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b06544bd54
Add normal estimation and region growing algorithm for point cloud * Add normal estimation and region growing algorithm for point cloud * 1.Modified documentation for normal estimation;2.Converted curvature in region growing to absolute values;3.Changed the data type of threshold from float to double;4.Fixed some bugs; * Finished documentation * Add tests for normal estimation. Test the normal and curvature of each point in the plane and sphere of the point cloud. * Fix some warnings caused by to small numbers in test * Change the test to calculate the average difference instead of comparing each normal and curvature * Fixed the bugs found by testing * Redesigned the interface and fixed problems: 1. Make the interface compatible with radius search. 2. Make region growing optionally sortable on results. 3. Modified the region growing interface. 4. Format reference. 5. Removed sphere test. * Fix warnings * Remove flann dependency * Move the flann dependency to the corresponding test
314 lines
12 KiB
C++
314 lines
12 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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//
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// Copyright (C) 2021, Wanli Zhong <zhongwl2018@mail.sustech.edu.cn>
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#include "test_precomp.hpp"
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#include "test_ptcloud_utils.hpp"
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namespace opencv_test { namespace {
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int countNum(const vector<int> &m, int num)
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{
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int t = 0;
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for (int a: m)
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if (a == num) t++;
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return t;
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}
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string getHeader(const Ptr<SACSegmentation> &s){
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string r;
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if(!s->isParallel())
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r += "One thread ";
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else
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r += std::to_string(getNumThreads()) + "-thread ";
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if(s->getNumberOfModelsExpected() == 1)
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r += "single model segmentation ";
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else
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r += std::to_string(s->getNumberOfModelsExpected()) + " models segmentation ";
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if(s->getCustomModelConstraints() == nullptr)
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r += "without constraint:\n";
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else
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r += "with constraint:\n";
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r += "Confidence: " + std::to_string(s->getConfidence()) + "\n";
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r += "Max Iterations: " + std::to_string(s->getMaxIterations()) + "\n";
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r += "Expected Models Number: " + std::to_string(s->getNumberOfModelsExpected()) + "\n";
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r += "Distance Threshold: " + std::to_string(s->getDistanceThreshold());
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return r;
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}
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class SacSegmentationTest : public ::testing::Test
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{
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public:
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// Used to store the parameters of model generation
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vector<vector<float>> models, limits;
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vector<float> thrs;
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vector<int> pt_nums;
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int models_num = 0;
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// Used to store point cloud, generated plane and model
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Mat pt_cloud, generated_pts, segmented_models;
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vector<int> label;
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Ptr<SACSegmentation> sacSegmentation = SACSegmentation::create();
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SACSegmentation::ModelConstraintFunction model_constraint = nullptr;
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using CheckDiffFunction = std::function<bool(const Mat &, const Mat &)>;
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void singleModelSegmentation(int iter_num, const CheckDiffFunction &checkDiff, int idx)
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{
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sacSegmentation->setSacMethodType(SAC_METHOD_RANSAC);
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sacSegmentation->setConfidence(1);
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sacSegmentation->setMaxIterations(iter_num);
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sacSegmentation->setNumberOfModelsExpected(1);
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//A point with a distance equal to the threshold is not considered an inliner point
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sacSegmentation->setDistanceThreshold(thrs[idx] + 0.01);
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int num = sacSegmentation->segment(pt_cloud, label, segmented_models);
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string header = getHeader(sacSegmentation);
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ASSERT_EQ(1, num)
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<< header << endl
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<< "Model number should be equal to 1.";
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ASSERT_EQ(pt_cloud.rows, (int) (label.size()))
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<< header << endl
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<< "Label size should be equal to point number.";
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Mat ans_model, segmented_model;
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ans_model = Mat(1, (int) models[0].size(), CV_32F, models[idx].data());
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segmented_models.row(0).convertTo(segmented_model, CV_32F);
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ASSERT_TRUE(checkDiff(ans_model, segmented_model))
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<< header << endl
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<< "Initial model is " << ans_model << ". Segmented model is " << segmented_model
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<< ". The difference in coefficients should not be too large.";
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ASSERT_EQ(pt_nums[idx], countNum(label, 1))
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<< header << endl
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<< "There are " << pt_nums[idx] << " points need to be marked.";
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int start_idx = 0;
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for (int i = 0; i < idx; i++) start_idx += pt_nums[i];
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for (int i = 0; i < pt_cloud.rows; i++)
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{
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if (i >= start_idx && i < start_idx + pt_nums[idx])
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ASSERT_EQ(1, label[i])
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<< header << endl
