docs/tempus/Tempus__Test__BackwardEuler__SinCos_8cpp_source.html

//@HEADER

// *****************************************************************************

//          Tempus: Time Integration and Sensitivity Analysis Package

//

// Copyright 2017 NTESS and the Tempus contributors.

// SPDX-License-Identifier: BSD-3-Clause

// *****************************************************************************

//@HEADER


#include "Teuchos_UnitTestHarness.hpp"

#include "Teuchos_XMLParameterListHelpers.hpp"

#include "Teuchos_TimeMonitor.hpp"

#include "Teuchos_DefaultComm.hpp"


#include "Tempus_config.hpp"

#include "Tempus_IntegratorBasic.hpp"

#include "Tempus_StepperBackwardEuler.hpp"


#include "../TestModels/SinCosModel.hpp"

#include "../TestUtils/Tempus_ConvergenceTestUtils.hpp"


#include <vector>

#include <fstream>

#include <sstream>

#include <limits>


namespace Tempus_Test {


using Teuchos::getParametersFromXmlFile;

using Teuchos::ParameterList;

using Teuchos::RCP;

using Teuchos::rcp;

using Teuchos::rcp_const_cast;

using Teuchos::sublist;


using Tempus::IntegratorBasic;

using Tempus::SolutionHistory;

using Tempus::SolutionState;


// ************************************************************

// ************************************************************


TEUCHOS_UNIT_TEST(BackwardEuler, SinCos)

{

  RCP<Tempus::IntegratorBasic<double>> integrator;

  std::vector<RCP<Thyra::VectorBase<double>>> solutions;

  std::vector<RCP<Thyra::VectorBase<double>>> solutionsDot;

  std::vector<double> StepSize;

  std::vector<double> xErrorNorm;

  std::vector<double> xDotErrorNorm;

  const int nTimeStepSizes = 7;

  double dt                = 0.2;

  double time              = 0.0;

  for (int n = 0; n < nTimeStepSizes; n++) {

    // Read params from .xml file

    RCP<ParameterList> pList =

        getParametersFromXmlFile("Tempus_BackwardEuler_SinCos.xml");


    // std::ofstream ftmp("PL.txt");

    // pList->print(ftmp);

    // ftmp.close();


    // Setup the SinCosModel

    RCP<ParameterList> scm_pl = sublist(pList, "SinCosModel", true);

    // RCP<SinCosModel<double> > model = sineCosineModel(scm_pl);

    auto model = rcp(new SinCosModel<double>(scm_pl));


    dt /= 2;


    // Setup the Integrator and reset initial time step

    RCP<ParameterList> pl = sublist(pList, "Tempus", true);

    pl->sublist("Default Integrator")

        .sublist("Time Step Control")

        .set("Initial Time Step", dt);

    integrator = Tempus::createIntegratorBasic<double>(pl, model);


    // Initial Conditions

    // During the Integrator construction, the initial SolutionState

    // is set by default to model->getNominalVales().get_x().  However,

    // the application can set it also by integrator->initializeSolutionHistory.

    RCP<Thyra::VectorBase<double>> x0 =

        model->getNominalValues().get_x()->clone_v();

    integrator->initializeSolutionHistory(0.0, x0);


    // Integrate to timeMax

    bool integratorStatus = integrator->advanceTime();

    TEST_ASSERT(integratorStatus)


    // Test if at 'Final Time'

    time             = integrator->getTime();

    double timeFinal = pl->sublist("Default Integrator")

                           .sublist("Time Step Control")

                           .get<double>("Final Time");

    TEST_FLOATING_EQUALITY(time, timeFinal, 1.0e-14);


    // Plot sample solution and exact solution

    if (n == 0) {

      RCP<const SolutionHistory<double>> solutionHistory =

          integrator->getSolutionHistory();

      writeSolution("Tempus_BackwardEuler_SinCos.dat", solutionHistory);


      auto solnHistExact = rcp(new Tempus::SolutionHistory<double>());

      for (int i = 0; i < solutionHistory->getNumStates(); i++) {

        double time_i = (*solutionHistory)[i]->getTime();

        auto state    = Tempus::createSolutionStateX(

               rcp_const_cast<Thyra::VectorBase<double>>(

                model->getExactSolution(time_i).get_x()),

               rcp_const_cast<Thyra::VectorBase<double>>(

                model->getExactSolution(time_i).get_x_dot()));

        state->setTime((*solutionHistory)[i]->getTime());

        solnHistExact->addState(state);

      }

      writeSolution("Tempus_BackwardEuler_SinCos-Ref.dat", solnHistExact);

    }


    // Store off the final solution and step size

    StepSize.push_back(dt);

    auto solution = Thyra::createMember(model->get_x_space());

    Thyra::copy(*(integrator->getX()), solution.ptr());

    solutions.push_back(solution);

    auto solutionDot = Thyra::createMember(model->get_x_space());

    Thyra::copy(*(integrator->getXDot()), solutionDot.ptr());

    solutionsDot.push_back(solutionDot);

    if (n == nTimeStepSizes - 1) {  // Add exact solution last in vector.

