DTM2000.java
- /* Copyright 2002-2019 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.forces.drag.atmosphere;
- import java.io.BufferedReader;
- import java.io.IOException;
- import java.io.InputStream;
- import java.io.InputStreamReader;
- import java.util.Arrays;
- import java.util.Calendar;
- import java.util.GregorianCalendar;
- import org.hipparchus.RealFieldElement;
- import org.hipparchus.exception.DummyLocalizable;
- import org.hipparchus.geometry.euclidean.threed.FieldVector3D;
- import org.hipparchus.geometry.euclidean.threed.Vector3D;
- import org.hipparchus.util.FastMath;
- import org.hipparchus.util.MathArrays;
- import org.orekit.bodies.BodyShape;
- import org.orekit.bodies.FieldGeodeticPoint;
- import org.orekit.bodies.GeodeticPoint;
- import org.orekit.errors.OrekitException;
- import org.orekit.errors.OrekitMessages;
- import org.orekit.frames.Frame;
- import org.orekit.time.AbsoluteDate;
- import org.orekit.time.FieldAbsoluteDate;
- import org.orekit.time.TimeScalesFactory;
- import org.orekit.utils.PVCoordinatesProvider;
- /** This atmosphere model is the realization of the DTM-2000 model.
- * <p>
- * It is described in the paper: <br>
- *
- * <b>The DTM-2000 empirical thermosphere model with new data assimilation
- * and constraints at lower boundary: accuracy and properties</b><br>
- *
- * <i>S. Bruinsma, G. Thuillier and F. Barlier</i> <br>
- *
- * Journal of Atmospheric and Solar-Terrestrial Physics 65 (2003) 1053–1070<br>
- *
- *</p>
- *<p>
- * This model provides dense output for altitudes beyond 120 km.
- *</p>
- *
- * <p>
- * The model needs geographical and time information to compute general values,
- * but also needs space weather data : mean and instantaneous solar flux and
- * geomagnetic indices.
- * </p>
- * <p>
- * Mean solar flux is (for the moment) represented by the F10.7 indices. Instantaneous
- * flux can be set to the mean value if the data is not available. Geomagnetic
- * activity is represented by the Kp indice, which goes from 1 (very low activity) to
- * 9 (high activity).
- *
- * <p>
- * All these data can be found on the <a href="http://sec.noaa.gov/Data/index.html">
- * NOAA (National Oceanic and Atmospheric Administration) website.</a>
- * </p>
- *
- *
- * @author R. Biancale, S. Bruinsma: original fortran routine
- * @author Fabien Maussion (java translation)
- */
- public class DTM2000 implements Atmosphere {
- /** Identifier for hydrogen. */
- public static final int HYDROGEN = 1;
- /** Identifier for helium. */
- public static final int HELIUM = 2;
- /** Identifier for atomic oxygen. */
- public static final int ATOMIC_OXYGEN = 3;
- /** Identifier for molecular nitrogen. */
- public static final int MOLECULAR_NITROGEN = 4;
- /** Identifier for molecular oxygen. */
- public static final int MOLECULAR_OXYGEN = 5;
- /** Identifier for atomic nitrogen. */
- public static final int ATOMIC_NITROGEN = 6;
- /** Serializable UID. */
- private static final long serialVersionUID = 20170705L;
- // Constants :
- /** Number of parameters. */
- private static final int NLATM = 96;
- /** Thermal diffusion coefficient. */
- private static final double[] ALEFA = {
- 0, -0.40, -0.38, 0, 0, 0, 0
- };
- /** Atomic mass H, He, O, N2, O2, N. */
- private static final double[] MA = {
- 0, 1, 4, 16, 28, 32, 14
- };
- /** Atomic mass H, He, O, N2, O2, N. */
- private static final double[] VMA = {
- 0, 1.6606e-24, 6.6423e-24, 26.569e-24, 46.4958e-24, 53.1381e-24, 23.2479e-24
- };
- /** Polar Earth radius. */
- private static final double RE = 6356.77;
- /** Reference altitude. */
- private static final double ZLB0 = 120.0;
- /** Cosine of the latitude of the magnetic pole (79N, 71W). */
- private static final double CPMG = .19081;
- /** Sine of the latitude of the magnetic pole (79N, 71W). */
- private static final double SPMG = .98163;
- /** Longitude (in radians) of the magnetic pole (79N, 71W). */
- private static final double XLMG = -1.2392;
- /** Gravity acceleration at 120 km altitude. */
- private static final double GSURF = 980.665;
- /** Universal gas constant. */
- private static final double RGAS = 831.4;
- /** 2 * π / 365. */
- private static final double ROT = 0.017214206;
- /** 2 * rot. */
- private static final double ROT2 = 0.034428412;
- /** Resources text file. */
- private static final String DTM2000 = "/assets/org/orekit/dtm_2000.txt";
- // CHECKSTYLE: stop JavadocVariable check
- /** Elements coefficients. */
- private static double[] tt = null;
- private static double[] h = null;
- private static double[] he = null;
- private static double[] o = null;
- private static double[] az2 = null;
- private static double[] o2 = null;
- private static double[] az = null;
- private static double[] t0 = null;
- private static double[] tp = null;
- /** Sun position. */
- private PVCoordinatesProvider sun;
- /** External data container. */
- private DTM2000InputParameters inputParams;
- /** Earth body shape. */
- private BodyShape earth;
- /** Simple constructor for independent computation.
- * @param parameters the solar and magnetic activity data
- * @param sun the sun position
- * @param earth the earth body shape
- */
- public DTM2000(final DTM2000InputParameters parameters,
- final PVCoordinatesProvider sun, final BodyShape earth) {
- synchronized (DTM2000.class) {
- // lazy reading of model coefficients
- if (tt == null) {
- readcoefficients();
- }
- }
- this.earth = earth;
- this.sun = sun;
- this.inputParams = parameters;
- }
- /** {@inheritDoc} */
- public Frame getFrame() {
- return earth.getBodyFrame();
- }
- /** Get the local density with initial entries.
- * @param day day of year
- * @param alti altitude in meters
- * @param lon local longitude (rad)
- * @param lat local latitude (rad)
- * @param hl local solar time in rad (O hr = 0 rad)
- * @param f instantaneous solar flux (F10.7)
- * @param fbar mean solar flux (F10.7)
- * @param akp3 3 hrs geomagnetic activity index (1-9)
- * @param akp24 Mean of last 24 hrs geomagnetic activity index (1-9)
- * @return the local density (kg/m³)
- */
- public double getDensity(final int day,
- final double alti, final double lon, final double lat,
- final double hl, final double f, final double fbar,
- final double akp3, final double akp24) {
- final double threshold = 120000;
- if (alti < threshold) {
- throw new OrekitException(OrekitMessages.ALTITUDE_BELOW_ALLOWED_THRESHOLD,
- alti, threshold);
- }
- final Computation result = new Computation(day, alti / 1000, lon, lat, hl,
- new double[] {
- 0, f, 0
- }, new double[] {
- 0, fbar, 0
- }, new double[] {
- 0, akp3, 0, akp24, 0
- });
- return result.ro * 1000;
- }
- /** Get the local density with initial entries.
