AbstractGaussianContribution.java
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* this work for additional information regarding copyright ownership.
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* Unless required by applicable law or agreed to in writing, software
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package org.orekit.propagation.semianalytical.dsst.forces;
import org.hipparchus.CalculusFieldElement;
import org.hipparchus.Field;
import org.hipparchus.analysis.CalculusFieldUnivariateVectorFunction;
import org.hipparchus.analysis.UnivariateVectorFunction;
import org.hipparchus.geometry.euclidean.threed.FieldRotation;
import org.hipparchus.geometry.euclidean.threed.FieldVector3D;
import org.hipparchus.geometry.euclidean.threed.Rotation;
import org.hipparchus.geometry.euclidean.threed.Vector3D;
import org.hipparchus.util.FastMath;
import org.hipparchus.util.FieldSinCos;
import org.hipparchus.util.MathArrays;
import org.hipparchus.util.SinCos;
import org.orekit.attitudes.Attitude;
import org.orekit.attitudes.AttitudeProvider;
import org.orekit.attitudes.FieldAttitude;
import org.orekit.forces.ForceModel;
import org.orekit.orbits.EquinoctialOrbit;
import org.orekit.orbits.FieldEquinoctialOrbit;
import org.orekit.orbits.FieldOrbit;
import org.orekit.orbits.Orbit;
import org.orekit.orbits.OrbitType;
import org.orekit.orbits.PositionAngleType;
import org.orekit.propagation.FieldSpacecraftState;
import org.orekit.propagation.PropagationType;
import org.orekit.propagation.SpacecraftState;
import org.orekit.propagation.semianalytical.dsst.utilities.AuxiliaryElements;
import org.orekit.propagation.semianalytical.dsst.utilities.CjSjCoefficient;
import org.orekit.propagation.semianalytical.dsst.utilities.FieldAuxiliaryElements;
import org.orekit.propagation.semianalytical.dsst.utilities.FieldCjSjCoefficient;
import org.orekit.propagation.semianalytical.dsst.utilities.FieldShortPeriodicsInterpolatedCoefficient;
import org.orekit.propagation.semianalytical.dsst.utilities.ShortPeriodicsInterpolatedCoefficient;
import org.orekit.time.AbsoluteDate;
import org.orekit.time.FieldAbsoluteDate;
import org.orekit.utils.FieldTimeSpanMap;
import org.orekit.utils.ParameterDriver;
import org.orekit.utils.TimeSpanMap;
import java.lang.reflect.Array;
import java.util.ArrayList;
import java.util.Collections;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import java.util.Set;
/**
* Common handling of {@link DSSTForceModel} methods for Gaussian contributions
* to DSST propagation.
* <p>
* This abstract class allows to provide easily a subset of
* {@link DSSTForceModel} methods for specific Gaussian contributions.
* </p>
* <p>
* This class implements the notion of numerical averaging of the DSST theory.
* Numerical averaging is mainly used for non-conservative disturbing forces
* such as atmospheric drag and solar radiation pressure.
* </p>
* <p>
* Gaussian contributions can be expressed as: da<sub>i</sub>/dt =
* δa<sub>i</sub>/δv . q<br>
* where:
* <ul>
* <li>a<sub>i</sub> are the six equinoctial elements</li>
* <li>v is the velocity vector</li>
* <li>q is the perturbing acceleration due to the considered force</li>
* </ul>
*
* <p>
* The averaging process and other considerations lead to integrate this
* contribution over the true longitude L possibly taking into account some
* limits.
*
* <p>
* To create a numerically averaged contribution, one needs only to provide a
* {@link ForceModel} and to implement in the derived class the methods:
* {@link #getLLimits(SpacecraftState, AuxiliaryElements)} and
* {@link #getParametersDriversWithoutMu()}.
* </p>
* @author Pascal Parraud
* @author Bryan Cazabonne (field translation)
*/
public abstract class AbstractGaussianContribution implements DSSTForceModel {
/**
* Retrograde factor I.
* <p>
* DSST model needs equinoctial orbit as internal representation. Classical
* equinoctial elements have discontinuities when inclination is close to zero.
* In this representation, I = +1. <br>
* To avoid this discontinuity, another representation exists and equinoctial
* elements can be expressed in a different way, called "retrograde" orbit. This
* implies I = -1. <br>
* As Orekit doesn't implement the retrograde orbit, I is always set to +1. But
* for the sake of consistency with the theory, the retrograde factor has been
* kept in the formulas.
* </p>
*/
private static final int I = 1;
/**
* Central attraction scaling factor.
* <p>
* We use a power of 2 to avoid numeric noise introduction in the
* multiplications/divisions sequences.
* </p>
*/
private static final double MU_SCALE = FastMath.scalb(1.0, 32);
/** Available orders for Gauss quadrature. */
private static final int[] GAUSS_ORDER = { 12, 16, 20, 24, 32, 40, 48 };
/** Max rank in Gauss quadrature orders array. */
private static final int MAX_ORDER_RANK = GAUSS_ORDER.length - 1;
/** Number of points for interpolation. */
private static final int INTERPOLATION_POINTS = 3;
/** Maximum value for j index. */
private static final int JMAX = 12;
/** Contribution to be numerically averaged. */
private final ForceModel contribution;
/** Gauss integrator. */
private final double threshold;
/** Gauss integrator. */
private GaussQuadrature integrator;
/** Flag for Gauss order computation. */
private boolean isDirty;
/** Attitude provider. */
private AttitudeProvider attitudeProvider;
/** Prefix for coefficients keys. */
private final String coefficientsKeyPrefix;
/** Short period terms. */
private GaussianShortPeriodicCoefficients gaussianSPCoefs;
/** Short period terms. */
private Map<Field<?>, FieldGaussianShortPeriodicCoefficients<?>> gaussianFieldSPCoefs;
/** Driver for gravitational parameter. */
private final ParameterDriver gmParameterDriver;
/**
* Build a new instance.
* @param coefficientsKeyPrefix prefix for coefficients keys
* @param threshold tolerance for the choice of the Gauss quadrature
* order
* @param contribution the {@link ForceModel} to be numerically
* averaged
* @param mu central attraction coefficient
*/
protected AbstractGaussianContribution(final String coefficientsKeyPrefix, final double threshold,
final ForceModel contribution, final double mu) {
gmParameterDriver = new ParameterDriver(DSSTNewtonianAttraction.CENTRAL_ATTRACTION_COEFFICIENT, mu, MU_SCALE,
0.0, Double.POSITIVE_INFINITY);
this.coefficientsKeyPrefix = coefficientsKeyPrefix;
this.contribution = contribution;
this.threshold = threshold;
this.integrator = new GaussQuadrature(GAUSS_ORDER[MAX_ORDER_RANK]);
this.isDirty = true;
gaussianFieldSPCoefs = new HashMap<>();
}
/** {@inheritDoc} */
@Override
public void init(final SpacecraftState initialState, final AbsoluteDate target) {
// Initialize the numerical force model
contribution.init(initialState, target);
}
/** {@inheritDoc} */
@Override
public <T extends CalculusFieldElement<T>> void init(final FieldSpacecraftState<T> initialState, final FieldAbsoluteDate<T> target) {
// Initialize the numerical force model
contribution.init(initialState, target);
}
/** {@inheritDoc} */
@Override
public List<ParameterDriver> getParametersDrivers() {
// Initialize drivers (without central attraction coefficient driver)
final List<ParameterDriver> drivers = new ArrayList<>(getParametersDriversWithoutMu());
// We put central attraction coefficient driver at the end of the array
drivers.add(gmParameterDriver);
return drivers;
}
/**
* Get the drivers for force model parameters except the one for the central
* attraction coefficient.
* <p>
* The driver for central attraction coefficient is automatically added at the
* last element of the {@link ParameterDriver} array into
* {@link #getParametersDrivers()} method.
* </p>
* @return drivers for force model parameters
*/
protected abstract List<ParameterDriver> getParametersDriversWithoutMu();
/** {@inheritDoc} */
@Override
public List<ShortPeriodTerms> initializeShortPeriodTerms(final AuxiliaryElements auxiliaryElements, final PropagationType type,
final double[] parameters) {
final List<ShortPeriodTerms> list = new ArrayList<>();
gaussianSPCoefs = new GaussianShortPeriodicCoefficients(coefficientsKeyPrefix, JMAX, INTERPOLATION_POINTS,
new TimeSpanMap<>(new Slot(JMAX, INTERPOLATION_POINTS)));
list.add(gaussianSPCoefs);
return list;
}
/** {@inheritDoc} */
@Override
public <T extends CalculusFieldElement<T>> List<FieldShortPeriodTerms<T>> initializeShortPeriodTerms(
final FieldAuxiliaryElements<T> auxiliaryElements, final PropagationType type, final T[] parameters) {
final Field<T> field = auxiliaryElements.getDate().getField();
final FieldGaussianShortPeriodicCoefficients<T> fgspc = new FieldGaussianShortPeriodicCoefficients<>(
coefficientsKeyPrefix, JMAX, INTERPOLATION_POINTS,
new FieldTimeSpanMap<>(new FieldSlot<>(JMAX, INTERPOLATION_POINTS), field));
gaussianFieldSPCoefs.put(field, fgspc);
return Collections.singletonList(fgspc);
}
/**
* Performs initialization at each integration step for the current force model.
* <p>
* This method aims at being called before mean elements rates computation.
* </p>
* @param auxiliaryElements auxiliary elements related to the current orbit
* @param parameters parameters values of the force model parameters
* only 1 value for each parameterDriver
* @return new force model context
*/
private AbstractGaussianContributionContext initializeStep(final AuxiliaryElements auxiliaryElements,
final double[] parameters) {
return new AbstractGaussianContributionContext(auxiliaryElements, parameters);
}
/**
* Performs initialization at each integration step for the current force model.
* <p>
* This method aims at being called before mean elements rates computation.
* </p>
* @param <T> type of the elements
* @param auxiliaryElements auxiliary elements related to the current orbit
* @param parameters parameters values of the force model parameters
* (only 1 values for each parameters corresponding
* to state date) by getting the parameters for a specific date.
* @return new force model context
*/
private <T extends CalculusFieldElement<T>> FieldAbstractGaussianContributionContext<T> initializeStep(
final FieldAuxiliaryElements<T> auxiliaryElements, final T[] parameters) {
return new FieldAbstractGaussianContributionContext<>(auxiliaryElements, parameters);
}
/** {@inheritDoc} */
@Override
public double[] getMeanElementRate(final SpacecraftState state, final AuxiliaryElements auxiliaryElements,
final double[] parameters) {
// Container for attributes
final AbstractGaussianContributionContext context = initializeStep(auxiliaryElements, parameters);
double[] meanElementRate = new double[6];
// Computes the limits for the integral
final double[] ll = getLLimits(state, auxiliaryElements);
// Computes integrated mean element rates if Llow < Lhigh
if (ll[0] < ll[1]) {
meanElementRate = getMeanElementRate(state, integrator, ll[0], ll[1], context, parameters);
if (isDirty) {
boolean next = true;
for (int i = 0; i < MAX_ORDER_RANK && next; i++) {
final double[] meanRates = getMeanElementRate(state, new GaussQuadrature(GAUSS_ORDER[i]), ll[0],
ll[1], context, parameters);
if (getRatesDiff(meanElementRate, meanRates, context) < threshold) {
integrator = new GaussQuadrature(GAUSS_ORDER[i]);
next = false;
}
}
isDirty = false;
}
}
return meanElementRate;
}
/** {@inheritDoc} */
@Override
public <T extends CalculusFieldElement<T>> T[] getMeanElementRate(final FieldSpacecraftState<T> state,
final FieldAuxiliaryElements<T> auxiliaryElements, final T[] parameters) {
// Container for attributes
final FieldAbstractGaussianContributionContext<T> context = initializeStep(auxiliaryElements, parameters);
final Field<T> field = state.getDate().getField();
T[] meanElementRate = MathArrays.buildArray(field, 6);
// Computes the limits for the integral
final T[] ll = getLLimits(state, auxiliaryElements);
// Computes integrated mean element rates if Llow < Lhigh
if (ll[0].getReal() < ll[1].getReal()) {
meanElementRate = getMeanElementRate(state, integrator, ll[0], ll[1], context, parameters);
if (isDirty) {
boolean next = true;
for (int i = 0; i < MAX_ORDER_RANK && next; i++) {
final T[] meanRates = getMeanElementRate(state, new GaussQuadrature(GAUSS_ORDER[i]), ll[0], ll[1],
context, parameters);
if (getRatesDiff(meanElementRate, meanRates, context).getReal() < threshold) {
integrator = new GaussQuadrature(GAUSS_ORDER[i]);
next = false;
}
}
isDirty = false;
}
}
return meanElementRate;
}
/**
* Compute the limits in L, the true longitude, for integration.
*
* @param state current state information: date, kinematics,
* attitude
* @param auxiliaryElements auxiliary elements related to the current orbit
* @return the integration limits in L
*/
protected abstract double[] getLLimits(SpacecraftState state, AuxiliaryElements auxiliaryElements);
/**
* Compute the limits in L, the true longitude, for integration.
*
* @param <T> type of the elements
* @param state current state information: date, kinematics,
* attitude
* @param auxiliaryElements auxiliary elements related to the current orbit
* @return the integration limits in L
*/
protected abstract <T extends CalculusFieldElement<T>> T[] getLLimits(FieldSpacecraftState<T> state,
FieldAuxiliaryElements<T> auxiliaryElements);
/**
* Computes the mean equinoctial elements rates da<sub>i</sub> / dt.
*
* @param state current state
* @param gauss Gauss quadrature
* @param low lower bound of the integral interval
* @param high upper bound of the integral interval
* @param context container for attributes
* @param parameters values of the force model parameters
* at state date (1 values for each parameters)
* @return the mean element rates
*/
protected double[] getMeanElementRate(final SpacecraftState state, final GaussQuadrature gauss, final double low,
final double high, final AbstractGaussianContributionContext context, final double[] parameters) {
// Auxiliary elements related to the current orbit
final AuxiliaryElements auxiliaryElements = context.getAuxiliaryElements();
final double[] meanElementRate = gauss.integrate(new IntegrableFunction(state, true, 0, parameters), low, high);
// Constant multiplier for integral
final double coef = 1. / (2. * FastMath.PI * auxiliaryElements.getB());
// Corrects mean element rates
for (int i = 0; i < 6; i++) {
meanElementRate[i] *= coef;
}
return meanElementRate;
}
/**
* Computes the mean equinoctial elements rates da<sub>i</sub> / dt.
*
* @param <T> type of the elements
* @param state current state
* @param gauss Gauss quadrature
* @param low lower bound of the integral interval
* @param high upper bound of the integral interval
* @param context container for attributes
* @param parameters values of the force model parameters(1 values for each parameters)
* @return the mean element rates
*/
protected <T extends CalculusFieldElement<T>> T[] getMeanElementRate(final FieldSpacecraftState<T> state,
final GaussQuadrature gauss, final T low, final T high,
final FieldAbstractGaussianContributionContext<T> context, final T[] parameters) {
// Field
final Field<T> field = context.getA().getField();
// Auxiliary elements related to the current orbit
final FieldAuxiliaryElements<T> auxiliaryElements = context.getFieldAuxiliaryElements();
final T[] meanElementRate = gauss.integrate(new FieldIntegrableFunction<>(state, true, 0, parameters, field),
low, high, field);
// Constant multiplier for integral
final T coef = auxiliaryElements.getB().multiply(low.getPi()).multiply(2.).reciprocal();
// Corrects mean element rates
for (int i = 0; i < 6; i++) {
meanElementRate[i] = meanElementRate[i].multiply(coef);
}
return meanElementRate;
}
/**
* Estimates the weighted magnitude of the difference between 2 sets of
* equinoctial elements rates.
