use of org.orekit.propagation.SpacecraftState in project Orekit by CS-SI.
the class TurnAroundRangeAnalyticTest method genericTestValues.
/**
* Generic test function for values of the TAR
* @param printResults Print the results ?
* @throws OrekitException
*/
void genericTestValues(final boolean printResults) throws OrekitException {
Context context = EstimationTestUtils.eccentricContext("regular-data:potential:tides");
// Context context = EstimationTestUtils.geoStationnaryContext();
final NumericalPropagatorBuilder propagatorBuilder = context.createBuilder(OrbitType.KEPLERIAN, PositionAngle.TRUE, true, 1.0e-6, 60.0, 0.001);
// create perfect range measurements
final Propagator propagator = EstimationTestUtils.createPropagator(context.initialOrbit, propagatorBuilder);
final List<ObservedMeasurement<?>> measurements = EstimationTestUtils.createMeasurements(propagator, new TurnAroundRangeMeasurementCreator(context), 1.0, 3.0, 300.0);
propagator.setSlaveMode();
double[] absoluteErrors = new double[measurements.size()];
double[] relativeErrors = new double[measurements.size()];
int index = 0;
// Print the results ? Header
if (printResults) {
System.out.format(Locale.US, "%-15s %-15s %-23s %-23s %17s %17s %13s %13s%n", "Master Station", "Slave Station", "Measurement Date", "State Date", "TAR observed [m]", "TAR estimated [m]", "|ΔTAR| [m]", "rel |ΔTAR|");
}
// Loop on the measurements
for (final ObservedMeasurement<?> measurement : measurements) {
final double meanDelay = measurement.getObservedValue()[0] / Constants.SPEED_OF_LIGHT;
final AbsoluteDate date = measurement.getDate().shiftedBy(meanDelay);
final SpacecraftState state = propagator.propagate(date);
// Values of the TAR & errors
final double TARobserved = measurement.getObservedValue()[0];
final double TARestimated = new TurnAroundRangeAnalytic((TurnAroundRange) measurement).theoreticalEvaluationAnalytic(0, 0, propagator.getInitialState(), state).getEstimatedValue()[0];
absoluteErrors[index] = TARestimated - TARobserved;
relativeErrors[index] = FastMath.abs(absoluteErrors[index]) / FastMath.abs(TARobserved);
index++;
// Print results ? Values
if (printResults) {
final AbsoluteDate measurementDate = measurement.getDate();
String masterStationName = ((TurnAroundRange) measurement).getMasterStation().getBaseFrame().getName();
String slaveStationName = ((TurnAroundRange) measurement).getSlaveStation().getBaseFrame().getName();
System.out.format(Locale.US, "%-15s %-15s %-23s %-23s %17.6f %17.6f %13.6e %13.6e%n", masterStationName, slaveStationName, measurementDate, date, TARobserved, TARestimated, FastMath.abs(TARestimated - TARobserved), FastMath.abs((TARestimated - TARobserved) / TARobserved));
}
}
// Compute some statistics
final double absErrorsMedian = new Median().evaluate(absoluteErrors);
final double absErrorsMin = new Min().evaluate(absoluteErrors);
final double absErrorsMax = new Max().evaluate(absoluteErrors);
final double relErrorsMedian = new Median().evaluate(relativeErrors);
final double relErrorsMax = new Max().evaluate(relativeErrors);
// Print the results on console ? Final results
if (printResults) {
System.out.println();
System.out.println("Absolute errors median: " + absErrorsMedian);
System.out.println("Absolute errors min : " + absErrorsMin);
System.out.println("Absolute errors max : " + absErrorsMax);
System.out.println("Relative errors median: " + relErrorsMedian);
System.out.println("Relative errors max : " + relErrorsMax);
}
// Assert statistical errors
Assert.assertEquals(0.0, absErrorsMedian, 8.4e-08);
Assert.assertEquals(0.0, absErrorsMin, 9.0e-08);
Assert.assertEquals(0.0, absErrorsMax, 2.0e-07);
Assert.assertEquals(0.0, relErrorsMedian, 5.1e-15);
Assert.assertEquals(0.0, relErrorsMax, 1.2e-14);
}
use of org.orekit.propagation.SpacecraftState in project Orekit by CS-SI.
the class TurnAroundRangeMeasurementCreator method handleStep.
