示例#1
0
文件: HHT.cpp 项目: fmckenna/OpenSees
int HHT::newStep(double _deltaT)
{
    deltaT = _deltaT;
    if (beta == 0 || gamma == 0 )  {
        opserr << "HHT::newStep() - error in variable\n";
        opserr << "gamma = " << gamma << " beta = " << beta << endln;
        return -1;
    }
    
    if (deltaT <= 0.0)  {
        opserr << "HHT::newStep() - error in variable\n";
        opserr << "dT = " << deltaT << endln;
        return -2;
    }
    
    // get a pointer to the AnalysisModel
    AnalysisModel *theModel = this->getAnalysisModel();
    
    // set the constants
    c1 = 1.0;
    c2 = gamma/(beta*deltaT);
    c3 = 1.0/(beta*deltaT*deltaT);
    
    if (U == 0)  {
        opserr << "HHT::newStep() - domainChange() failed or hasn't been called\n";
        return -3;
    }
    
    // set response at t to be that at t+deltaT of previous step
    (*Ut) = *U;
    (*Utdot) = *Udot;
    (*Utdotdot) = *Udotdot;
    
    // determine new velocities and accelerations at t+deltaT
    double a1 = (1.0 - gamma/beta);
    double a2 = deltaT*(1.0 - 0.5*gamma/beta);
    Udot->addVector(a1, *Utdotdot, a2);
    
    double a3 = -1.0/(beta*deltaT);
    double a4 = 1.0 - 0.5/beta;
    Udotdot->addVector(a4, *Utdot, a3);
    
    // determine the velocities at t+alpha*deltaT
    (*Ualphadot) = *Utdot;
    Ualphadot->addVector((1.0-alpha), *Udot, alpha);
    
    // set the trial response quantities
    theModel->setVel(*Ualphadot);
    theModel->setAccel(*Udotdot);
    
    // increment the time to t+alpha*deltaT and apply the load
    double time = theModel->getCurrentDomainTime();
    time += alpha*deltaT;
    if (theModel->updateDomain(time, deltaT) < 0)  {
        opserr << "HHT::newStep() - failed to update the domain\n";
        return -4;
    }
    
    return 0;
}
示例#2
0
int NewmarkHSFixedNumIter::newStep(double deltaT)
{
    if (beta == 0 || gamma == 0)  {
        opserr << "NewmarkHSFixedNumIter::newStep() - error in variable\n";
        opserr << "gamma = " << gamma << " beta = " << beta << endln;
        return -1;
    }

    if (deltaT <= 0.0)  {
        opserr << "NewmarkHSFixedNumIter::newStep() - error in variable\n";
        opserr << "dT = " << deltaT << endln;
        return -2;
    }

    // get a pointer to the AnalysisModel
    AnalysisModel *theModel = this->getAnalysisModel();

    // set the constants
    c1 = 1.0;
    c2 = gamma/(beta*deltaT);
    c3 = 1.0/(beta*deltaT*deltaT);

    if (U == 0)  {
        opserr << "NewmarkHSFixedNumIter::newStep() - domainChange() failed or hasn't been called\n";
        return -3;
    }

    // set response at t to be that at t+deltaT of previous step
    (*Utm2) = *Utm1;
    (*Utm1) = *Ut;
    (*Ut) = *U;
    (*Utdot) = *Udot;
    (*Utdotdot) = *Udotdot;

    // determine new velocities and accelerations at t+deltaT
    double a1 = (1.0 - gamma/beta);
    double a2 = deltaT*(1.0 - 0.5*gamma/beta);
    Udot->addVector(a1, *Utdotdot, a2);

    double a3 = -1.0/(beta*deltaT);
    double a4 = 1.0 - 0.5/beta;
    Udotdot->addVector(a4, *Utdot, a3);

    // set the trial response quantities
    theModel->setVel(*Udot);
    theModel->setAccel(*Udotdot);

