Rugged.java
/* Copyright 2013-2019 CS Systèmes d'Information
* Licensed to CS Systèmes d'Information (CS) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership.
* CS licenses this file to You under the Apache License, Version 2.0
* (the "License"); you may not use this file except in compliance with
* the License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package org.orekit.rugged.api;
import java.util.Collection;
import java.util.HashMap;
import java.util.Map;
import org.hipparchus.analysis.differentiation.DerivativeStructure;
import org.hipparchus.geometry.euclidean.threed.FieldVector3D;
import org.hipparchus.geometry.euclidean.threed.Vector3D;
import org.hipparchus.util.FastMath;
import org.orekit.bodies.GeodeticPoint;
import org.orekit.frames.Transform;
import org.orekit.rugged.errors.DumpManager;
import org.orekit.rugged.errors.RuggedException;
import org.orekit.rugged.errors.RuggedInternalError;
import org.orekit.rugged.errors.RuggedMessages;
import org.orekit.rugged.intersection.IntersectionAlgorithm;
import org.orekit.rugged.linesensor.LineSensor;
import org.orekit.rugged.linesensor.SensorMeanPlaneCrossing;
import org.orekit.rugged.linesensor.SensorPixel;
import org.orekit.rugged.linesensor.SensorPixelCrossing;
import org.orekit.rugged.refraction.AtmosphericRefraction;
import org.orekit.rugged.utils.DSGenerator;
import org.orekit.rugged.utils.ExtendedEllipsoid;
import org.orekit.rugged.utils.NormalizedGeodeticPoint;
import org.orekit.rugged.utils.SpacecraftToObservedBody;
import org.orekit.time.AbsoluteDate;
import org.orekit.utils.Constants;
import org.orekit.utils.PVCoordinates;
/** Main class of Rugged library API.
* @see RuggedBuilder
* @author Luc Maisonobe
* @author Guylaine Prat
* @author Jonathan Guinet
* @author Lucie LabatAllee
*/
public class Rugged {
/** Accuracy to use in the first stage of inverse location.
* <p>
* This accuracy is only used to locate the point within one
* pixel, hence there is no point in choosing a too small value here.
* </p>
*/
private static final double COARSE_INVERSE_LOCATION_ACCURACY = 0.01;
/** Maximum number of evaluations for crossing algorithms. */
private static final int MAX_EVAL = 50;
/** Margin for computation of inverse location with atmospheric refraction correction. */
private static final double INVLOC_MARGIN = 0.8;
/** Threshold for pixel convergence in fixed point method
* (for inverse location with atmospheric refraction correction). */
private static final double PIXEL_CV_THRESHOLD = 1.e-4;
/** Threshold for line convergence in fixed point method
* (for inverse location with atmospheric refraction correction). */
private static final double LINE_CV_THRESHOLD = 1.e-4;
/** Reference ellipsoid. */
private final ExtendedEllipsoid ellipsoid;
/** Converter between spacecraft and body. */
private final SpacecraftToObservedBody scToBody;
/** Sensors. */
private final Map<String, LineSensor> sensors;
/** Mean plane crossing finders. */
private final Map<String, SensorMeanPlaneCrossing> finders;
/** DEM intersection algorithm. */
private final IntersectionAlgorithm algorithm;
/** Flag for light time correction. */
private boolean lightTimeCorrection;
/** Flag for aberration of light correction. */
private boolean aberrationOfLightCorrection;
/** Rugged name. */
private final String name;
/** Atmospheric refraction for line of sight correction. */
private AtmosphericRefraction atmosphericRefraction;
/** Build a configured instance.
* <p>
* By default, the instance performs both light time correction (which refers
* to ground point motion with respect to inertial frame) and aberration of
* light correction (which refers to spacecraft proper velocity). Explicit calls
* to {@link #setLightTimeCorrection(boolean) setLightTimeCorrection}
* and {@link #setAberrationOfLightCorrection(boolean) setAberrationOfLightCorrection}
* can be made after construction if these phenomena should not be corrected.
* </p>
* @param algorithm algorithm to use for Digital Elevation Model intersection
* @param ellipsoid f reference ellipsoid
* @param lightTimeCorrection if true, the light travel time between ground
* @param aberrationOfLightCorrection if true, the aberration of light
* is corrected for more accurate location
* and spacecraft is compensated for more accurate location
* @param atmosphericRefraction the atmospheric refraction model to be used for more accurate location
* @param scToBody transforms interpolator
* @param sensors sensors
* @param name Rugged name
*/
Rugged(final IntersectionAlgorithm algorithm, final ExtendedEllipsoid ellipsoid, final boolean lightTimeCorrection,
final boolean aberrationOfLightCorrection, final AtmosphericRefraction atmosphericRefraction,
final SpacecraftToObservedBody scToBody, final Collection<LineSensor> sensors, final String name) {
// space reference
this.ellipsoid = ellipsoid;
// orbit/attitude to body converter
this.scToBody = scToBody;
// intersection algorithm
this.algorithm = algorithm;
// Rugged name
// @since 2.0
this.name = name;
this.sensors = new HashMap<String, LineSensor>();
for (final LineSensor s : sensors) {
this.sensors.put(s.getName(), s);
}
this.finders = new HashMap<String, SensorMeanPlaneCrossing>();
this.lightTimeCorrection = lightTimeCorrection;
this.aberrationOfLightCorrection = aberrationOfLightCorrection;
this.atmosphericRefraction = atmosphericRefraction;
}
/** Get the Rugged name.
* @return Rugged name
* @since 2.0
*/
public String getName() {
return name;
}
/** Get the DEM intersection algorithm.
* @return DEM intersection algorithm
*/
public IntersectionAlgorithm getAlgorithm() {
return algorithm;
}
/** Get flag for light time correction.
* @return true if the light time between ground and spacecraft is
* compensated for more accurate location
*/
public boolean isLightTimeCorrected() {
return lightTimeCorrection;
}
/** Get flag for aberration of light correction.
* @return true if the aberration of light time is corrected
* for more accurate location
*/
public boolean isAberrationOfLightCorrected() {
return aberrationOfLightCorrection;
}
/** Get the atmospheric refraction model.
* @return atmospheric refraction model
* @since 2.0
*/
public AtmosphericRefraction getRefractionCorrection() {
return atmosphericRefraction;
}
/** Get the line sensors.
* @return line sensors
*/
public Collection<LineSensor> getLineSensors() {
return sensors.values();
}
/** Get the start of search time span.
* @return start of search time span
*/
public AbsoluteDate getMinDate() {
return scToBody.getMinDate();
}
/** Get the end of search time span.