*
* @param meanRef reference rates
* @param meanCur current rates
* @param context container for attributes
* @return estimated magnitude of weighted differences
*/
private double getRatesDiff(final double[] meanRef, final double[] meanCur,
final AbstractGaussianContributionContext context) {
// Auxiliary elements related to the current orbit
final AuxiliaryElements auxiliaryElements = context.getAuxiliaryElements();
double maxDiff = FastMath.abs(meanRef[0] - meanCur[0]) / auxiliaryElements.getSma();
// Corrects mean element rates
for (int i = 1; i < meanRef.length; i++) {
maxDiff = FastMath.max(maxDiff, FastMath.abs(meanRef[i] - meanCur[i]));
}
return maxDiff;
}
/**
* Estimates the weighted magnitude of the difference between 2 sets of
* equinoctial elements rates.
*
* @param <T> type of the elements
* @param meanRef reference rates
* @param meanCur current rates
* @param context container for attributes
* @return estimated magnitude of weighted differences
*/
private <T extends CalculusFieldElement<T>> T getRatesDiff(final T[] meanRef, final T[] meanCur,
final FieldAbstractGaussianContributionContext<T> context) {
// Auxiliary elements related to the current orbit
final FieldAuxiliaryElements<T> auxiliaryElements = context.getFieldAuxiliaryElements();
T maxDiff = FastMath.abs(meanRef[0].subtract(meanCur[0])).divide(auxiliaryElements.getSma());
// Corrects mean element rates
for (int i = 1; i < meanRef.length; i++) {
maxDiff = FastMath.max(maxDiff, FastMath.abs(meanRef[i].subtract(meanCur[i])));
}
return maxDiff;
}
/** {@inheritDoc} */
@Override
public void registerAttitudeProvider(final AttitudeProvider provider) {
this.attitudeProvider = provider;
}
/** {@inheritDoc} */
@Override
public void updateShortPeriodTerms(final double[] parameters, final SpacecraftState... meanStates) {
final Slot slot = gaussianSPCoefs.createSlot(meanStates);
for (final SpacecraftState meanState : meanStates) {
// Auxiliary elements related to the current orbit
final AuxiliaryElements auxiliaryElements = new AuxiliaryElements(meanState.getOrbit(), I);
// Container of attributes
// Extract the proper parameters valid for the corresponding meanState date from the input array
final double[] extractedParameters = this.extractParameters(parameters, auxiliaryElements.getDate());
final AbstractGaussianContributionContext context = initializeStep(auxiliaryElements, extractedParameters);
// Compute rhoj and sigmaj
final double[][] currentRhoSigmaj = computeRhoSigmaCoefficients(auxiliaryElements);
// Generate the Cij and Sij coefficients
final FourierCjSjCoefficients fourierCjSj = new FourierCjSjCoefficients(meanState, JMAX, auxiliaryElements,
extractedParameters);
// Generate the Uij and Vij coefficients
final UijVijCoefficients uijvij = new UijVijCoefficients(currentRhoSigmaj, fourierCjSj, JMAX);
gaussianSPCoefs.computeCoefficients(meanState, slot, fourierCjSj, uijvij, context.getMeanMotion(),
auxiliaryElements.getSma());
}
}
/** {@inheritDoc} */
@Override
@SuppressWarnings("unchecked")
public <T extends CalculusFieldElement<T>> void updateShortPeriodTerms(final T[] parameters,
final FieldSpacecraftState<T>... meanStates) {
// Field used by default
final Field<T> field = meanStates[0].getDate().getField();
final FieldGaussianShortPeriodicCoefficients<T> fgspc = (FieldGaussianShortPeriodicCoefficients<T>) gaussianFieldSPCoefs
.get(field);
final FieldSlot<T> slot = fgspc.createSlot(meanStates);
for (final FieldSpacecraftState<T> meanState : meanStates) {
// Auxiliary elements related to the current orbit
final FieldAuxiliaryElements<T> auxiliaryElements = new FieldAuxiliaryElements<>(meanState.getOrbit(), I);
// Container of attributes
// Extract the proper parameters valid for the corresponding meanState date from the input array
final T[] extractedParameters = this.extractParameters(parameters, auxiliaryElements.getDate());
final FieldAbstractGaussianContributionContext<T> context = initializeStep(auxiliaryElements, extractedParameters);
// Compute rhoj and sigmaj
final T[][] currentRhoSigmaj = computeRhoSigmaCoefficients(context, field);
// Generate the Cij and Sij coefficients
final FieldFourierCjSjCoefficients<T> fourierCjSj = new FieldFourierCjSjCoefficients<>(meanState, JMAX,
auxiliaryElements, extractedParameters, field);
// Generate the Uij and Vij coefficients
final FieldUijVijCoefficients<T> uijvij = new FieldUijVijCoefficients<>(currentRhoSigmaj, fourierCjSj, JMAX,
field);
fgspc.computeCoefficients(meanState, slot, fourierCjSj, uijvij, context.getMeanMotion(),
auxiliaryElements.getSma(), field);
}
}
/**
* Compute the auxiliary quantities ρ<sub>j</sub> and σ<sub>j</sub>.
* <p>
* The expressions used are equations 2.5.3-(4) from the Danielson paper. <br/>
* ρ<sub>j</sub> = (1+jB)(-b)<sup>j</sup>C<sub>j</sub>(k, h) <br/>
* σ<sub>j</sub> = (1+jB)(-b)<sup>j</sup>S<sub>j</sub>(k, h) <br/>
* </p>
* @param auxiliaryElements auxiliary elements related to the current orbit
* @return computed coefficients
*/
private double[][] computeRhoSigmaCoefficients(final AuxiliaryElements auxiliaryElements) {
final double[][] currentRhoSigmaj = new double[2][3 * JMAX + 1];
final CjSjCoefficient cjsjKH = new CjSjCoefficient(auxiliaryElements.getK(), auxiliaryElements.getH());
final double b = 1. / (1 + auxiliaryElements.getB());
// (-b)<sup>j</sup>
double mbtj = 1;
for (int j = 1; j <= 3 * JMAX; j++) {
// Compute current rho and sigma;
mbtj *= -b;
final double coef = (1 + j * auxiliaryElements.getB()) * mbtj;
currentRhoSigmaj[0][j] = coef * cjsjKH.getCj(j);
currentRhoSigmaj[1][j] = coef * cjsjKH.getSj(j);
}
return currentRhoSigmaj;
}
/**
* Compute the auxiliary quantities ρ<sub>j</sub> and σ<sub>j</sub>.
* <p>
* The expressions used are equations 2.5.3-(4) from the Danielson paper. <br/>
* ρ<sub>j</sub> = (1+jB)(-b)<sup>j</sup>C<sub>j</sub>(k, h) <br/>
* σ<sub>j</sub> = (1+jB)(-b)<sup>j</sup>S<sub>j</sub>(k, h) <br/>
* </p>
* @param <T> type of the elements
* @param context container for attributes
* @param field field used by default
* @return computed coefficients
*/
private <T extends CalculusFieldElement<T>> T[][] computeRhoSigmaCoefficients(final FieldAbstractGaussianContributionContext<T> context, final Field<T> field) {
// zero
final T zero = field.getZero();
final FieldAuxiliaryElements<T> auxiliaryElements = context.getFieldAuxiliaryElements();
final T[][] currentRhoSigmaj = MathArrays.buildArray(field, 2, 3 * JMAX + 1);
final FieldCjSjCoefficient<T> cjsjKH = new FieldCjSjCoefficient<>(auxiliaryElements.getK(),
auxiliaryElements.getH(), field);
final T b = auxiliaryElements.getB().add(1.).reciprocal();
// (-b)<sup>j</sup>
T mbtj = zero.newInstance(1.);
for (int j = 1; j <= 3 * JMAX; j++) {
// Compute current rho and sigma;
mbtj = mbtj.multiply(b.negate());
final T coef = mbtj.multiply(auxiliaryElements.getB().multiply(j).add(1.));
currentRhoSigmaj[0][j] = coef.multiply(cjsjKH.getCj(j));
currentRhoSigmaj[1][j] = coef.multiply(cjsjKH.getSj(j));
}
return currentRhoSigmaj;
}
/**
* Internal class for numerical quadrature.
* <p>
* This class is a rewrite of {@link IntegrableFunction} for field elements
* </p>
* @param <T> type of the field elements
*/
protected class FieldIntegrableFunction<T extends CalculusFieldElement<T>>
implements CalculusFieldUnivariateVectorFunction<T> {
/** Current state. */
private final FieldSpacecraftState<T> state;
/**
* Signal that this class is used to compute the values required by the mean
* element variations or by the short periodic element variations.
*/
private final boolean meanMode;
/**
* The j index.
* <p>
* Used only for short periodic variation. Ignored for mean elements variation.
* </p>
*/
private final int j;
/** Container for attributes. */
private final FieldAbstractGaussianContributionContext<T> context;
/** Auxiliary Elements. */
private final FieldAuxiliaryElements<T> auxiliaryElements;
/** Drivers for solar radiation and atmospheric drag forces. */
private final T[] parameters;
/**
* Build a new instance with a new field.
* @param state current state information: date, kinematics, attitude
* @param meanMode if true return the value associated to the mean elements
* variation, if false return the values associated to the
* short periodic elements variation
* @param j the j index. used only for short periodic variation.
* Ignored for mean elements variation.
* @param parameters values of the force model parameters (only 1 values
* for each parameters corresponding to state date) obtained by
* calling the extract parameter method {@link #extractParameters(double[], AbsoluteDate)}
* to selected the right value for state date or by getting the parameters for a specific date
* @param field field utilized by default
*/
public FieldIntegrableFunction(final FieldSpacecraftState<T> state, final boolean meanMode, final int j,
final T[] parameters, final Field<T> field) {
this.meanMode = meanMode;
this.j = j;
this.parameters = parameters.clone();
this.auxiliaryElements = new FieldAuxiliaryElements<>(state.getOrbit(), I);
this.context = new FieldAbstractGaussianContributionContext<>(auxiliaryElements, this.parameters);
// remove derivatives from state
final T[] stateVector = MathArrays.buildArray(field, 6);
final PositionAngleType positionAngleType = PositionAngleType.MEAN;
OrbitType.EQUINOCTIAL.mapOrbitToArray(state.getOrbit(), positionAngleType, stateVector, null);
final FieldOrbit<T> fixedOrbit = OrbitType.EQUINOCTIAL.mapArrayToOrbit(stateVector, null,
positionAngleType, state.getDate(), context.getMu(), state.getFrame());
this.state = new FieldSpacecraftState<>(fixedOrbit, state.getAttitude(), state.getMass());
}
/** {@inheritDoc} */
@Override
public T[] value(final T x) {
// Parameters for array building
final Field<T> field = auxiliaryElements.getDate().getField();
final int dimension = 6;
// Compute the time difference from the true longitude difference
final T shiftedLm = trueToMean(x);
final T dLm = shiftedLm.subtract(auxiliaryElements.getLM());
final T dt = dLm.divide(context.getMeanMotion());
final FieldSinCos<T> scL = FastMath.sinCos(x);
final T cosL = scL.cos();
final T sinL = scL.sin();
final T roa = auxiliaryElements.getB().multiply(auxiliaryElements.getB()).divide(auxiliaryElements.getH().multiply(sinL).add(auxiliaryElements.getK().multiply(cosL)).add(1.));
final T roa2 = roa.multiply(roa);
final T r = auxiliaryElements.getSma().multiply(roa);
final T X = r.multiply(cosL);
final T Y = r.multiply(sinL);
final T naob = context.getMeanMotion().multiply(auxiliaryElements.getSma())
.divide(auxiliaryElements.getB());
final T Xdot = naob.multiply(auxiliaryElements.getH().add(sinL)).negate();
final T Ydot = naob.multiply(auxiliaryElements.getK().add(cosL));
final FieldVector3D<T> vel = new FieldVector3D<>(Xdot, auxiliaryElements.getVectorF(), Ydot,
auxiliaryElements.getVectorG());
// shift the orbit to dt
final FieldOrbit<T> shiftedOrbit = state.getOrbit().shiftedBy(dt);
// Recompose an orbit with time held fixed to be compliant with DSST theory
final FieldOrbit<T> recomposedOrbit = new FieldEquinoctialOrbit<>(shiftedOrbit.getA(),
shiftedOrbit.getEquinoctialEx(), shiftedOrbit.getEquinoctialEy(), shiftedOrbit.getHx(),
shiftedOrbit.getHy(), shiftedOrbit.getLM(), PositionAngleType.MEAN, shiftedOrbit.getFrame(),
state.getDate(), context.getMu());
// Get the corresponding attitude
final FieldAttitude<T> recomposedAttitude;
if (contribution.dependsOnAttitudeRate()) {
recomposedAttitude = attitudeProvider.getAttitude(recomposedOrbit,
recomposedOrbit.getDate(), recomposedOrbit.getFrame());
} else {
final FieldRotation<T> rotation = attitudeProvider.getAttitudeRotation(recomposedOrbit,
recomposedOrbit.getDate(), recomposedOrbit.getFrame());
final FieldVector3D<T> zeroVector = FieldVector3D.getZero(recomposedOrbit.getA().getField());
recomposedAttitude = new FieldAttitude<>(recomposedOrbit.getDate(), recomposedOrbit.getFrame(),
rotation, zeroVector, zeroVector);
}
// create shifted SpacecraftState with attitude at specified time
final FieldSpacecraftState<T> shiftedState = new FieldSpacecraftState<>(recomposedOrbit, recomposedAttitude,
state.getMass());
final FieldVector3D<T> acc = contribution.acceleration(shiftedState, parameters);
// Compute the derivatives of the elements by the speed
final T[] deriv = MathArrays.buildArray(field, dimension);
// da/dv
deriv[0] = getAoV(vel).dotProduct(acc);
// dex/dv
deriv[1] = getKoV(X, Y, Xdot, Ydot).dotProduct(acc);
// dey/dv
deriv[2] = getHoV(X, Y, Xdot, Ydot).dotProduct(acc);
// dhx/dv
deriv[3] = getQoV(X).dotProduct(acc);
// dhy/dv
deriv[4] = getPoV(Y).dotProduct(acc);
// dλ/dv
deriv[5] = getLoV(X, Y, Xdot, Ydot).dotProduct(acc);
// Compute mean elements rates
final T[] val;
if (meanMode) {
val = MathArrays.buildArray(field, dimension);
for (int i = 0; i < 6; i++) {
// da<sub>i</sub>/dt
val[i] = deriv[i].multiply(roa2);
}
} else {
val = MathArrays.buildArray(field, dimension * 2);
//Compute cos(j*L) and sin(j*L);
final FieldSinCos<T> scjL = FastMath.sinCos(x.multiply(j));
final T cosjL = j == 1 ? cosL : scjL.cos();
final T sinjL = j == 1 ? sinL : scjL.sin();
for (int i = 0; i < 6; i++) {
// da<sub>i</sub>/dv * cos(jL)
val[i] = deriv[i].multiply(cosjL);
// da<sub>i</sub>/dv * sin(jL)
val[i + 6] = deriv[i].multiply(sinjL);
}
}
return val;
}
/**
* Converts true longitude to mean longitude.
* @param x True longitude
* @return Eccentric longitude
*/
private T trueToMean(final T x) {
return eccentricToMean(trueToEccentric(x));
}
/**
* Converts true longitude to eccentric longitude.
* @param lv True longitude
* @return Eccentric longitude
*/
private T trueToEccentric (final T lv) {
final FieldSinCos<T> sclV = FastMath.sinCos(lv);
final T cosLv = sclV.cos();
final T sinLv = sclV.sin();
final T num = auxiliaryElements.getH().multiply(cosLv).subtract(auxiliaryElements.getK().multiply(sinLv));
final T den = auxiliaryElements.getB().add(auxiliaryElements.getK().multiply(cosLv)).add(auxiliaryElements.getH().multiply(sinLv)).add(1.);
return FastMath.atan(num.divide(den)).multiply(2.).add(lv);
}
/**
* Converts eccentric longitude to mean longitude.