- * @param day day of year
- * @param alti altitude in meters
- * @param lon local longitude (rad)
- * @param lat local latitude (rad)
- * @param hl local solar time in rad (O hr = 0 rad)
- * @param f instantaneous solar flux (F10.7)
- * @param fbar mean solar flux (F10.7)
- * @param akp3 3 hrs geomagnetic activity index (1-9)
- * @param akp24 Mean of last 24 hrs geomagnetic activity index (1-9)
- * @param <T> type of the field elements
- * @return the local density (kg/m³)
- * @since 9.0
- */
- public <T extends RealFieldElement<T>> T getDensity(final int day,
- final T alti, final T lon, final T lat,
- final T hl, final double f, final double fbar,
- final double akp3, final double akp24) {
- final double threshold = 120000;
- if (alti.getReal() < threshold) {
- throw new OrekitException(OrekitMessages.ALTITUDE_BELOW_ALLOWED_THRESHOLD,
- alti, threshold);
- }
- final FieldComputation<T> result = new FieldComputation<>(day, alti.divide(1000), lon, lat, hl,
- new double[] {
- 0, f, 0
- }, new double[] {
- 0, fbar, 0
- }, new double[] {
- 0, akp3, 0, akp24, 0
- });
- return result.ro.multiply(1000);
- }
- /** Store the DTM model elements coefficients in internal arrays.
- */
- private static void readcoefficients() {
- final int size = NLATM + 1;
- tt = new double[size];
- h = new double[size];
- he = new double[size];
- o = new double[size];
- az2 = new double[size];
- o2 = new double[size];
- az = new double[size];
- t0 = new double[size];
- tp = new double[size];
- final InputStream in = DTM2000.class.getResourceAsStream(DTM2000);
- if (in == null) {
- throw new OrekitException(OrekitMessages.UNABLE_TO_FIND_RESOURCE, DTM2000);
- }
- BufferedReader r = null;
- try {
- r = new BufferedReader(new InputStreamReader(in, "UTF-8"));
- r.readLine();
- r.readLine();
- for (String line = r.readLine(); line != null; line = r.readLine()) {
- final int num = Integer.parseInt(line.substring(0, 4).replace(' ', '0'));
- line = line.substring(4);
- tt[num] = Double.parseDouble(line.substring(0, 13).replace(' ', '0'));
- line = line.substring(13 + 9);
- h[num] = Double.parseDouble(line.substring(0, 13).replace(' ', '0'));
- line = line.substring(13 + 9);
- he[num] = Double.parseDouble(line.substring(0, 13).replace(' ', '0'));
- line = line.substring(13 + 9);
- o[num] = Double.parseDouble(line.substring(0, 13).replace(' ', '0'));
- line = line.substring(13 + 9);
- az2[num] = Double.parseDouble(line.substring(0, 13).replace(' ', '0'));
- line = line.substring(13 + 9);
- o2[num] = Double.parseDouble(line.substring(0, 13).replace(' ', '0'));
- line = line.substring(13 + 9);
- az[num] = Double.parseDouble(line.substring(0, 13).replace(' ', '0'));
- line = line.substring(13 + 9);
- t0[num] = Double.parseDouble(line.substring(0, 13).replace(' ', '0'));
- line = line.substring(13 + 9);
- tp[num] = Double.parseDouble(line.substring(0, 13).replace(' ', '0'));
- }
- } catch (IOException ioe) {
- throw new OrekitException(ioe, new DummyLocalizable(ioe.getMessage()));
- } finally {
- if (r != null) {
- try {
- r.close();
- } catch (IOException ioe) {
- throw new OrekitException(ioe, new DummyLocalizable(ioe.getMessage()));
- }
- }
- }
- }
- /** Get the local density.
- * @param date current date
- * @param position current position in frame
- * @param frame the frame in which is defined the position
- * @return local density (kg/m³)
- */
- public double getDensity(final AbsoluteDate date, final Vector3D position,
- final Frame frame) {
- // check if data are available :
- if ((date.compareTo(inputParams.getMaxDate()) > 0) ||
- (date.compareTo(inputParams.getMinDate()) < 0)) {
- throw new OrekitException(OrekitMessages.NO_SOLAR_ACTIVITY_AT_DATE,
- date, inputParams.getMinDate(), inputParams.getMaxDate());
- }
- // compute day number in current year
- final Calendar cal = new GregorianCalendar();
- cal.setTime(date.toDate(TimeScalesFactory.getUTC()));
- final int day = cal.get(Calendar.DAY_OF_YEAR);
- //position in ECEF so we only have to do the transform once
- final Frame ecef = earth.getBodyFrame();
- final Vector3D pEcef = frame.getTransformTo(ecef, date)
- .transformPosition(position);
- // compute geodetic position
- final GeodeticPoint inBody = earth.transform(pEcef, ecef, date);
- final double alti = inBody.getAltitude();
- final double lon = inBody.getLongitude();
- final double lat = inBody.getLatitude();
- // compute local solar time
- final Vector3D sunPos = sun.getPVCoordinates(date, ecef).getPosition();
- final double hl = FastMath.PI + FastMath.atan2(
- sunPos.getX() * pEcef.getY() - sunPos.getY() * pEcef.getX(),
- sunPos.getX() * pEcef.getX() + sunPos.getY() * pEcef.getY());
- // get current solar activity data and compute
- return getDensity(day, alti, lon, lat, hl, inputParams.getInstantFlux(date),
- inputParams.getMeanFlux(date), inputParams.getThreeHourlyKP(date),
- inputParams.get24HoursKp(date));
- }
- /** {@inheritDoc} */
- @Override
- public <T extends RealFieldElement<T>> T
- getDensity(final FieldAbsoluteDate<T> date, final FieldVector3D<T> position,
- final Frame frame) {
- // check if data are available :
- final AbsoluteDate dateD = date.toAbsoluteDate();
- if ((dateD.compareTo(inputParams.getMaxDate()) > 0) ||
- (dateD.compareTo(inputParams.getMinDate()) < 0)) {
- throw new OrekitException(OrekitMessages.NO_SOLAR_ACTIVITY_AT_DATE,
- dateD, inputParams.getMinDate(), inputParams.getMaxDate());
- }
- // compute day number in current year
- final Calendar cal = new GregorianCalendar();
- cal.setTime(date.toDate(TimeScalesFactory.getUTC()));
- final int day = cal.get(Calendar.DAY_OF_YEAR);
- //position in ECEF so we only have to do the transform once
- final Frame ecef = earth.getBodyFrame();
- final FieldVector3D<T> pEcef = frame.getTransformTo(ecef, date).transformPosition(position);
- // compute geodetic position
- final FieldGeodeticPoint<T> inBody = earth.transform(pEcef, ecef, date);
- final T alti = inBody.getAltitude();
- final T lon = inBody.getLongitude();
- final T lat = inBody.getLatitude();
- // compute local solar time
- final Vector3D sunPos = sun.getPVCoordinates(dateD, ecef).getPosition();
- final T y = pEcef.getY().multiply(sunPos.getX()).subtract(pEcef.getX().multiply(sunPos.getY()));
- final T x = pEcef.getX().multiply(sunPos.getX()).add(pEcef.getY().multiply(sunPos.getY()));
- final T hl = y.atan2(x).add(FastMath.PI);
- // get current solar activity data and compute
- return getDensity(day, alti, lon, lat, hl, inputParams.getInstantFlux(dateD),
- inputParams.getMeanFlux(dateD), inputParams.getThreeHourlyKP(dateD),
- inputParams.get24HoursKp(dateD));
- }
- /** Local holder for intermediate results ensuring the model is reentrant. */
- private static class Computation {
- /** Number of days in current year. */
- private final int day;
- /** Instant solar flux. f[1] = instantaneous flux; f[2] = 0. (not used). */
- private final double[] f;
- /** Mean solar flux. fbar[1] = mean flux; fbar[2] = 0. (not used). */
- private final double[] fbar;
- /** Kp coefficients.
