@Override public void validate() throws ValidationException { if (iD.equals(Amount.ZERO)) throw new ValidationException(this, "Invalid iD"); if (oD.equals(Amount.ZERO)) throw new ValidationException(this, "Invalid oD"); if (getLength().equals(Amount.ZERO)) throw new ValidationException(this, "Invalid Length"); if (iD.isGreaterThan(oD)) throw new ValidationException(this, "iD > oD"); }
/** Evaluate effective AoA (i.e., taking into account airfoil twist) */ public double calculateAlphaEffective() { _alphaEffective = Amount.valueOf( geometry.get_twist().getEstimatedValue() + _alphaRoot.getEstimatedValue(), SI.RADIAN); return _alphaEffective.getEstimatedValue(); }
public double calculateCdAtClLinear(double cl) { double qValue = _clStar - _clAlpha.getEstimatedValue() * _alphaStar.getEstimatedValue(); Amount<Angle> alpha; double alphaTemp; alphaTemp = (cl - qValue) / _clAlpha.getEstimatedValue(); alpha = Amount.valueOf(alphaTemp, SI.RADIAN); double cdAirfoil = calculateCdAtAlpha(alpha); return cdAirfoil; }
@Override public int hashCode() { final int prime = 31; int result = super.hashCode(); result = prime * result + ((unitRate == null) ? 0 : unitRate.hashCode()); return result; }
public Finocyl() { try { setLength(Amount.valueOf(70, SI.MILLIMETER)); } catch (PropertyVetoException e) { e.printStackTrace(); } generateGeometry(); }
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 void plotClvsAlpha(String subfolderPath, String name) { System.out.println("\n \n-----------------------------------------------------"); System.out.println("STARTING PLOT AIRFOIL CL vs ALPHA CURVE " + name); System.out.println("-----------------------------------------------------"); MyArray alphaArray = new MyArray(); int _numberOfAlpha = 60; double[] clArray = new double[_numberOfAlpha]; double[] alphaArrayDeg = new double[_numberOfAlpha]; Amount<Angle> alphaActualAmount; Amount<Angle> alphaStart = Amount.valueOf(toRadians(-6.), SI.RADIAN); Amount<Angle> alphaEnd = Amount.valueOf(toRadians(25.0), SI.RADIAN); alphaArray.setDouble( MyArrayUtils.linspace( alphaStart.getEstimatedValue(), alphaEnd.getEstimatedValue(), _numberOfAlpha)); for (int i = 0; i < _numberOfAlpha; i++) { alphaActualAmount = Amount.valueOf(alphaArray.get(i), SI.RADIAN); clArray[i] = calculateClAtAlpha(alphaActualAmount.getEstimatedValue()); alphaArrayDeg[i] = alphaActualAmount.to(NonSI.DEGREE_ANGLE).getEstimatedValue(); } MyChartToFileUtils.plotNoLegend( alphaArrayDeg, clArray, null, null, null, null, "alpha", "CL", "deg", "", subfolderPath, "CL vs alpha Airfoil" + name); System.out.println("-----------------------------------------------------"); System.out.println("\n DONE"); System.out.println("-----------------------------------------------------"); }
/** * This function plots the airfoil drag polar using a parabolic approssimation. * * @author Manuela Ruocco */ public void plotPolar() { System.out.println("\n \n-----------------------------------------------------"); System.out.println("STARTING PLOT AIRFOIL DRAG POLAR"); System.out.println("-----------------------------------------------------"); MyArray alphaArray = new MyArray(); int _numberOfAlpha = 40; double[] cdArrayPolar = new double[_numberOfAlpha]; double[] clArrayPolar = new double[_numberOfAlpha]; Amount<Angle> alphaActualAmount; Amount<Angle> alphaStart = Amount.valueOf(toRadians(-6.), SI.RADIAN); Amount<Angle> alphaEnd = Amount.valueOf(toRadians(12.), SI.RADIAN); alphaArray.setDouble( MyArrayUtils.linspace( alphaStart.getEstimatedValue(), alphaEnd.getEstimatedValue(), _numberOfAlpha)); String folderPathPolar = MyConfiguration.currentDirectoryString + File.separator + "out" + File.separator; String subfolderPathPolar = JPADStaticWriteUtils.createNewFolder(folderPathPolar + "Polar_Airfoil" + File.separator); for (int i = 0; i < _numberOfAlpha; i++) { alphaActualAmount = Amount.valueOf(alphaArray.get(i), SI.RADIAN); clArrayPolar[i] = calculateClAtAlpha(alphaActualAmount.getEstimatedValue()); cdArrayPolar[i] = calculateCdAtAlpha(alphaActualAmount); } MyChartToFileUtils.plotNoLegend( cdArrayPolar, clArrayPolar, null, null, null, null, "Cd", "Cl", "", "", subfolderPathPolar, "Polar_Airfoil "); System.out.println("\n \n-----------------------------------------------------"); System.out.println("DONE"); System.out.println("-----------------------------------------------------"); }
private TemporalBoundEditOperation createPeriodicTemporalConstraintOperation( EPlanElement planElement, Amount<Duration> offset, IUndoContext undoContext) { ConstraintsMember facet = planElement.getMember(ConstraintsMember.class, true); Set<PeriodicTemporalConstraint> oldConstraints = getRelevantConstraints(facet); PeriodicTemporalConstraint newConstraint = null; for (PeriodicTemporalConstraint oldConstraint : oldConstraints) { Amount<Duration> time = getRelevantPartOfConstraint(oldConstraint); if (time.compareTo(offset) == 0) { return null; // same as an existing pin } } newConstraint = createPeriodicTemporalConstraint(planElement, offset); TemporalBoundEditOperation operation = new TemporalBoundEditOperation( getEarliestOrLatestName(), planElement, oldConstraints, newConstraint); if (undoContext != null) { operation.addContext(undoContext); } operation.addContext(undoContext); return operation; }
