AbstractBatchLSModel.java

  1. /* Copyright 2002-2021 CS GROUP
  2.  * Licensed to CS GROUP (CS) under one or more
  3.  * contributor license agreements.  See the NOTICE file distributed with
  4.  * this work for additional information regarding copyright ownership.
  5.  * CS licenses this file to You under the Apache License, Version 2.0
  6.  * (the "License"); you may not use this file except in compliance with
  7.  * the License.  You may obtain a copy of the License at
  8.  *
  9.  *   http://www.apache.org/licenses/LICENSE-2.0
  10.  *
  11.  * Unless required by applicable law or agreed to in writing, software
  12.  * distributed under the License is distributed on an "AS IS" BASIS,
  13.  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  14.  * See the License for the specific language governing permissions and
  15.  * limitations under the License.
  16.  */
  17. package org.orekit.estimation.leastsquares;

  19. import java.util.ArrayList;
  20. import java.util.Arrays;
  21. import java.util.Collections;
  22. import java.util.HashMap;
  23. import java.util.IdentityHashMap;
  24. import java.util.List;
  25. import java.util.Map;

  27. import org.hipparchus.linear.Array2DRowRealMatrix;
  28. import org.hipparchus.linear.ArrayRealVector;
  29. import org.hipparchus.linear.MatrixUtils;
  30. import org.hipparchus.linear.RealMatrix;
  31. import org.hipparchus.linear.RealVector;
  32. import org.hipparchus.optim.nonlinear.vector.leastsquares.MultivariateJacobianFunction;
  33. import org.hipparchus.util.FastMath;
  34. import org.hipparchus.util.Incrementor;
  35. import org.hipparchus.util.Pair;
  36. import org.orekit.estimation.measurements.EstimatedMeasurement;
  37. import org.orekit.estimation.measurements.ObservedMeasurement;
  38. import org.orekit.orbits.Orbit;
  39. import org.orekit.propagation.Propagator;
  40. import org.orekit.propagation.PropagatorsParallelizer;
  41. import org.orekit.propagation.SpacecraftState;
  42. import org.orekit.propagation.conversion.OrbitDeterminationPropagatorBuilder;
  43. import org.orekit.propagation.integration.AbstractJacobiansMapper;
  44. import org.orekit.propagation.sampling.MultiSatStepHandler;
  45. import org.orekit.time.AbsoluteDate;
  46. import org.orekit.time.ChronologicalComparator;
  47. import org.orekit.utils.ParameterDriver;
  48. import org.orekit.utils.ParameterDriversList;
  49. import org.orekit.utils.ParameterDriversList.DelegatingDriver;

  51. /** Bridge between {@link ObservedMeasurement measurements} and {@link
  52.  * org.hipparchus.optim.nonlinear.vector.leastsquares.LeastSquaresProblem
  53.  * least squares problems}.
  54.  * @author Luc Maisonobe
  55.  * @author Bryan Cazabonne
  56.  * @author Thomas Paulet
  57.  * @since 11.0
  58.  */
  59. public abstract class AbstractBatchLSModel implements MultivariateJacobianFunction {

  61.     /** Builders for propagators. */
  62.     private final OrbitDeterminationPropagatorBuilder[] builders;

  64.     /** Array of each builder's selected propagation drivers. */
  65.     private final ParameterDriversList[] estimatedPropagationParameters;

  67.     /** Estimated measurements parameters. */
  68.     private final ParameterDriversList estimatedMeasurementsParameters;

  70.     /** Measurements. */
  71.     private final List<ObservedMeasurement<?>> measurements;

  73.     /** Start columns for each estimated orbit. */
  74.     private final int[] orbitsStartColumns;

  76.     /** End columns for each estimated orbit. */
  77.     private final int[] orbitsEndColumns;

  79.     /** Map for propagation parameters columns. */
  80.     private final Map<String, Integer> propagationParameterColumns;

  82.     /** Map for measurements parameters columns. */
  83.     private final Map<String, Integer> measurementParameterColumns;

  85.     /** Last evaluations. */
  86.     private final Map<ObservedMeasurement<?>, EstimatedMeasurement<?>> evaluations;

  88.     /** Observer to be notified at orbit changes. */
  89.     private final ModelObserver observer;

  91.     /** Counter for the evaluations. */
  92.     private Incrementor evaluationsCounter;

  94.     /** Counter for the iterations. */
  95.     private Incrementor iterationsCounter;

  97.     /** Date of the first enabled measurement. */
  98.     private AbsoluteDate firstDate;

