protot/3rdparty/rbdl/tests/MultiDofTests.cc

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#include <UnitTest++.h>
#include <iostream>
#include "Fixtures.h"
#include "Human36Fixture.h"
#include "rbdl/rbdl_mathutils.h"
#include "rbdl/Logging.h"
#include "rbdl/Model.h"
#include "rbdl/Kinematics.h"
#include "rbdl/Dynamics.h"
#include "rbdl/Constraints.h"
using namespace std;
using namespace RigidBodyDynamics;
using namespace RigidBodyDynamics::Math;
const double TEST_PREC = 1.0e-12;
struct SphericalJoint {
SphericalJoint () {
ClearLogOutput();
emulated_model.gravity = Vector3d (0., 0., -9.81);
multdof3_model.gravity = Vector3d (0., 0., -9.81);
eulerzyx_model.gravity = Vector3d (0., 0., -9.81);
body = Body (1., Vector3d (1., 0., 0.), Vector3d (1., 1., 1.));
joint_rot_zyx = Joint (
SpatialVector (0., 0., 1., 0., 0., 0.),
SpatialVector (0., 1., 0., 0., 0., 0.),
SpatialVector (1., 0., 0., 0., 0., 0.)
);
joint_spherical = Joint (JointTypeSpherical);
joint_eulerzyx = Joint (JointTypeEulerZYX);
joint_rot_y = Joint (SpatialVector (0., 1., 0., 0., 0., 0.));
emulated_model.AppendBody (Xtrans(Vector3d (0., 0., 0.)), joint_rot_y, body);
emu_body_id = emulated_model.AppendBody (Xtrans (Vector3d (1., 0., 0.)), joint_rot_zyx, body);
emu_child_id = emulated_model.AppendBody (Xtrans (Vector3d (1., 0., 0.)), joint_rot_y, body);
multdof3_model.AppendBody (Xtrans(Vector3d (0., 0., 0.)), joint_rot_y, body);
sph_body_id = multdof3_model.AppendBody (Xtrans (Vector3d (1., 0., 0.)), joint_spherical, body);
sph_child_id = multdof3_model.AppendBody (Xtrans (Vector3d (1., 0., 0.)), joint_rot_y, body);
eulerzyx_model.AppendBody (Xtrans(Vector3d (0., 0., 0.)), joint_rot_y, body);
eulerzyx_body_id = eulerzyx_model.AppendBody (Xtrans (Vector3d (1., 0., 0.)), joint_eulerzyx, body);
eulerzyx_child_id = eulerzyx_model.AppendBody (Xtrans (Vector3d (1., 0., 0.)), joint_rot_y, body);
emuQ = VectorNd::Zero ((size_t) emulated_model.q_size);
emuQDot = VectorNd::Zero ((size_t) emulated_model.qdot_size);
emuQDDot = VectorNd::Zero ((size_t) emulated_model.qdot_size);
emuTau = VectorNd::Zero ((size_t) emulated_model.qdot_size);
sphQ = VectorNd::Zero ((size_t) multdof3_model.q_size);
sphQDot = VectorNd::Zero ((size_t) multdof3_model.qdot_size);
sphQDDot = VectorNd::Zero ((size_t) multdof3_model.qdot_size);
sphTau = VectorNd::Zero ((size_t) multdof3_model.qdot_size);
eulerzyxQ = VectorNd::Zero ((size_t) eulerzyx_model.q_size);
eulerzyxQDot = VectorNd::Zero ((size_t) eulerzyx_model.qdot_size);
eulerzyxQDDot = VectorNd::Zero ((size_t) eulerzyx_model.qdot_size);
eulerzyxTau = VectorNd::Zero ((size_t) eulerzyx_model.qdot_size);
}
Joint joint_rot_zyx;
Joint joint_spherical;
Joint joint_eulerzyx;
Joint joint_rot_y;
Body body;
unsigned int emu_body_id, emu_child_id,
sph_body_id, sph_child_id,
eulerzyx_body_id, eulerzyx_child_id;
Model emulated_model;
Model multdof3_model;
Model eulerzyx_model;
VectorNd emuQ;
VectorNd emuQDot;
VectorNd emuQDDot;
VectorNd emuTau;
VectorNd sphQ;
VectorNd sphQDot;
VectorNd sphQDDot;
VectorNd sphTau;
VectorNd eulerzyxQ;
VectorNd eulerzyxQDot;
VectorNd eulerzyxQDDot;
VectorNd eulerzyxTau;
};
void ConvertQAndQDotFromEmulated (
const Model &emulated_model, const VectorNd &q_emulated, const VectorNd &qdot_emulated,
const Model &multdof3_model, VectorNd *q_spherical, VectorNd *qdot_spherical) {
for (unsigned int i = 1; i < multdof3_model.mJoints.size(); i++) {
unsigned int q_index = multdof3_model.mJoints[i].q_index;
if (multdof3_model.mJoints[i].mJointType == JointTypeSpherical) {
Quaternion quat = Quaternion::fromZYXAngles ( Vector3d (
q_emulated[q_index + 0], q_emulated[q_index + 1], q_emulated[q_index + 2]));
multdof3_model.SetQuaternion (i, quat, (*q_spherical));
Vector3d omega = angular_velocity_from_angle_rates (
Vector3d (q_emulated[q_index], q_emulated[q_index + 1], q_emulated[q_index + 2]),
Vector3d (qdot_emulated[q_index], qdot_emulated[q_index + 1], qdot_emulated[q_index + 2])
);
(*qdot_spherical)[q_index] = omega[0];
(*qdot_spherical)[q_index + 1] = omega[1];
(*qdot_spherical)[q_index + 2] = omega[2];
} else {
(*q_spherical)[q_index] = q_emulated[q_index];
(*qdot_spherical)[q_index] = qdot_emulated[q_index];
}
}
}
TEST(TestQuaternionIntegration ) {
double timestep = 0.001;
Vector3d zyx_angles_t0 (0.1, 0.2, 0.3);
Vector3d zyx_rates (3., 5., 2.);
Vector3d zyx_angles_t1 = zyx_angles_t0 + timestep * zyx_rates;
Quaternion q_zyx_t1 = Quaternion::fromZYXAngles (zyx_angles_t1);
Quaternion q_t0 = Quaternion::fromZYXAngles (zyx_angles_t0);
Vector3d w_base = global_angular_velocity_from_rates (zyx_angles_t0, zyx_rates);
Quaternion q_t1 = q_t0.timeStep (w_base, timestep);
// Note: we test with a rather crude precision. My guess for the error is
// that we compare two different things:
// A) integration under the assumption that the euler rates are
// constant
// B) integration under the assumption that the angular velocity is
// constant
// However I am not entirely sure about this...