public InputOutputTree() { alphaCurrent = Amount.valueOf(0.0, NonSI.DEGREE_ANGLE); alphaInitial = Amount.valueOf(0.0, NonSI.DEGREE_ANGLE); alphaFinal = Amount.valueOf(0.0, NonSI.DEGREE_ANGLE); sweepLE = Amount.valueOf(0.0, NonSI.DEGREE_ANGLE); altitude = Amount.valueOf(0.0, SI.METER); surface = Amount.valueOf(0.0, SI.SQUARE_METRE); chordDistribution = new ArrayList<Amount>(); xLEDistribution = new ArrayList<Amount>(); dihedralDistribution = new ArrayList<Amount>(); twistDistribution = new ArrayList<Amount>(); alphaZeroLiftDistribution = new ArrayList<Amount>(); alphaStarDistribution = new ArrayList<Amount>(); maximumliftCoefficientDistribution = new ArrayList<Double>(); yAdimensionalStationInput = new ArrayList<Double>(); machNumber = 0.0; aspectRatio = 0.0; adimensionalKinkStation = 0.0; meanThickness = 0.0; numberOfAlpha = 0; numberOfPointSemispan = 0; numberOfSections = 0; cLVsAlphaVector = new double[numberOfAlphaCL]; alphaVector = new double[numberOfAlphaCL]; }
@Override public boolean equals(Object obj) { if (this == obj) { return true; } if (!super.equals(obj)) { return false; } if (!(obj instanceof BillItemVO)) { return false; } BillItemVO<?, ?> other = (BillItemVO<?, ?>) obj; if (unitRate == null) { if (other.unitRate != null) { return false; } } else if (!unitRate.equals(other.unitRate)) { return false; } return true; }
/** * Returns a short description of the type of constraint. * * @param constraint * @param includeThat * @return null if the constraint is invalid */ public static String getDescription(BinaryTemporalConstraint constraint, boolean includeThat) { Amount<Duration> minimum = constraint.getMinimumBminusA(); Amount<Duration> maximum = constraint.getMaximumBminusA(); // construct the string if (minimum == null && maximum == null) { return null; } String minimumStr = minimum == null ? null : EnsembleAmountFormat.INSTANCE.formatAmount(minimum.abs()); String maximumStr = maximum == null ? null : EnsembleAmountFormat.INSTANCE.formatAmount(maximum.abs()); String string = ""; if (minimum == null && maximum != null) { // any time after if (maximum.approximates(ZERO)) { string += "anytime after"; } // at least after else if (maximum.isLessThan(ZERO)) { string += "at least " + maximumStr + " after"; } // at most before else { // max > 0 string += "at most " + maximumStr + " before"; } } else if (maximum == null && minimum != null) { // anytime before if (minimum.approximates(ZERO)) { string += "anytime before"; } // at most after else if (minimum.isLessThan(ZERO)) { string += "at most " + minimumStr + " after"; } // at least before else { // min > 0 string += "at least " + minimumStr + " before"; } } // at the same time else if (minimum != null && minimum.approximates(ZERO) && maximum != null && maximum.approximates(ZERO)) { string += "at the same time"; if (includeThat) { if (constraint.getPointB().hasEndpoint()) { string += " that"; } else { string += " as"; } } } // exactly else if (minimum != null && minimum.approximates(maximum)) { string += "exactly "; string += minimumStr; if (minimum.isLessThan(ZERO)) { string += " after"; } else { // min > 0 string += " before"; } } // between else { string += "between "; String minAndMaxStr; if (maximum != null && minimum != null && minimum.abs().isLessThan(maximum.abs())) { minAndMaxStr = minimumStr + " and " + maximumStr; } else { minAndMaxStr = maximumStr + " and " + minimumStr; } // after if (minimum != null && maximum != null && !minimum.isGreaterThan(ZERO) && !maximum.isGreaterThan(ZERO)) { // min <= 0 && max <= 0 string += minAndMaxStr; string += " after"; } // before else if (minimum != null && maximum != null && !minimum.isLessThan(ZERO) && !maximum.isLessThan(ZERO)) { // min >= 0 && max >= 0 string += minAndMaxStr; string += " before"; } // before and after else if (minimum != null && minimum.isLessThan(ZERO) && maximum != null && maximum.isGreaterThan(ZERO)) { string += maximumStr + " before and " + minimumStr + " after"; } else { return null; } } return string; }