/**
* Function handling the steps of the propagator
* A turn-around measurement needs 2 stations, a master and a slave
* The measurement is a signal:
* - Emitted from the master ground station
* - Reflected on the spacecraft
* - Reflected on the slave ground station
* - Reflected on the spacecraft again
* - Received on the master ground station
* Its value is the elapsed time between emission and reception
* divided by 2c were c is the speed of light.
*
* The path of the signal is divided into 2 legs:
* - The 1st leg goes from emission by the master station to reception by the slave station
* - The 2nd leg goes from emission by the slave station to reception by the master station
*
* The spacecraft state date should, after a few iterations of the estimation process, be
* set to the date of arrival/departure of the signal to/from the slave station.
* It is guaranteed by implementation of the estimated measurement.
* This is done to avoid big shifts in time to compute the transit states.
* See TurnAroundRange.java for more
* Thus the spacecraft date is the date when the 1st leg of the path ends and the 2nd leg begins
*/
public void handleStep(final SpacecraftState currentState, final boolean isLast) throws OrekitException {
try {
for (Map.Entry<GroundStation, GroundStation> entry : context.TARstations.entrySet()) {
final GroundStation masterStation = entry.getKey();
final GroundStation slaveStation = entry.getValue();
final AbsoluteDate date = currentState.getDate();
final Frame inertial = currentState.getFrame();
final Vector3D position = currentState.toTransform().getInverse().transformPosition(antennaPhaseCenter);
// Create a TAR measurement only if elevation for both stations is higher than elevationMin°
if ((masterStation.getBaseFrame().getElevation(position, inertial, date) > FastMath.toRadians(30.0)) && (slaveStation.getBaseFrame().getElevation(position, inertial, date) > FastMath.toRadians(30.0))) {
// The solver used
final UnivariateSolver solver = new BracketingNthOrderBrentSolver(1.0e-12, 5);
// Spacecraft date t = date of arrival/departure of the signal to/from from the slave station
// Slave station position in inertial frame at t
final Vector3D slaveStationPosition = slaveStation.getOffsetToInertial(inertial, date).transformPosition(Vector3D.ZERO);
// Downlink time of flight to slave station
// The date of arrival/departure of the signal to/from the slave station is known and
// equal to spacecraft date t.
// Therefore we can use the function "downlinkTimeOfFlight" from GroundStation class
// final double slaveTauD = slaveStation.downlinkTimeOfFlight(currentState, date);
final double slaveTauD = solver.solve(1000, new UnivariateFunction() {
public double value(final double x) throws OrekitExceptionWrapper {
final SpacecraftState transitState = currentState.shiftedBy(-x);
final double d = Vector3D.distance(transitState.toTransform().getInverse().transformPosition(antennaPhaseCenter), slaveStationPosition);
return d - x * Constants.SPEED_OF_LIGHT;
}
}, -1.0, 1.0);
// Uplink time of flight from slave station
// A solver is used to know where the satellite is when it receives the signal
// back from the slave station
final double slaveTauU = solver.solve(1000, new UnivariateFunction() {
public double value(final double x) throws OrekitExceptionWrapper {