CHECK_ARRAY_CLOSE (q_zyx_t1.data(), q_t1.data(), 4, 1.0e-5);
}
TEST_FIXTURE(SphericalJoint, TestQIndices) {
CHECK_EQUAL (0u, multdof3_model.mJoints[1].q_index);
CHECK_EQUAL (1u, multdof3_model.mJoints[2].q_index);
CHECK_EQUAL (4u, multdof3_model.mJoints[3].q_index);
CHECK_EQUAL (5u, emulated_model.q_size);
CHECK_EQUAL (5u, emulated_model.qdot_size);
CHECK_EQUAL (6u, multdof3_model.q_size);
CHECK_EQUAL (5u, multdof3_model.qdot_size);
CHECK_EQUAL (5u, multdof3_model.multdof3_w_index[2]);
}
TEST_FIXTURE(SphericalJoint, TestGetQuaternion) {
multdof3_model.AppendBody (Xtrans (Vector3d (1., 0., 0.)), joint_spherical, body);
sphQ = VectorNd::Zero ((size_t) multdof3_model.q_size);
sphQDot = VectorNd::Zero ((size_t) multdof3_model.qdot_size);
sphQDDot = VectorNd::Zero ((size_t) multdof3_model.qdot_size);
sphTau = VectorNd::Zero ((size_t) multdof3_model.qdot_size);
CHECK_EQUAL (10u, multdof3_model.q_size);
CHECK_EQUAL (8u, multdof3_model.qdot_size);
CHECK_EQUAL (0u, multdof3_model.mJoints[1].q_index);
CHECK_EQUAL (1u, multdof3_model.mJoints[2].q_index);
CHECK_EQUAL (4u, multdof3_model.mJoints[3].q_index);
CHECK_EQUAL (5u, multdof3_model.mJoints[4].q_index);
CHECK_EQUAL (8u, multdof3_model.multdof3_w_index[2]);
CHECK_EQUAL (9u, multdof3_model.multdof3_w_index[4]);
sphQ[0] = 100.;
sphQ[1] = 0.;
sphQ[2] = 1.;
sphQ[3] = 2.;
sphQ[4] = 100.;
sphQ[5] = -6.;
sphQ[6] = -7.;
sphQ[7] = -8;
sphQ[8] = 4.;
sphQ[9] = -9.;
Quaternion reference_1 (0., 1., 2., 4.);
Quaternion quat_1 = multdof3_model.GetQuaternion (2, sphQ);
CHECK_ARRAY_EQUAL (reference_1.data(), quat_1.data(), 4);
Quaternion reference_3 (-6., -7., -8., -9.);
Quaternion quat_3 = multdof3_model.GetQuaternion (4, sphQ);
CHECK_ARRAY_EQUAL (reference_3.data(), quat_3.data(), 4);
}
TEST_FIXTURE(SphericalJoint, TestSetQuaternion) {
multdof3_model.AppendBody (Xtrans (Vector3d (1., 0., 0.)), joint_spherical, body);
sphQ = VectorNd::Zero ((size_t) multdof3_model.q_size);
sphQDot = VectorNd::Zero ((size_t) multdof3_model.qdot_size);
sphQDDot = VectorNd::Zero ((size_t) multdof3_model.qdot_size);
sphTau = VectorNd::Zero ((size_t) multdof3_model.qdot_size);
Quaternion reference_1 (0., 1., 2., 3.);
multdof3_model.SetQuaternion (2, reference_1, sphQ);
Quaternion test = multdof3_model.GetQuaternion (2, sphQ);
CHECK_ARRAY_EQUAL (reference_1.data(), test.data(), 4);
Quaternion reference_2 (11., 22., 33., 44.);
multdof3_model.SetQuaternion (4, reference_2, sphQ);
test = multdof3_model.GetQuaternion (4, sphQ);
CHECK_ARRAY_EQUAL (reference_2.data(), test.data(), 4);
}
TEST_FIXTURE(SphericalJoint, TestOrientation) {
emuQ[0] = 1.1;
emuQ[1] = 1.1;
emuQ[2] = 1.1;
emuQ[3] = 1.1;
for (unsigned int i = 0; i < emuQ.size(); i++) {
sphQ[i] = emuQ[i];
}
Quaternion quat = Quaternion::fromAxisAngle (Vector3d (0., 0., 1.), emuQ[0])
* Quaternion::fromAxisAngle (Vector3d (0., 1., 0.), emuQ[1])
* Quaternion::fromAxisAngle (Vector3d (1., 0., 0.), emuQ[2]);
multdof3_model.SetQuaternion (2, quat, sphQ);
Matrix3d emu_orientation = CalcBodyWorldOrientation (emulated_model, emuQ, emu_child_id);
Matrix3d sph_orientation = CalcBodyWorldOrientation (multdof3_model, sphQ, sph_child_id);
CHECK_ARRAY_CLOSE (emu_orientation.data(), sph_orientation.data(), 9, TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestUpdateKinematics) {
emuQ[0] = 1.;
emuQ[1] = 1.;
emuQ[2] = 1.;
emuQ[3] = 1.;
emuQ[4] = 1.;
emuQDot[0] = 1.;
emuQDot[1] = 1.;
emuQDot[2] = 1.;
emuQDot[3] = 1.;
emuQDot[4] = 1.;
emuQDDot[0] = 1.;
emuQDDot[1] = 1.;
emuQDDot[2] = 1.;
emuQDDot[3] = 1.;
emuQDDot[4] = 1.;
ConvertQAndQDotFromEmulated (emulated_model, emuQ, emuQDot, multdof3_model, &sphQ, &sphQDot);
ConvertQAndQDotFromEmulated (emulated_model, emuQ, emuQDDot, multdof3_model, &sphQ, &sphQDDot);
Vector3d a = angular_acceleration_from_angle_rates (
Vector3d (emuQ[3], emuQ[2], emuQ[1]),
Vector3d (emuQDot[3], emuQDot[2], emuQDot[1]),
Vector3d (emuQDDot[3], emuQDDot[2], emuQDDot[1])
);
sphQDDot[0] = emuQDDot[0];
sphQDDot[1] = a[0];
sphQDDot[2] = a[1];
sphQDDot[3] = a[2];
sphQDDot[4] = emuQDDot[4];
UpdateKinematicsCustom (emulated_model, &emuQ, &emuQDot, &emuQDDot);
UpdateKinematicsCustom (multdof3_model, &sphQ, &sphQDot, &sphQDDot);
CHECK_ARRAY_CLOSE (emulated_model.v[emu_body_id].data(), multdof3_model.v[sph_body_id].data(), 6, TEST_PREC);
CHECK_ARRAY_CLOSE (emulated_model.a[emu_body_id].data(), multdof3_model.a[sph_body_id].data(), 6, TEST_PREC);
