private void generateGeometry() {
double odmm = oD.doubleValue(SI.MILLIMETER);
double idmm = iD.doubleValue(SI.MILLIMETER);
double fwmm = finWidth.doubleValue(SI.MILLIMETER);
double fdmm = finDiameter.doubleValue(SI.MILLIMETER);
xsection = new BurningShape();
Shape outside = new Ellipse2D.Double(-odmm / 2, -odmm / 2, odmm, odmm);
xsection.add(outside);
xsection.inhibit(outside);
xsection.subtract(new Ellipse2D.Double(-idmm / 2, -idmm / 2, idmm, idmm));
webThickness = null;
for (int i = 0; i < finCount; i++) {
Shape fin = new Rectangle2D.Double(-fwmm / 2, 0, fwmm, fdmm / 2);
xsection.subtract(fin, AffineTransform.getRotateInstance(i * (2.0 * Math.PI / finCount)));
}
}
public static List<Double> calcCmDistributionLiftingSurfaceWithIntegral(
NasaBlackwell theNasaBlackwellCalculator,
Amount<Angle> angleOfAttack,
List<Amount<Length>> liftingSurfaceDimensionalY,
List<Double> liftingSurfaceCl0Distribution, // all distributions must have the same length!!
List<Double> liftingSurfaceCLAlphaDegDistribution,
List<Double> liftingSurfaceCmACDistribution,
List<Double> liftingSurfaceXACadimensionalDistribution,
List<Amount<Length>> liftingSurfaceChordDistribution,
List<Amount<Length>> liftingSurfaceXLEDistribution,
List<List<Double>>
airfoilClMatrix, // this is a list of list. each list is referred to an airfoil along the
// semispan
List<Amount<Angle>>
anglesOfAttackClMatrix, // references angle of attack of the list of list airfoilClMatrix
Amount<Length> momentumPole // referred to the origin of LRF
) {
List<Double> cmDistribution = new ArrayList<>();
double[] distancesArrayAC,
clDistribution,
alphaDistribution,
clInducedDistributionAtAlphaNew,
xcPfracC;
int numberOfPointSemiSpanWise = liftingSurfaceCl0Distribution.size();
clDistribution = new double[numberOfPointSemiSpanWise];
alphaDistribution = new double[numberOfPointSemiSpanWise];
clInducedDistributionAtAlphaNew = new double[numberOfPointSemiSpanWise];
distancesArrayAC = new double[numberOfPointSemiSpanWise];
xcPfracC = new double[numberOfPointSemiSpanWise];
theNasaBlackwellCalculator.calculate(angleOfAttack);
clDistribution = theNasaBlackwellCalculator.getClTotalDistribution().toArray();
for (int ii = 0; ii < numberOfPointSemiSpanWise; ii++) {
alphaDistribution[ii] =
(clDistribution[ii] - liftingSurfaceCl0Distribution.get(ii))
/ liftingSurfaceCLAlphaDegDistribution.get(ii);
if (alphaDistribution[ii] < angleOfAttack.doubleValue(NonSI.DEGREE_ANGLE)) {
clInducedDistributionAtAlphaNew[ii] =
liftingSurfaceCLAlphaDegDistribution.get(ii) * alphaDistribution[ii]
+ liftingSurfaceCl0Distribution.get(ii);
} else {
clInducedDistributionAtAlphaNew[ii] =
MyMathUtils.getInterpolatedValue1DLinear(
MyArrayUtils.convertListOfAmountTodoubleArray(anglesOfAttackClMatrix),
MyArrayUtils.convertToDoublePrimitive(
MyArrayUtils.convertListOfDoubleToDoubleArray(airfoilClMatrix.get(ii))),
alphaDistribution[ii]);
}
xcPfracC[ii] =
liftingSurfaceXACadimensionalDistribution.get(ii)
- (liftingSurfaceCmACDistribution.get(ii) / clInducedDistributionAtAlphaNew[ii]);
distancesArrayAC[ii] =
momentumPole.doubleValue(SI.METER)
- (liftingSurfaceXLEDistribution.get(ii).doubleValue(SI.METER)
+ (xcPfracC[ii] * liftingSurfaceChordDistribution.get(ii).doubleValue(SI.METER)));
cmDistribution.add(
ii,
clInducedDistributionAtAlphaNew[ii]
* (distancesArrayAC[ii]
/ liftingSurfaceChordDistribution.get(ii).doubleValue(SI.METER)));
}
cmDistribution.set(numberOfPointSemiSpanWise - 1, 0.);
return cmDistribution;
}
public static List<Double> calcCMLiftingSurfaceWithIntegralACVariable(
NasaBlackwell theNasaBlackwellCalculator,
List<Amount<Angle>> anglesOfAttack,
Amount<Length> liftingSurfaceMAC,
List<Amount<Length>> liftingSurfaceDimensionalY,
List<Double> liftingSurfaceCl0Distribution, // all distributions must have the same length!!
