Chaste  Release::2017.1
AbstractRushLarsenCardiacCell.cpp
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35 
36 #include "AbstractRushLarsenCardiacCell.hpp"
37 
38 #include <cassert>
39 #include <cmath>
40 
41 #include "Exception.hpp"
42 #include "OdeSolution.hpp"
43 #include "TimeStepper.hpp"
44 
46  unsigned voltageIndex,
47  boost::shared_ptr<AbstractStimulusFunction> pIntracellularStimulus)
49  numberOfStateVariables,
50  voltageIndex,
51  pIntracellularStimulus)
52 {}
53 
55 {}
56 
57 OdeSolution AbstractRushLarsenCardiacCell::Compute(double tStart, double tEnd, double tSamp)
58 {
59  // In this method, we iterate over timesteps, doing the following for each:
60  // - update V using a forward Euler step
61  // - do as in ComputeExceptVoltage(t) to update the remaining state variables
62  // using Rush Larsen method or forward Euler as appropriate
63 
64  // Check length of time interval
65  if (tSamp < mDt)
66  {
67  tSamp = mDt;
68  }
69  const unsigned n_steps = (unsigned) floor((tEnd - tStart)/tSamp + 0.5);
70  assert(fabs(tStart+n_steps*tSamp - tEnd) < 1e-12);
71  const unsigned n_small_steps = (unsigned) floor(tSamp/mDt+0.5);
72  assert(fabs(mDt*n_small_steps - tSamp) < 1e-12);
73 
74  // Initialise solution store
75  OdeSolution solutions;
76  solutions.SetNumberOfTimeSteps(n_steps);
77  solutions.rGetSolutions().push_back(rGetStateVariables());
78  solutions.rGetTimes().push_back(tStart);
79  solutions.SetOdeSystemInformation(this->mpSystemInfo);
80 
81  std::vector<double> dy(mNumberOfStateVariables, 0);
82  std::vector<double> alpha(mNumberOfStateVariables, 0);
83  std::vector<double> beta(mNumberOfStateVariables, 0);
84 
85  // Loop over time
86  for (unsigned i=0; i<n_steps; i++)
87  {
88  double curr_time = tStart;
89  for (unsigned j=0; j<n_small_steps; j++)
90  {
91  curr_time = tStart + i*tSamp + j*mDt;
92  EvaluateEquations(curr_time, dy, alpha, beta);
94  ComputeOneStepExceptVoltage(dy, alpha, beta);
96  }
97 
98  // Update solutions
99  solutions.rGetSolutions().push_back(rGetStateVariables());
100  solutions.rGetTimes().push_back(curr_time+mDt);
101  }
102 
103  return solutions;
104 }
105 
107 {
109  TimeStepper stepper(tStart, tEnd, mDt);
110 
111  std::vector<double> dy(mNumberOfStateVariables, 0);
112  std::vector<double> alpha(mNumberOfStateVariables, 0);
113  std::vector<double> beta(mNumberOfStateVariables, 0);
114 
115  while (!stepper.IsTimeAtEnd())
116  {
117  EvaluateEquations(stepper.GetTime(), dy, alpha, beta);
118  ComputeOneStepExceptVoltage(dy, alpha, beta);
119 
120 #ifndef NDEBUG
121  // Check gating variables are still in range
123 #endif // NDEBUG
124 
125  stepper.AdvanceOneTimeStep();
126  }
128 }
129 
131 {
132  TimeStepper stepper(tStart, tEnd, mDt);
133 
134  std::vector<double> dy(mNumberOfStateVariables, 0);
135  std::vector<double> alpha(mNumberOfStateVariables, 0);
136  std::vector<double> beta(mNumberOfStateVariables, 0);
137 
138  while (!stepper.IsTimeAtEnd())
139  {
140  EvaluateEquations(stepper.GetTime(), dy, alpha, beta);
142  ComputeOneStepExceptVoltage(dy, alpha, beta);
144 
145  stepper.AdvanceOneTimeStep();
146  }
147 }
148 
150 {
151  unsigned v_index = GetVoltageIndex();
152  rGetStateVariables()[v_index] += mDt*rDY[v_index];
153 }
void UpdateTransmembranePotential(const std::vector< double > &rDY)
std::vector< std::vector< double > > & rGetSolutions()
double GetTime() const
virtual void ComputeOneStepExceptVoltage(const std::vector< double > &rDY, const std::vector< double > &rAlphaOrTau, const std::vector< double > &rBetaOrInf)=0
void AdvanceOneTimeStep()
bool IsTimeAtEnd() const
OdeSolution Compute(double tStart, double tEnd, double tSamp=0.0)
void SetOdeSystemInformation(boost::shared_ptr< const AbstractOdeSystemInformation > pOdeSystemInfo)
Definition: OdeSolution.cpp:66
void ComputeExceptVoltage(double tStart, double tEnd)
void SolveAndUpdateState(double tStart, double tEnd)
std::vector< double > & rGetTimes()
AbstractRushLarsenCardiacCell(unsigned numberOfStateVariables, unsigned voltageIndex, boost::shared_ptr< AbstractStimulusFunction > pIntracellularStimulus)
virtual void EvaluateEquations(double time, std::vector< double > &rDY, std::vector< double > &rAlphaOrTau, std::vector< double > &rBetaOrInf)=0
boost::shared_ptr< AbstractOdeSystemInformation > mpSystemInfo
void SetNumberOfTimeSteps(unsigned numTimeSteps)
Definition: OdeSolution.cpp:58