#ifndef CAM_APPLICATION_HPP_EUIC2VFR #define CAM_APPLICATION_HPP_EUIC2VFR #include "autoware_v2x/application.hpp" #include "rclcpp/rclcpp.hpp" #include #include #include "autoware_auto_vehicle_msgs/msg/velocity_report.hpp" #include "autoware_auto_vehicle_msgs/msg/gear_report.hpp" #include "autoware_auto_vehicle_msgs/msg/steering_report.hpp" #include "autoware_adapi_v1_msgs/msg/vehicle_dimensions.hpp" #include "autoware_v2x/positioning.hpp" #include namespace v2x { class V2XNode; class CamApplication : public Application { public: CamApplication(V2XNode *node, vanetza::Runtime &, bool is_sender); PortType port() override; void indicate(const DataIndication &, UpPacketPtr) override; void set_interval(vanetza::Clock::duration); void updateMGRS(double *, double *); void updateRP(double *, double *, double *); void updateGenerationDeltaTime(int *, long *); void updateHeading(double *); void setVehicleDimensions(const autoware_adapi_v1_msgs::msg::VehicleDimensions &); void updateVelocityReport(const autoware_auto_vehicle_msgs::msg::VelocityReport::ConstSharedPtr); void updateGearReport(const autoware_auto_vehicle_msgs::msg::GearReport::ConstSharedPtr); void updateSteeringReport(const autoware_auto_vehicle_msgs::msg::SteeringReport::ConstSharedPtr); void send(); private: void schedule_timer(); void on_timer(vanetza::Clock::time_point); V2XNode *node_; vanetza::Runtime &runtime_; vanetza::Clock::duration cam_interval_{}; struct VehicleDimensions { float wheel_radius; float wheel_width; float wheel_base; float wheel_tread; float front_overhang; float rear_overhang; float left_overhang; float right_overhang; float height; }; VehicleDimensions vehicleDimensions_; struct Ego_station { double mgrs_x; double mgrs_y; double latitude; double longitude; double altitude; double heading; }; Ego_station ego_; class PositionsDeque { public: void insert(double value) { if (deque.size() >= maxSize) { total -= deque.front(); deque.pop_front(); } total += value; mean = total / deque.size(); deque.push_back(value); } int getSize() { return deque.size(); } [[nodiscard]] double getMean() const { return this->mean; } using iterator = std::deque::const_iterator; [[nodiscard]] iterator begin() const { return deque.begin(); } [[nodiscard]] iterator end() const { return deque.end(); } double operator[](std::size_t index) const { if (index >= deque.size()) throw std::out_of_range("[PositionDeque] Index out of range"); return deque[index]; } private: static const std::size_t maxSize = 5; std::deque deque; double total = 0; double mean = 0; }; struct PositionConfidenceEllipse { PositionsDeque x; PositionsDeque y; double semiMajorConfidence{}; double semiMinorConfidence{}; double semiMajorOrientation{}; }; PositionConfidenceEllipse positionConfidenceEllipse_; struct VelocityReport { rclcpp::Time stamp; float heading_rate; float lateral_velocity; float longitudinal_velocity; float longitudinal_acceleration; }; VelocityReport velocityReport_; struct VehicleStatus { uint8_t gear; float steering_tire_angle; }; VehicleStatus vehicleStatus_; int generationDeltaTime_; long gdt_timestamp_{}; double objectConfidenceThreshold_; bool updating_velocity_report_; bool updating_vehicle_status_; bool sending_; bool is_sender_; bool reflect_packet_; unsigned long stationId_; int cam_num_; int received_cam_num_; bool use_dynamic_generation_rules_; }; } #endif /* CAM_APPLICATION_HPP_EUIC2VFR */