//============================================================================== Eigen::Vector3d State::_getJointPosition(BodyNode* _bodyNode) const { Joint* parentJoint = _bodyNode->getParentJoint(); Eigen::Vector3d localJointPosition = parentJoint->getTransformFromChildBodyNode().translation(); return _bodyNode->getTransform() * localJointPosition; }
// Current code only works for the left leg with only one constraint VectorXd MyWorld::updateGradients() { // compute c(q) mC = mSkel->getMarker(mConstrainedMarker)->getWorldPosition() - mTarget; // compute J(q) Vector4d offset; offset << mSkel->getMarker(mConstrainedMarker)->getLocalPosition(), 1; // Create a vector in homogeneous coordinates // w.r.t ankle dofs BodyNode *node = mSkel->getMarker(mConstrainedMarker)->getBodyNode(); Joint *joint = node->getParentJoint(); Matrix4d worldToParent = node->getParentBodyNode()->getTransform().matrix(); Matrix4d parentToJoint = joint->getTransformFromParentBodyNode().matrix(); Matrix4d dR = joint->getTransformDerivative(0); // Doesn't need .matrix() because it returns a Matrix4d instead of Isometry3d Matrix4d R = joint->getTransform(1).matrix(); Matrix4d jointToChild = joint->getTransformFromChildBodyNode().inverse().matrix(); Vector4d jCol = worldToParent * parentToJoint * dR * R * jointToChild * offset; int colIndex = joint->getIndexInSkeleton(0); mJ.col(colIndex) = jCol.head(3); // Take the first 3 elelemtns of jCol dR = joint->getTransformDerivative(1); R = joint->getTransform(0).matrix(); jCol = worldToParent * parentToJoint * R * dR * jointToChild * offset; colIndex = joint->getIndexInSkeleton(1); mJ.col(colIndex) = jCol.head(3); offset = parentToJoint * joint->getTransform(0).matrix() * joint->getTransform(1).matrix() * jointToChild * offset; // Update offset so it stores the chain below the parent joint // w.r.t knee dof node = node->getParentBodyNode(); // return NULL if node is the root node joint = node->getParentJoint(); worldToParent = node->getParentBodyNode()->getTransform().matrix(); parentToJoint = joint->getTransformFromParentBodyNode().matrix(); dR = joint->getTransformDerivative(0); // Doesn't need .matrix() because it returns a Matrix4d instead of Isometry3d jointToChild = joint->getTransformFromChildBodyNode().inverse().matrix(); jCol = worldToParent * parentToJoint * dR * jointToChild * offset; colIndex = joint->getIndexInSkeleton(0); mJ.col(colIndex) = jCol.head(3); // Take the first 3 elelemtns of jCol offset = parentToJoint * joint->getTransform(0).matrix() * jointToChild * offset; // w.r.t hip dofs node = node->getParentBodyNode(); joint = node->getParentJoint(); worldToParent = node->getParentBodyNode()->getTransform().matrix(); parentToJoint = joint->getTransformFromParentBodyNode().matrix(); dR = joint->getTransformDerivative(0); // Doesn't need .matrix() because it returns a Matrix4d instead of Isometry3d Matrix4d R1 = joint->getTransform(1).matrix(); Matrix4d R2 = joint->getTransform(2).matrix(); jointToChild = joint->getTransformFromChildBodyNode().inverse().matrix(); jCol = worldToParent * parentToJoint * dR * R1 * R2 * jointToChild * offset; colIndex = joint->getIndexInSkeleton(0); mJ.col(colIndex) = jCol.head(3); // Take the first 3 elelemtns of J R1 = joint->getTransform(0).matrix(); dR = joint->getTransformDerivative(1); R2 = joint->getTransform(2).matrix(); jCol = worldToParent * parentToJoint * R1 * dR * R2 * jointToChild * offset; colIndex = joint->getIndexInSkeleton(1); mJ.col(colIndex) = jCol.head(3); R1 = joint->getTransform(0).matrix(); R2 = joint->getTransform(1).matrix(); dR = joint->getTransformDerivative(2); jCol = worldToParent * parentToJoint * R1 * R2 * dR * jointToChild * offset; colIndex = joint->getIndexInSkeleton(2); mJ.col(colIndex) = jCol.head(3); // compute gradients VectorXd gradients = 2 * mJ.transpose() * mC; return gradients; }