UpdateKinematics (multdof3_model, sphQ, sphQDot, sphQDDot);
CHECK_ARRAY_CLOSE (emulated_model.v[emu_child_id].data(), multdof3_model.v[sph_child_id].data(), 6, TEST_PREC);
CHECK_ARRAY_CLOSE (emulated_model.a[emu_child_id].data(), multdof3_model.a[sph_child_id].data(), 6, TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestSpatialVelocities) {
emuQ[0] = 1.;
emuQ[1] = 2.;
emuQ[2] = 3.;
emuQ[3] = 4.;
emuQDot[0] = 4.;
emuQDot[1] = 2.;
emuQDot[2] = 3.;
emuQDot[3] = 6.;
ConvertQAndQDotFromEmulated (emulated_model, emuQ, emuQDot, multdof3_model, &sphQ, &sphQDot);
UpdateKinematicsCustom (emulated_model, &emuQ, &emuQDot, NULL);
UpdateKinematicsCustom (multdof3_model, &sphQ, &sphQDot, NULL);
CHECK_ARRAY_CLOSE (emulated_model.v[emu_child_id].data(), multdof3_model.v[sph_child_id].data(), 6, TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestForwardDynamicsQAndQDot) {
emuQ[0] = 1.1;
emuQ[1] = 1.2;
emuQ[2] = 1.3;
emuQ[3] = 1.4;
emuQDot[0] = 2.2;
emuQDot[1] = 2.3;
emuQDot[2] = 2.4;
emuQDot[3] = 2.5;
ConvertQAndQDotFromEmulated (emulated_model, emuQ, emuQDot, multdof3_model, &sphQ, &sphQDot);
ForwardDynamics (emulated_model, emuQ, emuQDot, emuTau, emuQDDot);
ForwardDynamics (multdof3_model, sphQ, sphQDot, sphTau, sphQDDot);
CHECK_ARRAY_CLOSE (emulated_model.a[emu_child_id].data(), multdof3_model.a[sph_child_id].data(), 6, TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestDynamicsConsistencyRNEA_ABA ) {
emuQ[0] = 1.1;
emuQ[1] = 1.2;
emuQ[2] = 1.3;
emuQ[3] = 1.4;
emuQ[4] = 1.5;
emuQDot[0] = 1.;
emuQDot[1] = 2.;
emuQDot[2] = 3.;
emuQDot[3] = 4.;
emuQDot[4] = 5.;
sphTau[0] = 5.;
sphTau[1] = 4.;
sphTau[2] = 7.;
sphTau[3] = 3.;
sphTau[4] = 2.;
ConvertQAndQDotFromEmulated (emulated_model, emuQ, emuQDot, multdof3_model, &sphQ, &sphQDot);
ForwardDynamics (multdof3_model, sphQ, sphQDot, sphTau, sphQDDot);
VectorNd tau_id (VectorNd::Zero (multdof3_model.qdot_size));
InverseDynamics (multdof3_model, sphQ, sphQDot, sphQDDot, tau_id);
CHECK_ARRAY_CLOSE (sphTau.data(), tau_id.data(), tau_id.size(), TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestCRBA ) {
emuQ[0] = 1.1;
emuQ[1] = 1.2;
emuQ[2] = 1.3;
emuQ[3] = 1.4;
emuQ[4] = 1.5;
emuQDot[0] = 1.;
emuQDot[1] = 2.;
emuQDot[2] = 3.;
emuQDot[3] = 4.;
emuQDot[4] = 5.;
sphTau[0] = 5.;
sphTau[1] = 4.;
sphTau[2] = 7.;
sphTau[3] = 3.;
sphTau[4] = 2.;
ConvertQAndQDotFromEmulated (emulated_model, emuQ, emuQDot, multdof3_model, &sphQ, &sphQDot);
MatrixNd H_crba (MatrixNd::Zero (multdof3_model.qdot_size, multdof3_model.qdot_size));
UpdateKinematicsCustom (multdof3_model, &sphQ, NULL, NULL);
CompositeRigidBodyAlgorithm (multdof3_model, sphQ, H_crba, false);
MatrixNd H_id (MatrixNd::Zero (multdof3_model.qdot_size, multdof3_model.qdot_size));
VectorNd H_col = VectorNd::Zero (multdof3_model.qdot_size);
VectorNd QDDot_zero = VectorNd::Zero (multdof3_model.qdot_size);
for (unsigned int i = 0; i < multdof3_model.qdot_size; i++) {
// compute each column
VectorNd delta_a = VectorNd::Zero (multdof3_model.qdot_size);
delta_a[i] = 1.;
// compute ID (model, q, qdot, delta_a)
VectorNd id_delta = VectorNd::Zero (multdof3_model.qdot_size);
InverseDynamics (multdof3_model, sphQ, sphQDot, delta_a, id_delta);
// compute ID (model, q, qdot, zero)
VectorNd id_zero = VectorNd::Zero (multdof3_model.qdot_size);
InverseDynamics (multdof3_model, sphQ, sphQDot, QDDot_zero, id_zero);
H_col = id_delta - id_zero;
H_id.block(0, i, multdof3_model.qdot_size, 1) = H_col;
}
CHECK_ARRAY_CLOSE (H_id.data(), H_crba.data(), multdof3_model.qdot_size * multdof3_model.qdot_size, TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestForwardDynamicsLagrangianVsABA ) {
emuQ[0] = 1.1;
emuQ[1] = 1.2;
emuQ[2] = 1.3;
emuQ[3] = 1.4;
emuQ[4] = 1.5;
emuQDot[0] = 1.;
emuQDot[1] = 2.;
emuQDot[2] = 3.;
emuQDot[3] = 4.;
emuQDot[4] = 5.;
sphTau[0] = 5.;
sphTau[1] = 4.;
sphTau[2] = 7.;
sphTau[3] = 3.;
sphTau[4] = 2.;
ConvertQAndQDotFromEmulated (emulated_model, emuQ, emuQDot, multdof3_model, &sphQ, &sphQDot);
VectorNd QDDot_aba = VectorNd::Zero (multdof3_model.qdot_size);
VectorNd QDDot_lag = VectorNd::Zero (multdof3_model.qdot_size);
ForwardDynamicsLagrangian (multdof3_model, sphQ, sphQDot, sphTau, QDDot_lag);
ForwardDynamics (multdof3_model, sphQ, sphQDot, sphTau, QDDot_aba);
CHECK_ARRAY_CLOSE (QDDot_lag.data(), QDDot_aba.data(), multdof3_model.qdot_size, TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestContactsLagrangian) {