* @return end of search time span
*/
public AbsoluteDate getMaxDate() {
return scToBody.getMaxDate();
}
/** Check if a date is in the supported range.
* <p>
* The support range is given by the {@code minDate} and
* {@code maxDate} construction parameters, with an {@code
* overshootTolerance} margin accepted (i.e. a date slightly
* before {@code minDate} or slightly after {@code maxDate}
* will be considered in range if the overshoot does not exceed
* the tolerance set at construction).
* </p>
* @param date date to check
* @return true if date is in the supported range
*/
public boolean isInRange(final AbsoluteDate date) {
return scToBody.isInRange(date);
}
/** Get the observed body ellipsoid.
* @return observed body ellipsoid
*/
public ExtendedEllipsoid getEllipsoid() {
return ellipsoid;
}
/** Direct location of a sensor line.
* @param sensorName name of the line sensor
* @param lineNumber number of the line to localize on ground
* @return ground position of all pixels of the specified sensor line
*/
public GeodeticPoint[] directLocation(final String sensorName, final double lineNumber) {
final LineSensor sensor = getLineSensor(sensorName);
final Vector3D sensorPosition = sensor.getPosition();
final AbsoluteDate date = sensor.getDate(lineNumber);
// Compute the transform for the date
// from spacecraft to inertial
final Transform scToInert = scToBody.getScToInertial(date);
// from inertial to body
final Transform inertToBody = scToBody.getInertialToBody(date);
// Compute spacecraft velocity in inertial frame
final Vector3D spacecraftVelocity = scToInert.transformPVCoordinates(PVCoordinates.ZERO).getVelocity();
// Compute sensor position in inertial frame
// TBN: for simplicity, due to the size of sensor, we consider each pixel to be at sensor position
final Vector3D pInert = scToInert.transformPosition(sensorPosition);
// Compute location of each pixel
final GeodeticPoint[] gp = new GeodeticPoint[sensor.getNbPixels()];
for (int i = 0; i < sensor.getNbPixels(); ++i) {
final Vector3D los = sensor.getLOS(date, i);
DumpManager.dumpDirectLocation(date, sensorPosition, los, lightTimeCorrection,
aberrationOfLightCorrection, atmosphericRefraction != null);
// compute the line of sight in inertial frame (without correction)
final Vector3D obsLInert = scToInert.transformVector(los);
final Vector3D lInert;
if (aberrationOfLightCorrection) {
// apply aberration of light correction on LOS
lInert = applyAberrationOfLightCorrection(obsLInert, spacecraftVelocity);
} else {
// don't apply aberration of light correction on LOS
lInert = obsLInert;
}
if (lightTimeCorrection) {
// compute DEM intersection with light time correction
// TBN: for simplicity, due to the size of sensor, we consider each pixel to be at sensor position
gp[i] = computeWithLightTimeCorrection(date, sensorPosition, los, scToInert, inertToBody, pInert, lInert);
} else {
// compute DEM intersection without light time correction
final Vector3D pBody = inertToBody.transformPosition(pInert);
final Vector3D lBody = inertToBody.transformVector(lInert);
gp[i] = algorithm.refineIntersection(ellipsoid, pBody, lBody,
algorithm.intersection(ellipsoid, pBody, lBody));
}
// compute with atmospheric refraction correction if necessary
if (atmosphericRefraction != null && atmosphericRefraction.mustBeComputed()) {
// apply atmospheric refraction correction
final Vector3D pBody = inertToBody.transformPosition(pInert);
final Vector3D lBody = inertToBody.transformVector(lInert);
gp[i] = atmosphericRefraction.applyCorrection(pBody, lBody, (NormalizedGeodeticPoint) gp[i], algorithm);
}
DumpManager.dumpDirectLocationResult(gp[i]);
}
return gp;
}
/** Direct location of a single line-of-sight.
* @param date date of the location
* @param sensorPosition sensor position in spacecraft frame. For simplicity, due to the size of sensor,
* we consider each pixel to be at sensor position
* @param los normalized line-of-sight in spacecraft frame
* @return ground position of intersection point between specified los and ground
*/
public GeodeticPoint directLocation(final AbsoluteDate date, final Vector3D sensorPosition, final Vector3D los) {
DumpManager.dumpDirectLocation(date, sensorPosition, los, lightTimeCorrection, aberrationOfLightCorrection,
atmosphericRefraction != null);
// Compute the transforms for the date
// from spacecraft to inertial
final Transform scToInert = scToBody.getScToInertial(date);
// from inertial to body
final Transform inertToBody = scToBody.getInertialToBody(date);
// Compute spacecraft velocity in inertial frame
final Vector3D spacecraftVelocity = scToInert.transformPVCoordinates(PVCoordinates.ZERO).getVelocity();
// Compute sensor position in inertial frame
// TBN: for simplicity, due to the size of sensor, we consider each pixel to be at sensor position
final Vector3D pInert = scToInert.transformPosition(sensorPosition);
// Compute the line of sight in inertial frame (without correction)
final Vector3D obsLInert = scToInert.transformVector(los);
final Vector3D lInert;
if (aberrationOfLightCorrection) {
// apply aberration of light correction on LOS
lInert = applyAberrationOfLightCorrection(obsLInert, spacecraftVelocity);
} else {
// don't apply aberration of light correction on LOS
lInert = obsLInert;
}
// Compute ground location of specified pixel
final NormalizedGeodeticPoint gp;
if (lightTimeCorrection) {
// compute DEM intersection with light time correction
// TBN: for simplicity, due to the size of sensor, we consider each pixel to be at sensor position
gp = computeWithLightTimeCorrection(date, sensorPosition, los, scToInert, inertToBody, pInert, lInert);
} else {
// compute DEM intersection without light time correction
final Vector3D pBody = inertToBody.transformPosition(pInert);
final Vector3D lBody = inertToBody.transformVector(lInert);
gp = algorithm.refineIntersection(ellipsoid, pBody, lBody,
algorithm.intersection(ellipsoid, pBody, lBody));
}
NormalizedGeodeticPoint result = gp;
// compute the ground location with atmospheric correction if asked for
if (atmosphericRefraction != null && atmosphericRefraction.mustBeComputed()) {
// apply atmospheric refraction correction
final Vector3D pBody = inertToBody.transformPosition(pInert);
final Vector3D lBody = inertToBody.transformVector(lInert);
result = atmosphericRefraction.applyCorrection(pBody, lBody, gp, algorithm);
} // end test on atmosphericRefraction != null
DumpManager.dumpDirectLocationResult(result);
return result;
}
/** Find the date at which sensor sees a ground point.
