HansenTesseralLinear.java
/* Copyright 2002-2015 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.propagation.semianalytical.dsst.utilities.hansen;
import org.apache.commons.math3.analysis.differentiation.DerivativeStructure;
import org.apache.commons.math3.analysis.polynomials.PolynomialFunction;
import org.apache.commons.math3.util.FastMath;
import org.orekit.propagation.semianalytical.dsst.utilities.NewcombOperators;
/**
* Hansen coefficients K(t,n,s) for t!=0 and n < 0.
* <p>
* Implements Collins 4-236 or Danielson 2.7.3-(9) for Hansen Coefficients and
* Collins 4-240 for derivatives. The recursions are transformed into
* composition of linear transformations to obtain the associated polynomials
* for coefficients and their derivatives - see Petre's paper
*
* @author Petre Bazavan
* @author Lucian Barbulescu
*/
public class HansenTesseralLinear {
/** The number of coefficients that will be computed with a set of roots. */
private static final int SLICE = 10;
/**
* The first vector of polynomials associated to Hansen coefficients and
* derivatives.
*/
private PolynomialFunction[][] mpvec;
/** The second vector of polynomials associated only to derivatives. */
private PolynomialFunction[][] mpvecDeriv;
/** The Hansen coefficients used as roots. */
private double[][] hansenRoot;
/** The derivatives of the Hansen coefficients used as roots. */
private double[][] hansenDerivRoot;
/** The minimum value for the order. */
private int Nmin;
/** The index of the initial condition, Petre's paper. */
private int N0;
/** The s coefficient. */
private int s;
/** The j coefficient. */
private int j;
/** The number of slices needed to compute the coefficients. */
private int numSlices;
/**
* The offset used to identify the polynomial that corresponds to a negative.
* value of n in the internal array that starts at 0
*/
private int offset;
/** The objects used to calculate initial data by means of Newcomb operators. */
private HansenCoefficientsBySeries[] hansenInit;
/**
* Constructor.
*
* @param nMax the maximum (absolute) value of n parameter
* @param s s parameter
* @param j j parameter
* @param n0 the minimum (absolute) value of n
* @param maxHansen maximum power of e2 in Hansen expansion
*/
public HansenTesseralLinear(final int nMax, final int s, final int j, final int n0, final int maxHansen) {
//Initialize the fields
this.offset = nMax + 1;
this.Nmin = -nMax - 1;
this.N0 = -n0 - 4;
this.s = s;
this.j = j;
//Ensure that only the needed terms are computed
final int maxRoots = FastMath.min(4, N0 - Nmin + 4);
this.hansenInit = new HansenCoefficientsBySeries[maxRoots];
for (int i = 0; i < maxRoots; i++) {
this.hansenInit[i] = new HansenCoefficientsBySeries(N0 - i + 3, s, j, maxHansen);
}
// The first 4 values are computed with series. No linear combination is needed.
final int size = N0 - Nmin;
this.numSlices = (int) FastMath.max(FastMath.ceil(((double) size) / SLICE), 1);
hansenRoot = new double[numSlices][4];
hansenDerivRoot = new double[numSlices][4];
if (size > 0) {
mpvec = new PolynomialFunction[size][];
mpvecDeriv = new PolynomialFunction[size][];
// Prepare the database of the associated polynomials
generatePolynomials();
}
}
/**
* Compute polynomial coefficient a.
*
* <p>
* It is used to generate the coefficient for K<sub>j</sub><sup>-n, s</sup> when computing K<sub>j</sub><sup>-n-1, s</sup>
* and the coefficient for dK<sub>j</sub><sup>-n, s</sup> / de² when computing dK<sub>j</sub><sup>-n-1, s</sup> / de²
* </p>
*
* <p>
* See Danielson 2.7.3-(9) and Collins 4-236 and 4-240
* </p>
*
* @param mnm1 -n-1
* @return the polynomial
*/
private PolynomialFunction a(final int mnm1) {
// Collins 4-236, Danielson 2.7.3-(9)
final double r1 = (mnm1 + 2.) * (2. * mnm1 + 5.);
final double r2 = (2. + mnm1 + s) * (2. + mnm1 - s);
return new PolynomialFunction(new double[] {
0.0, 0.0, r1 / r2
});
}
/**
* Compute polynomial coefficient b.