ConstraintSet constraint_set_emu;
constraint_set_emu.AddContactConstraint (emu_child_id, Vector3d (0., 0., -1.), Vector3d (1., 0., 0.));
constraint_set_emu.AddContactConstraint (emu_child_id, Vector3d (0., 0., -1.), Vector3d (0., 1., 0.));
constraint_set_emu.AddContactConstraint (emu_child_id, Vector3d (0., 0., -1.), Vector3d (0., 0., 1.));
constraint_set_emu.Bind(emulated_model);
ConstraintSet constraint_set_sph;
constraint_set_sph.AddContactConstraint (sph_child_id, Vector3d (0., 0., -1.), Vector3d (1., 0., 0.));
constraint_set_sph.AddContactConstraint (sph_child_id, Vector3d (0., 0., -1.), Vector3d (0., 1., 0.));
constraint_set_sph.AddContactConstraint (sph_child_id, Vector3d (0., 0., -1.), Vector3d (0., 0., 1.));
constraint_set_sph.Bind(multdof3_model);
ForwardDynamicsConstraintsDirect (emulated_model, emuQ, emuQDot, emuTau, constraint_set_emu, emuQDDot);
VectorNd emu_force_lagrangian = constraint_set_emu.force;
ForwardDynamicsConstraintsDirect (multdof3_model, sphQ, sphQDot, sphTau, constraint_set_sph, sphQDDot);
VectorNd sph_force_lagrangian = constraint_set_sph.force;
CHECK_ARRAY_CLOSE (emu_force_lagrangian.data(), sph_force_lagrangian.data(), 3, TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestContacts) {
ConstraintSet constraint_set_emu;
constraint_set_emu.AddContactConstraint (emu_child_id, Vector3d (0., 0., -1.), Vector3d (1., 0., 0.));
constraint_set_emu.AddContactConstraint (emu_child_id, Vector3d (0., 0., -1.), Vector3d (0., 1., 0.));
constraint_set_emu.AddContactConstraint (emu_child_id, Vector3d (0., 0., -1.), Vector3d (0., 0., 1.));
constraint_set_emu.Bind(emulated_model);
ConstraintSet constraint_set_sph;
constraint_set_sph.AddContactConstraint (sph_child_id, Vector3d (0., 0., -1.), Vector3d (1., 0., 0.));
constraint_set_sph.AddContactConstraint (sph_child_id, Vector3d (0., 0., -1.), Vector3d (0., 1., 0.));
constraint_set_sph.AddContactConstraint (sph_child_id, Vector3d (0., 0., -1.), Vector3d (0., 0., 1.));
constraint_set_sph.Bind(multdof3_model);
ForwardDynamicsContactsKokkevis (emulated_model, emuQ, emuQDot, emuTau, constraint_set_emu, emuQDDot);
VectorNd emu_force_kokkevis = constraint_set_emu.force;
ForwardDynamicsContactsKokkevis (multdof3_model, sphQ, sphQDot, sphTau, constraint_set_sph, sphQDDot);
VectorNd sph_force_kokkevis = constraint_set_sph.force;
CHECK_ARRAY_CLOSE (emu_force_kokkevis.data(), sph_force_kokkevis.data(), 3, TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestEulerZYXvsEmulatedLagrangian ) {
emuQ[0] = 1.1;
emuQ[1] = 1.2;
emuQ[2] = 1.3;
emuQ[3] = 1.4;
emuQ[4] = 1.5;
emuQDot[0] = 1.;
emuQDot[1] = 2.;
emuQDot[2] = 3.;
emuQDot[3] = 4.;
emuQDot[4] = 5.;
emuTau[0] = 5.;
emuTau[1] = 4.;
emuTau[2] = 7.;
emuTau[3] = 3.;
emuTau[4] = 2.;
VectorNd QDDot_emu = VectorNd::Zero (emulated_model.qdot_size);
VectorNd QDDot_eulerzyx = VectorNd::Zero (eulerzyx_model.qdot_size);
ForwardDynamicsLagrangian (emulated_model, emuQ, emuQDot, emuTau, QDDot_emu);
ForwardDynamicsLagrangian (eulerzyx_model, emuQ, emuQDot, emuTau, QDDot_eulerzyx);
CHECK_ARRAY_CLOSE (QDDot_emu.data(), QDDot_eulerzyx.data(), emulated_model.qdot_size, TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestEulerZYXvsEmulatedArticulatedBodyAlgorithm ) {
emuQ[0] = 1.1;
emuQ[1] = 1.2;
emuQ[2] = 1.3;
emuQ[3] = 1.4;
emuQ[4] = 1.5;
emuQDot[0] = 1.;
emuQDot[1] = 2.;
emuQDot[2] = 3.;
emuQDot[3] = 4.;
emuQDot[4] = 5.;
emuTau[0] = 5.;
emuTau[1] = 4.;
emuTau[2] = 7.;
emuTau[3] = 3.;
emuTau[4] = 2.;
VectorNd QDDot_emu = VectorNd::Zero (emulated_model.qdot_size);
VectorNd QDDot_eulerzyx = VectorNd::Zero (eulerzyx_model.qdot_size);
ForwardDynamics (emulated_model, emuQ, emuQDot, emuTau, QDDot_emu);
ForwardDynamics (eulerzyx_model, emuQ, emuQDot, emuTau, QDDot_eulerzyx);
CHECK_ARRAY_CLOSE (QDDot_emu.data(), QDDot_eulerzyx.data(), emulated_model.qdot_size, TEST_PREC);
}
TEST_FIXTURE(SphericalJoint, TestEulerZYXvsEmulatedContacts ) {
emuQ[0] = 1.1;
emuQ[1] = 1.2;
emuQ[2] = 1.3;
emuQ[3] = 1.4;
emuQ[4] = 1.5;
emuQDot[0] = 1.;
emuQDot[1] = 2.;
emuQDot[2] = 3.;
emuQDot[3] = 4.;
emuQDot[4] = 5.;
emuTau[0] = 5.;
emuTau[1] = 4.;
emuTau[2] = 7.;
emuTau[3] = 3.;
emuTau[4] = 2.;
VectorNd QDDot_emu = VectorNd::Zero (emulated_model.qdot_size);
VectorNd QDDot_eulerzyx = VectorNd::Zero (eulerzyx_model.qdot_size);
ConstraintSet CS_euler;
