double D1MinusLinearOSI::computeResiduHalfExplicitAccelerationLevel()
{
  DEBUG_BEGIN("\n D1MinusLinearOSI::computeResiduHalfExplicitAccelerationLevel()\n");

  double t = _simulation->nextTime(); // end of the time step
  double told = _simulation->startingTime(); // beginning of the time step
  double h = _simulation->timeStep(); // time step length

  SP::OneStepNSProblems allOSNS  = _simulation->oneStepNSProblems(); // all OSNSP
  SP::Topology topo =  _simulation->nonSmoothDynamicalSystem()->topology();
  SP::InteractionsGraph indexSet2 = topo->indexSet(2);

  /**************************************************************************************************************
   *  Step 1-  solve a LCP at acceleration level for lambda^+_{k} for the last set indices
   *   if index2 is empty we should skip this step
   **************************************************************************************************************/

  DEBUG_PRINT("\nEVALUATE LEFT HAND SIDE\n");

  DEBUG_EXPR(std::cout<< "allOSNS->empty()   " << std::boolalpha << allOSNS->empty() << std::endl << std::endl);
  DEBUG_EXPR(std::cout<< "allOSNS->size()   "  << allOSNS->size() << std::endl << std::endl);

// -- LEFT SIDE --
  DynamicalSystemsGraph::VIterator dsi, dsend;
  for (std11::tie(dsi, dsend) = _dynamicalSystemsGraph->vertices(); dsi != dsend; ++dsi)
  {
    if (!checkOSI(dsi)) continue;
    SP::DynamicalSystem ds = _dynamicalSystemsGraph->bundle(*dsi);

    Type::Siconos dsType = Type::value(*ds);
    SP::SiconosVector accFree;
    SP::SiconosVector work_tdg;
    SP::SiconosMatrix Mold;
    DEBUG_EXPR((*it)->display());

    if ((dsType == Type::LagrangianDS) || (dsType == Type::LagrangianLinearTIDS))
    {
      SP::LagrangianDS d = std11::static_pointer_cast<LagrangianDS> (ds);
      accFree = d->workspace(DynamicalSystem::free); /* POINTER CONSTRUCTOR : will contain
                                                       * the acceleration without contact force */
      accFree->zero();

      // get left state from memory
      SP::SiconosVector qold = d->qMemory()->getSiconosVector(0);
      SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0); // right limit
      Mold = d->mass();

      DEBUG_EXPR(accFree->display());
      DEBUG_EXPR(qold->display());
      DEBUG_EXPR(vold->display());
      DEBUG_EXPR(Mold->display());

      if (! d->workspace(DynamicalSystem::free_tdg))
      {
        d->allocateWorkVector(DynamicalSystem::free_tdg, d->dimension()) ;
      }
      work_tdg = d->workspace(DynamicalSystem::free_tdg);
      work_tdg->zero();
      DEBUG_EXPR(work_tdg->display());

      if (d->forces())
      {
        d->computeForces(told, qold, vold);
        DEBUG_EXPR(d->forces()->display());

        *accFree += *(d->forces());
      }
      Mold->PLUForwardBackwardInPlace(*accFree); // contains left (right limit) acceleration without contact force
      d->addWorkVector(accFree,DynamicalSystem::free_tdg); // store the value in WorkFreeFree
    }
    else if(dsType == Type::NewtonEulerDS)
    {
      SP::NewtonEulerDS d = std11::static_pointer_cast<NewtonEulerDS> (ds);
      accFree = d->workspace(DynamicalSystem::free); // POINTER CONSTRUCTOR : contains acceleration without contact force
      accFree->zero();