* <p>
* This method is a partial {@link #inverseLocation(String, GeodeticPoint, int, int) inverse location} focusing only on date.
* </p>
* <p>
* The point is given only by its latitude and longitude, the elevation is
* computed from the Digital Elevation Model.
* </p>
* <p>
* Note that for each sensor name, the {@code minLine} and {@code maxLine} settings
* are cached, because they induce costly frames computation. So these settings
* should not be tuned very finely and changed at each call, but should rather be
* a few thousand lines wide and refreshed only when needed. If for example an
* inverse location is roughly estimated to occur near line 53764 (for example
* using {@link org.orekit.rugged.utils.RoughVisibilityEstimator}), {@code minLine}
* and {@code maxLine} could be set for example to 50000 and 60000, which would
* be OK also if next line inverse location is expected to occur near line 53780,
* and next one ... The setting could be changed for example to 55000 and 65000 when
* an inverse location is expected to occur after 55750. Of course, these values
* are only an example and should be adjusted depending on mission needs.
* </p>
* @param sensorName name of the line sensor
* @param latitude ground point latitude (rad)
* @param longitude ground point longitude (rad)
* @param minLine minimum line number
* @param maxLine maximum line number
* @return date at which ground point is seen by line sensor
* @see #inverseLocation(String, double, double, int, int)
* @see org.orekit.rugged.utils.RoughVisibilityEstimator
*/
public AbsoluteDate dateLocation(final String sensorName,
final double latitude, final double longitude,
final int minLine, final int maxLine) {
final GeodeticPoint groundPoint =
new GeodeticPoint(latitude, longitude, algorithm.getElevation(latitude, longitude));
return dateLocation(sensorName, groundPoint, minLine, maxLine);
}
/** Find the date at which sensor sees a ground point.
* <p>
* This method is a partial {@link #inverseLocation(String,
* GeodeticPoint, int, int) inverse location} focusing only on date.
* </p>
* <p>
* Note that for each sensor name, the {@code minLine} and {@code maxLine} settings
* are cached, because they induce costly frames computation. So these settings
* should not be tuned very finely and changed at each call, but should rather be
* a few thousand lines wide and refreshed only when needed. If for example an
* inverse location is roughly estimated to occur near line 53764 (for example
* using {@link org.orekit.rugged.utils.RoughVisibilityEstimator}), {@code minLine}
* and {@code maxLine} could be set for example to 50000 and 60000, which would
* be OK also if next line inverse location is expected to occur near line 53780,
* and next one ... The setting could be changed for example to 55000 and 65000 when
* an inverse location is expected to occur after 55750. Of course, these values
* are only an example and should be adjusted depending on mission needs.
* </p>
* @param sensorName name of the line sensor
* @param point point to localize
* @param minLine minimum line number
* @param maxLine maximum line number
* @return date at which ground point is seen by line sensor
* @see #inverseLocation(String, GeodeticPoint, int, int)
* @see org.orekit.rugged.utils.RoughVisibilityEstimator
*/
public AbsoluteDate dateLocation(final String sensorName, final GeodeticPoint point,
final int minLine, final int maxLine) {
final LineSensor sensor = getLineSensor(sensorName);
final SensorMeanPlaneCrossing planeCrossing = getPlaneCrossing(sensorName, minLine, maxLine);
// find approximately the sensor line at which ground point crosses sensor mean plane
final Vector3D target = ellipsoid.transform(point);
final SensorMeanPlaneCrossing.CrossingResult crossingResult = planeCrossing.find(target);
if (crossingResult == null) {
// target is out of search interval
return null;
} else {
return sensor.getDate(crossingResult.getLine());
}
}
/** Inverse location of a ground point.
* <p>
* The point is given only by its latitude and longitude, the elevation is
* computed from the Digital Elevation Model.
* </p>
* <p>
* Note that for each sensor name, the {@code minLine} and {@code maxLine} settings
* are cached, because they induce costly frames computation. So these settings
* should not be tuned very finely and changed at each call, but should rather be
* a few thousand lines wide and refreshed only when needed. If for example an
* inverse location is roughly estimated to occur near line 53764 (for example
* using {@link org.orekit.rugged.utils.RoughVisibilityEstimator}), {@code minLine}
* and {@code maxLine} could be set for example to 50000 and 60000, which would
* be OK also if next line inverse location is expected to occur near line 53780,
* and next one ... The setting could be changed for example to 55000 and 65000 when
* an inverse location is expected to occur after 55750. Of course, these values
* are only an example and should be adjusted depending on mission needs.
* </p>
* @param sensorName name of the line sensor
* @param latitude ground point latitude (rad)
* @param longitude ground point longitude (rad)
* @param minLine minimum line number
* @param maxLine maximum line number
* @return sensor pixel seeing ground point, or null if ground point cannot
* be seen between the prescribed line numbers
* @see org.orekit.rugged.utils.RoughVisibilityEstimator
*/
public SensorPixel inverseLocation(final String sensorName,
final double latitude, final double longitude,
final int minLine, final int maxLine) {
final GeodeticPoint groundPoint = new GeodeticPoint(latitude, longitude, algorithm.getElevation(latitude, longitude));
return inverseLocation(sensorName, groundPoint, minLine, maxLine);
}
/** Inverse location of a point.
* <p>
* Note that for each sensor name, the {@code minLine} and {@code maxLine} settings
* are cached, because they induce costly frames computation. So these settings
* should not be tuned very finely and changed at each call, but should rather be
* a few thousand lines wide and refreshed only when needed. If for example an
* inverse location is roughly estimated to occur near line 53764 (for example
* using {@link org.orekit.rugged.utils.RoughVisibilityEstimator}), {@code minLine}
* and {@code maxLine} could be set for example to 50000 and 60000, which would
* be OK also if next line inverse location is expected to occur near line 53780,
* and next one ... The setting could be changed for example to 55000 and 65000 when
* an inverse location is expected to occur after 55750. Of course, these values
* are only an example and should be adjusted depending on mission needs.
