NiellMappingFunctionModel.java
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package org.orekit.models.earth.troposphere;
import org.hipparchus.Field;
import org.hipparchus.CalculusFieldElement;
import org.hipparchus.analysis.UnivariateFunction;
import org.hipparchus.analysis.interpolation.LinearInterpolator;
import org.hipparchus.util.FastMath;
import org.hipparchus.util.MathArrays;
import org.orekit.annotation.DefaultDataContext;
import org.orekit.bodies.FieldGeodeticPoint;
import org.orekit.bodies.GeodeticPoint;
import org.orekit.data.DataContext;
import org.orekit.models.earth.weather.FieldPressureTemperatureHumidity;
import org.orekit.models.earth.weather.PressureTemperatureHumidity;
import org.orekit.time.AbsoluteDate;
import org.orekit.time.DateTimeComponents;
import org.orekit.time.FieldAbsoluteDate;
import org.orekit.time.TimeScale;
import org.orekit.utils.FieldTrackingCoordinates;
import org.orekit.utils.TrackingCoordinates;
/** The Niell Mapping Function model for radio wavelengths.
* This model is an empirical mapping function. It only needs the
* values of the station latitude, height and the date for the computations.
* <p>
* With this model, the hydrostatic mapping function is time and latitude dependent
* whereas the wet mapping function is only latitude dependent.
* </p>
*
* @see "A. E. Niell(1996), Global mapping functions for the atmosphere delay of radio wavelengths,
* J. Geophys. Res., 101(B2), pp. 3227–3246, doi: 10.1029/95JB03048."
*
* @author Bryan Cazabonne
*
*/
public class NiellMappingFunctionModel implements TroposphereMappingFunction {
/** Values for the ah average function. */
private static final double[] VALUES_FOR_AH_AVERAGE = {
1.2769934e-3, 1.2683230e-3, 1.2465397e-3, 1.2196049e-3, 1.2045996e-3
};
/** Values for the bh average function. */
private static final double[] VALUES_FOR_BH_AVERAGE = {
2.9153695e-3, 2.9152299e-3, 2.9288445e-3, 2.9022565e-3, 2.9024912e-3
};
/** Values for the ch average function. */
private static final double[] VALUES_FOR_CH_AVERAGE = {
62.610505e-3, 62.837393e-3, 63.721774e-3, 63.824265e-3, 64.258455e-3
};
/** Values for the ah amplitude function. */
private static final double[] VALUES_FOR_AH_AMPLITUDE = {
0.0, 1.2709626e-5, 2.6523662e-5, 3.4000452e-5, 4.1202191e-5
};
/** Values for the bh amplitude function. */
private static final double[] VALUES_FOR_BH_AMPLITUDE = {
0.0, 2.1414979e-5, 3.0160779e-5, 7.2562722e-5, 11.723375e-5
};
/** X values for the ch amplitude function. */
private static final double[] VALUES_FOR_CH_AMPLITUDE = {
0.0, 9.0128400e-5, 4.3497037e-5, 84.795348e-5, 170.37206e-5
};
/** Values for the aw function. */
private static final double[] VALUES_FOR_AW = {
5.8021897e-4, 5.6794847e-4, 5.8118019e-4, 5.9727542e-4, 6.1641693e-4
};
/** Values for the bw function. */
private static final double[] VALUES_FOR_BW = {
1.4275268e-3, 1.5138625e-3, 1.4572752e-3, 1.5007428e-3, 1.7599082e-3
};
/** Values for the cw function. */
private static final double[] VALUES_FOR_CW = {
4.3472961e-2, 4.6729510e-2, 4.3908931e-2, 4.4626982e-2, 5.4736038e-2
};
/** Values for the cw function. */
private static final double[] LATITUDE_VALUES = {
FastMath.toRadians(15.0), FastMath.toRadians(30.0), FastMath.toRadians(45.0), FastMath.toRadians(60.0), FastMath.toRadians(75.0),
};
/** Interpolation function for the ah (average) term. */
private final UnivariateFunction ahAverageFunction;
/** Interpolation function for the bh (average) term. */
private final UnivariateFunction bhAverageFunction;
/** Interpolation function for the ch (average) term. */
private final UnivariateFunction chAverageFunction;
/** Interpolation function for the ah (amplitude) term. */
private final UnivariateFunction ahAmplitudeFunction;
/** Interpolation function for the bh (amplitude) term. */
private final UnivariateFunction bhAmplitudeFunction;
/** Interpolation function for the ch (amplitude) term. */
private final UnivariateFunction chAmplitudeFunction;
/** Interpolation function for the aw term. */
private final UnivariateFunction awFunction;
/** Interpolation function for the bw term. */
private final UnivariateFunction bwFunction;
/** Interpolation function for the cw term. */
private final UnivariateFunction cwFunction;
/** UTC time scale. */
private final TimeScale utc;
/** Builds a new instance.
*
* <p>This constructor uses the {@link DataContext#getDefault() default data context}.
*
* @see #NiellMappingFunctionModel(TimeScale)
*/
@DefaultDataContext
public NiellMappingFunctionModel() {
this(DataContext.getDefault().getTimeScales().getUTC());
}
/** Builds a new instance.
* @param utc UTC time scale.