      // get left state from memory
      SP::SiconosVector qold = d->qMemory()->getSiconosVector(0);
      SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0); // right limit
      //Mold = d->mass();
      assert(!d->mass()->isPLUInversed());
      Mold.reset(new SimpleMatrix(*(d->mass()))); // we copy the mass matrix to avoid its factorization
      DEBUG_EXPR(accFree->display());
      DEBUG_EXPR(qold->display());
      DEBUG_EXPR(vold->display());
      DEBUG_EXPR(Mold->display());

      if (! d->workspace(DynamicalSystem::free_tdg))
      {
        d->allocateWorkVector(DynamicalSystem::free_tdg, d->dimension()) ;
      }

      work_tdg = d->workspace(DynamicalSystem::free_tdg);
      work_tdg->zero();
      DEBUG_EXPR(work_tdg->display());

      if (d->forces())
      {
        d->computeForces(told, qold, vold);
        DEBUG_EXPR(d->forces()->display());

        *accFree += *(d->forces());
      }
      Mold->PLUForwardBackwardInPlace(*accFree); // contains left (right limit) acceleration without contact force

      d->addWorkVector(accFree,DynamicalSystem::free_tdg); // store the value in WorkFreeFree

    }
    else
    {
      RuntimeException::selfThrow("D1MinusLinearOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType);
    }


    DEBUG_PRINT("accFree contains right limit acceleration at  t^+_k with contact force :\n");
    DEBUG_EXPR(accFree->display());
    DEBUG_PRINT("work_tdg contains right limit acceleration at t^+_k without contact force :\n");
    DEBUG_EXPR(work_tdg->display());

  }


  if (!allOSNS->empty())
  {
    if (indexSet2->size() >0)
    {
      InteractionsGraph::VIterator ui, uiend;
      SP::Interaction inter;
      for (std11::tie(ui, uiend) = indexSet2->vertices(); ui != uiend; ++ui)
      {
        inter = indexSet2->bundle(*ui);
        inter->relation()->computeJach(t, *inter, indexSet2->properties(*ui));
        inter->relation()->computeJacg(told, *inter, indexSet2->properties(*ui));
      }

      if (_simulation->nonSmoothDynamicalSystem()->topology()->hasChanged())
      {
        for (OSNSIterator itOsns = allOSNS->begin(); itOsns != allOSNS->end(); ++itOsns)
        {
          (*itOsns)->setHasBeenUpdated(false);
        }
      }
      assert((*allOSNS)[SICONOS_OSNSP_TS_VELOCITY + 1]);

      if (((*allOSNS)[SICONOS_OSNSP_TS_VELOCITY + 1]->hasInteractions())) // it should be equivalent to indexSet2
      {
        DEBUG_PRINT("We compute lambda^+_{k} \n");
        (*allOSNS)[SICONOS_OSNSP_TS_VELOCITY + 1]->compute(told);
        DEBUG_EXPR((*allOSNS)[SICONOS_OSNSP_TS_VELOCITY + 1]->display());
      }


      // Note Franck : at the time this results in a call to swapInMem of all Interactions of the NSDS
      // So let the simu do this.
      //(*allOSNS)[SICONOS_OSNSP_TS_VELOCITY + 1]->saveInMemory(); // we push y and lambda in Memories
      _simulation->nonSmoothDynamicalSystem()->pushInteractionsInMemory();
      _simulation->nonSmoothDynamicalSystem()->updateInput(_simulation->nextTime(),2);

      for (std11::tie(dsi, dsend) = _dynamicalSystemsGraph->vertices(); dsi != dsend; ++dsi)
      {
        if (!checkOSI(dsi)) continue;
        SP::DynamicalSystem ds = _dynamicalSystemsGraph->bundle(*dsi);

        Type::Siconos dsType = Type::value(*ds);
        if ((dsType == Type::LagrangianDS) || (dsType == Type::LagrangianLinearTIDS))
        {
          SP::LagrangianDS d = std11::static_pointer_cast<LagrangianDS> (ds);
          SP::SiconosVector accFree = d->workspace(DynamicalSystem::free); // POINTER CONSTRUCTOR : contains acceleration without contact force