- * <ul>
- * <li>akp[1] = 3-hourly kp</li>
- * <li>akp[2] = 0 (not used)</li>
- * <li>akp[3] = mean kp of last 24 hours</li>
- * <li>akp[4] = 0 (not used)</li>
- * </ul>
- */
- private final double[] akp;
- /** Cosine of the longitude. */
- private final double clfl;
- /** Sine of the longitude. */
- private final double slfl;
- /** Total density (g/cm3). */
- private final double ro;
- // CHECKSTYLE: stop JavadocVariable check
- /** Legendre coefficients. */
- private final double p10;
- private final double p20;
- private final double p30;
- private final double p40;
- private final double p50;
- private final double p60;
- private final double p11;
- private final double p21;
- private final double p31;
- private final double p41;
- private final double p51;
- private final double p22;
- private final double p32;
- private final double p42;
- private final double p52;
- private final double p62;
- private final double p33;
- private final double p10mg;
- private final double p20mg;
- private final double p40mg;
- /** Local time intermediate values. */
- private final double hl0;
- private final double ch;
- private final double sh;
- private final double c2h;
- private final double s2h;
- private final double c3h;
- private final double s3h;
- /** Simple constructor.
- * @param day day of year
- * @param altiKM altitude <em>in kilometers</em>
- * @param lon local longitude (rad)
- * @param lat local latitude (rad)
- * @param hl local solar time in rad (O hr = 0 rad)
- * @param f instantaneous solar flux (F10.7)
- * @param fbar mean solar flux (F10.7)
- * @param akp geomagnetic activity index
- */
- Computation(final int day,
- final double altiKM, final double lon, final double lat,
- final double hl, final double[] f, final double[] fbar,
- final double[] akp) {
- this.day = day;
- this.f = f;
- this.fbar = fbar;
- this.akp = akp;
- // compute Legendre polynomials wrt geographic pole
- final double c = FastMath.sin(lat);
- final double c2 = c * c;
- final double c4 = c2 * c2;
- final double s = FastMath.cos(lat);
- final double s2 = s * s;
- p10 = c;
- p20 = 1.5 * c2 - 0.5;
- p30 = c * (2.5 * c2 - 1.5);
- p40 = 4.375 * c4 - 3.75 * c2 + 0.375;
- p50 = c * (7.875 * c4 - 8.75 * c2 + 1.875);
- p60 = (5.5 * c * p50 - 2.5 * p40) / 3.0;
- p11 = s;
- p21 = 3.0 * c * s;
- p31 = s * (7.5 * c2 - 1.5);
- p41 = c * s * (17.5 * c2 - 7.5);
- p51 = s * (39.375 * c4 - 26.25 * c2 + 1.875);
- p22 = 3.0 * s2;
- p32 = 15.0 * c * s2;
- p42 = s2 * (52.5 * c2 - 7.5);
- p52 = 3.0 * c * p42 - 2.0 * p32;
- p62 = 2.75 * c * p52 - 1.75 * p42;
- p33 = 15.0 * s * s2;
- // compute Legendre polynomials wrt magnetic pole (79N, 71W)
- final double clmlmg = FastMath.cos(lon - XLMG);
- final double cmg = s * CPMG * clmlmg + c * SPMG;
- final double cmg2 = cmg * cmg;
- final double cmg4 = cmg2 * cmg2;
- p10mg = cmg;
- p20mg = 1.5 * cmg2 - 0.5;
- p40mg = 4.375 * cmg4 - 3.75 * cmg2 + 0.375;
- clfl = FastMath.cos(lon);
- slfl = FastMath.sin(lon);
- // local time
- hl0 = hl;
- ch = FastMath.cos(hl0);
- sh = FastMath.sin(hl0);
- c2h = ch * ch - sh * sh;
- s2h = 2.0 * ch * sh;
- c3h = c2h * ch - s2h * sh;
- s3h = s2h * ch + c2h * sh;
- final double zlb = ZLB0; // + dzlb ??