* @param le Eccentric longitude
* @return Mean longitude
*/
private T eccentricToMean (final T le) {
final FieldSinCos<T> scle = FastMath.sinCos(le);
return le.subtract(auxiliaryElements.getK().multiply(scle.sin())).add(auxiliaryElements.getH().multiply(scle.cos()));
}
/**
* Compute δa/δv.
* @param vel satellite velocity
* @return δa/δv
*/
private FieldVector3D<T> getAoV(final FieldVector3D<T> vel) {
return new FieldVector3D<>(context.getTon2a(), vel);
}
/**
* Compute δh/δv.
* @param X satellite position component along f, equinoctial reference frame
* 1st vector
* @param Y satellite position component along g, equinoctial reference frame
* 2nd vector
* @param Xdot satellite velocity component along f, equinoctial reference frame
* 1st vector
* @param Ydot satellite velocity component along g, equinoctial reference frame
* 2nd vector
* @return δh/δv
*/
private FieldVector3D<T> getHoV(final T X, final T Y, final T Xdot, final T Ydot) {
final T kf = (Xdot.multiply(Y).multiply(2.).subtract(X.multiply(Ydot))).multiply(context.getOoMU());
final T kg = X.multiply(Xdot).multiply(context.getOoMU());
final T kw = auxiliaryElements.getK().multiply(
auxiliaryElements.getQ().multiply(Y).multiply(I).subtract(auxiliaryElements.getP().multiply(X)))
.multiply(context.getOOAB());
return new FieldVector3D<>(kf, auxiliaryElements.getVectorF(), kg.negate(), auxiliaryElements.getVectorG(),
kw, auxiliaryElements.getVectorW());
}
/**
* Compute δk/δv.
* @param X satellite position component along f, equinoctial reference frame
* 1st vector
* @param Y satellite position component along g, equinoctial reference frame
* 2nd vector
* @param Xdot satellite velocity component along f, equinoctial reference frame
* 1st vector
* @param Ydot satellite velocity component along g, equinoctial reference frame
* 2nd vector
* @return δk/δv
*/
private FieldVector3D<T> getKoV(final T X, final T Y, final T Xdot, final T Ydot) {
final T kf = Y.multiply(Ydot).multiply(context.getOoMU());
final T kg = (X.multiply(Ydot).multiply(2.).subtract(Xdot.multiply(Y))).multiply(context.getOoMU());
final T kw = auxiliaryElements.getH().multiply(
auxiliaryElements.getQ().multiply(Y).multiply(I).subtract(auxiliaryElements.getP().multiply(X)))
.multiply(context.getOOAB());
return new FieldVector3D<>(kf.negate(), auxiliaryElements.getVectorF(), kg, auxiliaryElements.getVectorG(),
kw.negate(), auxiliaryElements.getVectorW());
}
/**
* Compute δp/δv.
* @param Y satellite position component along g, equinoctial reference frame
* 2nd vector
* @return δp/δv
*/
private FieldVector3D<T> getPoV(final T Y) {
return new FieldVector3D<>(context.getCo2AB().multiply(Y), auxiliaryElements.getVectorW());
}
/**
* Compute δq/δv.
* @param X satellite position component along f, equinoctial reference frame
* 1st vector
* @return δq/δv
*/
private FieldVector3D<T> getQoV(final T X) {
return new FieldVector3D<>(context.getCo2AB().multiply(X).multiply(I), auxiliaryElements.getVectorW());
}
/**
* Compute δλ/δv.
* @param X satellite position component along f, equinoctial reference frame
* 1st vector
* @param Y satellite position component along g, equinoctial reference frame
* 2nd vector
* @param Xdot satellite velocity component along f, equinoctial reference frame
* 1st vector
* @param Ydot satellite velocity component along g, equinoctial reference frame
* 2nd vector
* @return δλ/δv
*/
private FieldVector3D<T> getLoV(final T X, final T Y, final T Xdot, final T Ydot) {
final FieldVector3D<T> pos = new FieldVector3D<>(X, auxiliaryElements.getVectorF(), Y,
auxiliaryElements.getVectorG());
final FieldVector3D<T> v2 = new FieldVector3D<>(auxiliaryElements.getK(), getHoV(X, Y, Xdot, Ydot),
auxiliaryElements.getH().negate(), getKoV(X, Y, Xdot, Ydot));
return new FieldVector3D<>(context.getOOA().multiply(-2.), pos, context.getOoBpo(), v2,
context.getOOA().multiply(auxiliaryElements.getQ().multiply(Y).multiply(I)
.subtract(auxiliaryElements.getP().multiply(X))),
auxiliaryElements.getVectorW());
}
}
/** Internal class for numerical quadrature. */
protected class IntegrableFunction implements UnivariateVectorFunction {
/** Current state. */
private final SpacecraftState state;
/**
* Signal that this class is used to compute the values required by the mean
* element variations or by the short periodic element variations.
*/
private final boolean meanMode;
/**
* The j index.
* <p>
* Used only for short periodic variation. Ignored for mean elements variation.
* </p>
*/
private final int j;
/** Container for attributes. */
private final AbstractGaussianContributionContext context;
/** Auxiliary Elements. */
private final AuxiliaryElements auxiliaryElements;
/** Drivers for solar radiation and atmospheric drag forces. */
private final double[] parameters;
/**
* Build a new instance.
* @param state current state information: date, kinematics, attitude
* @param meanMode if true return the value associated to the mean elements
* variation, if false return the values associated to the
* short periodic elements variation
* @param j the j index. used only for short periodic variation.
* Ignored for mean elements variation.
* @param parameters list of the estimated values for each driver at state date of the force model parameters
* only 1 value for each parameter
*/
IntegrableFunction(final SpacecraftState state, final boolean meanMode, final int j,
final double[] parameters) {
this.meanMode = meanMode;
this.j = j;
this.parameters = parameters.clone();
this.auxiliaryElements = new AuxiliaryElements(state.getOrbit(), I);
this.context = new AbstractGaussianContributionContext(auxiliaryElements, this.parameters);
// remove derivatives from state
final double[] stateVector = new double[6];
final PositionAngleType positionAngleType = PositionAngleType.MEAN;
OrbitType.EQUINOCTIAL.mapOrbitToArray(state.getOrbit(), positionAngleType, stateVector, null);
final Orbit fixedOrbit = OrbitType.EQUINOCTIAL.mapArrayToOrbit(stateVector, null, positionAngleType,
state.getDate(), context.getMu(), state.getFrame());
this.state = new SpacecraftState(fixedOrbit, state.getAttitude(), state.getMass());
}
/** {@inheritDoc} */
@SuppressWarnings("checkstyle:FinalLocalVariable")
@Override
public double[] value(final double x) {
// Compute the time difference from the true longitude difference
final double shiftedLm = trueToMean(x);
final double dLm = shiftedLm - auxiliaryElements.getLM();
final double dt = dLm / context.getMeanMotion();
final SinCos scL = FastMath.sinCos(x);
final double cosL = scL.cos();
final double sinL = scL.sin();
final double roa = auxiliaryElements.getB() * auxiliaryElements.getB() / (1. + auxiliaryElements.getH() * sinL + auxiliaryElements.getK() * cosL);
final double roa2 = roa * roa;
final double r = auxiliaryElements.getSma() * roa;
final double X = r * cosL;
final double Y = r * sinL;
final double naob = context.getMeanMotion() * auxiliaryElements.getSma() / auxiliaryElements.getB();
final double Xdot = -naob * (auxiliaryElements.getH() + sinL);
final double Ydot = naob * (auxiliaryElements.getK() + cosL);
final Vector3D vel = new Vector3D(Xdot, auxiliaryElements.getVectorF(), Ydot,
auxiliaryElements.getVectorG());
// shift the orbit to dt
final Orbit shiftedOrbit = state.getOrbit().shiftedBy(dt);
// Recompose an orbit with time held fixed to be compliant with DSST theory
final Orbit recomposedOrbit = new EquinoctialOrbit(shiftedOrbit.getA(), shiftedOrbit.getEquinoctialEx(),
shiftedOrbit.getEquinoctialEy(), shiftedOrbit.getHx(), shiftedOrbit.getHy(), shiftedOrbit.getLM(),
PositionAngleType.MEAN, shiftedOrbit.getFrame(), state.getDate(), context.getMu());
// Get the corresponding attitude
final Attitude recomposedAttitude;
if (contribution.dependsOnAttitudeRate()) {
recomposedAttitude = attitudeProvider.getAttitude(recomposedOrbit,
recomposedOrbit.getDate(), recomposedOrbit.getFrame());
} else {
final Rotation rotation = attitudeProvider.getAttitudeRotation(recomposedOrbit,
recomposedOrbit.getDate(), recomposedOrbit.getFrame());
final Vector3D zeroVector = Vector3D.ZERO;
recomposedAttitude = new Attitude(recomposedOrbit.getDate(), recomposedOrbit.getFrame(),
rotation, zeroVector, zeroVector);
}
// create shifted SpacecraftState with attitude at specified time
final SpacecraftState shiftedState = new SpacecraftState(recomposedOrbit, recomposedAttitude,
state.getMass());
// here parameters is a list of all span values of each parameter driver
final Vector3D acc = contribution.acceleration(shiftedState, parameters);
// Compute the derivatives of the elements by the speed
final double[] deriv = new double[6];
// da/dv
deriv[0] = getAoV(vel).dotProduct(acc);
// dex/dv
deriv[1] = getKoV(X, Y, Xdot, Ydot).dotProduct(acc);
// dey/dv
deriv[2] = getHoV(X, Y, Xdot, Ydot).dotProduct(acc);
// dhx/dv
deriv[3] = getQoV(X).dotProduct(acc);
// dhy/dv
deriv[4] = getPoV(Y).dotProduct(acc);
// dλ/dv
deriv[5] = getLoV(X, Y, Xdot, Ydot).dotProduct(acc);
// Compute mean elements rates
final double[] val;
if (meanMode) {
val = new double[6];
for (int i = 0; i < 6; i++) {
// da<sub>i</sub>/dt
val[i] = roa2 * deriv[i];
}
} else {
val = new double[12];
//Compute cos(j*L) and sin(j*L);
final SinCos scjL = FastMath.sinCos(j * x);
final double cosjL = j == 1 ? cosL : scjL.cos();
final double sinjL = j == 1 ? sinL : scjL.sin();
for (int i = 0; i < 6; i++) {
// da<sub>i</sub>/dv * cos(jL)
val[i] = cosjL * deriv[i];
// da<sub>i</sub>/dv * sin(jL)
val[i + 6] = sinjL * deriv[i];
}
}
return val;
}
/**
* Converts true longitude to eccentric longitude.
* @param lv True longitude
* @return Eccentric longitude
*/
private double trueToEccentric (final double lv) {
final SinCos scLv = FastMath.sinCos(lv);
final double num = auxiliaryElements.getH() * scLv.cos() - auxiliaryElements.getK() * scLv.sin();
final double den = auxiliaryElements.getB() + 1. + auxiliaryElements.getK() * scLv.cos() + auxiliaryElements.getH() * scLv.sin();
return lv + 2. * FastMath.atan(num / den);
}
/**
* Converts eccentric longitude to mean longitude.
* @param le Eccentric longitude
* @return Mean longitude
*/
private double eccentricToMean (final double le) {
final SinCos scLe = FastMath.sinCos(le);
return le - auxiliaryElements.getK() * scLe.sin() + auxiliaryElements.getH() * scLe.cos();
}
/**
* Converts true longitude to mean longitude.
* @param lv True longitude
* @return Eccentric longitude
*/
private double trueToMean(final double lv) {
return eccentricToMean(trueToEccentric(lv));
}
/**
* Compute δa/δv.
* @param vel satellite velocity
* @return δa/δv
*/
private Vector3D getAoV(final Vector3D vel) {
return new Vector3D(context.getTon2a(), vel);
}
/**
* Compute δh/δv.
* @param X satellite position component along f, equinoctial reference frame
* 1st vector
* @param Y satellite position component along g, equinoctial reference frame
* 2nd vector
* @param Xdot satellite velocity component along f, equinoctial reference frame
* 1st vector
* @param Ydot satellite velocity component along g, equinoctial reference frame
* 2nd vector
* @return δh/δv
*/
private Vector3D getHoV(final double X, final double Y, final double Xdot, final double Ydot) {
final double kf = (2. * Xdot * Y - X * Ydot) * context.getOoMU();
final double kg = X * Xdot * context.getOoMU();
final double kw = auxiliaryElements.getK() *
(I * auxiliaryElements.getQ() * Y - auxiliaryElements.getP() * X) * context.getOOAB();
return new Vector3D(kf, auxiliaryElements.getVectorF(), -kg, auxiliaryElements.getVectorG(), kw,
auxiliaryElements.getVectorW());
}
/**
* Compute δk/δv.
* @param X satellite position component along f, equinoctial reference frame
* 1st vector
* @param Y satellite position component along g, equinoctial reference frame
* 2nd vector
* @param Xdot satellite velocity component along f, equinoctial reference frame
* 1st vector
* @param Ydot satellite velocity component along g, equinoctial reference frame
* 2nd vector
* @return δk/δv
*/
private Vector3D getKoV(final double X, final double Y, final double Xdot, final double Ydot) {
final double kf = Y * Ydot * context.getOoMU();
final double kg = (2. * X * Ydot - Xdot * Y) * context.getOoMU();
final double kw = auxiliaryElements.getH() *
(I * auxiliaryElements.getQ() * Y - auxiliaryElements.getP() * X) * context.getOOAB();
return new Vector3D(-kf, auxiliaryElements.getVectorF(), kg, auxiliaryElements.getVectorG(), -kw,
auxiliaryElements.getVectorW());
}
/**
* Compute δp/δv.
* @param Y satellite position component along g, equinoctial reference frame
* 2nd vector
* @return δp/δv
*/
private Vector3D getPoV(final double Y) {
return new Vector3D(context.getCo2AB() * Y, auxiliaryElements.getVectorW());
}
/**
* Compute δq/δv.
* @param X satellite position component along f, equinoctial reference frame
* 1st vector
* @return δq/δv
*/
private Vector3D getQoV(final double X) {
return new Vector3D(I * context.getCo2AB() * X, auxiliaryElements.getVectorW());
}
/**
* Compute δλ/δv.
* @param X satellite position component along f, equinoctial reference frame
* 1st vector
* @param Y satellite position component along g, equinoctial reference frame
* 2nd vector
* @param Xdot satellite velocity component along f, equinoctial reference frame
* 1st vector
* @param Ydot satellite velocity component along g, equinoctial reference frame
* 2nd vector
* @return δλ/δv
*/
private Vector3D getLoV(final double X, final double Y, final double Xdot, final double Ydot) {
final Vector3D pos = new Vector3D(X, auxiliaryElements.getVectorF(), Y, auxiliaryElements.getVectorG());
final Vector3D v2 = new Vector3D(auxiliaryElements.getK(), getHoV(X, Y, Xdot, Ydot),
-auxiliaryElements.getH(), getKoV(X, Y, Xdot, Ydot));
return new Vector3D(-2. * context.getOOA(), pos, context.getOoBpo(), v2,
(I * auxiliaryElements.getQ() * Y - auxiliaryElements.getP() * X) * context.getOOA(),
auxiliaryElements.getVectorW());
}
}
/**
* Class used to {@link #integrate(UnivariateVectorFunction, double, double)
* integrate} a {@link org.hipparchus.analysis.UnivariateVectorFunction
* function} of the orbital elements using the Gaussian quadrature rule to get
* the acceleration.
