void compute(const uqFullEnvironmentClass& env, bool useExperiments, bool useML) { if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "Entering compute()..." << std::endl; } //*********************************************************************** // Step 01 of 09: Instantiate parameter space, parameter domain, and prior Rv //*********************************************************************** unsigned int paper_p_t = 1; // parameter dimension; 'p_t' in paper; drag coefficient 'C' in tower example uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> paper_p_t_space(env, "param_", paper_p_t, NULL); uqGslVectorClass paramMins(paper_p_t_space.zeroVector()); uqGslVectorClass paramMaxs(paper_p_t_space.zeroVector()); paramMins[0] = 0.; paramMaxs[0] = 1.; uqBoxSubsetClass<uqGslVectorClass,uqGslMatrixClass> paramDomain("param_",paper_p_t_space,paramMins,paramMaxs); uqUniformVectorRVClass<uqGslVectorClass,uqGslMatrixClass>* paramPriorRvPtr = NULL; //uqGaussianVectorRVClass<uqGslVectorClass,uqGslMatrixClass>* paramPriorRvPtr = NULL; //*********************************************************************** // Step 02 of 09: Instantiate the 'scenario' and 'output' spaces //*********************************************************************** unsigned int paper_p_x = 1; // scenario dimension; 'p_x' in paper; ball radius 'R' in tower example uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> paper_p_x_space(env, "scenario_", paper_p_x, NULL); unsigned int paper_n_eta = 16; // simulation output dimension; 'n_eta' in paper; 16 in tower example uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> paper_n_eta_space(env, "output_", paper_n_eta, NULL); //*********************************************************************** // Step 03 of 09: Instantiate the simulation storage // Regarding simulation scenario input values, QUESO will standardize them so that // they exist inside a hypercube: this will be done in the 'uqSimulationModelClass' // constructor, step 04 of 09. // Regarding simulation output data, QUESO will transform it so that the mean is // zero and the variance is one: this will be done in the 'uqSimulationModelClass' // constructor, step 04 of 09. //*********************************************************************** unsigned int paper_m = 25; // number of simulations; 'm' in paper; 25 in tower example uqSimulationStorageClass<uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass> simulationStorage(paper_p_x_space,paper_p_t_space,paper_n_eta_space,paper_m); // Add simulations: what if none? uqGslVectorClass extraSimulationGridVec(paper_n_eta_space.zeroVector()); std::vector<uqGslVectorClass* > simulationScenarios(paper_m,(uqGslVectorClass*) NULL); std::vector<uqGslVectorClass* > paramVecs (paper_m,(uqGslVectorClass*) NULL); std::vector<uqGslVectorClass* > outputVecs (paper_m,(uqGslVectorClass*) NULL); for (unsigned int i = 0; i < paper_m; ++i) { simulationScenarios[i] = new uqGslVectorClass(paper_p_x_space.zeroVector()); // 'x_{i+1}^*' in paper paramVecs [i] = new uqGslVectorClass(paper_p_t_space.zeroVector()); // 't_{i+1}^*' in paper outputVecs [i] = new uqGslVectorClass(paper_n_eta_space.zeroVector()); // 'eta_{i+1}' in paper } // Populate all objects just instantiated std::set<unsigned int> tmpSetStep03; tmpSetStep03.insert(env.subId()); extraSimulationGridVec.subReadContents("inputData/extraSimulHeights", "m", tmpSetStep03); uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> paper_m_space(env, "simulation_", paper_m, NULL); uqGslVectorClass inputSimulScenarioVector(paper_m_space.zeroVector()); inputSimulScenarioVector.subReadContents("inputData/allSimulScenarios", "m", tmpSetStep03); uqGslVectorClass inputSimulParameterVector(paper_m_space.zeroVector()); inputSimulParameterVector.subReadContents("inputData/allSimulParameters", "m", tmpSetStep03); uqGslMatrixClass inputSimulOutputsMatrix(env,paper_n_eta_space.map(),paper_m); inputSimulOutputsMatrix.subReadContents("inputData/allSimulOutputs", "m", tmpSetStep03); for (unsigned int i = 0; i < paper_m; ++i) { (*(simulationScenarios[i]))[0] = inputSimulScenarioVector [i]; (*(paramVecs [i]))[0] = inputSimulParameterVector[i]; inputSimulOutputsMatrix.getColumn(i,*(outputVecs[i])); } // Finally, add information to the simulation storage for (unsigned int i = 0; i < paper_m; ++i) { simulationStorage.addSimulation(*(simulationScenarios[i]),*(paramVecs[i]),*(outputVecs[i])); } //*********************************************************************** // Step 04 of 09: Instantiate the simulation model //*********************************************************************** uqSimulationModelClass<uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass> simulationModel("", // prefix NULL, // options values simulationStorage); unsigned int paper_p_eta = simulationModel.numBasis(); // number of simulation basis; 'p_eta' in paper; 2 in tower example //*********************************************************************** // Step 05 of 09: Instantiate the experiment storage // Regarding experimental scenario input values, QUESO will standardize them so that // they exist inside a hypercube: this will be done in the 'uqExperimentModelClass' // constructor, step 06 of 09. // Regarding experimental data, the user has to provide it already in transformed // format, that is, with mean zero and standard deviation one. //*********************************************************************** uqExperimentStorageClass<uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass>* experimentStoragePtr = NULL; uqExperimentModelClass <uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass>* experimentModelPtr = NULL; unsigned int paper_n = 0; std::vector<uqGslVectorClass* > experimentScenarios_original(paper_n,(uqGslVectorClass*) NULL); std::vector<uqGslVectorClass* > experimentScenarios_standard(paper_n,(uqGslVectorClass*) NULL); std::vector<unsigned int> experimentDims (paper_n,0); std::vector<uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass>* > experimentSpaces (paper_n,(uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass>*) NULL); std::vector<uqGslVectorClass* > extraExperimentGridVecs (paper_n,(uqGslVectorClass*) NULL); std::vector<uqGslVectorClass* > experimentVecs_original (paper_n,(uqGslVectorClass*) NULL); std::vector<uqGslVectorClass* > experimentVecs_auxMean (paper_n,(uqGslVectorClass*) NULL); std::vector<uqGslVectorClass* > experimentVecs_transformed (paper_n,(uqGslVectorClass*) NULL); std::vector<uqGslMatrixClass* > experimentMats_original (paper_n,(uqGslMatrixClass*) NULL); std::vector<uqGslMatrixClass* > experimentMats_transformed (paper_n,(uqGslMatrixClass*) NULL); std::vector<uqGslMatrixClass* > DobsMats (paper_n, (uqGslMatrixClass*) NULL); std::vector<uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass>* > Kmats_interp_spaces (paper_n, (uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass>*) NULL); std::vector<uqGslMatrixClass* > Kmats_interp (paper_n, (uqGslMatrixClass*) NULL); // Interpolations of 'Kmat_eta' = 'K_i's' in paper if (useExperiments) { paper_n = 3; // number of experiments; 'n' in paper; 3 in tower example experimentStoragePtr = new uqExperimentStorageClass<uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass>(paper_p_x_space, paper_n); // Add experiments experimentScenarios_original.resize(paper_n,(uqGslVectorClass*) NULL); experimentScenarios_standard.resize(paper_n,(uqGslVectorClass*) NULL); experimentDims.resize (paper_n,0); experimentSpaces.resize (paper_n,(uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass>*) NULL); extraExperimentGridVecs.resize (paper_n,(uqGslVectorClass*) NULL); experimentVecs_original.resize (paper_n,(uqGslVectorClass*) NULL); experimentVecs_auxMean.resize (paper_n,(uqGslVectorClass*) NULL); experimentVecs_transformed.resize (paper_n,(uqGslVectorClass*) NULL); experimentMats_original.resize (paper_n,(uqGslMatrixClass*) NULL); experimentMats_transformed.resize (paper_n,(uqGslMatrixClass*) NULL); experimentDims[0] = 4; // 'n_y_1' in paper; 4 in tower example experimentDims[1] = 4; // 'n_y_2' in paper; 4 in tower example experimentDims[2] = 3; // 'n_y_3' in paper; 3 in tower example for (unsigned int i = 0; i < paper_n; ++i) { experimentScenarios_original[i] = new uqGslVectorClass (paper_p_x_space.zeroVector()); // 'x_{i+1}' in paper experimentScenarios_standard[i] = new uqGslVectorClass (paper_p_x_space.zeroVector()); // 'x_{i+1}' in paper experimentSpaces [i] = new uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass>(env, "expSpace", experimentDims[i], NULL); extraExperimentGridVecs [i] = new uqGslVectorClass (experimentSpaces[i]->zeroVector()); // experimentVecs_original [i] = new uqGslVectorClass (experimentSpaces[i]->zeroVector()); // experimentVecs_auxMean [i] = new uqGslVectorClass (experimentSpaces[i]->zeroVector()); // experimentVecs_transformed [i] = new uqGslVectorClass (experimentSpaces[i]->zeroVector()); // 'y_{i+1}' in paper experimentMats_original [i] = new uqGslMatrixClass (experimentSpaces[i]->zeroVector()); // experimentMats_transformed [i] = new uqGslMatrixClass (experimentSpaces[i]->zeroVector()); // 'W_{i+1}' in paper } //*********************************************************************** // Populate information regarding experiment '0' //*********************************************************************** (*(experimentScenarios_original[0]))[0] = 0.1; // 'x_1' in paper; Radius in tower example *(experimentScenarios_standard[0]) = *(experimentScenarios_original[0]); *(experimentScenarios_standard[0]) -= simulationModel.xSeq_original_mins(); for (unsigned int j = 0; j < paper_p_x; ++j) { (*(experimentScenarios_standard[0]))[j] /= simulationModel.xSeq_original_ranges()[j]; } (*(extraExperimentGridVecs[0]))[0] = 5.; (*(extraExperimentGridVecs[0]))[1] = 10.; (*(extraExperimentGridVecs[0]))[2] = 15.; (*(extraExperimentGridVecs[0]))[3] = 20.; (*(experimentVecs_original[0]))[0] = 1.2180; (*(experimentVecs_original[0]))[1] = 2.0126; (*(experimentVecs_original[0]))[2] = 2.7942; (*(experimentVecs_original[0]))[3] = 3.5747; experimentVecs_auxMean[0]->matlabLinearInterpExtrap(extraSimulationGridVec,simulationModel.etaSeq_original_mean(),*(extraExperimentGridVecs[0])); if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { *env.subDisplayFile() << "In compute(), step 05, experiment 0:" << "\n extraSimulationGridVec = " << extraSimulationGridVec << "\n simulationModel.etaSeq_original_mean() = " << simulationModel.etaSeq_original_mean() << "\n *(extraExperimentGridVecs[0]) = " << *(extraExperimentGridVecs[0]) << "\n *(experimentVecs_auxMean[0]) = " << *(experimentVecs_auxMean[0]) << std::endl; } *(experimentVecs_transformed[0]) = (1./simulationModel.etaSeq_allStd()) * ( *(experimentVecs_original[0]) - *(experimentVecs_auxMean[0]) ); // 'y_1' in paper if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { *env.subDisplayFile() << "In compute(), step 05, experiment 0:" << "\n *(experimentVecs_original[0]) = " << *(experimentVecs_original[0]) << "\n *(experimentVecs_auxMean[0]) = " << *(experimentVecs_auxMean[0]) << "\n simulationModel.etaSeq_allStd() = " << simulationModel.etaSeq_allStd() << "\n *(experimentVecs_transformed[0]) = " << *(experimentVecs_transformed[0]) << std::endl; } (*(experimentMats_original[0]))(0,0) = 1.; (*(experimentMats_original[0]))(1,1) = 1.; (*(experimentMats_original[0]))(2,2) = 1.; (*(experimentMats_original[0]))(3,3) = 1.; *(experimentMats_transformed[0]) = *(experimentMats_original[0]); //*********************************************************************** // Populate information regarding experiment '1' //*********************************************************************** (*(experimentScenarios_original[1]))[0] = 0.2; // 'x_2' in paper; Radius in tower example *(experimentScenarios_standard[1]) = *(experimentScenarios_original[1]); *(experimentScenarios_standard[1]) -= simulationModel.xSeq_original_mins(); for (unsigned int j = 0; j < paper_p_x; ++j) { (*(experimentScenarios_standard[1]))[j] /= simulationModel.xSeq_original_ranges()[j]; } (*(extraExperimentGridVecs[1]))[0] = 5.; (*(extraExperimentGridVecs[1]))[1] = 10.; (*(extraExperimentGridVecs[1]))[2] = 15.; (*(extraExperimentGridVecs[1]))[3] = 20.; (*(experimentVecs_original[1]))[0] = 1.1129; (*(experimentVecs_original[1]))[1] = 1.7225; (*(experimentVecs_original[1]))[2] = 2.2898; (*(experimentVecs_original[1]))[3] = 2.8462; experimentVecs_auxMean[1]->matlabLinearInterpExtrap(extraSimulationGridVec,simulationModel.etaSeq_original_mean(),*(extraExperimentGridVecs[1])); *(experimentVecs_transformed[1]) = (1./simulationModel.etaSeq_allStd()) * ( *(experimentVecs_original[1]) - *(experimentVecs_auxMean[1]) ); // 'y_2' in paper if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { *env.subDisplayFile() << "In compute(), step 05, experiment 1:" << "\n *(experimentVecs_original[1]) = " << *(experimentVecs_original[1]) << "\n *(experimentVecs_auxMean[1]) = " << *(experimentVecs_auxMean[1]) << "\n simulationModel.etaSeq_allStd() = " << simulationModel.etaSeq_allStd() << "\n *(experimentVecs_transformed[1]) = " << *(experimentVecs_transformed[1]) << std::endl; } (*(experimentMats_original[1]))(0,0) = 1.; (*(experimentMats_original[1]))(1,1) = 1.; (*(experimentMats_original[1]))(2,2) = 1.; (*(experimentMats_original[1]))(3,3) = 1.; *(experimentMats_transformed[1]) = *(experimentMats_original[1]); //*********************************************************************** // Populate information regarding experiment '2' //*********************************************************************** (*(experimentScenarios_original[2]))[0] = 0.4; // 'x_3' in paper; Radius in tower example *(experimentScenarios_standard[2]) = *(experimentScenarios_original[2]); *(experimentScenarios_standard[2]) -= simulationModel.xSeq_original_mins(); for (unsigned int j = 0; j < paper_p_x; ++j) { (*(experimentScenarios_standard[2]))[j] /= simulationModel.xSeq_original_ranges()[j]; } (*(extraExperimentGridVecs[2]))[0] = 5.; (*(extraExperimentGridVecs[2]))[1] = 10.; (*(extraExperimentGridVecs[2]))[2] = 15.; (*(experimentVecs_original[2]))[0] = 1.0611; (*(experimentVecs_original[2]))[1] = 1.5740; (*(experimentVecs_original[2]))[2] = 2.0186; experimentVecs_auxMean[2]->matlabLinearInterpExtrap(extraSimulationGridVec,simulationModel.etaSeq_original_mean(),*(extraExperimentGridVecs[2])); *(experimentVecs_transformed[2]) = (1./simulationModel.etaSeq_allStd()) * ( *(experimentVecs_original[2]) - *(experimentVecs_auxMean[2]) ); // 'y_3' in paper if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { *env.subDisplayFile() << "In compute(), step 05, experiment 2:" << "\n *(experimentVecs_original[2]) = " << *(experimentVecs_original[2]) << "\n *(experimentVecs_auxMean[2]) = " << *(experimentVecs_auxMean[2]) << "\n simulationModel.etaSeq_allStd() = " << simulationModel.etaSeq_allStd() << "\n *(experimentVecs_transformed[2]) = " << *(experimentVecs_transformed[2]) << std::endl; } (*(experimentMats_original[2]))(0,0) = 1.; (*(experimentMats_original[2]))(1,1) = 1.; (*(experimentMats_original[2]))(2,2) = 1.; *(experimentMats_transformed[2]) = *(experimentMats_original[2]); //*********************************************************************** // Finally, add information to the experiment storage //*********************************************************************** for (unsigned int i = 0; i < paper_n; ++i) { if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { *env.subDisplayFile() << "In compute(), step 05" << ": calling experimentStoragePtr->addExperiment() for experiment of id '" << i << "'..." << std::endl; } experimentStoragePtr->addExperiment(*(experimentScenarios_standard[i]),*(experimentVecs_transformed[i]),*(experimentMats_transformed[i])); if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { *env.subDisplayFile() << "In compute(), step 05" << ": returned from experimentStoragePtr->addExperiment() for experiment of id '" << i << "'" << std::endl; } } //*********************************************************************** // Step 06 of 09: Instantiate the experiment model // User has to provide 'D' matrices // User has to interpolate 'K_eta' matrix in order to form 'K_i' matrices // 'K_eta' is 'Ksim' in the GPMSA tower example document (page 9) // 'K_i' is 'Kobs' in the GPMSA tower example document (page 9) //*********************************************************************** unsigned int paper_p_delta = 13; // number of experiment basis; 'p_delta' in paper; 13 in tower example //*********************************************************************** // Form