rbdlsim/3rdparty/rbdl/tests/UtilsTests.cc

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#include "rbdl_tests.h"
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#include <iostream>
#include "Fixtures.h"
#include "Human36Fixture.h"
#include "rbdl/rbdl_mathutils.h"
#include "rbdl/rbdl_utils.h"
#include "rbdl/Logging.h"
#include "rbdl/Model.h"
#include "rbdl/Kinematics.h"
#include "rbdl/Dynamics.h"
using namespace std;
using namespace RigidBodyDynamics;
using namespace RigidBodyDynamics::Math;
TEST_CASE_METHOD (FloatingBase12DoF, __FILE__"_TestKineticEnergy", "") {
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VectorNd q = VectorNd::Zero(model->q_size);
VectorNd qdot = VectorNd::Zero(model->q_size);
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.1 * i;
qdot[i] = 0.3 * i;
}
MatrixNd H = MatrixNd::Zero (model->q_size, model->q_size);
CompositeRigidBodyAlgorithm (*model, q, H, true);
double kinetic_energy_ref = 0.5 * qdot.transpose() * H * qdot;
double kinetic_energy = Utils::CalcKineticEnergy (*model, q, qdot);
REQUIRE (kinetic_energy_ref == kinetic_energy);
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}
TEST_CASE (__FILE__"_TestPotentialEnergy", "") {
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Model model;
Matrix3d inertia = Matrix3d::Zero(3,3);
Body body (0.5, Vector3d (0., 0., 0.), inertia);
Joint joint (
SpatialVector (0., 0., 0., 1., 0., 0.),
SpatialVector (0., 0., 0., 0., 1., 0.),
SpatialVector (0., 0., 0., 0., 0., 1.)
);
model.AppendBody (Xtrans (Vector3d::Zero()), joint, body);
VectorNd q = VectorNd::Zero(model.q_size);
double potential_energy_zero = Utils::CalcPotentialEnergy (model, q);
REQUIRE (0. == potential_energy_zero);
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q[1] = 1.;
double potential_energy_lifted = Utils::CalcPotentialEnergy (model, q);
REQUIRE (4.905 == potential_energy_lifted);
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}
TEST_CASE (__FILE__"_TestCOMSimple", "") {
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Model model;
Matrix3d inertia = Matrix3d::Zero(3,3);
Body body (123., Vector3d (0., 0., 0.), inertia);
Joint joint (
SpatialVector (0., 0., 0., 1., 0., 0.),
SpatialVector (0., 0., 0., 0., 1., 0.),
SpatialVector (0., 0., 0., 0., 0., 1.)
);
model.AppendBody (Xtrans (Vector3d::Zero()), joint, body);
VectorNd q = VectorNd::Zero(model.q_size);
VectorNd qdot = VectorNd::Zero(model.qdot_size);
double mass;
Vector3d com;
Vector3d com_velocity;
Utils::CalcCenterOfMass (model, q, qdot, NULL, mass, com, &com_velocity);
REQUIRE (123. == mass);
REQUIRE (Vector3d (0., 0., 0.) == com);
REQUIRE (Vector3d (0., 0., 0.) == com_velocity);
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q[1] = 1.;
Utils::CalcCenterOfMass (model, q, qdot, NULL, mass, com, &com_velocity);
REQUIRE (Vector3d (0., 1., 0.) == com);
REQUIRE (Vector3d (0., 0., 0.) == com_velocity);
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qdot[1] = 1.;
Utils::CalcCenterOfMass (model, q, qdot, NULL, mass, com, &com_velocity);
REQUIRE (Vector3d (0., 1., 0.) == com);
REQUIRE (Vector3d (0., 1., 0.) == com_velocity);
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}
TEST_CASE (__FILE__"_TestAngularMomentumSimple", "") {
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Model model;
Matrix3d inertia = Matrix3d::Zero(3,3);
inertia(0,0) = 1.1;
inertia(1,1) = 2.2;
inertia(2,2) = 3.3;
Body body (0.5, Vector3d (1., 0., 0.), inertia);
Joint joint (
SpatialVector (1., 0., 0., 0., 0., 0.),
SpatialVector (0., 1., 0., 0., 0., 0.),
SpatialVector (0., 0., 1., 0., 0., 0.)