final SpacecraftState transitState = currentState.shiftedBy(+x);
final double d = Vector3D.distance(transitState.toTransform().getInverse().transformPosition(antennaPhaseCenter), slaveStationPosition);
return d - x * Constants.SPEED_OF_LIGHT;
}
}, -1.0, 1.0);
// Find the position of the master station at signal departure and arrival
// ----
// Transit state position & date for the 1st leg of the signal path
final SpacecraftState S1 = currentState.shiftedBy(-slaveTauD);
final Vector3D P1 = S1.toTransform().getInverse().transformPosition(antennaPhaseCenter);
final AbsoluteDate T1 = date.shiftedBy(-slaveTauD);
// Transit state position & date for the 2nd leg of the signal path
final Vector3D P2 = currentState.shiftedBy(+slaveTauU).toTransform().getInverse().transformPosition(antennaPhaseCenter);
final AbsoluteDate T2 = date.shiftedBy(+slaveTauU);
// Master station downlink delay - from P2 to master station
// We use a solver to know where the master station is when it receives
// the signal back from the satellite on the 2nd leg of the path
final double masterTauD = solver.solve(1000, new UnivariateFunction() {
public double value(final double x) throws OrekitExceptionWrapper {
try {
final Transform t = masterStation.getOffsetToInertial(inertial, T2.shiftedBy(+x));
final double d = Vector3D.distance(P2, t.transformPosition(Vector3D.ZERO));
return d - x * Constants.SPEED_OF_LIGHT;
} catch (OrekitException oe) {
throw new OrekitExceptionWrapper(oe);
}
}
}, -1.0, 1.0);
final AbsoluteDate masterReceptionDate = T2.shiftedBy(+masterTauD);
final TimeStampedPVCoordinates masterStationAtReception = masterStation.getOffsetToInertial(inertial, masterReceptionDate).transformPVCoordinates(new TimeStampedPVCoordinates(masterReceptionDate, PVCoordinates.ZERO));
// Master station uplink delay - from master station to P1
// Here the state date is known. Thus we can use the function "signalTimeOfFlight"
// of the AbstractMeasurement class
final double masterTauU = AbstractMeasurement.signalTimeOfFlight(masterStationAtReception, P1, T1);
final AbsoluteDate masterEmissionDate = T1.shiftedBy(-masterTauU);
final Vector3D masterStationAtEmission = masterStation.getOffsetToInertial(inertial, masterEmissionDate).transformPosition(Vector3D.ZERO);
// Uplink/downlink distance from/to slave station
final double slaveDownLinkDistance = Vector3D.distance(P1, slaveStationPosition);
final double slaveUpLinkDistance = Vector3D.distance(P2, slaveStationPosition);
// Uplink/downlink distance from/to master station
final double masterUpLinkDistance = Vector3D.distance(P1, masterStationAtEmission);
final double masterDownLinkDistance = Vector3D.distance(P2, masterStationAtReception.getPosition());
addMeasurement(new TurnAroundRange(masterStation, slaveStation, masterReceptionDate, 0.5 * (masterUpLinkDistance + slaveDownLinkDistance + slaveUpLinkDistance + masterDownLinkDistance), 1.0, 10));
}
}
} catch (OrekitExceptionWrapper oew) {
throw new OrekitException(oew.getException());
} catch (OrekitException oe) {
throw new OrekitException(oe);
}
}
use of org.orekit.propagation.SpacecraftState in project Orekit by CS-SI.
the class TurnAroundRangeTest method genericTestValues.
/**
* Generic test function for values of the TAR
* @param printResults Print the results ?