and compute 'DsimMat' // Not mentioned in the paper // 'Dsim' in the GPMSA tower example document (page 11) //*********************************************************************** double kernelSigma = 2.; uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> paper_p_delta_space(env, "paper_p_delta_space", paper_p_delta, NULL); uqGslVectorClass kernelCenters(paper_p_delta_space.zeroVector()); for (unsigned int i = 1; i < paper_p_delta; ++i) { // Yes, '1' kernelCenters[i] = kernelSigma*((double) i); } uqGslMatrixClass DsimMat(env,paper_n_eta_space.map(),paper_p_delta); // Important matrix (not mentioned on paper) uqGslVectorClass DsimCol(paper_n_eta_space.zeroVector()); uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> oneDSpace(env, "oneDSpace", 1, NULL); uqGslVectorClass oneDVec(oneDSpace.zeroVector()); uqGslMatrixClass oneDMat(oneDSpace.zeroVector()); oneDMat(0,0) = kernelSigma*kernelSigma; for (unsigned int colId = 0; colId < DsimMat.numCols(); ++colId) { oneDVec[0] = kernelCenters[colId]; uqGaussianJointPdfClass<uqGslVectorClass,uqGslMatrixClass> kernelPdf("",oneDSpace,oneDVec,oneDMat); for (unsigned int rowId = 0; rowId < paper_n_eta; ++rowId) { oneDVec[0] = extraSimulationGridVec[rowId]; DsimCol[rowId] = kernelPdf.actualValue(oneDVec,NULL,NULL,NULL,NULL); } DsimMat.setColumn(colId,DsimCol); } //*********************************************************************** // Populate information regarding experiment 'i' // 'D_{i+1}' in the paper // 'Dobs' in the GPMSA tower example document (page 11) //*********************************************************************** DobsMats.resize(paper_n, (uqGslMatrixClass*) NULL); // Important matrices (D_i's on paper) for (unsigned int i = 0; i < paper_n; ++i) { DobsMats[i] = new uqGslMatrixClass(env,experimentSpaces[i]->map(),paper_p_delta); // 'D_{i+1}' in paper uqGslVectorClass DobsCol(experimentSpaces[i]->zeroVector()); for (unsigned int colId = 0; colId < DobsMats[i]->numCols(); ++colId) { oneDVec[0] = kernelCenters[colId]; uqGaussianJointPdfClass<uqGslVectorClass,uqGslMatrixClass> kernelPdf("",oneDSpace,oneDVec,oneDMat); for (unsigned int rowId = 0; rowId < DobsCol.sizeLocal(); ++rowId) { oneDVec[0] = (*(extraExperimentGridVecs[1]))[rowId]; DobsCol[rowId] = kernelPdf.actualValue(oneDVec,NULL,NULL,NULL,NULL); } DobsMats[i]->setColumn(colId,DobsCol); } } //*********************************************************************** // Normalize 'DsimMat' and all 'DobsMats' //*********************************************************************** uqGslMatrixClass DsimMatTranspose(env,paper_p_delta_space.map(),paper_n_eta); DsimMatTranspose.fillWithTranspose(0,0,DsimMat,true,true); double Dmax = (DsimMat * DsimMatTranspose).max(); if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { *env.subDisplayFile() << "In compute()" << ": Dmax = " << Dmax << std::endl; } DsimMat /= std::sqrt(Dmax); if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { DsimMat.setPrintHorizontally(false); *env.subDisplayFile() << "In compute()" << ": 'DsimMat'" << ", nRows = " << DsimMat.numRowsLocal() << ", nCols = " << DsimMat.numCols() << ", contents =\n " << DsimMat << std::endl; } for (unsigned int i = 0; i < paper_n; ++i) { *(DobsMats[i]) /= std::sqrt(Dmax); DobsMats[i]->setPrintHorizontally(false); if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { *env.subDisplayFile() << "In compute()" << ": 'DobsMats', i = " << i << ", nRows = " << DobsMats[i]->numRowsLocal() << ", nCols = " << DobsMats[i]->numCols() << ", contents =\n" << *(DobsMats[i]) << std::endl; } } //*********************************************************************** // Compute 'K_i' matrices // 'Kobs' in the GPMSA tower example document (page 9) //*********************************************************************** Kmats_interp_spaces.resize(paper_n, (uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass>*) NULL); Kmats_interp.resize (paper_n, (uqGslMatrixClass*) NULL); // Important matrices (K_i's on paper) for (unsigned int i = 0; i < paper_n; ++i) { Kmats_interp_spaces[i] = new uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass>(env,"Kmats_interp_spaces_",experimentStoragePtr->n_ys_transformed()[i],NULL); Kmats_interp [i] = new uqGslMatrixClass(env,Kmats_interp_spaces[i]->map(),paper_p_eta); Kmats_interp [i]->matlabLinearInterpExtrap(extraSimulationGridVec,simulationModel.Kmat_eta(),*(extraExperimentGridVecs[i])); // Important matrix (K_eta on paper) Kmats_interp[i]->setPrintHorizontally(false); if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { *env.subDisplayFile() << "In compute()" << ": 'Kmats_interp', i = " << i << ", nRows = " << Kmats_interp[i]->numRowsLocal() << ", nCols = " << Kmats_interp[i]->numCols() << ", contents =\n" << *(Kmats_interp[i]) << std::endl; } } if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "In compute()" << ": finished computing 'K_i' matrices" << std::endl; } //*********************************************************************** // The constructor below will read from the options file: // --> the 'G' values (a total of 'F' of them); 'Gs' in paper; G[0] = 13 in tower example // --> 'F' in paper = number of groups of experiment basis; 1 in tower example //*********************************************************************** experimentModelPtr = new uqExperimentModelClass<uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass>("", // prefix NULL, // options values *experimentStoragePtr, DobsMats, Kmats_interp); paramPriorRvPtr = new uqUniformVectorRVClass<uqGslVectorClass,uqGslMatrixClass>("prior_",paramDomain); //uqGslVectorClass meanVec(paper_p_t_space.zeroVector()); //meanVec[0] = 0.5; //uqGslMatrixClass covaMat(paper_p_t_space.zeroVector()); //covaMat(0,0) = 100.; //paramPriorRvPtr = new uqGaussianVectorRVClass<uqGslVectorClass,uqGslMatrixClass>("prior_",paramDomain/*paper_p_t_space*/,meanVec,covaMat); } // if (useExperiments) //*********************************************************************** // Step 07 of 09: Instantiate the GPMSA computer model //*********************************************************************** uqGpmsaComputerModelClass<uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass,uqGslVectorClass,uqGslMatrixClass>* gcm; gcm = new uqGpmsaComputerModelClass<uqGslVectorClass,uqGslMatrixClass, uqGslVectorClass,uqGslMatrixClass, uqGslVectorClass,uqGslMatrixClass, uqGslVectorClass,uqGslMatrixClass> ("", NULL, simulationStorage, simulationModel, experimentStoragePtr, // pass "NULL" if there is no experimental data available experimentModelPtr, // pass "NULL" if there is no experimental data available paramPriorRvPtr); // pass "NULL" if there is no experimental data available if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "In compute()" << ": finished instantiating 'gcm'" << ", gcm->totalSpace().dimLocal() = " << gcm->totalSpace().dimLocal() << std::endl; } //*********************************************************************** // Step 08 of 09: Calibrate the computer model //*********************************************************************** uqGslVectorClass totalInitialVec(gcm->totalSpace().zeroVector()); gcm->totalPriorRv().realizer().realization(totalInitialVec); // todo_r uqGslVectorClass diagVec(gcm->totalSpace().zeroVector()); diagVec.cwSet(0.25); if (useExperiments) { #if 1 // Use same initial values as matlab code, for debug totalInitialVec[ 0] = 2.9701e+04; // lambda_eta = lamWOs totalInitialVec[ 1] = 1.; // lambda_w_1 = lamUz totalInitialVec[ 2] = 1.; // lambda_w_2 = totalInitialVec[ 3] = std::exp(-0.1*0.25); // rho_w_1_1 = exp(-model.betaU.*(0.5^2)); totalInitialVec[ 4] = std::exp(-0.1*0.25); // rho_w_1_2 = totalInitialVec[ 5] = std::exp(-0.1*0.25); // rho_w_2_1 = totalInitialVec[ 6] = std::exp(-0.1*0.25); // rho_w_2_2 = totalInitialVec[ 7] = 1000.; // lambda_s_1 = lamWs totalInitialVec[ 8] = 1000.; // lambda_s_2 = totalInitialVec[ 9] = 999.999; // lambda_y = lamOs totalInitialVec[10] = 20.; // lambda_v_1 = lamVz totalInitialVec[11] = std::exp(-0.1*0.25); // rho_v_1_1 = betaV totalInitialVec[12] = 0.5; // theta_1 = theta #endif diagVec[ 0] = 2500.; // lambda_eta = lamWOs diagVec[ 1] = 0.09; // lambda_w_1 = lamUz diagVec[ 2] = 0.09; // lambda_w_2 = diagVec[ 3] = 0.01; // rho_w_1_1 = betaU diagVec[ 4] = 0.01; // rho_w_1_2 = diagVec[ 5] = 0.01; // rho_w_2_1 = diagVec[ 6] = 0.01; // rho_w_2_2 = diagVec[ 7] = 2500.; // lambda_s_1 = lamWs diagVec[ 8] = 2500; // lambda_s_2 = diagVec[ 9] = 2500; // lambda_y = lamOs diagVec[10] = 2500; // lambda_v_1 = lamVz diagVec[11] = 0.01; // rho_v_1_1 = betaV diagVec[12] = 100.; // theta_1 = theta } else { #if 1 // Use same initial values as matlab code, for debug totalInitialVec[ 0] = 2.9701e+04; // lambda_eta = lamWOs totalInitialVec[ 1] = 1.; // lambda_w_1 = lamUz totalInitialVec[ 2] = 1.; // lambda_w_2 = totalInitialVec[ 3] = std::exp(-0.1*0.25); // rho_w_1_1 = exp(-model.betaU.*(0.5^2)); totalInitialVec[ 4] = std::exp(-0.1*0.25); // rho_w_1_2 = totalInitialVec[ 5] = std::exp(-0.1*0.25); // rho_w_2_1 = totalInitialVec[ 6] = std::exp(-0.1*0.25); // rho_w_2_2 = totalInitialVec[ 7] = 1000.; // lambda_s_1 = lamWs totalInitialVec[ 8] = 1000.; // lambda_s_2 = #endif diagVec[ 0] = 2500.; // lambda_eta = lamWOs diagVec[ 1] = 0.09; // lambda_w_1 = lamUz diagVec[ 2] = 0.09; // lambda_w_2 = diagVec[ 3] = 0.01; // rho_w_1_1 = betaU diagVec[ 4] = 0.01; // rho_w_1_2 = diagVec[ 5] = 0.01; // rho_w_2_1 = diagVec[ 6] = 0.01; // rho_w_2_2 = diagVec[ 7] = 2500.; // lambda_s_1 = lamWs diagVec[ 8] = 2500; // lambda_s_2 = } uqGslMatrixClass totalInitialProposalCovMatrix(diagVec); // todo_r if (useML) { gcm->calibrateWithBayesMLSampling(); } else { gcm->calibrateWithBayesMetropolisHastings(NULL,totalInitialVec,&totalInitialProposalCovMatrix); } if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "In compute()" << ": finished calibrating 'gcm'" << std::endl; } //*********************************************************************** // Step 09 of 09: Make predictions with the calibrated computer model // Substep 09a: predict 'v' and 'u' weights // Substep 09b: predict 'w' weights // Substep 09c: predict new experiment results // Substep 09d: predict new simulation outputs //*********************************************************************** unsigned int dim1 = 16; uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> predictionGrid1Space(env, "predictionGrid1_", dim1, NULL); uqGslVectorClass predictionGrid1Vec(predictionGrid1Space.zeroVector()); for (unsigned int i = 0; i < dim1; ++i) { predictionGrid1Vec[i] = ((double) i)/((double) (dim1-1)); } unsigned int dim2 = 16; uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> predictionGrid2Space(env, "predictionGrid2_", dim2, NULL); uqGslVectorClass predictionGrid2Vec(predictionGrid2Space.zeroVector()); for (unsigned int j = 0; j < dim2; ++j) { predictionGrid2Vec[j] = ((double) j)/((double) (dim2-1)); } if (env.fullRank() == 0) { // Yes, only one processor in all 'full' communicator std::set<unsigned