- final double[] dtt = new double[tt.length];
- final double[] dh = new double[tt.length];
- final double[] dhe = new double[tt.length];
- final double[] dox = new double[tt.length];
- final double[] daz2 = new double[tt.length];
- final double[] do2 = new double[tt.length];
- final double[] daz = new double[tt.length];
- final double[] dt0 = new double[tt.length];
- final double[] dtp = new double[tt.length];
- Arrays.fill(dtt, Double.NaN);
- Arrays.fill(dh, Double.NaN);
- Arrays.fill(dhe, Double.NaN);
- Arrays.fill(dox, Double.NaN);
- Arrays.fill(daz2, Double.NaN);
- Arrays.fill(do2, Double.NaN);
- Arrays.fill(daz, Double.NaN);
- Arrays.fill(dt0, Double.NaN);
- Arrays.fill(dtp, Double.NaN);
- // compute function g(l) / tinf, t120, tp120
- int kleq = 1;
- final double gdelt = gFunction(tt, dtt, 1, kleq);
- dtt[1] = 1.0 + gdelt;
- final double tinf = tt[1] * dtt[1];
- kleq = 0; // equinox
- if ((day < 59) || (day > 284)) {
- kleq = -1; // north winter
- }
- if ((day > 99) && (day < 244)) {
- kleq = 1; // north summer
- }
- final double gdelt0 = gFunction(t0, dt0, 0, kleq);
- dt0[1] = (t0[1] + gdelt0) / t0[1];
- final double t120 = t0[1] + gdelt0;
- final double gdeltp = gFunction(tp, dtp, 0, kleq);
- dtp[1] = (tp[1] + gdeltp) / tp[1];
- final double tp120 = tp[1] + gdeltp;
- // compute n(z) concentrations: H, He, O, N2, O2, N
- final double sigma = tp120 / (tinf - t120);
- final double dzeta = (RE + zlb) / (RE + altiKM);
- final double zeta = (altiKM - zlb) * dzeta;
- final double sigzeta = sigma * zeta;
- final double expsz = FastMath.exp(-sigzeta);
- final double tz = tinf - (tinf - t120) * expsz;
- final double[] dbase = new double[7];
- kleq = 1;
- final double gdelh = gFunction(h, dh, 0, kleq);
- dh[1] = FastMath.exp(gdelh);
- dbase[1] = h[1] * dh[1];
- final double gdelhe = gFunction(he, dhe, 0, kleq);
- dhe[1] = FastMath.exp(gdelhe);
- dbase[2] = he[1] * dhe[1];
- final double gdelo = gFunction(o, dox, 1, kleq);
- dox[1] = FastMath.exp(gdelo);
- dbase[3] = o[1] * dox[1];
- final double gdelaz2 = gFunction(az2, daz2, 1, kleq);
- daz2[1] = FastMath.exp(gdelaz2);
- dbase[4] = az2[1] * daz2[1];
- final double gdelo2 = gFunction(o2, do2, 1, kleq);
- do2[1] = FastMath.exp(gdelo2);
- dbase[5] = o2[1] * do2[1];
- final double gdelaz = gFunction(az, daz, 1, kleq);
- daz[1] = FastMath.exp(gdelaz);
- dbase[6] = az[1] * daz[1];
- final double zlbre = 1.0 + zlb / RE;
- final double glb = (GSURF / (zlbre * zlbre)) / (sigma * RGAS * tinf);
- final double t120tz = t120 / tz;
- // Partial densities in (g/cm3).
- // d(1) = hydrogen
- // d(2) = helium
- // d(3) = atomic oxygen
- // d(4) = molecular nitrogen
- // d(5) = molecular oxygen
- // d(6) = atomic nitrogen
- double tmpro = 0;
- for (int i = 1; i <= 6; i++) {
- final double gamma = MA[i] * glb;
- final double upapg = 1.0 + ALEFA[i] + gamma;
- final double fzI = FastMath.pow(t120tz, upapg) * FastMath.exp(-sigzeta * gamma);
- // concentrations of H, He, O, N2, O2, N (particles/cm³)
- final double ccI = dbase[i] * fzI;
- // contribution of densities of H, He, O, N2, O2, N (g/cm³)
- tmpro += ccI * VMA[i];
- }
- this.ro = tmpro;
- }
- /** Computation of function G.
- * @param a vector of coefficients for computation
- * @param da vector of partial derivatives
- * @param ff0 coefficient flag (1 for Ox, Az, He, T°; 0 for H and tp120)
- * @param kle_eq season indicator flag (summer, winter, equinox)
- * @return value of G
- */
- private double gFunction(final double[] a, final double[] da,
- final int ff0, final int kle_eq) {
- final double[] fmfb = new double[3];
- final double[] fbm150 = new double[3];
- // latitude terms
- da[2] = p20;
- da[3] = p40;
- da[74] = p10;
- double a74 = a[74];
- double a77 = a[77];
- double a78 = a[78];
- if (kle_eq == -1) {
- // winter
- a74 = -a74;
- a77 = -a77;
- a78 = -a78;
- }
- if (kle_eq == 0 ) {
- // equinox
- a74 = semestrialCorrection(a74);
- a77 = semestrialCorrection(a77);
- a78 = semestrialCorrection(a78);
- }
- da[77] = p30;
- da[78] = p50;
- da[79] = p60;
- // flux terms
- fmfb[1] = f[1] - fbar[1];
- fmfb[2] = f[2] - fbar[2];
- fbm150[1] = fbar[1] - 150.0;
- fbm150[2] = fbar[2];
- da[4] = fmfb[1];
- da[6] = fbm150[1];
- da[4] = da[4] + a[70] * fmfb[2];
- da[6] = da[6] + a[71] * fbm150[2];
- da[70] = fmfb[2] * (a[4] + 2.0 * a[5] * da[4] + a[82] * p10 +
- a[83] * p20 + a[84] * p30);
- da[71] = fbm150[2] * (a[6] + 2.0 * a[69] * da[6] + a[85] * p10 +
- a[86] * p20 + a[87] * p30);
- da[5] = da[4] * da[4];
- da[69] = da[6] * da[6];
- da[82] = da[4] * p10;
- da[83] = da[4] * p20;
- da[84] = da[4] * p30;
- da[85] = da[6] * p20;
- da[86] = da[6] * p30;
- da[87] = da[6] * p40;
- // Kp terms
- final int ikp = 62;
- final int ikpm = 67;
- final double c2fi = 1.0 - p10mg * p10mg;
- final double dkp = akp[1] + (a[ikp] + c2fi * a[ikp + 1]) * akp[2];
- double dakp = a[7] + a[8] * p20mg + a[68] * p40mg +
- 2.0 * dkp * (a[60] + a[61] * p20mg +
- a[75] * 2.0 * dkp * dkp);
- da[ikp] = dakp * akp[2];
- da[ikp + 1] = da[ikp] * c2fi;
- final double dkpm = akp[3] + a[ikpm] * akp[4];
- final double dakpm = a[64] + a[65] * p20mg + a[72] * p40mg +
- 2.0 * dkpm * (a[66] + a[73] * p20mg +
- a[76] * 2.0 * dkpm * dkpm);
- da[ikpm] = dakpm * akp[4];
- da[7] = dkp;
- da[8] = p20mg * dkp;
- da[68] = p40mg * dkp;
- da[60] = dkp * dkp;
- da[61] = p20mg * da[60];
- da[75] = da[60] * da[60];
- da[64] = dkpm;
- da[65] = p20mg * dkpm;
- da[72] = p40mg * dkpm;
- da[66] = dkpm * dkpm;
- da[73] = p20mg * da[66];
- da[76] = da[66] * da[66];
- // non-periodic g(l) function
- double f0 = a[4] * da[4] + a[5] * da[5] + a[6] * da[6] +
- a[69] * da[69] + a[82] * da[82] + a[83] * da[83] +
- a[84] * da[84] + a[85] * da[85] + a[86] * da[86] +
- a[87] * da[87];
- final double f1f = 1.0 + f0 * ff0;
- f0 = f0 + a[2] * da[2] + a[3] * da[3] + a74 * da[74] +
- a77 * da[77] + a[7] * da[7] + a[8] * da[8] +
- a[60] * da[60] + a[61] * da[61] + a[68] * da[68] +
