bool Equal(const MomentumJacobian& a,const MomentumJacobian& b,double eps) { if(a.rows()==b.rows()&&a.columns()==b.columns()){ return a.data.isApprox(b.data,eps); }else return false; }
bool changeRefPoint(const MomentumJacobian& src1, const Vector& base_AB, MomentumJacobian& dest) { if(src1.columns()!=dest.columns()) return false; for(unsigned int i=0;i<src1.columns();i++) dest.setColumn(i,src1.getColumn(i).RefPoint(base_AB)); return true; }
bool changeRefFrame(const MomentumJacobian& src1,const Frame& frame, MomentumJacobian& dest) { if(src1.columns()!=dest.columns()) return false; for(unsigned int i=0;i<src1.columns();i++) dest.setColumn(i,frame*src1.getColumn(i)); return true; }
bool changeBase(const MomentumJacobian& src1, const Rotation& rot, MomentumJacobian& dest) { if(src1.columns()!=dest.columns()) return false; for(unsigned int i=0;i<src1.columns();i++) dest.setColumn(i,rot*src1.getColumn(i));; return true; }
bool divideJacobianInertia(const MomentumJacobian& src, const RigidBodyInertia& I, Jacobian& dest) { /** \todo if the inertia matrix is singular ? */ if(src.columns()!=dest.columns() || I.getMass() == 0) return false; for(unsigned int i=0;i<src.columns();i++) dest.setColumn(i,src.getColumn(i)/I); return true; }
bool multiplyInertiaJacobian(const Jacobian& src, const RigidBodyInertia& I, MomentumJacobian& dest) { if(src.columns()!=dest.columns()) return false; for(unsigned int i=0;i<src.columns();i++) dest.setColumn(i,I*src.getColumn(i));; return true; }
int crba_momentum_jacobian_loop(const UndirectedTree & undirected_tree, const Traversal & traversal, const JntArray & q, std::vector<RigidBodyInertia> & Ic, MomentumJacobian & H, RigidBodyInertia & InertiaCOM ) { #ifndef NDEBUG if( undirected_tree.getNrOfLinks() != traversal.getNrOfVisitedLinks() || undirected_tree.getNrOfDOFs() != q.rows() || Ic.size() != undirected_tree.getNrOfLinks() || H.columns() != (undirected_tree.getNrOfDOFs() + 6) ) { std::cerr << "crba_momentum_jacobian_loop: input data error" << std::endl; return -1; } #endif double q_; Wrench F = Wrench::Zero(); //Sweep from root to leaf for(int i=0; i<(int)traversal.getNrOfVisitedLinks(); i++) { LinkMap::const_iterator link_it = traversal.getOrderedLink(i); int link_index = link_it->getLinkIndex(); //Collect RigidBodyInertia Ic[link_index]=link_it->getInertia(); } for(int i=(int)traversal.getNrOfVisitedLinks()-1; i >= 1; i-- ) { int dof_id; LinkMap::const_iterator link_it = traversal.getOrderedLink(i); int link_index = link_it->getLinkIndex(); LinkMap::const_iterator parent_it = traversal.getParentLink(link_index); int parent_index = parent_it->getLinkIndex(); if( link_it->getAdjacentJoint(parent_it)->getNrOfDOFs() == 1 ) { dof_id = link_it->getAdjacentJoint(parent_it)->getDOFIndex(); q_ = q(dof_id); } else { q_ = 0.0; dof_id = -1; } Ic[parent_index] = Ic[parent_index]+link_it->pose(parent_it,q_)*Ic[link_index]; if( link_it->getAdjacentJoint(parent_it)->getNrOfDOFs() == 1 ) { KDL::Twist S_link_parent = parent_it->S(link_it,q_); F = Ic[link_index]*S_link_parent; if( traversal.getParentLink(link_it) != undirected_tree.getInvalidLinkIterator() ) { double q__; int dof_id_; LinkMap::const_iterator predecessor_it = traversal.getParentLink(link_it); LinkMap::const_iterator successor_it = link_it; while(true) { if( predecessor_it->getAdjacentJoint(successor_it)->getNrOfDOFs() == 1 ) { q__ = q( predecessor_it->getAdjacentJoint(successor_it)->getDOFIndex()); } else { q__ = 0.0; } F = successor_it->pose(predecessor_it,q__)*F; successor_it = predecessor_it; predecessor_it = traversal.getParentLink(predecessor_it); if( predecessor_it == undirected_tree.getInvalidLinkIterator() ) { break; } if( predecessor_it->getAdjacentJoint(successor_it)->getNrOfDOFs() == 1 ) { dof_id_ = predecessor_it->getAdjacentJoint(successor_it)->getDOFIndex(); q__ = q(dof_id_); } else { q__ = 0.0; dof_id_ = -1; } } if( dof_id >= 0 ) { H.data.block(0,6+dof_id,6,1) = toEigen(F); } //The first 6x6 submatrix of the Momentum Jacobian are simply the spatial inertia //of all the structure expressed in the base reference frame H.data.block(0,0,6,6) = toEigen(Ic[traversal.getBaseLink()->getLinkIndex()]); } } } //We have then to translate the reference point of the obtained jacobian to the com //The Ic[traversal.order[0]->getLink(index)] contain the spatial inertial of all the tree //expressed in link coordite frames Vector com = Ic[traversal.getBaseLink()->getLinkIndex()].getCOG(); H.changeRefPoint(com); InertiaCOM = Frame(com)*Ic[traversal.getBaseLink()->getLinkIndex()]; return 0; }