CS_euler.AddContactConstraint (eulerzyx_child_id, Vector3d (1., 1., 1.), Vector3d (1., 0., 0.));
CS_euler.AddContactConstraint (eulerzyx_child_id, Vector3d (0., 0., 0.), Vector3d (0., 1., 0.));
CS_euler.AddContactConstraint (eulerzyx_child_id, Vector3d (0., 0., 0.), Vector3d (0., 0., 1.));
CS_euler.Bind (eulerzyx_model);
ConstraintSet CS_emulated;
CS_emulated.AddContactConstraint (emu_child_id, Vector3d (1., 1., 1.), Vector3d (1., 0., 0.));
CS_emulated.AddContactConstraint (emu_child_id, Vector3d (0., 0., 0.), Vector3d (0., 1., 0.));
CS_emulated.AddContactConstraint (emu_child_id, Vector3d (0., 0., 0.), Vector3d (0., 0., 1.));
CS_emulated.Bind (emulated_model);
ForwardDynamicsConstraintsDirect (emulated_model, emuQ, emuQDot, emuTau, CS_emulated, QDDot_emu);
ForwardDynamicsConstraintsDirect (eulerzyx_model, emuQ, emuQDot, emuTau, CS_euler, QDDot_eulerzyx);
CHECK_ARRAY_CLOSE (QDDot_emu.data(), QDDot_eulerzyx.data(), emulated_model.qdot_size, TEST_PREC);
ClearLogOutput();
ForwardDynamicsContactsKokkevis (emulated_model, emuQ, emuQDot, emuTau, CS_emulated, QDDot_emu);
ForwardDynamicsContactsKokkevis (eulerzyx_model, emuQ, emuQDot, emuTau, CS_euler, QDDot_eulerzyx);
CHECK_ARRAY_CLOSE (QDDot_emu.data(), QDDot_eulerzyx.data(), emulated_model.qdot_size, TEST_PREC * QDDot_emu.norm());
ForwardDynamicsContactsKokkevis (emulated_model, emuQ, emuQDot, emuTau, CS_emulated, QDDot_emu);
ForwardDynamicsConstraintsDirect (eulerzyx_model, emuQ, emuQDot, emuTau, CS_euler, QDDot_eulerzyx);
CHECK_ARRAY_CLOSE (QDDot_emu.data(), QDDot_eulerzyx.data(), emulated_model.qdot_size, TEST_PREC * QDDot_emu.norm());
}
TEST_FIXTURE(SphericalJoint, TestEulerZYXvsEmulatedCRBA ) {
emuQ[0] = 1.1;
emuQ[1] = 1.2;
emuQ[2] = 1.3;
emuQ[3] = 1.4;
emuQ[4] = 1.5;
MatrixNd H_emulated (MatrixNd::Zero (emulated_model.q_size, emulated_model.q_size));
MatrixNd H_eulerzyx (MatrixNd::Zero (eulerzyx_model.q_size, eulerzyx_model.q_size));
CompositeRigidBodyAlgorithm (emulated_model, emuQ, H_emulated);
CompositeRigidBodyAlgorithm (eulerzyx_model, emuQ, H_eulerzyx);
CHECK_ARRAY_CLOSE (H_emulated.data(), H_eulerzyx.data(), emulated_model.q_size * emulated_model.q_size, TEST_PREC);
}
TEST ( TestJointTypeTranslationZYX ) {
Model model_emulated;
Model model_3dof;
Body body (1., Vector3d (1., 2., 1.), Matrix3d (1., 0., 0, 0., 1., 0., 0., 0., 1.));
Joint joint_emulated (
SpatialVector (0., 0., 0., 1., 0., 0.),
SpatialVector (0., 0., 0., 0., 1., 0.),
SpatialVector (0., 0., 0., 0., 0., 1.)
);
Joint joint_3dof (JointTypeTranslationXYZ);
model_emulated.AppendBody (SpatialTransform (), joint_emulated, body);
model_3dof.AppendBody (SpatialTransform (), joint_3dof, body);
VectorNd q (VectorNd::Zero (model_emulated.q_size));
VectorNd qdot (VectorNd::Zero (model_emulated.qdot_size));
VectorNd qddot_emulated (VectorNd::Zero (model_emulated.qdot_size));
VectorNd qddot_3dof (VectorNd::Zero (model_emulated.qdot_size));
VectorNd tau (VectorNd::Zero (model_emulated.qdot_size));
for (int i = 0; i < q.size(); i++) {
q[i] = 1.1 * (static_cast<double>(i + 1));
qdot[i] = 0.1 * (static_cast<double>(i + 1));
qddot_3dof[i] = 0.21 * (static_cast<double>(i + 1));
tau[i] = 2.1 * (static_cast<double>(i + 1));
}
qddot_emulated = qddot_3dof;
VectorNd id_emulated (tau);
VectorNd id_3dof(tau);
InverseDynamics (model_emulated, q, qdot, qddot_emulated, id_emulated);
InverseDynamics (model_3dof, q, qdot, qddot_emulated, id_3dof);
CHECK_ARRAY_CLOSE (id_emulated.data(), id_3dof.data(), id_emulated.size(), TEST_PREC * id_emulated.norm());
ForwardDynamicsLagrangian (model_emulated, q, qdot, tau, qddot_emulated);
ForwardDynamicsLagrangian (model_3dof, q, qdot, tau, qddot_3dof);
CHECK_ARRAY_EQUAL (qddot_emulated.data(), qddot_3dof.data(), qddot_emulated.size());
MatrixNd H_emulated (MatrixNd::Zero (q.size(), q.size()));
MatrixNd H_3dof (MatrixNd::Zero (q.size(), q.size()));
CompositeRigidBodyAlgorithm (model_emulated, q, H_emulated);
CompositeRigidBodyAlgorithm (model_3dof, q, H_3dof);
CHECK_ARRAY_CLOSE (H_emulated.data(), H_3dof.data(), q.size() * q.size(), TEST_PREC);
}
TEST ( TestJointTypeEulerXYZ ) {
Model model_emulated;
Model model_3dof;
Body body (1., Vector3d (1., 2., 1.), Matrix3d (1., 0., 0, 0., 1., 0., 0., 0., 1.));
Joint joint_emulated (
SpatialVector (1., 0., 0., 0., 0., 0.),
SpatialVector (0., 1., 0., 0., 0., 0.),
SpatialVector (0., 0., 1., 0., 0., 0.)