- a[64] * da[64] + a[65] * da[65] + a[66] * da[66] +
- a[72] * da[72] + a[73] * da[73] + a[75] * da[75] +
- a[76] * da[76] + a78 * da[78] + a[79] * da[79];
- // termes annuels symetriques en latitude
- da[9] = FastMath.cos(ROT * (day - a[11]));
- da[10] = p20 * da[9];
- // termes semi-annuels symetriques en latitude
- da[12] = FastMath.cos(ROT2 * (day - a[14]));
- da[13] = p20 * da[12];
- // termes annuels non symetriques en latitude
- final double coste = FastMath.cos(ROT * (day - a[18]));
- da[15] = p10 * coste;
- da[16] = p30 * coste;
- da[17] = p50 * coste;
- // terme semi-annuel non symetrique en latitude
- final double cos2te = FastMath.cos(ROT2 * (day - a[20]));
- da[19] = p10 * cos2te;
- da[39] = p30 * cos2te;
- da[59] = p50 * cos2te;
- // termes diurnes [et couples annuel]
- da[21] = p11 * ch;
- da[22] = p31 * ch;
- da[23] = p51 * ch;
- da[24] = da[21] * coste;
- da[25] = p21 * ch * coste;
- da[26] = p11 * sh;
- da[27] = p31 * sh;
- da[28] = p51 * sh;
- da[29] = da[26] * coste;
- da[30] = p21 * sh * coste;
- // termes semi-diurnes [et couples annuel]
- da[31] = p22 * c2h;
- da[37] = p42 * c2h;
- da[32] = p32 * c2h * coste;
- da[33] = p22 * s2h;
- da[38] = p42 * s2h;
- da[34] = p32 * s2h * coste;
- da[88] = p32 * c2h;
- da[89] = p32 * s2h;
- da[90] = p52 * c2h;
- da[91] = p52 * s2h;
- double a88 = a[88];
- double a89 = a[89];
- double a90 = a[90];
- double a91 = a[91];
- if (kle_eq == -1) { //hiver
- a88 = -a88;
- a89 = -a89;
- a90 = -a90;
- a91 = -a91;
- }
- if (kle_eq == 0) { //equinox
- a88 = semestrialCorrection(a88);
- a89 = semestrialCorrection(a89);
- a90 = semestrialCorrection(a90);
- a91 = semestrialCorrection(a91);
- }
- da[92] = p62 * c2h;
- da[93] = p62 * s2h;
- // termes ter-diurnes
- da[35] = p33 * c3h;
- da[36] = p33 * s3h;
- // fonction g[l] periodique
- double fp = a[9] * da[9] + a[10] * da[10] + a[12] * da[12] + a[13] * da[13] +
- a[15] * da[15] + a[16] * da[16] + a[17] * da[17] + a[19] * da[19] +
- a[21] * da[21] + a[22] * da[22] + a[23] * da[23] + a[24] * da[24] +
- a[25] * da[25] + a[26] * da[26] + a[27] * da[27] + a[28] * da[28] +
- a[29] * da[29] + a[30] * da[30] + a[31] * da[31] + a[32] * da[32] +
- a[33] * da[33] + a[34] * da[34] + a[35] * da[35] + a[36] * da[36] +
- a[37] * da[37] + a[38] * da[38] + a[39] * da[39] + a[59] * da[59] +
- a88 * da[88] + a89 * da[89] + a90 * da[90] + a91 * da[91] +
- a[92] * da[92] + a[93] * da[93];
- // termes d'activite magnetique
- da[40] = p10 * coste * dkp;
- da[41] = p30 * coste * dkp;
- da[42] = p50 * coste * dkp;
- da[43] = p11 * ch * dkp;
- da[44] = p31 * ch * dkp;
- da[45] = p51 * ch * dkp;
- da[46] = p11 * sh * dkp;
- da[47] = p31 * sh * dkp;
- da[48] = p51 * sh * dkp;
- // fonction g[l] periodique supplementaire
- fp += a[40] * da[40] + a[41] * da[41] + a[42] * da[42] + a[43] * da[43] +
- a[44] * da[44] + a[45] * da[45] + a[46] * da[46] + a[47] * da[47] +
- a[48] * da[48];
- dakp = (a[40] * p10 + a[41] * p30 + a[42] * p50) * coste +
- (a[43] * p11 + a[44] * p31 + a[45] * p51) * ch +
- (a[46] * p11 + a[47] * p31 + a[48] * p51) * sh;
- da[ikp] += dakp * akp[2];
- da[ikp + 1] = da[ikp] + dakp * c2fi * akp[2];
- // termes de longitude
- da[49] = p11 * clfl;
- da[50] = p21 * clfl;
- da[51] = p31 * clfl;
- da[52] = p41 * clfl;
- da[53] = p51 * clfl;
- da[54] = p11 * slfl;
- da[55] = p21 * slfl;
- da[56] = p31 * slfl;
- da[57] = p41 * slfl;
- da[58] = p51 * slfl;
- // fonction g[l] periodique supplementaire
- fp += a[49] * da[49] + a[50] * da[50] + a[51] * da[51] + a[52] * da[52] +
- a[53] * da[53] + a[54] * da[54] + a[55] * da[55] + a[56] * da[56] +
- a[57] * da[57] + a[58] * da[58];
- // fonction g(l) totale (couplage avec le flux)
- return f0 + fp * f1f;
- }
- /** Apply a correction coefficient to the given parameter.
- * @param param the parameter to correct
- * @return the corrected parameter
- */
- private double semestrialCorrection(final double param) {
- final int debeq_pr = 59;
- final int debeq_au = 244;
- final double result;
- if (day >= 100) {
- final double xmult = (day - debeq_au) / 40.0;
- result = param - 2.0 * param * xmult;
- } else {
- final double xmult = (day - debeq_pr) / 40.0;
- result = 2.0 * param * xmult - param;
- }
- return result;
- }
- }
- /** Local holder for intermediate results ensuring the model is reentrant.
- * @param <T> type of the field elements
- */
- private static class FieldComputation<T extends RealFieldElement<T>> {
- /** Number of days in current year. */
- private int day;
- /** Instant solar flux. f[1] = instantaneous flux; f[2] = 0. (not used). */
- private double[] f = new double[3];
- /** Mean solar flux. fbar[1] = mean flux; fbar[2] = 0. (not used). */
- private double[] fbar = new double[3];
- /** Kp coefficients.
- * <ul>
- * <li>akp[1] = 3-hourly kp</li>
- * <li>akp[2] = 0 (not used)</li>
- * <li>akp[3] = mean kp of last 24 hours</li>
- * <li>akp[4] = 0 (not used)</li>
- * </ul>
- */
- private double[] akp = new double[5];
- /** Cosine of the longitude. */
- private final T clfl;
- /** Sine of the longitude. */
- private final T slfl;
- /** Total density (g/cm3). */
- private final T ro;
- // CHECKSTYLE: stop JavadocVariable check
- /** Legendre coefficients. */
- private final T p10;
- private final T p20;
- private final T p30;
- private final T p40;
- private final T p50;
- private final T p60;
- private final T p11;
- private final T p21;
- private final T p31;
- private final T p41;
- private final T p51;
- private final T p22;
- private final T p32;
- private final T p42;
- private final T p52;
- private final T p62;
- private final T p33;
- private final T p10mg;
- private final T p20mg;
- private final T p40mg;
- /** Local time intermediate values. */
- private final T hl0;
- private final T ch;
- private final T sh;
- private final T c2h;
- private final T s2h;
- private final T c3h;
- private final T s3h;
- /** Simple constructor.
