int main( int argc, char * argv [] )
{
if( argc < 3 )
{
std::cerr << "Missing command line arguments" << std::endl;
std::cerr << "Usage : ImageMutualInformation1 inputImage1 inputImage2 " << std::endl;
return EXIT_FAILURE;
}
typedef unsigned char PixelComponentType;
ReaderType::Pointer reader1 = ReaderType::New();
ReaderType::Pointer reader2 = ReaderType::New();
reader1->SetFileName( argv[1] );
reader2->SetFileName( argv[2] );
JoinFilterType::Pointer joinFilter = JoinFilterType::New();
joinFilter->SetInput1( reader1->GetOutput() );
joinFilter->SetInput2( reader2->GetOutput() );
try
{
joinFilter->Update();
}
{
std::cerr << excp << std::endl;
return EXIT_FAILURE;
}
typedef JoinFilterType::OutputImageType VectorImageType;
VectorImageType > HistogramFilterType;
HistogramFilterType::Pointer histogramFilter = HistogramFilterType::New();
histogramFilter->SetInput( joinFilter->GetOutput() );
histogramFilter->SetMarginalScale( 10.0 );
typedef HistogramFilterType::HistogramSizeType HistogramSizeType;
HistogramSizeType size( 2 );
size[0] = 255;
size[1] = 255;
histogramFilter->SetHistogramSize( size );
typedef HistogramFilterType::HistogramMeasurementVectorType
HistogramMeasurementVectorType;
HistogramMeasurementVectorType binMinimum( 3 );
HistogramMeasurementVectorType binMaximum( 3 );
binMinimum[0] = -0.5;
binMinimum[1] = -0.5;
binMinimum[2] = -0.5;
binMaximum[0] = 255.5;
binMaximum[1] = 255.5;
binMaximum[2] = 255.5;
histogramFilter->SetHistogramBinMinimum( binMinimum );
histogramFilter->SetHistogramBinMaximum( binMaximum );
histogramFilter->Update();
typedef HistogramFilterType::HistogramType HistogramType;
const HistogramType * histogram = histogramFilter->GetOutput();
HistogramType::ConstIterator itr = histogram->Begin();
HistogramType::ConstIterator end = histogram->End();
const double Sum = histogram->GetTotalFrequency();
double JointEntropy = 0.0;
while( itr != end )
{
const double count = itr.GetFrequency();
if( count > 0.0 )
{
const double probability = count / Sum;
JointEntropy +=
- probability * std::log( probability ) / std::log( 2.0 );
}
++itr;
}
std::cout << "Joint Entropy = " << JointEntropy << " bits " << std::endl;
size[0] = 255;
size[1] = 1;
histogramFilter->SetHistogramSize( size );
histogramFilter->Update();
itr = histogram->Begin();
end = histogram->End();
double Entropy1 = 0.0;
while( itr != end )
{
const double count = itr.GetFrequency();
if( count > 0.0 )
{
const double probability = count / Sum;
Entropy1 += - probability * std::log( probability ) / std::log( 2.0 );
}
++itr;
}
std::cout << "Image1 Entropy = " << Entropy1 << " bits " << std::endl;
size[0] = 1;
size[1] = 255;
histogramFilter->SetHistogramSize( size );
histogramFilter->Update();
itr = histogram->Begin();
end = histogram->End();
double Entropy2 = 0.0;
while( itr != end )
{
const double count = itr.GetFrequency();
if( count > 0.0 )
{
const double probability = count / Sum;
Entropy2 += - probability * std::log( probability ) / std::log( 2.0 );
}
++itr;
}
std::cout << "Image2 Entropy = " << Entropy2 << " bits " << std::endl;
double MutualInformation = Entropy1 + Entropy2 - JointEntropy;
std::cout << "Mutual Information = " << MutualInformation << " bits " << std::endl;
double NormalizedMutualInformation1 =
2.0 * MutualInformation / ( Entropy1 + Entropy2 );
std::cout << "Normalized Mutual Information 1 = " << NormalizedMutualInformation1 << std::endl;
double NormalizedMutualInformation2 = ( Entropy1 + Entropy2 ) / JointEntropy;
std::cout << "Normalized Mutual Information 2 = " << NormalizedMutualInformation2 << std::endl;
return EXIT_SUCCESS;
}