// ------------------------------------------------------------------------------------------ // MAIN: public static void main(String[] args) throws HDF5LibraryException, NullPointerException, CmdLineException { // -------------------------------------------------------------------------------------- // Arguments check and initial activities if (args.length == 0) { System.err.println("NO INPUT FILE GIVEN --> TERMINATING"); return; } System.out.println("------------------------------------------------------------"); System.out.println("PayloadRangeCalc_Test :: TURBOPROP"); System.out.println("------------------------------------------------------------"); System.out.println(" "); PayloadRange_Test_TP_SA main = new PayloadRange_Test_TP_SA(); System.out.println("Input variable usage:"); main.theCmdLineParser.printUsage(System.out); System.out.println("-----------------------------------------------------------"); main.theCmdLineParser.parseArgument(args); String path = main.get_inputFile().getAbsolutePath(); JPADXmlReader reader = new JPADXmlReader(path); System.out.println("-----------------------------------------------------------"); System.out.println("XML File Path : " + path); System.out.println("-----------------------------------------------------------"); System.out.println("Initialize reading \n"); // -------------------------------------------------------------------------------------- // Input data Amount<Angle> sweepLEEquivalent = (Amount<Angle>) reader.getXMLAmountWithUnitByPath("//ATR72/SweepLE"); Amount<Mass> maxTakeOffMass = (Amount<Mass>) reader.getXMLAmountWithUnitByPath("//ATR72/Maximum_take_off_mass"); Amount<Mass> operatingEmptyMass = (Amount<Mass>) reader.getXMLAmountWithUnitByPath("//ATR72/Operating_empty_mass"); Amount<Mass> maxFuelMass = (Amount<Mass>) reader.getXMLAmountWithUnitByPath("//ATR72/Maximum_fuel_mass"); Amount<Area> surface = (Amount<Area>) reader.getXMLAmountWithUnitByPath("//ATR72/Planform_surface"); List<String> cd0_property = reader.getXMLPropertiesByPath("//ATR72/CD0"); double cd0 = Double.valueOf(cd0_property.get(0)); List<String> oswald_property = reader.getXMLPropertiesByPath("//ATR72/OswaldFactor"); double oswald = Double.valueOf(oswald_property.get(0)); List<String> ar_property = reader.getXMLPropertiesByPath("//ATR72/AspectRatio"); double ar = Double.valueOf(ar_property.get(0)); List<String> cl_property = reader.getXMLPropertiesByPath("//ATR72/Current_lift_coefficient"); double cl = Double.valueOf(cl_property.get(0)); List<String> tcMax_property = reader.getXMLPropertiesByPath("//ATR72/Mean_maximum_thickness"); double tcMax = Double.valueOf(tcMax_property.get(0)); List<String> altitude_property = reader.getXMLPropertiesByPath("//ATR72/Altitude"); double altitude = Double.valueOf(altitude_property.get(0)); List<String> eta_property = reader.getXMLPropertiesByPath("//ATR72/Propeller_efficiency"); double eta = Double.valueOf(eta_property.get(0)); List<String> currentMach_property = reader.getXMLPropertiesByPath("//ATR72/Mach_number"); double currentMach = Double.valueOf(currentMach_property.get(0)); List<String> byPassRatio_property = reader.getXMLPropertiesByPath("//ATR72/ByPassRatio"); double byPassRatio = Double.valueOf(byPassRatio_property.get(0)); List<String> nPassMax_property = reader.getXMLPropertiesByPath("//ATR72/Maximum_number_of_passengers"); double nPassMax = Double.valueOf(nPassMax_property.get(0)); List<String> taperRatioEquivalent_property = reader.getXMLPropertiesByPath("//ATR72/TaperRatio"); double taperRatioEquivalent = Double.valueOf(taperRatioEquivalent_property.get(0)); Amount<Angle> sweepHalfChordEquivalent = LSGeometryCalc.calculateSweep( ar, taperRatioEquivalent, sweepLEEquivalent.to(SI.RADIAN).getEstimatedValue(), 0.5, 0.0); // -------------------------------------------------------------------------------------- // the next step is necessary to calculate CL and Speed at point E (or A) of the parabolic polar ACAerodynamicsManager analysis = new ACAerodynamicsManager(); analysis.calculateDragPolarPoints( ar, oswald, cd0, AtmosphereCalc.getDensity(altitude), maxTakeOffMass.getEstimatedValue() * 9.81, surface.getEstimatedValue()); // -------------------------------------------------------------------------------------- // Assign all default folders MyConfiguration.initWorkingDirectoryTree(); // -------------------------------------------------------------------------------------- // Setup database(s) String databaseFolderPath = MyConfiguration.getDir(FoldersEnum.DATABASE_DIR); String fuelFractionDatabaseFileName = "FuelFractions.h5"; FuelFractionDatabaseReader fuelFractionReader = new FuelFractionDatabaseReader(databaseFolderPath, fuelFractionDatabaseFileName); // -------------------------------------------------------------------------------------- // Creating calculator object PayloadRangeCalc test = new PayloadRangeCalc( maxTakeOffMass, operatingEmptyMass, maxFuelMass, sweepHalfChordEquivalent, nPassMax, cl, tcMax, AirplaneType.TURBOPROP_REGIONAL, EngineTypeEnum.TURBOPROP, AirfoilTypeEnum.CONVENTIONAL, analysis, fuelFractionReader); // -----------------------CRITICAL MACH NUMBER CHECK---------------------------- boolean check = test.checkCriticalMach(currentMach); if (check) System.out.println( "\n\n-----------------------------------------------------------" + "\nCurrent Mach is lower then critical Mach number." + "\nCurrent Mach = " + currentMach + "\nCritical Mach = " + test.getCriticalMach() + "\n\n\t CHECK PASSED --> PROCEDING TO CALCULATION " + "\n\n" + "-----------------------------------------------------------"); else { System.err.println( "\n\n-----------------------------------------------------------" + "\nCurrent Mach is bigger then critical Mach number." + "\nCurrent Mach = " + currentMach + "\nCritical Mach = " + test.getCriticalMach() + "\n\n\t CHECK NOT PASSED --> TERMINATING " + "\n\n" + "-----------------------------------------------------------"); return; } // ------------------------MTOM PARAMETERIZATION--------------------------------- test.createPayloadRangeMatrices( sweepHalfChordEquivalent, surface, cd0, oswald, cl, ar, tcMax, byPassRatio, eta, altitude, currentMach, false); // ------------------------------PLOTTING----------------------------------------------- // MTOM parameterization: test.createPayloadRangeCharts_MaxTakeOffMass(test.getRangeMatrix(), test.getPayloadMatrix()); }
public void setOD(Amount<Length> od) throws PropertyVetoException { if (od.equals(this.oD)) return; this.oD = od; generateGeometry(); }
public void setID(Amount<Length> id) throws PropertyVetoException { if (id.equals(this.iD)) return; iD = id; generateGeometry(); }
public class Aerodynamics extends AuxiliaryComponentCalculator { private String _id = ""; public static int idCounter = 0; public static int nAero = 0; private CalculateMachCr calculateMachCr; private CalculateCdWaveDrag calculateCdWaveDrag; private double _mach; private double _clCurrent, _clCurrentViscid; /** The angle of attack of lifting surface chord root */ private Amount<Angle> _alphaRoot; /** Zero lift angle of attack */ private Amount<Angle> _alphaZeroLift = Amount.valueOf(0, SI.RADIAN); /** End of linear region of lift vs alpha curve */ private Amount<Angle> _alphaStar = Amount.valueOf(0, SI.RADIAN); // end-of-linearity /** Stall angle */ private Amount<Angle> _alphaStall = Amount.valueOf(0, SI.RADIAN); /** Current angle of attack */ private Amount<Angle> _alphaCurrent; /** The actual angle of attack of the airfoil */ private Amount<Angle> _alphaEffective = Amount.valueOf(0, SI.RADIAN); private Double _clAtAlpha0; private Amount<?> _clAlpha; private Double _clStar; private Double _clMax; private Double _cdMin; private Double _clAtCdMin; private Double _kFactorDragPolar; private Double _mExponentPolar; private Double _mExponentDragPolar; private Double _machCr0; private static Map<AirfoilEnum, Double> _kWaveDragMap = new HashMap<AirfoilEnum, Double>(); private Double _aerodynamicCenterX; private Double _cmAC; private Double _cmACStall; private Double _cmAlphaAC; private double _machCr, _cdw = 0., _machCurrent; private Geometry geometry; private Airfoil _theAirfoil; private double[] clAirfoil; MyArray alphaArray = new MyArray(); /* * This constructor builds the airfoil aerodynamics using the AirfoilCreator class */ public Aerodynamics(AirfoilCreator airfoilCreator) { _alphaZeroLift = airfoilCreator.getAlphaZeroLift(); _clAtAlpha0 = airfoilCreator.getClAtAlphaZero(); _clAlpha = airfoilCreator.getClAlphaLinearTrait(); _alphaStar = airfoilCreator.getAlphaEndLinearTrait(); _clStar = airfoilCreator.getClEndLinearTrait(); _alphaStall = airfoilCreator.getAlphaStall(); _clMax = airfoilCreator.getClMax(); _cdMin = airfoilCreator.getCdMin(); _clAtCdMin = airfoilCreator.getClAtCdMin(); _kFactorDragPolar = airfoilCreator.getKFactorDragPolar(); _aerodynamicCenterX = airfoilCreator.getXACNormalized(); _cmAC = airfoilCreator.getCmAC(); _cmACStall = airfoilCreator.getCmACAtStall(); _cmAlphaAC = airfoilCreator.getCmAlphaQuarterChord(); _mExponentPolar = airfoilCreator.getMExponentDragPolar(); calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); } public Aerodynamics(Airfoil airf, AircraftEnum aircraftName, AirfoilStationEnum station) { switch (aircraftName) { case ATR72: switch (station) { case ROOT: initializeAerodynamics(airf, AirfoilEnum.NACA23_018); break; case KINK: initializeAerodynamics(airf, AirfoilEnum.NACA23_018); break; case TIP: initializeAerodynamics(airf, AirfoilEnum.NACA23_015); break; } break; case B747_100B: // TODO implement this switch (station) { case ROOT: initializeAerodynamics(airf, AirfoilEnum.NACA65_209); break; case KINK: initializeAerodynamics(airf, AirfoilEnum.NACA65_209); break; case TIP: initializeAerodynamics(airf, AirfoilEnum.NACA65_206); break; } break; case AGILE_DC1: switch (station) { case ROOT: initializeAerodynamics(airf, AirfoilEnum.DFVLR_R4); // TODO: It should be Ha5 airfoil break; case KINK: initializeAerodynamics(airf, AirfoilEnum.DFVLR_R4); break; case TIP: initializeAerodynamics(airf, AirfoilEnum.DFVLR_R4); break; } } } public Aerodynamics(Airfoil airfoil, AirfoilEnum airfoilName) { initializeAerodynamics(airfoil, airfoilName); } private void initializeAerodynamics(Airfoil airf, AirfoilEnum airfoilName) { switch (airfoilName) { case NACA23_018: _id = airf.getId() + "1" + idCounter + "99"; idCounter++; airf.setName(AirfoilEnum.NACA23_018); _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-1.2), SI.RADIAN); _clAlpha = Amount.valueOf(6.3, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(9.5), SI.RADIAN); // end-of-linearity _clStar = 1.3; _alphaStall = Amount.valueOf(Math.toRadians(16.0), SI.RADIAN); _clMax = 1.65; // 1.8; _cdMin = 0.00675; _clAtCdMin = 0.3; _kFactorDragPolar = 0.004; _aerodynamicCenterX = 0.243; _cmAC = -0.02; _cmACStall = -0.09; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case NACA23_015: airf.setName(AirfoilEnum.NACA23_015); _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-1.1), SI.RADIAN); _clAlpha = Amount.valueOf(6.3, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(10), SI.RADIAN); // end-of-linearity _clStar = 1.2; _alphaStall = Amount.valueOf(Math.toRadians(18.0), SI.RADIAN); _clMax = 1.7; // 1.6; _cdMin = 0.00625; _clAtCdMin = 0.1; _kFactorDragPolar = 0.004; _aerodynamicCenterX = 0.243; _cmAC = -0.02; _cmACStall = -0.07; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case NACA23_012: airf.setName(AirfoilEnum.NACA23_012); _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-1.32), SI.RADIAN); _clAlpha = Amount.valueOf(6.3, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(14), SI.RADIAN); // end-of-linearity _clStar = 1.6; _alphaStall = Amount.valueOf(Math.toRadians(18), SI.RADIAN); _clMax = 1.8; // 1.5; _cdMin = 0.00575; _clAtCdMin = 0.23; _kFactorDragPolar = 0.004; _aerodynamicCenterX = 0.247; _cmAC = -0.03; _cmACStall = -0.09; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case NACA65_209: _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-1.3), SI.RADIAN); _clAlpha = Amount.valueOf(5.96, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(11), SI.RADIAN); // end-of-linearity _clStar = 1.1; _alphaStall = Amount.valueOf(Math.toRadians(17.0), SI.RADIAN); _clMax = 1.6; _cdMin = 0.025; _clAtCdMin = 0.2; _kFactorDragPolar = 0.0035; _aerodynamicCenterX = 0.25; _cmAC = -0.07; _cmACStall = -0.09; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case NACA65_206: _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-1.4), SI.RADIAN); _clAlpha = Amount.valueOf(6.13, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(10.0), SI.RADIAN); // end-of-linearity _clStar = _clAlpha.getEstimatedValue() * _alphaStar.getEstimatedValue(); _alphaStall = Amount.valueOf(Math.toRadians(15.0), SI.RADIAN); _clMax = 1.3; _cdMin = 0.025; _clAtCdMin = 0.2; _kFactorDragPolar = 0.0035; _aerodynamicCenterX = 0.25; _cmAC = -0.07; _cmACStall = -0.09; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case NACA0012: airf.setName(AirfoilEnum.NACA0012); _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(0), SI.RADIAN); _clAlpha = Amount.valueOf(6.92, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(11), SI.RADIAN); // end-of-linearity _clStar = 1.23; _alphaStall = Amount.valueOf(Math.toRadians(20.1), SI.RADIAN); _clMax = 1.86; // 1.5; _cdMin = 0.0055; _clAtCdMin = 0.0; _kFactorDragPolar = 0.0035; _aerodynamicCenterX = 0.25; _cmAC = 0.0; _cmACStall = -0.09; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case DFVLR_R4: airf.setName(AirfoilEnum.DFVLR_R4); _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-3.75), SI.RADIAN); _clAlpha = Amount.valueOf(6.3, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(11), SI.RADIAN); // end-of-linearity _clStar = 1.53; _alphaStall = Amount.valueOf(Math.toRadians(16.75), SI.RADIAN); _clMax = 1.7671; // 1.5; _cdMin = 0.0056; _clAtCdMin = 0.0; _kFactorDragPolar = 0.075; _aerodynamicCenterX = 0.25; _cmAC = -0.1168; _cmACStall = -0.0515; _cmAlphaAC = 0.0015; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; default: break; } } public double calculateClAtAlphaLinear(Double alpha) { _clCurrent = alpha / _clAlpha.getEstimatedValue(); return _clCurrent; } /** * This function calculates Cl at alpha of an airfoil. It calculates both in the linear trait and * non linear using a cubic interpolation * * @author Manuela Ruocco * @param double alpha: angle of attack in radians */ public double calculateClAtAlpha(double alpha) { // double clActual= MyMathUtils.getInterpolatedValue1DLinear(alphaArray.toArray(), clAirfoil, // alpha); // return clActual; double q = _clStar - _clAlpha.getEstimatedValue() * _alphaStar.getEstimatedValue(); if (alpha < _alphaStar.getEstimatedValue()) { _clCurrentViscid = _clAlpha.getEstimatedValue() * alpha + q; } else { double[][] matrixData = { { Math.pow(_alphaStall.getEstimatedValue(), 3), Math.pow(_alphaStall.getEstimatedValue(), 2), _alphaStall.getEstimatedValue(), 1.0 }, { 3 * Math.pow(_alphaStall.getEstimatedValue(), 2), 2 * _alphaStall.getEstimatedValue(), 1.0, 0.0 }, { 3 * Math.pow(_alphaStar.getEstimatedValue(), 2), 2 * _alphaStar.getEstimatedValue(), 1.0, 0.0 }, { Math.pow(_alphaStar.getEstimatedValue(), 3), Math.pow(_alphaStar.getEstimatedValue(), 2), _alphaStar.getEstimatedValue(), 1.0 } }; RealMatrix m = MatrixUtils.createRealMatrix(matrixData); double[] vector = {_clMax, 0, _clAlpha.getEstimatedValue(), _clStar}; double[] solSystem = MyMathUtils.solveLinearSystem(m, vector); double a = solSystem[0]; double b = solSystem[1]; double c = solSystem[2]; double d = solSystem[3]; _clCurrentViscid = a * Math.pow(alpha, 3) + b * Math.pow(alpha, 2) + c * alpha + d; } return _clCurrentViscid; } public double calculateClAtAlphaInterp(double alpha) { double clActual = MyMathUtils.getInterpolatedValue1DLinear(alphaArray.toArray(), clAirfoil, alpha); return clActual; } public void calculateClvsAlpha() { int nValue = 50; double alphaMin = Math.toRadians(-5); double alphaMax = Math.toRadians(25); alphaArray.linspace(alphaMin, alphaMax, nValue); double alpha; double q = _clStar - _clAlpha.getEstimatedValue() * _alphaStar.getEstimatedValue(); clAirfoil = new double[nValue]; for (int i = 0; i < nValue; i++) { alpha = alphaArray.get(i); if (alpha < _alphaStar.getEstimatedValue()) { clAirfoil[i] = _clAlpha.getEstimatedValue() * alpha + q; } else { double[][] matrixData = { { Math.pow(_alphaStall.getEstimatedValue(), 3), Math.pow(_alphaStall.getEstimatedValue(), 2), _alphaStall.getEstimatedValue(), 1.0 }, { 3 * Math.pow(_alphaStall.getEstimatedValue(), 2), 2 * _alphaStall.getEstimatedValue(), 1.0, 0.0 }, { 3 * Math.pow(_alphaStar.getEstimatedValue(), 2), 2 * _alphaStar.getEstimatedValue(), 1.0, 0.0 }, { Math.pow(_alphaStar.getEstimatedValue(), 3), Math.pow(_alphaStar.getEstimatedValue(), 2), _alphaStar.getEstimatedValue(), 1.0 } }; RealMatrix m = MatrixUtils.createRealMatrix(matrixData); double[] vector = {_clMax, 0, _clAlpha.getEstimatedValue(), _clStar}; double[] solSystem = MyMathUtils.solveLinearSystem(m, vector); double a = solSystem[0]; double b = solSystem[1]; double c = solSystem[2]; double d = solSystem[3]; clAirfoil[i] = a * Math.pow(alpha, 3) + b * Math.pow(alpha, 2) + c * alpha + d; } } } public void plotClvsAlpha(String subfolderPath, String name) { System.out.println("\n \n-----------------------------------------------------"); System.out.println("STARTING PLOT AIRFOIL CL vs ALPHA CURVE " + name); System.out.println("-----------------------------------------------------"); MyArray alphaArray = new MyArray(); int _numberOfAlpha = 60; double[] clArray = new double[_numberOfAlpha]; double[] alphaArrayDeg = new double[_numberOfAlpha]; Amount<Angle> alphaActualAmount; Amount<Angle> alphaStart = Amount.valueOf(toRadians(-6.), SI.RADIAN); Amount<Angle> alphaEnd = Amount.valueOf(toRadians(25.0), SI.RADIAN); alphaArray.setDouble( MyArrayUtils.linspace( alphaStart.getEstimatedValue(), alphaEnd.getEstimatedValue(), _numberOfAlpha)); for (int i = 0; i < _numberOfAlpha; i++) { alphaActualAmount = Amount.valueOf(alphaArray.get(i), SI.RADIAN); clArray[i] = calculateClAtAlpha(alphaActualAmount.getEstimatedValue()); alphaArrayDeg[i] = alphaActualAmount.to(NonSI.DEGREE_ANGLE).getEstimatedValue(); } MyChartToFileUtils.plotNoLegend( alphaArrayDeg, clArray, null, null, null, null, "alpha", "CL", "deg", "", subfolderPath, "CL vs alpha Airfoil" + name); System.out.println("-----------------------------------------------------"); System.out.println("\n DONE"); System.out.println("-----------------------------------------------------"); } /** Evaluate Cl at effective AoA (i.e., taking into account airfoil twist) */ public void calculateClAtAlphaEffective() { calculateClAtAlphaLinear(calculateAlphaEffective()); } /** Evaluate effective AoA (i.e., taking into account airfoil twist) */ public double calculateAlphaEffective() { _alphaEffective = Amount.valueOf( geometry.get_twist().getEstimatedValue() + _alphaRoot.getEstimatedValue(), SI.RADIAN); return _alphaEffective.getEstimatedValue(); } /** * Evaluate Cd using a parabolic polar curve * * @author Manuela Ruocco */ public double calculateCdAtAlpha(Amount<Angle> alpha) { double cdAirfoil; double clAirfoil = calculateClAtAlpha(alpha.getEstimatedValue()); cdAirfoil = get_cdMin() + Math.pow((clAirfoil - get_clAtCdMin()), 2) * get_kFactorDragPolar(); return cdAirfoil; } public double calculateCdAtClLinear(double cl) { double qValue = _clStar - _clAlpha.getEstimatedValue() * _alphaStar.getEstimatedValue(); Amount<Angle> alpha; double alphaTemp; alphaTemp = (cl - qValue) / _clAlpha.getEstimatedValue(); alpha = Amount.valueOf(alphaTemp, SI.RADIAN); double cdAirfoil = calculateCdAtAlpha(alpha); return cdAirfoil; } /** * Evaluate Cd using a parabolic polar curve * * @author Manuela Ruocco */ public static double calculateCd( double clAirfoil, Double cdMin, Double clAtCdMin, double kFactorDragPolar) { double cdAirfoil; cdAirfoil = cdMin + Math.pow((clAirfoil - clAtCdMin), 2) * kFactorDragPolar; return cdAirfoil; } /** * This function plots the airfoil drag polar using a parabolic approssimation. * * @author Manuela Ruocco */ public void plotPolar() { System.out.println("\n \n-----------------------------------------------------"); System.out.println("STARTING PLOT AIRFOIL DRAG POLAR"); System.out.println("-----------------------------------------------------"); MyArray alphaArray = new MyArray(); int _numberOfAlpha = 40; double[] cdArrayPolar = new double[_numberOfAlpha]; double[] clArrayPolar = new double[_numberOfAlpha]; Amount<Angle> alphaActualAmount; Amount<Angle> alphaStart = Amount.valueOf(toRadians(-6.), SI.RADIAN); Amount<Angle> alphaEnd = Amount.valueOf(toRadians(12.), SI.RADIAN); alphaArray.setDouble( MyArrayUtils.linspace( alphaStart.getEstimatedValue(), alphaEnd.getEstimatedValue(), _numberOfAlpha)); String folderPathPolar = MyConfiguration.currentDirectoryString + File.separator + "out" + File.separator; String subfolderPathPolar = JPADStaticWriteUtils.createNewFolder(folderPathPolar + "Polar_Airfoil" + File.separator); for (int i = 0; i < _numberOfAlpha; i++) { alphaActualAmount = Amount.valueOf(alphaArray.get(i), SI.RADIAN); clArrayPolar[i] = calculateClAtAlpha(alphaActualAmount.getEstimatedValue()); cdArrayPolar[i] = calculateCdAtAlpha(alphaActualAmount); } MyChartToFileUtils.plotNoLegend( cdArrayPolar, clArrayPolar, null, null, null, null, "Cd", "Cl", "", "", subfolderPathPolar, "Polar_Airfoil "); System.out.println("\n \n-----------------------------------------------------"); System.out.println("DONE"); System.out.println("-----------------------------------------------------"); } public class CalculateMachCr { private double mCr0PerkinsAndHage() { // Page 407 Sforza _machCr0 = 0.89 - 1.3 * (geometry.get_maximumThicknessOverChord()); return _machCr0; } private double mCr0Shevell() { // Page 409 Sforza _machCr0 = 0.9 - geometry.get_maximumThicknessOverChord(); return _machCr0; } public double perkinsAndHage() { if (_kWaveDragMap.containsKey(_theAirfoil.getFamily())) { _machCr = mCr0PerkinsAndHage() - _kWaveDragMap.get(_theAirfoil.getFamily()) * _clCurrent; } else _machCr = 0.; return _machCr; } public double shevell() { _machCr = mCr0Shevell() - (0.17 + 0.016) * _clCurrent; return _machCr; } public double korn() { double k; if (_theAirfoil.getType().equals(AirfoilTypeEnum.CONVENTIONAL)) k = 0.87; else k = 0.95; _machCr = (k - 0.108) - geometry.get_maximumThicknessOverChord() - 0.1 * _clCurrent; return _machCr; } public void allMethods() { perkinsAndHage(); shevell(); korn(); } } public class CalculateCdWaveDrag { public double perkinsAndHage() { // Difference between current mach number and critical mach number double diff = _machCurrent - calculateMachCr.perkinsAndHage(); if (diff > 0) _cdw = 9.5 * Math.pow((diff), 2.8) + 0.00193; return _cdw; } /** Page 410 Sforza */ public double lockShevell() { double diff = _machCurrent - calculateMachCr.shevell(); if (diff > 0) _cdw = 20 * Math.pow((diff), 4); return _cdw; } public double lockKorn() { double diff = _machCurrent - calculateMachCr.korn(); if (diff > 0) _cdw = 20 * Math.pow((diff), 4); return _cdw; } public void allMethods() { perkinsAndHage(); lockShevell(); lockKorn(); } } public CalculateMachCr getCalculateMachCr() { return calculateMachCr; } public CalculateCdWaveDrag getCalculateCdWaveDrag() { return calculateCdWaveDrag; } public double get_mach() { return _mach; } public void set_mach(double _mach) { this._mach = _mach; } public double get_clCurrent() { return _clCurrent; } public void set_clCurrent(double _clCurrent) { this._clCurrent = _clCurrent; } public Amount<Angle> get_alphaRoot() { return _alphaRoot; } public void set_alphaRoot(Amount<Angle> _alphaRoot) { this._alphaRoot = _alphaRoot; } public Amount<Angle> get_alphaZeroLift() { return _alphaZeroLift; } public void set_alphaZeroLift(Amount<Angle> _alphaZeroLift) { this._alphaZeroLift = _alphaZeroLift; } public Amount<Angle> get_alphaStar() { return _alphaStar; } public void set_alphaStar(Amount<Angle> _alphaStar) { this._alphaStar = _alphaStar; } public Amount<Angle> get_alphaStall() { return _alphaStall; } public void set_alphaStall(Amount<Angle> _alphaStall) { this._alphaStall = _alphaStall; } public Amount<Angle> get_alphaCurrent() { return _alphaCurrent; } public void set_alphaCurrent(Amount<Angle> _alphaCurrent) { this._alphaCurrent = _alphaCurrent; } public Amount<Angle> get_alphaEffective() { return _alphaEffective; } public void set_alphaEffective(Amount<Angle> _alphaEffective) { this._alphaEffective = _alphaEffective; } public Double get_clAtAlpha0() { return _clAtAlpha0; } public void set_clAtAlpha0(Double _clAtAlpha0) { this._clAtAlpha0 = _clAtAlpha0; } public Amount<?> getClAlpha() { return _clAlpha; } public void set_clAlpha(Amount<?