- * @param day day of year
- * @param altiKM altitude <em>in kilometers</em>
- * @param lon local longitude (rad)
- * @param lat local latitude (rad)
- * @param hl local solar time in rad (O hr = 0 rad)
- * @param f instantaneous solar flux (F10.7)
- * @param far mean solar flux (F10.7)
- * @param akp geomagnetic activity index
- */
- FieldComputation(final int day,
- final T altiKM, final T lon, final T lat,
- final T hl, final double[] f, final double[] far,
- final double[] akp) {
- this.day = day;
- this.f = f;
- this.fbar = far;
- this.akp = akp;
- // compute Legendre polynomials wrt geographic pole
- final T c = lat.sin();
- final T c2 = c.multiply(c);
- final T c4 = c2.multiply(c2);
- final T s = lat.cos();
- final T s2 = s.multiply(s);
- p10 = c;
- p20 = c2.multiply(1.5).subtract(0.5);
- p30 = c.multiply(c2.multiply(2.5).subtract(1.5));
- p40 = c4.multiply(4.375).subtract(c2.multiply(3.75)).add(0.375);
- p50 = c.multiply(c4.multiply(7.875).subtract(c2.multiply(8.75)).add(1.875));
- p60 = (c.multiply(5.5).multiply(p50).subtract(p40.multiply(2.5))).divide(3.0);
- p11 = s;
- p21 = c.multiply(3.0).multiply(s);
- p31 = s.multiply(c2.multiply(7.5).subtract(1.5));
- p41 = c.multiply(s).multiply(c2.multiply(17.5).subtract(7.5));
- p51 = s.multiply(c4.multiply(39.375).subtract(c2.multiply(26.25)).add(1.875));
- p22 = s2.multiply(3.0);
- p32 = c.multiply(15.0).multiply(s2);
- p42 = s2.multiply(c2.multiply(52.5).subtract(7.5));
- p52 = c.multiply(3.0).multiply(p42).subtract(p32.multiply(2.0));
- p62 = c.multiply(2.75).multiply(p52).subtract(p42.multiply(1.75));
- p33 = s.multiply(15.0).multiply(s2);
- // compute Legendre polynomials wrt magnetic pole (79N, 71W)
- final T clmlmg = lon.subtract(XLMG).cos();
- final T cmg = s.multiply(CPMG).multiply(clmlmg).add(c.multiply(SPMG));
- final T cmg2 = cmg.multiply(cmg);
- final T cmg4 = cmg2.multiply(cmg2);
- p10mg = cmg;
- p20mg = cmg2.multiply(1.5).subtract(0.5);
- p40mg = cmg4.multiply(4.375).subtract(cmg2.multiply(3.75)).add(0.375);
- clfl = lon.cos();
- slfl = lon.sin();
- // local time
- hl0 = hl;
- ch = hl0.cos();
- sh = hl0.sin();
- c2h = ch.multiply(ch).subtract(sh.multiply(sh));
- s2h = ch.multiply(sh).multiply(2);
- c3h = c2h.multiply(ch).subtract(s2h.multiply(sh));
- s3h = s2h.multiply(ch).add(c2h.multiply(sh));
- final double zlb = ZLB0; // + dzlb ??
- final T[] dtt = MathArrays.buildArray(altiKM.getField(), tt.length);
- final T[] dh = MathArrays.buildArray(altiKM.getField(), tt.length);
- final T[] dhe = MathArrays.buildArray(altiKM.getField(), tt.length);
- final T[] dox = MathArrays.buildArray(altiKM.getField(), tt.length);
- final T[] daz2 = MathArrays.buildArray(altiKM.getField(), tt.length);
- final T[] do2 = MathArrays.buildArray(altiKM.getField(), tt.length);
- final T[] daz = MathArrays.buildArray(altiKM.getField(), tt.length);
- final T[] dt0 = MathArrays.buildArray(altiKM.getField(), tt.length);
- final T[] dtp = MathArrays.buildArray(altiKM.getField(), tt.length);
- // compute function g(l) / tinf, t120, tp120
- int kleq = 1;
- final T gdelt = gFunction(tt, dtt, 1, kleq);
- dtt[1] = gdelt.add(1);
- final T tinf = dtt[1].multiply(tt[1]);
- kleq = 0; // equinox
- if ((day < 59) || (day > 284)) {
- kleq = -1; // north winter
- }
- if ((day > 99) && (day < 244)) {
- kleq = 1; // north summer
- }
- final T gdelt0 = gFunction(t0, dt0, 0, kleq);
- dt0[1] = gdelt0.add(t0[1]).divide(t0[1]);
- final T t120 = gdelt0.add(t0[1]);
- final T gdeltp = gFunction(tp, dtp, 0, kleq);
- dtp[1] = gdeltp.add(tp[1]).divide(tp[1]);
- final T tp120 = gdeltp.add(tp[1]);
- // compute n(z) concentrations: H, He, O, N2, O2, N
- final T sigma = tp120.divide(tinf.subtract(t120));
- final T dzeta = altiKM.add(RE).reciprocal().multiply(zlb + RE);
- final T zeta = altiKM.subtract(zlb).multiply(dzeta);
- final T sigzeta = sigma.multiply(zeta);
- final T expsz = sigzeta.negate().exp();
- final T tz = tinf.subtract(tinf.subtract(t120).multiply(expsz));
- final T[] dbase = MathArrays.buildArray(altiKM.getField(), 7);
- kleq = 1;
- final T gdelh = gFunction(h, dh, 0, kleq);
- dh[1] = gdelh.exp();
- dbase[1] = dh[1].multiply(h[1]);
- final T gdelhe = gFunction(he, dhe, 0, kleq);
- dhe[1] = gdelhe.exp();
- dbase[2] = dhe[1].multiply(he[1]);
- final T gdelo = gFunction(o, dox, 1, kleq);
- dox[1] = gdelo.exp();
- dbase[3] = dox[1].multiply(o[1]);
- final T gdelaz2 = gFunction(az2, daz2, 1, kleq);
- daz2[1] = gdelaz2.exp();
- dbase[4] = daz2[1].multiply(az2[1]);
- final T gdelo2 = gFunction(o2, do2, 1, kleq);
- do2[1] = gdelo2.exp();
- dbase[5] = do2[1].multiply(o2[1]);
- final T gdelaz = gFunction(az, daz, 1, kleq);
- daz[1] = gdelaz.exp();
- dbase[6] = daz[1].multiply(az[1]);
- final double zlbre = 1.0 + zlb / RE;
- final T glb = sigma.multiply(RGAS).multiply(tinf).reciprocal().multiply(GSURF / (zlbre * zlbre));
- final T t120tz = t120.divide(tz);
- // Partial densities in (g/cm3).