* </p>
* @param sensorName name of the line sensor
* @param point geodetic point to localize
* @param minLine minimum line number where the search will be performed
* @param maxLine maximum line number where the search will be performed
* @return sensor pixel seeing point, or null if point cannot be seen between the
* prescribed line numbers
* @see #dateLocation(String, GeodeticPoint, int, int)
* @see org.orekit.rugged.utils.RoughVisibilityEstimator
*/
public SensorPixel inverseLocation(final String sensorName, final GeodeticPoint point,
final int minLine, final int maxLine) {
final LineSensor sensor = getLineSensor(sensorName);
DumpManager.dumpInverseLocation(sensor, point, ellipsoid, minLine, maxLine, lightTimeCorrection,
aberrationOfLightCorrection, atmosphericRefraction != null);
final SensorMeanPlaneCrossing planeCrossing = getPlaneCrossing(sensorName, minLine, maxLine);
DumpManager.dumpSensorMeanPlane(planeCrossing);
if (atmosphericRefraction == null || !atmosphericRefraction.mustBeComputed()) {
// Compute inverse location WITHOUT atmospheric refraction
return findSensorPixelWithoutAtmosphere(point, sensor, planeCrossing);
} else {
// Compute inverse location WITH atmospheric refraction
return findSensorPixelWithAtmosphere(point, sensor, minLine, maxLine);
}
}
/** Apply aberration of light correction (for direct location).
* @param spacecraftVelocity spacecraft velocity in inertial frame
* @param obsLInert line of sight in inertial frame
* @return line of sight with aberration of light correction
*/
private Vector3D applyAberrationOfLightCorrection(final Vector3D obsLInert, final Vector3D spacecraftVelocity) {
// As the spacecraft velocity is small with respect to speed of light,
// we use classical velocity addition and not relativistic velocity addition
// we look for a positive k such that: c * lInert + vsat = k * obsLInert
// with lInert normalized
final double a = obsLInert.getNormSq();
final double b = -Vector3D.dotProduct(obsLInert, spacecraftVelocity);
final double c = spacecraftVelocity.getNormSq() - Constants.SPEED_OF_LIGHT * Constants.SPEED_OF_LIGHT;
// a > 0 and c < 0
final double s = FastMath.sqrt(b * b - a * c);
// Only the k > 0 are kept as solutions (the solutions: -(s+b)/a and c/(s-b) are useless)
final double k = (b > 0) ? -c / (s + b) : (s - b) / a;
final Vector3D lInert = new Vector3D( k / Constants.SPEED_OF_LIGHT, obsLInert, -1.0 / Constants.SPEED_OF_LIGHT, spacecraftVelocity);
return lInert;
}
/** Compute the DEM intersection with light time correction.
* @param date date of the los
* @param sensorPosition sensor position in spacecraft frame
* @param los los in spacecraft frame
* @param scToInert transform for the date from spacecraft to inertial
* @param inertToBody transform for the date from inertial to body
* @param pInert sensor position in inertial frame
* @param lInert line of sight in inertial frame
* @return geodetic point with light time correction
*/
private NormalizedGeodeticPoint computeWithLightTimeCorrection(final AbsoluteDate date,
final Vector3D sensorPosition, final Vector3D los,
final Transform scToInert, final Transform inertToBody,
final Vector3D pInert, final Vector3D lInert) {
// compute the approximate transform between spacecraft and observed body
final Transform approximate = new Transform(date, scToInert, inertToBody);
final Vector3D sL = approximate.transformVector(los);
final Vector3D sP = approximate.transformPosition(sensorPosition);
final Vector3D eP1 = ellipsoid.transform(ellipsoid.pointOnGround(sP, sL, 0.0));
final double deltaT1 = eP1.distance(sP) / Constants.SPEED_OF_LIGHT;
final Transform shifted1 = inertToBody.shiftedBy(-deltaT1);
final NormalizedGeodeticPoint gp1 = algorithm.intersection(ellipsoid,
shifted1.transformPosition(pInert),
shifted1.transformVector(lInert));
final Vector3D eP2 = ellipsoid.transform(gp1);
final double deltaT2 = eP2.distance(sP) / Constants.SPEED_OF_LIGHT;
final Transform shifted2 = inertToBody.shiftedBy(-deltaT2);
return algorithm.refineIntersection(ellipsoid,
shifted2.transformPosition(pInert),
shifted2.transformVector(lInert),
gp1);
}
/**
* Find the sensor pixel WITHOUT atmospheric refraction correction.
* @param point geodetic point to localize
* @param sensor the line sensor
* @param planeCrossing the sensor mean plane crossing
* @return the sensor pixel crossing or null if cannot be found
* @since 2.1
*/
private SensorPixel findSensorPixelWithoutAtmosphere(final GeodeticPoint point,
final LineSensor sensor, final SensorMeanPlaneCrossing planeCrossing) {
// find approximately the sensor line at which ground point crosses sensor mean plane
final Vector3D target = ellipsoid.transform(point);
final SensorMeanPlaneCrossing.CrossingResult crossingResult = planeCrossing.find(target);
if (crossingResult == null) {
// target is out of search interval
return null;
}
// find approximately the pixel along this sensor line
final SensorPixelCrossing pixelCrossing =
new SensorPixelCrossing(sensor, planeCrossing.getMeanPlaneNormal(),
crossingResult.getTargetDirection(),
MAX_EVAL, COARSE_INVERSE_LOCATION_ACCURACY);
final double coarsePixel = pixelCrossing.locatePixel(crossingResult.getDate());
if (Double.isNaN(coarsePixel)) {
// target is out of search interval
return null;
}
// fix line by considering the closest pixel exact position and line-of-sight
// (this pixel might point towards a direction slightly above or below the mean sensor plane)
final int lowIndex = FastMath.max(0, FastMath.min(sensor.getNbPixels() - 2, (int) FastMath.floor(coarsePixel)));
final Vector3D lowLOS = sensor.getLOS(crossingResult.getDate(), lowIndex);
final Vector3D highLOS = sensor.getLOS(crossingResult.getDate(), lowIndex + 1);
final Vector3D localZ = Vector3D.crossProduct(lowLOS, highLOS).normalize();
final double beta = FastMath.acos(Vector3D.dotProduct(crossingResult.getTargetDirection(), localZ));
final double s = Vector3D.dotProduct(crossingResult.getTargetDirectionDerivative(), localZ);
final double betaDer = -s / FastMath.sqrt(1 - s * s);
final double deltaL = (0.5 * FastMath.PI - beta) / betaDer;
final double fixedLine = crossingResult.getLine() + deltaL;
final Vector3D fixedDirection = new Vector3D(1, crossingResult.getTargetDirection(),
deltaL, crossingResult.getTargetDirectionDerivative()).normalize();
// fix neighbouring pixels
final AbsoluteDate fixedDate = sensor.getDate(fixedLine);
final Vector3D fixedX = sensor.getLOS(fixedDate, lowIndex);
final Vector3D fixedZ = Vector3D.crossProduct(fixedX, sensor.getLOS(fixedDate, lowIndex + 1));
final Vector3D fixedY = Vector3D.crossProduct(fixedZ, fixedX);
// fix pixel
final double pixelWidth = FastMath.atan2(Vector3D.dotProduct(highLOS, fixedY),
Vector3D.dotProduct(highLOS, fixedX));
final double alpha = FastMath.atan2(Vector3D.dotProduct(fixedDirection, fixedY),
Vector3D.dotProduct(fixedDirection, fixedX));
final double fixedPixel = lowIndex + alpha / pixelWidth;
final SensorPixel result = new SensorPixel(fixedLine, fixedPixel);
DumpManager.dumpInverseLocationResult(result);
return result;
}
/**
* Find the sensor pixel WITH atmospheric refraction correction.
