void CPoseRandomSampler::setPosePDF(const CPose3DPDF::Ptr& pdf) { setPosePDF(pdf.get()); }
void test_icp3D() { // Create the reference objects: COpenGLScene::Ptr scene1 = mrpt::make_aligned_shared<COpenGLScene>(); COpenGLScene::Ptr scene2 = mrpt::make_aligned_shared<COpenGLScene>(); COpenGLScene::Ptr scene3 = mrpt::make_aligned_shared<COpenGLScene>(); opengl::CGridPlaneXY::Ptr plane1 = mrpt::make_aligned_shared<CGridPlaneXY>(-20, 20, -20, 20, 0, 1); plane1->setColor(0.3, 0.3, 0.3); scene1->insert(plane1); scene2->insert(plane1); scene3->insert(plane1); CSetOfObjects::Ptr world = mrpt::make_aligned_shared<CSetOfObjects>(); generateObjects(world); scene1->insert(world); // Perform the 3D scans: CAngularObservationMesh::Ptr aom1 = mrpt::make_aligned_shared<CAngularObservationMesh>(); CAngularObservationMesh::Ptr aom2 = mrpt::make_aligned_shared<CAngularObservationMesh>(); cout << "Performing ray-tracing..." << endl; CAngularObservationMesh::trace2DSetOfRays( scene1, viewpoint1, aom1, CAngularObservationMesh::TDoubleRange::CreateFromAperture( M_PI, HOW_MANY_PITCHS), CAngularObservationMesh::TDoubleRange::CreateFromAperture( M_PI, HOW_MANY_YAWS)); CAngularObservationMesh::trace2DSetOfRays( scene1, viewpoint2, aom2, CAngularObservationMesh::TDoubleRange::CreateFromAperture( M_PI, HOW_MANY_PITCHS), CAngularObservationMesh::TDoubleRange::CreateFromAperture( M_PI, HOW_MANY_YAWS)); cout << "Ray-tracing done" << endl; // Put the viewpoints origins: { CSetOfObjects::Ptr origin1 = opengl::stock_objects::CornerXYZ(); origin1->setPose(viewpoint1); origin1->setScale(0.6); scene1->insert(origin1); scene2->insert(origin1); } { CSetOfObjects::Ptr origin2 = opengl::stock_objects::CornerXYZ(); origin2->setPose(viewpoint2); origin2->setScale(0.6); scene1->insert(origin2); scene2->insert(origin2); } // Show the scanned points: CSimplePointsMap M1, M2; aom1->generatePointCloud(&M1); aom2->generatePointCloud(&M2); // Create the wrongly-localized M2: CSimplePointsMap M2_noisy; M2_noisy = M2; M2_noisy.changeCoordinatesReference(SCAN2_POSE_ERROR); CSetOfObjects::Ptr PTNS1 = mrpt::make_aligned_shared<CSetOfObjects>(); CSetOfObjects::Ptr PTNS2 = mrpt::make_aligned_shared<CSetOfObjects>(); CPointsMap::COLOR_3DSCENE(mrpt::utils::TColorf(1, 0, 0)); M1.getAs3DObject(PTNS1); CPointsMap::COLOR_3DSCENE(mrpt::utils::TColorf(0, 0, 1)); M2_noisy.getAs3DObject(PTNS2); scene2->insert(PTNS1); scene2->insert(PTNS2); // -------------------------------------- // Do the ICP-3D // -------------------------------------- float run_time; CICP icp; CICP::TReturnInfo icp_info; icp.options.thresholdDist = 0.40; icp.options.thresholdAng = 0; std::vector<double> xs, ys, zs; M1.getAllPoints(xs, ys, ys); cout << "Size of xs in M1: " << xs.size() << endl; M2.getAllPoints(xs, ys, ys); cout << "Size of xs in M2: " << xs.size() << endl; CPose3DPDF::Ptr pdf = icp.Align3D( &M2_noisy, // Map to align &M1, // Reference map CPose3D(), // Initial gross estimate &run_time, &icp_info); CPose3D mean = pdf->getMeanVal(); cout << "ICP run took " << run_time << " secs." << endl; cout << "Goodness: " << 100 * icp_info.goodness << "% , # of iterations= " << icp_info.nIterations << " Quality: " << icp_info.quality << endl; cout << "ICP output: mean= " << mean << endl; cout << "Real displacement: " << SCAN2_POSE_ERROR << endl; // Aligned maps: CSetOfObjects::Ptr PTNS2_ALIGN = mrpt::make_aligned_shared<CSetOfObjects>(); M2_noisy.changeCoordinatesReference(CPose3D() - mean); M2_noisy.getAs3DObject(PTNS2_ALIGN); scene3->insert(PTNS1); scene3->insert(PTNS2_ALIGN); // Show in Windows: CDisplayWindow3D window("ICP-3D demo: scene", 500, 500); CDisplayWindow3D window2("ICP-3D demo: UNALIGNED scans", 500, 500); CDisplayWindow3D window3("ICP-3D demo: ICP-ALIGNED scans", 500, 500); window.setPos(10, 10); window2.setPos(530, 10); window3.setPos(10, 520); window.get3DSceneAndLock() = scene1; window.unlockAccess3DScene(); window2.get3DSceneAndLock() = scene2; window2.unlockAccess3DScene(); window3.get3DSceneAndLock() = scene3; window3.unlockAccess3DScene(); std::this_thread::sleep_for(20ms); window.forceRepaint(); window2.forceRepaint(); window.setCameraElevationDeg(15); window.setCameraAzimuthDeg(90); window.setCameraZoom(15); window2.setCameraElevationDeg(15); window2.setCameraAzimuthDeg(90); window2.setCameraZoom(15); window3.setCameraElevationDeg(15); window3.setCameraAzimuthDeg(90); window3.setCameraZoom(15); cout << "Press any key to exit..." << endl; window.waitForKey(); }
void ICPslamWrapper::run3Dwindow() { // Create 3D window if requested (the code is copied from ../mrpt/apps/icp-slam/icp-slam_main.cpp): if (SHOW_PROGRESS_3D_REAL_TIME && win3D_) { // get currently builded map metric_map_ = mapBuilder.getCurrentlyBuiltMetricMap(); lst_current_laser_scans.clear(); CPose3D robotPose; mapBuilder.getCurrentPoseEstimation()->getMean(robotPose); COpenGLScene::Ptr scene = COpenGLScene::Create(); COpenGLViewport::Ptr view = scene->getViewport("main"); COpenGLViewport::Ptr view_map = scene->createViewport("mini-map"); view_map->setBorderSize(2); view_map->setViewportPosition(0.01, 0.01, 0.35, 0.35); view_map->setTransparent(false); { mrpt::opengl::CCamera &cam = view_map->getCamera(); cam.setAzimuthDegrees(-90); cam.setElevationDegrees(90); cam.setPointingAt(robotPose); cam.setZoomDistance(20); cam.setOrthogonal(); } // The ground: mrpt::opengl::CGridPlaneXY::Ptr groundPlane = mrpt::opengl::CGridPlaneXY::Create(-200, 200, -200, 200, 0, 5); groundPlane->setColor(0.4, 0.4, 0.4); view->insert(groundPlane); view_map->insert(CRenderizable::Ptr(groundPlane)); // A copy // The camera pointing to the current robot pose: if (CAMERA_3DSCENE_FOLLOWS_ROBOT) { scene->enableFollowCamera(true); mrpt::opengl::CCamera &cam = view_map->getCamera(); cam.setAzimuthDegrees(-45); cam.setElevationDegrees(45); cam.setPointingAt(robotPose); } // The maps: { opengl::CSetOfObjects::Ptr obj = opengl::CSetOfObjects::Create(); metric_map_->getAs3DObject(obj); view->insert(obj); // Only the point map: opengl::CSetOfObjects::Ptr ptsMap = opengl::CSetOfObjects::Create(); if (metric_map_->m_pointsMaps.size()) { metric_map_->m_pointsMaps[0]->getAs3DObject(ptsMap); view_map->insert(ptsMap); } } // Draw the robot path: CPose3DPDF::Ptr posePDF = mapBuilder.getCurrentPoseEstimation(); CPose3D