int> tmpSet; tmpSet.insert(0); predictionGrid1Vec.subWriteContents("towerPredictionGrid1", // varNamePrefix, "predictionGrid1", "m", tmpSet); // allowedSubEnvIds predictionGrid2Vec.subWriteContents("towerPredictionGrid2", // varNamePrefix, "predictionGrid2", "m", tmpSet); // allowedSubEnvIds } uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> paper_p_eta_space(env, "paper_p_eta_", paper_p_eta, NULL); // = gcm->unique_u_space() or gcm->unique_w_space() if (useExperiments) { #if 1 // Might put '0' while code is not finished //*********************************************************************** // Substep 09a of 09: Predict 'v' and 'u' weights //*********************************************************************** uqGslVectorClass tmpExperimentScenarioVec (paper_p_x_space.zeroVector()); uqGslVectorClass tmpSimulationParameterVec(paper_p_t_space.zeroVector()); unsigned int paper_p_delta = 13; // todo_rr: repeated uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> paper_p_delta_space(env, "paper_p_delta_space", paper_p_delta, NULL); // todo_rr: repeated // = gcm_unique_v_space() std::vector<uqGslMatrixClass* > predictionGridVMats(paper_p_delta,NULL); for (unsigned int k = 0; k < paper_p_delta; ++k) { predictionGridVMats[k] = new uqGslMatrixClass(predictionGrid1Space.zeroVector()); } std::vector<uqGslMatrixClass* > predictionGridUMats(paper_p_eta,NULL); for (unsigned int k = 0; k < paper_p_eta; ++k) { predictionGridUMats[k] = new uqGslMatrixClass(predictionGrid1Space.zeroVector()); } uqGslVectorClass vuMeanVec (gcm->unique_vu_space().zeroVector()); uqGslMatrixClass vuCovMatrix(gcm->unique_vu_space().zeroVector()); uqGslVectorClass vMeanVec (paper_p_delta_space.zeroVector()); uqGslMatrixClass vCovMatrix (paper_p_delta_space.zeroVector()); uqGslVectorClass uMeanVec (paper_p_eta_space.zeroVector()); uqGslMatrixClass uCovMatrix (paper_p_eta_space.zeroVector()); for (unsigned int i = 0; i < dim1; ++i) { tmpExperimentScenarioVec[0] = predictionGrid1Vec[i]; for (unsigned int j = 0; j < dim2; ++j) { tmpSimulationParameterVec[0] = predictionGrid2Vec[j]; #if 1 gcm->predictVUsAtGridPoint(tmpExperimentScenarioVec, tmpSimulationParameterVec, vuMeanVec, vuCovMatrix, vMeanVec, vCovMatrix, uMeanVec, uCovMatrix); #endif for (unsigned int k = 0; k < paper_p_delta; ++k) { (*predictionGridVMats[k])(i,j) = vMeanVec[k]; } for (unsigned int k = 0; k < paper_p_eta; ++k) { (*predictionGridUMats[k])(i,j) = uMeanVec[k]; } } } if (env.fullRank() == 0) { // Yes, only one processor in all 'full' communicator std::set<unsigned int> tmpSet; tmpSet.insert(0); char varNamePrefix[32+1]; char fileName [32+1]; for (unsigned int i = 0; i < paper_p_delta; ++i) { sprintf(varNamePrefix,"towerV%dmat",i+1); sprintf(fileName, "v%dmat", i+1); predictionGridVMats[i]->subWriteContents(varNamePrefix, fileName, "m", tmpSet); // allowedSubEnvIds } for (unsigned int i = 0; i < paper_p_eta; ++i) { sprintf(varNamePrefix,"towerU%dmat",i+1); sprintf(fileName, "u%dmat", i+1); predictionGridUMats[i]->subWriteContents(varNamePrefix, fileName, "m", tmpSet); // allowedSubEnvIds } } for (unsigned int i = 0; i < paper_p_eta; ++i) { delete predictionGridUMats[i]; } for (unsigned int i = 0; i < paper_p_delta; ++i) { delete predictionGridVMats[i]; } #endif // Might put '0' } // if (useExperiments) #if 1 // Might put '0' while code is not finished //*********************************************************************** // Substep 09b of 09: Predict 'w' weights //*********************************************************************** uqGslVectorClass tmpSimulationScenarioVec (paper_p_x_space.zeroVector()); uqGslVectorClass tmpSimulationParameterVec(paper_p_t_space.zeroVector()); uqGslVectorClass wMeanVec (paper_p_eta_space.zeroVector()); uqGslMatrixClass wCovMatrix(paper_p_eta_space.zeroVector()); #if 0 // For debug only tmpSimulationScenarioVec [0] = 0.4; tmpSimulationParameterVec[0] = 0.4; uqGslVectorClass forcingSampleVecForDebug(gcm->totalSpace().zeroVector()); forcingSampleVecForDebug[ 0] = 2.9700e+04; // lambda_eta = lamWOs forcingSampleVecForDebug[ 1] = 1.0000; // lambda_w_1 = lamUz forcingSampleVecForDebug[ 2] = 1.0083; // lambda_w_2 = forcingSampleVecForDebug[ 3] = std::exp(-0.1004*0.25); // rho_w_1_1 = exp(-model.betaU.*(0.5^2)); forcingSampleVecForDebug[ 4] = std::exp(-0.1022*0.25); // rho_w_1_2 = forcingSampleVecForDebug[ 5] = std::exp(-0.1013*0.25); // rho_w_2_1 = forcingSampleVecForDebug[ 6] = std::exp(-0.1011*0.25); // rho_w_2_2 = forcingSampleVecForDebug[ 7] = 999.5113; // lambda_s_1 = lamWs forcingSampleVecForDebug[ 8] = 999.3138; // lambda_s_2 = forcingSampleVecForDebug[ 9] = 996.6176; // lambda_y = lamOs forcingSampleVecForDebug[10] = 20.0194; // lambda_v_1 = lamVz forcingSampleVecForDebug[11] = std::exp(-0.1020*0.25); // rho_v_1_1 = betaV forcingSampleVecForDebug[12] = 0.5000; // theta_1 = theta gcm->predictWsAtGridPoint(tmpSimulationScenarioVec, tmpSimulationParameterVec, &forcingSampleVecForDebug, wMeanVec, wCovMatrix); if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "In compute()" << ": for scenario = " << tmpSimulationScenarioVec [0] << " and parameter = " << tmpSimulationParameterVec[0] << ", wMeanVec = " << wMeanVec << ", wCovMatrix = " << wCovMatrix << std::endl; } env.fullComm().Barrier(); sleep(1); exit(1); #endif std::vector<uqGslMatrixClass* > predictionGridWMats(paper_p_eta,NULL); for (unsigned int k = 0; k < paper_p_eta; ++k) { predictionGridWMats[k] = new uqGslMatrixClass(env,predictionGrid1Space.map(),dim2); } if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "In compute()" << ": beginning loop on predictions" << ", dim1 = " << dim1 << ", dim2 = " << dim2 << std::endl; } for (unsigned int i = 0; i < dim1; ++i) { tmpSimulationScenarioVec[0] = predictionGrid1Vec[i]; for (unsigned int j = 0; j < dim2; ++j) { tmpSimulationParameterVec[0] = predictionGrid2Vec[j]; struct timeval timevalBeforePredict; int iRC = gettimeofday(&timevalBeforePredict, NULL); if (iRC) {}; // just to remove compiler warning gcm->predictWsAtGridPoint(tmpSimulationScenarioVec, tmpSimulationParameterVec, NULL, wMeanVec, wCovMatrix); double predictTime = uqMiscGetEllapsedSeconds(&timevalBeforePredict); if ((env.subDisplayFile()) && (env.displayVerbosity() >= 3)) { *env.subDisplayFile() << "In compute()" << ": looping on predictions" << ", i = " << i << " < " << dim1 << ", j = " << j << " < " << dim2 << ", returned from 'gcm->predictWsAtGridPoint()' after " << predictTime << " seconds" << std::endl; } for (unsigned int k = 0; k < paper_p_eta; ++k) { (*predictionGridWMats[k])(i,j) = wMeanVec[k]; } } } if (env.fullRank() == 0) { // Yes, only one processor in all 'full' communicator std::set<unsigned int> tmpSet; tmpSet.insert(0); char varNamePrefix[32+1]; char fileName [32+1]; for (unsigned int i = 0; i < paper_p_eta; ++i) { sprintf(varNamePrefix,"towerW%dmat",i+1); sprintf(fileName, "w%dmat", i+1); predictionGridWMats[i]->subWriteContents(varNamePrefix, fileName, "m", tmpSet); // allowedSubEnvIds } } for (unsigned int i = 0; i < paper_p_eta; ++i) { delete predictionGridWMats[i]; } if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "In compute()" << ": finished making predictions" << std::endl; } #endif // Might put '0' #if 0 // Might put '0' while code is not finished //*********************************************************************** // Substep 09c of 09: Predict new experiment results //*********************************************************************** uqGslVectorClass newExperimentScenarioVec(paper_p_x_space.zeroVector()); // todo_rr uqGslMatrixClass newKmat_interp (env,paper_n_eta_space.map(),paper_p_eta); // todo_rr uqGslMatrixClass newDmat (env,paper_n_eta_space.map(),paper_p_delta); // todo_rr uqGslVectorClass simulationOutputMeanVec (paper_n_eta_space.zeroVector()); // Yes, size of simulation, since it is a prediction using the emulator uqGslVectorClass discrepancyMeanVec (paper_n_eta_space.zeroVector()); gcm->predictExperimentResults(newExperimentScenarioVec,newKmat_interp,newDmat,simulationOutputMeanVec,discrepancyMeanVec); //*********************************************************************** // Substep 09d of 09: Predict new simulation outputs //*********************************************************************** uqGslVectorClass newSimulationScenarioVec (paper_p_x_space.zeroVector ()); // todo_rr uqGslVectorClass newSimulationParameterVec(paper_p_t_space.zeroVector ()); // todo_rr uqGslVectorClass simulationOutputMeanVec2 (paper_n_eta_space.zeroVector()); gcm->predictSimulationOutputs(newSimulationScenarioVec,newSimulationParameterVec,simulationOutputMeanVec2); #endif // Might put '0' //*********************************************************************** // Clean memory //*********************************************************************** env.fullComm().Barrier(); delete paramPriorRvPtr; delete experimentModelPtr; delete experimentStoragePtr; for (unsigned int i = 0; i < paper_n; ++i) { delete Kmats_interp [i]; delete Kmats_interp_spaces[i]; } for (unsigned int i = 0; i < paper_m; ++i) { delete outputVecs [i]; delete paramVecs [i]; delete simulationScenarios[i]; } for (unsigned int i = 0; i < paper_n; ++i) { delete experimentMats_transformed [i]; delete experimentMats_original [i]; delete experimentVecs_transformed [i]; delete experimentVecs_original [i]; delete experimentSpaces [i]; delete experimentScenarios_standard[i]; delete experimentScenarios_original[i]; } delete gcm; if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "Leaving compute()" << std::endl; } return; }
void solveSip(const uqFullEnvironmentClass& env, bool useML) { if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "Entering solveSip()..." << std::endl; } //////////////////////////////////////////////////////// // Step 1 of 5: Instantiate the parameter space //////////////////////////////////////////////////////// unsigned int p = 1; uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> paramSpace(env, "param_", p, NULL); uqGslVectorClass bVec(paramSpace.zeroVector()); bVec[0] = 0.045213; //////////////////////////////////////////////////////// // Step 2 of 5: Instantiate the parameter domain //////////////////////////////////////////////////////// //uqGslVectorClass paramMins (paramSpace.zeroVector()); //uqGslVectorClass paramMaxs (paramSpace.zeroVector()); //paramMins [0] = -1.e+16; //paramMaxs [0] = 1.e+16; //paramMins [1] = -1.e+16; //paramMaxs [1] = 1.e+16; //uqBoxSubsetClass<uqGslVectorClass,uqGslMatrixClass> paramDomain("param_",paramSpace,paramMins,paramMaxs); uqVectorSetClass<uqGslVectorClass,uqGslMatrixClass>* paramDomain = ¶mSpace; //////////////////////////////////////////////////////// // Step 3 of 5: Instantiate the likelihood function object //////////////////////////////////////////////////////// unsigned int nAll = 100000; uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> dataSpaceAll(env, "data_", nAll, NULL); double sigmaTotal = bVec[0]/2.; std::set<unsigned int> tmpSet; tmpSet.insert(env.subId()); uqGslVectorClass ySamplesAll(dataSpaceAll.zeroVector()); ySamplesAll.subReadContents("input/dataPoints", "m", tmpSet); unsigned