AttitudesSequence.java
/* Copyright 2002-2024 CS GROUP
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* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* CS licenses this file to You under the Apache License, Version 2.0
* (the "License"); you may not use this file except in compliance with
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*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
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package org.orekit.attitudes;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.List;
import org.hipparchus.CalculusFieldElement;
import org.hipparchus.Field;
import org.hipparchus.geometry.euclidean.threed.FieldRotation;
import org.hipparchus.geometry.euclidean.threed.Rotation;
import org.hipparchus.ode.events.Action;
import org.orekit.errors.OrekitException;
import org.orekit.errors.OrekitMessages;
import org.orekit.frames.Frame;
import org.orekit.orbits.Orbit;
import org.orekit.propagation.FieldPropagator;
import org.orekit.propagation.FieldSpacecraftState;
import org.orekit.propagation.Propagator;
import org.orekit.propagation.SpacecraftState;
import org.orekit.propagation.events.AdaptableInterval;
import org.orekit.propagation.events.EventDetector;
import org.orekit.propagation.events.FieldAdaptableInterval;
import org.orekit.propagation.events.FieldEventDetector;
import org.orekit.propagation.events.handlers.EventHandler;
import org.orekit.propagation.events.handlers.FieldEventHandler;
import org.orekit.time.AbsoluteDate;
import org.orekit.time.FieldAbsoluteDate;
import org.orekit.time.FieldTimeInterpolator;
import org.orekit.time.TimeInterpolator;
import org.orekit.utils.AngularDerivativesFilter;
import org.orekit.utils.DoubleArrayDictionary;
import org.orekit.utils.FieldPVCoordinatesProvider;
import org.orekit.utils.PVCoordinatesProvider;
import org.orekit.utils.TimeSpanMap;
import org.orekit.utils.TimeStampedAngularCoordinates;
import org.orekit.utils.TimeStampedAngularCoordinatesHermiteInterpolator;
import org.orekit.utils.TimeStampedFieldAngularCoordinates;
import org.orekit.utils.TimeStampedFieldAngularCoordinatesHermiteInterpolator;
/** This classes manages a sequence of different attitude providers that are activated
* in turn according to switching events.
* <p>Only one attitude provider in the sequence is in an active state. When one of
* the switch event associated with the active provider occurs, the active provider becomes
* the one specified with the event. A simple example is a provider for the sun lighted part
* of the orbit and another provider for the eclipse time. When the sun lighted provider is active,
* the eclipse entry event is checked and when it occurs the eclipse provider is activated.
* When the eclipse provider is active, the eclipse exit event is checked and when it occurs
* the sun lighted provider is activated again. This sequence is a simple loop.</p>
* <p>An active attitude provider may have several switch events and next provider settings, leading
* to different activation patterns depending on which events are triggered first. An example
* of this feature is handling switches to safe mode if some contingency condition is met, in
* addition to the nominal switches that correspond to proper operations. Another example
* is handling of maneuver mode.
* <p>
* Note that this attitude provider is stateful, it keeps in memory the sequence of active
* underlying providers with their switch dates and the transitions from one provider to
* the other. This implies that this provider should <em>not</em> be shared among different
* propagators at the same time, each propagator should use its own instance of this provider.
* <p>
* The sequence kept in memory is reset when {@link #resetActiveProvider(AttitudeProvider)}
* is called, and only the specify provider is kept. The sequence is also partially
* reset each time a propagation starts. If a new propagation is started after a first
* propagation has been run, all the already computed switches that occur after propagation
* start for forward propagation or before propagation start for backward propagation will
* be erased. New switches will be computed and applied properly according to the new
* propagation settings. The already computed switches that are not in covered are kept
* in memory. This implies that if a propagation is interrupted and restarted in the
* same direction, then attitude switches will remain in place, ensuring that even if the
* interruption occurred in the middle of an attitude transition the second propagation will
* properly complete the transition that was started by the first propagator.
* </p>
* @author Luc Maisonobe
* @since 5.1
*/
public class AttitudesSequence implements AttitudeProvider {
/** Providers that have been activated. */
private transient TimeSpanMap<AttitudeProvider> activated;
/** Switching events list. */
private final List<Switch> switches;
/** Constructor for an initially empty sequence.
*/
public AttitudesSequence() {
activated = null;
switches = new ArrayList<>();
}
/** Reset the active provider.