List<Double> liftingSurfaceCLAlphaDegDistribution,
List<Double> liftingSurfaceCLforCMMatrix,
List<List<Double>> liftingSurfaceCmACDistribution,
List<Double> liftingSurfaceXACadimensionalDistribution,
List<Amount<Length>> liftingSurfaceChordDistribution,
List<Amount<Length>> liftingSurfaceXLEDistribution,
List<List<Double>>
airfoilClMatrix, // this is a list of list. each list is referred to an airfoil along the
// semispan
List<Amount<Angle>>
anglesOfAttackClMatrix, // references angle of attack of the list of list airfoilClMatrix
Amount<Area> liftingSurfaceArea,
Amount<Length> momentumPole // referred to the origin of LRF
) {
List<Double> liftingSurfaceMomentCoefficient = new ArrayList<>();
double[] distancesArrayAC,
clDistribution,
alphaDistribution,
clInducedDistributionAtAlphaNew,
cmDistribution,
cCm,
xcPfracC;
double cmActual;
int numberOfAlphas = anglesOfAttack.size();
int numberOfPointSemiSpanWise = liftingSurfaceCl0Distribution.size();
for (int i = 0; i < numberOfAlphas; i++) {
clDistribution = new double[numberOfPointSemiSpanWise];
alphaDistribution = new double[numberOfPointSemiSpanWise];
clInducedDistributionAtAlphaNew = new double[numberOfPointSemiSpanWise];
distancesArrayAC = new double[numberOfPointSemiSpanWise];
cmDistribution = new double[numberOfPointSemiSpanWise];
cCm = new double[numberOfPointSemiSpanWise];
xcPfracC = new double[numberOfPointSemiSpanWise];
theNasaBlackwellCalculator.calculate(anglesOfAttack.get(i));
clDistribution = theNasaBlackwellCalculator.getClTotalDistribution().toArray();
// clInducedDistributionAtAlphaNew = clDistribution;
for (int ii = 0; ii < numberOfPointSemiSpanWise; ii++) {
alphaDistribution[ii] =
(clDistribution[ii] - liftingSurfaceCl0Distribution.get(ii))
/ liftingSurfaceCLAlphaDegDistribution.get(ii);
if (alphaDistribution[ii] < anglesOfAttack.get(0).doubleValue(NonSI.DEGREE_ANGLE)) {
clInducedDistributionAtAlphaNew[ii] =
liftingSurfaceCLAlphaDegDistribution.get(ii) * alphaDistribution[ii]
+ liftingSurfaceCl0Distribution.get(ii);
} else {
clInducedDistributionAtAlphaNew[ii] =
MyMathUtils.getInterpolatedValue1DLinear(
MyArrayUtils.convertListOfAmountTodoubleArray(anglesOfAttackClMatrix),
MyArrayUtils.convertToDoublePrimitive(
MyArrayUtils.convertListOfDoubleToDoubleArray(airfoilClMatrix.get(ii))),
alphaDistribution[ii]);
}
cmActual =
MyMathUtils.getInterpolatedValue1DLinear(
MyArrayUtils.convertToDoublePrimitive(liftingSurfaceCLforCMMatrix),
MyArrayUtils.convertToDoublePrimitive(liftingSurfaceCmACDistribution.get(ii)),
clInducedDistributionAtAlphaNew[ii]);
// xcPfracC[ii] = liftingSurfaceXACadimensionalDistribution.get(ii) -
// (cmActual/
// clInducedDistributionAtAlphaNew[ii]);
xcPfracC[ii] = 0.25 - (cmActual / clInducedDistributionAtAlphaNew[ii]);
distancesArrayAC[ii] =
momentumPole.doubleValue(SI.METER)
- (liftingSurfaceXLEDistribution.get(ii).doubleValue(SI.METER)
+ (xcPfracC[ii]
* liftingSurfaceChordDistribution.get(ii).doubleValue(SI.METER)));
cmDistribution[ii] =
clInducedDistributionAtAlphaNew[ii]
* (distancesArrayAC[ii]
/ liftingSurfaceChordDistribution.get(ii).doubleValue(SI.METER));
cCm[ii] =
cmDistribution[ii]
* liftingSurfaceChordDistribution.get(ii).doubleValue(SI.METER)
* liftingSurfaceChordDistribution.get(ii).doubleValue(SI.METER);
}
// System.out.println(" distance " + Arrays.toString(distancesArrayAC));
// System.out.println(" xcp " + Arrays.toString(xcPfracC));
// System.out.println(" cl " + Arrays.toString(clDistribution));
// System.out.println(" cl new " + Arrays.toString(clInducedDistributionAtAlphaNew));
// System.out.println(" cm " + Arrays.toString(cmDistribution) );
// System.out.println(" ccm " + Arrays.toString(cCm));
cCm[numberOfPointSemiSpanWise - 1] = 0;
liftingSurfaceMomentCoefficient.add(
i,
((2
/ (liftingSurfaceArea.doubleValue(SI.SQUARE_METRE)
* liftingSurfaceMAC.doubleValue(SI.METER)))
* MyMathUtils.integrate1DSimpsonSpline(
MyArrayUtils.convertListOfAmountTodoubleArray(liftingSurfaceDimensionalY), cCm)));
}
return liftingSurfaceMomentCoefficient;
}