/** * Calculate the wrapping of one path segment over one wrap object. * * @param aPoint1 The first patth point * @param aPoint2 The second path point * @param aPathWrap An object holding the parameters for this path/wrap-object pairing * @param aWrapResult The result of the wrapping (tangent points, etc.) * @return The status, as a WrapAction enum */ int WrapObject::wrapPathSegment(const SimTK::State& s, PathPoint& aPoint1, PathPoint& aPoint2, const PathWrap& aPathWrap, WrapResult& aWrapResult) const { int return_code = noWrap; bool p_flag; Vec3 pt1(0.0); Vec3 pt2(0.0); // Convert the path points from the frames of the bodies they are attached // to to the frame of the wrap object's body _model->getSimbodyEngine().transformPosition(s, aPoint1.getBody(), aPoint1.getLocation(), getBody(), pt1); _model->getSimbodyEngine().transformPosition(s, aPoint2.getBody(), aPoint2.getLocation(), getBody(), pt2); // Convert the path points from the frame of the wrap object's body // into the frame of the wrap object pt1 = _pose.shiftBaseStationToFrame(pt1); pt2 = _pose.shiftBaseStationToFrame(pt2); return_code = wrapLine(s, pt1, pt2, aPathWrap, aWrapResult, p_flag); if (p_flag == true && return_code > 0) { // Convert the tangent points from the frame of the wrap object to the // frame of the wrap object's body aWrapResult.r1 = _pose.shiftFrameStationToBase(aWrapResult.r1); aWrapResult.r2 = _pose.shiftFrameStationToBase(aWrapResult.r2); // Convert the surface points (between the tangent points) from the frame of // the wrap object to the frame of the wrap object's body for (int i = 0; i < aWrapResult.wrap_pts.getSize(); i++) aWrapResult.wrap_pts.get(i) = _pose.shiftFrameStationToBase(aWrapResult.wrap_pts.get(i)); } return return_code; }
// get the path as PointForceDirections directions // CAUTION: the return points are heap allocated; you must delete them yourself! // (TODO: that is really lame) void GeometryPath:: getPointForceDirections(const SimTK::State& s, OpenSim::Array<PointForceDirection*> *rPFDs) const { int i; PathPoint* start; PathPoint* end; const OpenSim::PhysicalFrame* startBody; const OpenSim::PhysicalFrame* endBody; const Array<PathPoint*>& currentPath = getCurrentPath(s); int np = currentPath.getSize(); rPFDs->ensureCapacity(np); for (i = 0; i < np; i++) { PointForceDirection *pfd = new PointForceDirection(currentPath[i]->getLocation(), currentPath[i]->getBody(), Vec3(0)); rPFDs->append(pfd); } for (i = 0; i < np-1; i++) { start = currentPath[i]; end = currentPath[i+1]; startBody = &start->getBody(); endBody = &end->getBody(); if (startBody != endBody) { Vec3 posStart, posEnd; Vec3 direction(0); // Find the positions of start and end in the inertial frame. //engine.getPosition(s, start->getBody(), start->getLocation(), posStart); posStart = start->getLocationInGround(s); //engine.getPosition(s, end->getBody(), end->getLocation(), posEnd); posEnd = end->getLocationInGround(s); // Form a vector from start to end, in the inertial frame. direction = (posEnd - posStart); // Check that the two points are not coincident. // This can happen due to infeasible wrapping of the path, // when the origin or insertion enters the wrapping surface. // This is a temporary fix, since the wrap algorithm should // return NaN for the points and/or throw an Exception- aseth if (direction.norm() < SimTK::SignificantReal){ direction = direction*SimTK::NaN; } else{ direction = direction.normalize(); } // Get resultant direction at each point rPFDs->get(i)->addToDirection(direction); rPFDs->get(i+1)->addToDirection(-direction); } } }