// Current code only works for the left leg with only one constraint VectorXd MyWorld::updateGradients() { mJ.setZero(); mC.setZero(); // compute c(q) //std::cout << "HAMYDEBUG: mConstrainedMarker = " << getMarker(mConstrainedMarker) << std::endl; mC = getMarker(mConstrainedMarker)->getWorldPosition() - mTarget; std::cout << "C(q) = " << mC << std::endl; // compute J(q) Vector4d offset; offset << getMarker(mConstrainedMarker)->getLocalPosition(), 1; // Create a vector in homogeneous coordinates //Setup vars BodyNode *node = getMarker(mConstrainedMarker)->getBodyNode(); Joint *joint = node->getParentJoint(); Matrix4d worldToParent; Matrix4d parentToJoint; //Declare Vars Matrix4d dR; // Doesn't need .matrix() because it returns a Matrix4d instead of Isometry3d Matrix4d R; Matrix4d R1; Matrix4d R2; Matrix4d jointToChild; Vector4d jCol; int colIndex; //TODO: Might want to change this to check if root using given root fcn //Iterate until we get to the root node while(true) { //std::cout << "HAMY DEBUG: Beginning new looop" << std::endl; if(node->getParentBodyNode() == NULL) { worldToParent = worldToParent.setIdentity(); } else { worldToParent = node->getParentBodyNode()->getTransform().matrix(); } parentToJoint = joint->getTransformFromParentBodyNode().matrix(); // Doesn't need .matrix() because it returns a Matrix4d instead of Isometry3d jointToChild = joint->getTransformFromChildBodyNode().inverse().matrix(); //TODO: R1, R2, ... Rn code depending on DOFs int nDofs = joint->getNumDofs(); //std::cout << "HAMY: nDofs=" << nDofs << std::endl; //Can only have up to 3 DOFs on any one piece switch(nDofs){ case 1: //std::cout << "HAMY: 1 nDOF" << std::endl; dR = joint->getTransformDerivative(0); jCol = worldToParent * parentToJoint * dR * jointToChild * offset; colIndex = joint->getIndexInSkeleton(0); mJ.col(colIndex) = jCol.head(3); // Take the first 3 elelemtns of jCol offset = parentToJoint * joint->getTransform(0).matrix() * jointToChild * offset; break; case 2: //std::cout << "HAMY: 2 nDOF" << std::endl; dR = joint->getTransformDerivative(0); // Doesn't need .matrix() because it returns a Matrix4d instead of Isometry3d R = joint->getTransform(1).matrix(); jointToChild = joint->getTransformFromChildBodyNode().inverse().matrix(); jCol = worldToParent * parentToJoint * dR * R * jointToChild * offset; colIndex = joint->getIndexInSkeleton(0); mJ.col(colIndex) = jCol.head(3); // Take the first 3 elelemtns of jCol dR = joint->getTransformDerivative(1); R = joint->getTransform(0).matrix(); jCol = worldToParent * parentToJoint * R * dR * jointToChild * offset; colIndex = joint->getIndexInSkeleton(1); mJ.col(colIndex) = jCol.head(3); offset = parentToJoint * joint->getTransform(0).matrix() * joint->getTransform(1).matrix() * jointToChild * offset; // Upd break; case 3: //std::cout << "HAMY: 3 nDOF" << std::endl; dR = joint->getTransformDerivative(0); // Doesn't need .matrix() because it returns a Matrix4d instead of Isometry3d R1 = joint->getTransform(1).matrix(); R2 = joint->getTransform(2).matrix(); jointToChild = joint->getTransformFromChildBodyNode().inverse().matrix(); jCol = worldToParent * parentToJoint * dR * R1 * R2 * jointToChild * offset; colIndex = joint->getIndexInSkeleton(0); mJ.col(colIndex) = jCol.head(3); // Take the first 3 elelemtns of J R1 = joint->getTransform(0).matrix(); dR = joint->getTransformDerivative(1); R2 = joint->getTransform(2).matrix(); jCol = worldToParent * parentToJoint * R1 * dR * R2 * jointToChild * offset; colIndex = joint->getIndexInSkeleton(1); mJ.col(colIndex) = jCol.head(3); R1 = joint->getTransform(0).matrix(); R2 = joint->getTransform(1).matrix(); dR = joint->getTransformDerivative(2); jCol = worldToParent * parentToJoint * R1 * R2 * dR * jointToChild * offset; colIndex = joint->getIndexInSkeleton(2); mJ.col(colIndex) = jCol.head(3); offset = parentToJoint * joint->getTransform(0).matrix() * joint->getTransform(1).matrix() * joint->getTransform(2).matrix() * jointToChild * offset; break; default: //std::cout << "HAMY: Unexpected nDOF = " << nDofs << std::endl; break; } if(node != mSkel->getRootBodyNode()) { //std::cout << "HAMY DEBUG: Not root, continue loop" << std::endl; node = node->getParentBodyNode(); // return NULL if node is the root node joint = node->getParentJoint(); } else { break; } } // compute gradients VectorXd gradients = 2 * mJ.transpose() * mC; return gradients; }