void SchatzmanPaoliOSI::computeFreeState() { // This function computes "free" states of the DS belonging to this Integrator. // "Free" means without taking non-smooth effects into account. //double t = simulationLink->nextTime(); // End of the time step //double told = simulationLink->startingTime(); // Beginning of the time step //double h = t-told; // time step length // Operators computed at told have index i, and (i+1) at t. // Note: integration of r with a theta method has been removed // SiconosVector *rold = static_cast<SiconosVector*>(d->rMemory()->getSiconosVector(0)); // Iteration through the set of Dynamical Systems. // DSIterator it; // Iterator through the set of DS. SP::DynamicalSystem ds; // Current Dynamical System. SP::SiconosMatrix W; // W SchatzmanPaoliOSI matrix of the current DS. Type::Siconos dsType ; // Type of the current DS. for (it = OSIDynamicalSystems->begin(); it != OSIDynamicalSystems->end(); ++it) { ds = *it; // the considered dynamical system dsType = Type::value(*ds); // Its type W = WMap[ds->number()]; // Its W SchatzmanPaoliOSI matrix of iteration. //1 - Lagrangian Non Linear Systems if (dsType == Type::LagrangianDS) { // // IN to be updated at current time: W, M, q, v, fL // // IN at told: qi,vi, fLi // // Note: indices i/i+1 corresponds to value at the beginning/end of the time step. // // Index k stands for Newton iteration and thus corresponds to the last computed // // value, ie the one saved in the DynamicalSystem. // // "i" values are saved in memory vectors. // // vFree = v_k,i+1 - W^{-1} ResiduFree // // with // // ResiduFree = M(q_k,i+1)(v_k,i+1 - v_i) - h*theta*forces(t,v_k,i+1, q_k,i+1) - h*(1-theta)*forces(ti,vi,qi) // // -- Convert the DS into a Lagrangian one. // SP::LagrangianDS d = std11::static_pointer_cast<LagrangianDS> (ds); // // Get state i (previous time step) from Memories -> var. indexed with "Old" // SP::SiconosVector qold =d->qMemory()->getSiconosVector(0); // SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0); // // --- ResiduFree computation --- // // ResFree = M(v-vold) - h*[theta*forces(t) + (1-theta)*forces(told)] // // // // vFree pointer is used to compute and save ResiduFree in this first step. // SP::SiconosVector vfree = d->workspace(DynamicalSystem::free);//workX[d]; // (*vfree)=*(d->workspace(DynamicalSystem::freeresidu)); // // -- Update W -- // // Note: during computeW, mass and jacobians of fL will be computed/ // computeW(t,d); // SP::SiconosVector v = d->velocity(); // v = v_k,i+1 // // -- vfree = v - W^{-1} ResiduFree -- // // At this point vfree = residuFree // // -> Solve WX = vfree and set vfree = X // W->PLUForwardBackwardInPlace(*vfree); // // -> compute real vfree // *vfree *= -1.0; // *vfree += *v; RuntimeException::selfThrow("SchatzmanPaoliOSI::computeFreeState - not yet implemented for Dynamical system type: " + dsType); } // 2 - Lagrangian Linear Systems else if (dsType == Type::LagrangianLinearTIDS) { // IN to be updated at current time: Fext // IN at told: qi,vi, fext // IN constants: K,C // Note: indices i/i+1 corresponds to value at the beginning/end of the time step. // "i" values are saved in memory vectors. // vFree = v_i + W^{-1} ResiduFree // with // ResiduFree = (-h*C -h^2*theta*K)*vi - h*K*qi + h*theta * Fext_i+1 + h*(1-theta)*Fext_i // -- Convert the DS into a Lagrangian one. SP::LagrangianLinearTIDS