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

#include <UnitTest++.h>

#include <iostream>

#include "Fixtures.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_FIXTURE(FloatingBase12DoF, TestKineticEnergy) {
  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);

  CHECK_EQUAL (kinetic_energy_ref, kinetic_energy);
}

TEST(TestPotentialEnergy) {
  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);
  CHECK_EQUAL (0., potential_energy_zero);

  q[1] = 1.;
  double potential_energy_lifted = Utils::CalcPotentialEnergy (model, q);
  CHECK_EQUAL (4.905, potential_energy_lifted);
}

TEST(TestCOMSimple) {
  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, mass, com, &com_velocity);

  CHECK_EQUAL (123., mass);
  CHECK_EQUAL (Vector3d (0., 0., 0.), com);
  CHECK_EQUAL (Vector3d (0., 0., 0.), com_velocity);

  q[1] = 1.;
  Utils::CalcCenterOfMass (model, q, qdot, mass, com, &com_velocity);
  CHECK_EQUAL (Vector3d (0., 1., 0.), com);
  CHECK_EQUAL (Vector3d (0., 0., 0.), com_velocity);

  qdot[1] = 1.;
  Utils::CalcCenterOfMass (model, q, qdot, mass, com, &com_velocity);
  CHECK_EQUAL (Vector3d (0., 1., 0.), com);
  CHECK_EQUAL (Vector3d (0., 1., 0.), com_velocity);
}

TEST(TestAngularMomentumSimple) {
  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, mass, com, NULL, &angular_momentum);
  CHECK_EQUAL (Vector3d (1.1, 0., 0.), angular_momentum);

  qdot << 0., 1., 0.;
  Utils::CalcCenterOfMass (model, q, qdot, mass, com, NULL, &angular_momentum);
  CHECK_EQUAL (Vector3d (0., 2.2, 0.), angular_momentum);

  qdot << 0., 0., 1.;
  Utils::CalcCenterOfMass (model, q, qdot, mass, com, NULL, &angular_momentum);
  CHECK_EQUAL (Vector3d (0., 0., 3.3), angular_momentum);
}

TEST_FIXTURE (TwoArms12DoF, TestAngularMomentumSimple) {
  double mass;
  Vector3d com;
  Vector3d angular_momentum;

  Utils::CalcCenterOfMass (*model, q, qdot, mass, com, NULL, &angular_momentum);

  CHECK_EQUAL (Vector3d (0., 0., 0.), angular_momentum);

  qdot[0] = 1.;
  qdot[1] = 2.;
  qdot[2] = 3.;

  Utils::CalcCenterOfMass (*model, q, qdot, mass, com, NULL, &angular_momentum);

  // only a rough guess from test calculation
  CHECK_ARRAY_CLOSE (Vector3d (3.3, 2.54, 1.5).data(), angular_momentum.data(), 3, 1.0e-1);

  qdot[3] = -qdot[0];
  qdot[4] = -qdot[1];
  qdot[5] = -qdot[2];

  ClearLogOutput();
  Utils::CalcCenterOfMass (*model, q, qdot, mass, com, NULL, &angular_momentum);

  CHECK (angular_momentum[0] == 0);
  CHECK (angular_momentum[1] < 0);
  CHECK (angular_momentum[2] == 0.);
}
Added RBDL to 3rdparty, added empty rig model, used better coding style in CharacterModule 2017-02-22 21:35:14 +01:00			`#include <UnitTest++.h>`

			`#include <iostream>`

			`#include "Fixtures.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_FIXTURE(FloatingBase12DoF, TestKineticEnergy) {`
			`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);`

			`CHECK_EQUAL (kinetic_energy_ref, kinetic_energy);`
			`}`

			`TEST(TestPotentialEnergy) {`
			`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);`
			`CHECK_EQUAL (0., potential_energy_zero);`

			`q[1] = 1.;`
			`double potential_energy_lifted = Utils::CalcPotentialEnergy (model, q);`
			`CHECK_EQUAL (4.905, potential_energy_lifted);`
			`}`

			`TEST(TestCOMSimple) {`
			`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, mass, com, &com_velocity);`

			`CHECK_EQUAL (123., mass);`
			`CHECK_EQUAL (Vector3d (0., 0., 0.), com);`
			`CHECK_EQUAL (Vector3d (0., 0., 0.), com_velocity);`

			`q[1] = 1.;`
			`Utils::CalcCenterOfMass (model, q, qdot, mass, com, &com_velocity);`
			`CHECK_EQUAL (Vector3d (0., 1., 0.), com);`
			`CHECK_EQUAL (Vector3d (0., 0., 0.), com_velocity);`

			`qdot[1] = 1.;`
			`Utils::CalcCenterOfMass (model, q, qdot, mass, com, &com_velocity);`
			`CHECK_EQUAL (Vector3d (0., 1., 0.), com);`
			`CHECK_EQUAL (Vector3d (0., 1., 0.), com_velocity);`
			`}`

			`TEST(TestAngularMomentumSimple) {`
			`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, mass, com, NULL, &angular_momentum);`
			`CHECK_EQUAL (Vector3d (1.1, 0., 0.), angular_momentum);`

			`qdot << 0., 1., 0.;`
			`Utils::CalcCenterOfMass (model, q, qdot, mass, com, NULL, &angular_momentum);`
			`CHECK_EQUAL (Vector3d (0., 2.2, 0.), angular_momentum);`

			`qdot << 0., 0., 1.;`
			`Utils::CalcCenterOfMass (model, q, qdot, mass, com, NULL, &angular_momentum);`
			`CHECK_EQUAL (Vector3d (0., 0., 3.3), angular_momentum);`
			`}`

			`TEST_FIXTURE (TwoArms12DoF, TestAngularMomentumSimple) {`
			`double mass;`
			`Vector3d com;`
			`Vector3d angular_momentum;`

			`Utils::CalcCenterOfMass (*model, q, qdot, mass, com, NULL, &angular_momentum);`

			`CHECK_EQUAL (Vector3d (0., 0., 0.), angular_momentum);`

			`qdot[0] = 1.;`
			`qdot[1] = 2.;`
			`qdot[2] = 3.;`

			`Utils::CalcCenterOfMass (*model, q, qdot, mass, com, NULL, &angular_momentum);`

			`// only a rough guess from test calculation`
			`CHECK_ARRAY_CLOSE (Vector3d (3.3, 2.54, 1.5).data(), angular_momentum.data(), 3, 1.0e-1);`

			`qdot[3] = -qdot[0];`
			`qdot[4] = -qdot[1];`
			`qdot[5] = -qdot[2];`

			`ClearLogOutput();`
			`Utils::CalcCenterOfMass (*model, q, qdot, mass, com, NULL, &angular_momentum);`

			`CHECK (angular_momentum[0] == 0);`
			`CHECK (angular_momentum[1] < 0);`
			`CHECK (angular_momentum[2] == 0.);`
			`}`