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

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#include "rbdl_tests.h"
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#include <iostream>
#include <cmath>
#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;
struct ScrewJoint1DofFixedBase {
ScrewJoint1DofFixedBase() {
using namespace RigidBodyDynamics;
using namespace RigidBodyDynamics::Math;
ClearLogOutput();
model = new Model;
/* Single screw joint with a fixed base. Rotation about Z, translation along X.
* A rolling log.
*/
Body body = Body (1., Vector3d (0., 0, 0.), Vector3d (1., 1., 1.));
Joint joint = Joint (SpatialVector (0., 0., 1., 1., 0., 0.));
roller = model->AppendBody (Xtrans (Vector3d (0., 0., 0.)), joint, body, "Roller");
q = VectorNd::Constant ((size_t) model->dof_count, 0.);
qdot = VectorNd::Constant ((size_t) model->dof_count, 0.);
qddot = VectorNd::Constant ((size_t) model->dof_count, 0.);
tau = VectorNd::Constant ((size_t) model->dof_count, 0.);
epsilon = 1e-8;
ClearLogOutput();
}
~ScrewJoint1DofFixedBase() {
delete model;
}
RigidBodyDynamics::Model *model;
RigidBodyDynamics::Math::VectorNd q;
RigidBodyDynamics::Math::VectorNd qdot;
RigidBodyDynamics::Math::VectorNd qddot;
RigidBodyDynamics::Math::VectorNd tau;
unsigned int roller;
double epsilon;
};
TEST_CASE_METHOD (ScrewJoint1DofFixedBase, __FILE__"_UpdateKinematics", "") {
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q[0] = 1;
qdot[0] = 2;
qddot[0] = 0;
UpdateKinematics (*model, q, qdot, qddot);
REQUIRE_THAT (Xrot(1,Vector3d(0,0,1)).E, AllCloseMatrix(model->X_base[roller].E));
REQUIRE_THAT (Vector3d(1.,0.,0.), AllCloseVector(model->X_base[roller].r));
REQUIRE_THAT (SpatialVector(0.,0.,2.,cos(q[0])*2,-sin(q[0])*2.,0.), AllCloseVector(model->v[roller]));
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SpatialVector a0(model->a[roller]);
SpatialVector v0(model->v[roller]);
q[0] = 1+2*epsilon;
qdot[0] = 2;
qddot[0] = 0;
UpdateKinematics (*model, q, qdot, qddot);
v0 = model->v[roller] - v0;
v0 /= epsilon;
REQUIRE_THAT (a0, AllCloseVector(v0, 1e-5, 1e-5)); //finite diff vs. analytical derivative
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}
TEST_CASE_METHOD (ScrewJoint1DofFixedBase, __FILE__"_Jacobians", "") {
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q[0] = 1;
qdot[0] = 0;
qddot[0] = 9;
Vector3d refPt = Vector3d(1,0,3);
MatrixNd GrefPt = MatrixNd::Constant(3,1,0.);
MatrixNd Gexpected = MatrixNd::Constant(3,1,0.);
Vector3d refPtBaseCoord = Vector3d();
refPtBaseCoord = CalcBodyToBaseCoordinates(*model, q, roller, refPt);
REQUIRE_THAT (Vector3d(1+cos(1), sin(1), 3), AllCloseVector(refPtBaseCoord));
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CalcPointJacobian(*model, q, roller, refPt, GrefPt);
Gexpected(0,0) = 1 - sin(1);
Gexpected(1,0) = cos(1);
Gexpected(2,0) = 0;
REQUIRE_THAT (Gexpected, AllCloseMatrix(GrefPt));
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}