*/
protected static class GaussQuadrature {
// Points and weights for the available quadrature orders
/** Points for quadrature of order 12. */
private static final double[] P_12 = { -0.98156063424671910000, -0.90411725637047490000,
-0.76990267419430470000, -0.58731795428661740000, -0.36783149899818024000, -0.12523340851146890000,
0.12523340851146890000, 0.36783149899818024000, 0.58731795428661740000, 0.76990267419430470000,
0.90411725637047490000, 0.98156063424671910000 };
/** Weights for quadrature of order 12. */
private static final double[] W_12 = { 0.04717533638651220000, 0.10693932599531830000, 0.16007832854334633000,
0.20316742672306584000, 0.23349253653835478000, 0.24914704581340286000, 0.24914704581340286000,
0.23349253653835478000, 0.20316742672306584000, 0.16007832854334633000, 0.10693932599531830000,
0.04717533638651220000 };
/** Points for quadrature of order 16. */
private static final double[] P_16 = { -0.98940093499164990000, -0.94457502307323260000,
-0.86563120238783160000, -0.75540440835500310000, -0.61787624440264380000, -0.45801677765722737000,
-0.28160355077925890000, -0.09501250983763745000, 0.09501250983763745000, 0.28160355077925890000,
0.45801677765722737000, 0.61787624440264380000, 0.75540440835500310000, 0.86563120238783160000,
0.94457502307323260000, 0.98940093499164990000 };
/** Weights for quadrature of order 16. */
private static final double[] W_16 = { 0.02715245941175405800, 0.06225352393864777000, 0.09515851168249283000,
0.12462897125553388000, 0.14959598881657685000, 0.16915651939500256000, 0.18260341504492360000,
0.18945061045506847000, 0.18945061045506847000, 0.18260341504492360000, 0.16915651939500256000,
0.14959598881657685000, 0.12462897125553388000, 0.09515851168249283000, 0.06225352393864777000,
0.02715245941175405800 };
/** Points for quadrature of order 20. */
private static final double[] P_20 = { -0.99312859918509490000, -0.96397192727791390000,
-0.91223442825132600000, -0.83911697182221890000, -0.74633190646015080000, -0.63605368072651510000,
-0.51086700195082700000, -0.37370608871541955000, -0.22778585114164507000, -0.07652652113349734000,
0.07652652113349734000, 0.22778585114164507000, 0.37370608871541955000, 0.51086700195082700000,
0.63605368072651510000, 0.74633190646015080000, 0.83911697182221890000, 0.91223442825132600000,
0.96397192727791390000, 0.99312859918509490000 };
/** Weights for quadrature of order 20. */
private static final double[] W_20 = { 0.01761400713915226400, 0.04060142980038684000, 0.06267204833410904000,
0.08327674157670477000, 0.10193011981724048000, 0.11819453196151844000, 0.13168863844917678000,
0.14209610931838212000, 0.14917298647260380000, 0.15275338713072600000, 0.15275338713072600000,
0.14917298647260380000, 0.14209610931838212000, 0.13168863844917678000, 0.11819453196151844000,
0.10193011981724048000, 0.08327674157670477000, 0.06267204833410904000, 0.04060142980038684000,
0.01761400713915226400 };
/** Points for quadrature of order 24. */
private static final double[] P_24 = { -0.99518721999702130000, -0.97472855597130950000,
-0.93827455200273270000, -0.88641552700440100000, -0.82000198597390300000, -0.74012419157855440000,
-0.64809365193697550000, -0.54542147138883950000, -0.43379350762604520000, -0.31504267969616340000,
-0.19111886747361634000, -0.06405689286260563000, 0.06405689286260563000, 0.19111886747361634000,
0.31504267969616340000, 0.43379350762604520000, 0.54542147138883950000, 0.64809365193697550000,
0.74012419157855440000, 0.82000198597390300000, 0.88641552700440100000, 0.93827455200273270000,
0.97472855597130950000, 0.99518721999702130000 };
/** Weights for quadrature of order 24. */
private static final double[] W_24 = { 0.01234122979998733500, 0.02853138862893380600, 0.04427743881741981000,
0.05929858491543691500, 0.07334648141108027000, 0.08619016153195320000, 0.09761865210411391000,
0.10744427011596558000, 0.11550566805372553000, 0.12167047292780335000, 0.12583745634682825000,
0.12793819534675221000, 0.12793819534675221000, 0.12583745634682825000, 0.12167047292780335000,
0.11550566805372553000, 0.10744427011596558000, 0.09761865210411391000, 0.08619016153195320000,
0.07334648141108027000, 0.05929858491543691500, 0.04427743881741981000, 0.02853138862893380600,
0.01234122979998733500 };
/** Points for quadrature of order 32. */
private static final double[] P_32 = { -0.99726386184948160000, -0.98561151154526840000,
-0.96476225558750640000, -0.93490607593773970000, -0.89632115576605220000, -0.84936761373256990000,
-0.79448379596794250000, -0.73218211874028970000, -0.66304426693021520000, -0.58771575724076230000,
-0.50689990893222950000, -0.42135127613063540000, -0.33186860228212767000, -0.23928736225213710000,
-0.14447196158279646000, -0.04830766568773831000, 0.04830766568773831000, 0.14447196158279646000,
0.23928736225213710000, 0.33186860228212767000, 0.42135127613063540000, 0.50689990893222950000,
0.58771575724076230000, 0.66304426693021520000, 0.73218211874028970000, 0.79448379596794250000,
0.84936761373256990000, 0.89632115576605220000, 0.93490607593773970000, 0.96476225558750640000,
0.98561151154526840000, 0.99726386184948160000 };
/** Weights for quadrature of order 32. */
private static final double[] W_32 = { 0.00701861000947013600, 0.01627439473090571200, 0.02539206530926214200,
0.03427386291302141000, 0.04283589802222658600, 0.05099805926237621600, 0.05868409347853559000,
0.06582222277636193000, 0.07234579410884862000, 0.07819389578707042000, 0.08331192422694673000,
0.08765209300440380000, 0.09117387869576390000, 0.09384439908080441000, 0.09563872007927487000,
0.09654008851472784000, 0.09654008851472784000, 0.09563872007927487000, 0.09384439908080441000,
0.09117387869576390000, 0.08765209300440380000, 0.08331192422694673000, 0.07819389578707042000,
0.07234579410884862000, 0.06582222277636193000, 0.05868409347853559000, 0.05099805926237621600,
0.04283589802222658600, 0.03427386291302141000, 0.02539206530926214200, 0.01627439473090571200,
0.00701861000947013600 };
/** Points for quadrature of order 40. */
private static final double[] P_40 = { -0.99823770971055930000, -0.99072623869945710000,
-0.97725994998377420000, -0.95791681921379170000, -0.93281280827867660000, -0.90209880696887420000,
-0.86595950321225960000, -0.82461223083331170000, -0.77830565142651940000, -0.72731825518992710000,
-0.67195668461417960000, -0.61255388966798030000, -0.54946712509512820000, -0.48307580168617870000,
-0.41377920437160500000, -0.34199409082575850000, -0.26815218500725370000, -0.19269758070137110000,
-0.11608407067525522000, -0.03877241750605081600, 0.03877241750605081600, 0.11608407067525522000,
0.19269758070137110000, 0.26815218500725370000, 0.34199409082575850000, 0.41377920437160500000,
0.48307580168617870000, 0.54946712509512820000, 0.61255388966798030000, 0.67195668461417960000,
0.72731825518992710000, 0.77830565142651940000, 0.82461223083331170000, 0.86595950321225960000,
0.90209880696887420000, 0.93281280827867660000, 0.95791681921379170000, 0.97725994998377420000,
0.99072623869945710000, 0.99823770971055930000 };
/** Weights for quadrature of order 40. */
private static final double[] W_40 = { 0.00452127709853309800, 0.01049828453115270400, 0.01642105838190797300,
0.02224584919416689000, 0.02793700698002338000, 0.03346019528254786500, 0.03878216797447199000,
0.04387090818567333000, 0.04869580763507221000, 0.05322784698393679000, 0.05743976909939157000,
0.06130624249292891000, 0.06480401345660108000, 0.06791204581523394000, 0.07061164739128681000,
0.07288658239580408000, 0.07472316905796833000, 0.07611036190062619000, 0.07703981816424793000,
0.07750594797842482000, 0.07750594797842482000, 0.07703981816424793000, 0.07611036190062619000,
0.07472316905796833000, 0.07288658239580408000, 0.07061164739128681000, 0.06791204581523394000,
0.06480401345660108000, 0.06130624249292891000, 0.05743976909939157000, 0.05322784698393679000,
0.04869580763507221000, 0.04387090818567333000, 0.03878216797447199000, 0.03346019528254786500,
0.02793700698002338000, 0.02224584919416689000, 0.01642105838190797300, 0.01049828453115270400,
0.00452127709853309800 };
/** Points for quadrature of order 48. */
private static final double[] P_48 = { -0.99877100725242610000, -0.99353017226635080000,
-0.98412458372282700000, -0.97059159254624720000, -0.95298770316043080000, -0.93138669070655440000,
-0.90587913671556960000, -0.87657202027424800000, -0.84358826162439350000, -0.80706620402944250000,
-0.76715903251574020000, -0.72403413092381470000, -0.67787237963266400000, -0.62886739677651370000,
-0.57722472608397270000, -0.52316097472223300000, -0.46690290475095840000, -0.40868648199071680000,
-0.34875588629216070000, -0.28736248735545555000, -0.22476379039468908000, -0.16122235606889174000,
-0.09700469920946270000, -0.03238017096286937000, 0.03238017096286937000, 0.09700469920946270000,
0.16122235606889174000, 0.22476379039468908000, 0.28736248735545555000, 0.34875588629216070000,
0.40868648199071680000, 0.46690290475095840000, 0.52316097472223300000, 0.57722472608397270000,
0.62886739677651370000, 0.67787237963266400000, 0.72403413092381470000, 0.76715903251574020000,
0.80706620402944250000, 0.84358826162439350000, 0.87657202027424800000, 0.90587913671556960000,
0.93138669070655440000, 0.95298770316043080000, 0.97059159254624720000, 0.98412458372282700000,
0.99353017226635080000, 0.99877100725242610000 };
/** Weights for quadrature of order 48. */
private static final double[] W_48 = { 0.00315334605230596250, 0.00732755390127620800, 0.01147723457923446900,
0.01557931572294386600, 0.01961616045735556700, 0.02357076083932435600, 0.02742650970835688000,
0.03116722783279807000, 0.03477722256477045000, 0.03824135106583080600, 0.04154508294346483000,
0.04467456085669424000, 0.04761665849249054000, 0.05035903555385448000, 0.05289018948519365000,
0.05519950369998416500, 0.05727729210040315000, 0.05911483969839566000, 0.06070443916589384000,
0.06203942315989268000, 0.06311419228625403000, 0.06392423858464817000, 0.06446616443595010000,
0.06473769681268386000, 0.06473769681268386000, 0.06446616443595010000, 0.06392423858464817000,
0.06311419228625403000, 0.06203942315989268000, 0.06070443916589384000, 0.05911483969839566000,
0.05727729210040315000, 0.05519950369998416500, 0.05289018948519365000, 0.05035903555385448000,
0.04761665849249054000, 0.04467456085669424000, 0.04154508294346483000, 0.03824135106583080600,
0.03477722256477045000, 0.03116722783279807000, 0.02742650970835688000, 0.02357076083932435600,
0.01961616045735556700, 0.01557931572294386600, 0.01147723457923446900, 0.00732755390127620800,
0.00315334605230596250 };
/** Node points. */
private final double[] nodePoints;
/** Node weights. */
private final double[] nodeWeights;
/** Number of points. */
private final int numberOfPoints;
/**
* Creates a Gauss integrator of the given order.
*
* @param numberOfPoints Order of the integration rule.
*/
GaussQuadrature(final int numberOfPoints) {
this.numberOfPoints = numberOfPoints;
switch (numberOfPoints) {
case 12:
this.nodePoints = P_12.clone();
this.nodeWeights = W_12.clone();
break;
case 16:
this.nodePoints = P_16.clone();
this.nodeWeights = W_16.clone();
break;
case 20:
this.nodePoints = P_20.clone();
this.nodeWeights = W_20.clone();
break;
case 24:
this.nodePoints = P_24.clone();
this.nodeWeights = W_24.clone();
break;
case 32:
this.nodePoints = P_32.clone();
this.nodeWeights = W_32.clone();
break;
case 40:
this.nodePoints = P_40.clone();
this.nodeWeights = W_40.clone();
break;
case 48:
default:
this.nodePoints = P_48.clone();
this.nodeWeights = W_48.clone();
break;
}
}
/**
* Integrates a given function on the given interval.
*
* @param f Function to integrate.
* @param lowerBound Lower bound of the integration interval.
* @param upperBound Upper bound of the integration interval.
* @return the integral of the weighted function.
*/
public double[] integrate(final UnivariateVectorFunction f, final double lowerBound, final double upperBound) {
final double[] adaptedPoints = nodePoints.clone();
final double[] adaptedWeights = nodeWeights.clone();
transform(adaptedPoints, adaptedWeights, lowerBound, upperBound);
return basicIntegrate(f, adaptedPoints, adaptedWeights);
}
/**
* Integrates a given function on the given interval.
*
* @param <T> the type of the field elements
* @param f Function to integrate.
* @param lowerBound Lower bound of the integration interval.
* @param upperBound Upper bound of the integration interval.
* @param field field utilized by default
* @return the integral of the weighted function.
*/
public <T extends CalculusFieldElement<T>> T[] integrate(final CalculusFieldUnivariateVectorFunction<T> f,
final T lowerBound, final T upperBound, final Field<T> field) {
final T zero = field.getZero();
final T[] adaptedPoints = MathArrays.buildArray(field, numberOfPoints);
final T[] adaptedWeights = MathArrays.buildArray(field, numberOfPoints);
for (int i = 0; i < numberOfPoints; i++) {
adaptedPoints[i] = zero.newInstance(nodePoints[i]);
adaptedWeights[i] = zero.newInstance(nodeWeights[i]);
}
transform(adaptedPoints, adaptedWeights, lowerBound, upperBound);
return basicIntegrate(f, adaptedPoints, adaptedWeights, field);
}
/**
* Performs a change of variable so that the integration can be performed on an
* arbitrary interval {@code [a, b]}.
* <p>
* It is assumed that the natural interval is {@code [-1, 1]}.
* </p>
*
* @param points Points to adapt to the new interval.
* @param weights Weights to adapt to the new interval.
* @param a Lower bound of the integration interval.
* @param b Lower bound of the integration interval.
*/
private void transform(final double[] points, final double[] weights, final double a, final double b) {
// Scaling
final double scale = (b - a) / 2;
final double shift = a + scale;
for (int i = 0; i < points.length; i++) {
points[i] = points[i] * scale + shift;
weights[i] *= scale;
}
}
/**
* Performs a change of variable so that the integration can be performed on an
* arbitrary interval {@code [a, b]}.
* <p>
* It is assumed that the natural interval is {@code [-1, 1]}.
* </p>
* @param <T> the type of the field elements
* @param points Points to adapt to the new interval.
* @param weights Weights to adapt to the new interval.
* @param a Lower bound of the integration interval.
* @param b Lower bound of the integration interval
*/
private <T extends CalculusFieldElement<T>> void transform(final T[] points, final T[] weights, final T a,
final T b) {
// Scaling
final T scale = (b.subtract(a)).divide(2.);
final T shift = a.add(scale);
for (int i = 0; i < points.length; i++) {
points[i] = scale.multiply(points[i]).add(shift);
weights[i] = scale.multiply(weights[i]);
}
}
/**
* Returns an estimate of the integral of {@code f(x) * w(x)}, where {@code w}
* is a weight function that depends on the actual flavor of the Gauss
* integration scheme.