* <p>
* Calling this method clears all already seen switch history,
* so it should <em>not</em> be used during the propagation itself,
* it is intended to be used only at start
* </p>
* @param provider provider to activate
*/
public void resetActiveProvider(final AttitudeProvider provider) {
activated = new TimeSpanMap<>(provider);
}
/** Register all wrapped switch events to the propagator.
* <p>
* This method must be called once before propagation, after the
* switching conditions have been set up by calls to {@link
* #addSwitchingCondition(AttitudeProvider, AttitudeProvider, EventDetector,
* boolean, boolean, double, AngularDerivativesFilter, SwitchHandler)
* addSwitchingCondition}.
* </p>
* @param propagator propagator that will handle the events
*/
public void registerSwitchEvents(final Propagator propagator) {
for (final Switch s : switches) {
propagator.addEventDetector(s);
}
}
/** Register all wrapped switch events to the propagator.
* <p>
* This method must be called once before propagation, after the
* switching conditions have been set up by calls to {@link
* #addSwitchingCondition(AttitudeProvider, AttitudeProvider, EventDetector,
* boolean, boolean, double, AngularDerivativesFilter, SwitchHandler)
* addSwitchingCondition}.
* </p>
* @param field field to which the elements belong
* @param propagator propagator that will handle the events
* @param <T> type of the field elements
*/
public <T extends CalculusFieldElement<T>> void registerSwitchEvents(final Field<T> field, final FieldPropagator<T> propagator) {
for (final Switch sw : switches) {
propagator.addEventDetector(new FieldEventDetector<T>() {
/** {@inheritDoc} */
@Override
public void init(final FieldSpacecraftState<T> s0,
final FieldAbsoluteDate<T> t) {
sw.init(s0.toSpacecraftState(), t.toAbsoluteDate());
}
/** {@inheritDoc} */
@Override
public T g(final FieldSpacecraftState<T> s) {
return field.getZero().add(sw.g(s.toSpacecraftState()));
}
/** {@inheritDoc} */
@Override
public T getThreshold() {
return field.getZero().add(sw.getThreshold());
}
/** {@inheritDoc} */
@Override
public FieldAdaptableInterval<T> getMaxCheckInterval() {
return s -> sw.getMaxCheckInterval().currentInterval(s.toSpacecraftState());
}
/** {@inheritDoc} */
@Override
public int getMaxIterationCount() {
return sw.getMaxIterationCount();
}
/** {@inheritDoc} */
@Override
public FieldEventHandler<T> getHandler() {
return new FieldEventHandler<T>() {
/** {@inheritDoc} */
@Override
public Action eventOccurred(final FieldSpacecraftState<T> s,
final FieldEventDetector<T> detector,
final boolean increasing) {
return sw.eventOccurred(s.toSpacecraftState(), sw, increasing);
}
/** {@inheritDoc} */
@Override
public FieldSpacecraftState<T> resetState(final FieldEventDetector<T> detector,
final FieldSpacecraftState<T> oldState) {
return new FieldSpacecraftState<>(field, sw.resetState(sw, oldState.toSpacecraftState()));
}
};
}
});
}
}
/** Add a switching condition between two attitude providers.
* <p>
* The {@code past} and {@code future} attitude providers are defined with regard
* to the natural flow of time. This means that if the propagation is forward, the
* propagator will switch from {@code past} provider to {@code future} provider at
* event occurrence, but if the propagation is backward, the propagator will switch
* from {@code future} provider to {@code past} provider at event occurrence. The
* transition between the two attitude laws is not instantaneous, the switch event
* defines the start of the transition (i.e. when leaving the {@code past} attitude
* law and entering the interpolated transition law). The end of the transition
* (i.e. when leaving the interpolating transition law and entering the {@code future}
* attitude law) occurs at switch time plus {@code transitionTime}.
* </p>
* <p>
* An attitude provider may have several different switch events associated to
* it. Depending on which event is triggered, the appropriate provider is
* switched to.
* </p>
* <p>
* The switch events specified here must <em>not</em> be registered to the
* propagator directly. The proper way to register these events is to
* call {@link #registerSwitchEvents(Propagator)} once after all switching
* conditions have been set up. The reason for this is that the events will
* be wrapped before being registered.
