public abstract class EmbeddedRungeKuttaIntegrator extends AdaptiveStepsizeIntegrator
These methods are embedded explicit Runge-Kutta methods with two sets of coefficients allowing to estimate the error, their Butcher arrays are as follows :
0 |
c2 | a21
c3 | a31 a32
... | ...
cs | as1 as2 ... ass-1
|--------------------------
| b1 b2 ... bs-1 bs
| b'1 b'2 ... b's-1 b's
In fact, we rather use the array defined by ej = bj - b'j to compute directly the error rather than computing two estimates and then comparing them.
Some methods are qualified as fsal (first same as last) methods. This means the last evaluation of the derivatives in one step is the same as the first in the next step. Then, this evaluation can be reused from one step to the next one and the cost of such a method is really s-1 evaluations despite the method still has s stages. This behaviour is true only for successful steps, if the step is rejected after the error estimation phase, no evaluation is saved. For an fsal method, we have cs = 1 and asi = bi for all i.
| Modifier and Type | Method and Description |
|---|---|
double |
getMaxGrowth()
Get the maximal growth factor for stepsize control.
|
double |
getMinReduction()
Get the minimal reduction factor for stepsize control.
|
abstract int |
getOrder()
Get the order of the method.
|
double |
getSafety()
Get the safety factor for stepsize control.
|
void |
integrate(ExpandableStatefulODE equations,
double t)
Integrate a set of differential equations up to the given time.
|
void |
setMaxGrowth(double maxGrowth)
Set the maximal growth factor for stepsize control.
|
void |
setMinReduction(double minReduction)
Set the minimal reduction factor for stepsize control.
|
void |
setSafety(double safety)
Set the safety factor for stepsize control.
|
getCurrentStepStart, getMaxStep, getMinStep, initializeStep, setInitialStepSize, setStepSizeControl, setStepSizeControladdEventHandler, addEventHandler, addStepHandler, clearEventHandlers, clearStepHandlers, computeDerivatives, getCurrentSignedStepsize, getEvaluations, getEventHandlers, getMaxEvaluations, getName, getStepHandlers, integrate, setMaxEvaluationspublic abstract int getOrder()
public double getSafety()
public void setSafety(double safety)
safety - safety factorpublic void integrate(ExpandableStatefulODE equations, double t) throws NumberIsTooSmallException, DimensionMismatchException, MaxCountExceededException, NoBracketingException
This method solves an Initial Value Problem (IVP).
The set of differential equations is composed of a main set, which can be extended by some sets of secondary equations. The set of equations must be already set up with initial time and partial states. At integration completion, the final time and partial states will be available in the same object.
Since this method stores some internal state variables made
available in its public interface during integration (AbstractIntegrator.getCurrentSignedStepsize()), it is not thread-safe.
integrate in class AdaptiveStepsizeIntegratorequations - complete set of differential equations to integratet - target time for the integration
(can be set to a value smaller than t0 for backward integration)NumberIsTooSmallException - if integration step is too smallDimensionMismatchException - if the dimension of the complete state does not
match the complete equations sets dimensionMaxCountExceededException - if the number of functions evaluations is exceededNoBracketingException - if the location of an event cannot be bracketedpublic double getMinReduction()
public void setMinReduction(double minReduction)
minReduction - minimal reduction factorpublic double getMaxGrowth()
public void setMaxGrowth(double maxGrowth)
maxGrowth - maximal growth factorJas4pp 1.5 © Java Analysis Studio for Particle Physics