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<< "This index should be marked: " << i
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<< ". This point is " << pt_cloud.row(i);
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else
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ASSERT_EQ(0, label[i])
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<< header << endl
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<< "This index should not be marked: "
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<< i << ". This point is " << pt_cloud.row(i);
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}
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}
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void multiModelSegmentation(int iter_num, const CheckDiffFunction &checkDiff)
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{
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sacSegmentation->setSacMethodType(SAC_METHOD_RANSAC);
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sacSegmentation->setConfidence(1);
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sacSegmentation->setMaxIterations(iter_num);
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sacSegmentation->setNumberOfModelsExpected(models_num);
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sacSegmentation->setDistanceThreshold(thrs[models_num - 1] + 0.01);
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int num = sacSegmentation->segment(pt_cloud, label, segmented_models);
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string header = getHeader(sacSegmentation);
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ASSERT_EQ(models_num, num)
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<< header << endl
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<< "Model number should be equal to " << models_num << ".";
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ASSERT_EQ(pt_cloud.rows, (int) (label.size()))
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<< header << endl
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<< "Label size should be equal to point number.";
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int checked_num = 0;
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for (int i = 0; i < models_num; i++)
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{
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Mat ans_model, segmented_model;
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ans_model = Mat(1, (int) models[0].size(), CV_32F, models[models_num - 1 - i].data());
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segmented_models.row(i).convertTo(segmented_model, CV_32F);
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ASSERT_TRUE(checkDiff(ans_model, segmented_model))
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<< header << endl
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<< "Initial model is " << ans_model << ". Segmented model is " << segmented_model
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<< ". The difference in coefficients should not be too large.";
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ASSERT_EQ(pt_nums[models_num - 1 - i], countNum(label, i + 1))
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<< header << endl
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<< "There are " << pt_nums[i] << " points need to be marked.";
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for (int j = checked_num; j < pt_nums[i]; j++)
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ASSERT_EQ(models_num - i, label[j])
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<< header << endl
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<< "This index " << j << " should be marked as " << models_num - i
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<< ". This point is " << pt_cloud.row(j);
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checked_num += pt_nums[i];
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}
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}
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};
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TEST_F(SacSegmentationTest, PlaneSacSegmentation)
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{
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sacSegmentation->setSacModelType(SAC_MODEL_PLANE);
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models = {
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{0, 0, 1, 0},
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{1, 0, 0, 0},
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{0, 1, 0, 0},
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{1, 1, 1, -150},
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};
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thrs = {0.1f, 0.2f, 0.3f, 0.4f};
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pt_nums = {100, 200, 300, 400};
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limits = {
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{5, 55, 5, 55, 0, 0},
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{0, 0, 5, 55, 5, 55},
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{5, 55, 0, 0, 5, 55},
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{10, 50, 10, 50, 0, 0},
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};
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models_num = (int) models.size();
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// 1 * 3.1415926f / 180
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float vector_radian_tolerance = 0.0174533f, ratio_tolerance = 0.1f;
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CheckDiffFunction planeCheckDiff = [vector_radian_tolerance, ratio_tolerance](const Mat &a,
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const Mat &b) -> bool {
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Mat m1, m2;
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a.convertTo(m1, CV_32F);
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b.convertTo(m2, CV_32F);
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auto p1 = (float *) m1.data, p2 = (float *) m2.data;
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Vec3f n1(p1[0], p1[1], p1[2]);
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Vec3f n2(p2[0], p2[1], p2[2]);
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float cos_theta_square = n1.dot(n2) * n1.dot(n2) / (n1.dot(n1) * n2.dot(n2));
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float r1 = p1[3] * p1[3] / n1.dot(n1);
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float r2 = p2[3] * p2[3] / n2.dot(n2);
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return cos_theta_square >= cos(vector_radian_tolerance) * cos(vector_radian_tolerance)
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&& abs(r1 - r2) <= ratio_tolerance * ratio_tolerance;
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};
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// Single plane segmentation
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for (int i = 0; i < models_num; i++)
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{
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generatePlane(generated_pts, models[i], thrs[i], pt_nums[i], limits[i]);
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pt_cloud.push_back(generated_pts);
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singleModelSegmentation(1000, planeCheckDiff, i);
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}
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// Single plane segmentation with constraint
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for (int i = models_num / 2; i < models_num; i++)
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{
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vector<float> constraint_normal = {models[i][0], models[i][1], models[i][2]};
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// Normal vector constraint function
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model_constraint = [constraint_normal](const vector<double> &model) -> bool {