* @throws OrekitException
*/
void genericTestValues(final boolean printResults) throws OrekitException {
Context context = EstimationTestUtils.eccentricContext("regular-data:potential:tides");
// Context context = EstimationTestUtils.geoStationnaryContext();
final NumericalPropagatorBuilder propagatorBuilder = context.createBuilder(OrbitType.KEPLERIAN, PositionAngle.TRUE, true, 1.0e-6, 60.0, 0.001);
// create perfect range measurements
final Propagator propagator = EstimationTestUtils.createPropagator(context.initialOrbit, propagatorBuilder);
final List<ObservedMeasurement<?>> measurements = EstimationTestUtils.createMeasurements(propagator, new TurnAroundRangeMeasurementCreator(context), 1.0, 3.0, 300.0);
propagator.setSlaveMode();
double[] absoluteErrors = new double[measurements.size()];
double[] relativeErrors = new double[measurements.size()];
int index = 0;
// Print the results ? Header
if (printResults) {
System.out.format(Locale.US, "%-15s %-15s %-23s %-23s %17s %17s %13s %13s%n", "Master Station", "Slave Station", "Measurement Date", "State Date", "TAR observed [m]", "TAR estimated [m]", "|ΔTAR| [m]", "rel |ΔTAR|");
}
// Loop on the measurements
for (final ObservedMeasurement<?> measurement : measurements) {
final double meanDelay = measurement.getObservedValue()[0] / Constants.SPEED_OF_LIGHT;
final AbsoluteDate date = measurement.getDate().shiftedBy(meanDelay);
final SpacecraftState state = propagator.propagate(date);
// Values of the TAR & errors
final double TARobserved = measurement.getObservedValue()[0];
final EstimatedMeasurement<?> estimated = measurement.estimate(0, 0, new SpacecraftState[] { state });
final double TARestimated = estimated.getEstimatedValue()[0];
final TimeStampedPVCoordinates[] participants = estimated.getParticipants();
Assert.assertEquals(5, participants.length);
Assert.assertEquals(0.5 * Constants.SPEED_OF_LIGHT * participants[4].getDate().durationFrom(participants[0].getDate()), estimated.getEstimatedValue()[0], 2.0e-8);
absoluteErrors[index] = TARestimated - TARobserved;
relativeErrors[index] = FastMath.abs(absoluteErrors[index]) / FastMath.abs(TARobserved);
index++;
// Print results ? Values
if (printResults) {
final AbsoluteDate measurementDate = measurement.getDate();
String masterStationName = ((TurnAroundRange) measurement).getMasterStation().getBaseFrame().getName();
String slaveStationName = ((TurnAroundRange) measurement).getSlaveStation().getBaseFrame().getName();
System.out.format(Locale.US, "%-15s %-15s %-23s %-23s %17.6f %17.6f %13.6e %13.6e%n", masterStationName, slaveStationName, measurementDate, date, TARobserved, TARestimated, FastMath.abs(TARestimated - TARobserved), FastMath.abs((TARestimated - TARobserved) / TARobserved));
}
}
// Compute some statistics
final double absErrorsMedian = new Median().evaluate(absoluteErrors);
final double absErrorsMin = new Min().evaluate(absoluteErrors);
final double absErrorsMax = new Max().evaluate(absoluteErrors);
final double relErrorsMedian = new Median().evaluate(relativeErrors);
final double relErrorsMax = new Max().evaluate(relativeErrors);
// Print the results on console ? Final results
if (printResults) {
System.out.println();
System.out.println("Absolute errors median: " + absErrorsMedian);
System.out.println("Absolute errors min : " + absErrorsMin);
System.out.println("Absolute errors max : " + absErrorsMax);
System.out.println("Relative errors median: " + relErrorsMedian);
System.out.println("Relative errors max : " + relErrorsMax);
}
// Assert statistical errors
Assert.assertEquals(0.0, absErrorsMedian, 1.4e-7);
Assert.assertEquals(0.0, absErrorsMin, 5.0e-7);
Assert.assertEquals(0.0, absErrorsMax, 4.9e-7);
Assert.assertEquals(0.0, relErrorsMedian, 8.9e-15);
Assert.assertEquals(0.0, relErrorsMax, 2.9e-14);
}
use of org.orekit.propagation.SpacecraftState in project Orekit by CS-SI.
the class TurnAroundRangeTest method genericTestStateDerivatives.