);
Joint joint_3dof (JointTypeEulerXYZ);
model_emulated.AppendBody (SpatialTransform (), joint_emulated, body);
model_3dof.AppendBody (SpatialTransform (), joint_3dof, body);
VectorNd q (VectorNd::Zero (model_emulated.q_size));
VectorNd qdot (VectorNd::Zero (model_emulated.qdot_size));
VectorNd qddot_emulated (VectorNd::Zero (model_emulated.qdot_size));
VectorNd qddot_3dof (VectorNd::Zero (model_emulated.qdot_size));
VectorNd tau (VectorNd::Zero (model_emulated.qdot_size));
for (int i = 0; i < q.size(); i++) {
q[i] = 1.1 * (static_cast<double>(i + 1));
qdot[i] = 0.55* (static_cast<double>(i + 1));
qddot_emulated[i] = 0.23 * (static_cast<double>(i + 1));
qddot_3dof[i] = 0.22 * (static_cast<double>(i + 1));
tau[i] = 2.1 * (static_cast<double>(i + 1));
}
UpdateKinematicsCustom (model_emulated, &q, &qdot, &qddot_emulated);
UpdateKinematicsCustom (model_3dof, &q, &qdot, &qddot_emulated);
CHECK_ARRAY_EQUAL (model_emulated.X_base[3].E.data(), model_3dof.X_base[1].E.data(), 9);
CHECK_ARRAY_EQUAL (model_emulated.v[3].data(), model_3dof.v[1].data(), 6);
ForwardDynamicsLagrangian (model_emulated, q, qdot, tau, qddot_emulated);
ForwardDynamicsLagrangian (model_3dof, q, qdot, tau, qddot_3dof);
CHECK_ARRAY_CLOSE (qddot_emulated.data(), qddot_3dof.data(), qddot_emulated.size(), TEST_PREC);
MatrixNd H_emulated (MatrixNd::Zero (q.size(), q.size()));
MatrixNd H_3dof (MatrixNd::Zero (q.size(), q.size()));
CompositeRigidBodyAlgorithm (model_emulated, q, H_emulated);
CompositeRigidBodyAlgorithm (model_3dof, q, H_3dof);
CHECK_ARRAY_CLOSE (H_emulated.data(), H_3dof.data(), q.size() * q.size(), TEST_PREC);
}
TEST ( TestJointTypeEulerYXZ ) {
Model model_emulated;
Model model_3dof;
Body body (1., Vector3d (1., 2., 1.), Matrix3d (1., 0., 0, 0., 1., 0., 0., 0., 1.));
Joint joint_emulated (
SpatialVector (0., 1., 0., 0., 0., 0.),
SpatialVector (1., 0., 0., 0., 0., 0.),
SpatialVector (0., 0., 1., 0., 0., 0.)
);
Joint joint_3dof (JointTypeEulerYXZ);
model_emulated.AppendBody (SpatialTransform (), joint_emulated, body);
model_3dof.AppendBody (SpatialTransform (), joint_3dof, body);
VectorNd q (VectorNd::Zero (model_emulated.q_size));
VectorNd qdot (VectorNd::Zero (model_emulated.qdot_size));
VectorNd qddot_emulated (VectorNd::Zero (model_emulated.qdot_size));
VectorNd qddot_3dof (VectorNd::Zero (model_emulated.qdot_size));
VectorNd tau (VectorNd::Zero (model_emulated.qdot_size));
for (int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qddot_3dof[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
qddot_emulated = qddot_3dof;
UpdateKinematicsCustom (model_emulated, &q, &qdot, &qddot_emulated);
UpdateKinematicsCustom (model_3dof, &q, &qdot, &qddot_emulated);
CHECK_ARRAY_CLOSE (model_emulated.X_base[3].E.data(), model_3dof.X_base[1].E.data(), 9, TEST_PREC);
CHECK_ARRAY_CLOSE (model_emulated.v[3].data(), model_3dof.v[1].data(), 6, TEST_PREC);
VectorNd id_emulated (tau);
VectorNd id_3dof(tau);
InverseDynamics (model_emulated, q, qdot, qddot_emulated, id_emulated);
InverseDynamics (model_3dof, q, qdot, qddot_emulated, id_3dof);
CHECK_ARRAY_CLOSE (id_emulated.data(), id_3dof.data(), id_emulated.size(), TEST_PREC);
ForwardDynamicsLagrangian (model_emulated, q, qdot, tau, qddot_emulated);
ForwardDynamicsLagrangian (model_3dof, q, qdot, tau, qddot_3dof);
CHECK_ARRAY_CLOSE (qddot_emulated.data(), qddot_3dof.data(), qddot_emulated.size(), TEST_PREC);
MatrixNd H_emulated (MatrixNd::Zero (q.size(), q.size()));
MatrixNd H_3dof (MatrixNd::Zero (q.size(), q.size()));
CompositeRigidBodyAlgorithm (model_emulated, q, H_emulated);
CompositeRigidBodyAlgorithm (model_3dof, q, H_3dof);
CHECK_ARRAY_CLOSE (H_emulated.data(), H_3dof.data(), q.size() * q.size(), TEST_PREC);
}
TEST_FIXTURE (Human36, TestUpdateKinematics) {
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qddot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
VectorNd id_emulated (tau);
VectorNd id_3dof (tau);
UpdateKinematics (*model_emulated, q, qdot, qddot);
UpdateKinematics (*model_3dof, q, qdot, qddot);
CHECK_ARRAY_CLOSE (model_emulated->v[body_id_emulated[BodyPelvis]].data(), model_3dof->v[body_id_3dof[BodyPelvis]].data(), 6, TEST_PREC);
CHECK_ARRAY_CLOSE (model_emulated->v[body_id_emulated[BodyThighRight]].data(), model_3dof->v[body_id_3dof[BodyThighRight]].data(), 6, TEST_PREC);
CHECK_ARRAY_CLOSE (model_emulated->v[body_id_emulated[BodyShankRight]].data(), model_3dof->v[body_id_3dof[BodyShankRight]].data(), 6, TEST_PREC);
}
TEST_FIXTURE (Human36, TestInverseDynamics) {
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qddot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
VectorNd id_emulated (tau);
VectorNd id_3dof (tau);
ClearLogOutput();
InverseDynamics (*model_emulated, q, qdot, qddot, id_emulated);
InverseDynamics (*model_3dof, q, qdot, qddot, id_3dof);
CHECK_ARRAY_CLOSE (id_emulated.data(), id_3dof.data(), id_emulated.size(), TEST_PREC * id_emulated.norm());
}
TEST_FIXTURE (Human36, TestNonlinearEffects) {
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qddot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
VectorNd nle_emulated (tau);
VectorNd nle_3dof (tau);
ClearLogOutput();
NonlinearEffects (*model_emulated, q, qdot, nle_emulated);
NonlinearEffects (*model_3dof, q, qdot, nle_3dof);
CHECK_ARRAY_CLOSE (nle_emulated.data(), nle_3dof.data(), nle_emulated.size(), TEST_PREC * nle_emulated.norm());
}
TEST_FIXTURE (Human36, TestContactsEmulatedLagrangianKokkevis) {