);
model.AppendBody (Xtrans (Vector3d(0., 0., 0.)), joint, body);
VectorNd q = VectorNd::Zero(model.q_size);
VectorNd qdot = VectorNd::Zero(model.qdot_size);
double mass;
Vector3d com;
Vector3d angular_momentum;
qdot << 1., 0., 0.;
Utils::CalcCenterOfMass (model, q, qdot, NULL, mass, com, NULL, NULL, &angular_momentum);
REQUIRE (Vector3d (1.1, 0., 0.) == angular_momentum);
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qdot << 0., 1., 0.;
Utils::CalcCenterOfMass (model, q, qdot, NULL, mass, com, NULL, NULL, &angular_momentum);
REQUIRE (Vector3d (0., 2.2, 0.) == angular_momentum);
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qdot << 0., 0., 1.;
Utils::CalcCenterOfMass (model, q, qdot, NULL, mass, com, NULL, NULL, &angular_momentum);
REQUIRE (Vector3d (0., 0., 3.3) == angular_momentum);
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}
TEST_CASE_METHOD (TwoArms12DoF, __FILE__"_TestAngularMomentumSimple2", "") {
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double mass;
Vector3d com;
Vector3d angular_momentum;
Utils::CalcCenterOfMass (*model, q, qdot, NULL, mass, com, NULL, NULL, &angular_momentum);
REQUIRE (Vector3d (0., 0., 0.) == angular_momentum);
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qdot[0] = 1.;
qdot[1] = 2.;
qdot[2] = 3.;
Utils::CalcCenterOfMass (*model, q, qdot, NULL, mass, com, NULL, NULL, &angular_momentum);
// only a rough guess from test calculation
REQUIRE_THAT (Vector3d (3.3, 2.54, 1.5), AllCloseVector(angular_momentum, 1.0e-1, 1.0e-1));
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qdot[3] = -qdot[0];
qdot[4] = -qdot[1];
qdot[5] = -qdot[2];
ClearLogOutput();
Utils::CalcCenterOfMass (*model, q, qdot, NULL, mass, com, NULL, NULL, &angular_momentum);
REQUIRE (angular_momentum[0] == 0);
REQUIRE (angular_momentum[1] < 0);
REQUIRE (angular_momentum[2] == 0.);
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}
template <typename T>
void TestCoMComputation (
T &obj
) {
VectorNd Q = VectorNd::Random (obj.model->dof_count);
VectorNd QDot = VectorNd::Random (obj.model->dof_count);
VectorNd QDDot = VectorNd::Random (obj.model->dof_count);
// compute quantities directly from model
double mass_expected = 0.0;
UpdateKinematicsCustom(*obj.model, &Q, NULL, NULL);
for (unsigned int i = 1; i < obj.model->mBodies.size(); i++) {
// mass_expected += obj.model->I[i].m;
mass_expected += obj.model->mBodies[i].mMass;
}
double mass_actual = 0.0;
Vector3d com = Vector3d::Zero();
Utils::CalcCenterOfMass (
*obj.model,
Q, QDot, NULL,
mass_actual, com,
NULL, NULL
);
REQUIRE_THAT (mass_expected, IsClose(mass_actual, 1e-7, 1e-7));
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return;
}
TEST_CASE_METHOD (LinearInvertedPendulumModel, __FILE__"_TestCoMComputationLinearInvertedPendulumModel", "") {
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TestCoMComputation (*this);
}
TEST_CASE_METHOD (FixedJoint2DoF, __FILE__"_TestCoMComputationFixedJoint2DoF", "") {
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TestCoMComputation (*this);
}
TEST_CASE_METHOD (FixedBase6DoF12DoFFloatingBase, __FILE__"_TestCoMComputationFixedBase6DoF12DoFFloatingBase", "") {
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TestCoMComputation (*this);
}
TEST_CASE_METHOD (Human36, __FILE__"_TestCoMComputationHuman36", "") {
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TestCoMComputation (*this);
}
template <typename T>
void TestCoMAccelerationUsingFD (
T & obj,
const double TOL = 1e-7
) {
const double EPS = 1e-7;
obj.Q = VectorNd::Random (obj.model->dof_count);
obj.QDot = VectorNd::Random (obj.model->dof_count);
obj.QDDot = VectorNd::Random (obj.model->dof_count);
double mass = 0.0;
Vector3d com (Vector3d::Zero());
Vector3d com_vec (Vector3d::Zero());