curRobotPose; posePDF->getMean(curRobotPose); { opengl::CSetOfObjects::Ptr obj = opengl::stock_objects::RobotPioneer(); obj->setPose(curRobotPose); view->insert(obj); } { opengl::CSetOfObjects::Ptr obj = opengl::stock_objects::RobotPioneer(); obj->setPose(curRobotPose); view_map->insert(obj); } opengl::COpenGLScene::Ptr &ptrScene = win3D_->get3DSceneAndLock(); ptrScene = scene; win3D_->unlockAccess3DScene(); // Move camera: win3D_->setCameraPointingToPoint(curRobotPose.x(), curRobotPose.y(), curRobotPose.z()); // Update: win3D_->forceRepaint(); // Build list of scans: if (SHOW_LASER_SCANS_3D) { // Rawlog in "Observation-only" format: if (isObsBasedRawlog) { if (IS_CLASS(observation, CObservation2DRangeScan)) { lst_current_laser_scans.push_back(mrpt::ptr_cast<CObservation2DRangeScan>::from(observation)); } } else { // Rawlog in the Actions-SF format: for (size_t i = 0;; i++) { CObservation2DRangeScan::Ptr new_obs = observations->getObservationByClass<CObservation2DRangeScan>(i); if (!new_obs) break; // There're no more scans else lst_current_laser_scans.push_back(new_obs); } } } // Draw laser scanners in 3D: if (SHOW_LASER_SCANS_3D) { for (size_t i = 0; i < lst_current_laser_scans.size(); i++) { // Create opengl object and load scan data from the scan observation: opengl::CPlanarLaserScan::Ptr obj = opengl::CPlanarLaserScan::Create(); obj->setScan(*lst_current_laser_scans[i]); obj->setPose(curRobotPose); obj->setSurfaceColor(1.0f, 0.0f, 0.0f, 0.5f); // inser into the scene: view->insert(obj); } } } }
// ------------------------------------------------------ // MapBuilding_ICP // override_rawlog_file: If not empty, use that rawlog // instead of that in the config file. // ------------------------------------------------------ void MapBuilding_ICP( const string& INI_FILENAME, const string& override_rawlog_file) { MRPT_START CConfigFile iniFile(INI_FILENAME); // ------------------------------------------ // Load config from file: // ------------------------------------------ const string RAWLOG_FILE = !override_rawlog_file.empty() ? override_rawlog_file : iniFile.read_string( "MappingApplication", "rawlog_file", "", /*Force existence:*/ true); const unsigned int rawlog_offset = iniFile.read_int( "MappingApplication", "rawlog_offset", 0, /*Force existence:*/ true); const string OUT_DIR_STD = iniFile.read_string( "MappingApplication", "logOutput_dir", "log_out", /*Force existence:*/ true); const int LOG_FREQUENCY = iniFile.read_int( "MappingApplication", "LOG_FREQUENCY", 5, /*Force existence:*/ true); const bool SAVE_POSE_LOG = iniFile.read_bool( "MappingApplication", "SAVE_POSE_LOG", false, /*Force existence:*/ true); const bool SAVE_3D_SCENE = iniFile.read_bool( "MappingApplication", "SAVE_3D_SCENE", false, /*Force existence:*/ true); const bool CAMERA_3DSCENE_FOLLOWS_ROBOT = iniFile.read_bool( "MappingApplication", "CAMERA_3DSCENE_FOLLOWS_ROBOT", true, /*Force existence:*/ true); bool SHOW_PROGRESS_3D_REAL_TIME = false; int SHOW_PROGRESS_3D_REAL_TIME_DELAY_MS = 0; bool SHOW_LASER_SCANS_3D = true; MRPT_LOAD_CONFIG_VAR( SHOW_PROGRESS_3D_REAL_TIME, bool, iniFile, "MappingApplication"); MRPT_LOAD_CONFIG_VAR( SHOW_LASER_SCANS_3D, bool, iniFile, "MappingApplication"); MRPT_LOAD_CONFIG_VAR( SHOW_PROGRESS_3D_REAL_TIME_DELAY_MS, int, iniFile, "MappingApplication"); const char* OUT_DIR = OUT_DIR_STD.c_str(); // ------------------------------------ // Constructor of ICP-SLAM object // ------------------------------------ CMetricMapBuilderICP mapBuilder; mapBuilder.ICP_options.loadFromConfigFile(iniFile, "MappingApplication"); mapBuilder.ICP_params.loadFromConfigFile(iniFile, "ICP"); // Construct the maps with the loaded configuration. mapBuilder.initialize(); // --------------------------------- // CMetricMapBuilder::TOptions // --------------------------------- mapBuilder.setVerbosityLevel(LVL_DEBUG); mapBuilder.options.alwaysInsertByClass.fromString( iniFile.read_string("MappingApplication", "alwaysInsertByClass", "")); // Print params: printf("Running with the following parameters:\n"); printf(" RAWLOG file:'%s'\n", RAWLOG_FILE.c_str()); printf(" Output directory:\t\t\t'%s'\n", OUT_DIR); printf( " matchAgainstTheGrid:\t\t\t%c\n", mapBuilder.ICP_options.matchAgainstTheGrid ? 'Y' : 'N'); printf(" Log record freq:\t\t\t%u\n", LOG_FREQUENCY); printf(" SAVE_3D_SCENE:\t\t\t%c\n", SAVE_3D_SCENE ? 'Y' : 'N'); printf(" SAVE_POSE_LOG:\t\t\t%c\n", SAVE_POSE_LOG ? 'Y' : 'N'); printf( " CAMERA_3DSCENE_FOLLOWS_ROBOT:\t%c\n", CAMERA_3DSCENE_FOLLOWS_ROBOT ? 'Y' : 'N'); printf("\n"); mapBuilder.ICP_params.dumpToConsole(); mapBuilder.ICP_options.dumpToConsole(); // Checks: ASSERT_(RAWLOG_FILE.size() > 0) ASSERT_FILE_EXISTS_(RAWLOG_FILE) CTicTac tictac, tictacGlobal, tictac_JH; int step = 0; string str; CSimpleMap finalMap; float t_exec; COccupancyGridMap2D::TEntropyInfo entropy; size_t rawlogEntry = 0; CFileGZInputStream rawlogFile(RAWLOG_FILE.c_str()); // Prepare output directory: // -------------------------------- deleteFilesInDirectory(OUT_DIR); createDirectory(OUT_DIR); // Open log files: // ---------------------------------- CFileOutputStream f_log(format("%s/log_times.txt", OUT_DIR)); CFileOutputStream f_path(format("%s/log_estimated_path.txt", OUT_DIR)); CFileOutputStream f_pathOdo(format("%s/log_odometry_path.txt", OUT_DIR)); // Create 3D window if requested: CDisplayWindow3D::Ptr win3D; #if MRPT_HAS_WXWIDGETS if (SHOW_PROGRESS_3D_REAL_TIME) { win3D = mrpt::make_aligned_shared<CDisplayWindow3D>( "ICP-SLAM @ MRPT C++ Library", 600, 500); win3D->setCameraZoom(20); win3D->setCameraAzimuthDeg(-45); } #endif // ---------------------------------------------------------- // Map Building // ---------------------------------------------------------- CPose2D odoPose(0, 0, 0); tictacGlobal.Tic(); for (;;) { CActionCollection::Ptr action; CSensoryFrame::Ptr observations; CObservation::Ptr observation; if (os::kbhit()) { char c = os::getch(); if (c == 27) break; } // Load action/observation pair from the rawlog: // -------------------------------------------------- if (!CRawlog::getActionObservationPairOrObservation( rawlogFile, action, observations, observation, rawlogEntry)) break; // file EOF const bool isObsBasedRawlog = observation ? true : false; std::vector<mrpt::obs::CObservation2DRangeScan::Ptr> lst_current_laser_scans; // Just for