d = std11::static_pointer_cast<LagrangianLinearTIDS> (ds); // Get state i (previous time step) from Memories -> var. indexed with "Old" SP::SiconosVector qold = d->qMemory()->getSiconosVector(0); // q_k // SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0); //v_k // --- ResiduFree computation --- // vFree pointer is used to compute and save ResiduFree in this first step. // Velocity free and residu. vFree = RESfree (pointer equality !!). SP::SiconosVector qfree = d->workspace(DynamicalSystem::free);//workX[d]; (*qfree) = *(d->workspace(DynamicalSystem::freeresidu)); W->PLUForwardBackwardInPlace(*qfree); *qfree *= -1.0; *qfree += *qold; } // 3 - Newton Euler Systems else if (dsType == Type::NewtonEulerDS) { // // IN to be updated at current time: W, M, q, v, fL // // IN at told: qi,vi, fLi // // Note: indices i/i+1 corresponds to value at the beginning/end of the time step. // // Index k stands for Newton iteration and thus corresponds to the last computed // // value, ie the one saved in the DynamicalSystem. // // "i" values are saved in memory vectors. // // vFree = v_k,i+1 - W^{-1} ResiduFree // // with // // ResiduFree = M(q_k,i+1)(v_k,i+1 - v_i) - h*theta*forces(t,v_k,i+1, q_k,i+1) - h*(1-theta)*forces(ti,vi,qi) // // -- Convert the DS into a Lagrangian one. // SP::NewtonEulerDS d = std11::static_pointer_cast<NewtonEulerDS> (ds); // computeW(t,d); // // Get state i (previous time step) from Memories -> var. indexed with "Old" // SP::SiconosVector qold =d->qMemory()->getSiconosVector(0); // SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0); // // --- ResiduFree computation --- // // ResFree = M(v-vold) - h*[theta*forces(t) + (1-theta)*forces(told)] // // // // vFree pointer is used to compute and save ResiduFree in this first step. // SP::SiconosVector vfree = d->workspace(DynamicalSystem::free);//workX[d]; // (*vfree)=*(d->workspace(DynamicalSystem::freeresidu)); // //*(d->vPredictor())=*(d->workspace(DynamicalSystem::freeresidu)); // // -- Update W -- // // Note: during computeW, mass and jacobians of fL will be computed/ // SP::SiconosVector v = d->velocity(); // v = v_k,i+1 // // -- vfree = v - W^{-1} ResiduFree -- // // At this point vfree = residuFree // // -> Solve WX = vfree and set vfree = X // // std::cout<<"SchatzmanPaoliOSI::computeFreeState residu free"<<endl; // // vfree->display(); // d->luW()->PLUForwardBackwardInPlace(*vfree); // // std::cout<<"SchatzmanPaoliOSI::computeFreeState -WRfree"<<endl; // // vfree->display(); // // scal(h,*vfree,*vfree); // // -> compute real vfree // *vfree *= -1.0; // *vfree += *v; RuntimeException::selfThrow("SchatzmanPaoliOSI::computeFreeState - not yet implemented for Dynamical system type: " + dsType); } else RuntimeException::selfThrow("SchatzmanPaoliOSI::computeFreeState - not yet implemented for Dynamical system type: " + dsType); } }