void genericTestStateDerivatives(final boolean isModifier, final boolean printResults, final double refErrorsPMedian, final double refErrorsPMean, final double refErrorsPMax, final double refErrorsVMedian, final double refErrorsVMean, final double refErrorsVMax) throws OrekitException {
Context context = EstimationTestUtils.eccentricContext("regular-data:potential:tides");
// Context context = EstimationTestUtils.geoStationnaryContext();
final NumericalPropagatorBuilder propagatorBuilder = context.createBuilder(OrbitType.KEPLERIAN, PositionAngle.TRUE, true, 1.0e-6, 60.0, 0.001);
// create perfect range2 measurements
final Propagator propagator = EstimationTestUtils.createPropagator(context.initialOrbit, propagatorBuilder);
final List<ObservedMeasurement<?>> measurements = EstimationTestUtils.createMeasurements(propagator, new TurnAroundRangeMeasurementCreator(context), 1.0, 3.0, 300.0);
propagator.setSlaveMode();
double[] errorsP = new double[3 * measurements.size()];
double[] errorsV = new double[3 * measurements.size()];
int indexP = 0;
int indexV = 0;
// Print the results ? Header
if (printResults) {
System.out.format(Locale.US, "%-15s %-15s %-23s %-23s " + "%10s %10s %10s " + "%10s %10s %10s " + "%10s %10s %10s " + "%10s %10s %10s%n", "Master Station", "Slave Station", "Measurement Date", "State Date", "ΔdPx", "ΔdPy", "ΔdPz", "ΔdVx", "ΔdVy", "ΔdVz", "rel ΔdPx", "rel ΔdPy", "rel ΔdPz", "rel ΔdVx", "rel ΔdVy", "rel ΔdVz");
}
// Loop on the measurements
for (final ObservedMeasurement<?> measurement : measurements) {
// Add modifiers if test implies it
final TurnAroundRangeTroposphericDelayModifier modifier = new TurnAroundRangeTroposphericDelayModifier(SaastamoinenModel.getStandardModel());
if (isModifier) {
((TurnAroundRange) measurement).addModifier(modifier);
}
// We intentionally propagate to a date which is close to the
// real spacecraft state but is *not* the accurate date, by
// compensating only part of the downlink delay. This is done
// in order to validate the partial derivatives with respect
// to velocity. If we had chosen the proper state date, the
// range would have depended only on the current position but
// not on the current velocity.
final double meanDelay = measurement.getObservedValue()[0] / Constants.SPEED_OF_LIGHT;
final AbsoluteDate date = measurement.getDate().shiftedBy(-0.75 * meanDelay);
final SpacecraftState state = propagator.propagate(date);
final double[][] jacobian = measurement.estimate(0, 0, new SpacecraftState[] { state }).getStateDerivatives(0);
// Jacobian reference value
final double[][] jacobianRef;
// Compute a reference value using finite differences
jacobianRef = Differentiation.differentiate(new StateFunction() {
public double[] value(final SpacecraftState state) throws OrekitException {
return measurement.estimate(0, 0, new SpacecraftState[] { state }).getEstimatedValue();
}
}, measurement.getDimension(), propagator.getAttitudeProvider(), OrbitType.CARTESIAN, PositionAngle.TRUE, 2.0, 3).value(state);
Assert.assertEquals(jacobianRef.length, jacobian.length);
Assert.assertEquals(jacobianRef[0].length, jacobian[0].length);
double[][] dJacobian = new double[jacobian.length][jacobian[0].length];
double[][] dJacobianRelative = new double[jacobian.length][jacobian[0].length];
for (int i = 0; i < jacobian.length; ++i) {
for (int j = 0; j < jacobian[i].length; ++j) {
dJacobian[i][j] = jacobian[i][j] - jacobianRef[i][j];
dJacobianRelative[i][j] = FastMath.abs(dJacobian[i][j] / jacobianRef[i][j]);
if (j < 3) {
errorsP[indexP++] = dJacobianRelative[i][j];
} else {
errorsV[indexV++] = dJacobianRelative[i][j];
}
}
}
// Print results on the console ? Print the Jacobian
