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9d6f388809
New LevMarq implementation * Hash TSDF fix: apply volume pose when fetching pose * DualQuat minor fix * Pose Graph: getEdgePose(), getEdgeInfo() * debugging code for pose graph * add edge to submap * pose averaging: DualQuats instead of matrix averaging * overlapping ratio: rise it up; minor comment * remove `Submap::addEdgeToSubmap` * test_pose_graph: minor * SparseBlockMatrix: support 1xN as well as Nx1 for residual vector * small changes to old LMSolver * new LevMarq impl * Pose Graph rewritten to use new impl * solvePnP(), findHomography() and findExtrinsicCameraParams2() use new impl * estimateAffine...2D() use new impl * calibration and stereo calibration use new impl * BundleAdjusterBase::estimate() uses new impl * new LevMarq interface * PoseGraph: changing opt interface * findExtrinsicCameraParams2(): opt interface updated * HomographyRefine: opt interface updated * solvePnPRefine opt interface fixed * Affine2DRefine opt interface fixed * BundleAdjuster::estimate() opt interface fixed * calibration: opt interface fixed + code refactored a little * minor warning fixes * geodesic acceleration, Impl -> Backend rename * calcFunc() always uses probe vars * solveDecomposed, fixing negation * fixing geodesic acceleration + minors * PoseGraph exposes its optimizer now + its tests updated to check better convegence * Rosenbrock test added for LevMarq * LevMarq params upgraded * Rosenbrock can do better * fixing stereo calibration * old implementation removed (as well as debug code) * more debugging code removed * fix warnings * fixing warnings * fixing Eigen dependency * trying to fix Eigen deps * debugging code for submat is now temporary * trying to fix Eigen dependency * relax sanity check for solvePnP * relaxing sanity check even more * trying to fix Eigen dependency * warning fix * Quat<T>: fixing warnings * more warning fixes * fixed warning * fixing *KinFu OCL tests * algo params -> struct Settings * Backend moved to details * BaseLevMarq -> LevMarqBase * detail/pose_graph.hpp -> detail/optimizer.hpp * fixing include stuff for details/optimizer.hpp * doc fix * LevMarqBase rework: Settings, pImpl, Backend * Impl::settings and ::backend fix * HashTSDFGPU fix * fixing compilation * warning fix for OdometryFrameImplTMat * docs fix + compile warnings * remake: new class LevMarq with pImpl and enums, LevMarqBase => detail, no Backend class, Settings() => .cpp, Settings==() removed, Settings.set...() inlines * fixing warnings & whitespace
445 lines
13 KiB
C++
445 lines
13 KiB
C++
// This file is part of OpenCV project.
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// It is subject to the license terms in the LICENSE file found in the top-level directory
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// of this distribution and at http://opencv.org/license.html
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#include "test_precomp.hpp"
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#include <opencv2/3d/detail/optimizer.hpp>
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#include <opencv2/core/dualquaternion.hpp>
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namespace opencv_test { namespace {
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using namespace cv;
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#ifdef HAVE_EIGEN
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static Affine3d readAffine(std::istream& input)
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{
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Vec3d p;
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Vec4d q;
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input >> p[0] >> p[1] >> p[2];
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input >> q[1] >> q[2] >> q[3] >> q[0];
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// Normalize the quaternion to account for precision loss due to
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// serialization.
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return Affine3d(Quatd(q).toRotMat3x3(), p);
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};
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// Rewritten from Ceres pose graph demo: https://ceres-solver.org/
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static Ptr<detail::PoseGraph> readG2OFile(const std::string& g2oFileName)
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{
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Ptr<detail::PoseGraph> pg = detail::PoseGraph::create();
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// for debugging purposes
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size_t minId = 0, maxId = 1 << 30;
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std::ifstream infile(g2oFileName.c_str());
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if (!infile)
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{
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CV_Error(cv::Error::StsError, "failed to open file");
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}
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while (infile.good())
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{
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std::string data_type;
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// Read whether the type is a node or a constraint
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infile >> data_type;
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if (data_type == "VERTEX_SE3:QUAT")
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{
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size_t id;
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infile >> id;
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Affine3d pose = readAffine(infile);
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if (id < minId || id >= maxId)
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continue;
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bool fixed = (id == minId);
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// Ensure we don't have duplicate poses
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if (pg->isNodeExist(id))
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{
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CV_LOG_INFO(NULL, "duplicated node, id=" << id);
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}
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pg->addNode(id, pose, fixed);
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}
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else if (data_type == "EDGE_SE3:QUAT")
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{
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size_t startId, endId;
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infile >> startId >> endId;
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Affine3d pose = readAffine(infile);
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Matx66d info;
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for (int i = 0; i < 6 && infile.good(); ++i)
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{
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for (int j = i; j < 6 && infile.good(); ++j)
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{
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infile >> info(i, j);
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if (i != j)
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{
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info(j, i) = info(i, j);
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}
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}
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}
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if ((startId >= minId && startId < maxId) && (endId >= minId && endId < maxId))
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{
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pg->addEdge(startId, endId, pose, info);
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}
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}
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else
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{
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CV_Error(cv::Error::StsError, "unknown tag");
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}
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// Clear any trailing whitespace from the line
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infile >> std::ws;
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}
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return pg;
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}
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TEST(PoseGraph, sphereG2O)
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{
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// Test takes 15+ sec in Release mode and 400+ sec in Debug mode
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applyTestTag(CV_TEST_TAG_LONG, CV_TEST_TAG_DEBUG_VERYLONG);
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// The dataset was taken from here: https://lucacarlone.mit.edu/datasets/
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// Connected paper:
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// L.Carlone, R.Tron, K.Daniilidis, and F.Dellaert.
