocation can eventually throw an exception, the call
// must be placed inside a try/catch block.
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
try
{
fftFilter->Update();
}
catch( itk::ExceptionObject & excp )
{
std::cerr << "Error: " << std::endl;
std::cerr << excp << std::endl;
return EXIT_FAILURE;
}
// Software Guide : EndCodeSnippet
// Software Guide : BeginLatex
//
// In general the output of the FFT filter will be a complex image. We can
// proceed to save this image in a file for further analysis. This can be done
// by simply instantiating an \doxygen{ImageFileWriter} using the trait of the
// output image from the FFT filter. We construct one instance of the writer
// and pass the output of the FFT filter as the input of the writer.
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
typedef FFTFilterType::OutputImageType ComplexImageType;
typedef itk::ImageFileWriter< ComplexImageType > ComplexWriterType;
ComplexWriterType::Pointer complexWriter = ComplexWriterType::New();
complexWriter->SetFileName( argv[4] );
complexWriter->SetInput( fftFilter->GetOutput() );
// Software Guide : EndCodeSnippet
// Software Guide : BeginLatex
//
// Finally we invoke the \code{Update()} method placed inside a try/catch
// block.
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
try
{
complexWriter->Update();
}
catch( itk::ExceptionObject & excp )
{
std::cerr << "Error: " << std::endl;
std::cerr << excp << std::endl;
return EXIT_FAILURE;
}
// Software Guide : EndCodeSnippet
// Software Guide : BeginLatex
//
// In addition to saving the complex image into a file, we could also extract
// its real and imaginary parts for further analysis. This can be done with the
// \doxygen{ComplexToRealImageFilter} and the
// \doxygen{ComplexToImaginaryImageFilter}.
//
// We instantiate first the ImageFilter that will help us to extract the real
// part from the complex image. The \code{ComplexToRealImageFilter} takes as
// its first template parameter the type of the complex image and as its second
// template parameter it takes the type of the output image pixel. We create
// one instance of this filter and connect as its input the output of the FFT
// filter.
//
// \index{itk::ComplexToRealImageFilter}
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
ComplexImageType, ImageType > RealFilterType;
RealFilterType::Pointer realFilter = RealFilterType::New();
realFilter->SetInput( fftFilter->GetOutput() );
// Software Guide : EndCodeSnippet
typedef unsigned char WritePixelType;
// Software Guide : BeginLatex
//
// Since the range of intensities in the Fourier domain can be quite
// concentrated, it is convenient to rescale the image in order to
// visualize it. For this purpose we instantiate a
// \doxygen{RescaleIntensityImageFilter} that will rescale the intensities of
// the \code{real} image into a range suitable for writing in a file. We also
// set the minimum and maximum values of the output to the range of the pixel
// type used for writing.
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
ImageType,
WriteImageType > RescaleFilterType;
RescaleFilterType::Pointer intensityRescaler = RescaleFilterType::New();
intensityRescaler->SetInput( realFilter->GetOutput() );
intensityRescaler->SetOutputMinimum( 0 );
intensityRescaler->SetOutputMaximum( 255 );
// Software Guide : EndCodeSnippet
WriterType::Pointer writer = WriterType::New();
writer->SetFileName( argv[2] );
writer->SetInput( intensityRescaler->GetOutput() );
try
{
writer->Update();
}
catch( itk::ExceptionObject & excp )
{
std::cerr << "Error writing the real image: " << std::endl;
std::cerr << excp << std::endl;
return EXIT_FAILURE;
}
// Software Guide : BeginLatex
//
// We can now instantiate the ImageFilter that will help us to extract the
// imaginary part from the complex image. The filter that we use here is the
// \doxygen{ComplexToImaginaryImageFilter}. It takes as first template
// parameter the type of the complex image and as second template parameter it
// takes the type of the output image pixel. An instance of the filter is
// created, and its input is connected to the output of the FFT filter.
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
typedef FFTFilterType::OutputImageType ComplexImageType;
ComplexImageType, ImageType > ImaginaryFilterType;
ImaginaryFilterType::Pointer imaginaryFilter = ImaginaryFilterType::New();
imaginaryFilter->SetInput( fftFilter->GetOutput() );
// Software Guide : EndCodeSnippet
// Software Guide : BeginLatex
//
// The Imaginary image can then be rescaled and saved into a file, just as we
// did with the Real part.
//
// Software Guide : EndLatex
intensityRescaler->SetInput( imaginaryFilter->GetOutput() );
writer->SetFileName( argv[3] );
try
{
writer->Update();
}
catch( itk::ExceptionObject & excp )
{
std::cerr << "Error writing the imaginary image: " << std::endl;
std::cerr << excp << std::endl;
return EXIT_FAILURE;
}
// Software Guide : BeginLatex
//
// For the sake of illustrating the use of a \doxygen{ImageFileReader} on
// Complex images, here we instantiate a reader that will load the Complex
// image that we just saved. Note that nothing special is required in this
// case. The instantiation is done just the same as for any other type of
// image, which once again illustrates the power of Generic Programming.
//
// Software Guide : EndLatex
// Software Guide : BeginCodeSnippet
typedef itk::ImageFileReader< ComplexImageType > ComplexReaderType;
ComplexReaderType::Pointer complexReader = ComplexReaderType::New();
complexReader->SetFileName( argv[4] );
complexReader->Update();
// Software Guide : EndCodeSnippet
// A way of testing the pixel type of an image in file is to
// invoke the ImageIO object from the reader and then call
// \code{GetPixelTypeAsString()}
complexReader->GetImageIO()->GetPixelTypeAsString(
complexReader->GetImageIO()->GetPixelType() );
return EXIT_SUCCESS;
}