public class OneSatEventDetectorWrapper extends MultiAbstractDetector
This class allows to convert an EventDetector
into a MultiEventDetector
. The EventDetector
is
associated with a single spacecraft identified by its ID.
MultiPropagator.addEventDetector(EventDetector, String)
DEFAULT_MAX_ITERATION_COUNT, DEFAULT_MAXCHECK, DEFAULT_THRESHOLD
DECREASING, INCREASING, INCREASING_DECREASING
Constructor and Description |
---|
OneSatEventDetectorWrapper(EventDetector detector,
String satId)
Simple constructor.
|
Modifier and Type | Method and Description |
---|---|
EventDetector.Action |
eventOccurred(Map<String,SpacecraftState> s,
boolean increasing,
boolean forward)
Handle an event and choose what to do next.
|
double |
g(Map<String,SpacecraftState> s)
Compute the value of the switching function.
|
double |
g(SpacecraftState s)
Compute the value of the switching function.
|
String |
getID()
Returns the ID of the spacecraft associated with the detector.
|
void |
init(Map<String,SpacecraftState> s0,
AbsoluteDate t)
Initialize event handler at the start of a propagation.
|
Map<String,SpacecraftState> |
resetStates(Map<String,SpacecraftState> oldStates)
Reset the states (including additional states) prior to continue propagation.
|
boolean |
shouldBeRemoved()
This method is called after the step handler has returned and before the next step is started, but only when
MultiEventDetector.eventOccurred(java.util.Map<java.lang.String, fr.cnes.sirius.patrius.propagation.SpacecraftState>, boolean, boolean) has been called. |
getMaxCheckInterval, getMaxIterationCount, getSlopeSelection, getThreshold
public OneSatEventDetectorWrapper(EventDetector detector, String satId)
detector
- the event detectorsatId
- the ID of the spacecraft associated with the detectorpublic void init(Map<String,SpacecraftState> s0, AbsoluteDate t)
This method is called once at the start of the propagation. It may be used by the event handler to initialize some internal data if needed.
init
in interface MultiEventDetector
init
in class MultiAbstractDetector
s0
- map of initial statest
- target time for the integrationpublic double g(SpacecraftState s) throws PatriusException
s
- the current states information: date, kinematics, attitudes for forces
and events computation, and additional states for each statesPatriusException
- if some specific error occurspublic double g(Map<String,SpacecraftState> s) throws PatriusException
This function must be continuous (at least in its roots neighborhood), as the integrator will need to find its roots to locate the events.
g
in interface MultiEventDetector
g
in class MultiAbstractDetector
s
- the current states information: date, kinematics, attitudes for forces
and events computation, and additional states for each statesPatriusException
- if some specific error occurspublic EventDetector.Action eventOccurred(Map<String,SpacecraftState> s, boolean increasing, boolean forward) throws PatriusException
The scheduling between this method and the MultiOrekitStepHandler method handleStep is to call this method first
and handleStep
afterwards. This scheduling allows the propagator to pass true
as the
isLast
parameter to the step handler to make it aware the step will be the last one if this method
returns EventDetector.Action.STOP
. As the interpolator may be
used to navigate back throughout the last step MultiOrekitStepNormalizer does for example), user code called by
this method and user code called by step handlers may experience apparently out of order values of the
independent time variable. As an example, if the same user object implements both this MultiEventDetector
interface and the MultiOrekitFixedStepHandler interface, a forward integration may
call its eventOccurred
method with a state at 2000-01-01T00:00:10 first and call its
handleStep
method with a state at 2000-01-01T00:00:09 afterwards. Such out of order calls are
limited to the size of the integration step for MultiOrekitStepHandler and to the size of the fixed step for
MultiOrekitFixedStepHandler.
eventOccurred
in interface MultiEventDetector
eventOccurred
in class MultiAbstractDetector
s
- the current states information: date, kinematics, attitude for forces
and events computation, and additional states for each statesincreasing
- if true, the value of the switching function increases
when times increases around event (note that increase is measured with respect
to physical time, not with respect to propagation which may go backward in time)forward
- if true, the integration variable (time) increases during integration.EventDetector.Action.STOP
,
EventDetector.Action.RESET_STATE
,
EventDetector.Action.RESET_DERIVATIVES
,
EventDetector.Action.CONTINUE
PatriusException
- if some specific error occurspublic boolean shouldBeRemoved()
This method is called after the step handler has returned and before the next step is started, but only when
MultiEventDetector.eventOccurred(java.util.Map<java.lang.String, fr.cnes.sirius.patrius.propagation.SpacecraftState>, boolean, boolean)
has been called.
shouldBeRemoved
in interface MultiEventDetector
shouldBeRemoved
in class MultiAbstractDetector
public Map<String,SpacecraftState> resetStates(Map<String,SpacecraftState> oldStates) throws PatriusException
This method is called after the step handler has returned and before the next step is started, but only when
MultiEventDetector.eventOccurred(java.util.Map<java.lang.String, fr.cnes.sirius.patrius.propagation.SpacecraftState>, boolean, boolean)
has itself returned the
EventDetector.Action.RESET_STATE
indicator. It allows the user
to reset the state for the next step, without perturbing the step handler of the finishing step. If the
MultiEventDetector.eventOccurred(java.util.Map<java.lang.String, fr.cnes.sirius.patrius.propagation.SpacecraftState>, boolean, boolean)
never returns the
EventDetector.Action.RESET_STATE
indicator, this function will
never be called, and it is safe to simply return null.
resetStates
in interface MultiEventDetector
resetStates
in class MultiAbstractDetector
oldStates
- old statesPatriusException
- if the states cannot be resetedpublic String getID()
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