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// Initialization Techniques for 3D SLAM : a Survey on Rotation Estimation and its Use in Pose Graph Optimization.
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// In IEEE Intl.Conf.on Robotics and Automation(ICRA), pages 4597 - 4604, 2015.
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std::string filename = cvtest::TS::ptr()->get_data_path() + "/cv/rgbd/sphere_bignoise_vertex3.g2o";
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Ptr<detail::PoseGraph> pg = readG2OFile(filename);
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// You may change logging level to view detailed optimization report
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// For example, set env. variable like this: OPENCV_LOG_LEVEL=INFO
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// geoScale=1 is experimental, not guaranteed to work on other problems
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// the rest are default params
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pg->createOptimizer(LevMarq::Settings().setGeoScale(1.0)
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.setMaxIterations(100)
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.setCheckRelEnergyChange(true)
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.setRelEnergyDeltaTolerance(1e-6)
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.setGeodesic(true));
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auto r = pg->optimize();
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EXPECT_TRUE(r.found);
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EXPECT_LE(r.iters, 20); // should converge in 31 iterations
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EXPECT_LE(r.energy, 1.47723e+06); // should converge to 1.47722e+06 or less
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// Add the "--test_debug" to arguments to see resulting pose graph nodes positions
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if (cvtest::debugLevel > 0)
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{
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// Write edge-only model of how nodes are located in space
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std::string fname = "pgout.obj";
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std::fstream of(fname, std::fstream::out);
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std::vector<size_t> ids = pg->getNodesIds();
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for (const size_t& id : ids)
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{
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Point3d d = pg->getNodePose(id).translation();
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of << "v " << d.x << " " << d.y << " " << d.z << std::endl;
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}
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size_t esz = pg->getNumEdges();
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for (size_t i = 0; i < esz; i++)
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{
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size_t sid = pg->getEdgeStart(i), tid = pg->getEdgeEnd(i);
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of << "l " << sid + 1 << " " << tid + 1 << std::endl;
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}
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of.close();
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}
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}
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// ------------------------------------------------------------------------------------------
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// Wireframe meshes for debugging visualization purposes
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struct Mesh
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{
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std::vector<Point3f> pts;
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std::vector<Vec2i> lines;
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Mesh join(const Mesh& m2) const
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{
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Mesh mo;
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size_t sz1 = this->pts.size();
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std::copy(this->pts.begin(), this->pts.end(), std::back_inserter(mo.pts));
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std::copy(m2.pts.begin(), m2.pts.end(), std::back_inserter(mo.pts));
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std::copy(this->lines.begin(), this->lines.end(), std::back_inserter(mo.lines));
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std::transform(m2.lines.begin(), m2.lines.end(), std::back_inserter(mo.lines),
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[sz1](Vec2i ab) { return Vec2i(ab[0] + (int)sz1, ab[1] + (int)sz1); });
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return mo;
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}
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Mesh transform(Affine3f a, float scale = 1.f) const
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{
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Mesh out;
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out.lines = this->lines;
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for (Point3f p : this->pts)
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{
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out.pts.push_back(a * (p * scale));
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}
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return out;
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}
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// 0-2 - min, 3-5 - max
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Vec6f getBoundingBox() const
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{
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float maxv = std::numeric_limits<float>::max();
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Vec3f xmin(maxv, maxv, maxv), xmax(-maxv, -maxv, -maxv);
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for (Point3f p : this->pts)
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{
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xmin[0] = min(p.x, xmin[0]); xmin[1] = min(p.y, xmin[1]); xmin[2] = min(p.z, xmin[2]);
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xmax[0] = max(p.x, xmax[0]); xmax[1] = max(p.y, xmax[1]); xmax[2] = max(p.z, xmax[2]);
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}
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return Vec6f(xmin[0], xmin[1], xmin[2], xmax[0], xmax[1], xmax[2]);
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}
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};
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Mesh seg7(int d)
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{
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const std::vector<Point3f> pt = { {0, 0, 0}, {0, 1, 0},
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{1, 0, 0}, {1, 1, 0},
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{2, 0, 0}, {2, 1, 0} };
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std::vector<Mesh> seg(7);
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seg[0].pts = { pt[0], pt[1] };
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seg[1].pts = { pt[1], pt[3] };
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seg[2].pts = { pt[3], pt[5] };