          SP::SiconosVector dummy(new SiconosVector(*(d->p(2)))); // value = contact force
          SP::SiconosMatrix Mold = d->mass();
          Mold->PLUForwardBackwardInPlace(*dummy);
          *accFree  += *(dummy);

          DEBUG_EXPR(d->p(2)->display());
        }
        else if (dsType == Type::NewtonEulerDS)
        {
          SP::NewtonEulerDS d = std11::static_pointer_cast<NewtonEulerDS> (ds);
          SP::SiconosVector accFree = d->workspace(DynamicalSystem::free); // POINTER CONSTRUCTOR : contains acceleration without contact force

          SP::SiconosVector dummy(new SiconosVector(*(d->p(2)))); // value = contact force
          SP::SiconosMatrix Mold(new SimpleMatrix(*(d->mass())));  // we copy the mass matrix to avoid its factorization
          DEBUG_EXPR(Mold->display());
          Mold->PLUForwardBackwardInPlace(*dummy);
          *accFree  += *(dummy);

          DEBUG_EXPR(d->p(2)->display());

        }
        else
          RuntimeException::selfThrow("D1MinusLinearOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType);

      }
    }
  }

  /**************************************************************************************************************
   *  Step 2 -  compute v_{k,1}
   **************************************************************************************************************/


  DEBUG_PRINT("\n PREDICT RIGHT HAND SIDE\n");

  for (std11::tie(dsi, dsend) = _dynamicalSystemsGraph->vertices(); dsi != dsend; ++dsi)
  {
    if (!checkOSI(dsi)) continue;
    SP::DynamicalSystem ds = _dynamicalSystemsGraph->bundle(*dsi);


    // type of the current DS
    Type::Siconos dsType = Type::value(*ds);
    /* \warning the following conditional statement should be removed with a MechanicalDS class */
    if ((dsType == Type::LagrangianDS) || (dsType == Type::LagrangianLinearTIDS))
    {
      SP::LagrangianDS d = std11::static_pointer_cast<LagrangianDS> (ds);
      SP::SiconosVector accFree = d->workspace(DynamicalSystem::free); // contains acceleration without contact force

      // get left state from memory
      SP::SiconosVector qold = d->qMemory()->getSiconosVector(0);
      SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0);

      // initialize *it->residuFree and predicted right velocity (left limit)
      SP::SiconosVector residuFree = ds->workspace(DynamicalSystem::freeresidu); // contains residu without nonsmooth effect
      SP::SiconosVector v = d->velocity(); //contains velocity v_{k+1}^- and not free velocity
      residuFree->zero();
      v->zero();

      DEBUG_EXPR(accFree->display());
      DEBUG_EXPR(qold->display());
      DEBUG_EXPR(vold->display());


      *residuFree -= 0.5 * h**accFree;

      *v += h**accFree;
      *v += *vold;

      DEBUG_EXPR(residuFree->display());
      DEBUG_EXPR(v->display());

      SP::SiconosVector q = d->q(); // POINTER CONSTRUCTOR : contains position q_{k+1}
      *q = *qold;

      scal(0.5 * h, *vold + *v, *q, false);
      DEBUG_EXPR(q->display());
    }
    else if (dsType == Type::NewtonEulerDS)
    {
      SP::NewtonEulerDS d = std11::static_pointer_cast<NewtonEulerDS> (ds);
      SP::SiconosVector accFree = d->workspace(DynamicalSystem::free);

      // get left state from memory
      SP::SiconosVector qold = d->qMemory()->getSiconosVector(0);
      SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0);

      // initialize *it->residuFree and predicted right velocity (left limit)
      SP::SiconosVector residuFree = ds->workspace(DynamicalSystem::freeresidu); // contains residu without nonsmooth effect
      SP::SiconosVector v = d->velocity(); //contains velocity v_{k+1}^- and not free velocity
      residuFree->zero();
      v->zero();