/* add in the equivalent spatial forces on bodies for an applied tension along the GeometryPath to a set of bodyForces */ void GeometryPath::addInEquivalentForces(const SimTK::State& s, const double& tension, SimTK::Vector_<SimTK::SpatialVec>& bodyForces, SimTK::Vector& mobilityForces) const { PathPoint* start = NULL; PathPoint* end = NULL; const SimTK::MobilizedBody* bo = NULL; const SimTK::MobilizedBody* bf = NULL; const Array<PathPoint*>& currentPath = getCurrentPath(s); int np = currentPath.getSize(); const SimTK::SimbodyMatterSubsystem& matter = getModel().getMatterSubsystem(); // start point, end point, direction, and force vectors in ground Vec3 po(0), pf(0), dir(0), force(0); // partial velocity of point in body expressed in ground Vec3 dPodq_G(0), dPfdq_G(0); // gen force (torque) due to moving point under tension double fo, ff; for (int i = 0; i < np-1; ++i) { start = currentPath[i]; end = currentPath[i+1]; bo = &start->getBody().getMobilizedBody(); bf = &end->getBody().getMobilizedBody(); if (bo != bf) { // Find the positions of start and end in the inertial frame. po = start->getLocationInGround(s); pf = end->getLocationInGround(s); // Form a vector from start to end, in the inertial frame. dir = (pf - po); // Check that the two points are not coincident. // This can happen due to infeasible wrapping of the path, // when the origin or insertion enters the wrapping surface. // This is a temporary fix, since the wrap algorithm should // return NaN for the points and/or throw an Exception- aseth if (dir.norm() < SimTK::SignificantReal){ dir = dir*SimTK::NaN; } else{ dir = dir.normalize(); } force = tension*dir; const MovingPathPoint* mppo = dynamic_cast<MovingPathPoint *>(start); // do the same for the end point of this segment of the path const MovingPathPoint* mppf = dynamic_cast<MovingPathPoint *>(end); // add in the tension point forces to body forces if (mppo) {// moving path point location is a function of the state // transform of the frame of the point to the base mobilized body auto X_BF = mppo->getParentFrame().findTransformInBaseFrame(); bo->applyForceToBodyPoint(s, X_BF*mppo->getLocation(s), force, bodyForces); } else { // transform of the frame of the point to the base mobilized body auto X_BF = start->getParentFrame().findTransformInBaseFrame(); bo->applyForceToBodyPoint(s, X_BF*start->getLocation(), force, bodyForces); } if (mppf) {// moving path point location is a function of the state // transform of the frame of the point to the base mobilized body auto X_BF = mppf->getParentFrame().findTransformInBaseFrame(); bf->applyForceToBodyPoint(s, X_BF*mppf->getLocation(s), -force, bodyForces); } else { // transform of the frame of the point to the base mobilized body auto X_BF = end->getParentFrame().findTransformInBaseFrame(); bf->applyForceToBodyPoint(s, X_BF*end->getLocation(), -force, bodyForces); } // Now account for the work being done by virtue of the moving // path point motion relative to the body it is on if(mppo){ // torque (genforce) contribution due to relative movement // of a via point w.r.t. the body it is connected to. dPodq_G = bo->expressVectorInGroundFrame(s, start->getdPointdQ(s)); fo = ~dPodq_G*force; // get the mobilized body the coordinate is couple to. const SimTK::MobilizedBody& mpbod = matter.getMobilizedBody(mppo->getXCoordinate().getBodyIndex()); // apply the generalized (mobility) force to the coordinate's body mpbod.applyOneMobilityForce(s, mppo->getXCoordinate().getMobilizerQIndex(), fo, mobilityForces); } if(mppf){ dPfdq_G = bf->expressVectorInGroundFrame(s, end->getdPointdQ(s)); ff = ~dPfdq_G*(-force); // get the mobilized body the coordinate is couple to. const SimTK::MobilizedBody& mpbod = matter.getMobilizedBody(mppf->getXCoordinate().getBodyIndex()); mpbod.applyOneMobilityForce(s, mppf->getXCoordinate().getMobilizerQIndex(), ff, mobilityForces); } } } }