Example #1
0
	MatrixXf featureGradient( const MatrixXf & a, const MatrixXf & b ) const {
		if (ntype_ == NO_NORMALIZATION )
			return kernelGradient( a, b );
		else if (ntype_ == NORMALIZE_SYMMETRIC ) {
			MatrixXf fa = lattice_.compute( a*norm_.asDiagonal(), true );
			MatrixXf fb = lattice_.compute( b*norm_.asDiagonal() );
			MatrixXf ones = MatrixXf::Ones( a.rows(), a.cols() );
			VectorXf norm3 = norm_.array()*norm_.array()*norm_.array();
			MatrixXf r = kernelGradient( 0.5*( a.array()*fb.array() + fa.array()*b.array() ).matrix()*norm3.asDiagonal(), ones );
			return - r + kernelGradient( a*norm_.asDiagonal(), b*norm_.asDiagonal() );
		}
		else if (ntype_ == NORMALIZE_AFTER ) {
			MatrixXf fb = lattice_.compute( b );
			
			MatrixXf ones = MatrixXf::Ones( a.rows(), a.cols() );
			VectorXf norm2 = norm_.array()*norm_.array();
			MatrixXf r = kernelGradient( ( a.array()*fb.array() ).matrix()*norm2.asDiagonal(), ones );
			return - r + kernelGradient( a*norm_.asDiagonal(), b );
		}
		else /*if (ntype_ == NORMALIZE_BEFORE )*/ {
			MatrixXf fa = lattice_.compute( a, true );
			
			MatrixXf ones = MatrixXf::Ones( a.rows(), a.cols() );
			VectorXf norm2 = norm_.array()*norm_.array();
			MatrixXf r = kernelGradient( ( fa.array()*b.array() ).matrix()*norm2.asDiagonal(), ones );
			return -r+kernelGradient( a, b*norm_.asDiagonal() );
		}
	}
Example #2
0
	BPPottsPotential(const float* features1, const float* features2, int D, int N1, int N2, float w, bool per_pixel_normalization=true) :N1_(N1), N2_(N2), w_(w) {
		float * features = new float[ (N1_+N2_)*D ];
		memset( features, 0, (N1_+N2_)*D*sizeof(float) );
		memcpy( features      , features1, N1_*D*sizeof(float) );
		memcpy( features+N1_*D, features2, N2_*D*sizeof(float) );
		lattice_.init( features, D, N1_+N2_ );
		delete [] features;
		
		norm_ = allocate( N2_ );
		float * tmp = allocate( N1_ );
		for( int i=0; i<N1_; i++ )
			tmp[i] = 1;
		// Compute the normalization factor
		lattice_.compute( norm_, tmp, 1, 0, N1_, N1_, N2_ );
		if( per_pixel_normalization ){
			// use a per pixel normalization
			for( int i=0; i<N2_; i++ )
				norm_[i] = 1.f / (norm_[i]+1e-20f);
		}
		else{
			float mean_norm = 0;
			for( int i=0; i<N2_; i++ )
				mean_norm += norm_[i];
			mean_norm = N2_ / mean_norm;
			// use a per pixel normalization
			for( int i=0; i<N2_; i++ )
				norm_[i] = mean_norm;
		}
		deallocate( tmp );
	}
Example #3
0
	void filter( MatrixXf & out, const MatrixXf & in, bool transpose ) const {
		// Read in the values
		if( ntype_ == NORMALIZE_SYMMETRIC || (ntype_ == NORMALIZE_BEFORE && !transpose) || (ntype_ == NORMALIZE_AFTER && transpose))
			out = in*norm_.asDiagonal();
		else
			out = in;
	
		// Filter
		if( transpose )
			lattice_.compute( out, out, true );
		else
			lattice_.compute( out, out );
// 			lattice_.compute( out.data(), out.data(), out.rows() );
	
		// Normalize again
		if( ntype_ == NORMALIZE_SYMMETRIC || (ntype_ == NORMALIZE_BEFORE && transpose) || (ntype_ == NORMALIZE_AFTER && !transpose))
			out = out*norm_.asDiagonal();
	}
Example #4
0
	PottsPotential(const float* features, int D, int N, float w, bool per_pixel_normalization=true) :N_(N), w_(w) {
		lattice_.init( features, D, N );
		norm_ = allocate( N );
		for ( int i=0; i<N; i++ )
			norm_[i] = 1;
		// Compute the normalization factor
		lattice_.compute( norm_, norm_, 1 );
		if ( per_pixel_normalization ) {
			// use a per pixel normalization
			for ( int i=0; i<N; i++ )
				norm_[i] = 1.f / (norm_[i]+1e-20f);
		}
		else {
			float mean_norm = 0;
			for ( int i=0; i<N; i++ )
				mean_norm += norm_[i];
			mean_norm = N / mean_norm;
			// use a per pixel normalization
			for ( int i=0; i<N; i++ )
				norm_[i] = mean_norm;
		}
	}
Example #5
0
	void initLattice( const MatrixXf & f ) {
		const int N = f.cols();
		lattice_.init( f );
		
		norm_ = lattice_.compute( VectorXf::Ones( N ).transpose() ).transpose();
		
		if ( ntype_ == NO_NORMALIZATION ) {
			float mean_norm = 0;
			for ( int i=0; i<N; i++ )
				mean_norm += norm_[i];
			mean_norm = N / mean_norm;
			for ( int i=0; i<N; i++ )
				norm_[i] = mean_norm;
		}
		else if ( ntype_ == NORMALIZE_SYMMETRIC ) {
			for ( int i=0; i<N; i++ )
				norm_[i] = 1.0 / sqrt(norm_[i]+1e-20);
		}
		else {
			for ( int i=0; i<N; i++ )
				norm_[i] = 1.0 / (norm_[i]+1e-20);
		}
	}
	void apply(float* out_values, const float* in_values, float* tmp, int value_size) const {
		lattice_.compute( tmp, in_values, value_size );
		for ( int i=0,k=0; i<N_; i++ )
			for ( int j=0; j<value_size; j++, k++ )
				out_values[k] += w_*norm_[i]*tmp[k];
	}