void SchatzmanPaoliOSI::computeFreeState() { // This function computes "free" states of the DS belonging to this Integrator. // "Free" means without taking non-smooth effects into account. //double t = _simulation->nextTime(); // End of the time step //double told = _simulation->startingTime(); // Beginning of the time step //double h = t-told; // time step length // Operators computed at told have index i, and (i+1) at t. // Note: integration of r with a theta method has been removed // SiconosVector *rold = static_cast<SiconosVector*>(d->rMemory()->getSiconosVector(0)); // Iteration through the set of Dynamical Systems. // SP::DynamicalSystem ds; // Current Dynamical System. SP::SiconosMatrix W; // W SchatzmanPaoliOSI matrix of the current DS. Type::Siconos dsType ; // Type of the current DS. DynamicalSystemsGraph::VIterator dsi, dsend; for (std11::tie(dsi, dsend) = _dynamicalSystemsGraph->vertices(); dsi != dsend; ++dsi) { if (!checkOSI(dsi)) continue; ds = _dynamicalSystemsGraph->bundle(*dsi); dsType = Type::value(*ds); // Its type W = _dynamicalSystemsGraph->properties(*dsi).W; // Its W SchatzmanPaoliOSI matrix of iteration. //1 - Lagrangian Non Linear Systems if (dsType == Type::LagrangianDS) { RuntimeException::selfThrow("SchatzmanPaoliOSI::computeFreeState - not yet implemented for Dynamical system type: " + dsType); } // 2 - Lagrangian Linear Systems else if (dsType == Type::LagrangianLinearTIDS) { // IN to be updated at current time: Fext // IN at told: qi,vi, fext // IN constants: K,C // Note: indices i/i+1 corresponds to value at the beginning/end of the time step. // "i" values are saved in memory vectors. // vFree = v_i + W^{-1} ResiduFree // with // ResiduFree = (-h*C -h^2*theta*K)*vi - h*K*qi + h*theta * Fext_i+1 + h*(1-theta)*Fext_i // -- Convert the DS into a Lagrangian one. SP::LagrangianLinearTIDS d = std11::static_pointer_cast<LagrangianLinearTIDS> (ds); // Get state i (previous time step) from Memories -> var. indexed with "Old" SP::SiconosVector qold = d->qMemory()->getSiconosVector(0); // q_k // SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0); //v_k // --- ResiduFree computation --- // vFree pointer is used to compute and save ResiduFree in this first step. // Velocity free and residu. vFree = RESfree (pointer equality !!). SP::SiconosVector qfree = d->workspace(DynamicalSystem::free);//workX[d]; (*qfree) = *(d->workspace(DynamicalSystem::freeresidu)); W->PLUForwardBackwardInPlace(*qfree); *qfree *= -1.0; *qfree += *qold; } // 3 - Newton Euler Systems else if (dsType == Type::NewtonEulerDS) { RuntimeException::selfThrow("SchatzmanPaoliOSI::computeFreeState - not yet implemented for Dynamical system type: " + dsType); } else RuntimeException::selfThrow("SchatzmanPaoliOSI::computeFreeState - not yet implemented for Dynamical system type: " + dsType); } }
double SchatzmanPaoliOSI::computeResidu() { // This function is used to compute the residu for each "SchatzmanPaoliOSI-discretized" dynamical system. // It then computes the norm of each of them and finally return the maximum // value for those norms. // // The state values used are those saved in the DS, ie the last computed ones. // $\mathcal R(x,r) = x - x_{k} -h\theta f( x , t_{k+1}) - h(1-\theta)f(x_k,t_k) - h r$ // $\mathcal R_{free}(x,r) = x - x_{k} -h\theta f( x , t_{k+1}) - h(1-\theta)f(x_k,t_k) $ double t = simulationLink->nextTime(); // End of the time step double told = simulationLink->startingTime(); // Beginning of the time step double h = t - told; // time step length // Operators computed at told have index i, and (i+1) at t. // Iteration through the set of Dynamical Systems. // DSIterator it; SP::DynamicalSystem ds; // Current Dynamical System. Type::Siconos dsType ; // Type of the current DS. double maxResidu = 0; double normResidu = maxResidu; for (it = OSIDynamicalSystems->begin(); it != OSIDynamicalSystems->end(); ++it) { ds = *it; // the considered dynamical system dsType = Type::value(*ds); // Its type SP::SiconosVector residuFree = ds->workspace(DynamicalSystem::freeresidu); // 1 - Lagrangian Non Linear Systems if (dsType == Type::LagrangianDS) { // // residu = M(q*)(v_k,i+1 - v_i) - h*theta*forces(t,v_k,i+1, q_k,i+1) - h*(1-theta)*forces(ti,vi,qi) - pi+1 // // -- Convert the DS into a Lagrangian one. // SP::LagrangianDS d = std11::static_pointer_cast<LagrangianDS> (ds); // // Get state i (previous time step) from Memories -> var. indexed with "Old" // SP::SiconosVector qold =d->qMemory()->getSiconosVector(0); // SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0); // SP::SiconosVector q =d->q(); // d->computeMass(); // SP::SiconosMatrix M = d->mass(); // SP::SiconosVector v = d->velocity(); // v = v_k,i+1 // //residuFree->zero(); // // std::cout << "(*v-*vold)->norm2()" << (*v-*vold).norm2() << std::endl; // prod(*M, (*v-*vold), *residuFree); // residuFree = M(v - vold) // if (d->forces()) // if fL exists // { // // computes forces(ti,vi,qi) // d->computeForces(told,qold,vold); // double coef = -h*(1-_theta); // // residuFree += coef * fL_i // scal(coef, *d->forces(), *residuFree, false); // // computes forces(ti+1, v_k,i+1, q_k,i+1) = forces(t,v,q) // //d->computeForces(t); // // or forces(ti+1, v_k,i+1, q(v_k,i+1)) // //or // SP::SiconosVector qbasedonv(new SiconosVector(*qold)); // *qbasedonv += h*( (1-_theta)* *vold + _theta * *v ); // d->computeForces(t,qbasedonv,v); // coef = -h*_theta; // // residuFree += coef * fL_k,i+1 // scal(coef, *d->forces(), *residuFree, false); // } // if (d->boundaryConditions()) // { // d->boundaryConditions()->computePrescribedVelocity(t); // unsigned int columnindex=0; // SP::SimpleMatrix WBoundaryConditions = _WBoundaryConditionsMap[ds]; // SP::SiconosVector columntmp(new SiconosVector(ds->getDim())); // for (vector<unsigned int>::iterator itindex = d->boundaryConditions()->velocityIndices()->begin() ; // itindex != d->boundaryConditions()->velocityIndices()->end(); // ++itindex) // { // double DeltaPrescribedVelocity = // d->boundaryConditions()->prescribedVelocity()->getValue(columnindex) // - vold->getValue(columnindex); // WBoundaryConditions->getCol(columnindex,*columntmp); // *residuFree -= *columntmp * (DeltaPrescribedVelocity); // residuFree->setValue(*itindex, columntmp->getValue(*itindex) *(DeltaPrescribedVelocity)); // columnindex ++; // } // } // *(d->workspace(DynamicalSystem::free))=*residuFree; // copy residuFree in Workfree // // std::cout << "SchatzmanPaoliOSI::ComputeResidu LagrangianDS residufree :" << std::endl; // // residuFree->display(); // if (d->p(1)) // *(d->workspace(DynamicalSystem::free)) -= *d->p(1); // Compute Residu in Workfree Notation !! // // std::cout << "SchatzmanPaoliOSI::ComputeResidu LagrangianDS residu :" << std::endl; // // d->workspace(DynamicalSystem::free)->display(); // normResidu = d->workspace(DynamicalSystem::free)->norm2(); RuntimeException::selfThrow("SchatzmanPaoliOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType); } // 2 - Lagrangian Linear Systems else if (dsType == Type::LagrangianLinearTIDS) { // ResiduFree = M(-q_{k}+q_{k-1}) + h^2 (K q_k)+ h^2 C (\theta \Frac{q_k-q_{k-1}}{2h}+ (1-\theta) v_k)) (1) // This formulae is only valid for the first computation of the residual for