  100.     /** Date of the last enabled measurement. */
  101.     private AbsoluteDate lastDate;

  103.     /** Boolean indicating if the propagation will go forward or backward. */
  104.     private final boolean forwardPropagation;

  106.     /** Model function value. */
  107.     private RealVector value;

  109.     /** Mappers for extracting Jacobians from integrated states. */
  110.     private final AbstractJacobiansMapper[] mappers;

  112.     /** Model function Jacobian. */
  113.     private RealMatrix jacobian;

  115.     /**
  116.      * Constructor.
  117.      * @param propagatorBuilders builders to use for propagation
  118.      * @param measurements measurements
  119.      * @param estimatedMeasurementsParameters estimated measurements parameters
  120.      * @param mappers jacobian mappers
  121.      * @param observer observer to be notified at model calls
  122.      */
  123.     public AbstractBatchLSModel(final OrbitDeterminationPropagatorBuilder[] propagatorBuilders,
  124.                                 final List<ObservedMeasurement<?>> measurements,
  125.                                 final ParameterDriversList estimatedMeasurementsParameters,
  126.                                 final AbstractJacobiansMapper[] mappers,
  127.                                 final ModelObserver observer) {

  129.         this.builders                        = propagatorBuilders.clone();
  130.         this.measurements                    = measurements;
  131.         this.estimatedMeasurementsParameters = estimatedMeasurementsParameters;
  132.         this.measurementParameterColumns     = new HashMap<>(estimatedMeasurementsParameters.getDrivers().size());
  133.         this.estimatedPropagationParameters  = new ParameterDriversList[builders.length];
  134.         this.evaluations                     = new IdentityHashMap<>(measurements.size());
  135.         this.observer                        = observer;
  136.         this.mappers                         = mappers.clone();

  138.         // allocate vector and matrix
  139.         int rows = 0;
  140.         for (final ObservedMeasurement<?> measurement : measurements) {
  141.             rows += measurement.getDimension();
  142.         }

  144.         this.orbitsStartColumns = new int[builders.length];
  145.         this.orbitsEndColumns   = new int[builders.length];
  146.         int columns = 0;
  147.         for (int i = 0; i < builders.length; ++i) {
  148.             this.orbitsStartColumns[i] = columns;
  149.             for (final ParameterDriver driver : builders[i].getOrbitalParametersDrivers().getDrivers()) {
  150.                 if (driver.isSelected()) {
  151.                     ++columns;
  152.                 }
  153.             }
  154.             this.orbitsEndColumns[i] = columns;
  155.         }

  157.         // Gather all the propagation drivers names in a list
  158.         final List<String> estimatedPropagationParametersNames = new ArrayList<>();
  159.         for (int i = 0; i < builders.length; ++i) {
  160.             // The index i in array estimatedPropagationParameters (attribute of the class) is populated
  161.             // when the first call to getSelectedPropagationDriversForBuilder(i) is made
  162.             for (final DelegatingDriver delegating : getSelectedPropagationDriversForBuilder(i).getDrivers()) {
  163.                 final String driverName = delegating.getName();
  164.                 // Add the driver name if it has not been added yet
  165.                 if (!estimatedPropagationParametersNames.contains(driverName)) {
  166.                     estimatedPropagationParametersNames.add(driverName);
  167.                 }
  168.             }
  169.         }
  170.         // Populate the map of propagation drivers' columns and update the total number of columns
  171.         propagationParameterColumns = new HashMap<>(estimatedPropagationParametersNames.size());
  172.         for (final String driverName : estimatedPropagationParametersNames) {
  173.             propagationParameterColumns.put(driverName, columns);
  174.             ++columns;
  175.         }

  177.         // Populate the map of measurement drivers' columns and update the total number of columns
  178.         for (final ParameterDriver parameter : estimatedMeasurementsParameters.getDrivers()) {
  179.             measurementParameterColumns.put(parameter.getName(), columns);
  180.             ++columns;
  181.         }

  183.         // Initialize point and value
  184.         value    = new ArrayRealVector(rows);
  185.         jacobian = MatrixUtils.createRealMatrix(rows, columns);

  187.         // Decide whether the propagation will be done forward or backward.
  188.         // Minimize the duration between first measurement treated and orbit determination date
  189.         // Propagator builder number 0 holds the reference date for orbit determination
  190.         final AbsoluteDate refDate = builders[0].getInitialOrbitDate();