* </p>
* <p>
* If the underlying detector has an event handler associated to it, this handler
* will be triggered (i.e. its {@link org.orekit.propagation.events.handlers.EventHandler#eventOccurred(SpacecraftState,
* EventDetector, boolean) eventOccurred} method will be called), <em>regardless</em>
* of the event really triggering an attitude switch or not. As an example, if an
* eclipse detector is used to switch from day to night attitude mode when entering
* eclipse, with {@code switchOnIncrease} set to {@code false} and {@code switchOnDecrease}
* set to {@code true}. Then a handler set directly at eclipse detector level would
* be triggered at both eclipse entry and eclipse exit, but attitude switch would
* occur <em>only</em> at eclipse entry. Note that for the sake of symmetry, the
* transition start and end dates should match for both forward and backward propagation.
* This implies that for backward propagation, we have to compensate for the {@code
* transitionTime} when looking for the event. An unfortunate consequence is that the
* {@link org.orekit.propagation.events.handlers.EventHandler#eventOccurred(SpacecraftState, EventDetector, boolean)
* eventOccurred} method may appear to be called out of sync with respect to the
* propagation (it will be called when propagator reaches transition end, despite it
* refers to transition start, as per {@code transitionTime} compensation), and if the
* method returns {@link Action#STOP}, it will stop at the end of the
* transition instead of at the start. For these reasons, it is not recommended to
* set up an event handler for events that are used to switch attitude. If an event
* handler is needed for other purposes, a second handler should be registered to
* the propagator rather than relying on the side effects of attitude switches.
* </p>
* <p>
* The smoothness of the transition between past and future attitude laws can be tuned
* using the {@code transitionTime} and {@code transitionFilter} parameters. The {@code
* transitionTime} parameter specifies how much time is spent to switch from one law to
* the other law. It should be larger than the event {@link EventDetector#getThreshold()
* convergence threshold} in order to ensure attitude continuity. The {@code
* transitionFilter} parameter specifies the attitude time derivatives that should match
* at the boundaries between past attitude law and transition law on one side, and
* between transition law and future law on the other side.
* {@link AngularDerivativesFilter#USE_R} means only the rotation should be identical,
* {@link AngularDerivativesFilter#USE_RR} means both rotation and rotation rate
* should be identical, {@link AngularDerivativesFilter#USE_RRA} means both rotation,
* rotation rate and rotation acceleration should be identical. During the transition,
* the attitude law is computed by interpolating between past attitude law at switch time
* and future attitude law at current intermediate time.
* </p>
* @param past attitude provider applicable for times in the switch event occurrence past
* @param future attitude provider applicable for times in the switch event occurrence future
* @param switchEvent event triggering the attitude providers switch
* @param switchOnIncrease if true, switch is triggered on increasing event
* @param switchOnDecrease if true, switch is triggered on decreasing event
* @param transitionTime duration of the transition between the past and future attitude laws
* @param transitionFilter specification of transition law time derivatives that
* should match past and future attitude laws
* @param handler handler to call for notifying when switch occurs (may be null)
* @param <T> class type for the switch event
* @since 7.1
*/
public <T extends EventDetector> void addSwitchingCondition(final AttitudeProvider past,
final AttitudeProvider future,
final T switchEvent,
final boolean switchOnIncrease,
final boolean switchOnDecrease,
final double transitionTime,
final AngularDerivativesFilter transitionFilter,
final SwitchHandler handler) {
// safety check, for ensuring attitude continuity
if (transitionTime < switchEvent.getThreshold()) {
throw new OrekitException(OrekitMessages.TOO_SHORT_TRANSITION_TIME_FOR_ATTITUDES_SWITCH,
transitionTime, switchEvent.getThreshold());
}
// if it is the first switching condition, assume first active law is the past one
if (activated == null) {
resetActiveProvider(past);
}
// add the switching condition
switches.add(new Switch(switchEvent, switchOnIncrease, switchOnDecrease,
past, future, transitionTime, transitionFilter, handler));
}
/** {@inheritDoc} */
@Override
public Attitude getAttitude(final PVCoordinatesProvider pvProv,
final AbsoluteDate date, final Frame frame) {
return activated.get(date).getAttitude(pvProv, date, frame);
}
/** {@inheritDoc} */
@Override
public <T extends CalculusFieldElement<T>> FieldAttitude<T> getAttitude(final FieldPVCoordinatesProvider<T> pvProv,
final FieldAbsoluteDate<T> date,
final Frame frame) {
return activated.get(date.toAbsoluteDate()).getAttitude(pvProv, date, frame);
}
/** {@inheritDoc} */
@Override
public Rotation getAttitudeRotation(final PVCoordinatesProvider pvProv, final AbsoluteDate date, final Frame frame) {
return activated.get(date).getAttitudeRotation(pvProv, date, frame);
}
@Override
public <T extends CalculusFieldElement<T>> FieldRotation<T> getAttitudeRotation(final FieldPVCoordinatesProvider<T> pvProv,
final FieldAbsoluteDate<T> date,
final Frame frame) {
return activated.get(date.toAbsoluteDate()).getAttitudeRotation(pvProv, date, frame);
}
/** Switch specification. */
private class Switch implements EventDetector, EventHandler {
/** Event. */
private final EventDetector event;
/** Event direction triggering the switch. */
private final boolean switchOnIncrease;
/** Event direction triggering the switch. */
private final boolean switchOnDecrease;
/** Attitude provider applicable for times in the switch event occurrence past. */
private final AttitudeProvider past;
/** Attitude provider applicable for times in the switch event occurrence future. */
private final AttitudeProvider future;
/** Duration of the transition between the past and future attitude laws. */
private final double transitionTime;
/** Order at which the transition law time derivatives should match past and future attitude laws. */
private final AngularDerivativesFilter transitionFilter;
/** Handler to call for notifying when switch occurs (may be null). */
private final SwitchHandler switchHandler;
/** Propagation direction. */
private boolean forward;
/** Simple constructor.