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seg[3].pts = { pt[5], pt[4] };
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seg[4].pts = { pt[4], pt[2] };
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seg[5].pts = { pt[2], pt[0] };
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seg[6].pts = { pt[2], pt[3] };
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for (int i = 0; i < 7; i++)
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seg[i].lines = { {0, 1} };
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vector<Mesh> digits = {
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seg[0].join(seg[1]).join(seg[2]).join(seg[3]).join(seg[4]).join(seg[5]), // 0
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seg[1].join(seg[2]), // 1
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seg[0].join(seg[1]).join(seg[3]).join(seg[4]).join(seg[6]), // 2
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seg[0].join(seg[1]).join(seg[2]).join(seg[3]).join(seg[6]), // 3
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seg[1].join(seg[2]).join(seg[5]).join(seg[6]), // 4
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seg[0].join(seg[2]).join(seg[3]).join(seg[5]).join(seg[6]), // 5
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seg[0].join(seg[2]).join(seg[3]).join(seg[4]).join(seg[5]).join(seg[6]), // 6
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seg[0].join(seg[1]).join(seg[2]), // 7
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seg[0].join(seg[1]).join(seg[2]).join(seg[3]).join(seg[4]).join(seg[5]).join(seg[6]), // 8
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seg[0].join(seg[1]).join(seg[2]).join(seg[3]).join(seg[5]).join(seg[6]), // 9
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seg[6], // -
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};
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return digits[d];
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}
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Mesh drawId(size_t x)
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{
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vector<int> digits;
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do
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{
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digits.push_back(x % 10);
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x /= 10;
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}
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while (x > 0);
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float spacing = 0.2f;
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Mesh m;
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for (size_t i = 0; i < digits.size(); i++)
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{
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Mesh digit = seg7(digits[digits.size() - 1 - i]);
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Vec6f bb = digit.getBoundingBox();
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digit = digit.transform(Affine3f().translate(-Vec3f(0, bb[1], 0)));
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Vec3f tr;
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if (m.pts.empty())
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tr = Vec3f();
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else
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tr = Vec3f(0, (m.getBoundingBox()[4] + spacing), 0);
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m = m.join(digit.transform( Affine3f().translate(tr) ));
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}
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return m;
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}
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Mesh drawFromTo(size_t f, size_t t)
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{
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Mesh m;
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Mesh df = drawId(f);
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Mesh dp = seg7(10);
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Mesh dt = drawId(t);
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float spacing = 0.2f;
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m = m.join(df).join(dp.transform(Affine3f().translate(Vec3f(0, df.getBoundingBox()[4] + spacing, 0))))
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.join(dt.transform(Affine3f().translate(Vec3f(0, df.getBoundingBox()[4] + 2*spacing + 1, 0))));
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return m;
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}
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Mesh drawPoseGraph(Ptr<detail::PoseGraph> pg)
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{
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Mesh marker;
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marker.pts = { {0, 0, 0}, {1, 0, 0}, {0, 1, 0}, {0, 0, 1}, {1, 1, 0} };
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marker.lines = { {0, 1}, {0, 2}, {0, 3}, {1, 4} };
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Mesh allMeshes;
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Affine3f margin = Affine3f().translate(Vec3f(0.1f, 0.1f, 0));
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std::vector<size_t> ids = pg->getNodesIds();
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for (const size_t& id : ids)
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{
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Affine3f pose = pg->getNodePose(id);
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Mesh m = marker.join(drawId(id).transform(margin, 0.25f)).transform(pose);
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allMeshes = allMeshes.join(m);
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}
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// edges
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margin = Affine3f().translate(Vec3f(0.05f, 0.05f, 0));
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for (size_t i = 0; i < pg->getNumEdges(); i++)
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{
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Affine3f pose = pg->getEdgePose(i);
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size_t sid = pg->getEdgeStart(i);
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size_t did = pg->getEdgeEnd(i);
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Affine3f spose = pg->getNodePose(sid);
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Affine3f dpose = spose * pose;
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Mesh m = marker.join(drawFromTo(sid, did).transform(margin, 0.125f)).transform(dpose);
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allMeshes = allMeshes.join(m);
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}
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return allMeshes;
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}
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void writeObj(const std::string& fname, const Mesh& m)
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{
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// Write edge-only model of how nodes are located in space
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std::fstream of(fname, std::fstream::out);
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for (const Point3f& d : m.pts)
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{
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of << "v " << d.x << " " << d.y << " " << d.z << std::endl;
