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- #pragma once
- #include <pcl\point_types.h>
- #include <pcl\point_cloud.h>
- #include <pcl\segmentation\sac_segmentation.h>
- #include "data_def_api.h"
- #include "data_def.h"
- #include "logger.h"
- #include "imstorage_manager.h"
- #include "grab_occlusion.h"
- namespace graft_cv {
- class CRootStockGrabPoint {
- public:
- CRootStockGrabPoint(ConfigParam&c, CGcvLogger*pLog = 0);
- ~CRootStockGrabPoint();
- int grab_point_detect(PositionInfo& posinfo);
- float* get_raw_point_cloud(int &data_size);
- int load_data(float*pPoint, int pixel_size, int pt_size, int dtype, const char* fn = 0);
- void set_image_saver(CImStoreManager** ppis) { m_ppImgSaver = ppis; }
- private:
- //global configure parameters
- ConfigParam& m_cparam;
- CGcvLogger * m_pLogger;
- int m_dtype;
- string m_pcdId;
- //历史植株位置信息
- CStemResultInfos* m_pStemInfos;
- std::string m_stem_info_file;
- std::vector<CStemResult> m_root_centers; //通过m_pStemInfos获取到历史根中心位置
- std::vector<bool> m_root_center_with_seedling; //m_root_centers位置上是否含有植株
- //用于记录第一排z均值,用来辅助判别1、2排的苗
- float m_1st_row_zmean_rs = -1.0;
- float m_1st_row_zmean_sc = -1.0;
- CImStoreManager** m_ppImgSaver;
- //返回图片,用于调试
- ImgInfo* m_pImginfoResult;//识别结果的图片
-
- pcl::PointCloud<pcl::PointXYZ>::Ptr m_raw_cloud;
- double m_cloud_mean_dist;
- void clear_imginfo();
- int read_ply_file(const char* fn);
- double compute_nearest_neighbor_distance(pcl::PointCloud<pcl::PointXYZ>::Ptr);
- /////////////////////////////////////////////////////////////////////////////////////
- //叶子剔除,通过欧式距离聚类,然后判断每一个类别是否是叶子
- // 出现的问题:叶子和茎通过叶柄连接时,会误判
- void leaf_filter(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud,
- std::vector<int> &stem_cloud_idx
- );
-
- void leaf_filter_ror(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud, //input 输入点云数据
- std::vector<int> &stem_cloud_idx, //output, 过滤后的点云序号
- std::vector<int>& leaf_idx //output, 叶子的点云序号
- );
- void cloud_mean_dist(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud, //input 输入点云数据
- double& mean_dist
- );
- //////////////////////////////////////////////////////////////////////////////////////
- void CRootStockGrabPoint::find_fork(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_line_cloud,
- float& max_dist,//最大距离
- int& max_idx //距离边界最大的点序号
- );
- void gen_all_seedling_positions(
- pcl::PointXYZ&key_center, //输入,已知的苗的坐标
- std::vector<pcl::PointXYZ>&candidate_center //输出,有倾斜苗的坐标
- );
- bool find_seedling_position_key(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud,
- std::vector<int> &first_seedling_cloud_idx,
- pcl::PointXYZ&xz_center,
- pcl::ModelCoefficients::Ptr& lmodel,
- int& first_row_size //返回第一排植株的数量
- );
- // 邻域最小抑制
- void nms_box(
- std::vector<pcl::PointXYZ>&clt_root_v, //目标点的可能位置
- std::vector<float>&valid_box_cc_dist, //目标点的重心到中心的距离,距离越近越好
- float hole_step_radius, //目标点搜索半径
- std::vector<pcl::PointXYZ>& target_toot // 返回值
- );
- //通过指定位置内,取部分点云分析是否存在真正的茎,真茎位置保存到target_filtered
- void line_filter(pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud, //输入点云
- float radius, //输入,取点半径
- float ymin, //输入,y最小值
- float ymax, //输入,y最大值
- std::vector<pcl::PointXYZ>&target_root, //输入,位置
- std::vector<pcl::PointXYZ>&target_filtered, //输出,位置
- std::vector<pcl::PointXYZ>&target_filtered_root, //输出,茎上根部点坐标
- std::vector<std::vector<int>>&target_filtered_element, //输出,茎上点index
- std::vector<pcl::ModelCoefficients::Ptr>& target_filtered_models//输出,茎直线模型
- );
- void get_line_project_hist(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_line_cloud, //input 茎上直线点云
- pcl::ModelCoefficients::Ptr line_model, //input
- std::vector<int>& count_hist // 返回有效直线1mm内点云数量
- );
- /////////////////////////////////////////////////
- void find_seedling_position(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud,
- std::vector<int> &first_seedling_cloud_idx,