      DEBUG_EXPR(accFree->display());
      DEBUG_EXPR(qold->display());
      DEBUG_EXPR(vold->display());


      *residuFree -= 0.5 * h**accFree;

      *v += h**accFree;
      *v += *vold;

      DEBUG_EXPR(residuFree->display());
      DEBUG_EXPR(v->display());

      //first step consists in computing  \dot q.
      //second step consists in updating q.
      //
      SP::SiconosMatrix T = d->T();
      SP::SiconosVector dotq = d->dotq();
      prod(*T, *v, *dotq, true);

      SP::SiconosVector dotqold = d->dotqMemory()->getSiconosVector(0);

      SP::SiconosVector q = d->q(); // POINTER CONSTRUCTOR : contains position q_{k+1}
      *q = *qold;

      scal(0.5 * h, *dotqold + *dotq, *q, false);
      DEBUG_PRINT("new q before normalizing\n");
      DEBUG_EXPR(q->display());
      //q[3:6] must be normalized
      d->normalizeq();
      d->computeT();
      DEBUG_PRINT("new q after normalizing\n");
      DEBUG_EXPR(q->display());



    }
    else
      RuntimeException::selfThrow("D1MinusLinearOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType);


    /** At this step, we obtain
     * \f[
     * \begin{cases}
     * v_{k,0} = \mbox{\tt vold} \\
     * q_{k,0} = qold \\
     * F_{k,+} = F(told,qold,vold) \\
     * Work_{freefree} =  M^{-1}_k (F^+_{k})  \mbox{stored in work_tdg} \\
     * Work_{free} =  M^{-1}_k (P^+_{2,k}+F^+_{k})  \mbox{stored in accFree} \\
     * R_{free} = -h/2 * M^{-1}_k (P^+_{2,k}+F^+_{k})  \mbox{stored in ResiduFree} \\
     * v_{k,1} = v_{k,0} + h * M^{-1}_k (P^+_{2,k}+F^+_{k})  \mbox{stored in v} \\
     * q_{k,1} = q_{k,0} + \frac{h}{2} (v_{k,0} + v_{k,1}) \mbox{stored in q} \\
     * \end{cases}
     * \f]
     **/
  }

  DEBUG_PRINT("\n DECIDE STRATEGY\n");
  /** Decide of the strategy impact or smooth multiplier.
   *  Compute _isThereImpactInTheTimeStep
   */
  _isThereImpactInTheTimeStep = false;
  if (!allOSNS->empty())
  {

    for (unsigned int level = _simulation->levelMinForOutput();
         level < _simulation->levelMaxForOutput(); level++)
    {
      _simulation->nonSmoothDynamicalSystem()->updateOutput(_simulation->nextTime(),level);
    }
    _simulation->updateIndexSets();

    SP::Topology topo =  _simulation->nonSmoothDynamicalSystem()->topology();
    SP::InteractionsGraph indexSet3 = topo->indexSet(3);

    if (indexSet3->size() > 0)
    {
      _isThereImpactInTheTimeStep = true;
      DEBUG_PRINT("There is an impact in the step. indexSet3->size() > 0. _isThereImpactInTheTimeStep = true;\n");
    }
    else
    {
      _isThereImpactInTheTimeStep = false;
      DEBUG_PRINT("There is no  impact in the step. indexSet3->size() = 0. _isThereImpactInTheTimeStep = false;\n");
    }
  }


  /* If _isThereImpactInTheTimeStep = true;
   * we recompute residuFree by removing the contribution of the nonimpulsive contact forces.
   * We add the contribution of the external forces at the end
   * of the time--step
   * If _isThereImpactInTheTimeStep = false;
   * we recompute residuFree by adding   the contribution of the external forces at the end
   * and the contribution of the nonimpulsive contact forces that are computed by solving the osnsp.
   */
  if (_isThereImpactInTheTimeStep)
  {