* @param point geodetic point to localize
* @param sensor the line sensor
* @param minLine minimum line number where the search will be performed
* @param maxLine maximum line number where the search will be performed
* @return the sensor pixel crossing or null if cannot be found
* @since 2.1
*/
private SensorPixel findSensorPixelWithAtmosphere(final GeodeticPoint point,
final LineSensor sensor, final int minLine, final int maxLine) {
// TBN: there is no direct way to compute the inverse location.
// The method is based on an interpolation grid associated with the fixed point method
final String sensorName = sensor.getName();
// Compute a correction grid (at sensor level)
// ===========================================
// Need to be computed only once for a given sensor (with the same minLine and maxLine)
if (atmosphericRefraction.getBifPixel() == null || atmosphericRefraction.getBifLine() == null || // lazy evaluation
(!atmosphericRefraction.isSameContext(sensorName, minLine, maxLine))) { // Must be recomputed if the context changed
// Definition of a regular grid (at sensor level)
atmosphericRefraction.configureCorrectionGrid(sensor, minLine, maxLine);
// Get the grid nodes
final int nbPixelGrid = atmosphericRefraction.getComputationParameters().getNbPixelGrid();
final int nbLineGrid = atmosphericRefraction.getComputationParameters().getNbLineGrid();
final double[] pixelGrid = atmosphericRefraction.getComputationParameters().getUgrid();
final double[] lineGrid = atmosphericRefraction.getComputationParameters().getVgrid();
// Computation, for the sensor grid, of the direct location WITH atmospheric refraction
// (full computation)
atmosphericRefraction.reactivateComputation();
final GeodeticPoint[][] geodeticGridWithAtmosphere = computeDirectLocOnGridWithAtmosphere(pixelGrid, lineGrid, sensor);
// pixelGrid and lineGrid are the nodes where the direct loc is computed WITH atmosphere
// Computation of the inverse location WITHOUT atmospheric refraction for the grid nodes
atmosphericRefraction.deactivateComputation();
final SensorPixel[][] sensorPixelGridInverseWithout = computeInverseLocOnGridWithoutAtmosphere(geodeticGridWithAtmosphere,
nbPixelGrid, nbLineGrid, sensor, minLine, maxLine);
atmosphericRefraction.reactivateComputation();
// Compute the grid correction functions (for pixel and line)
atmosphericRefraction.computeGridCorrectionFunctions(sensorPixelGridInverseWithout);
}
// Fixed point method
// ==================
// Initialization
// --------------
// Deactivate the dump because no need to keep intermediate computations of inverse loc (can be regenerate)
final Boolean wasSuspended = DumpManager.suspend();
// compute the sensor pixel on the desired ground point WITHOUT atmosphere
atmosphericRefraction.deactivateComputation();
final SensorPixel sp0 = inverseLocation(sensorName, point, minLine, maxLine);
atmosphericRefraction.reactivateComputation();
// Reactivate the dump
DumpManager.resume(wasSuspended);
if (sp0 == null) {
// In order for the dump to end nicely
DumpManager.endNicely();
// Impossible to find the point in the given min line and max line (without atmosphere)
throw new RuggedException(RuggedMessages.INVALID_RANGE_FOR_LINES, minLine, maxLine, "");
}
// set up the starting point of the fixed point method
final double pixel0 = sp0.getPixelNumber();
final double line0 = sp0.getLineNumber();
// Needed data for the dump
sensor.dumpRate(line0);
// Apply fixed point method until convergence in pixel and line
// ------------------------------------------------------------
// compute the first (pixel, line) value:
// initial sensor pixel value + correction due to atmosphere at this same sensor pixel
double corrPixelPrevious = pixel0 + atmosphericRefraction.getBifPixel().value(pixel0, line0);
double corrLinePrevious = line0 + atmosphericRefraction.getBifLine().value(pixel0, line0);
double deltaCorrPixel = Double.POSITIVE_INFINITY;
double deltaCorrLine = Double.POSITIVE_INFINITY;
while (deltaCorrPixel > PIXEL_CV_THRESHOLD && deltaCorrLine > LINE_CV_THRESHOLD) {
// Compute the current (pixel, line) value =
// initial sensor pixel value + correction due to atmosphere on the previous sensor pixel
final double corrPixelCurrent = pixel0 + atmosphericRefraction.getBifPixel().value(corrPixelPrevious, corrLinePrevious);
final double corrLineCurrent = line0 + atmosphericRefraction.getBifLine().value(corrPixelPrevious, corrLinePrevious);
// Compute the delta in pixel and line to check the convergence
deltaCorrPixel = FastMath.abs(corrPixelCurrent - corrPixelPrevious);
deltaCorrLine = FastMath.abs(corrLineCurrent - corrLinePrevious);
// Store the (pixel, line) for next loop
corrPixelPrevious = corrPixelCurrent;
corrLinePrevious = corrLineCurrent;
}
// The sensor pixel is found !
final SensorPixel sensorPixelWithAtmosphere = new SensorPixel(corrLinePrevious, corrPixelPrevious);
// Dump the found sensorPixel
DumpManager.dumpInverseLocationResult(sensorPixelWithAtmosphere);
return sensorPixelWithAtmosphere;
}
/** Compute the inverse location WITHOUT atmospheric refraction for the geodetic points
* associated to the sensor grid nodes.