drawing in 3D views if (rawlogEntry >= rawlog_offset) { // Update odometry: if (isObsBasedRawlog) { static CPose2D lastOdo; static bool firstOdo = true; if (IS_CLASS(observation, CObservationOdometry)) { CObservationOdometry::Ptr o = std::dynamic_pointer_cast<CObservationOdometry>( observation); if (!firstOdo) odoPose = odoPose + (o->odometry - lastOdo); lastOdo = o->odometry; firstOdo = false; } } else { CActionRobotMovement2D::Ptr act = action->getBestMovementEstimation(); if (act) odoPose = odoPose + act->poseChange->getMeanVal(); } // Build list of scans: if (SHOW_LASER_SCANS_3D) { // Rawlog in "Observation-only" format: if (isObsBasedRawlog) { if (IS_CLASS(observation, CObservation2DRangeScan)) { lst_current_laser_scans.push_back( std::dynamic_pointer_cast<CObservation2DRangeScan>( observation)); } } else { // Rawlog in the Actions-SF format: for (size_t i = 0;; i++) { CObservation2DRangeScan::Ptr new_obs = observations->getObservationByClass< CObservation2DRangeScan>(i); if (!new_obs) break; // There're no more scans else lst_current_laser_scans.push_back(new_obs); } } } // Execute: // ---------------------------------------- tictac.Tic(); if (isObsBasedRawlog) mapBuilder.processObservation(observation); else mapBuilder.processActionObservation(*action, *observations); t_exec = tictac.Tac(); printf("Map building executed in %.03fms\n", 1000.0f * t_exec); // Info log: // ----------- f_log.printf( "%f %i\n", 1000.0f * t_exec, mapBuilder.getCurrentlyBuiltMapSize()); const CMultiMetricMap* mostLikMap = mapBuilder.getCurrentlyBuiltMetricMap(); if (0 == (step % LOG_FREQUENCY)) { // Pose log: // ------------- if (SAVE_POSE_LOG) { printf("Saving pose log information..."); mapBuilder.getCurrentPoseEstimation()->saveToTextFile( format("%s/mapbuild_posepdf_%03u.txt", OUT_DIR, step)); printf("Ok\n"); } } // Save a 3D scene view of the mapping process: if (0 == (step % LOG_FREQUENCY) || (SAVE_3D_SCENE || win3D)) { CPose3D robotPose; mapBuilder.getCurrentPoseEstimation()->getMean(robotPose); COpenGLScene::Ptr scene = mrpt::make_aligned_shared<COpenGLScene>(); COpenGLViewport::Ptr view = scene->getViewport("main"); ASSERT_(view); COpenGLViewport::Ptr view_map = scene->createViewport("mini-map"); view_map->setBorderSize(2); view_map->setViewportPosition(0.01, 0.01, 0.35, 0.35); view_map->setTransparent(false); { mrpt::opengl::CCamera& cam = view_map->getCamera(); cam.setAzimuthDegrees(-90); cam.setElevationDegrees(90); cam.setPointingAt(robotPose); cam.setZoomDistance(20); cam.setOrthogonal(); } // The ground: mrpt::opengl::CGridPlaneXY::Ptr groundPlane = mrpt::make_aligned_shared<mrpt::opengl::CGridPlaneXY>( -200, 200, -200, 200, 0, 5); groundPlane->setColor(0.4, 0.4, 0.4); view->insert(groundPlane); view_map->insert(CRenderizable::Ptr(groundPlane)); // A copy // The camera pointing to the current robot pose: if (CAMERA_3DSCENE_FOLLOWS_ROBOT) { scene->enableFollowCamera(true); mrpt::opengl::CCamera& cam = view_map->getCamera(); cam.setAzimuthDegrees(-45); cam.setElevationDegrees(45); cam.setPointingAt(robotPose); } // The maps: { opengl::CSetOfObjects::Ptr obj = mrpt::make_aligned_shared<opengl::CSetOfObjects>(); mostLikMap->getAs3DObject(obj); view->insert(obj); // Only the point map: opengl::CSetOfObjects::Ptr ptsMap = mrpt::make_aligned_shared<opengl::CSetOfObjects>(); if (mostLikMap->m_pointsMaps.size()) { mostLikMap->m_pointsMaps[0]->getAs3DObject(ptsMap); view_map->insert(ptsMap); } } // Draw the robot path: CPose3DPDF::Ptr posePDF = mapBuilder.getCurrentPoseEstimation(); CPose3D curRobotPose; posePDF->getMean(curRobotPose); { opengl::CSetOfObjects::Ptr obj = opengl::stock_objects::RobotPioneer(); obj->setPose(curRobotPose); view->insert(obj); } { opengl::CSetOfObjects::Ptr obj = opengl::stock_objects::RobotPioneer(); obj->setPose(curRobotPose); view_map->insert(obj); } // Draw laser scanners in 3D: if (SHOW_LASER_SCANS_3D) { for (size_t i = 0; i < lst_current_laser_scans.size(); i++) { // Create opengl object and load scan data from the scan // observation: opengl::CPlanarLaserScan::Ptr obj = mrpt::make_aligned_shared< opengl::CPlanarLaserScan>(); obj->setScan(*lst_current_laser_scans[i]); obj->setPose(curRobotPose); obj->setSurfaceColor(1.0f, 0.0f, 0.0f, 0.5f); // inser into the scene: view->insert(obj); } } // Save as file: if (0 == (step % LOG_FREQUENCY) && SAVE_3D_SCENE) { CFileGZOutputStream f( format("%s/buildingmap_%05u.3Dscene", OUT_DIR, step)); f << *scene; } // Show 3D? if (win3D) { opengl::COpenGLScene::Ptr& ptrScene = win3D->get3DSceneAndLock(); ptrScene = scene; win3D->unlockAccess3DScene(); // Move camera: win3D->setCameraPointingToPoint( curRobotPose.x(), curRobotPose.y(), curRobotPose.z()); // Update: win3D->forceRepaint(); std::this_thread::sleep_for( std::chrono::milliseconds( SHOW_PROGRESS_3D_REAL_TIME_DELAY_MS)); } } // Save the memory usage: // ------------------------------------------------------------------ { printf("Saving memory usage..."); unsigned long memUsage = getMemoryUsage(); FILE* f = os::fopen( format("%s/log_MemoryUsage.txt", OUT_DIR).c_str(), "at"); if (f) { os::fprintf(f, "%u\t%lu\n", step, memUsage); os::fclose(f); } printf("Ok! (%.04fMb)\n", ((float)memUsage) / (1024 * 1024)); } // Save the robot estimated pose for each step: f_path.printf( "%i %f %f %f\n", step, mapBuilder.getCurrentPoseEstimation()->getMeanVal().x(), mapBuilder.getCurrentPoseEstimation()->getMeanVal().y(), mapBuilder.getCurrentPoseEstimation()->getMeanVal().yaw()); f_pathOdo.printf( "%i %f %f %f\n", step, odoPose.x(), odoPose.y(), odoPose.phi()); } // end of if "rawlog_offset"... step++; printf( "\n---------------- STEP %u | RAWLOG ENTRY %u ----------------\n", step, (unsigned)rawlogEntry); }; printf( "\n---------------- END!! (total time: %.03f sec) ----------------\n", tictacGlobal.Tac()); // Save map: mapBuilder.getCurrentlyBuiltMap(finalMap); str = format("%s/_finalmap_.simplemap", OUT_DIR); printf("Dumping final map in binary format to: %s\n", str.c_str()); mapBuilder.saveCurrentMapToFile(str); const CMultiMetricMap* finalPointsMap = mapBuilder.getCurrentlyBuiltMetricMap(); str = format("%s/_finalmaps_.txt", OUT_DIR); printf("Dumping final metric maps to %s_XXX\n", str.c_str()); finalPointsMap->saveMetricMapRepresentationToFile(str); if (win3D) win3D->waitForKey(); MRPT_END }