*
* @param f Function to integrate.
* @param points Nodes.
* @param weights Nodes weights.
* @return the integral of the weighted function.
*/
private double[] basicIntegrate(final UnivariateVectorFunction f, final double[] points,
final double[] weights) {
double x = points[0];
double w = weights[0];
double[] v = f.value(x);
final double[] y = new double[v.length];
for (int j = 0; j < v.length; j++) {
y[j] = w * v[j];
}
final double[] t = y.clone();
final double[] c = new double[v.length];
final double[] s = t.clone();
for (int i = 1; i < points.length; i++) {
x = points[i];
w = weights[i];
v = f.value(x);
for (int j = 0; j < v.length; j++) {
y[j] = w * v[j] - c[j];
t[j] = s[j] + y[j];
c[j] = (t[j] - s[j]) - y[j];
s[j] = t[j];
}
}
return s;
}
/**
* Returns an estimate of the integral of {@code f(x) * w(x)}, where {@code w}
* is a weight function that depends on the actual flavor of the Gauss
* integration scheme.
*
* @param <T> the type of the field elements.
* @param f Function to integrate.
* @param points Nodes.
* @param weights Nodes weight
* @param field field utilized by default
* @return the integral of the weighted function.
*/
private <T extends CalculusFieldElement<T>> T[] basicIntegrate(final CalculusFieldUnivariateVectorFunction<T> f,
final T[] points, final T[] weights, final Field<T> field) {
T x = points[0];
T w = weights[0];
T[] v = f.value(x);
final T[] y = MathArrays.buildArray(field, v.length);
for (int j = 0; j < v.length; j++) {
y[j] = v[j].multiply(w);
}
final T[] t = y.clone();
final T[] c = MathArrays.buildArray(field, v.length);
final T[] s = t.clone();
for (int i = 1; i < points.length; i++) {
x = points[i];
w = weights[i];
v = f.value(x);
for (int j = 0; j < v.length; j++) {
y[j] = v[j].multiply(w).subtract(c[j]);
t[j] = y[j].add(s[j]);
c[j] = (t[j].subtract(s[j])).subtract(y[j]);
s[j] = t[j];
}
}
return s;
}
}
/**
* Compute the C<sub>i</sub><sup>j</sup> and the S<sub>i</sub><sup>j</sup>
* coefficients.
* <p>
* Those coefficients are given in Danielson paper by expression 4.4-(6)
* </p>
* @author Petre Bazavan
* @author Lucian Barbulescu
*/
protected class FourierCjSjCoefficients {
/** Maximum possible value for j. */
private final int jMax;
/**
* The C<sub>i</sub><sup>j</sup> coefficients.
* <p>
* the index i corresponds to the following elements: <br/>
* - 0 for a <br>
* - 1 for k <br>
* - 2 for h <br>
* - 3 for q <br>
* - 4 for p <br>
* - 5 for λ <br>
* </p>
*/
private final double[][] cCoef;
/**
* The C<sub>i</sub><sup>j</sup> coefficients.
* <p>
* the index i corresponds to the following elements: <br/>
* - 0 for a <br>
* - 1 for k <br>
* - 2 for h <br>
* - 3 for q <br>
* - 4 for p <br>
* - 5 for λ <br>
* </p>
*/
private final double[][] sCoef;
/**
* Standard constructor.
* @param state the current state
* @param jMax maximum value for j
* @param auxiliaryElements auxiliary elements related to the current orbit
* @param parameters list of parameter values at state date for each driver
* of the force model parameters (1 value per parameter)
*/
FourierCjSjCoefficients(final SpacecraftState state, final int jMax, final AuxiliaryElements auxiliaryElements,
final double[] parameters) {
// Initialise the fields
this.jMax = jMax;
// Allocate the arrays
final int rows = jMax + 1;
cCoef = new double[rows][6];
sCoef = new double[rows][6];
// Compute the coefficients
computeCoefficients(state, auxiliaryElements, parameters);
}
/**
* Compute the Fourrier coefficients.
* <p>
* Only the C<sub>i</sub><sup>j</sup> and S<sub>i</sub><sup>j</sup> coefficients
* need to be computed as D<sub>i</sub><sup>m</sup> is always 0.
* </p>
* @param state the current state
* @param auxiliaryElements auxiliary elements related to the current orbit
* @param parameters list of parameter values at state date for each driver
* of the force model parameters (1 value per parameter)
*/
private void computeCoefficients(final SpacecraftState state, final AuxiliaryElements auxiliaryElements,
final double[] parameters) {
// Computes the limits for the integral
final double[] ll = getLLimits(state, auxiliaryElements);
// Computes integrated mean element rates if Llow < Lhigh
if (ll[0] < ll[1]) {
// Compute 1 / PI
final double ooPI = 1 / FastMath.PI;
// loop through all values of j
for (int j = 0; j <= jMax; j++) {
final double[] curentCoefficients = integrator
.integrate(new IntegrableFunction(state, false, j, parameters), ll[0], ll[1]);
// divide by PI and set the values for the coefficients
for (int i = 0; i < 6; i++) {
cCoef[j][i] = ooPI * curentCoefficients[i];
sCoef[j][i] = ooPI * curentCoefficients[i + 6];
}
}
}
}
/**
* Get the coefficient C<sub>i</sub><sup>j</sup>.
* @param i i index - corresponds to the required variation
* @param j j index
* @return the coefficient C<sub>i</sub><sup>j</sup>
*/
public double getCij(final int i, final int j) {
return cCoef[j][i];
}
/**
* Get the coefficient S<sub>i</sub><sup>j</sup>.
* @param i i index - corresponds to the required variation
* @param j j index
* @return the coefficient S<sub>i</sub><sup>j</sup>
*/
public double getSij(final int i, final int j) {
return sCoef[j][i];
}
}
/**
* Compute the C<sub>i</sub><sup>j</sup> and the S<sub>i</sub><sup>j</sup>
* coefficients with field elements.
* <p>
* Those coefficients are given in Danielson paper by expression 4.4-(6)
* </p>
* @author Petre Bazavan
* @author Lucian Barbulescu
* @param <T> type of the field elements
*/
protected class FieldFourierCjSjCoefficients<T extends CalculusFieldElement<T>> {
/** Maximum possible value for j. */
private final int jMax;
/**
* The C<sub>i</sub><sup>j</sup> coefficients.
* <p>
* the index i corresponds to the following elements: <br/>
* - 0 for a <br>
* - 1 for k <br>
* - 2 for h <br>
* - 3 for q <br>
* - 4 for p <br>
* - 5 for λ <br>
* </p>
*/
private final T[][] cCoef;
/**
* The C<sub>i</sub><sup>j</sup> coefficients.
* <p>
* the index i corresponds to the following elements: <br/>
* - 0 for a <br>
* - 1 for k <br>
* - 2 for h <br>
* - 3 for q <br>
* - 4 for p <br>
* - 5 for λ <br>
* </p>
*/
private final T[][] sCoef;
/**
* Standard constructor.
* @param state the current state
* @param jMax maximum value for j
* @param auxiliaryElements auxiliary elements related to the current orbit
* @param parameters values of the force model parameters
* @param field field used by default
*/
FieldFourierCjSjCoefficients(final FieldSpacecraftState<T> state, final int jMax,
final FieldAuxiliaryElements<T> auxiliaryElements, final T[] parameters, final Field<T> field) {
// Initialise the fields
this.jMax = jMax;
// Allocate the arrays
final int rows = jMax + 1;
cCoef = MathArrays.buildArray(field, rows, 6);
sCoef = MathArrays.buildArray(field, rows, 6);
// Compute the coefficients
computeCoefficients(state, auxiliaryElements, parameters, field);
}
/**
* Compute the Fourrier coefficients.
* <p>
* Only the C<sub>i</sub><sup>j</sup> and S<sub>i</sub><sup>j</sup> coefficients
* need to be computed as D<sub>i</sub><sup>m</sup> is always 0.
* </p>
* @param state the current state
* @param auxiliaryElements auxiliary elements related to the current orbit
* @param parameters values of the force model parameters
* @param field field used by default
*/
private void computeCoefficients(final FieldSpacecraftState<T> state,
final FieldAuxiliaryElements<T> auxiliaryElements, final T[] parameters, final Field<T> field) {
// Zero
final T zero = field.getZero();
// Computes the limits for the integral
final T[] ll = getLLimits(state, auxiliaryElements);
// Computes integrated mean element rates if Llow < Lhigh
if (ll[0].getReal() < ll[1].getReal()) {
// Compute 1 / PI
final T ooPI = zero.getPi().reciprocal();
// loop through all values of j
for (int j = 0; j <= jMax; j++) {
final T[] curentCoefficients = integrator.integrate(
new FieldIntegrableFunction<>(state, false, j, parameters, field), ll[0], ll[1], field);
// divide by PI and set the values for the coefficients
for (int i = 0; i < 6; i++) {
cCoef[j][i] = curentCoefficients[i].multiply(ooPI);
sCoef[j][i] = curentCoefficients[i + 6].multiply(ooPI);
}
}
}
}
/**
* Get the coefficient C<sub>i</sub><sup>j</sup>.
* @param i i index - corresponds to the required variation
* @param j j index
* @return the coefficient C<sub>i</sub><sup>j</sup>
*/
public T getCij(final int i, final int j) {
return cCoef[j][i];
}
/**
* Get the coefficient S<sub>i</sub><sup>j</sup>.
* @param i i index - corresponds to the required variation
* @param j j index
* @return the coefficient S<sub>i</sub><sup>j</sup>
*/
public T getSij(final int i, final int j) {
return sCoef[j][i];
}
}
/**
* This class handles the short periodic coefficients described in Danielson
* 2.5.3-26.
*
* <p>
* The value of M is 0. Also, since the values of the Fourier coefficient
* D<sub>i</sub><sup>m</sup> is 0 then the values of the coefficients
* D<sub>i</sub><sup>m</sup> for m > 2 are also 0.
* </p>
* @author Petre Bazavan
* @author Lucian Barbulescu
*
*/
protected static class GaussianShortPeriodicCoefficients implements ShortPeriodTerms {
/** Maximum value for j index. */
private final int jMax;
/** Number of points used in the interpolation process. */
private final int interpolationPoints;
/** Prefix for coefficients keys. */
private final String coefficientsKeyPrefix;
/** All coefficients slots. */
private final transient TimeSpanMap<Slot> slots;
/**
* Constructor.
* @param coefficientsKeyPrefix prefix for coefficients keys
* @param jMax maximum value for j index
* @param interpolationPoints number of points used in the interpolation
* process
* @param slots all coefficients slots
*/
GaussianShortPeriodicCoefficients(final String coefficientsKeyPrefix, final int jMax,
final int interpolationPoints, final TimeSpanMap<Slot> slots) {
// Initialize fields
this.jMax = jMax;
this.interpolationPoints = interpolationPoints;
this.coefficientsKeyPrefix = coefficientsKeyPrefix;
this.slots = slots;
}
/**
* Get the slot valid for some date.
* @param meanStates mean states defining the slot
* @return slot valid at the specified date
*/
public Slot createSlot(final SpacecraftState... meanStates) {
final Slot slot = new Slot(jMax, interpolationPoints);
final AbsoluteDate first = meanStates[0].getDate();
final AbsoluteDate last = meanStates[meanStates.length - 1].getDate();
final int compare = first.compareTo(last);
if (compare < 0) {
slots.addValidAfter(slot, first, false);
} else if (compare > 0) {
slots.addValidBefore(slot, first, false);
} else {
// single date, valid for all time
slots.addValidAfter(slot, AbsoluteDate.PAST_INFINITY, false);
}
return slot;
}
/**
* Compute the short periodic coefficients.
*
* @param state current state information: date, kinematics, attitude
* @param slot coefficients slot
* @param fourierCjSj Fourier coefficients
* @param uijvij U and V coefficients
* @param n Keplerian mean motion
* @param a semi major axis
*/
private void computeCoefficients(final SpacecraftState state, final Slot slot,
final FourierCjSjCoefficients fourierCjSj, final UijVijCoefficients uijvij, final double n,
final double a) {
// get the current date
final AbsoluteDate date = state.getDate();
// compute the k₂⁰ coefficient
final double k20 = computeK20(jMax, uijvij.currentRhoSigmaj);
// 1. / n
final double oon = 1. / n;
// 3. / (2 * a * n)
final double to2an = 1.5 * oon / a;
// 3. / (4 * a * n)
final double to4an = to2an / 2;
// Compute the coefficients for each element
final int size = jMax + 1;
final double[] di1 = new double[6];
final double[] di2 = new double[6];
final double[][] currentCij = new double[size][6];
final double[][] currentSij = new double[size][6];
for (int i = 0; i < 6; i++) {
// compute D<sub>i</sub>¹ and D<sub>i</sub>² (all others are 0)
di1[i] = -oon * fourierCjSj.getCij(i, 0);
if (i == 5) {
di1[i] += to2an * uijvij.getU1(0, 0);
}
di2[i] = 0.;
if (i == 5) {
di2[i] += -to4an * fourierCjSj.getCij(0, 0);
}
// the C<sub>i</sub>⁰ is computed based on all others
currentCij[0][i] = -di2[i] * k20;
for (int j = 1; j <= jMax; j++) {
// compute the current C<sub>i</sub><sup>j</sup> and S<sub>i</sub><sup>j</sup>
currentCij[j][i] = oon * uijvij.getU1(j, i);
if (i == 5) {
currentCij[j][i] += -to2an * uijvij.getU2(j);
}
currentSij[j][i] = oon * uijvij.getV1(j, i);
if (i == 5) {
currentSij[j][i] += -to2an * uijvij.getV2(j);
}
// add the computed coefficients to C<sub>i</sub>⁰
currentCij[0][i] -= currentCij[j][i] * uijvij.currentRhoSigmaj[0][j] +
currentSij[j][i] * uijvij.currentRhoSigmaj[1][j];
}
}
// add the values to the interpolators
slot.cij[0].addGridPoint(date, currentCij[0]);
slot.dij[1].addGridPoint(date, di1);
slot.dij[2].addGridPoint(date, di2);
for (int j = 1; j <= jMax; j++) {
slot.cij[j].addGridPoint(date, currentCij[j]);
slot.sij[j].addGridPoint(date, currentSij[j]);
}
}
/**
* Compute the coefficient k₂⁰ by using the equation 2.5.3-(9a) from Danielson.