*
* <p>
* It is used to generate the coefficient for K<sub>j</sub><sup>-n+1, s</sup> when computing K<sub>j</sub><sup>-n-1, s</sup>
* and the coefficient for dK<sub>j</sub><sup>-n+1, s</sup> / de² when computing dK<sub>j</sub><sup>-n-1, s</sup> / de²
* </p>
*
* <p>
* See Danielson 2.7.3-(9) and Collins 4-236 and 4-240
* </p>
*
* @param mnm1 -n-1
* @return the polynomial
*/
private PolynomialFunction b(final int mnm1) {
// Collins 4-236, Danielson 2.7.3-(9)
final double r2 = (2. + mnm1 + s) * (2. + mnm1 - s);
final double d1 = (mnm1 + 3.) * 2. * j * s / (r2 * (mnm1 + 4.));
final double d2 = (mnm1 + 3.) * (mnm1 + 2.) / r2;
return new PolynomialFunction(new double[] {
0.0, -d1, -d2
});
}
/**
* Compute polynomial coefficient c.
*
* <p>
* It is used to generate the coefficient for K<sub>j</sub><sup>-n+3, s</sup> when computing K<sub>j</sub><sup>-n-1, s</sup>
* and the coefficient for dK<sub>j</sub><sup>-n+3, s</sup> / de² when computing dK<sub>j</sub><sup>-n-1, s</sup> / de²
* </p>
*
* <p>
* See Danielson 2.7.3-(9) and Collins 4-236 and 4-240
* </p>
*
* @param mnm1 -n-1
* @return the polynomial
*/
private PolynomialFunction c(final int mnm1) {
// Collins 4-236, Danielson 2.7.3-(9)
final double r1 = j * j * (mnm1 + 2.);
final double r2 = (mnm1 + 4.) * (2. + mnm1 + s) * (2. + mnm1 - s);
return new PolynomialFunction(new double[] {
0.0, 0.0, r1 / r2
});
}
/**
* Compute polynomial coefficient d.
*
* <p>
* It is used to generate the coefficient for K<sub>j</sub><sup>-n-1, s</sup> / dχ when computing dK<sub>j</sub><sup>-n-1, s</sup> / de²
* </p>
*
* <p>
* See Danielson 2.7.3-(9) and Collins 4-236 and 4-240
* </p>
*
* @param mnm1 -n-1
* @return the polynomial
*/
private PolynomialFunction d(final int mnm1) {
// Collins 4-236, Danielson 2.7.3-(9)
return new PolynomialFunction(new double[] {
0.0, 0.0, 1.0
});
}
/**
* Compute polynomial coefficient f.
*
* <p>
* It is used to generate the coefficient for K<sub>j</sub><sup>-n+1, s</sup> / dχ when computing dK<sub>j</sub><sup>-n-1, s</sup> / de²
* </p>
*
* <p>
* See Danielson 2.7.3-(9) and Collins 4-236 and 4-240
* </p>
*
* @param n index
* @return the polynomial
*/
private PolynomialFunction f(final int n) {
// Collins 4-236, Danielson 2.7.3-(9)
final double r1 = (n + 3.0) * j * s;
final double r2 = (n + 4.0) * (2.0 + n + s) * (2.0 + n - s);
return new PolynomialFunction(new double[] {
0.0, 0.0, 0.0, r1 / r2
});
}
/**
* Generate the polynomials needed in the linear transformation.
*
* <p>
* See Petre's paper
* </p>
*/
private void generatePolynomials() {
// Initialization of the matrices for linear transformations
// The final configuration of these matrices are obtained by composition
// of linear transformations
// The matrix of polynomials associated to Hansen coefficients, Petre's
// paper
PolynomialFunctionMatrix A = HansenUtilities.buildIdentityMatrix4();
// The matrix of polynomials associated to derivatives, Petre's paper
final PolynomialFunctionMatrix B = HansenUtilities.buildZeroMatrix4();
PolynomialFunctionMatrix D = HansenUtilities.buildZeroMatrix4();
final PolynomialFunctionMatrix a = HansenUtilities.buildZeroMatrix4();
// The matrix of the current linear transformation
a.setMatrixLine(0, new PolynomialFunction[] {
HansenUtilities.ZERO, HansenUtilities.ONE, HansenUtilities.ZERO, HansenUtilities.ZERO
});
a.setMatrixLine(1, new PolynomialFunction[] {
HansenUtilities.ZERO, HansenUtilities.ZERO, HansenUtilities.ONE, HansenUtilities.ZERO
});
a.setMatrixLine(2, new PolynomialFunction[] {
HansenUtilities.ZERO, HansenUtilities.ZERO, HansenUtilities.ZERO, HansenUtilities.ONE
});
// The generation process
int index;
int sliceCounter = 0;
for (int i = N0 - 1; i > Nmin - 1; i--) {
index = i + this.offset;
// The matrix of the current linear transformation is updated
// Petre's paper
a.setMatrixLine(3, new PolynomialFunction[] {
c(i), HansenUtilities.ZERO, b(i), a(i)
});
// composition of the linear transformations to calculate
// the polynomials associated to Hansen coefficients
// Petre's paper
A = A.multiply(a);
// store the polynomials for Hansen coefficients
mpvec[index] = A.getMatrixLine(3);
// composition of the linear transformations to calculate
// the polynomials associated to derivatives
// Petre's paper
D = D.multiply(a);
//Update the B matrix
B.setMatrixLine(3, new PolynomialFunction[] {
HansenUtilities.ZERO, f(i),
HansenUtilities.ZERO, d(i)
});
D = D.add(A.multiply(B));
// store the polynomials for Hansen coefficients from the
// expressions of derivatives
mpvecDeriv[index] = D.getMatrixLine(3);
if (++sliceCounter % SLICE == 0) {
// Re-Initialisation of matrix for linear transformmations
// The final configuration of these matrix are obtained by composition
// of linear transformations
A = HansenUtilities.buildIdentityMatrix4();
D = HansenUtilities.buildZeroMatrix4();
}
}
}
/**
* Compute the values for the first four coefficients and their derivatives by means of series.