* @param event event
* @param switchOnIncrease if true, switch is triggered on increasing event
* @param switchOnDecrease if true, switch is triggered on decreasing event
* otherwise switch is triggered on decreasing event
* @param past attitude provider applicable for times in the switch event occurrence past
* @param future attitude provider applicable for times in the switch event occurrence future
* @param transitionTime duration of the transition between the past and future attitude laws
* @param transitionFilter order at which the transition law time derivatives
* should match past and future attitude laws
* @param switchHandler handler to call for notifying when switch occurs (may be null)
*/
Switch(final EventDetector event,
final boolean switchOnIncrease, final boolean switchOnDecrease,
final AttitudeProvider past, final AttitudeProvider future,
final double transitionTime, final AngularDerivativesFilter transitionFilter,
final SwitchHandler switchHandler) {
this.event = event;
this.switchOnIncrease = switchOnIncrease;
this.switchOnDecrease = switchOnDecrease;
this.past = past;
this.future = future;
this.transitionTime = transitionTime;
this.transitionFilter = transitionFilter;
this.switchHandler = switchHandler;
}
/** {@inheritDoc} */
@Override
public double getThreshold() {
return event.getThreshold();
}
/** {@inheritDoc} */
@Override
public AdaptableInterval getMaxCheckInterval() {
return event.getMaxCheckInterval();
}
/** {@inheritDoc} */
@Override
public int getMaxIterationCount() {
return event.getMaxIterationCount();
}
/** {@inheritDoc} */
public void init(final SpacecraftState s0, final AbsoluteDate t) {
// reset the transition parameters (this will be done once for each switch,
// despite doing it only once would have sufficient; it's not really a problem)
forward = t.durationFrom(s0.getDate()) >= 0.0;
if (activated.getSpansNumber() > 1) {
// remove transitions that will be overridden during upcoming propagation
if (forward) {
activated = activated.extractRange(AbsoluteDate.PAST_INFINITY, s0.getDate().shiftedBy(transitionTime));
} else {
activated = activated.extractRange(s0.getDate().shiftedBy(-transitionTime), AbsoluteDate.FUTURE_INFINITY);
}
}
// initialize the underlying event
event.init(s0, t);
}
/** {@inheritDoc} */
public double g(final SpacecraftState s) {
return event.g(forward ? s : s.shiftedBy(-transitionTime));
}
/** {@inheritDoc} */
public EventHandler getHandler() {
return this;
}
/** {@inheritDoc} */
public Action eventOccurred(final SpacecraftState s, final EventDetector detector, final boolean increasing) {
final AbsoluteDate date = s.getDate();
if (activated.get(date) == (forward ? past : future) &&
(increasing && switchOnIncrease || !increasing && switchOnDecrease)) {
if (forward) {
// prepare transition
final AbsoluteDate transitionEnd = date.shiftedBy(transitionTime);
activated.addValidAfter(new TransitionProvider(s.getAttitude(), transitionEnd), date, false);
// prepare future law after transition
activated.addValidAfter(future, transitionEnd, false);
// notify about the switch
if (switchHandler != null) {
switchHandler.switchOccurred(past, future, s);
}
return event.getHandler().eventOccurred(s, event, increasing);
} else {
// estimate state at transition start, according to the past attitude law
final Orbit sOrbit = s.getOrbit().shiftedBy(-transitionTime);
final Attitude sAttitude = past.getAttitude(sOrbit, sOrbit.getDate(), sOrbit.getFrame());
SpacecraftState sState = new SpacecraftState(sOrbit, sAttitude, s.getMass());
for (final DoubleArrayDictionary.Entry entry : s.getAdditionalStatesValues().getData()) {
sState = sState.addAdditionalState(entry.getKey(), entry.getValue());
}
// prepare transition
activated.addValidBefore(new TransitionProvider(sAttitude, date), date, false);
// prepare past law before transition
activated.addValidBefore(past, sOrbit.getDate(), false);
// notify about the switch
if (switchHandler != null) {
switchHandler.switchOccurred(future, past, sState);
}
return event.getHandler().eventOccurred(sState, event, increasing);
}
} else {
// trigger the underlying event despite no attitude switch occurred
return event.getHandler().eventOccurred(s, event, increasing);
}
}
/** {@inheritDoc} */
@Override
public SpacecraftState resetState(final EventDetector detector, final SpacecraftState oldState) {
// delegate to underlying event
return event.getHandler().resetState(event, oldState);
}
/** Provider for transition phases.