* @since 10.1
*/
public NiellMappingFunctionModel(final TimeScale utc) {
this.utc = utc;
// Interpolation functions for hydrostatic coefficients
this.ahAverageFunction = new LinearInterpolator().interpolate(LATITUDE_VALUES, VALUES_FOR_AH_AVERAGE);
this.bhAverageFunction = new LinearInterpolator().interpolate(LATITUDE_VALUES, VALUES_FOR_BH_AVERAGE);
this.chAverageFunction = new LinearInterpolator().interpolate(LATITUDE_VALUES, VALUES_FOR_CH_AVERAGE);
this.ahAmplitudeFunction = new LinearInterpolator().interpolate(LATITUDE_VALUES, VALUES_FOR_AH_AMPLITUDE);
this.bhAmplitudeFunction = new LinearInterpolator().interpolate(LATITUDE_VALUES, VALUES_FOR_BH_AMPLITUDE);
this.chAmplitudeFunction = new LinearInterpolator().interpolate(LATITUDE_VALUES, VALUES_FOR_CH_AMPLITUDE);
// Interpolation functions for wet coefficients
this.awFunction = new LinearInterpolator().interpolate(LATITUDE_VALUES, VALUES_FOR_AW);
this.bwFunction = new LinearInterpolator().interpolate(LATITUDE_VALUES, VALUES_FOR_BW);
this.cwFunction = new LinearInterpolator().interpolate(LATITUDE_VALUES, VALUES_FOR_CW);
}
/** {@inheritDoc} */
@Override
public double[] mappingFactors(final TrackingCoordinates trackingCoordinates, final GeodeticPoint point,
final PressureTemperatureHumidity weather,
final AbsoluteDate date) {
// Day of year computation
final DateTimeComponents dtc = date.getComponents(utc);
final int dofyear = dtc.getDate().getDayOfYear();
// Temporal factor
double t0 = 28;
if (point.getLatitude() < 0) {
// southern hemisphere: t0 = 28 + an integer half of year
t0 += 183;
}
final double coef = 2 * FastMath.PI * ((dofyear - t0) / 365.25);
final double cosCoef = FastMath.cos(coef);
// Compute ah, bh and ch Eq. 5
double absLatidude = FastMath.abs(point.getLatitude());
// there are no data in the model for latitudes lower than 15°
absLatidude = FastMath.max(FastMath.toRadians(15.0), absLatidude);
// there are no data in the model for latitudes greater than 75°
absLatidude = FastMath.min(FastMath.toRadians(75.0), absLatidude);
final double ah = ahAverageFunction.value(absLatidude) - ahAmplitudeFunction.value(absLatidude) * cosCoef;
final double bh = bhAverageFunction.value(absLatidude) - bhAmplitudeFunction.value(absLatidude) * cosCoef;
final double ch = chAverageFunction.value(absLatidude) - chAmplitudeFunction.value(absLatidude) * cosCoef;
final double[] function = new double[2];
// Hydrostatic mapping factor
function[0] = TroposphericModelUtils.mappingFunction(ah, bh, ch, trackingCoordinates.getElevation());
// Wet mapping factor
function[1] = TroposphericModelUtils.mappingFunction(awFunction.value(absLatidude),
bwFunction.value(absLatidude),
cwFunction.value(absLatidude),
trackingCoordinates.getElevation());
// Apply height correction
final double correction = TroposphericModelUtils.computeHeightCorrection(trackingCoordinates.getElevation(),
point.getAltitude());
function[0] = function[0] + correction;
return function;
}
/** {@inheritDoc} */
@Override
public <T extends CalculusFieldElement<T>> T[] mappingFactors(final FieldTrackingCoordinates<T> trackingCoordinates,
final FieldGeodeticPoint<T> point,
final FieldPressureTemperatureHumidity<T> weather,
final FieldAbsoluteDate<T> date) {
final Field<T> field = date.getField();
final T zero = field.getZero();
// Day of year computation
final DateTimeComponents dtc = date.getComponents(utc);
final int dofyear = dtc.getDate().getDayOfYear();
// Temporal factor
double t0 = 28;
if (point.getLatitude().getReal() < 0) {
// southern hemisphere: t0 = 28 + an integer half of year
t0 += 183;
}
final T coef = zero.getPi().multiply(2.0).multiply((dofyear - t0) / 365.25);
final T cosCoef = FastMath.cos(coef);
// Compute ah, bh and ch Eq. 5
double absLatidude = FastMath.abs(point.getLatitude().getReal());
// there are no data in the model for latitudes lower than 15°
absLatidude = FastMath.max(FastMath.toRadians(15.0), absLatidude);
// there are no data in the model for latitudes greater than 75°
absLatidude = FastMath.min(FastMath.toRadians(75.0), absLatidude);
final T ah = cosCoef.multiply(ahAmplitudeFunction.value(absLatidude)).negate().add(ahAverageFunction.value(absLatidude));
final T bh = cosCoef.multiply(bhAmplitudeFunction.value(absLatidude)).negate().add(bhAverageFunction.value(absLatidude));
final T ch = cosCoef.multiply(chAmplitudeFunction.value(absLatidude)).negate().add(chAverageFunction.value(absLatidude));
final T[] function = MathArrays.buildArray(field, 2);
// Hydrostatic mapping factor
function[0] = TroposphericModelUtils.mappingFunction(ah, bh, ch,
trackingCoordinates.getElevation());
// Wet mapping factor
function[1] = TroposphericModelUtils.mappingFunction(zero.newInstance(awFunction.value(absLatidude)), zero.newInstance(bwFunction.value(absLatidude)),
zero.newInstance(cwFunction.value(absLatidude)), trackingCoordinates.getElevation());
// Apply height correction
final T correction = TroposphericModelUtils.computeHeightCorrection(trackingCoordinates.getElevation(),
point.getAltitude(),
field);
function[0] = function[0].add(correction);
return function;
}
}