- pcl::PointXYZ&xz_center
- );
- void crop_nn_analysis(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud,
- pcl::PointCloud<pcl::PointXYZ>::Ptr seed_cloud,
- double dist_mean,
- std::vector<double>&mass_indices,
- std::vector<int>& idx
- );
- void euclidean_clustering_ttsas(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud,
- double d1, double d2,
- std::vector<pcl::PointXYZ>&cluster_center,
- std::vector<std::vector<int>> &clustr_member
- );
- void cal_obb_2d(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud,
- int axis,
- double &dx_obb,
- double &dy_obb,
- double &angle_obb);
-
- //已知检测出苗的位置,找出有可能有苗的位置
- void tilted_seedling_discover(
- std::vector<pcl::PointXYZ>&cluster_center, //输入,已知的苗的坐标
- std::vector<pcl::PointXYZ>&tilted_center //输出,有倾斜苗的坐标
- );
-
- //通过比较直线点云和原始点云相同位置邻域内xz的范围,确定此点是否是无干扰点的茎
- void get_optimal_seed_compare(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud, //input
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_line_cloud, //input
- pcl::ModelCoefficients::Ptr line_model, //input
- pcl::PointXYZ&pt, //输出,
- pcl::PointXYZ &pt_ref, //输出, 返回点茎节的参考点
- float& stem_width_mu, //输出,茎宽度,直径
- float& stem_deflection //输出,茎的最大挠度,最大弯曲处的偏离直径轴心的距离,毫米
- );
- //计算茎的弯曲度:点云到直线距离的95分位
- double calculate_deflection(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_line_cloud, //input
- pcl::ModelCoefficients::Ptr line_model //input
- );
- //在一株苗的空间范围内找出直线(茎,假设茎是直线分布的),并返回直线上的点index
- void find_line_in_cube(
- pcl::PointCloud<pcl::PointXYZ>::Ptr, //输入,整体点云
- pcl::PointXYZ& min_pt_ex, //输入,
- pcl::PointXYZ& max_pt_ex, //输入,
- std::vector<int>& out_idx //输出,直线上点的index, 基于输入整体点云
- );
- //生成结果图片
- void gen_result_img(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud_raw,//输入,未经过滤的整体点云in_cloud_raw,
- pcl::PointCloud<pcl::PointXYZ>::Ptr, //输入,整体点云cloud_dowm_sampled,
- pcl::PointXYZ& selected_pt, //输入,selected_pt,
- pcl::PointXYZ& selected_pt_ref, //输入,selected_pt_ref,
- const PositionInfo& posinfo, //输入,
- cv::Mat& rst_img //输出,图片, 640*1280
- );
- //根据历史根的位置,计算对应位置点云数量,进而判断此位置是否有苗
- void occluded_seedling_detect_by_leaf(
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud, //input 输入点云数据
- std::vector<int>& leaf_idx); //input
- int get_point_count_inbox(const CStemResult& sr, //input
- pcl::PointXYZ& aabb_min, //output
- pcl::PointXYZ& aabb_max, //output
- pcl::PointCloud<pcl::PointXYZ>::Ptr in_cloud, //input 输入点云数据
- std::vector<int>& leaf_idx);
- //没有检测到苗的情况,后处理
- void no_seedling_detected_post_process(
- int first_row_seedling_number, //input
- int& selected_idx, //output, 选择root_center的序号
- pcl::PointXYZ& selected_pt, //output
- pcl::PointXYZ& selected_pt_ref, //output
- PositionInfo& posinfo //output
- );
- //检测到苗的情况,后处理
- void had_seedling_detected_post_process(
- int first_row_seedling_number, //input
- float stem_width_mu, //input
- float stem_deflection, //input
- int& selected_idx, //output, 选择root_center的序号
- pcl::PointXYZ& selected_pt, //input-output
- pcl::PointXYZ& selected_pt_ref, //input-output
- PositionInfo& posinfo //output
- );
- void viewer_cloud(pcl::PointCloud<pcl::PointXYZ>::Ptr, std::string&winname);
- void viewer_cloud(pcl::PointCloud<pcl::PointXYZRGB>::Ptr, std::string&winname);
- void viewer_cloud_debug(
- pcl::PointCloud<pcl::PointXYZRGB>::Ptr cloud,
- pcl::PointXYZ&p,//抓取点
- pcl::PointXYZ &p_ref,//分叉点
- pcl::PointXYZ &root_pt,
- std::string&winname);
- void viewer_cloud_cluster(pcl::PointCloud<pcl::PointXYZRGB>::Ptr cloud, std::vector<pcl::PointXYZ>cluster_center, std::string&winname);
- void viewer_cloud_cluster_box(
- pcl::PointCloud<pcl::PointXYZ>::Ptr cloud,
- std::vector<pcl::PointXYZ>&cluster_center,
- std::vector<pcl::PointXYZ>&cluster_box,
- std::vector<std::vector<int> >& clt_line_idx,
- std::string&winname);
- };
- };
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