* <p>
* After inserting 2.5.3-(8) into 2.5.3-(9a) the result becomes:<br>
* k₂⁰ = Σ<sub>k=1</sub><sup>kMax</sup>[(2 / k²) * (σ<sub>k</sub>² +
* ρ<sub>k</sub>²)]
* </p>
* @param kMax max value fot k index
* @param currentRhoSigmaj the current computed values for the ρ<sub>j</sub> and
* σ<sub>j</sub> coefficients
* @return the coefficient k₂⁰
*/
private double computeK20(final int kMax, final double[][] currentRhoSigmaj) {
double k20 = 0.;
for (int kIndex = 1; kIndex <= kMax; kIndex++) {
// After inserting 2.5.3-(8) into 2.5.3-(9a) the result becomes:
// k₂⁰ = Σ<sub>k=1</sub><sup>kMax</sup>[(2 / k²) * (σ<sub>k</sub>² +
// ρ<sub>k</sub>²)]
double currentTerm = currentRhoSigmaj[1][kIndex] * currentRhoSigmaj[1][kIndex] +
currentRhoSigmaj[0][kIndex] * currentRhoSigmaj[0][kIndex];
// multiply by 2 / k²
currentTerm *= 2. / (kIndex * kIndex);
// add the term to the result
k20 += currentTerm;
}
return k20;
}
/** {@inheritDoc} */
@Override
public double[] value(final Orbit meanOrbit) {
// select the coefficients slot
final Slot slot = slots.get(meanOrbit.getDate());
// Get the True longitude L
final double L = meanOrbit.getLv();
// Compute the center (l - λ)
final double center = L - meanOrbit.getLM();
// Compute (l - λ)²
final double center2 = center * center;
// Initialize short periodic variations
final double[] shortPeriodicVariation = slot.cij[0].value(meanOrbit.getDate());
final double[] d1 = slot.dij[1].value(meanOrbit.getDate());
final double[] d2 = slot.dij[2].value(meanOrbit.getDate());
for (int i = 0; i < 6; i++) {
shortPeriodicVariation[i] += center * d1[i] + center2 * d2[i];
}
for (int j = 1; j <= JMAX; j++) {
final double[] c = slot.cij[j].value(meanOrbit.getDate());
final double[] s = slot.sij[j].value(meanOrbit.getDate());
final SinCos sc = FastMath.sinCos(j * L);
final double cos = sc.cos();
final double sin = sc.sin();
for (int i = 0; i < 6; i++) {
// add corresponding term to the short periodic variation
shortPeriodicVariation[i] += c[i] * cos;
shortPeriodicVariation[i] += s[i] * sin;
}
}
return shortPeriodicVariation;
}
/** {@inheritDoc} */
public String getCoefficientsKeyPrefix() {
return coefficientsKeyPrefix;
}
/**
* {@inheritDoc}
* <p>
* For Gaussian forces, there are JMAX cj coefficients, JMAX sj coefficients and
* 3 dj coefficients. As JMAX = 12, this sums up to 27 coefficients. The j index
* is the integer multiplier for the true longitude argument in the cj and sj
* coefficients and to the degree in the polynomial dj coefficients.
* </p>
*/
@Override
public Map<String, double[]> getCoefficients(final AbsoluteDate date, final Set<String> selected) {
// select the coefficients slot
final Slot slot = slots.get(date);
final Map<String, double[]> coefficients = new HashMap<>(2 * JMAX + 3);
storeIfSelected(coefficients, selected, slot.cij[0].value(date), "d", 0);
storeIfSelected(coefficients, selected, slot.dij[1].value(date), "d", 1);
storeIfSelected(coefficients, selected, slot.dij[2].value(date), "d", 2);
for (int j = 1; j <= JMAX; j++) {
storeIfSelected(coefficients, selected, slot.cij[j].value(date), "c", j);
storeIfSelected(coefficients, selected, slot.sij[j].value(date), "s", j);
}
return coefficients;
}
/**
* Put a coefficient in a map if selected.
* @param map map to populate
* @param selected set of coefficients that should be put in the map (empty set
* means all coefficients are selected)
* @param value coefficient value
* @param id coefficient identifier
* @param indices list of coefficient indices
*/
private void storeIfSelected(final Map<String, double[]> map, final Set<String> selected, final double[] value,
final String id, final int... indices) {
final StringBuilder keyBuilder = new StringBuilder(getCoefficientsKeyPrefix());
keyBuilder.append(id);
for (int index : indices) {
keyBuilder.append('[').append(index).append(']');
}
final String key = keyBuilder.toString();
if (selected.isEmpty() || selected.contains(key)) {
map.put(key, value);
}
}
}
/**
* This class handles the short periodic coefficients described in Danielson
* 2.5.3-26.
*
* <p>
* The value of M is 0. Also, since the values of the Fourier coefficient
* D<sub>i</sub><sup>m</sup> is 0 then the values of the coefficients
* D<sub>i</sub><sup>m</sup> for m > 2 are also 0.
* </p>
* @author Petre Bazavan
* @author Lucian Barbulescu
* @param <T> type of the field elements
*/
protected static class FieldGaussianShortPeriodicCoefficients<T extends CalculusFieldElement<T>>
implements FieldShortPeriodTerms<T> {
/** Maximum value for j index. */
private final int jMax;
/** Number of points used in the interpolation process. */
private final int interpolationPoints;
/** Prefix for coefficients keys. */
private final String coefficientsKeyPrefix;
/** All coefficients slots. */
private final transient FieldTimeSpanMap<FieldSlot<T>, T> slots;
/**
* Constructor.
* @param coefficientsKeyPrefix prefix for coefficients keys
* @param jMax maximum value for j index
* @param interpolationPoints number of points used in the interpolation
* process
* @param slots all coefficients slots
*/
FieldGaussianShortPeriodicCoefficients(final String coefficientsKeyPrefix, final int jMax,
final int interpolationPoints, final FieldTimeSpanMap<FieldSlot<T>, T> slots) {
// Initialize fields
this.jMax = jMax;
this.interpolationPoints = interpolationPoints;
this.coefficientsKeyPrefix = coefficientsKeyPrefix;
this.slots = slots;
}
/**
* Get the slot valid for some date.
* @param meanStates mean states defining the slot
* @return slot valid at the specified date
*/
@SuppressWarnings("unchecked")
public FieldSlot<T> createSlot(final FieldSpacecraftState<T>... meanStates) {
final FieldSlot<T> slot = new FieldSlot<>(jMax, interpolationPoints);
final FieldAbsoluteDate<T> first = meanStates[0].getDate();
final FieldAbsoluteDate<T> last = meanStates[meanStates.length - 1].getDate();
if (first.compareTo(last) <= 0) {
slots.addValidAfter(slot, first);
} else {
slots.addValidBefore(slot, first);
}
return slot;
}
/**
* Compute the short periodic coefficients.
*
* @param state current state information: date, kinematics, attitude
* @param slot coefficients slot
* @param fourierCjSj Fourier coefficients
* @param uijvij U and V coefficients
* @param n Keplerian mean motion
* @param a semi major axis
* @param field field used by default
*/
private void computeCoefficients(final FieldSpacecraftState<T> state, final FieldSlot<T> slot,
final FieldFourierCjSjCoefficients<T> fourierCjSj, final FieldUijVijCoefficients<T> uijvij, final T n,
final T a, final Field<T> field) {
// Zero
final T zero = field.getZero();
// get the current date
final FieldAbsoluteDate<T> date = state.getDate();
// compute the k₂⁰ coefficient
final T k20 = computeK20(jMax, uijvij.currentRhoSigmaj, field);
// 1. / n
final T oon = n.reciprocal();
// 3. / (2 * a * n)
final T to2an = oon.multiply(1.5).divide(a);
// 3. / (4 * a * n)
final T to4an = to2an.divide(2.);
// Compute the coefficients for each element
final int size = jMax + 1;
final T[] di1 = MathArrays.buildArray(field, 6);
final T[] di2 = MathArrays.buildArray(field, 6);
final T[][] currentCij = MathArrays.buildArray(field, size, 6);
final T[][] currentSij = MathArrays.buildArray(field, size, 6);
for (int i = 0; i < 6; i++) {
// compute D<sub>i</sub>¹ and D<sub>i</sub>² (all others are 0)
di1[i] = oon.negate().multiply(fourierCjSj.getCij(i, 0));
if (i == 5) {
di1[i] = di1[i].add(to2an.multiply(uijvij.getU1(0, 0)));
}
di2[i] = zero;
if (i == 5) {
di2[i] = di2[i].add(to4an.negate().multiply(fourierCjSj.getCij(0, 0)));
}
// the C<sub>i</sub>⁰ is computed based on all others
currentCij[0][i] = di2[i].negate().multiply(k20);
for (int j = 1; j <= jMax; j++) {
// compute the current C<sub>i</sub><sup>j</sup> and S<sub>i</sub><sup>j</sup>
currentCij[j][i] = oon.multiply(uijvij.getU1(j, i));
if (i == 5) {
currentCij[j][i] = currentCij[j][i].add(to2an.negate().multiply(uijvij.getU2(j)));
}
currentSij[j][i] = oon.multiply(uijvij.getV1(j, i));
if (i == 5) {
currentSij[j][i] = currentSij[j][i].add(to2an.negate().multiply(uijvij.getV2(j)));
}
// add the computed coefficients to C<sub>i</sub>⁰
currentCij[0][i] = currentCij[0][i].add(currentCij[j][i].multiply(uijvij.currentRhoSigmaj[0][j])
.add(currentSij[j][i].multiply(uijvij.currentRhoSigmaj[1][j])).negate());
}
}
// add the values to the interpolators
slot.cij[0].addGridPoint(date, currentCij[0]);
slot.dij[1].addGridPoint(date, di1);
slot.dij[2].addGridPoint(date, di2);
for (int j = 1; j <= jMax; j++) {
slot.cij[j].addGridPoint(date, currentCij[j]);
slot.sij[j].addGridPoint(date, currentSij[j]);
}
}
/**
* Compute the coefficient k₂⁰ by using the equation 2.5.3-(9a) from Danielson.
* <p>
* After inserting 2.5.3-(8) into 2.5.3-(9a) the result becomes:<br>
* k₂⁰ = Σ<sub>k=1</sub><sup>kMax</sup>[(2 / k²) * (σ<sub>k</sub>² +
* ρ<sub>k</sub>²)]
* </p>
* @param kMax max value fot k index
* @param currentRhoSigmaj the current computed values for the ρ<sub>j</sub> and
* σ<sub>j</sub> coefficients
* @param field field used by default
* @return the coefficient k₂⁰
*/
private T computeK20(final int kMax, final T[][] currentRhoSigmaj, final Field<T> field) {
T k20 = field.getZero();
for (int kIndex = 1; kIndex <= kMax; kIndex++) {
// After inserting 2.5.3-(8) into 2.5.3-(9a) the result becomes:
// k₂⁰ = Σ<sub>k=1</sub><sup>kMax</sup>[(2 / k²) * (σ<sub>k</sub>² +
// ρ<sub>k</sub>²)]
T currentTerm = currentRhoSigmaj[1][kIndex].multiply(currentRhoSigmaj[1][kIndex])
.add(currentRhoSigmaj[0][kIndex].multiply(currentRhoSigmaj[0][kIndex]));
// multiply by 2 / k²
currentTerm = currentTerm.multiply(2. / (kIndex * kIndex));
// add the term to the result
k20 = k20.add(currentTerm);
}
return k20;
}
/** {@inheritDoc} */
@Override
public T[] value(final FieldOrbit<T> meanOrbit) {
// select the coefficients slot
final FieldSlot<T> slot = slots.get(meanOrbit.getDate());
// Get the True longitude L
final T L = meanOrbit.getLv();
// Compute the center (l - λ)
final T center = L.subtract(meanOrbit.getLM());
// Compute (l - λ)²
final T center2 = center.square();
// Initialize short periodic variations
final T[] shortPeriodicVariation = slot.cij[0].value(meanOrbit.getDate());
final T[] d1 = slot.dij[1].value(meanOrbit.getDate());
final T[] d2 = slot.dij[2].value(meanOrbit.getDate());
for (int i = 0; i < 6; i++) {
shortPeriodicVariation[i] = shortPeriodicVariation[i]
.add(center.multiply(d1[i]).add(center2.multiply(d2[i])));
}
for (int j = 1; j <= JMAX; j++) {
final T[] c = slot.cij[j].value(meanOrbit.getDate());
final T[] s = slot.sij[j].value(meanOrbit.getDate());
final FieldSinCos<T> sc = FastMath.sinCos(L.multiply(j));
final T cos = sc.cos();
final T sin = sc.sin();
for (int i = 0; i < 6; i++) {
// add corresponding term to the short periodic variation
shortPeriodicVariation[i] = shortPeriodicVariation[i].add(c[i].multiply(cos));
shortPeriodicVariation[i] = shortPeriodicVariation[i].add(s[i].multiply(sin));
}
}
return shortPeriodicVariation;
}
/** {@inheritDoc} */
public String getCoefficientsKeyPrefix() {
return coefficientsKeyPrefix;
}
/**
* {@inheritDoc}
* <p>
* For Gaussian forces, there are JMAX cj coefficients, JMAX sj coefficients and
* 3 dj coefficients. As JMAX = 12, this sums up to 27 coefficients. The j index
* is the integer multiplier for the true longitude argument in the cj and sj
* coefficients and to the degree in the polynomial dj coefficients.
* </p>
*/
@Override
public Map<String, T[]> getCoefficients(final FieldAbsoluteDate<T> date, final Set<String> selected) {
// select the coefficients slot
final FieldSlot<T> slot = slots.get(date);
final Map<String, T[]> coefficients = new HashMap<>(2 * JMAX + 3);
storeIfSelected(coefficients, selected, slot.cij[0].value(date), "d", 0);
storeIfSelected(coefficients, selected, slot.dij[1].value(date), "d", 1);
storeIfSelected(coefficients, selected, slot.dij[2].value(date), "d", 2);
for (int j = 1; j <= JMAX; j++) {
storeIfSelected(coefficients, selected, slot.cij[j].value(date), "c", j);
storeIfSelected(coefficients, selected, slot.sij[j].value(date), "s", j);
}
return coefficients;
}
/**
* Put a coefficient in a map if selected.
* @param map map to populate
* @param selected set of coefficients that should be put in the map (empty set
* means all coefficients are selected)
* @param value coefficient value
* @param id coefficient identifier
* @param indices list of coefficient indices
*/
private void storeIfSelected(final Map<String, T[]> map, final Set<String> selected, final T[] value,
final String id, final int... indices) {
final StringBuilder keyBuilder = new StringBuilder(getCoefficientsKeyPrefix());
keyBuilder.append(id);
for (int index : indices) {
keyBuilder.append('[').append(index).append(']');
}
final String key = keyBuilder.toString();
if (selected.isEmpty() || selected.contains(key)) {
map.put(key, value);
}
}
}
/**
* The U<sub>i</sub><sup>j</sup> and V<sub>i</sub><sup>j</sup> coefficients
* described by equations 2.5.3-(21) and 2.5.3-(22) from Danielson.
* <p>
* The index i takes only the values 1 and 2<br>
* For U only the index 0 for j is used.
* </p>
*
* @author Petre Bazavan
* @author Lucian Barbulescu
*/
protected static class UijVijCoefficients {
/**
* The U₁<sup>j</sup> coefficients.
* <p>
* The first index identifies the Fourier coefficients used<br>
* Those coefficients are computed for all Fourier C<sub>i</sub><sup>j</sup> and
* S<sub>i</sub><sup>j</sup><br>
* The only exception is when j = 0 when only the coefficient for fourier index
* = 1 (i == 0) is needed.<br>
* Also, for fourier index = 1 (i == 0), the coefficients up to 2 * jMax are
* computed, because are required to compute the coefficients U₂<sup>j</sup>
* </p>
*/
private final double[][] u1ij;
/**
* The V₁<sup>j</sup> coefficients.
* <p>
* The first index identifies the Fourier coefficients used<br>
* Those coefficients are computed for all Fourier C<sub>i</sub><sup>j</sup> and
* S<sub>i</sub><sup>j</sup><br>
* for fourier index = 1 (i == 0), the coefficients up to 2 * jMax are computed,
* because are required to compute the coefficients V₂<sup>j</sup>
* </p>
*/
private final double[][] v1ij;
/**
* The U₂<sup>j</sup> coefficients.
* <p>
* Only the coefficients that use the Fourier index = 1 (i == 0) are computed as
* they are the only ones required.
* </p>
*/
private final double[] u2ij;
/**
* The V₂<sup>j</sup> coefficients.
* <p>
* Only the coefficients that use the Fourier index = 1 (i == 0) are computed as
* they are the only ones required.
* </p>
*/
private final double[] v2ij;
/**
* The current computed values for the ρ<sub>j</sub> and σ<sub>j</sub>
* coefficients.
*/
private final double[][] currentRhoSigmaj;
/**
* The C<sub>i</sub><sup>j</sup> and the S<sub>i</sub><sup>j</sup> Fourier
* coefficients.