q = q_k // otherwise the complete formulae must be applied, that is // ResiduFree M(q-2q_{k}+q_{k-1}) + h^2 (K(\theta q+ (1-\theta) q_k)))+ h^2 C (\theta \Frac{q-q_{k-1}}{2h}+ (1-\theta) v_k)) (2) // for q != q_k, the formulae (1) is wrong. // in the sequel, only the equation (1) is implemented // -- Convert the DS into a Lagrangian one. SP::LagrangianLinearTIDS d = std11::static_pointer_cast<LagrangianLinearTIDS> (ds); // Get state i (previous time step) from Memories -> var. indexed with "Old" SP::SiconosVector q_k = d->qMemory()->getSiconosVector(0); // q_k SP::SiconosVector q_k_1 = d->qMemory()->getSiconosVector(1); // q_{k-1} SP::SiconosVector v_k = d->velocityMemory()->getSiconosVector(0); //v_k // std::cout << "SchatzmanPaoliOSI::computeResidu - q_k_1 =" <<std::endl; // q_k_1->display(); // std::cout << "SchatzmanPaoliOSI::computeResidu - q_k =" <<std::endl; // q_k->display(); // std::cout << "SchatzmanPaoliOSI::computeResidu - v_k =" <<std::endl; // v_k->display(); // --- ResiduFree computation Equation (1) --- residuFree->zero(); double coeff; // -- No need to update W -- //SP::SiconosVector v = d->velocity(); // v = v_k,i+1 SP::SiconosMatrix M = d->mass(); prod(*M, (*q_k_1 - *q_k), *residuFree); // residuFree = M(-q_{k}+q_{k-1}) SP::SiconosMatrix K = d->K(); if (K) { prod(h * h, *K, *q_k, *residuFree, false); // residuFree += h^2*K*qi } SP::SiconosMatrix C = d->C(); if (C) prod(h * h, *C, (1.0 / (2.0 * h)*_theta * (*q_k - *q_k_1) + (1.0 - _theta)* *v_k) , *residuFree, false); // residufree += h^2 C (\theta \Frac{q-q_{k-1}}{2h}+ (1-\theta) v_k)) SP::SiconosVector Fext = d->fExt(); if (Fext) { // computes Fext(ti) d->computeFExt(told); coeff = -h * h * (1 - _theta); scal(coeff, *Fext, *residuFree, false); // residufree -= h^2*(1-_theta) * fext(ti) // computes Fext(ti+1) d->computeFExt(t); coeff = -h * h * _theta; scal(coeff, *Fext, *residuFree, false); // residufree -= h^2*_theta * fext(ti+1) } // if (d->boundaryConditions()) // { // d->boundaryConditions()->computePrescribedVelocity(t); // unsigned int columnindex=0; // SP::SimpleMatrix WBoundaryConditions = _WBoundaryConditionsMap[ds]; // SP::SiconosVector columntmp(new SiconosVector(ds->getDim())); // for (vector<unsigned int>::iterator itindex = d->boundaryConditions()->velocityIndices()->begin() ; // itindex != d->boundaryConditions()->velocityIndices()->end(); // ++itindex) // { // double DeltaPrescribedVelocity = // d->boundaryConditions()->prescribedVelocity()->getValue(columnindex) // -vold->getValue(columnindex); // WBoundaryConditions->getCol(columnindex,*columntmp); // *residuFree += *columntmp * (DeltaPrescribedVelocity); // residuFree->setValue(*itindex, - columntmp->getValue(*itindex) *(DeltaPrescribedVelocity)); // columnindex ++; // } // } // std::cout << "SchatzmanPaoliOSI::ComputeResidu LagrangianLinearTIDS residufree :" << std::endl; // residuFree->display(); (* d->workspace(DynamicalSystem::free)) = *residuFree; // copy residuFree in Workfree if (d->p(0)) *(d->workspace(DynamicalSystem::free)) -= *d->p(0); // Compute Residu in Workfree Notation !! // std::cout << "SchatzmanPaoliOSI::ComputeResidu LagrangianLinearTIDS p(0) :" << std::endl; // if (d->p(0)) // d->p(0)->display(); // else // std::cout << " p(0) :" << std::endl; // std::cout << "SchatzmanPaoliOSI::ComputeResidu LagrangianLinearTIDS residu :" << std::endl; // d->workspace(DynamicalSystem::free)->display(); // normResidu = d->workspace(DynamicalSystem::free)->norm2(); normResidu = 0.0; // we assume that v = vfree + W^(-1) p // normResidu = realresiduFree->norm2(); } else if (dsType == Type::NewtonEulerDS) { // // residu = M(q*)(v_k,i+1 - v_i) - h*_theta*forces(t,v_k,i+1, q_k,i+1) - h*(1-_theta)*forces(ti,vi,qi) - pi+1 // // -- Convert the DS into a Lagrangian one. // SP::NewtonEulerDS d = std11::static_pointer_cast<NewtonEulerDS> (ds); // // Get state i (previous time step) from Memories -> var. indexed with "Old" // SP::SiconosVector qold =d->qMemory()->getSiconosVector(0); // SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0); // SP::SiconosVector q =d->q(); // SP::SiconosMatrix massMatrix = d->massMatrix(); // SP::SiconosVector v = d->velocity(); // v = v_k,i+1 // prod(*massMatrix, (*v-*vold), *residuFree); // residuFree = M(v - vold) // if (d->forces()) // if fL exists // { // // computes forces(ti,vi,qi) // SP::SiconosVector fLold=d->fLMemory()->getSiconosVector(0); // double _thetaFL=0.5; // double coef = -h*(1-_thetaFL); // // residuFree += coef * fL_i // scal(coef, *fLold, *residuFree, false); // d->computeForces(t); // // printf("cpmputeFreeState d->FL():\n"); // // d->forces()->display(); // coef = -h*_thetaFL; // scal(coef, *d->forces(), *residuFree, false); // } // *(d->workspace(DynamicalSystem::free))=*residuFree; // //cout<<"SchatzmanPaoliOSI::computeResidu :\n"; // // residuFree->display(); // if ( d->p(1) ) // *(d->workspace(DynamicalSystem::free)) -= *d->p(1); // normResidu = d->workspace(DynamicalSystem::free)->norm2(); RuntimeException::selfThrow("SchatzmanPaoliOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType); } else RuntimeException::selfThrow("SchatzmanPaoliOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType); if (normResidu > maxResidu) maxResidu = normResidu; } return maxResidu; }
double SchatzmanPaoliOSI::computeResidu() { // This function is used to compute the residu for each "SchatzmanPaoliOSI-discretized" dynamical system. // It then computes the norm of each of them and finally return the maximum // value for those norms. // // The state values used are those saved in the DS, ie the last computed ones. // $\mathcal R(x,r) = x - x_{k} -h\theta f( x , t_{k+1}) - h(1-\theta)f(x_k,t_k) - h r$ // $\mathcal R_{free}(x,r) = x - x_{k} -h\theta f( x , t_{k+1}) - h(1-\theta)f(x_k,t_k) $ double t = _simulation->nextTime(); // End of the time step double told = _simulation->startingTime(); // Beginning of the time step double h = t - told; // time step length // Operators computed at told have index i, and (i+1) at t. // Iteration through the set of Dynamical Systems. // SP::DynamicalSystem ds; // Current Dynamical System. Type::Siconos dsType ; // Type of the current DS. double maxResidu = 0; double normResidu = maxResidu; DynamicalSystemsGraph::VIterator dsi, dsend; for (std11::tie(dsi, dsend) = _dynamicalSystemsGraph->vertices(); dsi != dsend; ++dsi) { if (!checkOSI(dsi)) continue; SP::DynamicalSystem ds = _dynamicalSystemsGraph->bundle(*dsi); dsType = Type::value(*ds); // Its type SP::SiconosVector residuFree = ds->workspace(DynamicalSystem::freeresidu); // 1 - Lagrangian Non Linear Systems if (dsType == Type::LagrangianDS) { RuntimeException::selfThrow("SchatzmanPaoliOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType); } // 