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// The angle between the model normals and the constraints must be less than 1 degree
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// 1 * 3.1415926f / 180
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float radian_thr = 0.0174533f;
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vector<float> model_normal = {(float) model[0], (float) model[1], (float) model[2]};
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float dot12 = constraint_normal[0] * model_normal[0] +
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constraint_normal[1] * model_normal[1] +
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constraint_normal[2] * model_normal[2];
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float m1m1 = constraint_normal[0] * constraint_normal[0] +
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constraint_normal[1] * constraint_normal[1] +
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constraint_normal[2] * constraint_normal[2];
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float m2m2 = model_normal[0] * model_normal[0] +
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model_normal[1] * model_normal[1] +
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model_normal[2] * model_normal[2];
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float square_cos_theta = dot12 * dot12 / (m1m1 * m2m2);
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return square_cos_theta >= cos(radian_thr) * cos(radian_thr);
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};
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sacSegmentation->setCustomModelConstraints(model_constraint);
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singleModelSegmentation(5000, planeCheckDiff, i);
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}
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pt_cloud.release();
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sacSegmentation->setCustomModelConstraints(nullptr);
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sacSegmentation->setParallel(true);
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// Multi-plane segmentation
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for (int i = 0; i < models_num; i++)
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{
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generatePlane(generated_pts, models[i], thrs[models_num - 1], pt_nums[i], limits[i]);
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pt_cloud.push_back(generated_pts);
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}
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multiModelSegmentation(1000, planeCheckDiff);
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}
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TEST_F(SacSegmentationTest, SphereSacSegmentation)
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{
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sacSegmentation->setSacModelType(cv::SAC_MODEL_SPHERE);
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models = {
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{15, 15, 30, 5},
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{-15, -15, -30, 8},
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{0, 0, -35, 10},
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{0, 0, 0, 15},
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{0, 0, 0, 20},
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};
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thrs = {0.1f, 0.2f, 0.3f, 0.4f, 0.5f};
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pt_nums = {100, 200, 300, 400, 500};
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limits = {
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{0, 1, 0, 1, 0, 1},
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{-1, 0, -1, 0, -1, 0},
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{-1, 1, -1, 1, 0, 1},
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{-1, 1, -1, 1, -1, 1},
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{-1, 1, -1, 1, -1, 0},
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};
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models_num = (int) models.size();
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float distance_tolerance = 0.1f, radius_tolerance = 0.1f;
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CheckDiffFunction sphereCheckDiff = [distance_tolerance, radius_tolerance](const Mat &a,
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const Mat &b) -> bool {
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Mat d = a - b;
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auto d_ptr = (float *) d.data;
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// Distance square between sphere centers
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float d_square = d_ptr[0] * d_ptr[0] + d_ptr[1] * d_ptr[1] + d_ptr[2] * d_ptr[2];
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// Difference square between radius of two spheres
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float r_square = d_ptr[3] * d_ptr[3];
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return d_square <= distance_tolerance * distance_tolerance &&
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r_square <= radius_tolerance * radius_tolerance;
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};
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// Single sphere segmentation
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for (int i = 0; i < models_num; i++)
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{
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generateSphere(generated_pts, models[i], thrs[i], pt_nums[i], limits[i]);
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pt_cloud.push_back(generated_pts);
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singleModelSegmentation(3000, sphereCheckDiff, i);
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}
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// Single sphere segmentation with constraint
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for (int i = models_num / 2; i < models_num; i++)
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{
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float constraint_radius = models[i][3] + 0.5f;
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// Radius constraint function
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model_constraint = [constraint_radius](
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const vector<double> &model) -> bool {
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auto model_radius = (float) model[3];
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return model_radius <= constraint_radius;
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};
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sacSegmentation->setCustomModelConstraints(model_constraint);
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singleModelSegmentation(10000, sphereCheckDiff, i);
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}
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pt_cloud.release();
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sacSegmentation->setCustomModelConstraints(nullptr);
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sacSegmentation->setParallel(true);
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// Multi-sphere segmentation
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for (int i = 0; i < models_num; i++)
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{
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generateSphere(generated_pts, models[i], thrs[models_num - 1], pt_nums[i], limits[i]);
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pt_cloud.push_back(generated_pts);
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}
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multiModelSegmentation(5000, sphereCheckDiff);
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}
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} // namespace
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} // opencv_test
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