ComplexCenteredFftInverse
Computes the centered Fast Fourier inverse Transform of an image.
Access to parameter description
For an introduction: see section Frequency Domain.
The ComplexCenteredFftInverse algorithm is used to reconstruct an image after a centered FFT transform.
See also
Access to parameter description
For an introduction: see section Frequency Domain.
The ComplexCenteredFftInverse algorithm is used to reconstruct an image after a centered FFT transform.
See also
Function Syntax
This function returns a ComplexCenteredFftInverseOutput structure containing the outputRealImage and outputImaginaryImage output parameters.
// Output structure. struct ComplexCenteredFftInverseOutput { std::shared_ptr< iolink::ImageView > outputRealImage; std::shared_ptr< iolink::ImageView > outputImaginaryImage; }; // Function prototype. ComplexCenteredFftInverseOutput complexCenteredFftInverse( std::shared_ptr< iolink::ImageView > inputRealImage, std::shared_ptr< iolink::ImageView > inputImaginaryImage, std::shared_ptr< iolink::ImageView > outputRealImage = NULL, std::shared_ptr< iolink::ImageView > outputImaginaryImage = NULL );
This function returns a tuple containing the output_real_image and output_imaginary_image output parameters.
// Function prototype. complex_centered_fft_inverse( input_real_image, input_imaginary_image, output_real_image = None, output_imaginary_image = None )
This function returns a ComplexCenteredFftInverseOutput structure containing the outputRealImage and outputImaginaryImage output parameters.
/// Output structure of the ComplexCenteredFftInverse function. public struct ComplexCenteredFftInverseOutput { public IOLink.ImageView outputRealImage; public IOLink.ImageView outputImaginaryImage; }; // Function prototype. public static ComplexCenteredFftInverseOutput ComplexCenteredFftInverse( IOLink.ImageView inputRealImage, IOLink.ImageView inputImaginaryImage, IOLink.ImageView outputRealImage = null, IOLink.ImageView outputImaginaryImage = null );
Class Syntax
Parameters
Class Name | ComplexCenteredFftInverse |
---|
Parameter Name | Description | Type | Supported Values | Default Value | |
---|---|---|---|---|---|
inputRealImage |
The real input part image. It must be a floating point image. | Image | Grayscale or Multispectral | nullptr | |
inputImaginaryImage |
The imaginary part input image. This image must have same dimensions and data type as the real input image. | Image | Grayscale or Multispectral | nullptr | |
outputRealImage |
The output real part image. Its dimensions are forced to the same values as the input. Its data type is forced to floating point. | Image | nullptr | ||
outputImaginaryImage |
The output imaginary part image. Its dimensions are forced to the same values as the input. Its data type is forced to floating point. | Image | nullptr |
Object Examples
auto polystyrene_float = readVipImage( std::string( IMAGEDEVDATA_IMAGES_FOLDER ) + "polystyrene_float.vip" ); ComplexCenteredFftInverse complexCenteredFftInverseAlgo; complexCenteredFftInverseAlgo.setInputRealImage( polystyrene_float ); complexCenteredFftInverseAlgo.setInputImaginaryImage( polystyrene_float ); complexCenteredFftInverseAlgo.execute(); std::cout << "outputRealImage:" << complexCenteredFftInverseAlgo.outputRealImage()->toString(); std::cout << "outputImaginaryImage:" << complexCenteredFftInverseAlgo.outputImaginaryImage()->toString();
polystyrene_float = imagedev.read_vip_image(imagedev_data.get_image_path("polystyrene_float.vip")) complex_centered_fft_inverse_algo = imagedev.ComplexCenteredFftInverse() complex_centered_fft_inverse_algo.input_real_image = polystyrene_float complex_centered_fft_inverse_algo.input_imaginary_image = polystyrene_float complex_centered_fft_inverse_algo.execute() print( "output_real_image:", str( complex_centered_fft_inverse_algo.output_real_image ) ) print( "output_imaginary_image:", str( complex_centered_fft_inverse_algo.output_imaginary_image ) )
ImageView polystyrene_float = Data.ReadVipImage( @"Data/images/polystyrene_float.vip" ); ComplexCenteredFftInverse complexCenteredFftInverseAlgo = new ComplexCenteredFftInverse { inputRealImage = polystyrene_float, inputImaginaryImage = polystyrene_float }; complexCenteredFftInverseAlgo.Execute(); Console.WriteLine( "outputRealImage:" + complexCenteredFftInverseAlgo.outputRealImage.ToString() ); Console.WriteLine( "outputImaginaryImage:" + complexCenteredFftInverseAlgo.outputImaginaryImage.ToString() );
Function Examples
auto polystyrene_float = readVipImage( std::string( IMAGEDEVDATA_IMAGES_FOLDER ) + "polystyrene_float.vip" ); auto result = complexCenteredFftInverse( polystyrene_float, polystyrene_float ); std::cout << "outputRealImage:" << result.outputRealImage->toString(); std::cout << "outputImaginaryImage:" << result.outputImaginaryImage->toString();
polystyrene_float = imagedev.read_vip_image(imagedev_data.get_image_path("polystyrene_float.vip")) result_output_real_image, result_output_imaginary_image = imagedev.complex_centered_fft_inverse( polystyrene_float, polystyrene_float ) print( "output_real_image:", str( result_output_real_image ) ) print( "output_imaginary_image:", str( result_output_imaginary_image ) )
ImageView polystyrene_float = Data.ReadVipImage( @"Data/images/polystyrene_float.vip" ); Processing.ComplexCenteredFftInverseOutput result = Processing.ComplexCenteredFftInverse( polystyrene_float, polystyrene_float ); Console.WriteLine( "outputRealImage:" + result.outputRealImage.ToString() ); Console.WriteLine( "outputImaginaryImage:" + result.outputImaginaryImage.ToString() );