  192.         // Sort the measurement list chronologically
  193.         measurements.sort(new ChronologicalComparator());
  194.         firstDate = measurements.get(0).getDate();
  195.         lastDate  = measurements.get(measurements.size() - 1).getDate();

  197.         // Decide the direction of propagation
  198.         if (FastMath.abs(refDate.durationFrom(firstDate)) <= FastMath.abs(refDate.durationFrom(lastDate))) {
  199.             // Propagate forward from firstDate
  200.             forwardPropagation = true;
  201.         } else {
  202.             // Propagate backward from lastDate
  203.             forwardPropagation = false;
  204.         }
  205.     }

  207.     /** Set the counter for evaluations.
  208.      * @param evaluationsCounter counter for evaluations
  209.      */
  210.     public void setEvaluationsCounter(final Incrementor evaluationsCounter) {
  211.         this.evaluationsCounter = evaluationsCounter;
  212.     }

  214.     /** Set the counter for iterations.
  215.      * @param iterationsCounter counter for iterations
  216.      */
  217.     public void setIterationsCounter(final Incrementor iterationsCounter) {
  218.         this.iterationsCounter = iterationsCounter;
  219.     }

  221.     /** Return the forward propagation flag.
  222.      * @return the forward propagation flag
  223.      */
  224.     public boolean isForwardPropagation() {
  225.         return forwardPropagation;
  226.     }

  228.     /** Configure the propagator to compute derivatives.
  229.      * @param propagators {@link Propagator} to configure
  230.      * @return mapper for this propagator
  231.      */
  232.     protected abstract AbstractJacobiansMapper configureDerivatives(Propagator propagators);

  234.     /** Configure the current estimated orbits.
  235.      * <p>
  236.      * For DSST orbit determination, short period derivatives are also calculated.
  237.      * </p>
  238.      * @param mapper Jacobian mapper
  239.      * @param propagator the orbit propagator
  240.      * @return the current estimated orbits
  241.      */
  242.     protected abstract Orbit configureOrbits(AbstractJacobiansMapper mapper, Propagator propagator);

  244.     /** {@inheritDoc} */
  245.     @Override
  246.     public Pair<RealVector, RealMatrix> value(final RealVector point) {

  248.         // Set up the propagators parallelizer
  249.         final Propagator[] propagators = createPropagators(point);
  250.         final Orbit[] orbits = new Orbit[propagators.length];
  251.         for (int i = 0; i < propagators.length; ++i) {
  252.             mappers[i] = configureDerivatives(propagators[i]);
  253.             orbits[i]  = configureOrbits(mappers[i], propagators[i]);
  254.         }
  255.         final PropagatorsParallelizer parallelizer =
  256.                         new PropagatorsParallelizer(Arrays.asList(propagators), configureMeasurements(point));

  258.         // Reset value and Jacobian
  259.         evaluations.clear();
  260.         value.set(0.0);
  261.         for (int i = 0; i < jacobian.getRowDimension(); ++i) {
  262.             for (int j = 0; j < jacobian.getColumnDimension(); ++j) {
  263.                 jacobian.setEntry(i, j, 0.0);
  264.             }
  265.         }

  267.         // Run the propagation, gathering residuals on the fly
  268.         if (isForwardPropagation()) {
  269.             // Propagate forward from firstDate
  270.             parallelizer.propagate(firstDate.shiftedBy(-1.0), lastDate.shiftedBy(+1.0));
  271.         } else {
  272.             // Propagate backward from lastDate
  273.             parallelizer.propagate(lastDate.shiftedBy(+1.0), firstDate.shiftedBy(-1.0));
  274.         }

  276.         observer.modelCalled(orbits, evaluations);

  278.         return new Pair<RealVector, RealMatrix>(value, jacobian);

  280.     }

  282.     /** Get the selected propagation drivers for a propagatorBuilder.
  283.      * @param iBuilder index of the builder in the builders' array
  284.      * @return the list of selected propagation drivers for propagatorBuilder of index iBuilder
  285.      */
  286.     public ParameterDriversList getSelectedPropagationDriversForBuilder(final int iBuilder) {

  288.         // Lazy evaluation, create the list only if it hasn't been created yet
  289.         if (estimatedPropagationParameters[iBuilder] == null) {

  291.             // Gather the drivers
  292.             final ParameterDriversList selectedPropagationDrivers = new ParameterDriversList();
  293.             for (final DelegatingDriver delegating : builders[iBuilder].getPropagationParametersDrivers().getDrivers()) {
  294.                 if (delegating.isSelected()) {
  295.                     for (final ParameterDriver driver : delegating.getRawDrivers()) {
  296.                         selectedPropagationDrivers.add(driver);
  297.                     }
  298.                 }
  299.             }