      StepSize.push_back(0.0);

      auto solutionExact = Thyra::createMember(model->get_x_space());

      Thyra::copy(*(model->getExactSolution(time).get_x()),

                  solutionExact.ptr());

      solutions.push_back(solutionExact);

      auto solutionDotExact = Thyra::createMember(model->get_x_space());

      Thyra::copy(*(model->getExactSolution(time).get_x_dot()),

                  solutionDotExact.ptr());

      solutionsDot.push_back(solutionDotExact);

    }

  }


  // Check the order and intercept

  double xSlope                        = 0.0;

  double xDotSlope                     = 0.0;

  RCP<Tempus::Stepper<double>> stepper = integrator->getStepper();

  double order                         = stepper->getOrder();

  writeOrderError("Tempus_BackwardEuler_SinCos-Error.dat", stepper, StepSize,

                  solutions, xErrorNorm, xSlope, solutionsDot, xDotErrorNorm,

                  xDotSlope, out);


  TEST_FLOATING_EQUALITY(xSlope, order, 0.01);

  TEST_FLOATING_EQUALITY(xErrorNorm[0], 0.0486418, 1.0e-4);

  TEST_FLOATING_EQUALITY(xDotSlope, order, 0.01);

  TEST_FLOATING_EQUALITY(xDotErrorNorm[0], 0.0486418, 1.0e-4);


  Teuchos::TimeMonitor::summarize();

}


}  // namespace Tempus_Test

Tempus::IntegratorBasic
Basic time integrator.
Definition Tempus_IntegratorBasic_decl.hpp:28

Tempus::SolutionHistory
SolutionHistory is basically a container of SolutionStates. SolutionHistory maintains a collection of...
Definition Tempus_SolutionHistory_decl.hpp:119

Tempus::SolutionState
Solution state for integrators and steppers.
Definition Tempus_SolutionState_decl.hpp:139

Tempus_Test::SinCosModel
Sine-Cosine model problem from Rythmos. This is a canonical Sine-Cosine differential equation.
Definition SinCosModel_decl.hpp:110

Thyra::VectorBase

Tempus_Test
Definition Tempus_BackwardEuler_ASA.cpp:32

Tempus_Test::writeSolution
void writeSolution(const std::string filename, Teuchos::RCP< const Tempus::SolutionHistory< Scalar > > solutionHistory)
Definition Tempus_ConvergenceTestUtils.hpp:302

Tempus_Test::writeOrderError
void writeOrderError(const std::string filename, Teuchos::RCP< Tempus::Stepper< Scalar > > stepper, std::vector< Scalar > &StepSize, std::vector< Teuchos::RCP< Thyra::VectorBase< Scalar > > > &solutions, std::vector< Scalar > &xErrorNorm, Scalar &xSlope, std::vector< Teuchos::RCP< Thyra::VectorBase< Scalar > > > &solutionsDot, std::vector< Scalar > &xDotErrorNorm, Scalar &xDotSlope, std::vector< Teuchos::RCP< Thyra::VectorBase< Scalar > > > &solutionsDotDot, std::vector< Scalar > &xDotDotErrorNorm, Scalar &xDotDotSlope, Teuchos::FancyOStream &out)
Definition Tempus_ConvergenceTestUtils.hpp:188

Tempus_Test::TEUCHOS_UNIT_TEST
TEUCHOS_UNIT_TEST(BackwardEuler, SinCos_ASA)
Definition Tempus_BackwardEuler_ASA.cpp:45

Tempus::createSolutionStateX
Teuchos::RCP< SolutionState< Scalar > > createSolutionStateX(const Teuchos::RCP< Thyra::VectorBase< Scalar > > &x, const Teuchos::RCP< Thyra::VectorBase< Scalar > > &xdot=Teuchos::null, const Teuchos::RCP< Thyra::VectorBase< Scalar > > &xdotdot=Teuchos::null)
Nonmember constructor from non-const solution vectors, x.
Definition Tempus_SolutionState_impl.hpp:349