*
* @param e2 e²
* @param chi Χ
* @param chi2 Χ²
*/
public void computeInitValues(final double e2, final double chi, final double chi2) {
// compute the values for n, n+1, n+2 and n+3 by series
// See Danielson 2.7.3-(10)
//Ensure that only the needed terms are computed
final int maxRoots = FastMath.min(4, N0 - Nmin + 4);
for (int i = 0; i < maxRoots; i++) {
final DerivativeStructure hansenKernel = hansenInit[i].getValue(e2, chi, chi2);
this.hansenRoot[0][i] = hansenKernel.getValue();
this.hansenDerivRoot[0][i] = hansenKernel.getPartialDerivative(1);
}
for (int i = 1; i < numSlices; i++) {
for (int k = 0; k < 4; k++) {
final PolynomialFunction[] mv = mpvec[N0 - (i * SLICE) - k + 3 + offset];
final PolynomialFunction[] sv = mpvecDeriv[N0 - (i * SLICE) - k + 3 + offset];
hansenDerivRoot[i][k] = mv[3].value(chi) * hansenDerivRoot[i - 1][3] +
mv[2].value(chi) * hansenDerivRoot[i - 1][2] +
mv[1].value(chi) * hansenDerivRoot[i - 1][1] +
mv[0].value(chi) * hansenDerivRoot[i - 1][0] +
sv[3].value(chi) * hansenRoot[i - 1][3] +
sv[2].value(chi) * hansenRoot[i - 1][2] +
sv[1].value(chi) * hansenRoot[i - 1][1] +
sv[0].value(chi) * hansenRoot[i - 1][0];
hansenRoot[i][k] = mv[3].value(chi) * hansenRoot[i - 1][3] +
mv[2].value(chi) * hansenRoot[i - 1][2] +
mv[1].value(chi) * hansenRoot[i - 1][1] +
mv[0].value(chi) * hansenRoot[i - 1][0];
}
}
}
/**
* Compute the value of the Hansen coefficient K<sub>j</sub><sup>-n-1, s</sup>.
*
* @param mnm1 -n-1
* @param chi χ
* @return the coefficient K<sub>j</sub><sup>-n-1, s</sup>
*/
public double getValue(final int mnm1, final double chi) {
//Compute n
final int n = -mnm1 - 1;
//Compute the potential slice
int sliceNo = (n + N0 + 4) / SLICE;
if (sliceNo < numSlices) {
//Compute the index within the slice
final int indexInSlice = (n + N0 + 4) % SLICE;
//Check if a root must be returned
if (indexInSlice <= 3) {
return hansenRoot[sliceNo][indexInSlice];
}
} else {
//the value was a potential root for a slice, but that slice was not required
//Decrease the slice number
sliceNo--;
}
// Computes the coefficient by linear transformation
// Danielson 2.7.3-(9) or Collins 4-236 and Petre's paper
final PolynomialFunction[] v = mpvec[mnm1 + offset];
return v[3].value(chi) * hansenRoot[sliceNo][3] +
v[2].value(chi) * hansenRoot[sliceNo][2] +
v[1].value(chi) * hansenRoot[sliceNo][1] +
v[0].value(chi) * hansenRoot[sliceNo][0];
}
/**
* Compute the value of the derivative dK<sub>j</sub><sup>-n-1, s</sup> / de².
