void mitk::ConnectomicsSyntheticNetworkGenerator::GenerateSyntheticCenterToSurfaceNetwork( mitk::ConnectomicsNetwork::Pointer network, int numberOfPoints, double radius ) { //the random number generators unsigned int randomOne = (unsigned int) rand(); unsigned int randomTwo = (unsigned int) rand(); vnl_random rng( (unsigned int) rand() ); vnl_random rng2( (unsigned int) rand() ); mitk::ConnectomicsNetwork::VertexDescriptorType centerVertex; int vertexID(0); { //add center vertex std::vector< float > position; std::string label; std::stringstream labelStream; labelStream << vertexID; label = labelStream.str(); position.push_back( 0 ); position.push_back( 0 ); position.push_back( 0 ); centerVertex = network->AddVertex( vertexID ); network->SetLabel( centerVertex, label ); network->SetCoordinates( centerVertex, position ); }//end add center vertex // uniform weight of one int edgeWeight(1); mitk::ConnectomicsNetwork::VertexDescriptorType source; mitk::ConnectomicsNetwork::VertexDescriptorType target; //add vertices on sphere surface for( int loopID( 1 ); loopID < numberOfPoints; loopID++ ) { std::vector< float > position; std::string label; std::stringstream labelStream; labelStream << loopID; label = labelStream.str(); //generate random, uniformly distributed points on a sphere surface const double uVariable = rng.drand64( 0.0 , 1.0); const double vVariable = rng.drand64( 0.0 , 1.0); const double phi = 2 * vnl_math::pi * uVariable; const double theta = std::acos( 2 * vVariable - 1 ); double xpos = radius * std::cos( phi ) * std::sin( theta ); double ypos = radius * std::sin( phi ) * std::sin( theta ); double zpos = radius * std::cos( theta ); position.push_back( xpos ); position.push_back( ypos ); position.push_back( zpos ); mitk::ConnectomicsNetwork::VertexDescriptorType newVertex = network->AddVertex( loopID ); network->SetLabel( newVertex, label ); network->SetCoordinates( newVertex, position ); network->AddEdge( newVertex, centerVertex, loopID, 0, edgeWeight); } m_LastGenerationWasSuccess = true; }
void mitk::ConnectomicsSyntheticNetworkGenerator::GenerateSyntheticRandomNetwork( mitk::ConnectomicsNetwork::Pointer network, int numberOfPoints, double threshold ) { // as the surface is proportional to the square of the radius the density stays the same double radius = 5 * std::sqrt( (float) numberOfPoints ); //the random number generators unsigned int randomOne = (unsigned int) rand(); unsigned int randomTwo = (unsigned int) rand(); vnl_random rng( (unsigned int) rand() ); vnl_random rng2( (unsigned int) rand() ); // map for storing the conversion from indices to vertex descriptor std::map< int, mitk::ConnectomicsNetwork::VertexDescriptorType > idToVertexMap; //add vertices on sphere surface for( int loopID( 0 ); loopID < numberOfPoints; loopID++ ) { std::vector< float > position; std::string label; std::stringstream labelStream; labelStream << loopID; label = labelStream.str(); //generate random, uniformly distributed points on a sphere surface const double uVariable = rng.drand64( 0.0 , 1.0); const double vVariable = rng.drand64( 0.0 , 1.0); const double phi = 2 * vnl_math::pi * uVariable; const double theta = std::acos( 2 * vVariable - 1 ); double xpos = radius * std::cos( phi ) * std::sin( theta ); double ypos = radius * std::sin( phi ) * std::sin( theta ); double zpos = radius * std::cos( theta ); position.push_back( xpos ); position.push_back( ypos ); position.push_back( zpos ); mitk::ConnectomicsNetwork::VertexDescriptorType newVertex = network->AddVertex( loopID ); network->SetLabel( newVertex, label ); network->SetCoordinates( newVertex, position ); if ( idToVertexMap.count( loopID ) > 0 ) { MITK_ERROR << "Aborting network creation, duplicate vertex ID generated."; m_LastGenerationWasSuccess = false; return; } idToVertexMap.insert( std::pair< int, mitk::ConnectomicsNetwork::VertexDescriptorType >( loopID, newVertex) ); } int edgeID(0); // uniform weight of one int edgeWeight(1); mitk::ConnectomicsNetwork::VertexDescriptorType source; mitk::ConnectomicsNetwork::VertexDescriptorType target; for( int loopID( 0 ); loopID < numberOfPoints; loopID++ ) { // to avoid creating an edge twice (this being an undirected graph) we only // potentially generate edges with all nodes with a bigger ID for( int innerLoopID( loopID ); innerLoopID < numberOfPoints; innerLoopID++ ) { if( rng.drand64( 0.0 , 1.0) > threshold) { // do nothing } else { source = idToVertexMap.find( loopID )->second; target = idToVertexMap.find( innerLoopID )->second; network->AddEdge( source, target, loopID, innerLoopID, edgeWeight); edgeID++; } } // end for( int innerLoopID( loopID ); innerLoopID < numberOfPoints; innerLoopID++ ) } // end for( int loopID( 0 ); loopID < numberOfPoints; loopID++ ) m_LastGenerationWasSuccess = true; }
void mitk::ConnectomicsSyntheticNetworkGenerator::GenerateSyntheticCubeNetwork( mitk::ConnectomicsNetwork::Pointer network, int cubeExtent, double distance ) { // map for storing the conversion from indices to vertex descriptor std::map< int, mitk::ConnectomicsNetwork::VertexDescriptorType > idToVertexMap; int vertexID(0); for( int loopX( 0 ); loopX < cubeExtent; loopX++ ) { for( int loopY( 0 ); loopY < cubeExtent; loopY++ ) { for( int loopZ( 0 ); loopZ < cubeExtent; loopZ++ ) { std::vector< float > position; std::string label; std::stringstream labelStream; labelStream << vertexID; label = labelStream.str(); position.push_back( loopX * distance ); position.push_back( loopY * distance ); position.push_back( loopZ * distance ); mitk::ConnectomicsNetwork::VertexDescriptorType newVertex = network->AddVertex( vertexID ); network->SetLabel( newVertex, label ); network->SetCoordinates( newVertex, position ); if ( idToVertexMap.count( vertexID ) > 0 ) { MITK_ERROR << "Aborting network creation, duplicate vertex ID generated."; m_LastGenerationWasSuccess = false; return; } idToVertexMap.insert( std::pair< int, mitk::ConnectomicsNetwork::VertexDescriptorType >( vertexID, newVertex) ); vertexID++; } } } int edgeID(0), edgeSourceID(0), edgeTargetID(0); // uniform weight of one int edgeWeight(1); mitk::ConnectomicsNetwork::VertexDescriptorType source; mitk::ConnectomicsNetwork::VertexDescriptorType target; for( int loopX( 0 ); loopX < cubeExtent; loopX++ ) { for( int loopY( 0 ); loopY < cubeExtent; loopY++ ) { for( int loopZ( 0 ); loopZ < cubeExtent; loopZ++ ) { // to avoid creating an edge twice (this being an undirected graph) we only generate // edges in three directions, the others will be supplied by the corresponding nodes if( loopX != 0 ) { edgeTargetID = edgeSourceID - cubeExtent * cubeExtent; source = idToVertexMap.find( edgeSourceID )->second; target = idToVertexMap.find( edgeTargetID )->second; network->AddEdge( source, target, edgeSourceID, edgeTargetID, edgeWeight); edgeID++; } if( loopY != 0 ) { edgeTargetID = edgeSourceID - cubeExtent; source = idToVertexMap.find( edgeSourceID )->second; target = idToVertexMap.find( edgeTargetID )->second; network->AddEdge( source, target, edgeSourceID, edgeTargetID, edgeWeight); edgeID++; } if( loopZ != 0 ) { edgeTargetID = edgeSourceID - 1; source = idToVertexMap.find( edgeSourceID )->second; target = idToVertexMap.find( edgeTargetID )->second; network->AddEdge( source, target, edgeSourceID, edgeTargetID, edgeWeight); edgeID++; } edgeSourceID++; } // end for( int loopZ( 0 ); loopZ < cubeExtent; loopZ++ ) } // end for( int loopY( 0 ); loopY < cubeExtent; loopY++ ) } // end for( int loopX( 0 ); loopX < cubeExtent; loopX++ ) m_LastGenerationWasSuccess = true; }