* @param groundGridWithAtmosphere ground grid found for sensor grid nodes with atmosphere
* @param nbPixelGrid size of the pixel grid
* @param nbLineGrid size of the line grid
* @param sensor the line sensor
* @param minLine minimum line number where the search will be performed
* @param maxLine maximum line number where the search will be performed
* @return the sensor pixel grid computed without atmosphere
* @since 2.1
*/
private SensorPixel[][] computeInverseLocOnGridWithoutAtmosphere(final GeodeticPoint[][] groundGridWithAtmosphere,
final int nbPixelGrid, final int nbLineGrid,
final LineSensor sensor, final int minLine, final int maxLine) {
// Deactivate the dump because no need to keep intermediate computations of inverse loc (can be regenerate)
final Boolean wasSuspended = DumpManager.suspend();
final SensorPixel[][] sensorPixelGrid = new SensorPixel[nbPixelGrid][nbLineGrid];
final String sensorName = sensor.getName();
for (int uIndex = 0; uIndex < nbPixelGrid; uIndex++) {
for (int vIndex = 0; vIndex < nbLineGrid; vIndex++) {
// Check if the geodetic point exists
if (groundGridWithAtmosphere[uIndex][vIndex] != null) {
final GeodeticPoint groundPoint = groundGridWithAtmosphere[uIndex][vIndex];
final double currentLat = groundPoint.getLatitude();
final double currentLon = groundPoint.getLongitude();
try {
// Compute the inverse location for the current node
sensorPixelGrid[uIndex][vIndex] = inverseLocation(sensorName, currentLat, currentLon, minLine, maxLine);
} catch (RuggedException re) { // This should never happen
// In order for the dump to end nicely
DumpManager.endNicely();
throw new RuggedInternalError(re);
}
// Check if the pixel is inside the sensor (with a margin) OR if the inverse location was impossible (null result)
if ((sensorPixelGrid[uIndex][vIndex] != null &&
(sensorPixelGrid[uIndex][vIndex].getPixelNumber() < (-INVLOC_MARGIN) ||
sensorPixelGrid[uIndex][vIndex].getPixelNumber() > (INVLOC_MARGIN + sensor.getNbPixels() - 1))) ||
(sensorPixelGrid[uIndex][vIndex] == null) ) {
// In order for the dump to end nicely
DumpManager.endNicely();
// Impossible to find the point in the given min line
throw new RuggedException(RuggedMessages.INVALID_RANGE_FOR_LINES, minLine, maxLine, "");
}
} else { // groundGrid[uIndex][vIndex] == null: impossible to compute inverse loc because ground point not defined
sensorPixelGrid[uIndex][vIndex] = null;
} // groundGrid[uIndex][vIndex] != null
} // end loop vIndex
} // end loop uIndex
// Reactivate the dump
DumpManager.resume(wasSuspended);
// The sensor grid computed WITHOUT atmospheric refraction correction
return sensorPixelGrid;
}
/** Computation, for the sensor pixels grid, of the direct location WITH atmospheric refraction.
* (full computation)
* @param pixelGrid the pixel grid
* @param lineGrid the line grid
* @param sensor the line sensor
* @return the ground grid computed with atmosphere
* @since 2.1
*/
private GeodeticPoint[][] computeDirectLocOnGridWithAtmosphere(final double[] pixelGrid, final double[] lineGrid,
final LineSensor sensor) {
// Deactivate the dump because no need to keep intermediate computations of direct loc (can be regenerate)
final Boolean wasSuspended = DumpManager.suspend();
final int nbPixelGrid = pixelGrid.length;
final int nbLineGrid = lineGrid.length;
final GeodeticPoint[][] groundGridWithAtmosphere = new GeodeticPoint[nbPixelGrid][nbLineGrid];
final Vector3D sensorPosition = sensor.getPosition();
for (int uIndex = 0; uIndex < nbPixelGrid; uIndex++) {
final double pixelNumber = pixelGrid[uIndex];
for (int vIndex = 0; vIndex < nbLineGrid; vIndex++) {
final double lineNumber = lineGrid[vIndex];
final AbsoluteDate date = sensor.getDate(lineNumber);
final Vector3D los = sensor.getLOS(date, pixelNumber);
try {
// Compute the direct location for the current node
groundGridWithAtmosphere[uIndex][vIndex] = directLocation(date, sensorPosition, los);
} catch (RuggedException re) { // This should never happen
// In order for the dump to end nicely
DumpManager.endNicely();
throw new RuggedInternalError(re);
}
} // end loop vIndex
} // end loop uIndex
// Reactivate the dump
DumpManager.resume(wasSuspended);
// The ground grid computed WITH atmospheric refraction correction
return groundGridWithAtmosphere;
}
/** Compute distances between two line sensors.
* @param sensorA line sensor A
* @param dateA current date for sensor A
* @param pixelA pixel index for sensor A
* @param scToBodyA spacecraft to body transform for sensor A
* @param sensorB line sensor B
* @param dateB current date for sensor B
* @param pixelB pixel index for sensor B
* @return distances computed between LOS and to the ground
* @since 2.0
*/
public double[] distanceBetweenLOS(final LineSensor sensorA, final AbsoluteDate dateA, final double pixelA,
final SpacecraftToObservedBody scToBodyA,
final LineSensor sensorB, final AbsoluteDate dateB, final double pixelB) {
// Compute the approximate transform between spacecraft and observed body
// from Rugged instance A
final Transform scToInertA = scToBodyA.getScToInertial(dateA);
final Transform inertToBodyA = scToBodyA.getInertialToBody(dateA);
final Transform transformScToBodyA = new Transform(dateA, scToInertA, inertToBodyA);
// from (current) Rugged instance B
final Transform scToInertB = scToBody.getScToInertial(dateB);
final Transform inertToBodyB = scToBody.getInertialToBody(dateB);
final Transform transformScToBodyB = new Transform(dateB, scToInertB, inertToBodyB);
// Get sensors LOS into local frame
final Vector3D vALocal = sensorA.getLOS(dateA, pixelA);
final Vector3D vBLocal = sensorB.getLOS(dateB, pixelB);
// Position of sensors into local frame
final Vector3D sALocal = sensorA.getPosition(); // S_a : sensorA 's position
final Vector3D sBLocal = sensorB.getPosition(); // S_b : sensorB 's position
// Get sensors position and LOS into body frame
final Vector3D sA = transformScToBodyA.transformPosition(sALocal); // S_a : sensorA's position
final Vector3D vA = transformScToBodyA.transformVector(vALocal); // V_a : line of sight's vectorA
final Vector3D sB = transformScToBodyB.transformPosition(sBLocal); // S_b : sensorB's position
final Vector3D vB = transformScToBodyB.transformVector(vBLocal); // V_b : line of sight's vectorB
// Compute distance
final Vector3D vBase = sB.subtract(sA); // S_b - S_a
final double svA = Vector3D.dotProduct(vBase, vA); // SV_a = (S_b - S_a).V_a
final double svB = Vector3D.dotProduct(vBase, vB); // SV_b = (S_b - S_a).V_b
final double vAvB = Vector3D.dotProduct(vA, vB); // V_a.V_b
// Compute lambda_b = (SV_a * V_a.V_b - SV_b) / (1 - (V_a.V_b)²)
final double lambdaB = (svA * vAvB - svB) / (1 - vAvB * vAvB);
// Compute lambda_a = SV_a + lambdaB * V_a.V_b
final double lambdaA = svA + lambdaB * vAvB;
// Compute vector M_a = S_a + lambda_a * V_a
final Vector3D mA = sA.add(vA.scalarMultiply(lambdaA));
// Compute vector M_b = S_b + lambda_b * V_b
final Vector3D mB = sB.add(vB.scalarMultiply(lambdaB));
// Compute vector M_a -> M_B for which distance between LOS is minimum
final Vector3D vDistanceMin = mB.subtract(mA); // M_b - M_a
// Compute vector from mid point of vector M_a -> M_B to the ground (corresponds to minimum elevation)
final Vector3D midPoint = (mB.add(mA)).scalarMultiply(0.5);
// Get the euclidean norms to compute the minimum distances: between LOS and to the ground
final double[] distances = {vDistanceMin.getNorm(), midPoint.getNorm()};
return distances;
}
/** Compute distances between two line sensors with derivatives.