    DEBUG_PRINT("There is an impact in the step. indexSet3->size() > 0.  _isThereImpactInTheTimeStep = true\n");
    for (std11::tie(dsi, dsend) = _dynamicalSystemsGraph->vertices(); dsi != dsend; ++dsi)
    {
      if (!checkOSI(dsi)) continue;
      SP::DynamicalSystem ds = _dynamicalSystemsGraph->bundle(*dsi);

      // type of the current DS
      Type::Siconos dsType = Type::value(*ds);
      /* \warning the following conditional statement should be removed with a MechanicalDS class */
      if ((dsType == Type::LagrangianDS) || (dsType == Type::LagrangianLinearTIDS))
      {
        SP::LagrangianDS d = std11::static_pointer_cast<LagrangianDS> (ds);
        SP::SiconosVector residuFree = d->workspace(DynamicalSystem::freeresidu);
        SP::SiconosVector v = d->velocity();
        SP::SiconosVector q = d->q();
        SP::SiconosVector qold = d->qMemory()->getSiconosVector(0);
        SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0); // right limit

        SP::SiconosMatrix M = d->mass(); // POINTER CONSTRUCTOR : contains mass matrix

        //residuFree->zero();
        //v->zero();
        SP::SiconosVector work_tdg = d->workspace(DynamicalSystem::free_tdg);
        assert(work_tdg);
        *residuFree =  - 0.5 * h**work_tdg;


        d->computeMass();
        DEBUG_EXPR(M->display());
        if (d->forces())
        {
          d->computeForces(t, q, v);
          *work_tdg = *(d->forces());
          DEBUG_EXPR(d->forces()->display());
        }

        M->PLUForwardBackwardInPlace(*work_tdg); // contains right (left limit) acceleration without contact force
        *residuFree -= 0.5 * h**work_tdg;
        DEBUG_EXPR(residuFree->display());
      }
      else if (dsType == Type::NewtonEulerDS)
      {
        SP::NewtonEulerDS d = std11::static_pointer_cast<NewtonEulerDS> (ds);
        SP::SiconosVector residuFree = d->workspace(DynamicalSystem::freeresidu);
        SP::SiconosVector v = d->velocity();
        SP::SiconosVector q = d->q();
        SP::SiconosVector qold = d->qMemory()->getSiconosVector(0);
        SP::SiconosVector vold = d->velocityMemory()->getSiconosVector(0); // right limit

        SP::SiconosMatrix M(new SimpleMatrix(*(d->mass()))); // we copy the mass matrix to avoid its factorization;
        DEBUG_EXPR(M->display());

        //residuFree->zero();
        v->zero();
        SP::SiconosVector work_tdg = d->workspace(DynamicalSystem::free_tdg);
        assert(work_tdg);
        *residuFree = 0.5 * h**work_tdg;
        work_tdg->zero();

        if (d->forces())
        {
          d->computeForces(t, q, v);
          *work_tdg += *(d->forces());
        }

        M->PLUForwardBackwardInPlace(*work_tdg); // contains right (left limit) acceleration without contact force
        *residuFree -= 0.5 * h**work_tdg;
        DEBUG_EXPR(residuFree->display());
      }
      else
        RuntimeException::selfThrow("D1MinusLinearOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType);
    }
  }
  else
  {
    DEBUG_PRINT("There is no  impact in the step. indexSet3->size() = 0. _isThereImpactInTheTimeStep = false;\n");
    // -- RIGHT SIDE --
    // calculate acceleration without contact force

    for (std11::tie(dsi, dsend) = _dynamicalSystemsGraph->vertices(); dsi != dsend; ++dsi)
    {
      if (!checkOSI(dsi)) continue;
      SP::DynamicalSystem ds = _dynamicalSystemsGraph->bundle(*dsi);

    
      // type of the current DS
      Type::Siconos dsType = Type::value(*ds);
      /* \warning the following conditional statement should be removed with a MechanicalDS class */
      if ((dsType == Type::LagrangianDS) || (dsType == Type::LagrangianLinearTIDS))
      {