  301.             // List of propagation drivers are sorted in the BatchLSEstimator class.
  302.             // Hence we need to sort this list so the parameters' indexes match
  303.             selectedPropagationDrivers.sort();

  305.             // Add the list of selected propagation drivers to the array
  306.             estimatedPropagationParameters[iBuilder] = selectedPropagationDrivers;
  307.         }
  308.         return estimatedPropagationParameters[iBuilder];
  309.     }

  311.     /** Create the propagators and parameters corresponding to an evaluation point.
  312.      * @param point evaluation point
  313.      * @return an array of new propagators
  314.      */
  315.     public Propagator[] createPropagators(final RealVector point) {

  317.         final Propagator[] propagators = new Propagator[builders.length];

  319.         // Set up the propagators
  320.         for (int i = 0; i < builders.length; ++i) {

  322.             // Get the number of selected orbital drivers in the builder
  323.             final int nbOrb    = orbitsEndColumns[i] - orbitsStartColumns[i];

  325.             // Get the list of selected propagation drivers in the builder and its size
  326.             final ParameterDriversList selectedPropagationDrivers = getSelectedPropagationDriversForBuilder(i);
  327.             final int nbParams = selectedPropagationDrivers.getNbParams();

  329.             // Init the array of normalized parameters for the builder
  330.             final double[] propagatorArray = new double[nbOrb + nbParams];

  332.             // Add the orbital drivers normalized values
  333.             for (int j = 0; j < nbOrb; ++j) {
  334.                 propagatorArray[j] = point.getEntry(orbitsStartColumns[i] + j);
  335.             }

  337.             // Add the propagation drivers normalized values
  338.             for (int j = 0; j < nbParams; ++j) {
  339.                 propagatorArray[nbOrb + j] =
  340.                                 point.getEntry(propagationParameterColumns.get(selectedPropagationDrivers.getDrivers().get(j).getName()));
  341.             }

  343.             // Build the propagator
  344.             propagators[i] = builders[i].buildPropagator(propagatorArray);
  345.         }

  347.         return propagators;

  349.     }

  351.     /** Fetch a measurement that was evaluated during propagation.
  352.      * @param index index of the measurement first component
  353.      * @param evaluation measurement evaluation
  354.      */
  355.     public void fetchEvaluatedMeasurement(final int index, final EstimatedMeasurement<?> evaluation) {

  357.         // States and observed measurement
  358.         final SpacecraftState[]      evaluationStates    = evaluation.getStates();
  359.         final ObservedMeasurement<?> observedMeasurement = evaluation.getObservedMeasurement();

  361.         // compute weighted residuals
  362.         evaluations.put(observedMeasurement, evaluation);
  363.         if (evaluation.getStatus() == EstimatedMeasurement.Status.REJECTED) {
  364.             return;
  365.         }

  367.         final double[] evaluated = evaluation.getEstimatedValue();
  368.         final double[] observed  = observedMeasurement.getObservedValue();
  369.         final double[] sigma     = observedMeasurement.getTheoreticalStandardDeviation();
  370.         final double[] weight    = evaluation.getObservedMeasurement().getBaseWeight();
  371.         for (int i = 0; i < evaluated.length; ++i) {
  372.             value.setEntry(index + i, weight[i] * (evaluated[i] - observed[i]) / sigma[i]);
  373.         }

  375.         for (int k = 0; k < evaluationStates.length; ++k) {

  377.             final int p = observedMeasurement.getSatellites().get(k).getPropagatorIndex();

  379.             // partial derivatives of the current Cartesian coordinates with respect to current orbital state
  380.             final double[][] aCY = new double[6][6];
  381.             final Orbit currentOrbit = evaluationStates[k].getOrbit();
  382.             currentOrbit.getJacobianWrtParameters(builders[p].getPositionAngle(), aCY);
  383.             final RealMatrix dCdY = new Array2DRowRealMatrix(aCY, false);

  385.             // Jacobian of the measurement with respect to current orbital state
  386.             final RealMatrix dMdC = new Array2DRowRealMatrix(evaluation.getStateDerivatives(k), false);
  387.             final RealMatrix dMdY = dMdC.multiply(dCdY);

  389.             // compute derivatives used by analytical orbit determination methods
  390.             mappers[p].analyticalDerivatives(evaluationStates[k]);

