#include "autoware_v2x/cam_application.hpp" #include "autoware_v2x/positioning.hpp" #include "autoware_v2x/security.hpp" #include "autoware_v2x/link_layer.hpp" #include "autoware_v2x/v2x_node.hpp" #include "tf2/LinearMath/Quaternion.h" #include "tf2/LinearMath/Matrix3x3.h" #include "rclcpp/rclcpp.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace vanetza; using namespace std::chrono; namespace v2x { CamApplication::CamApplication(V2XNode * node, Runtime & rt, bool is_sender) : node_(node), runtime_(rt), cam_interval_(milliseconds(100)), vehicleDimensions_(), ego_(), positionConfidenceEllipse_(), velocityReport_(), vehicleStatus_(), generationDeltaTime_(0), objectConfidenceThreshold_(0.0), sending_(false), is_sender_(is_sender), reflect_packet_(false), cam_num_(0), received_cam_num_(0), use_dynamic_generation_rules_(false) { RCLCPP_INFO(node_->get_logger(), "CamApplication started. is_sender: %d", is_sender_); set_interval(cam_interval_); //createTables(); // Generate ID for this station std::random_device rd; std::mt19937 gen(rd()); std::uniform_int_distribution dis(0, 4294967295); stationId_ = dis(gen); } void CamApplication::set_interval(Clock::duration interval) { cam_interval_ = interval; runtime_.cancel(this); schedule_timer(); } void CamApplication::schedule_timer() { runtime_.schedule(cam_interval_, std::bind(&CamApplication::on_timer, this, std::placeholders::_1)); } void CamApplication::on_timer(vanetza::Clock::time_point) { schedule_timer(); send(); } CamApplication::PortType CamApplication::port() { return btp::ports::CAM; } void CamApplication::indicate(const Application::DataIndication &indication, Application::UpPacketPtr packet) { asn1::PacketVisitor visitor; std::shared_ptr rec_cam_ptr = boost::apply_visitor(visitor, *packet); if (!rec_cam_ptr) { RCLCPP_INFO(node_->get_logger(), "[CamApplication::indicate] Received invalid CAM"); return; } asn1::Cam rec_cam = *rec_cam_ptr; RCLCPP_INFO(node_->get_logger(), "[CamApplication::indicate] Received CAM from station with ID #%ld", rec_cam->header.stationID); std::chrono::milliseconds now_ms = std::chrono::duration_cast(std::chrono::system_clock::now().time_since_epoch()); cam_ts_CAM_t ts_cam; cam_ts_ItsPduHeader_t &header = ts_cam.header; header.protocolVersion = rec_cam->header.protocolVersion; header.messageId = rec_cam->header.messageID; header.stationId = rec_cam->header.stationID; cam_ts_CamPayload_t &coopAwareness = ts_cam.cam; coopAwareness.generationDeltaTime = rec_cam->cam.generationDeltaTime; cam_ts_BasicContainer_t &basic_container = coopAwareness.camParameters.basicContainer; BasicContainer_t &rec_basic_container = rec_cam->cam.camParameters.basicContainer; basic_container.stationType = rec_basic_container.stationType; basic_container.referencePosition.latitude = rec_basic_container.referencePosition.latitude; basic_container.referencePosition.longitude = rec_basic_container.referencePosition.longitude; basic_container.referencePosition.altitude.altitudeValue = rec_basic_container.referencePosition.altitude.altitudeValue; basic_container.referencePosition.altitude.altitudeConfidence = rec_basic_container.referencePosition.altitude.altitudeConfidence; basic_container.referencePosition.positionConfidenceEllipse.semiMajorAxisLength = rec_basic_container.referencePosition.positionConfidenceEllipse.semiMajorConfidence; basic_container.referencePosition.positionConfidenceEllipse.semiMinorAxisLength = rec_basic_container.referencePosition.positionConfidenceEllipse.semiMinorConfidence; basic_container.referencePosition.positionConfidenceEllipse.semiMajorAxisOrientation = rec_basic_container.referencePosition.positionConfidenceEllipse.semiMajorOrientation; cam_ts_BasicVehicleContainerHighFrequency_t &bvc = coopAwareness.camParameters.highFrequencyContainer.choice.basicVehicleContainerHighFrequency; coopAwareness.camParameters.highFrequencyContainer.present = cam_ts_HighFrequencyContainer_PR_basicVehicleContainerHighFrequency; BasicVehicleContainerHighFrequency_t &rec_bvc = rec_cam->cam.camParameters.highFrequencyContainer.choice.basicVehicleContainerHighFrequency; bvc.heading.headingValue = rec_bvc.heading.headingValue; bvc.heading.headingConfidence = rec_bvc.heading.headingConfidence; bvc.speed.speedValue = rec_bvc.speed.speedValue; bvc.speed.speedConfidence = rec_bvc.speed.speedConfidence; bvc.driveDirection = rec_bvc.driveDirection; bvc.vehicleLength.vehicleLengthValue = rec_bvc.vehicleLength.vehicleLengthValue; bvc.vehicleLength.vehicleLengthConfidenceIndication = rec_bvc.vehicleLength.vehicleLengthConfidenceIndication; bvc.vehicleWidth = rec_bvc.vehicleWidth; bvc.longitudinalAcceleration.value = rec_bvc.longitudinalAcceleration.longitudinalAccelerationValue; bvc.longitudinalAcceleration.confidence = rec_bvc.longitudinalAcceleration.longitudinalAccelerationConfidence; bvc.curvature.curvatureValue = rec_bvc.curvature.curvatureValue; bvc.curvature.curvatureConfidence = rec_bvc.curvature.curvatureConfidence; bvc.curvatureCalculationMode = rec_bvc.curvatureCalculationMode; bvc.yawRate.yawRateValue = rec_bvc.yawRate.yawRateValue; bvc.yawRate.yawRateConfidence = rec_bvc.yawRate.yawRateConfidence; etsi_its_cam_ts_msgs::msg::CAM ros_msg; etsi_its_cam_ts_conversion::toRos_CAM(ts_cam, ros_msg); node_->publishReceivedCam(ros_msg); } void CamApplication::updateMGRS(double *x, double *y) { ego_.mgrs_x = *x; ego_.mgrs_y = *y; } void CamApplication::updateRP(double *lat, double *lon, double *altitude) { ego_.latitude = *lat; ego_.longitude = *lon; ego_.altitude = *altitude; positionConfidenceEllipse_.x.insert(*lat); positionConfidenceEllipse_.y.insert(*lon); } void CamApplication::updateGenerationDeltaTime(int *gdt, long *gdt_timestamp) { generationDeltaTime_ = *gdt; gdt_timestamp_ = *gdt_timestamp; // ETSI-epoch milliseconds timestamp } void CamApplication::updateHeading(double *yaw) { ego_.heading = *yaw; } void CamApplication::setVehicleDimensions(const autoware_adapi_v1_msgs::msg::VehicleDimensions &msg) { vehicleDimensions_.wheel_radius = msg.wheel_radius; vehicleDimensions_.wheel_width = msg.wheel_width; vehicleDimensions_.wheel_base = msg.wheel_base; vehicleDimensions_.wheel_tread = msg.wheel_tread; vehicleDimensions_.front_overhang = msg.front_overhang; vehicleDimensions_.rear_overhang = msg.rear_overhang; vehicleDimensions_.left_overhang = msg.left_overhang; vehicleDimensions_.right_overhang = msg.right_overhang; vehicleDimensions_.height = msg.height; } void CamApplication::updateVelocityReport(const autoware_auto_vehicle_msgs::msg::VelocityReport::ConstSharedPtr msg) { rclcpp::Time msg_stamp(msg->header.stamp.sec, msg->header.stamp.nanosec); double dt = msg_stamp.seconds() - velocityReport_.stamp.seconds(); if (dt == 0) { RCLCPP_WARN(node_->get_logger(), "[CamApplication::updateVelocityReport] deltaTime is 0"); return; } float longitudinal_acceleration = (msg->longitudinal_velocity - velocityReport_.longitudinal_velocity) / dt; velocityReport_.stamp = msg->header.stamp; velocityReport_.heading_rate = msg->heading_rate; velocityReport_.lateral_velocity = msg->lateral_velocity; velocityReport_.longitudinal_velocity = msg->longitudinal_velocity; velocityReport_.longitudinal_acceleration = longitudinal_acceleration; } void CamApplication::updateGearReport(const autoware_auto_vehicle_msgs::msg::GearReport::ConstSharedPtr msg) { rclcpp::Time msg_stamp(msg->stamp.sec, msg->stamp.nanosec); vehicleStatus_.gear = msg->report; } void CamApplication::updateSteeringReport(const autoware_auto_vehicle_msgs::msg::SteeringReport::ConstSharedPtr msg) { vehicleStatus_.steering_tire_angle = msg->steering_tire_angle; } void CamApplication::send() { if (!is_sender_) return; if (sending_) { RCLCPP_WARN(node_->get_logger(), "[CamApplication::send] already sending"); return; } sending_ = true; vanetza::asn1::Cam message; ItsPduHeader_t &header = message->header; header.protocolVersion = 2; header.messageID = ItsPduHeader__messageID_cam; header.stationID = stationId_; CoopAwareness_t &cam = message->cam; cam.generationDeltaTime = generationDeltaTime_; BasicContainer_t &basic_container = cam.camParameters.basicContainer; basic_container.stationType = StationType_passengerCar; float latitude = ego_.latitude * 1e7; float longitude = ego_.longitude * 1e7; float altitude = ego_.altitude * 100; if (-900000000 <= latitude && latitude <= 900000000) basic_container.referencePosition.latitude = latitude; else basic_container.referencePosition.latitude = Latitude_unavailable; if (-1800000000 <= longitude && longitude <= 1800000000) basic_container.referencePosition.longitude = longitude; else basic_container.referencePosition.longitude = Longitude_unavailable; if (-100000 <= altitude && altitude <= 800000) basic_container.referencePosition.altitude.altitudeValue = altitude; else basic_container.referencePosition.altitude.altitudeValue = AltitudeValue_unavailable; // Articles consulted for the positionConficenceEllipse // https://users.cs.utah.edu/~tch/CS4640F2019/resources/A%20geometric%20interpretation%20of%20the%20covariance%20matrix.pdf // https://users.cs.utah.edu/~tch/CS6640F2020/resources/How%20to%20draw%20a%20covariance%20error%20ellipse.pdf if (positionConfidenceEllipse_.x.getSize() == positionConfidenceEllipse_.y.getSize()) { double xx_sum = 0; double yy_sum = 0; double xy_sum = 0; for (double x : positionConfidenceEllipse_.x) xx_sum += std::pow(x - positionConfidenceEllipse_.x.getMean(), 2); for (double y : positionConfidenceEllipse_.y) yy_sum += std::pow(y - positionConfidenceEllipse_.y.getMean(), 2); for (int i = 0; i < positionConfidenceEllipse_.x.getSize(); i++) xy_sum += (positionConfidenceEllipse_.x[i] - positionConfidenceEllipse_.x.getMean()) * (positionConfidenceEllipse_.y[i] - positionConfidenceEllipse_.y.getMean()); double sigma_xx = xx_sum / (positionConfidenceEllipse_.x.getSize() - 1); double sigma_yy = yy_sum / (positionConfidenceEllipse_.y.getSize() - 1); double sigma_xy = xy_sum / (positionConfidenceEllipse_.x.getSize() - 1); double lambda1 = (sigma_xx + sigma_yy) - std::sqrt(std::pow(sigma_xx + sigma_yy, 2) - 4 * (sigma_xx * sigma_yy - sigma_xy * sigma_xy)) / 2; double lambda2 = (sigma_xx + sigma_yy) + std::sqrt(std::pow(sigma_xx + sigma_yy, 2) - 4 * (sigma_xx * sigma_yy - sigma_xy * sigma_xy)) / 2; double lambda_max = std::max(lambda1, lambda2); double lambda_min = std::min(lambda1, lambda2); // For 95% confidence level, must use 2.4477 double majorConfidence = std::lround(2.4477 * std::sqrt(lambda_max)); double minorConfidence = std::lround(2.4477 * std::sqrt(lambda_min)); double majorOrientation = - (sigma_xy != 0 ? std::lround(std::atan(- (sigma_xx - lambda_max) / sigma_xy) * 180 / M_PI) : sigma_xx != 0 ? 0 : -90) * 10; if (majorOrientation < 0) majorOrientation += 3600; if (0 <= majorConfidence && majorConfidence <= 4094) basic_container.referencePosition.positionConfidenceEllipse.semiMajorConfidence = majorConfidence; else basic_container.referencePosition.positionConfidenceEllipse.semiMajorConfidence = SemiAxisLength_unavailable; if (0 <= minorConfidence && minorConfidence <= 4094) basic_container.referencePosition.positionConfidenceEllipse.semiMinorConfidence = minorConfidence; else basic_container.referencePosition.positionConfidenceEllipse.semiMinorConfidence = SemiAxisLength_unavailable; if (0 <= majorOrientation && majorOrientation <= 3600) basic_container.referencePosition.positionConfidenceEllipse.semiMajorOrientation = majorOrientation; else basic_container.referencePosition.positionConfidenceEllipse.semiMajorOrientation = HeadingValue_unavailable; } else { basic_container.referencePosition.positionConfidenceEllipse.semiMajorConfidence = SemiAxisLength_unavailable; basic_container.referencePosition.positionConfidenceEllipse.semiMinorConfidence = SemiAxisLength_unavailable; basic_container.referencePosition.positionConfidenceEllipse.semiMajorOrientation = HeadingValue_unavailable; } BasicVehicleContainerHighFrequency_t &bvc = cam.camParameters.highFrequencyContainer.choice.basicVehicleContainerHighFrequency; cam.camParameters.highFrequencyContainer.present = HighFrequencyContainer_PR_basicVehicleContainerHighFrequency; int heading = std::lround(((-ego_.heading * 180.0 / M_PI) + 90.0) * 10.0); if (heading < 0) heading += 3600; if (0 <= heading && heading <= 3600) bvc.heading.headingValue = heading; else bvc.heading.headingValue = HeadingValue_unavailable; float heading_rate = velocityReport_.heading_rate; float lateral_velocity = velocityReport_.lateral_velocity; float longitudinal_velocity = velocityReport_.longitudinal_velocity; float longitudinal_acceleration = std::lround(velocityReport_.longitudinal_acceleration * 100); uint8_t gearStatus = vehicleStatus_.gear; float steering_tire_angle = vehicleStatus_.steering_tire_angle; long speed = std::lround(std::sqrt(std::pow(longitudinal_velocity, 2) + std::pow(lateral_velocity, 2)) * 100); if (0 <= speed && speed <= 16382) bvc.speed.speedValue = speed; else bvc.speed.speedValue = SpeedValue_unavailable; if ((gearStatus >= 2 && gearStatus <= 19) || (gearStatus == 23 || gearStatus == 24)) bvc.driveDirection = DriveDirection_forward; else if (gearStatus == 20 || gearStatus == 21) bvc.driveDirection = DriveDirection_backward; else bvc.driveDirection = DriveDirection_unavailable; long vehicleLength = std::lround((vehicleDimensions_.front_overhang + vehicleDimensions_.wheel_base + vehicleDimensions_.rear_overhang) * 10); if (1 <= vehicleLength && vehicleLength <= 1022) bvc.vehicleLength.vehicleLengthValue = vehicleLength; else bvc.vehicleLength.vehicleLengthValue = VehicleLengthValue_unavailable; long vehicleWidth = std::lround((vehicleDimensions_.left_overhang + vehicleDimensions_.wheel_tread + vehicleDimensions_.right_overhang) * 10); if (1 <= vehicleWidth && vehicleWidth <= 61) bvc.vehicleWidth = vehicleWidth; else bvc.vehicleWidth = VehicleWidth_unavailable; if (-160 <= longitudinal_acceleration && longitudinal_acceleration <= 160) bvc.longitudinalAcceleration.longitudinalAccelerationValue = longitudinal_acceleration; else bvc.longitudinalAcceleration.longitudinalAccelerationValue = LongitudinalAccelerationValue_unavailable; long curvature = longitudinal_velocity != 0 ? std::abs(std::lround(lateral_velocity / std::pow(longitudinal_velocity, 2) * 100)) * (steering_tire_angle < 0 ? -1 : 1) : std::numeric_limits::infinity(); if (-1023 <= curvature && curvature <= 1022) bvc.curvature.curvatureValue = curvature; else bvc.curvature.curvatureValue = CurvatureValue_unavailable; bvc.curvatureCalculationMode = CurvatureCalculationMode_yawRateNotUsed; long heading_rate_deg = std::abs(std::lround(heading_rate * (180.0 / M_PI))) * (steering_tire_angle < 0 ? -1 : 1); if (-32766 <= heading_rate_deg && heading_rate_deg <= 32766) bvc.yawRate.yawRateValue = heading_rate_deg; else bvc.yawRate.yawRateValue = YawRateValue_unavailable; // UNAVAILABLE VALUES basic_container.referencePosition.altitude.altitudeConfidence = AltitudeConfidence_unavailable; // ------------------------------ bvc.heading.headingConfidence = HeadingConfidence_unavailable; bvc.speed.speedConfidence = SpeedConfidence_unavailable; bvc.vehicleLength.vehicleLengthConfidenceIndication = VehicleLengthConfidenceIndication_unavailable; bvc.longitudinalAcceleration.longitudinalAccelerationConfidence = AccelerationConfidence_unavailable; bvc.curvature.curvatureConfidence = CurvatureConfidence_unavailable; bvc.yawRate.yawRateConfidence = YawRateConfidence_unavailable; // ------------------------------ RCLCPP_INFO(node_->get_logger(), "[CamApplication::send] Sending CAM from station with ID %ld", stationId_); std::unique_ptr payload{new geonet::DownPacket()}; payload->layer(OsiLayer::Application) = std::move(message); Application::DataRequest request; request.its_aid = aid::CP; request.transport_type = geonet::TransportType::SHB; request.communication_profile = geonet::CommunicationProfile::ITS_G5; Application::DataConfirm confirm = Application::request(request, std::move(payload), node_); if (!confirm.accepted()) { throw std::runtime_error("[CamApplication::send] CAM application data request failed"); } RCLCPP_INFO(node_->get_logger(), "[CamApplication::send] Successfully sent"); sending_ = false; std::chrono::milliseconds ms = std::chrono::duration_cast ( std::chrono::system_clock::now().time_since_epoch() ); node_->latency_log_file << "T_depart," << cam_num_ << "," << ms.count() << std::endl; ++cam_num_; } }