        SP::LagrangianDS d = std11::static_pointer_cast<LagrangianDS> (ds);
        SP::SiconosVector accFree = d->workspace(DynamicalSystem::free); // POINTER CONSTRUCTOR : contains acceleration without contact force
        accFree->zero();
        // get right state from memory
        SP::SiconosVector q = d->q(); // contains position q_{k+1}
        SP::SiconosVector v = d->velocity(); // contains velocity v_{k+1}^- and not free velocity
        SP::SiconosMatrix M = d->mass(); // POINTER CONSTRUCTOR : contains mass matrix

        DEBUG_EXPR(accFree->display());
        DEBUG_EXPR(q->display());
        DEBUG_EXPR(v->display());
        // Lagrangian Nonlinear Systems
        if (dsType == Type::LagrangianDS || dsType == Type::LagrangianLinearTIDS)
        {
          d->computeMass();

          DEBUG_EXPR(M->display());
          if (d->forces())
          {
            d->computeForces(t, q, v);
            *accFree += *(d->forces());
          }
        }
        else
          RuntimeException::selfThrow
          ("D1MinusLinearOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType);

        M->PLUForwardBackwardInPlace(*accFree); // contains right (left limit) acceleration without contact force
        DEBUG_PRINT("accFree contains left limit acceleration at  t^-_{k+1} without contact force :\n");
        DEBUG_EXPR(accFree->display());
       }
      else if (dsType == Type::NewtonEulerDS)
      {
        SP::NewtonEulerDS d = std11::static_pointer_cast<NewtonEulerDS> (ds);
        SP::SiconosVector accFree = d->workspace(DynamicalSystem::free); // POINTER CONSTRUCTOR : contains acceleration without contact force
        accFree->zero();
        // get right state from memory
        SP::SiconosVector q = d->q(); // contains position q_{k+1}
        SP::SiconosVector v = d->velocity(); // contains velocity v_{k+1}^- and not free velocity
        SP::SiconosMatrix M(new SimpleMatrix(*(d->mass()))); // we copy the mass matrix to avoid its factorization;

        DEBUG_EXPR(accFree->display());
        DEBUG_EXPR(q->display());
        DEBUG_EXPR(v->display());

        if (d->forces())
        {
          d->computeForces(t, q, v);
          *accFree += *(d->forces());
        }

        M->PLUForwardBackwardInPlace(*accFree); // contains right (left limit) acceleration without contact force
        DEBUG_PRINT("accFree contains left limit acceleration at  t^-_{k+1} without contact force :\n");
        DEBUG_EXPR(accFree->display());
      }
      else
        RuntimeException::selfThrow("D1MinusLinearOSI::computeResidu - not yet implemented for Dynamical system type: " + dsType);

    }

    // solve a LCP at acceleration level only for contacts which have been active at the beginning of the time-step
    if (!allOSNS->empty())
    {
      // for (unsigned int level = _simulation->levelMinForOutput(); level < _simulation->levelMaxForOutput(); level++)
      // {
      //   _simulation->updateOutput(level);
      // }
      // _simulation->updateIndexSets();
      DEBUG_PRINT("We compute lambda^-_{k+1} \n");
      InteractionsGraph::VIterator ui, uiend;
      SP::Interaction inter;
      for (std11::tie(ui, uiend) = indexSet2->vertices(); ui != uiend; ++ui)
      {
        inter = indexSet2->bundle(*ui);
        inter->relation()->computeJach(t, *inter, indexSet2->properties(*ui));
        inter->relation()->computeJacg(t, *inter, indexSet2->properties(*ui));
      }
      if (_simulation->nonSmoothDynamicalSystem()->topology()->hasChanged())
      {
        for (OSNSIterator itOsns = allOSNS->begin(); itOsns != allOSNS->end(); ++itOsns)
        {
          (*itOsns)->setHasBeenUpdated(false);
        }
      }