*/
private final FourierCjSjCoefficients fourierCjSj;
/** The maximum value for j index. */
private final int jMax;
/**
* Constructor.
* @param currentRhoSigmaj the current computed values for the ρ<sub>j</sub> and
* σ<sub>j</sub> coefficients
* @param fourierCjSj the fourier coefficients C<sub>i</sub><sup>j</sup>
* and the S<sub>i</sub><sup>j</sup>
* @param jMax maximum value for j index
*/
UijVijCoefficients(final double[][] currentRhoSigmaj, final FourierCjSjCoefficients fourierCjSj,
final int jMax) {
this.currentRhoSigmaj = currentRhoSigmaj;
this.fourierCjSj = fourierCjSj;
this.jMax = jMax;
// initialize the internal arrays.
this.u1ij = new double[6][2 * jMax + 1];
this.v1ij = new double[6][2 * jMax + 1];
this.u2ij = new double[jMax + 1];
this.v2ij = new double[jMax + 1];
// compute the coefficients
computeU1V1Coefficients();
computeU2V2Coefficients();
}
/** Build the U₁<sup>j</sup> and V₁<sup>j</sup> coefficients. */
private void computeU1V1Coefficients() {
// generate the U₁<sup>j</sup> and V₁<sup>j</sup> coefficients
// for j >= 1
// also the U₁⁰ for Fourier index = 1 (i == 0) coefficient will be computed
u1ij[0][0] = 0;
for (int j = 1; j <= jMax; j++) {
// compute 1 / j
final double ooj = 1. / j;
for (int i = 0; i < 6; i++) {
// j is aready between 1 and J
u1ij[i][j] = fourierCjSj.getSij(i, j);
v1ij[i][j] = fourierCjSj.getCij(i, j);
// 1 - δ<sub>1j</sub> is 1 for all j > 1
if (j > 1) {
// k starts with 1 because j-J is less than or equal to 0
for (int kIndex = 1; kIndex <= j - 1; kIndex++) {
// C<sub>i</sub><sup>j-k</sup> * σ<sub>k</sub> +
// S<sub>i</sub><sup>j-k</sup> * ρ<sub>k</sub>
u1ij[i][j] += fourierCjSj.getCij(i, j - kIndex) * currentRhoSigmaj[1][kIndex] +
fourierCjSj.getSij(i, j - kIndex) * currentRhoSigmaj[0][kIndex];
// C<sub>i</sub><sup>j-k</sup> * ρ<sub>k</sub> -
// S<sub>i</sub><sup>j-k</sup> * σ<sub>k</sub>
v1ij[i][j] += fourierCjSj.getCij(i, j - kIndex) * currentRhoSigmaj[0][kIndex] -
fourierCjSj.getSij(i, j - kIndex) * currentRhoSigmaj[1][kIndex];
}
}
// since j must be between 1 and J-1 and is already between 1 and J
// the following sum is skiped only for j = jMax
if (j != jMax) {
for (int kIndex = 1; kIndex <= jMax - j; kIndex++) {
// -C<sub>i</sub><sup>j+k</sup> * σ<sub>k</sub> +
// S<sub>i</sub><sup>j+k</sup> * ρ<sub>k</sub>
u1ij[i][j] += -fourierCjSj.getCij(i, j + kIndex) * currentRhoSigmaj[1][kIndex] +
fourierCjSj.getSij(i, j + kIndex) * currentRhoSigmaj[0][kIndex];
// C<sub>i</sub><sup>j+k</sup> * ρ<sub>k</sub> +
// S<sub>i</sub><sup>j+k</sup> * σ<sub>k</sub>
v1ij[i][j] += fourierCjSj.getCij(i, j + kIndex) * currentRhoSigmaj[0][kIndex] +
fourierCjSj.getSij(i, j + kIndex) * currentRhoSigmaj[1][kIndex];
}
}
for (int kIndex = 1; kIndex <= jMax; kIndex++) {
// C<sub>i</sub><sup>k</sup> * σ<sub>j+k</sub> -
// S<sub>i</sub><sup>k</sup> * ρ<sub>j+k</sub>
u1ij[i][j] += -fourierCjSj.getCij(i, kIndex) * currentRhoSigmaj[1][j + kIndex] -
fourierCjSj.getSij(i, kIndex) * currentRhoSigmaj[0][j + kIndex];
// C<sub>i</sub><sup>k</sup> * ρ<sub>j+k</sub> +
// S<sub>i</sub><sup>k</sup> * σ<sub>j+k</sub>
v1ij[i][j] += fourierCjSj.getCij(i, kIndex) * currentRhoSigmaj[0][j + kIndex] +
fourierCjSj.getSij(i, kIndex) * currentRhoSigmaj[1][j + kIndex];
}
// divide by 1 / j
u1ij[i][j] *= -ooj;
v1ij[i][j] *= ooj;
// if index = 1 (i == 0) add the computed terms to U₁⁰
if (i == 0) {
// - (U₁<sup>j</sup> * ρ<sub>j</sub> + V₁<sup>j</sup> * σ<sub>j</sub>
u1ij[0][0] += -u1ij[0][j] * currentRhoSigmaj[0][j] - v1ij[0][j] * currentRhoSigmaj[1][j];
}
}
}
// Terms with j > jMax are required only when computing the coefficients
// U₂<sup>j</sup> and V₂<sup>j</sup>
// and those coefficients are only required for Fourier index = 1 (i == 0).
for (int j = jMax + 1; j <= 2 * jMax; j++) {
// compute 1 / j
final double ooj = 1. / j;
// the value of i is 0
u1ij[0][j] = 0.;
v1ij[0][j] = 0.;
// k starts from j-J as it is always greater than or equal to 1
for (int kIndex = j - jMax; kIndex <= j - 1; kIndex++) {
// C<sub>i</sub><sup>j-k</sup> * σ<sub>k</sub> +
// S<sub>i</sub><sup>j-k</sup> * ρ<sub>k</sub>
u1ij[0][j] += fourierCjSj.getCij(0, j - kIndex) * currentRhoSigmaj[1][kIndex] +
fourierCjSj.getSij(0, j - kIndex) * currentRhoSigmaj[0][kIndex];
// C<sub>i</sub><sup>j-k</sup> * ρ<sub>k</sub> -
// S<sub>i</sub><sup>j-k</sup> * σ<sub>k</sub>
v1ij[0][j] += fourierCjSj.getCij(0, j - kIndex) * currentRhoSigmaj[0][kIndex] -
fourierCjSj.getSij(0, j - kIndex) * currentRhoSigmaj[1][kIndex];
}
for (int kIndex = 1; kIndex <= jMax; kIndex++) {
// C<sub>i</sub><sup>k</sup> * σ<sub>j+k</sub> -
// S<sub>i</sub><sup>k</sup> * ρ<sub>j+k</sub>
u1ij[0][j] += -fourierCjSj.getCij(0, kIndex) * currentRhoSigmaj[1][j + kIndex] -
fourierCjSj.getSij(0, kIndex) * currentRhoSigmaj[0][j + kIndex];
// C<sub>i</sub><sup>k</sup> * ρ<sub>j+k</sub> +
// S<sub>i</sub><sup>k</sup> * σ<sub>j+k</sub>
v1ij[0][j] += fourierCjSj.getCij(0, kIndex) * currentRhoSigmaj[0][j + kIndex] +
fourierCjSj.getSij(0, kIndex) * currentRhoSigmaj[1][j + kIndex];
}
// divide by 1 / j
u1ij[0][j] *= -ooj;
v1ij[0][j] *= ooj;
}
}
/**
* Build the U₁<sup>j</sup> and V₁<sup>j</sup> coefficients.
* <p>
* Only the coefficients for Fourier index = 1 (i == 0) are required.
* </p>
*/
private void computeU2V2Coefficients() {
for (int j = 1; j <= jMax; j++) {
// compute 1 / j
final double ooj = 1. / j;
// only the values for i == 0 are computed
u2ij[j] = v1ij[0][j];
v2ij[j] = u1ij[0][j];
// 1 - δ<sub>1j</sub> is 1 for all j > 1
if (j > 1) {
for (int l = 1; l <= j - 1; l++) {
// U₁<sup>j-l</sup> * σ<sub>l</sub> +
// V₁<sup>j-l</sup> * ρ<sub>l</sub>
u2ij[j] += u1ij[0][j - l] * currentRhoSigmaj[1][l] + v1ij[0][j - l] * currentRhoSigmaj[0][l];
// U₁<sup>j-l</sup> * ρ<sub>l</sub> -
// V₁<sup>j-l</sup> * σ<sub>l</sub>
v2ij[j] += u1ij[0][j - l] * currentRhoSigmaj[0][l] - v1ij[0][j - l] * currentRhoSigmaj[1][l];
}
}
for (int l = 1; l <= jMax; l++) {
// -U₁<sup>j+l</sup> * σ<sub>l</sub> +
// U₁<sup>l</sup> * σ<sub>j+l</sub> +
// V₁<sup>j+l</sup> * ρ<sub>l</sub> -
// V₁<sup>l</sup> * ρ<sub>j+l</sub>
u2ij[j] += -u1ij[0][j + l] * currentRhoSigmaj[1][l] + u1ij[0][l] * currentRhoSigmaj[1][j + l] +
v1ij[0][j + l] * currentRhoSigmaj[0][l] - v1ij[0][l] * currentRhoSigmaj[0][j + l];
// U₁<sup>j+l</sup> * ρ<sub>l</sub> +
// U₁<sup>l</sup> * ρ<sub>j+l</sub> +
// V₁<sup>j+l</sup> * σ<sub>l</sub> +
// V₁<sup>l</sup> * σ<sub>j+l</sub>
u2ij[j] += u1ij[0][j + l] * currentRhoSigmaj[0][l] + u1ij[0][l] * currentRhoSigmaj[0][j + l] +
v1ij[0][j + l] * currentRhoSigmaj[1][l] + v1ij[0][l] * currentRhoSigmaj[1][j + l];
}
// divide by 1 / j
u2ij[j] *= -ooj;
v2ij[j] *= ooj;
}
}
/**
* Get the coefficient U₁<sup>j</sup> for Fourier index i.
*
* @param j j index
* @param i Fourier index (starts at 0)
* @return the coefficient U₁<sup>j</sup> for the given Fourier index i
*/
public double getU1(final int j, final int i) {
return u1ij[i][j];
}
/**
* Get the coefficient V₁<sup>j</sup> for Fourier index i.
*
* @param j j index
* @param i Fourier index (starts at 0)
* @return the coefficient V₁<sup>j</sup> for the given Fourier index i
*/
public double getV1(final int j, final int i) {
return v1ij[i][j];
}
/**
* Get the coefficient U₂<sup>j</sup> for Fourier index = 1 (i == 0).
*
* @param j j index
* @return the coefficient U₂<sup>j</sup> for Fourier index = 1 (i == 0)
*/
public double getU2(final int j) {
return u2ij[j];
}
/**
* Get the coefficient V₂<sup>j</sup> for Fourier index = 1 (i == 0).
*
* @param j j index
* @return the coefficient V₂<sup>j</sup> for Fourier index = 1 (i == 0)
*/
public double getV2(final int j) {
return v2ij[j];
}
}
/**
* The U<sub>i</sub><sup>j</sup> and V<sub>i</sub><sup>j</sup> coefficients
* described by equations 2.5.3-(21) and 2.5.3-(22) from Danielson.
* <p>
* The index i takes only the values 1 and 2<br>
* For U only the index 0 for j is used.
* </p>
*
* @author Petre Bazavan
* @author Lucian Barbulescu
* @param <T> type of the field elements
*/
protected static class FieldUijVijCoefficients<T extends CalculusFieldElement<T>> {
/**
* The U₁<sup>j</sup> coefficients.
* <p>
* The first index identifies the Fourier coefficients used<br>
* Those coefficients are computed for all Fourier C<sub>i</sub><sup>j</sup> and
* S<sub>i</sub><sup>j</sup><br>
* The only exception is when j = 0 when only the coefficient for fourier index
* = 1 (i == 0) is needed.<br>
* Also, for fourier index = 1 (i == 0), the coefficients up to 2 * jMax are
* computed, because are required to compute the coefficients U₂<sup>j</sup>
* </p>
*/
private final T[][] u1ij;
/**
* The V₁<sup>j</sup> coefficients.
* <p>
* The first index identifies the Fourier coefficients used<br>
* Those coefficients are computed for all Fourier C<sub>i</sub><sup>j</sup> and
* S<sub>i</sub><sup>j</sup><br>
* for fourier index = 1 (i == 0), the coefficients up to 2 * jMax are computed,
* because are required to compute the coefficients V₂<sup>j</sup>
* </p>
*/
private final T[][] v1ij;
/**
* The U₂<sup>j</sup> coefficients.
* <p>
* Only the coefficients that use the Fourier index = 1 (i == 0) are computed as
* they are the only ones required.
* </p>
*/
private final T[] u2ij;
/**
* The V₂<sup>j</sup> coefficients.
* <p>
* Only the coefficients that use the Fourier index = 1 (i == 0) are computed as
* they are the only ones required.
* </p>
*/
private final T[] v2ij;
/**
* The current computed values for the ρ<sub>j</sub> and σ<sub>j</sub>
* coefficients.
*/
private final T[][] currentRhoSigmaj;
/**
* The C<sub>i</sub><sup>j</sup> and the S<sub>i</sub><sup>j</sup> Fourier
* coefficients.
*/
private final FieldFourierCjSjCoefficients<T> fourierCjSj;
/** The maximum value for j index. */
private final int jMax;
/**
* Constructor.
* @param currentRhoSigmaj the current computed values for the ρ<sub>j</sub> and
* σ<sub>j</sub> coefficients
* @param fourierCjSj the fourier coefficients C<sub>i</sub><sup>j</sup>
* and the S<sub>i</sub><sup>j</sup>
* @param jMax maximum value for j index
* @param field field used by default
*/
FieldUijVijCoefficients(final T[][] currentRhoSigmaj, final FieldFourierCjSjCoefficients<T> fourierCjSj,
final int jMax, final Field<T> field) {
this.currentRhoSigmaj = currentRhoSigmaj;
this.fourierCjSj = fourierCjSj;
this.jMax = jMax;
// initialize the internal arrays.
this.u1ij = MathArrays.buildArray(field, 6, 2 * jMax + 1);
this.v1ij = MathArrays.buildArray(field, 6, 2 * jMax + 1);
this.u2ij = MathArrays.buildArray(field, jMax + 1);
this.v2ij = MathArrays.buildArray(field, jMax + 1);
// compute the coefficients
computeU1V1Coefficients(field);
computeU2V2Coefficients();
}
/**
* Build the U₁<sup>j</sup> and V₁<sup>j</sup> coefficients.