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
VectorNd qddot_lagrangian (qddot_emulated);
VectorNd qddot_kokkevis (qddot_emulated);
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_1B1C_emulated, qddot_lagrangian);
ForwardDynamicsContactsKokkevis (*model_emulated, q, qdot, tau, constraints_1B1C_emulated, qddot_kokkevis);
CHECK_ARRAY_CLOSE (qddot_lagrangian.data(), qddot_kokkevis.data(), qddot_lagrangian.size(), TEST_PREC * qddot_lagrangian.norm());
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_1B4C_emulated, qddot_lagrangian);
ForwardDynamicsContactsKokkevis (*model_emulated, q, qdot, tau, constraints_1B4C_emulated, qddot_kokkevis);
CHECK_ARRAY_CLOSE (qddot_lagrangian.data(), qddot_kokkevis.data(), qddot_lagrangian.size(), TEST_PREC * qddot_lagrangian.norm());
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_4B4C_emulated, qddot_lagrangian);
ForwardDynamicsContactsKokkevis (*model_emulated, q, qdot, tau, constraints_4B4C_emulated, qddot_kokkevis);
CHECK_ARRAY_CLOSE (qddot_lagrangian.data(), qddot_kokkevis.data(), qddot_lagrangian.size(), TEST_PREC * qddot_lagrangian.norm());
}
TEST_FIXTURE (Human36, TestContactsEmulatedLagrangianSparse) {
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = -0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
VectorNd qddot_lagrangian (qddot_emulated);
VectorNd qddot_sparse (qddot_emulated);
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_1B1C_emulated, qddot_lagrangian);
ForwardDynamicsConstraintsRangeSpaceSparse (*model_emulated, q, qdot, tau, constraints_1B1C_emulated, qddot_sparse);
CHECK_ARRAY_CLOSE (qddot_lagrangian.data(), qddot_sparse.data(), qddot_lagrangian.size(), TEST_PREC * qddot_lagrangian.norm());
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_1B4C_emulated, qddot_lagrangian);
ForwardDynamicsConstraintsRangeSpaceSparse (*model_emulated, q, qdot, tau, constraints_1B4C_emulated, qddot_sparse);
CHECK_ARRAY_CLOSE (qddot_lagrangian.data(), qddot_sparse.data(), qddot_lagrangian.size(), TEST_PREC * qddot_lagrangian.norm());
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_4B4C_emulated, qddot_lagrangian);
ForwardDynamicsConstraintsRangeSpaceSparse (*model_emulated, q, qdot, tau, constraints_4B4C_emulated, qddot_sparse);
CHECK_ARRAY_CLOSE (qddot_lagrangian.data(), qddot_sparse.data(), qddot_lagrangian.size(), TEST_PREC * qddot_lagrangian.norm());
}
TEST_FIXTURE (Human36, TestContactsEmulatedLagrangianNullSpace) {
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = -0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
VectorNd qddot_lagrangian (qddot_emulated);
VectorNd qddot_nullspace (qddot_emulated);
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_1B1C_emulated, qddot_lagrangian);
ForwardDynamicsConstraintsNullSpace (*model_emulated, q, qdot, tau, constraints_1B1C_emulated, qddot_nullspace);
CHECK_ARRAY_CLOSE (qddot_lagrangian.data(), qddot_nullspace.data(), qddot_lagrangian.size(), TEST_PREC * qddot_lagrangian.norm());
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_1B4C_emulated, qddot_lagrangian);
ForwardDynamicsConstraintsNullSpace (*model_emulated, q, qdot, tau, constraints_1B4C_emulated, qddot_nullspace);
CHECK_ARRAY_CLOSE (qddot_lagrangian.data(), qddot_nullspace.data(), qddot_lagrangian.size(), TEST_PREC * qddot_lagrangian.norm());
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_4B4C_emulated, qddot_lagrangian);
ForwardDynamicsConstraintsNullSpace (*model_emulated, q, qdot, tau, constraints_4B4C_emulated, qddot_nullspace);
CHECK_ARRAY_CLOSE (qddot_lagrangian.data(), qddot_nullspace.data(), qddot_lagrangian.size(), TEST_PREC * qddot_lagrangian.norm());
}
TEST_FIXTURE (Human36, TestContactsEmulatedMultdofLagrangian) {
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qddot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_1B1C_emulated, qddot_emulated);
ForwardDynamicsConstraintsDirect (*model_3dof, q, qdot, tau, constraints_1B1C_3dof, qddot_3dof);
CHECK_ARRAY_CLOSE (qddot_emulated.data(), qddot_3dof.data(), qddot_emulated.size(), TEST_PREC * qddot_emulated.norm());
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_1B4C_emulated, qddot_emulated);
ForwardDynamicsConstraintsDirect (*model_3dof, q, qdot, tau, constraints_1B4C_3dof, qddot_3dof);
CHECK_ARRAY_CLOSE (qddot_emulated.data(), qddot_3dof.data(), qddot_emulated.size(), TEST_PREC * qddot_emulated.norm());
ForwardDynamicsConstraintsDirect (*model_emulated, q, qdot, tau, constraints_4B4C_emulated, qddot_emulated);
ForwardDynamicsConstraintsDirect (*model_3dof, q, qdot, tau, constraints_4B4C_3dof, qddot_3dof);
CHECK_ARRAY_CLOSE (qddot_emulated.data(), qddot_3dof.data(), qddot_emulated.size(), TEST_PREC * qddot_emulated.norm());
}
TEST_FIXTURE (Human36, TestContactsEmulatedMultdofSparse) {
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
ForwardDynamicsConstraintsRangeSpaceSparse (*model_emulated, q, qdot, tau, constraints_1B1C_emulated, qddot_emulated);
for (unsigned int i = 0; i < q.size(); i++) {
CHECK_EQUAL (model_emulated->lambda_q[i], model_3dof->lambda_q[i]);
}
ForwardDynamicsConstraintsRangeSpaceSparse (*model_3dof, q, qdot, tau, constraints_1B1C_3dof, qddot_3dof);
CHECK_ARRAY_CLOSE (qddot_emulated.data(), qddot_3dof.data(), qddot_emulated.size(), TEST_PREC * qddot_emulated.norm());
ForwardDynamicsConstraintsRangeSpaceSparse (*model_emulated, q, qdot, tau, constraints_1B4C_emulated, qddot_emulated);