      if (((*allOSNS)[SICONOS_OSNSP_TS_VELOCITY + 1]->hasInteractions()))
      {
        (*allOSNS)[SICONOS_OSNSP_TS_VELOCITY + 1]->compute(t);
        DEBUG_EXPR((*allOSNS)[SICONOS_OSNSP_TS_VELOCITY + 1]->display(););
        _simulation->nonSmoothDynamicalSystem()->updateInput(_simulation->nextTime(),2);
      }
Ejemplo n.º 2
0
void SchatzmanPaoliOSI::updateState(const unsigned int level)
{

  double h = simulationLink->timeStep();

  double RelativeTol = simulationLink->relativeConvergenceTol();
  bool useRCC = simulationLink->useRelativeConvergenceCriteron();
  if (useRCC)
    simulationLink->setRelativeConvergenceCriterionHeld(true);

  DSIterator it;
  SP::SiconosMatrix W;
  for (it = OSIDynamicalSystems->begin(); it != OSIDynamicalSystems->end(); ++it)
  {
    SP::DynamicalSystem ds = *it;
    W = WMap[ds->number()];
    // Get the DS type

    Type::Siconos dsType = Type::value(*ds);

    // 1 - Lagrangian Systems
    if (dsType == Type::LagrangianDS || dsType == Type::LagrangianLinearTIDS)
    {
      // get dynamical system
      SP::LagrangianDS d = std11::static_pointer_cast<LagrangianDS> (ds);

      //    SiconosVector *vfree = d->velocityFree();
      SP::SiconosVector q = d->q();
      bool baux = dsType == Type::LagrangianDS && useRCC && simulationLink->relativeConvergenceCriterionHeld();
      if (level != LEVELMAX)
      {
        // To compute q, we solve W(q - qfree) = p
        if (d->p(level))
        {
          *q = *d->p(level); // q = p
          W->PLUForwardBackwardInPlace(*q);
        }

        // if (d->boundaryConditions())
        //   for (vector<unsigned int>::iterator
        //        itindex = d->boundaryConditions()->velocityIndices()->begin() ;
        //        itindex != d->boundaryConditions()->velocityIndices()->end();
        //        ++itindex)
        //     v->setValue(*itindex, 0.0);
        *q +=  * ds->workspace(DynamicalSystem::free);

      }
      else
        *q =  * ds->workspace(DynamicalSystem::free);



      // Computation of the velocity

      SP::SiconosVector v = d->velocity();
      SP::SiconosVector q_k_1 = d->qMemory()->getSiconosVector(1); // q_{k-1}

      //  std::cout << "SchatzmanPaoliOSI::updateState - q_k_1 =" <<std::endl;
      // q_k_1->display();
      //  std::cout << "SchatzmanPaoliOSI::updateState - q =" <<std::endl;
      // q->display();

      *v = 1.0 / (2.0 * h) * (*q - *q_k_1);
      //  std::cout << "SchatzmanPaoliOSI::updateState - v =" <<std::endl;
      // v->display();

      // int bc=0;
      // SP::SiconosVector columntmp(new SiconosVector(ds->getDim()));

      // if (d->boundaryConditions())
      // {
      //   for (vector<unsigned int>::iterator  itindex = d->boundaryConditions()->velocityIndices()->begin() ;
      //        itindex != d->boundaryConditions()->velocityIndices()->end();
      //        ++itindex)
      //   {
      //     _WBoundaryConditionsMap[ds]->getCol(bc,*columntmp);
      //     /*\warning we assume that W is symmetric in the Lagrangian case*/
      //     double value = - inner_prod(*columntmp, *v);
      //     value += (d->p(level))->getValue(*itindex);
      //     /* \warning the computation of reactionToBoundaryConditions take into
      //        account the contact impulse but not the external and internal forces.
      //        A complete computation of the residue should be better */
      //     d->reactionToBoundaryConditions()->setValue(bc,value) ;
      //     bc++;
      //   }

      if (baux)
      {
        ds->subWorkVector(q, DynamicalSystem::local_buffer);
        double aux = ((ds->workspace(DynamicalSystem::local_buffer))->norm2()) / (ds->normRef());
        if (aux > RelativeTol)
          simulationLink->setRelativeConvergenceCriterionHeld(false);
      }