* @param field field used by default
*/
private void computeU1V1Coefficients(final Field<T> field) {
// Zero
final T zero = field.getZero();
// generate the U₁<sup>j</sup> and V₁<sup>j</sup> coefficients
// for j >= 1
// also the U₁⁰ for Fourier index = 1 (i == 0) coefficient will be computed
u1ij[0][0] = zero;
for (int j = 1; j <= jMax; j++) {
// compute 1 / j
final double ooj = 1. / j;
for (int i = 0; i < 6; i++) {
// j is aready between 1 and J
u1ij[i][j] = fourierCjSj.getSij(i, j);
v1ij[i][j] = fourierCjSj.getCij(i, j);
// 1 - δ<sub>1j</sub> is 1 for all j > 1
if (j > 1) {
// k starts with 1 because j-J is less than or equal to 0
for (int kIndex = 1; kIndex <= j - 1; kIndex++) {
// C<sub>i</sub><sup>j-k</sup> * σ<sub>k</sub> +
// S<sub>i</sub><sup>j-k</sup> * ρ<sub>k</sub>
u1ij[i][j] = u1ij[i][j]
.add(fourierCjSj.getCij(i, j - kIndex).multiply(currentRhoSigmaj[1][kIndex]).add(
fourierCjSj.getSij(i, j - kIndex).multiply(currentRhoSigmaj[0][kIndex])));
// C<sub>i</sub><sup>j-k</sup> * ρ<sub>k</sub> -
// S<sub>i</sub><sup>j-k</sup> * σ<sub>k</sub>
v1ij[i][j] = v1ij[i][j].add(
fourierCjSj.getCij(i, j - kIndex).multiply(currentRhoSigmaj[0][kIndex]).subtract(
fourierCjSj.getSij(i, j - kIndex).multiply(currentRhoSigmaj[1][kIndex])));
}
}
// since j must be between 1 and J-1 and is already between 1 and J
// the following sum is skiped only for j = jMax
if (j != jMax) {
for (int kIndex = 1; kIndex <= jMax - j; kIndex++) {
// -C<sub>i</sub><sup>j+k</sup> * σ<sub>k</sub> +
// S<sub>i</sub><sup>j+k</sup> * ρ<sub>k</sub>
u1ij[i][j] = u1ij[i][j].add(fourierCjSj.getCij(i, j + kIndex).negate()
.multiply(currentRhoSigmaj[1][kIndex])
.add(fourierCjSj.getSij(i, j + kIndex).multiply(currentRhoSigmaj[0][kIndex])));
// C<sub>i</sub><sup>j+k</sup> * ρ<sub>k</sub> +
// S<sub>i</sub><sup>j+k</sup> * σ<sub>k</sub>
v1ij[i][j] = v1ij[i][j]
.add(fourierCjSj.getCij(i, j + kIndex).multiply(currentRhoSigmaj[0][kIndex]).add(
fourierCjSj.getSij(i, j + kIndex).multiply(currentRhoSigmaj[1][kIndex])));
}
}
for (int kIndex = 1; kIndex <= jMax; kIndex++) {
// C<sub>i</sub><sup>k</sup> * σ<sub>j+k</sub> -
// S<sub>i</sub><sup>k</sup> * ρ<sub>j+k</sub>
u1ij[i][j] = u1ij[i][j].add(fourierCjSj.getCij(i, kIndex).negate()
.multiply(currentRhoSigmaj[1][j + kIndex])
.subtract(fourierCjSj.getSij(i, kIndex).multiply(currentRhoSigmaj[0][j + kIndex])));
// C<sub>i</sub><sup>k</sup> * ρ<sub>j+k</sub> +
// S<sub>i</sub><sup>k</sup> * σ<sub>j+k</sub>
v1ij[i][j] = v1ij[i][j]
.add(fourierCjSj.getCij(i, kIndex).multiply(currentRhoSigmaj[0][j + kIndex])
.add(fourierCjSj.getSij(i, kIndex).multiply(currentRhoSigmaj[1][j + kIndex])));
}
// divide by 1 / j
u1ij[i][j] = u1ij[i][j].multiply(-ooj);
v1ij[i][j] = v1ij[i][j].multiply(ooj);
// if index = 1 (i == 0) add the computed terms to U₁⁰
if (i == 0) {
// - (U₁<sup>j</sup> * ρ<sub>j</sub> + V₁<sup>j</sup> * σ<sub>j</sub>
u1ij[0][0] = u1ij[0][0].add(u1ij[0][j].negate().multiply(currentRhoSigmaj[0][j])
.subtract(v1ij[0][j].multiply(currentRhoSigmaj[1][j])));
}
}
}
// Terms with j > jMax are required only when computing the coefficients
// U₂<sup>j</sup> and V₂<sup>j</sup>
// and those coefficients are only required for Fourier index = 1 (i == 0).
for (int j = jMax + 1; j <= 2 * jMax; j++) {
// compute 1 / j
final double ooj = 1. / j;
// the value of i is 0
u1ij[0][j] = zero;
v1ij[0][j] = zero;
// k starts from j-J as it is always greater than or equal to 1
for (int kIndex = j - jMax; kIndex <= j - 1; kIndex++) {
// C<sub>i</sub><sup>j-k</sup> * σ<sub>k</sub> +
// S<sub>i</sub><sup>j-k</sup> * ρ<sub>k</sub>
u1ij[0][j] = u1ij[0][j].add(fourierCjSj.getCij(0, j - kIndex).multiply(currentRhoSigmaj[1][kIndex])
.add(fourierCjSj.getSij(0, j - kIndex).multiply(currentRhoSigmaj[0][kIndex])));
// C<sub>i</sub><sup>j-k</sup> * ρ<sub>k</sub> -
// S<sub>i</sub><sup>j-k</sup> * σ<sub>k</sub>
v1ij[0][j] = v1ij[0][j].add(fourierCjSj.getCij(0, j - kIndex).multiply(currentRhoSigmaj[0][kIndex])
.subtract(fourierCjSj.getSij(0, j - kIndex).multiply(currentRhoSigmaj[1][kIndex])));
}
for (int kIndex = 1; kIndex <= jMax; kIndex++) {
// C<sub>i</sub><sup>k</sup> * σ<sub>j+k</sub> -
// S<sub>i</sub><sup>k</sup> * ρ<sub>j+k</sub>
u1ij[0][j] = u1ij[0][j]
.add(fourierCjSj.getCij(0, kIndex).negate().multiply(currentRhoSigmaj[1][j + kIndex])
.subtract(fourierCjSj.getSij(0, kIndex).multiply(currentRhoSigmaj[0][j + kIndex])));
// C<sub>i</sub><sup>k</sup> * ρ<sub>j+k</sub> +
// S<sub>i</sub><sup>k</sup> * σ<sub>j+k</sub>
v1ij[0][j] = v1ij[0][j].add(fourierCjSj.getCij(0, kIndex).multiply(currentRhoSigmaj[0][j + kIndex])
.add(fourierCjSj.getSij(0, kIndex).multiply(currentRhoSigmaj[1][j + kIndex])));
}
// divide by 1 / j
u1ij[0][j] = u1ij[0][j].multiply(-ooj);
v1ij[0][j] = v1ij[0][j].multiply(ooj);
}
}
/**
* Build the U₁<sup>j</sup> and V₁<sup>j</sup> coefficients.
* <p>
* Only the coefficients for Fourier index = 1 (i == 0) are required.
* </p>
*/
private void computeU2V2Coefficients() {
for (int j = 1; j <= jMax; j++) {
// compute 1 / j
final double ooj = 1. / j;
// only the values for i == 0 are computed
u2ij[j] = v1ij[0][j];
v2ij[j] = u1ij[0][j];
// 1 - δ<sub>1j</sub> is 1 for all j > 1
if (j > 1) {
for (int l = 1; l <= j - 1; l++) {
// U₁<sup>j-l</sup> * σ<sub>l</sub> +
// V₁<sup>j-l</sup> * ρ<sub>l</sub>
u2ij[j] = u2ij[j].add(u1ij[0][j - l].multiply(currentRhoSigmaj[1][l])
.add(v1ij[0][j - l].multiply(currentRhoSigmaj[0][l])));
// U₁<sup>j-l</sup> * ρ<sub>l</sub> -
// V₁<sup>j-l</sup> * σ<sub>l</sub>
v2ij[j] = v2ij[j].add(u1ij[0][j - l].multiply(currentRhoSigmaj[0][l])
.subtract(v1ij[0][j - l].multiply(currentRhoSigmaj[1][l])));
}
}
for (int l = 1; l <= jMax; l++) {
// -U₁<sup>j+l</sup> * σ<sub>l</sub> +
// U₁<sup>l</sup> * σ<sub>j+l</sub> +
// V₁<sup>j+l</sup> * ρ<sub>l</sub> -
// V₁<sup>l</sup> * ρ<sub>j+l</sub>
u2ij[j] = u2ij[j].add(u1ij[0][j + l].negate().multiply(currentRhoSigmaj[1][l])
.add(u1ij[0][l].multiply(currentRhoSigmaj[1][j + l]))
.add(v1ij[0][j + l].multiply(currentRhoSigmaj[0][l]))
.subtract(v1ij[0][l].multiply(currentRhoSigmaj[0][j + l])));
// U₁<sup>j+l</sup> * ρ<sub>l</sub> +
// U₁<sup>l</sup> * ρ<sub>j+l</sub> +
// V₁<sup>j+l</sup> * σ<sub>l</sub> +
// V₁<sup>l</sup> * σ<sub>j+l</sub>
u2ij[j] = u2ij[j].add(u1ij[0][j + l].multiply(currentRhoSigmaj[0][l])
.add(u1ij[0][l].multiply(currentRhoSigmaj[0][j + l]))
.add(v1ij[0][j + l].multiply(currentRhoSigmaj[1][l]))
.add(v1ij[0][l].multiply(currentRhoSigmaj[1][j + l])));
}
// divide by 1 / j
u2ij[j] = u2ij[j].multiply(-ooj);
v2ij[j] = v2ij[j].multiply(ooj);
}
}
/**
* Get the coefficient U₁<sup>j</sup> for Fourier index i.
*
* @param j j index
* @param i Fourier index (starts at 0)
* @return the coefficient U₁<sup>j</sup> for the given Fourier index i
*/
public T getU1(final int j, final int i) {
return u1ij[i][j];
}
/**
* Get the coefficient V₁<sup>j</sup> for Fourier index i.
*
* @param j j index
* @param i Fourier index (starts at 0)
* @return the coefficient V₁<sup>j</sup> for the given Fourier index i
*/
public T getV1(final int j, final int i) {
return v1ij[i][j];
}
/**
* Get the coefficient U₂<sup>j</sup> for Fourier index = 1 (i == 0).
*
* @param j j index
* @return the coefficient U₂<sup>j</sup> for Fourier index = 1 (i == 0)
*/
public T getU2(final int j) {
return u2ij[j];
}
/**
* Get the coefficient V₂<sup>j</sup> for Fourier index = 1 (i == 0).
*
* @param j j index
* @return the coefficient V₂<sup>j</sup> for Fourier index = 1 (i == 0)
*/
public T getV2(final int j) {
return v2ij[j];
}
}
/** Coefficients valid for one time slot. */
protected static class Slot {
/**
* The coefficients D<sub>i</sub><sup>j</sup>.
* <p>
* Only for j = 1 and j = 2 the coefficients are not 0. <br>
* i corresponds to the equinoctial element, as follows: - i=0 for a <br/>
* - i=1 for k <br/>
* - i=2 for h <br/>
* - i=3 for q <br/>
* - i=4 for p <br/>
* - i=5 for λ <br/>
* </p>
*/
private final ShortPeriodicsInterpolatedCoefficient[] dij;
/**
* The coefficients C<sub>i</sub><sup>j</sup>.
* <p>
* The index order is cij[j][i] <br/>
* i corresponds to the equinoctial element, as follows: <br/>
* - i=0 for a <br/>
* - i=1 for k <br/>
* - i=2 for h <br/>
* - i=3 for q <br/>
* - i=4 for p <br/>
* - i=5 for λ <br/>
* </p>
*/
private final ShortPeriodicsInterpolatedCoefficient[] cij;
/**
* The coefficients S<sub>i</sub><sup>j</sup>.
* <p>
* The index order is sij[j][i] <br/>
* i corresponds to the equinoctial element, as follows: <br/>
* - i=0 for a <br/>
* - i=1 for k <br/>
* - i=2 for h <br/>
* - i=3 for q <br/>
* - i=4 for p <br/>
* - i=5 for λ <br/>
* </p>
*/
private final ShortPeriodicsInterpolatedCoefficient[] sij;
/**
* Simple constructor.
* @param jMax maximum value for j index
* @param interpolationPoints number of points used in the interpolation process
*/
Slot(final int jMax, final int interpolationPoints) {
dij = new ShortPeriodicsInterpolatedCoefficient[3];
cij = new ShortPeriodicsInterpolatedCoefficient[jMax + 1];
sij = new ShortPeriodicsInterpolatedCoefficient[jMax + 1];
// Initialize the C<sub>i</sub><sup>j</sup>, S<sub>i</sub><sup>j</sup> and
// D<sub>i</sub><sup>j</sup> coefficients
for (int j = 0; j <= jMax; j++) {
cij[j] = new ShortPeriodicsInterpolatedCoefficient(interpolationPoints);
if (j > 0) {
sij[j] = new ShortPeriodicsInterpolatedCoefficient(interpolationPoints);
}
// Initialize only the non-zero D<sub>i</sub><sup>j</sup> coefficients
if (j == 1 || j == 2) {
dij[j] = new ShortPeriodicsInterpolatedCoefficient(interpolationPoints);
}
}
}
}
/** Coefficients valid for one time slot.
* @param <T> type of the field elements
*/
protected static class FieldSlot<T extends CalculusFieldElement<T>> {
/**
* The coefficients D<sub>i</sub><sup>j</sup>.
* <p>
* Only for j = 1 and j = 2 the coefficients are not 0. <br>
* i corresponds to the equinoctial element, as follows: - i=0 for a <br/>
* - i=1 for k <br/>
* - i=2 for h <br/>
* - i=3 for q <br/>
* - i=4 for p <br/>
* - i=5 for λ <br/>
* </p>
*/
private final FieldShortPeriodicsInterpolatedCoefficient<T>[] dij;
/**
* The coefficients C<sub>i</sub><sup>j</sup>.
* <p>
* The index order is cij[j][i] <br/>
* i corresponds to the equinoctial element, as follows: <br/>
* - i=0 for a <br/>
* - i=1 for k <br/>
* - i=2 for h <br/>
* - i=3 for q <br/>
* - i=4 for p <br/>
* - i=5 for λ <br/>
* </p>
*/
private final FieldShortPeriodicsInterpolatedCoefficient<T>[] cij;
/**
* The coefficients S<sub>i</sub><sup>j</sup>.
* <p>
* The index order is sij[j][i] <br/>
* i corresponds to the equinoctial element, as follows: <br/>
* - i=0 for a <br/>
* - i=1 for k <br/>
* - i=2 for h <br/>
* - i=3 for q <br/>
* - i=4 for p <br/>
* - i=5 for λ <br/>
* </p>
*/
private final FieldShortPeriodicsInterpolatedCoefficient<T>[] sij;
/**
* Simple constructor.
* @param jMax maximum value for j index
* @param interpolationPoints number of points used in the interpolation process
*/
@SuppressWarnings("unchecked")
FieldSlot(final int jMax, final int interpolationPoints) {
dij = (FieldShortPeriodicsInterpolatedCoefficient<T>[]) Array
.newInstance(FieldShortPeriodicsInterpolatedCoefficient.class, 3);
cij = (FieldShortPeriodicsInterpolatedCoefficient<T>[]) Array
.newInstance(FieldShortPeriodicsInterpolatedCoefficient.class, jMax + 1);
sij = (FieldShortPeriodicsInterpolatedCoefficient<T>[]) Array
.newInstance(FieldShortPeriodicsInterpolatedCoefficient.class, jMax + 1);
// Initialize the C<sub>i</sub><sup>j</sup>, S<sub>i</sub><sup>j</sup> and
// D<sub>i</sub><sup>j</sup> coefficients
for (int j = 0; j <= jMax; j++) {
cij[j] = new FieldShortPeriodicsInterpolatedCoefficient<>(interpolationPoints);
if (j > 0) {
sij[j] = new FieldShortPeriodicsInterpolatedCoefficient<>(interpolationPoints);
}
// Initialize only the non-zero D<sub>i</sub><sup>j</sup> coefficients
if (j == 1 || j == 2) {
dij[j] = new FieldShortPeriodicsInterpolatedCoefficient<>(interpolationPoints);
}
}
}
}
}