- // d(1) = hydrogen
- // d(2) = helium
- // d(3) = atomic oxygen
- // d(4) = molecular nitrogen
- // d(5) = molecular oxygen
- // d(6) = atomic nitrogen
- T tmpro = altiKM.getField().getZero();
- for (int i = 1; i <= 6; i++) {
- final T gamma = glb.multiply(MA[i]);
- final T upapg = gamma.add(1.0 + ALEFA[i]);
- final T fzI = t120tz.pow(upapg).multiply(sigzeta.negate().multiply(gamma).exp());
- // concentrations of H, He, O, N2, O2, N (particles/cm³)
- final T ccI = dbase[i].multiply(fzI);
- // contribution of densities of H, He, O, N2, O2, N (g/cm³)
- tmpro = tmpro.add(ccI.multiply(VMA[i]));
- }
- this.ro = tmpro;
- }
- /** Computation of function G.
- * @param a vector of coefficients for computation
- * @param da vector of partial derivatives
- * @param ff0 coefficient flag (1 for Ox, Az, He, T°; 0 for H and tp120)
- * @param kle_eq season indicator flag (summer, winter, equinox)
- * @return value of G
- */
- private T gFunction(final double[] a, final T[] da,
- final int ff0, final int kle_eq) {
- final T zero = da[0].getField().getZero();
- final double[] fmfb = new double[3];
- final double[] fbm150 = new double[3];
- // latitude terms
- da[2] = p20;
- da[3] = p40;
- da[74] = p10;
- double a74 = a[74];
- double a77 = a[77];
- double a78 = a[78];
- if (kle_eq == -1) {
- // winter
- a74 = -a74;
- a77 = -a77;
- a78 = -a78;
- }
- if (kle_eq == 0 ) {
- // equinox
- a74 = semestrialCorrection(a74);
- a77 = semestrialCorrection(a77);
- a78 = semestrialCorrection(a78);
- }
- da[77] = p30;
- da[78] = p50;
- da[79] = p60;
- // flux terms
- fmfb[1] = f[1] - fbar[1];
- fmfb[2] = f[2] - fbar[2];
- fbm150[1] = fbar[1] - 150.0;
- fbm150[2] = fbar[2];
- da[4] = zero.add(fmfb[1]);
- da[6] = zero.add(fbm150[1]);
- da[4] = da[4].add(a[70] * fmfb[2]);
- da[6] = da[6].add(a[71] * fbm150[2]);
- da[70] = da[4].multiply(a[ 5]).multiply(2).
- add(p10.multiply(a[82])).
- add(p20.multiply(a[83])).
- add(p30.multiply(a[84])).
- add(a[4]).
- multiply(fmfb[2]);
- da[71] = da[6].multiply(a[69]).multiply(2).
- add(p10.multiply(a[85])).
- add(p20.multiply(a[86])).
- add(p30.multiply(a[87])).
- add(a[6]).
- multiply(fbm150[2]);
- da[5] = da[4].multiply(da[4]);
- da[69] = da[6].multiply(da[6]);
- da[82] = da[4].multiply(p10);
- da[83] = da[4].multiply(p20);
- da[84] = da[4].multiply(p30);
- da[85] = da[6].multiply(p20);
- da[86] = da[6].multiply(p30);
- da[87] = da[6].multiply(p40);
- // Kp terms
- final int ikp = 62;
- final int ikpm = 67;
- final T c2fi = p10mg.multiply(p10mg).negate().add(1);
- final T dkp = c2fi.multiply(a[ikp + 1]).add(a[ikp]).multiply(akp[2]).add(akp[1]);
- T dakp = p20mg.multiply(a[8]).add(p40mg.multiply(a[68])).
- add(p20mg.multiply(a[61]).add(dkp.multiply(dkp).multiply(2 * a[75]).add(a[60])).multiply(dkp.multiply(2))).
- add(a[7]);
- da[ikp] = dakp.multiply(akp[2]);
- da[ikp + 1] = da[ikp].multiply(c2fi);
- final double dkpm = akp[3] + a[ikpm] * akp[4];
- final T dakpm = p20mg.multiply(a[65]).add(p40mg.multiply(a[72])).
- add(p20mg.multiply(a[73]).add(a[66] + a[76] * 2.0 * dkpm * dkpm).multiply( 2.0 * dkpm)).
- add(a[64]);
- da[ikpm] = dakpm.multiply(akp[4]);
- da[7] = dkp;
- da[8] = p20mg.multiply(dkp);
- da[68] = p40mg.multiply(dkp);
- da[60] = dkp.multiply(dkp);
- da[61] = p20mg.multiply(da[60]);
- da[75] = da[60].multiply(da[60]);
- da[64] = zero.add(dkpm);
- da[65] = p20mg.multiply(dkpm);
- da[72] = p40mg.multiply(dkpm);
- da[66] = zero.add(dkpm * dkpm);
- da[73] = p20mg.multiply(da[66]);
- da[76] = da[66].multiply(da[66]);
- // non-periodic g(l) function
- T f0 = da[4].multiply(a[4]).
- add(da[5].multiply(a[5])).
- add(da[6].multiply(a[6])).
- add(da[69].multiply(a[69])).
- add(da[82].multiply(a[82])).
- add(da[83].multiply(a[83])).
- add(da[84].multiply(a[84])).
- add(da[85].multiply(a[85])).
- add(da[86].multiply(a[86])).
- add(da[87].multiply(a[87]));
- final T f1f = f0.multiply(ff0).add(1);
- f0 = f0.
- add(da[2].multiply(a[2])).
- add(da[3].multiply(a[3])).
- add(da[7].multiply(a[7])).
- add(da[8].multiply(a[8])).
- add(da[60].multiply(a[60])).
- add(da[61].multiply(a[61])).
- add(da[68].multiply(a[68])).
- add(da[64].multiply(a[64])).
- add(da[65].multiply(a[65])).
- add(da[66].multiply(a[66])).
- add(da[72].multiply(a[72])).
- add(da[73].multiply(a[73])).
- add(da[74].multiply(a74)).
- add(da[75].multiply(a[75])).
- add(da[76].multiply(a[76])).
- add(da[77].multiply(a77)).
- add(da[78].multiply(a78)).