ForwardDynamicsConstraintsRangeSpaceSparse (*model_3dof, q, qdot, tau, constraints_1B4C_3dof, qddot_3dof);
CHECK_ARRAY_CLOSE (qddot_emulated.data(), qddot_3dof.data(), qddot_emulated.size(), TEST_PREC * qddot_emulated.norm());
ForwardDynamicsConstraintsRangeSpaceSparse (*model_emulated, q, qdot, tau, constraints_4B4C_emulated, qddot_emulated);
ForwardDynamicsConstraintsRangeSpaceSparse (*model_3dof, q, qdot, tau, constraints_4B4C_3dof, qddot_3dof);
CHECK_ARRAY_CLOSE (qddot_emulated.data(), qddot_3dof.data(), qddot_emulated.size(), TEST_PREC * qddot_emulated.norm());
}
TEST_FIXTURE (Human36, TestContactsEmulatedMultdofKokkevisSparse) {
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
ForwardDynamicsConstraintsRangeSpaceSparse (*model_emulated, q, qdot, tau, constraints_1B1C_emulated, qddot_emulated);
for (unsigned int i = 0; i < q.size(); i++) {
CHECK_EQUAL (model_emulated->lambda_q[i], model_3dof->lambda_q[i]);
}
VectorNd qddot_sparse (qddot_emulated);
VectorNd qddot_kokkevis (qddot_emulated);
ForwardDynamicsConstraintsRangeSpaceSparse (*model_3dof, q, qdot, tau, constraints_1B1C_3dof, qddot_sparse);
ForwardDynamicsContactsKokkevis (*model_3dof, q, qdot, tau, constraints_1B1C_3dof, qddot_kokkevis);
CHECK_ARRAY_CLOSE (qddot_sparse.data(), qddot_kokkevis.data(), qddot_sparse.size(), TEST_PREC * qddot_sparse.norm());
ForwardDynamicsConstraintsRangeSpaceSparse (*model_3dof, q, qdot, tau, constraints_1B4C_3dof, qddot_sparse);
ForwardDynamicsContactsKokkevis (*model_3dof, q, qdot, tau, constraints_1B4C_3dof, qddot_kokkevis);
CHECK_ARRAY_CLOSE (qddot_sparse.data(), qddot_kokkevis.data(), qddot_sparse.size(), TEST_PREC * qddot_sparse.norm());
ForwardDynamicsConstraintsRangeSpaceSparse (*model_3dof, q, qdot, tau, constraints_4B4C_3dof, qddot_sparse);
ForwardDynamicsContactsKokkevis (*model_3dof, q, qdot, tau, constraints_4B4C_3dof, qddot_kokkevis);
CHECK_ARRAY_CLOSE (qddot_sparse.data(), qddot_kokkevis.data(), qddot_sparse.size(), TEST_PREC * qddot_sparse.norm());
}
TEST_FIXTURE (Human36, TestContactsEmulatedMultdofKokkevisMultiple ) {
for (unsigned int i = 0; i < q.size(); i++) {
q[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
qdot[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
tau[i] = 0.5 * M_PI * static_cast<double>(rand()) / static_cast<double>(RAND_MAX);
}
VectorNd qddot_kokkevis (qddot_emulated);
VectorNd qddot_kokkevis_2 (qddot_emulated);
ForwardDynamicsContactsKokkevis (*model_3dof, q, qdot, tau, constraints_1B1C_3dof, qddot_kokkevis);
ForwardDynamicsContactsKokkevis (*model_3dof, q, qdot, tau, constraints_1B1C_3dof, qddot_kokkevis_2);
CHECK_ARRAY_CLOSE (qddot_kokkevis.data(), qddot_kokkevis_2.data(), qddot_kokkevis.size(), TEST_PREC * qddot_kokkevis.norm());
ForwardDynamicsContactsKokkevis (*model_3dof, q, qdot, tau, constraints_1B4C_3dof, qddot_kokkevis);
ForwardDynamicsContactsKokkevis (*model_3dof, q, qdot, tau, constraints_1B4C_3dof, qddot_kokkevis_2);
CHECK_ARRAY_CLOSE (qddot_kokkevis.data(), qddot_kokkevis_2.data(), qddot_kokkevis.size(), TEST_PREC * qddot_kokkevis.norm());
ForwardDynamicsContactsKokkevis (*model_3dof, q, qdot, tau, constraints_4B4C_3dof, qddot_kokkevis);
ForwardDynamicsContactsKokkevis (*model_3dof, q, qdot, tau, constraints_4B4C_3dof, qddot_kokkevis_2);
CHECK_ARRAY_CLOSE (qddot_kokkevis.data(), qddot_kokkevis_2.data(), qddot_kokkevis.size(), TEST_PREC * qddot_kokkevis.norm());
}
TEST_FIXTURE(SphericalJoint, TestEulerZYXvsEmulated ) {
emuQ[0] = 1.1;
emuQ[1] = 1.2;
emuQ[2] = 1.3;
emuQ[3] = 1.4;
emuQ[4] = 1.5;
emuQDot[0] = 1.;
emuQDot[1] = 2.;
emuQDot[2] = 3.;
emuQDot[3] = 4.;
emuQDot[4] = 5.;
emuTau[0] = 5.;
emuTau[1] = 4.;
emuTau[2] = 7.;
emuTau[3] = 3.;
emuTau[4] = 2.;
VectorNd QDDot_emu = VectorNd::Zero (emulated_model.qdot_size);
VectorNd QDDot_eulerzyx = VectorNd::Zero (eulerzyx_model.qdot_size);
ForwardDynamicsLagrangian (emulated_model, emuQ, emuQDot, emuTau, QDDot_emu);
ForwardDynamicsLagrangian (eulerzyx_model, emuQ, emuQDot, emuTau, QDDot_eulerzyx);
CHECK_ARRAY_CLOSE (QDDot_emu.data(), QDDot_eulerzyx.data(), emulated_model.qdot_size, TEST_PREC);
}
TEST_FIXTURE ( Human36, SolveMInvTimesTau) {
for (unsigned int i = 0; i < model->dof_count; i++) {
q[i] = rand() / static_cast<double>(RAND_MAX);
tau[i] = rand() / static_cast<double>(RAND_MAX);
}
MatrixNd M (MatrixNd::Zero(model->dof_count, model->dof_count));
CompositeRigidBodyAlgorithm (*model, q, M);
VectorNd qddot_solve_llt = M.llt().solve(tau);
VectorNd qddot_minv (q);
CalcMInvTimesTau (*model, q, tau, qddot_minv);
CHECK_ARRAY_CLOSE (qddot_solve_llt.data(), qddot_minv.data(), model->dof_count, TEST_PREC * qddot_minv.norm());
}
TEST_FIXTURE ( Human36, SolveMInvTimesTauReuse) {
for (unsigned int i = 0; i < model->dof_count; i++) {
q[i] = rand() / static_cast<double>(RAND_MAX);
tau[i] = rand() / static_cast<double>(RAND_MAX);
}
MatrixNd M (MatrixNd::Zero(model->dof_count, model->dof_count));
CompositeRigidBodyAlgorithm (*model, q, M);
VectorNd qddot_solve_llt = M.llt().solve(tau);
VectorNd qddot_minv (q);
CalcMInvTimesTau (*model, q, tau, qddot_minv);
for (unsigned int j = 0; j < 1; j++) {
for (unsigned int i = 0; i < model->dof_count; i++) {
tau[i] = rand() / static_cast<double>(RAND_MAX);
}
CompositeRigidBodyAlgorithm (*model, q, M);
qddot_solve_llt = M.llt().solve(tau);
CalcMInvTimesTau (*model, q, tau, qddot_minv);
CHECK_ARRAY_CLOSE (qddot_solve_llt.data(), qddot_minv.data(), model->dof_count, TEST_PREC * qddot_solve_llt.norm());
}
}