int numCases = 5; std::vector<unsigned int> ns(numCases,0); ns[0] = 1; ns[1] = 10; ns[2] = 100; ns[3] = 500; ns[4] = 1000; for (unsigned int caseId = 0; caseId < numCases; ++caseId) { uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> dataSpace(env, "data_", ns[caseId], NULL); uqGslVectorClass ySamples(dataSpace.zeroVector()); for (unsigned int i = 0; i < ns[caseId]; ++i) { ySamples[i] = ySamplesAll[i]; } struct likelihoodDataStruct likelihoodData; likelihoodData.bVec = &bVec; likelihoodData.sigmaTotal = sigmaTotal; likelihoodData.ySamples = &ySamples; uqGenericScalarFunctionClass<uqGslVectorClass,uqGslMatrixClass> likelihoodFunctionObj("like_", *paramDomain, likelihoodRoutine, (void *) &likelihoodData, true); // routine computes [ln(function)] //////////////////////////////////////////////////////// // Step 4 of 5: Instantiate the inverse problem //////////////////////////////////////////////////////// uqUniformVectorRVClass<uqGslVectorClass,uqGslMatrixClass> priorRv("prior_", *paramDomain); uqGenericVectorRVClass<uqGslVectorClass,uqGslMatrixClass> postRv ("post_", paramSpace); char prefixStr[16+1]; sprintf(prefixStr,"sip%d_",caseId+1); uqStatisticalInverseProblemClass<uqGslVectorClass,uqGslMatrixClass> sip(prefixStr, NULL, priorRv, likelihoodFunctionObj, postRv); if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "In solveSip():" << "\n caseId = " << caseId << "\n prefixStr = " << prefixStr << "\n p = " << p << "\n bVec = " << bVec << "\n ns[caseId] = " << ns[caseId] << "\n sigmaTotal = " << sigmaTotal << "\n ySamples = " << ySamples << "\n useML = " << useML << std::endl; } //////////////////////////////////////////////////////// // Step 5 of 5: Solve the inverse problem //////////////////////////////////////////////////////// uqGslVectorClass initialValues(paramSpace.zeroVector()); initialValues[0] = 0.; uqGslMatrixClass proposalCovMat(paramSpace.zeroVector()); proposalCovMat(0,0) = 1.; if (useML) { sip.solveWithBayesMLSampling(); } else { sip.solveWithBayesMetropolisHastings(NULL,initialValues,&proposalCovMat); } } // for caseId if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "Leaving solveSip()" << std::endl; } return; }
void solveSip(const uqFullEnvironmentClass& env, bool useML) { if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "Entering solveSip()..." << std::endl; } //////////////////////////////////////////////////////// // Step 1 of 5: Instantiate the parameter space //////////////////////////////////////////////////////// unsigned int p = 1; uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> paramSpace(env, "param_", p, NULL); uqGslVectorClass aVec(paramSpace.zeroVector()); aVec[0] = 126831.7; uqGslVectorClass bVec(paramSpace.zeroVector()); bVec[0] = 112136.1; //////////////////////////////////////////////////////// // Step 2 of 5: Instantiate the parameter domain //////////////////////////////////////////////////////// //uqGslVectorClass paramMins (paramSpace.zeroVector()); //uqGslVectorClass paramMaxs (paramSpace.zeroVector()); //paramMins [0] = -1.e+16; //paramMaxs [0] = 1.e+16; //paramMins [1] = -1.e+16; //paramMaxs [1] = 1.e+16; //uqBoxSubsetClass<uqGslVectorClass,uqGslMatrixClass> paramDomain("param_",paramSpace,paramMins,paramMaxs); uqVectorSetClass<uqGslVectorClass,uqGslMatrixClass>* paramDomain = ¶mSpace; //////////////////////////////////////////////////////// // Step 3 of 5: Instantiate the likelihood function object //////////////////////////////////////////////////////// unsigned int n = 400; uqVectorSpaceClass<uqGslVectorClass,uqGslMatrixClass> dataSpace(env, "data_", n, NULL); double sigmaTotal = 4229.55; std::set<unsigned int> tmpSet; tmpSet.insert(env.subId()); uqGslVectorClass ySamples(dataSpace.zeroVector()); ySamples.subReadContents("input/dataPoints", "m", tmpSet); struct likelihoodDataStruct likelihoodData; likelihoodData.aVec = &aVec; likelihoodData.bVec = &bVec; likelihoodData.sigmaTotal = sigmaTotal; likelihoodData.ySamples = &ySamples; uqGenericScalarFunctionClass<uqGslVectorClass,uqGslMatrixClass> likelihoodFunctionObj("like_", *paramDomain, likelihoodRoutine, (void *) &likelihoodData, true); // routine computes [ln(function)] //////////////////////////////////////////////////////// // Step 4 of 5: Instantiate the inverse problem //////////////////////////////////////////////////////// uqUniformVectorRVClass<uqGslVectorClass,uqGslMatrixClass> priorRv("prior_", *paramDomain); uqGenericVectorRVClass<uqGslVectorClass,uqGslMatrixClass> postRv ("post_", paramSpace); uqStatisticalInverseProblemClass<uqGslVectorClass,uqGslMatrixClass> sip("sip_", NULL, priorRv, likelihoodFunctionObj, postRv); if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "In solveSip():" << "\n p = " << p << "\n aVec = " << aVec << "\n bVec = " << bVec << "\n n = " << n << "\n sigmaTotal = " << sigmaTotal << "\n ySamples = " << ySamples << "\n useML = " << useML << std::endl; } //////////////////////////////////////////////////////// // Step 5 of 5: Solve the inverse problem //////////////////////////////////////////////////////// uqGslVectorClass initialValues(paramSpace.zeroVector()); initialValues[0] = 0.; uqGslMatrixClass proposalCovMat(paramSpace.zeroVector()); proposalCovMat(0,0) = 1.; if (useML) { sip.solveWithBayesMLSampling(); } else { sip.solveWithBayesMetropolisHastings(NULL,initialValues,&proposalCovMat); } if ((env.subDisplayFile()) && (env.displayVerbosity() >= 2)) { *env.subDisplayFile() << "Leaving solveSip()" << std::endl; } return; }