    // increment the time to t+deltaT and apply the load
    double time = theModel->getCurrentDomainTime();
    time += deltaT;
    theModel->applyLoadDomain(time);

    //correctForce = true;

    return 0;
}
示例#3
0
文件: Collocation.cpp 项目: lcpt/xc
int XC::Collocation::newStep(double _deltaT)
{
    deltaT = _deltaT;
    if (theta <= 0.0 )  {
        std::cerr << "XC::Collocation::newStep() - error in variable\n";
        std::cerr << "theta: " << theta << " <= 0.0\n";
        return -1;
    }
    
    if (deltaT <= 0.0)  {
        std::cerr << "XC::Collocation::newStep() - error in variable\n";
        std::cerr << "dT = " << deltaT << std::endl;
        return -2;
    }
    
    // get a pointer to the XC::AnalysisModel
    AnalysisModel *theModel = this->getAnalysisModelPtr();

    // set the constants
    c1 = 1.0;
    c2 = gamma/(beta*theta*deltaT);
    c3 = 1.0/(beta*theta*theta*deltaT*deltaT);
    
    if (U.get().Size() == 0)  {
        std::cerr << "XC::Collocation::newStep() - domainChange() failed or hasn't been called\n"; 
        return -3;	
    }
    
    // set response at t to be that at t+deltaT of previous step
    Ut= U;

    // increment the time to t+theta*deltaT and apply the load
    double time = getCurrentModelTime();
    time += theta*deltaT;
//    theModel->applyLoadDomain(time);
    if(updateModel(time, deltaT) < 0)
      {
        std::cerr << "XC::Collocation::newStep() - failed to update the domain\n";
        return -4;
      }
    
    // determine new_ velocities and accelerations at t+theta*deltaT
    double a1 = (1.0 - gamma/beta); 
    double a2 = theta*deltaT*(1.0 - 0.5*gamma/beta);
    U.getDot().addVector(a1, Ut.getDotDot(), a2);
      
    double a3 = -1.0/(beta*theta*deltaT);
    double a4 = 1.0 - 0.5/beta;
    U.getDotDot().addVector(a4, Ut.getDot(), a3);
    
    // set the trial response quantities for the nodes
    theModel->setVel(U.getDot());
    theModel->setAccel(U.getDotDot());
    
    return 0;
}
int CollocationHSIncrReduct::newStep(double _deltaT)
{
    if (theta <= 0.0 )  {
        opserr << "CollocationHSIncrReduct::newStep() - error in variable\n";
        opserr << "theta: " << theta << " <= 0.0\n";
        return -1;
    }
    
    deltaT = _deltaT;
    if (deltaT <= 0.0)  {
        opserr << "CollocationHSIncrReduct::newStep() - error in variable\n";
        opserr << "dT = " << deltaT << endln;
        return -2;
    }
    
    // get a pointer to the AnalysisModel
    AnalysisModel *theModel = this->getAnalysisModel();
    
    // set the constants
    c1 = 1.0;
    c2 = gamma/(beta*theta*deltaT);
    c3 = 1.0/(beta*theta*theta*deltaT*deltaT);
    
    if (U == 0)  {
        opserr << "CollocationHSIncrReduct::newStep() - domainChange() failed or hasn't been called\n"; 
        return -3;
    }
    
    // set response at t to be that at t+deltaT of previous step
    (*Ut) = *U;
    (*Utdot) = *Udot;
    (*Utdotdot) = *Udotdot;
    
    // determine new velocities and accelerations at t+theta*deltaT
    double a1 = (1.0 - gamma/beta);
    double a2 = theta*deltaT*(1.0 - 0.5*gamma/beta);
    Udot->addVector(a1, *Utdotdot, a2);
    
    double a3 = -1.0/(beta*theta*deltaT);
    double a4 = 1.0 - 0.5/beta;
    Udotdot->addVector(a4, *Utdot, a3);
    