if (printResults) {
String masterStationName = ((TurnAroundRange) measurement).getMasterStation().getBaseFrame().getName();
String slaveStationName = ((TurnAroundRange) measurement).getSlaveStation().getBaseFrame().getName();
System.out.format(Locale.US, "%-15s %-15s %-23s %-23s " + "%10.3e %10.3e %10.3e " + "%10.3e %10.3e %10.3e " + "%10.3e %10.3e %10.3e " + "%10.3e %10.3e %10.3e%n", masterStationName, slaveStationName, measurement.getDate(), date, dJacobian[0][0], dJacobian[0][1], dJacobian[0][2], dJacobian[0][3], dJacobian[0][4], dJacobian[0][5], dJacobianRelative[0][0], dJacobianRelative[0][1], dJacobianRelative[0][2], dJacobianRelative[0][3], dJacobianRelative[0][4], dJacobianRelative[0][5]);
}
}
// End loop on the measurements
// Compute some statistics
final double errorsPMedian = new Median().evaluate(errorsP);
final double errorsPMean = new Mean().evaluate(errorsP);
final double errorsPMax = new Max().evaluate(errorsP);
final double errorsVMedian = new Median().evaluate(errorsV);
final double errorsVMean = new Mean().evaluate(errorsV);
final double errorsVMax = new Max().evaluate(errorsV);
// Print the results on console ? Final results
if (printResults) {
System.out.println();
System.out.format(Locale.US, "Relative errors dR/dP -> Median: %6.3e / Mean: %6.3e / Max: %6.3e%n", errorsPMedian, errorsPMean, errorsPMax);
System.out.format(Locale.US, "Relative errors dR/dV -> Median: %6.3e / Mean: %6.3e / Max: %6.3e%n", errorsVMedian, errorsVMean, errorsVMax);
}
Assert.assertEquals(0.0, errorsPMedian, refErrorsPMedian);
Assert.assertEquals(0.0, errorsPMean, refErrorsPMean);
Assert.assertEquals(0.0, errorsPMax, refErrorsPMax);
Assert.assertEquals(0.0, errorsVMedian, refErrorsVMedian);
Assert.assertEquals(0.0, errorsVMean, refErrorsVMean);
Assert.assertEquals(0.0, errorsVMax, refErrorsVMax);
}
use of org.orekit.propagation.SpacecraftState in project Orekit by CS-SI.
the class IonoModifierTest method testRangeRateIonoModifier.
@Test
public void testRangeRateIonoModifier() throws OrekitException {
Context context = EstimationTestUtils.eccentricContext("regular-data:potential:tides");
final NumericalPropagatorBuilder propagatorBuilder = context.createBuilder(OrbitType.KEPLERIAN, PositionAngle.TRUE, true, 1.0e-6, 60.0, 0.001);
// create perfect range measurements
for (final GroundStation station : context.stations) {
station.getEastOffsetDriver().setSelected(true);
station.getNorthOffsetDriver().setSelected(true);
station.getZenithOffsetDriver().setSelected(true);
}
final Propagator propagator = EstimationTestUtils.createPropagator(context.initialOrbit, propagatorBuilder);
final List<ObservedMeasurement<?>> measurements = EstimationTestUtils.createMeasurements(propagator, new RangeRateMeasurementCreator(context, false), 1.0, 3.0, 300.0);
propagator.setSlaveMode();
final RangeRateIonosphericDelayModifier modifier = new RangeRateIonosphericDelayModifier(model, true);
for (final ObservedMeasurement<?> measurement : measurements) {
final AbsoluteDate date = measurement.getDate();
final SpacecraftState refstate = propagator.propagate(date);
RangeRate rangeRate = (RangeRate) measurement;
EstimatedMeasurement<RangeRate> evalNoMod = rangeRate.estimate(0, 0, new SpacecraftState[] { refstate });
// add modifier
rangeRate.addModifier(modifier);
//
EstimatedMeasurement<RangeRate> eval = rangeRate.estimate(0, 0, new SpacecraftState[] { refstate });
final double diffMetersSec = eval.getEstimatedValue()[0] - evalNoMod.getEstimatedValue()[0];
// TODO: check threshold
Assert.assertEquals(0.0, diffMetersSec, 0.016);
}
}
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