2 - Lagrangian Linear Systems else if (dsType == Type::LagrangianLinearTIDS) { // ResiduFree = M(-q_{k}+q_{k-1}) + h^2 (K q_k)+ h^2 C (\theta \Frac{q_k-q_{k-1}}{2h}+ (1-\theta) v_k)) (1) // This formulae is only valid for the first computation of the residual for q = q_k // otherwise the complete formulae must be applied, that is // ResiduFree M(q-2q_{k}+q_{k-1}) + h^2 (K(\theta q+ (1-\theta) q_k)))+ h^2 C (\theta \Frac{q-q_{k-1}}{2h}+ (1-\theta) v_k)) (2) // for q != q_k, the formulae (1) is wrong. // in the sequel, only the equation (1) is implemented // -- Convert the DS into a Lagrangian one. SP::LagrangianLinearTIDS d = std11::static_pointer_cast<LagrangianLinearTIDS> (ds); // Get state i (previous time step) from Memories -> var. indexed with "Old" SP::SiconosVector q_k = d->qMemory()->getSiconosVector(0); // q_k SP::SiconosVector q_k_1 = d->qMemory()->getSiconosVector(1); // q_{k-1} SP::SiconosVector v_k = d->velocityMemory()->getSiconosVector(0); //v_k // std::cout << "SchatzmanPaoliOSI::computeResidu - q_k_1 =" <<std::endl; // q_k_1->display(); // std::cout << "SchatzmanPaoliOSI::computeResidu - q_k =" <<std::endl; // q_k->display(); // std::cout << "SchatzmanPaoliOSI::computeResidu - v_k =" <<std::endl; // v_k->display(); // --- ResiduFree computation Equation (1) --- residuFree->zero(); double coeff; // -- No need to update W -- //SP::SiconosVector v = d->velocity(); // v = v_k,i+1 SP::SiconosMatrix M = d->mass(); prod(*M, (*q_k_1 - *q_k), *residuFree); // residuFree = M(-q_{k}+q_{k-1}) SP::SiconosMatrix K = d->K(); if (K) { prod(h * h, *K, *q_k, *residuFree, false); // residuFree += h^2*K*qi } SP::SiconosMatrix C = d->C(); if (C) prod(h * h, *C, (1.0 / (2.0 * h)*_theta * (*q_k - *q_k_1) + (1.0 - _theta)* *v_k) , *residuFree, false); // residufree += h^2 C (\theta \Frac{q-q_{k-1}}{2h}+ (1-\theta) v_k)) SP::SiconosVector Fext = d->fExt(); if (Fext) { // computes Fext(ti) d->computeFExt(told); coeff = -h * h * (1 - _theta); scal(coeff, *Fext, *residuFree, false); // residufree -= h^2*(1-_theta) * fext(ti) // computes Fext(ti+1) d->computeFExt(t); coeff = -h * h * _theta; scal(coeff, *Fext, *residuFree, false); // residufree -= h^2*_theta * fext(ti+1) } // std::cout << "SchatzmanPaoliOSI::ComputeResidu LagrangianLinearTIDS residufree :" << std::endl; // residuFree->display(); (* d->workspace(DynamicalSystem::free)) = *residuFree; // copy residuFree in Workfree if (d->p(0)) *(d->workspace(DynamicalSystem::free)) -= *d->p(0); // Compute Residu in Workfree Notation !! // std::cout << "SchatzmanPaoliOSI::ComputeResidu LagrangianLinearTIDS p(0) :" << std::endl; // if (d->p(0)) // d->p(0)->display(); // else // std::cout << " p(0) :" << std::endl; // std::cout << "SchatzmanPaoliOSI::ComputeResidu LagrangianLinearTIDS residu :" << std::endl; // d->workspace(DynamicalSystem::free)->display(); // normResidu = d->workspace(DynamicalSystem::free)->norm2(); normResidu = 0.0; // we assume that v = vfree + W^(-1) p // normResidu = realresiduFree->norm2(); } else if (dsType == Type::NewtonEulerDS) { RuntimeException::selfThrow("SchatzmanPaoliOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType); } else RuntimeException::selfThrow("SchatzmanPaoliOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType); if (normResidu > maxResidu) maxResidu = normResidu; } return maxResidu; }