    // set the trial response quantities
    theModel->setVel(*Udot);
    theModel->setAccel(*Udotdot);
    
    // increment the time to t+theta*deltaT and apply the load
    double time = theModel->getCurrentDomainTime();
    time += theta*deltaT;
    theModel->applyLoadDomain(time);
    
    return 0;
}
示例#5
0
int AlphaOS::update(const Vector &deltaU)
{
    updateCount++;
    if (updateCount > 1)  {
        opserr << "WARNING AlphaOS::update() - called more than once -";
        opserr << " AlphaOS integration scheme requires a LINEAR solution algorithm\n";
        return -1;
    }
    
    AnalysisModel *theModel = this->getAnalysisModel();
    if (theModel == 0)  {
        opserr << "WARNING AlphaOS::update() - no AnalysisModel set\n";
        return -2;
    }
    
    // check domainChanged() has been called, i.e. Ut will not be zero
    if (Ut == 0)  {
        opserr << "WARNING AlphaOS::update() - domainChange() failed or not called\n";
        return -3;
    }
    
    // check deltaU is of correct size
    if (deltaU.Size() != U->Size())  {
        opserr << "WARNING AlphaOS::update() - Vectors of incompatible size ";
        opserr << " expecting " << U->Size() << " obtained " << deltaU.Size() << "\n";
        return -4;
    }
    
    // save the predictor displacements
    (*Upt) = *U;
    
    //  determine the response at t+deltaT
    U->addVector(1.0, deltaU, c1);
    
    Udot->addVector(1.0, deltaU, c2);
    
    Udotdot->addVector(0.0, deltaU, c3);
    
    // update the response at the DOFs
    theModel->setVel(*Udot);
    theModel->setAccel(*Udotdot);
    if (theModel->updateDomain() < 0)  {
        opserr << "AlphaOS::update() - failed to update the domain\n";
        return -5;
    }
    // do not update displacements in elements only at nodes
    theModel->setDisp(*U);
    
    return 0;
}
int
CentralDifferenceAlternative::update(const Vector &X)
{
  updateCount++;
  if (updateCount > 1) {
    opserr << "ERROR CentralDifferenceAlternative::update() - called more than once -";
    opserr << " Central Difference integraion schemes require a LINEAR solution algorithm\n";
    return -1;
  }
  
  AnalysisModel *theModel = this->getAnalysisModel();

  if (theModel == 0) {
    opserr << "ERROR CentralDifferenceAlternative::update() - no AnalysisModel set\n";
    return -2;
  }	
  
  // check domainChanged() has been called, i.e. Ut will not be zero
  if (Ut == 0) {
    opserr << "WARNING CentralDifferenceAlternative::update() - domainChange() failed or not called\n";
    return -2;
  }	

  // check deltaU is of correct size
  if (X.Size() != Ut->Size()) {
    opserr << "WARNING CentralDifferenceAlternative::update() - Vectors of incompatible size ";
    opserr << " expecting " << Ut->Size() << " obtained " << X.Size() << endln;
    return -3;
  }


  //  determine the displacement at t+delta t 
  Utp1->addVector(0.0, X, deltaT * deltaT);
  (*Utp1) += *Ut;
  Utp1->addVector(1.0, *Udot, deltaT);

  //  determine the vel at t+ 0.5 * delta t 
  (*Udot) =  *Utp1;
  (*Udot) -= *Ut;
  (*Udot) *= (1.0/deltaT);

  // update the disp & responses at the DOFs
  theModel->setDisp(*Utp1);
  theModel->setVel(*Udot);
  theModel->updateDomain();

  return 0;
  }    
示例#7
0
int CentralDifference::newStep(double _deltaT)
{
    updateCount = 0;
    
    deltaT = _deltaT;
    if (deltaT <= 0.0)  {
        opserr << "CentralDifference::newStep() - error in variable\n";
        opserr << "dT = " << deltaT << endln;
        return -2;	
    }
    