*
* @param mnm1 -n-1
* @param chi χ
* @return the derivative dK<sub>j</sub><sup>-n-1, s</sup> / de²
*/
public double getDerivative(final int mnm1, final double chi) {
//Compute n
final int n = -mnm1 - 1;
//Compute the potential slice
int sliceNo = (n + N0 + 4) / SLICE;
if (sliceNo < numSlices) {
//Compute the index within the slice
final int indexInSlice = (n + N0 + 4) % SLICE;
//Check if a root must be returned
if (indexInSlice <= 3) {
return hansenDerivRoot[sliceNo][indexInSlice];
}
} else {
//the value was a potential root for a slice, but that slice was not required
//Decrease the slice number
sliceNo--;
}
// Computes the coefficient by linear transformation
// Danielson 2.7.3-(9) or Collins 4-236 and Petre's paper
final PolynomialFunction[] v = mpvec[mnm1 + this.offset];
final PolynomialFunction[] vv = mpvecDeriv[mnm1 + this.offset];
return v[3].value(chi) * hansenDerivRoot[sliceNo][3] +
v[2].value(chi) * hansenDerivRoot[sliceNo][2] +
v[1].value(chi) * hansenDerivRoot[sliceNo][1] +
v[0].value(chi) * hansenDerivRoot[sliceNo][0] +
vv[3].value(chi) * hansenRoot[sliceNo][3] +
vv[2].value(chi) * hansenRoot[sliceNo][2] +
vv[1].value(chi) * hansenRoot[sliceNo][1] +
vv[0].value(chi) * hansenRoot[sliceNo][0];
}
/**
* Compute a Hansen coefficient with series.
* <p>
* This class implements the computation of the Hansen kernels
* through a power series in e² and that is using
* modified Newcomb operators. The reference formulae can be found
* in Danielson 2.7.3-10 and 3.3-5
* </p>
*/
private static class HansenCoefficientsBySeries {
/** -n-1 coefficient. */
private final int mnm1;
/** s coefficient. */
private final int s;
/** j coefficient. */
private final int j;
/** Max power in e² for the Newcomb's series expansion. */
private final int maxNewcomb;
/** Polynomial representing the serie. */
private PolynomialFunction polynomial;
/**
* Class constructor.
*
* @param mnm1 -n-1 value
* @param s s value
* @param j j value
* @param maxHansen max power of e² in series expansion
*/
public HansenCoefficientsBySeries(final int mnm1, final int s,
final int j, final int maxHansen) {
this.mnm1 = mnm1;
this.s = s;
this.j = j;
this.maxNewcomb = maxHansen;
this.polynomial = generatePolynomial();
}
/** Computes the value of Hansen kernel and its derivative at e².
* <p>
* The formulae applied are described in Danielson 2.7.3-10 and
* 3.3-5
* </p>
* @param e2 e²
* @param chi Χ
* @param chi2 Χ²
* @return the value of the Hansen coefficient and its derivative for e²
*/
public DerivativeStructure getValue(final double e2, final double chi, final double chi2) {
//Estimation of the serie expansion at e2
final DerivativeStructure serie = polynomial.value(
new DerivativeStructure(1, 1, 0, e2));
final double value = FastMath.pow(chi2, -mnm1 - 1) * serie.getValue() / chi;
final double coef = -(mnm1 + 1.5);
final double derivative = coef * chi2 * value +
FastMath.pow(chi2, -mnm1 - 1) * serie.getPartialDerivative(1) / chi;
return new DerivativeStructure(1, 1, value, derivative);
}
/** Generate the serie expansion in e².
* <p>
* Generate the series expansion in e² used in the formulation
* of the Hansen kernel (see Danielson 2.7.3-10):
* Σ Y<sup>ns</sup><sub>α+a,α+b</sub>
* *e<sup>2α</sup>
* </p>
* @return polynomial representing the power serie expansion
*/
private PolynomialFunction generatePolynomial() {
// Initialization
final int aHT = FastMath.max(j - s, 0);
final int bHT = FastMath.max(s - j, 0);
final double[] coefficients = new double[maxNewcomb + 1];
//Loop for getting the Newcomb operators
for (int alphaHT = 0; alphaHT <= maxNewcomb; alphaHT++) {
coefficients[alphaHT] =
NewcombOperators.getValue(alphaHT + aHT, alphaHT + bHT, mnm1, s);
}
//Creation of the polynomial
return new PolynomialFunction(coefficients);
}
}
}