Vector3d ang_mom (Vector3d::Zero());
Vector3d com_acc_nom (Vector3d::Zero());
Vector3d com_acc_fd (Vector3d::Zero());
Vector3d ch_ang_mom_nom (Vector3d::Zero());
Vector3d ch_ang_mom_fd (Vector3d::Zero());
// compute com acceleration nominal
Utils::CalcCenterOfMass (
*obj.model,
obj.Q, obj.QDot, &obj.QDDot,
mass,
com, &com_vec, &com_acc_nom,
&ang_mom, &ch_ang_mom_nom
);
// compute com acceleration using finite differences from velocity
Utils::CalcCenterOfMass (
*obj.model,
obj.Q + EPS*obj.QDot,
obj.QDot + EPS*obj.QDDot,
NULL,
mass, com, &com_acc_fd, NULL,
&ch_ang_mom_fd
);
com_acc_fd = (com_acc_fd - com_vec) / EPS;
ch_ang_mom_fd = (ch_ang_mom_fd - ang_mom) / EPS;
// check CoM acceleration
REQUIRE_THAT (com_acc_nom, AllCloseVector(com_acc_fd, TOL, TOL));
REQUIRE_THAT (ch_ang_mom_nom, AllCloseVector(ch_ang_mom_fd, TOL, TOL));
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return;
}
TEST_CASE_METHOD (LinearInvertedPendulumModel, __FILE__"_TestCoMAccelerationUsingFDLinearInvertedPendulumModel", "") {
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TestCoMAccelerationUsingFD (*this, 1e-8);
}
TEST_CASE_METHOD (FixedJoint2DoF, __FILE__"_TestCoMAccelerationUsingFDFixedJoint2DoF", "") {
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TestCoMAccelerationUsingFD (*this, 1e-7);
}
TEST_CASE_METHOD (FixedBase6DoF12DoFFloatingBase, __FILE__"_TestCoMAccelerationUsingFDFixedBase6DoF12DoFFloatingBase", "") {
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TestCoMAccelerationUsingFD (*this, 1e-6);
}
template <typename T>
void TestZMPComputationForNotMovingSystem(
T & obj,
const double TOL = 1e-8
) {
// Test ZMP against CoM projection for non-moving system (qdot, qddot = 0)
// for this configurations CoM and ZMP coincide
obj.Q = VectorNd::Random (obj.model->dof_count);
obj.QDot = VectorNd::Zero (obj.model->dof_count);
obj.QDDot = VectorNd::Zero (obj.model->dof_count);
Vector3d zmp (Vector3d::Zero());
Utils::CalcZeroMomentPoint (
*obj.model,
obj.Q, obj.QDot, obj.QDDot,
&zmp,
obj.contact_normal, obj.contact_point
);
double mass = 0.0;
Vector3d com (Vector3d::Zero());
Utils::CalcCenterOfMass (
*obj.model,
obj.Q, obj.QDot, NULL,
mass, com, NULL, NULL
);
// project CoM onto surface
double distance = (com - obj.contact_point).dot(obj.contact_normal);
com = com - distance * obj.contact_normal;
// check ZMP against CoM
REQUIRE_THAT (com, AllCloseVector(zmp, TOL, TOL));
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return;
}
TEST_CASE_METHOD (LinearInvertedPendulumModel, __FILE__"_TestZMPComputationForNotMovingSystemLinearInvertedPendulumModel", "") {
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TestZMPComputationForNotMovingSystem (*this, 1e-8);
}
template <typename T>
void TestZMPComputationAgainstTableCartModel(
T & obj,
const double TOL = 1e-8
) {
obj.Q = VectorNd::Random (obj.model->dof_count);
obj.QDot = VectorNd::Random (obj.model->dof_count);
obj.QDDot = VectorNd::Random (obj.model->dof_count);
Vector3d zmp (Vector3d::Zero());
Utils::CalcZeroMomentPoint (
*obj.model,
obj.Q, obj.QDot, obj.QDDot,
&zmp,
obj.contact_normal, obj.contact_point
);
double mass = 0.0;
Vector3d com (Vector3d::Zero());
Utils::CalcCenterOfMass (
*obj.model,
obj.Q, obj.QDot, NULL,
mass, com, NULL, NULL
);
com.set(
obj.Q[0] - com[2]/obj.model->gravity.norm()*obj.QDDot[0],
obj.Q[1] - com[2]/obj.model->gravity.norm()*obj.QDDot[1],
0.
);
// check ZMP against CoM
REQUIRE_THAT (com, AllCloseVector(zmp, TOL, TOL));
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return;
}
TEST_CASE_METHOD (LinearInvertedPendulumModel, __FILE__"_TestZMPComputationAgainstTableCartModelLinearInvertedPendulumModel", "") {
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TestZMPComputationAgainstTableCartModel (*this, 1e-8);
}