    // get a pointer to the AnalysisModel
    AnalysisModel *theModel = this->getAnalysisModel();
    
    // set the constants
    c2 = 0.5/deltaT;
    c3 = 1.0/(deltaT*deltaT);
    
    if (Ut == 0)  {
        opserr << "CentralDifference::newStep() - domainChange() failed or hasn't been called\n";
        return -3;	
    }
        
    // determine the garbage velocities and accelerations at t
    Utdot->addVector(0.0, *Utm1, -c2);
    
    Utdotdot->addVector(0.0, *Ut, -2.0*c3);
    Utdotdot->addVector(1.0, *Utm1, c3);
    
    // set the garbage response quantities for the nodes
    theModel->setVel(*Utdot);
    theModel->setAccel(*Utdotdot);

    // increment the time to t and apply the load
    double time = theModel->getCurrentDomainTime();
    if (theModel->updateDomain(time, deltaT) < 0)  {
        opserr << "CentralDifference::newStep() - failed to update the domain\n";
        return -4;
    }
    
    // set response at t to be that at t+deltaT of previous step
    (*Utdot) = *Udot;
    (*Utdotdot) = *Udotdot;
    
    return 0;
}
示例#8
0
int NewmarkExplicit::update(const Vector &aiPlusOne)
{
    updateCount++;
    if (updateCount > 1)  {
        opserr << "WARNING NewmarkExplicit::update() - called more than once -";
        opserr << " NewmarkExplicit integration scheme requires a LINEAR solution algorithm\n";
        return -1;
    }
    
    AnalysisModel *theModel = this->getAnalysisModel();
    if (theModel == 0)  {
        opserr << "WARNING NewmarkExplicit::update() - no AnalysisModel set\n";
        return -1;
    }	
    
    // check domainChanged() has been called, i.e. Ut will not be zero
    if (Ut == 0)  {
        opserr << "WARNING NewmarkExplicit::update() - domainChange() failed or not called\n";
        return -2;
    }	
    
    // check aiPlusOne is of correct size
    if (aiPlusOne.Size() != U->Size())  {
        opserr << "WARNING NewmarkExplicit::update() - Vectors of incompatible size ";
        opserr << " expecting " << U->Size() << " obtained " << aiPlusOne.Size() << endln;
        return -3;
    }
    
    //  determine the response at t+deltaT
    Udot->addVector(1.0, aiPlusOne, c2);

    (*Udotdot) = aiPlusOne;
    
    // update the response at the DOFs
    theModel->setVel(*Udot);
    theModel->setAccel(*Udotdot);
    if (updDomFlag == true)  {
        if (theModel->updateDomain() < 0)  {
            opserr << "NewmarkExplicit::update() - failed to update the domain\n";
            return -4;
        }
    }
    
    return 0;
}    
示例#9
0
文件: TRBDF2.cpp 项目: lge88/OpenSees
int TRBDF2::newStep(double deltaT)
{
  // check the vectors have been created
  if (U == 0)  {
    opserr << "TRBDF2::newStep() - domainChange() failed or hasn't been called\n";
    return -3;	
  }

  // mark step as Trapezoidal (=0) or Backward Euler (=1)

  if (deltaT != dt || step == 1) {
    step = 0;
  } else
    step = 1;

  // get a pointer to the AnalysisModel
  AnalysisModel *theModel = this->getAnalysisModel();

  // set response at t to be that at t+deltaT of previous step
  dt = deltaT;

  (*Utm1) = *Ut;
  (*Utm1dot) = *Utdot;

  (*Ut) = *U;        
  (*Utdot) = *Udot;  
  (*Utdotdot) = *Udotdot;

  // set the constants
  if (step == 0)  { // trapezoidal
    c1 = 1.0;
    c2 = 2.0/deltaT;
    c3 = 4.0/(deltaT*deltaT);