* @param sensorA line sensor A
* @param dateA current date for sensor A
* @param pixelA pixel index for sensor A
* @param scToBodyA spacecraftToBody transform for sensor A
* @param sensorB line sensor B
* @param dateB current date for sensor B
* @param pixelB pixel index for sensor B
* @param generator generator to use for building {@link DerivativeStructure} instances
* @return distances computed, with derivatives, between LOS and to the ground
* @see #distanceBetweenLOS(LineSensor, AbsoluteDate, double, SpacecraftToObservedBody, LineSensor, AbsoluteDate, double)
*/
public DerivativeStructure[] distanceBetweenLOSderivatives(
final LineSensor sensorA, final AbsoluteDate dateA, final double pixelA,
final SpacecraftToObservedBody scToBodyA,
final LineSensor sensorB, final AbsoluteDate dateB, final double pixelB,
final DSGenerator generator) {
// Compute the approximate transforms between spacecraft and observed body
// from Rugged instance A
final Transform scToInertA = scToBodyA.getScToInertial(dateA);
final Transform inertToBodyA = scToBodyA.getInertialToBody(dateA);
final Transform transformScToBodyA = new Transform(dateA, scToInertA, inertToBodyA);
// from (current) Rugged instance B
final Transform scToInertB = scToBody.getScToInertial(dateB);
final Transform inertToBodyB = scToBody.getInertialToBody(dateB);
final Transform transformScToBodyB = new Transform(dateB, scToInertB, inertToBodyB);
// Get sensors LOS into local frame
final FieldVector3D<DerivativeStructure> vALocal = sensorA.getLOSDerivatives(dateA, pixelA, generator);
final FieldVector3D<DerivativeStructure> vBLocal = sensorB.getLOSDerivatives(dateB, pixelB, generator);
// Get sensors LOS into body frame
final FieldVector3D<DerivativeStructure> vA = transformScToBodyA.transformVector(vALocal); // V_a : line of sight's vectorA
final FieldVector3D<DerivativeStructure> vB = transformScToBodyB.transformVector(vBLocal); // V_b : line of sight's vectorB
// Position of sensors into local frame
final Vector3D sAtmp = sensorA.getPosition();
final Vector3D sBtmp = sensorB.getPosition();
final DerivativeStructure scaleFactor = FieldVector3D.dotProduct(vA.normalize(), vA.normalize()); // V_a.V_a=1
// Build a vector from the position and a scale factor (equals to 1).
// The vector built will be scaleFactor * sAtmp for example.
final FieldVector3D<DerivativeStructure> sALocal = new FieldVector3D<DerivativeStructure>(scaleFactor, sAtmp);
final FieldVector3D<DerivativeStructure> sBLocal = new FieldVector3D<DerivativeStructure>(scaleFactor, sBtmp);
// Get sensors position into body frame
final FieldVector3D<DerivativeStructure> sA = transformScToBodyA.transformPosition(sALocal); // S_a : sensorA 's position
final FieldVector3D<DerivativeStructure> sB = transformScToBodyB.transformPosition(sBLocal); // S_b : sensorB 's position
// Compute distance
final FieldVector3D<DerivativeStructure> vBase = sB.subtract(sA); // S_b - S_a
final DerivativeStructure svA = FieldVector3D.dotProduct(vBase, vA); // SV_a = (S_b - S_a).V_a
final DerivativeStructure svB = FieldVector3D.dotProduct(vBase, vB); // SV_b = (S_b - S_a).V_b
final DerivativeStructure vAvB = FieldVector3D.dotProduct(vA, vB); // V_a.V_b
// Compute lambda_b = (SV_a * V_a.V_b - SV_b) / (1 - (V_a.V_b)²)
final DerivativeStructure lambdaB = (svA.multiply(vAvB).subtract(svB)).divide(vAvB.multiply(vAvB).subtract(1).negate());
// Compute lambda_a = SV_a + lambdaB * V_a.V_b
final DerivativeStructure lambdaA = vAvB.multiply(lambdaB).add(svA);
// Compute vector M_a:
final FieldVector3D<DerivativeStructure> mA = sA.add(vA.scalarMultiply(lambdaA)); // M_a = S_a + lambda_a * V_a
// Compute vector M_b
final FieldVector3D<DerivativeStructure> mB = sB.add(vB.scalarMultiply(lambdaB)); // M_b = S_b + lambda_b * V_b
// Compute vector M_a -> M_B for which distance between LOS is minimum
final FieldVector3D<DerivativeStructure> vDistanceMin = mB.subtract(mA); // M_b - M_a
// Compute vector from mid point of vector M_a -> M_B to the ground (corresponds to minimum elevation)
final FieldVector3D<DerivativeStructure> midPoint = (mB.add(mA)).scalarMultiply(0.5);
// Get the euclidean norms to compute the minimum distances:
// between LOS
final DerivativeStructure dMin = vDistanceMin.getNorm();
// to the ground
final DerivativeStructure dCentralBody = midPoint.getNorm();
return new DerivativeStructure[] {dMin, dCentralBody};
}
/** Get the mean plane crossing finder for a sensor.