    }
    //2 - Newton Euler Systems
    else if (dsType == Type::NewtonEulerDS)
    {
      //  // get dynamical system
      //       SP::NewtonEulerDS d = std11::static_pointer_cast<NewtonEulerDS> (ds);
      //       SP::SiconosVector v = d->velocity();
      // #ifdef SCHATZMANPAOLI_NE_DEBUG
      //       std::cout<<"SchatzmanPaoliOSI::updatestate prev v"<<endl;
      //       v->display();
      // #endif

      //       /*d->p has been fill by the Relation->computeInput, it contains
      //            B \lambda _{k+1}*/
      //       *v = *d->p(level); // v = p
      //       d->luW()->PLUForwardBackwardInPlace(*v);

      // #ifdef SCHATZMANPAOLI_NE_DEBUG
      //       std::cout<<"SchatzmanPaoliOSI::updatestate hWB lambda"<<endl;
      //       v->display();
      // #endif

      //       *v +=  * ds->workspace(DynamicalSystem::free);

      // #ifdef SCHATZMANPAOLI_NE_DEBUG
      //       std::cout<<"SchatzmanPaoliOSI::updatestate work free"<<endl;
      //       ds->workspace(DynamicalSystem::free)->display();
      //       std::cout<<"SchatzmanPaoliOSI::updatestate new v"<<endl;
      //       v->display();
      // #endif
      //       //compute q
      //       //first step consists in computing  \dot q.
      //       //second step consists in updating q.
      //       //
      //       SP::SiconosMatrix T = d->T();
      //       SP::SiconosVector dotq = d->dotq();
      //       prod(*T,*v,*dotq,true);
      //       // std::cout<<"SchatzmanPaoliOSI::updateState v"<<endl;
      //       // v->display();
      //       // std::cout<<"SchatzmanPaoliOSI::updateState dotq"<<endl;
      //       // dotq->display();




      //       SP::SiconosVector q = d->q();

      //       //  -> get previous time step state
      //       SP::SiconosVector dotqold = d->dotqMemory()->getSiconosVector(0);
      //       SP::SiconosVector qold = d->qMemory()->getSiconosVector(0);
      //       // *q = *qold + h*(theta * *v +(1.0 - theta)* *vold)
      //       double coeff = h*_theta;
      //       scal(coeff, *dotq, *q) ; // q = h*theta*v
      //       coeff = h*(1-_theta);
      //       scal(coeff,*dotqold,*q,false); // q += h(1-theta)*vold
      //       *q += *qold;
      // #ifdef SCHATZMANPAOLI_NE_DEBUG
      //       std::cout<<"new q before normalizing"<<endl;
      //       q->display();
      // #endif

      //       //q[3:6] must be normalized
      //       d->normalizeq();
      //       dotq->setValue(3,(q->getValue(3)-qold->getValue(3))/h);
      //       dotq->setValue(4,(q->getValue(4)-qold->getValue(4))/h);
      //       dotq->setValue(5,(q->getValue(5)-qold->getValue(5))/h);
      //       dotq->setValue(6,(q->getValue(6)-qold->getValue(6))/h);
      //       d->updateT();
      RuntimeException::selfThrow("SchatzmanPaoliOSI::updateState - not yet implemented for Dynamical system type: " + dsType);
    }
    else RuntimeException::selfThrow("SchatzmanPaoliOSI::updateState - not yet implemented for Dynamical system type: " + dsType);
  }
}
Ejemplo n.º 3
0
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;
}
Ejemplo n.º 4
0
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;
}