    (*Udot) *= -1.0;

    double a3 = -4.0/deltaT;
    double a4 = -1;
    Udotdot->addVector(a4, *Utdot, a3);
    
    // set the trial response quantities
    theModel->setVel(*Udot);
    theModel->setAccel(*Udotdot);    

  } else  {  // backward euler
    c1 = 1.0;
    c2 = 1.5/deltaT;
    c3 = 2.25/(deltaT*deltaT);

    (*Udot) = *Utm1;
    Udot->addVector(0.5/deltaT, *Ut, -1/(2.0*deltaT));

    (*Udotdot) = *Utm1dot;
    Udotdot->addVector(0.5/deltaT, *Utdot, -4.0/(2.0*deltaT));    
    Udotdot->addVector(1.0, *Udot, 3.0/(2.0*deltaT));    

    // set the trial response quantities
    theModel->setVel(*Udot);
    theModel->setAccel(*Udotdot);    
  }

  // increment the time to t+deltaT and apply the load
  double time = theModel->getCurrentDomainTime();
  time += deltaT;
  if (theModel->updateDomain(time, deltaT) < 0)  {
    opserr << "TRBDF2::newStep() - failed to update the domain\n";
    return -4;
  }
  
  return 0;
}
示例#10
0
int HHTGeneralized_TP::newStep(double _deltaT)
{
    if (beta == 0 || gamma == 0 )  {
        opserr << "HHTGeneralized_TP::newStep() - error in variable\n";
        opserr << "gamma = " << gamma << " beta = " << beta << endln;
        return -1;
    }
    
    deltaT = _deltaT;
    if (deltaT <= 0.0)  {
        opserr << "HHTGeneralized_TP::newStep() - error in variable\n";
        opserr << "dT = " << deltaT << endln;
        return -2;
    }
    
    // get a pointer to the LinearSOE and the AnalysisModel
    LinearSOE *theLinSOE = this->getLinearSOE();
    AnalysisModel *theModel = this->getAnalysisModel();
    if (theLinSOE == 0 || theModel == 0)  {
        opserr << "WARNING HHT_TP::newStep() - ";
        opserr << "no LinearSOE or AnalysisModel has been set\n";
        return -3;
    }
    
    // set the constants
    c1 = 1.0;
    c2 = gamma/(beta*deltaT);
    c3 = 1.0/(beta*deltaT*deltaT);
       
    if (U == 0)  {
        opserr << "HHTGeneralized_TP::newStep() - domainChange() failed or hasn't been called\n";
        return -4;
    }
    
    // set response at t to be that at t+deltaT of previous step
    (*Ut) = *U;
    (*Utdot) = *Udot;
    (*Utdotdot) = *Udotdot;
    
    // get unbalance at t and store it
    alphaM = (1.0 - alphaI);
    alphaD = alphaR = alphaP = (1.0 - alphaF);
    this->TransientIntegrator::formUnbalance();
    (*Put) = theLinSOE->getB();
    
    // determine new velocities and accelerations at t+deltaT
    double a1 = (1.0 - gamma/beta);
    double a2 = deltaT*(1.0 - 0.5*gamma/beta);
    Udot->addVector(a1, *Utdotdot, a2);
    
    double a3 = -1.0/(beta*deltaT);
    double a4 = 1.0 - 0.5/beta;  
    Udotdot->addVector(a4, *Utdot, a3);
    
    // set the trial response quantities
    theModel->setVel(*Udot);
    theModel->setAccel(*Udotdot);
    
    // increment the time to t+deltaT and apply the load
    double time = theModel->getCurrentDomainTime();
    time += deltaT;
    if (theModel->updateDomain(time, deltaT) < 0)  {
        opserr << "HHTGeneralized_TP::newStep() - failed to update the domain\n";
        return -5;
    }
    
    // modify constants for subsequent iterations
    alphaM = alphaI;
    alphaD = alphaR = alphaP = alphaF;
    
    return 0;
}