int main(int argc, char** argv) { ros::init(argc, argv, "parser_test"); ros::NodeHandle nh; try { std::string name = "red_arm"; RobotPtr robot = std::make_shared<Robot>(name); ParserPtr parser = std::make_shared<Parser>(); std::string path = "/home/daichi/Work/catkin_ws/src/ahl_ros_pkg/ahl_robot/ahl_robot/yaml/red_arm.yaml"; parser->load(path, robot); ros::MultiThreadedSpinner spinner; TfPublisherPtr tf_publisher = std::make_shared<TfPublisher>(); const std::string mnp_name = "mnp"; unsigned long cnt = 0; ros::Rate r(10.0); while(ros::ok()) { Eigen::VectorXd q = Eigen::VectorXd::Zero(robot->getDOF(mnp_name)); ManipulatorPtr mnp = robot->getManipulator(mnp_name); double goal = sin(2.0 * M_PI * 0.2 * cnt * 0.1); ++cnt; for(uint32_t i = 0; i < q.rows(); ++i) { q.coeffRef(6) = M_PI / 4.0 * goal; } std::cout << M_PI / 4.0 * goal << std::endl; //q = Eigen::VectorXd::Constant(q.rows(), 0.0 * M_PI / 4.0); robot->update(q); robot->computeJacobian(mnp_name); robot->computeMassMatrix(mnp_name); M = robot->getMassMatrix(mnp_name); J = robot->getJacobian(mnp_name, "gripper"); calc(); tf_publisher->publish(robot, false); r.sleep(); } } catch(ahl_utils::Exception& e) { ROS_ERROR_STREAM(e.what()); } return 0; }
void updateModel(const ros::TimerEvent&) { try { boost::mutex::scoped_lock lock(mutex); if(joint_updated) { robot->computeBasicJacobian("mnp"); robot->computeMassMatrix("mnp"); controller->updateModel(); updated = true; tf_pub->publish(robot); } } catch(ahl_ctrl::Exception& e) { ROS_ERROR_STREAM(e.what()); } catch(ahl_gazebo_if::Exception& e) { ROS_ERROR_STREAM(e.what()); } }
int main(int argc, char** argv) { ros::init(argc, argv, "parser_test"); ros::NodeHandle nh; try { std::string name = "personal_robot"; RobotPtr robot = RobotPtr(new Robot(name)); ParserPtr parser = ParserPtr(new Parser()); std::string path = "/home/daichi/Work/catkin_ws/src/ahl_ros_pkg/ahl_robot/ahl_robot/yaml/pr2.yaml"; parser->load(path, robot); ros::MultiThreadedSpinner spinner; TfPublisherPtr tf_publisher = TfPublisherPtr(new TfPublisher()); const std::string mnp_name1 = "left_mnp"; const std::string mnp_name2 = "right_mnp"; unsigned long cnt = 0; ros::Rate r(10.0); while(ros::ok()) { Eigen::VectorXd q = Eigen::VectorXd::Zero(robot->getDOF()); ManipulatorPtr left_mnp = robot->getManipulator(mnp_name1); double goal = sin(2.0 * M_PI * 0.2 * cnt * 0.1); ++cnt; //std::cout << M_PI / 4.0 * goal << std::endl; q = Eigen::VectorXd::Constant(q.rows(), 0.0); q[10] = goal; robot->update(q); //robot->update(mnp_name2, q); robot->computeJacobian(mnp_name1); robot->computeJacobian(mnp_name2); robot->computeMassMatrix(mnp_name1); robot->computeMassMatrix(mnp_name2); M1 = robot->getMassMatrix(mnp_name1); M2 = robot->getMassMatrix(mnp_name2); J1 = robot->getJacobian(mnp_name1, "gripper_l_link"); J2 = robot->getJacobian(mnp_name2, "gripper_r_link"); calc(); tf_publisher->publish(robot, false); r.sleep(); } } catch(ahl_utils::Exception& e) { ROS_ERROR_STREAM(e.what()); } return 0; }
int main(int argc, char** argv) { ros::init(argc, argv, "parser_test"); ros::NodeHandle nh; try { std::string name = "youbot"; RobotPtr robot = RobotPtr(new Robot(name)); ParserPtr parser = ParserPtr(new Parser()); std::string path = "/home/daichi/Work/catkin_ws/src/ahl_ros_pkg/ahl_robot/ahl_robot/yaml/youbot.yaml"; parser->load(path, robot); robot->getMobility()->print(); ros::MultiThreadedSpinner spinner; TfPublisherPtr tf_publisher = TfPublisherPtr(new TfPublisher()); const std::string mnp_name = "mnp"; unsigned long cnt = 0; const double period = 0.001; ros::Rate r(1 / period); ahl_filter::DifferentiatorPtr differentiator = ahl_filter::DifferentiatorPtr(new ahl_filter::PseudoDifferentiator(period, 1.0)); Eigen::VectorXd q = Eigen::VectorXd::Constant(robot->getDOF(mnp_name), 0.0); Eigen::VectorXd dq = Eigen::VectorXd::Constant(robot->getDOF(mnp_name), 0.0); differentiator->init(q, dq); Eigen::VectorXd pre_q = q; //std::ofstream ofs1; //ofs1.open("result1.hpp"); //std::ofstream ofs2; //ofs2.open("result2.hpp"); //std::ofstream ofs3; //ofs3.open("result3.hpp"); while(ros::ok()) { q = Eigen::VectorXd::Constant(robot->getDOF(mnp_name), 1.0); double coeff = 1.0 * sin(2.0 * M_PI * 0.1 * cnt * period); ++cnt; q = coeff * q; //q = Eigen::VectorXd::Constant(robot->getDOF(mnp_name), M_PI / 2.0); q.coeffRef(0) = 0.0; q.coeffRef(1) = 0.0; q.coeffRef(2) = 0.0; robot->update(mnp_name, q); robot->computeBasicJacobian(mnp_name); robot->computeMassMatrix(mnp_name); differentiator->apply(q); Eigen::VectorXd dq1 = robot->getJointVelocity(mnp_name); Eigen::VectorXd dq2; differentiator->copyDerivativeValueTo(dq2); std::cout << "p : " << q.transpose() << std::endl; std::cout << "pre_p : " << pre_q.transpose() << std::endl; Eigen::VectorXd dq3 = (q - pre_q) / period; pre_q = q; //std::cout << "dq1 : " << dq1.block(3, 0, dq.rows() - 3, 1).transpose() << std::endl; //std::cout << "dq2 : " << dq2.block(3, 0, dq.rows() - 3, 1).transpose() << std::endl; //std::cout << "dq3 : " << dq3.block(3, 0, dq.rows() - 3, 1).transpose() << std::endl; //std::cout << dq << std::endl << std::endl; //std::cout << cos(2.0 * M_PI * 0.1 * cnt * 0.1) << std::endl; tf_publisher->publish(robot, false); /* ofs1 << cnt * period << " "; ofs2 << cnt * period << " "; ofs3 << cnt * period << " "; for(unsigned int i = 0; i < dq.rows() - 3; ++i) { ofs1 << dq1[i + 3] << " "; ofs2 << dq2[i + 3] << " "; ofs3 << dq3[i + 3] << " "; } ofs1 << std::endl; ofs2 << std::endl; ofs3 << std::endl; */ r.sleep(); } } catch(ahl_robot::Exception& e) { ROS_ERROR_STREAM(e.what()); } return 0; }