  392.             // Jacobian of the measurement with respect to initial orbital state
  393.             final double[][] aYY0 = new double[6][6];
  394.             mappers[p].getStateJacobian(evaluationStates[k], aYY0);
  395.             final RealMatrix dYdY0 = new Array2DRowRealMatrix(aYY0, false);
  396.             final RealMatrix dMdY0 = dMdY.multiply(dYdY0);
  397.             for (int i = 0; i < dMdY0.getRowDimension(); ++i) {
  398.                 int jOrb = orbitsStartColumns[p];
  399.                 for (int j = 0; j < dMdY0.getColumnDimension(); ++j) {
  400.                     final ParameterDriver driver = builders[p].getOrbitalParametersDrivers().getDrivers().get(j);
  401.                     if (driver.isSelected()) {
  402.                         jacobian.setEntry(index + i, jOrb++,
  403.                                           weight[i] * dMdY0.getEntry(i, j) / sigma[i] * driver.getScale());
  404.                     }
  405.                 }
  406.             }

  408.             // Jacobian of the measurement with respect to propagation parameters
  409.             final ParameterDriversList selectedPropagationDrivers = getSelectedPropagationDriversForBuilder(p);
  410.             final int nbParams = selectedPropagationDrivers.getNbParams();
  411.             if ( nbParams > 0) {
  412.                 final double[][] aYPp  = new double[6][nbParams];
  413.                 mappers[p].getParametersJacobian(evaluationStates[k], aYPp);
  414.                 final RealMatrix dYdPp = new Array2DRowRealMatrix(aYPp, false);
  415.                 final RealMatrix dMdPp = dMdY.multiply(dYdPp);
  416.                 for (int i = 0; i < dMdPp.getRowDimension(); ++i) {
  417.                     for (int j = 0; j < nbParams; ++j) {
  418.                         final ParameterDriver delegating = selectedPropagationDrivers.getDrivers().get(j);
  419.                         jacobian.addToEntry(index + i, propagationParameterColumns.get(delegating.getName()),
  420.                                             weight[i] * dMdPp.getEntry(i, j) / sigma[i] * delegating.getScale());
  421.                     }
  422.                 }
  423.             }
  424.         }
  425.         // Jacobian of the measurement with respect to measurements parameters
  426.         for (final ParameterDriver driver : observedMeasurement.getParametersDrivers()) {
  427.             if (driver.isSelected()) {
  428.                 final double[] aMPm = evaluation.getParameterDerivatives(driver);
  429.                 for (int i = 0; i < aMPm.length; ++i) {
  430.                     jacobian.setEntry(index + i, measurementParameterColumns.get(driver.getName()),
  431.                                       weight[i] * aMPm[i] / sigma[i] * driver.getScale());
  432.                 }
  433.             }
  434.         }

  436.     }

  438.     /** Configure the multi-satellites handler to handle measurements.
  439.      * @param point evaluation point
  440.      * @return multi-satellites handler to handle measurements
  441.      */
  442.     private MultiSatStepHandler configureMeasurements(final RealVector point) {

  444.         // Set up the measurement parameters
  445.         int index = orbitsEndColumns[builders.length - 1] + propagationParameterColumns.size();
  446.         for (final ParameterDriver parameter : estimatedMeasurementsParameters.getDrivers()) {
  447.             parameter.setNormalizedValue(point.getEntry(index++));
  448.         }

  450.         // Set up measurements handler
  451.         final List<PreCompensation> precompensated = new ArrayList<>();
  452.         for (final ObservedMeasurement<?> measurement : measurements) {
  453.             if (measurement.isEnabled()) {
  454.                 precompensated.add(new PreCompensation(measurement, evaluations.get(measurement)));
  455.             }
  456.         }
  457.         precompensated.sort(new ChronologicalComparator());

  459.         // Assign first and last date
  460.         firstDate = precompensated.get(0).getDate();
  461.         lastDate  = precompensated.get(precompensated.size() - 1).getDate();

  463.         // Reverse the list in case of backward propagation
  464.         if (!forwardPropagation) {
  465.             Collections.reverse(precompensated);
  466.         }

  468.         return new MeasurementHandler(this, precompensated);

  470.     }

  472.     /** Get the iterations count.
  473.      * @return iterations count
  474.      */
  475.     public int getIterationsCount() {
  476.         return iterationsCounter.getCount();
  477.     }

  479.     /** Get the evaluations count.
  480.      * @return evaluations count
  481.      */
  482.     public int getEvaluationsCount() {
  483.         return evaluationsCounter.getCount();
  484.     }

  486. }
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