See: Description
Interface | Description |
---|---|
FieldODEFixedStepHandler<T extends RealFieldElement<T>> |
This interface represents a handler that should be called after
each successful fixed step.
|
FieldODEStateInterpolator<T extends RealFieldElement<T>> |
This interface represents an interpolator over the last step
during an ODE integration.
|
FieldODEStepHandler<T extends RealFieldElement<T>> |
This interface represents a handler that should be called after
each successful step.
|
ODEFixedStepHandler |
This interface represents a handler that should be called after
each successful fixed step.
|
ODEStateInterpolator |
This interface represents an interpolator over the last step
during an ODE integration.
|
ODEStepHandler |
This interface represents a handler that should be called after
each successful step.
|
Class | Description |
---|---|
AbstractFieldODEStateInterpolator<T extends RealFieldElement<T>> |
This abstract class represents an interpolator over the last step
during an ODE integration.
|
AbstractODEStateInterpolator |
This abstract class represents an interpolator over the last step
during an ODE integration.
|
FieldStepNormalizer<T extends RealFieldElement<T>> |
This class wraps an object implementing
FieldODEFixedStepHandler
into a FieldODEStepHandler . |
StepNormalizer |
This class wraps an object implementing
ODEFixedStepHandler
into a ODEStepHandler . |
Enum | Description |
---|---|
StepNormalizerBounds |
Step normalizer bounds settings. |
StepNormalizerMode |
Step normalizer modes. |
This package provides classes to handle sampling steps during Ordinary Differential Equations integration.
In addition to computing the evolution of the state vector at some grid points, all
ODE integrators also build up interpolation models of this evolution inside the
last computed step. If users are interested in these interpolators, they can register a
ODEStepHandler
instance using the
addStepHandler
method which is supported by all integrators. The integrator will call this instance
at the end of each accepted step and provide it the interpolator. The user can do
whatever he wants with this interpolator, which computes both the state and its
time-derivative. A typical use of step handler is to provide some output to monitor
the integration process.
In a sense, this is a kind of Inversion Of Control: rather than having the master application driving the slave integrator by providing the target end value for the free variable, we get a master integrator scheduling the free variable evolution and calling the slave application callbacks that were registered at configuration time.
Since some integrators may use variable step size, the generic ODEStepHandler
interface can be called
either at regular or irregular rate. This interface allows to navigate to any location
within the last computed step, thanks to the provided ODEStateInterpolator
object.
If regular output is desired (for example in order to write an ephemeris file), then
the simpler ODEFixedStepHandler
interface can be used. Objects implementing this interface should be wrapped within a
StepNormalizer
instance
in order to be registered to the integrator.
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