* @since 9.2
*/
private class TransitionProvider implements AttitudeProvider {
/** Attitude at preceding transition. */
private final Attitude transitionPreceding;
/** Date of final switch to following attitude law. */
private final AbsoluteDate transitionEnd;
/** Simple constructor.
* @param transitionPreceding attitude at preceding transition
* @param transitionEnd date of final switch to following attitude law
*/
TransitionProvider(final Attitude transitionPreceding, final AbsoluteDate transitionEnd) {
this.transitionPreceding = transitionPreceding;
this.transitionEnd = transitionEnd;
}
/** {@inheritDoc} */
public Attitude getAttitude(final PVCoordinatesProvider pvProv,
final AbsoluteDate date, final Frame frame) {
// Create sample
final TimeStampedAngularCoordinates start =
transitionPreceding.withReferenceFrame(frame).getOrientation();
final TimeStampedAngularCoordinates end =
future.getAttitude(pvProv, transitionEnd, frame).getOrientation();
final List<TimeStampedAngularCoordinates> sample = Arrays.asList(start, end);
// Create interpolator
final TimeInterpolator<TimeStampedAngularCoordinates> interpolator =
new TimeStampedAngularCoordinatesHermiteInterpolator(sample.size(), transitionFilter);
// interpolate between the two boundary attitudes
final TimeStampedAngularCoordinates interpolated = interpolator.interpolate(date, sample);
return new Attitude(frame, interpolated);
}
/** {@inheritDoc} */
public <S extends CalculusFieldElement<S>> FieldAttitude<S> getAttitude(final FieldPVCoordinatesProvider<S> pvProv,
final FieldAbsoluteDate<S> date,
final Frame frame) {
// create sample
final TimeStampedFieldAngularCoordinates<S> start =
new TimeStampedFieldAngularCoordinates<>(date.getField(),
transitionPreceding.withReferenceFrame(frame).getOrientation());
final TimeStampedFieldAngularCoordinates<S> end =
future.getAttitude(pvProv,
new FieldAbsoluteDate<>(date.getField(), transitionEnd),
frame).getOrientation();
final List<TimeStampedFieldAngularCoordinates<S>> sample = Arrays.asList(start, end);
// create interpolator
final FieldTimeInterpolator<TimeStampedFieldAngularCoordinates<S>, S> interpolator =
new TimeStampedFieldAngularCoordinatesHermiteInterpolator<>(sample.size(), transitionFilter);
// interpolate between the two boundary attitudes
final TimeStampedFieldAngularCoordinates<S> interpolated = interpolator.interpolate(date, sample);
return new FieldAttitude<>(frame, interpolated);
}
}
}
/** Interface for attitude switch notifications.
* <p>
* This interface is intended to be implemented by users who want to be
* notified when an attitude switch occurs.
* </p>
* @since 7.1
*/
public interface SwitchHandler {
/** Method called when attitude is switched from one law to another law.
* @param preceding attitude law used preceding the switch (i.e. in the past
* of the switch event for a forward propagation, or in the future
* of the switch event for a backward propagation)
* @param following attitude law used following the switch (i.e. in the future
* of the switch event for a forward propagation, or in the past
* of the switch event for a backward propagation)
* @param state state at switch time (with attitude computed using the {@code preceding} law)
*/
void switchOccurred(AttitudeProvider preceding, AttitudeProvider following, SpacecraftState state);
}
}