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}
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for (const Vec2i& v : m.lines)
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{
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of << "l " << v[0] + 1 << " " << v[1] + 1 << std::endl;
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}
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of.close();
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}
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TEST(PoseGraph, simple)
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{
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Ptr<detail::PoseGraph> pg = detail::PoseGraph::create();
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DualQuatf true0(1, 0, 0, 0, 0, 0, 0, 0);
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DualQuatf true1 = DualQuatf::createFromPitch((float)CV_PI / 3.0f, 10.0f, Vec3f(1, 1.5f, 1.2f), Vec3f());
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DualQuatf pose0 = true0;
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vector<DualQuatf> noise(7);
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for (size_t i = 0; i < noise.size(); i++)
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{
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float angle = cv::theRNG().uniform(-1.f, 1.f);
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float shift = cv::theRNG().uniform(-2.f, 2.f);
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Matx31f axis = Vec3f::randu(0.f, 1.f), moment = Vec3f::randu(0.f, 1.f);
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noise[i] = DualQuatf::createFromPitch(angle, shift,
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Vec3f(axis(0), axis(1), axis(2)),
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Vec3f(moment(0), moment(1), moment(2)));
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}
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DualQuatf pose1 = noise[0] * true1;
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DualQuatf diff = true1 * true0.inv();
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vector<DualQuatf> cfrom = { diff, diff * noise[1], noise[2] * diff };
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DualQuatf diffInv = diff.inv();
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vector<DualQuatf> cto = { diffInv, diffInv * noise[3], noise[4] * diffInv };
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pg->addNode(123, pose0.toAffine3(), true);
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pg->addNode(456, pose1.toAffine3(), false);
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Matx66f info = Matx66f::eye();
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for (int i = 0; i < 3; i++)
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{
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pg->addEdge(123, 456, cfrom[i].toAffine3(), info);
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pg->addEdge(456, 123, cto[i].toAffine3(), info);
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}
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Mesh allMeshes = drawPoseGraph(pg);
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// Add the "--test_debug" to arguments to see resulting pose graph nodes positions
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if (cvtest::debugLevel > 0)
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{
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writeObj("pg_simple_in.obj", allMeshes);
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}
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auto r = pg->optimize();
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Mesh after = drawPoseGraph(pg);
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// Add the "--test_debug" to arguments to see resulting pose graph nodes positions
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if (cvtest::debugLevel > 0)
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{
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writeObj("pg_simple_out.obj", after);
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}
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EXPECT_TRUE(r.found);
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}
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#else
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TEST(PoseGraph, sphereG2O)
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{
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throw SkipTestException("Build with Eigen required for pose graph optimization");
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}
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TEST(PoseGraph, simple)
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{
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throw SkipTestException("Build with Eigen required for pose graph optimization");
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}
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#endif
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TEST(LevMarq, Rosenbrock)
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{
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auto f = [](double x, double y) -> double
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{
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return (1.0 - x) * (1.0 - x) + 100.0 * (y - x * x) * (y - x * x);
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};
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auto j = [](double x, double y) -> Matx12d
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{
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return {/*dx*/ -2.0 + 2.0 * x - 400.0 * x * y + 400.0 * x*x*x,
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/*dy*/ 200.0 * y - 200.0 * x*x,
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};
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};
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LevMarq solver(2, [f, j](InputOutputArray param, OutputArray err, OutputArray jv) -> bool
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{
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Vec2d v = param.getMat();
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double x = v[0], y = v[1];
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err.create(1, 1, CV_64F);
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err.getMat().at<double>(0) = f(x, y);
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if (jv.needed())
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{
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jv.create(1, 2, CV_64F);
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Mat(j(x, y)).copyTo(jv);
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}
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return true;
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},
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LevMarq::Settings().setGeodesic(true));
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Mat_<double> x (Vec2d(1, 3));
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auto r = solver.run(x);
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EXPECT_TRUE(r.found);
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EXPECT_LT(r.energy, 0.035);
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EXPECT_LE(r.iters, 17);
|
|
}
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|
|
|
|
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}} // namespace
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