- add(da[79].multiply(a[79]));
- // termes annuels symetriques en latitude
- da[9] = zero.add(FastMath.cos(ROT * (day - a[11])));
- da[10] = p20.multiply(da[9]);
- // termes semi-annuels symetriques en latitude
- da[12] = zero.add(FastMath.cos(ROT2 * (day - a[14])));
- da[13] = p20.multiply(da[12]);
- // termes annuels non symetriques en latitude
- final double coste = FastMath.cos(ROT * (day - a[18]));
- da[15] = p10.multiply(coste);
- da[16] = p30.multiply(coste);
- da[17] = p50.multiply(coste);
- // terme semi-annuel non symetrique en latitude
- final double cos2te = FastMath.cos(ROT2 * (day - a[20]));
- da[19] = p10.multiply(cos2te);
- da[39] = p30.multiply(cos2te);
- da[59] = p50.multiply(cos2te);
- // termes diurnes [et couples annuel]
- da[21] = p11.multiply(ch);
- da[22] = p31.multiply(ch);
- da[23] = p51.multiply(ch);
- da[24] = da[21].multiply(coste);
- da[25] = p21.multiply(ch).multiply(coste);
- da[26] = p11.multiply(sh);
- da[27] = p31.multiply(sh);
- da[28] = p51.multiply(sh);
- da[29] = da[26].multiply(coste);
- da[30] = p21.multiply(sh).multiply(coste);
- // termes semi-diurnes [et couples annuel]
- da[31] = p22.multiply(c2h);
- da[37] = p42.multiply(c2h);
- da[32] = p32.multiply(c2h).multiply(coste);
- da[33] = p22.multiply(s2h);
- da[38] = p42.multiply(s2h);
- da[34] = p32.multiply(s2h).multiply(coste);
- da[88] = p32.multiply(c2h);
- da[89] = p32.multiply(s2h);
- da[90] = p52.multiply(c2h);
- da[91] = p52.multiply(s2h);
- double a88 = a[88];
- double a89 = a[89];
- double a90 = a[90];
- double a91 = a[91];
- if (kle_eq == -1) { //hiver
- a88 = -a88;
- a89 = -a89;
- a90 = -a90;
- a91 = -a91;
- }
- if (kle_eq == 0) { //equinox
- a88 = semestrialCorrection(a88);
- a89 = semestrialCorrection(a89);
- a90 = semestrialCorrection(a90);
- a91 = semestrialCorrection(a91);
- }
- da[92] = p62.multiply(c2h);
- da[93] = p62.multiply(s2h);
- // termes ter-diurnes
- da[35] = p33.multiply(c3h);
- da[36] = p33.multiply(s3h);
- // fonction g[l] periodique
- T fp = da[ 9].multiply(a[ 9]) .add(da[10].multiply(a[10])).add(da[12].multiply(a[12])).add(da[13].multiply(a[13])).
- add(da[15].multiply(a[15])).add(da[16].multiply(a[16])).add(da[17].multiply(a[17])).add(da[19].multiply(a[19])).
- add(da[21].multiply(a[21])).add(da[22].multiply(a[22])).add(da[23].multiply(a[23])).add(da[24].multiply(a[24])).
- add(da[25].multiply(a[25])).add(da[26].multiply(a[26])).add(da[27].multiply(a[27])).add(da[28].multiply(a[28])).
- add(da[29].multiply(a[29])).add(da[30].multiply(a[30])).add(da[31].multiply(a[31])).add(da[32].multiply(a[32])).
- add(da[33].multiply(a[33])).add(da[34].multiply(a[34])).add(da[35].multiply(a[35])).add(da[36].multiply(a[36])).
- add(da[37].multiply(a[37])).add(da[38].multiply(a[38])).add(da[39].multiply(a[39])).add(da[59].multiply(a[59])).
- add(da[88].multiply(a88)) .add(da[89].multiply(a89) ).add(da[90].multiply(a90) ).add(da[91].multiply(a91) ).
- add(da[92].multiply(a[92])).add(da[93].multiply(a[93]));
- // termes d'activite magnetique
- da[40] = p10.multiply(coste).multiply(dkp);
- da[41] = p30.multiply(coste).multiply(dkp);
- da[42] = p50.multiply(coste).multiply(dkp);
- da[43] = p11.multiply(ch).multiply(dkp);
- da[44] = p31.multiply(ch).multiply(dkp);
- da[45] = p51.multiply(ch).multiply(dkp);
- da[46] = p11.multiply(sh).multiply(dkp);
- da[47] = p31.multiply(sh).multiply(dkp);
- da[48] = p51.multiply(sh).multiply(dkp);
- // fonction g[l] periodique supplementaire
- fp = fp.
- add(da[40].multiply(a[40])).
- add(da[41].multiply(a[41])).
- add(da[42].multiply(a[42])).
- add(da[43].multiply(a[43])).
- add(da[44].multiply(a[44])).
- add(da[45].multiply(a[45])).
- add(da[46].multiply(a[46])).
- add(da[47].multiply(a[47])).
- add(da[48].multiply(a[48]));
- dakp = p10.multiply(a[40]).add(p30.multiply(a[41])).add(p50.multiply(a[42])).multiply(coste).
- add(p11.multiply(a[40]).add(p31.multiply(a[44])).add(p51.multiply(a[45])).multiply(ch)).
- add(p11.multiply(a[46]).add(p31.multiply(a[47])).add(p51.multiply(a[48])).multiply(sh));
- da[ikp] = da[ikp].add(dakp.multiply(akp[2]));
- da[ikp + 1] = da[ikp].add(dakp.multiply(c2fi).multiply(akp[2]));
- // termes de longitude
- da[49] = p11.multiply(clfl);
- da[50] = p21.multiply(clfl);
- da[51] = p31.multiply(clfl);
- da[52] = p41.multiply(clfl);
- da[53] = p51.multiply(clfl);
- da[54] = p11.multiply(slfl);
- da[55] = p21.multiply(slfl);
- da[56] = p31.multiply(slfl);
- da[57] = p41.multiply(slfl);
- da[58] = p51.multiply(slfl);
- // fonction g[l] periodique supplementaire
- fp = fp.
- add(da[49].multiply(a[49])).
- add(da[50].multiply(a[50])).
- add(da[51].multiply(a[51])).
- add(da[52].multiply(a[52])).
- add(da[53].multiply(a[53])).
- add(da[54].multiply(a[54])).
- add(da[55].multiply(a[55])).
- add(da[56].multiply(a[56])).
- add(da[57].multiply(a[57])).
- add(da[58].multiply(a[58]));
- // fonction g(l) totale (couplage avec le flux)
- return f0.add(fp.multiply(f1f));
- }
- /** Apply a correction coefficient to the given parameter.
- * @param param the parameter to correct
- * @return the corrected parameter
- */
- private double semestrialCorrection(final double param) {
- final int debeq_pr = 59;
- final int debeq_au = 244;
- final double result;
- if (day >= 100) {
- final double xmult = (day - debeq_au) / 40.0;
- result = param - 2.0 * param * xmult;
- } else {
- final double xmult = (day - debeq_pr) / 40.0;
- result = 2.0 * param * xmult - param;
- }
- return result;
- }
- }
- }