* @param sensorName name of the line sensor
* @param minLine minimum line number
* @param maxLine maximum line number
* @return mean plane crossing finder
*/
private SensorMeanPlaneCrossing getPlaneCrossing(final String sensorName,
final int minLine, final int maxLine) {
final LineSensor sensor = getLineSensor(sensorName);
SensorMeanPlaneCrossing planeCrossing = finders.get(sensorName);
if (planeCrossing == null ||
planeCrossing.getMinLine() != minLine ||
planeCrossing.getMaxLine() != maxLine) {
// create a new finder for the specified sensor and range
planeCrossing = new SensorMeanPlaneCrossing(sensor, scToBody, minLine, maxLine,
lightTimeCorrection, aberrationOfLightCorrection,
MAX_EVAL, COARSE_INVERSE_LOCATION_ACCURACY);
// store the finder, in order to reuse it
// (and save some computation done in its constructor)
setPlaneCrossing(planeCrossing);
}
return planeCrossing;
}
/** Set the mean plane crossing finder for a sensor.
* @param planeCrossing plane crossing finder
*/
private void setPlaneCrossing(final SensorMeanPlaneCrossing planeCrossing) {
finders.put(planeCrossing.getSensor().getName(), planeCrossing);
}
/** Inverse location of a point with derivatives.
* @param sensorName name of the line sensor
* @param point point to localize
* @param minLine minimum line number
* @param maxLine maximum line number
* @param generator generator to use for building {@link DerivativeStructure} instances
* @return sensor pixel seeing point with derivatives, or null if point cannot be seen between the
* prescribed line numbers
* @see #inverseLocation(String, GeodeticPoint, int, int)
* @since 2.0
*/
public DerivativeStructure[] inverseLocationDerivatives(final String sensorName,
final GeodeticPoint point,
final int minLine,
final int maxLine,
final DSGenerator generator) {
final LineSensor sensor = getLineSensor(sensorName);
final SensorMeanPlaneCrossing planeCrossing = getPlaneCrossing(sensorName, minLine, maxLine);
// find approximately the sensor line at which ground point crosses sensor mean plane
final Vector3D target = ellipsoid.transform(point);
final SensorMeanPlaneCrossing.CrossingResult crossingResult = planeCrossing.find(target);
if (crossingResult == null) {
// target is out of search interval
return null;
}
// find approximately the pixel along this sensor line
final SensorPixelCrossing pixelCrossing =
new SensorPixelCrossing(sensor, planeCrossing.getMeanPlaneNormal(),
crossingResult.getTargetDirection(),
MAX_EVAL, COARSE_INVERSE_LOCATION_ACCURACY);
final double coarsePixel = pixelCrossing.locatePixel(crossingResult.getDate());
if (Double.isNaN(coarsePixel)) {
// target is out of search interval
return null;
}
// fix line by considering the closest pixel exact position and line-of-sight
// (this pixel might point towards a direction slightly above or below the mean sensor plane)
final int lowIndex = FastMath.max(0, FastMath.min(sensor.getNbPixels() - 2, (int) FastMath.floor(coarsePixel)));
final FieldVector3D<DerivativeStructure> lowLOS =
sensor.getLOSDerivatives(crossingResult.getDate(), lowIndex, generator);
final FieldVector3D<DerivativeStructure> highLOS = sensor.getLOSDerivatives(crossingResult.getDate(), lowIndex + 1, generator);
final FieldVector3D<DerivativeStructure> localZ = FieldVector3D.crossProduct(lowLOS, highLOS).normalize();
final DerivativeStructure beta = FieldVector3D.dotProduct(crossingResult.getTargetDirection(), localZ).acos();
final DerivativeStructure s = FieldVector3D.dotProduct(crossingResult.getTargetDirectionDerivative(), localZ);
final DerivativeStructure minusBetaDer = s.divide(s.multiply(s).subtract(1).negate().sqrt());
final DerivativeStructure deltaL = beta.subtract(0.5 * FastMath.PI) .divide(minusBetaDer);
final DerivativeStructure fixedLine = deltaL.add(crossingResult.getLine());
final FieldVector3D<DerivativeStructure> fixedDirection =
new FieldVector3D<DerivativeStructure>(deltaL.getField().getOne(), crossingResult.getTargetDirection(),
deltaL, crossingResult.getTargetDirectionDerivative()).normalize();
// fix neighbouring pixels
final AbsoluteDate fixedDate = sensor.getDate(fixedLine.getValue());
final FieldVector3D<DerivativeStructure> fixedX = sensor.getLOSDerivatives(fixedDate, lowIndex, generator);
final FieldVector3D<DerivativeStructure> fixedZ = FieldVector3D.crossProduct(fixedX, sensor.getLOSDerivatives(fixedDate, lowIndex + 1, generator));
final FieldVector3D<DerivativeStructure> fixedY = FieldVector3D.crossProduct(fixedZ, fixedX);
// fix pixel
final DerivativeStructure hY = FieldVector3D.dotProduct(highLOS, fixedY);
final DerivativeStructure hX = FieldVector3D.dotProduct(highLOS, fixedX);
final DerivativeStructure pixelWidth = hY.atan2(hX);
final DerivativeStructure fY = FieldVector3D.dotProduct(fixedDirection, fixedY);
final DerivativeStructure fX = FieldVector3D.dotProduct(fixedDirection, fixedX);
final DerivativeStructure alpha = fY.atan2(fX);
final DerivativeStructure fixedPixel = alpha.divide(pixelWidth).add(lowIndex);
return new DerivativeStructure[] {
fixedLine, fixedPixel
};
}
/** Get transform from spacecraft to inertial frame.
* @param date date of the transform
* @return transform from spacecraft to inertial frame
*/
public Transform getScToInertial(final AbsoluteDate date) {
return scToBody.getScToInertial(date);
}
/** Get transform from inertial frame to observed body frame.
* @param date date of the transform
* @return transform from inertial frame to observed body frame
*/
public Transform getInertialToBody(final AbsoluteDate date) {
return scToBody.getInertialToBody(date);
}
/** Get transform from observed body frame to inertial frame.
* @param date date of the transform
* @return transform from observed body frame to inertial frame
*/
public Transform getBodyToInertial(final AbsoluteDate date) {
return scToBody.getBodyToInertial(date);
}
/** Get a sensor.
* @param sensorName sensor name
* @return selected sensor
*/
public LineSensor getLineSensor(final String sensorName) {
final LineSensor sensor = sensors.get(sensorName);
if (sensor == null) {
throw new RuggedException(RuggedMessages.UNKNOWN_SENSOR, sensorName);
}
return sensor;
}
/** Get converter between spacecraft and body.
* @return the scToBody
* @since 2.0
*/
public SpacecraftToObservedBody getScToBody() {
return scToBody;
}
}