UINT GesturesAnalyzer::PredictGesture(const vector<vector<cv::Point3d>>& pSampleVec) { GRT::MatrixDouble sample = GRT::MatrixDouble( ); vector<double> vecTemp; UINT predictedClassLabel = 0; for(int iterator = 0; iterator < pSampleVec.size(); iterator++) { int x0 = pSampleVec[iterator][nite::JOINT_TORSO].x; int y0 = pSampleVec[iterator][nite::JOINT_TORSO].y; int z0 = pSampleVec[iterator][nite::JOINT_TORSO].z; vecTemp.push_back(pSampleVec[iterator][nite::JOINT_RIGHT_HAND].x - x0); vecTemp.push_back(pSampleVec[iterator][nite::JOINT_RIGHT_HAND].y - y0); vecTemp.push_back(pSampleVec[iterator][nite::JOINT_RIGHT_HAND].z - z0); vecTemp.push_back(pSampleVec[iterator][nite::JOINT_LEFT_HAND].x - x0); vecTemp.push_back(pSampleVec[iterator][nite::JOINT_LEFT_HAND].y - y0); vecTemp.push_back(pSampleVec[iterator][nite::JOINT_LEFT_HAND].z - z0); sample.push_back(vecTemp); vecTemp.clear(); } if( !m_dtw.predict(sample)) { printf("Failed prediction !\n"); } else { predictedClassLabel = m_dtw.getPredictedClassLabel(); } return predictedClassLabel; }
void HiddenMarkovModels::setUpTrainingDataset() { /* Setup Quantizer */ if (quantizer != NULL) { delete(quantizer); } quantizer = new GRT::KMeansQuantizer( trainingDataset.getNumDimensions(), NUM_SYMBOLS ); //Train the quantizer using the training data if(!quantizer->train( trainingDataset ) ){ throw TestModelException("HiddenMarkovModels: ERROR: Failed to train quantizer!"); } //Quantize the training data GRT::LabelledTimeSeriesClassificationData quantizedTrainingData( 1 ); for( GRT::UINT i=0; i<trainingDataset.getNumSamples(); i++){ GRT::UINT classLabel = trainingDataset[i].getClassLabel(); GRT::MatrixDouble quantizedSample; for(GRT::UINT j=0; j<trainingDataset[i].getLength(); j++) { quantizer->quantize( trainingDataset[i].getData().getRowVector(j) ); quantizedSample.push_back( quantizer->getFeatureVector() ); } if( !quantizedTrainingData.addSample(classLabel, quantizedSample) ){ throw TestModelException("HiddenMarkovModels: ERROR: Failed to quantize training data!"); } } this->trainingDataset = quantizedTrainingData; }
void ASCIISerialStream::readSerial() { // TODO(benzh) This readSerial is running in a different thread // and performing a busy polling (100% CPU usage). Should be // optimized. int sleep_time = 10; ofLog() << "Serial port will be read every " << sleep_time << " ms"; while (has_started_) { string s; do { while (serial_->available() < 1) { std::this_thread::sleep_for(std::chrono::milliseconds(sleep_time)); } s += serial_->readByte(); } while(s[s.length() - 1] != '\n'); //ofLog() << "read: '" << s << "'" << endl; if (data_ready_callback_ != nullptr) { istringstream iss(s); vector<double> data; double d; while (iss >> d) data.push_back(d); if (data.size() > 0) { data = normalize(data); GRT::MatrixDouble matrix; matrix.push_back(data); data_ready_callback_(matrix); } } }
bool Plotter::setData(const GRT::MatrixDouble& data) { x_start_ = 0; x_end_ = 0; data_.clear(); for (int i = 0; i < data.getNumRows(); i++) push_back(data.getRowVector(i)); is_content_modified_ = true; return true; }
HRESULT GesturesAnalyzer::DTWSaveSampleAndTrain(UINT pClasse, const vector<vector<cv::Point3d>>& pSampleVec) { printf("Start saving DTW sample\n"); GRT::MatrixDouble sample = GRT::MatrixDouble( ); vector<double> vecTemp; for(int iterator = 0; iterator < pSampleVec.size(); iterator++) { int x0 = pSampleVec[iterator][nite::JOINT_TORSO].x; int y0 = pSampleVec[iterator][nite::JOINT_TORSO].y; int z0 = pSampleVec[iterator][nite::JOINT_TORSO].z; vecTemp.push_back(pSampleVec[iterator][nite::JOINT_RIGHT_HAND].x - x0); vecTemp.push_back(pSampleVec[iterator][nite::JOINT_RIGHT_HAND].y - y0); vecTemp.push_back(pSampleVec[iterator][nite::JOINT_RIGHT_HAND].z - z0); vecTemp.push_back(pSampleVec[iterator][nite::JOINT_LEFT_HAND].x - x0); vecTemp.push_back(pSampleVec[iterator][nite::JOINT_LEFT_HAND].y - y0); vecTemp.push_back(pSampleVec[iterator][nite::JOINT_LEFT_HAND].z - z0); sample.push_back(vecTemp); vecTemp.clear(); } printf("Adding sample to DTW data\n"); if( !m_DTWTrainingData.addSample(pClasse, sample)) { printf("Failed to add DTW sample\n"); return E_FAIL; } if( !m_DTWTrainingData.saveDatasetToFile("TrainingData\\DTWTrainingData.txt")) { printf("Failed to save DTW data\n"); return E_FAIL; } printf("Training DTW classifier\n"); if( !m_dtw.train( m_DTWTrainingData ) ){ cout << "Failed to train DTW classifier!\n"; return E_FAIL; } else { printf("Succesfully trained DTW Classifier\n"); } return S_OK; }
void HiddenMarkovModels::setUpTestingDataset() { //Quantize the test data GRT::LabelledTimeSeriesClassificationData quantizedTestData( 1 ); for(GRT::UINT i=0; i < testDataset.getNumSamples(); i++){ GRT::UINT classLabel = testDataset[i].getClassLabel(); GRT::MatrixDouble quantizedSample; for(GRT::UINT j=0; j<testDataset[i].getLength(); j++){ quantizer->quantize( testDataset[i].getData().getRowVector(j) ); quantizedSample.push_back( quantizer->getFeatureVector() ); } if( !quantizedTestData.addSample(classLabel, quantizedSample) ){ throw TestModelException("HiddenMarkovModels: ERROR: Failed to quantize training data!"); } } this->testDataset = quantizedTestData; }
void ASCIISerialStream::parseSerial(vector<unsigned char> &buffer) { auto newline = find(buffer.begin(), buffer.end(), '\n'); if (newline != buffer.end()) { string s(buffer.begin(), newline); buffer.erase(buffer.begin(), ++newline); if (data_ready_callback_ != nullptr) { istringstream iss(s); vector<double> data; double d; while (iss >> d) data.push_back(d); if (data.size() > 0) { data = normalize(data); GRT::MatrixDouble matrix; matrix.push_back(data); data_ready_callback_(matrix); } }