void testJacobian(std::string group_name, std::string base_link, std::string tip_link)
{
SCOPED_TRACE(group_name + ": " + base_link + " to " + tip_link);
srand ( time(NULL) ); // initialize random seed:
rdf_loader::RDFLoader model_loader("robot_description");
robot_model::RobotModelPtr kinematic_model;
kinematic_model.reset(new robot_model::RobotModel(model_loader.getURDF(),model_loader.getSRDF()));
robot_state::RobotStatePtr kinematic_state;
kinematic_state.reset(new robot_state::RobotState(kinematic_model));
kinematic_state->setToDefaultValues();
const moveit::core::JointModelGroup* joint_state_group = kinematic_state->getRobotModel()->getJointModelGroup(group_name);
std::string link_name = tip_link;
std::vector<double> joint_angles(7,0.0);
geometry_msgs::Point ref_position;
Eigen::MatrixXd jacobian;
Eigen::Vector3d point(0.0,0.0,0.0);
kinematic_state->setJointGroupPositions(joint_state_group, &joint_angles[0]);
ASSERT_TRUE(kinematic_state->getJacobian(joint_state_group, kinematic_state->getRobotModel()->getLinkModel(link_name),point,jacobian));
KDL::Tree tree;
if (!kdl_parser::treeFromUrdfModel(*model_loader.getURDF(), tree))
{
ROS_ERROR("Could not initialize tree object");
}
KDL::Chain kdl_chain;
std::string base_frame(base_link);
std::string tip_frame(tip_link);
if (!tree.getChain(base_frame, tip_frame, kdl_chain))
{
ROS_ERROR("Could not initialize chain object");
}
KDL::ChainJntToJacSolver kdl_solver(kdl_chain);
KDL::Jacobian jacobian_kdl(7);
KDL::JntArray q_in(7);
EXPECT_TRUE(kdl_solver.JntToJac(q_in,jacobian_kdl) >= 0);
unsigned int NUM_TESTS = 10000;
for(unsigned int i=0; i < NUM_TESTS; i++)
{
for(int j=0; j < 7; j++)
{
q_in(j) = gen_rand(-M_PI,M_PI);
joint_angles[j] = q_in(j);
}
EXPECT_TRUE(kdl_solver.JntToJac(q_in,jacobian_kdl) >= 0);
kinematic_state->setJointGroupPositions(joint_state_group, &joint_angles[0]);
EXPECT_TRUE(kinematic_state->getJacobian(joint_state_group, kinematic_state->getRobotModel()->getLinkModel(link_name), point, jacobian));
for(unsigned int k=0; k < 6; k++)
{
for(unsigned int m=0; m < 7; m++)
{
EXPECT_FALSE(NOT_NEAR(jacobian_kdl(k,m),jacobian(k,m),1e-10));
}
}
}
}
TEST(JacobianSolver, solver)
{
srand ( time(NULL) ); // initialize random seed:
rdf_loader::RDFLoader model_loader("robot_description");
robot_model::RobotModelPtr kinematic_model;
kinematic_model.reset(new robot_model::RobotModel(model_loader.getURDF(),model_loader.getSRDF()));
robot_state::RobotStatePtr kinematic_state;
kinematic_state.reset(new robot_state::RobotState(kinematic_model));
kinematic_state->setToDefaultValues();
robot_state::JointStateGroup* joint_state_group = kinematic_state->getJointStateGroup("right_arm");
std::string link_name = "r_wrist_roll_link";
std::vector<double> joint_angles(7,0.0);
geometry_msgs::Point ref_position;
Eigen::MatrixXd jacobian;
Eigen::Vector3d point(0.0,0.0,0.0);
joint_state_group->setVariableValues(joint_angles);
ASSERT_TRUE(joint_state_group->getJacobian(link_name,point,jacobian));
KDL::Tree tree;
if (!kdl_parser::treeFromUrdfModel(*model_loader.getURDF(), tree))
{
ROS_ERROR("Could not initialize tree object");
}
KDL::Chain kdl_chain;
std::string base_frame("torso_lift_link");
std::string tip_frame("r_wrist_roll_link");
if (!tree.getChain(base_frame, tip_frame, kdl_chain))
{
ROS_ERROR("Could not initialize chain object");
}
KDL::ChainJntToJacSolver kdl_solver(kdl_chain);
KDL::Jacobian jacobian_kdl(7);
KDL::JntArray q_in(7);
EXPECT_TRUE(kdl_solver.JntToJac(q_in,jacobian_kdl) >= 0);
unsigned int NUM_TESTS = 1000000;
for(unsigned int i=0; i < NUM_TESTS; i++)
{
for(int j=0; j < 7; j++)
{
q_in(j) = gen_rand(-M_PI,M_PI);
joint_angles[j] = q_in(j);
}
EXPECT_TRUE(kdl_solver.JntToJac(q_in,jacobian_kdl) >= 0);
joint_state_group->setVariableValues(joint_angles);
EXPECT_TRUE(joint_state_group->getJacobian(link_name,point,jacobian));
for(unsigned int k=0; k < 6; k++)
{
for(unsigned int m=0; m < 7; m++)
{
EXPECT_FALSE(NOT_NEAR(jacobian_kdl(k,m),jacobian(k,m),1e-10));
}
}
}
}