> _clAlpha) { this._clAlpha = _clAlpha; } public Double get_clStar() { return _clStar; } public void set_clStar(Double _clStar) { this._clStar = _clStar; } public Double get_clMax() { return _clMax; } public void set_clMax(Double _clMax) { this._clMax = _clMax; } public Double get_cdMin() { return _cdMin; } public void set_cdMin(Double _cdMin) { this._cdMin = _cdMin; } public Double get_clAtCdMin() { return _clAtCdMin; } public void set_clAtCdMin(Double _clAtCdMin) { this._clAtCdMin = _clAtCdMin; } public Double get_kFactorDragPolar() { return _kFactorDragPolar; } public void set_kFactorDragPolar(Double _kFactorDragPolar) { this._kFactorDragPolar = _kFactorDragPolar; } public Double get_mExponentDragPolar() { return _mExponentDragPolar; } public void set_mExponentDragPolar(Double _mExponentDragPolar) { this._mExponentDragPolar = _mExponentDragPolar; } public Double get_machCr0() { return _machCr0; } public void set_machCr0(Double _machCr0) { this._machCr0 = _machCr0; } public Double get_aerodynamicCenterX() { return _aerodynamicCenterX; } public void set_aerodynamicCenterX(Double _aerodynamicCenterX) { this._aerodynamicCenterX = _aerodynamicCenterX; } public Double get_cmAC() { return _cmAC; } public void set_cmAC(Double _cmAC) { this._cmAC = _cmAC; } public Double get_cmACStall() { return _cmACStall; } public void set_cmACStall(Double _cmACStall) { this._cmACStall = _cmACStall; } public Double get_cmAlphaAC() { return _cmAlphaAC; } public void set_cmAlphaAC(Double _cmAlphaAC) { this._cmAlphaAC = _cmAlphaAC; } public double get_machCr() { return _machCr; } public void set_machCr(double _machCr) { this._machCr = _machCr; } public double get_cdw() { return _cdw; } public void set_cdw(double _cdw) { this._cdw = _cdw; } public double get_machCurrent() { return _machCurrent; } public void set_machCurrent(double _machCurrent) { this._machCurrent = _machCurrent; } public static Map<AirfoilEnum, Double> get_kWaveDragMap() { return _kWaveDragMap; } @Override public String getId() { return _id; } public String getIdNew() { String id = _theAirfoil.getId() + "aero" + nAero; nAero++; return id; } public double[] getClAirfoil() { return clAirfoil; } public void setClAirfoil(double[] clAirfoil) { this.clAirfoil = clAirfoil; } public MyArray getAlphaArray() { return alphaArray; } public void setAlphaArray(MyArray alphaArray) { this.alphaArray = alphaArray; } public Double get_mExponentPolar() { return _mExponentPolar; } public void set_mExponentPolar(Double _mExponentPolar) { this._mExponentPolar = _mExponentPolar; } }
/** * Evaluate overall CG * * @param aircraft */ public void calculateTotalCG(Aircraft aircraft) { // Structural CG _cgStructure = new CenterOfGravity(); _cgList.add(aircraft.get_fuselage().get_cg()); _cgList.add(aircraft.get_wing().get_cg()); _cgList.add(aircraft.get_HTail().get_cg()); _cgList.add(aircraft.get_VTail().get_cg()); _cgList.add(aircraft.get_landingGear().get_cg()); _cgList.addAll(aircraft.get_theNacelles().get_cgList()); System.out.println("\n \nCG COMPONENTS LOCATION IN BRF"); System.out.println("fuselage --> " + _cgList.get(0).get_xBRF()); System.out.println("wing --> " + _cgList.get(1).get_xBRF()); System.out.println("HTail --> " + _cgList.get(2).get_xBRF()); System.out.println("VTail --> " + _cgList.get(3).get_xBRF()); System.out.println("Landing gear --> " + _cgList.get(4).get_xBRF()); for (int i = 0; i < aircraft.get_theNacelles().get_cgList().size(); i++) { System.out.println("Nacelle " + i + " --> " + _cgList.get(i + 5).get_xBRF()); } // _cgList.forEach(p-> System.out.println(p.get_xBRF())); double prod = 0., sum = 0.; for (int i = 0; i < _cgList.size(); i++) { prod += _cgList.get(i).get_xBRF().getEstimatedValue() * aircraft.get_weights().get_massStructureList().get(i).getEstimatedValue(); sum += aircraft.get_weights().get_massStructureList().get(i).getEstimatedValue(); } _cgStructure.set_xBRF(Amount.valueOf(prod / sum, SI.METER)); _cgStructure.calculateCGinMAC( aircraft.get_wing().get_xLEMacActualBRF(), aircraft.get_wing().get_xLEMacActualBRF(), Amount.valueOf(0., SI.METER), aircraft.get_wing().get_meanAerodChordActual()); // Structure + engines CG _cgStructureAndPower = new CenterOfGravity(); System.out.println( "fuel tank --> " + aircraft.get_theFuelTank().get_cg().get_xBRF().getEstimatedValue()); double cgPowerPlantContribute = 0.0; for (int i = 0; i < aircraft.get_powerPlant().get_engineNumber(); i++) { cgPowerPlantContribute = cgPowerPlantContribute + (aircraft.get_powerPlant().get_cgList().get(i).get_xBRF().getEstimatedValue() * aircraft .get_powerPlant() .get_engineList() .get(i) .get_totalMass() .getEstimatedValue()); System.out.println( "Engine " + i + " --> " + aircraft.get_powerPlant().get_cgList().get(i).get_xBRF()); } _cgStructureAndPower.set_xBRF( Amount.valueOf( (cgPowerPlantContribute + aircraft.get_weights().get_structuralMass().getEstimatedValue() * get_cgStructure().get_xBRF().getEstimatedValue()) / (aircraft.get_weights().get_structuralMass().getEstimatedValue() + aircraft.get_powerPlant().get_totalMass().getEstimatedValue()), SI.METER)); get_cgStructureAndPower() .calculateCGinMAC( aircraft.get_wing().get_xLEMacActualBRF(), aircraft.get_wing().get_xLEMacActualBRF(), Amount.valueOf(0., SI.METER), aircraft.get_wing().get_meanAerodChordActual()); // MZFW CG location _cgMZFM = new CenterOfGravity(); get_cgMZFM() .set_xBRF( Amount.valueOf( (get_cgStructureAndPower().get_xBRF().getEstimatedValue() * aircraft.get_weights().get_OEM().getEstimatedValue() + aircraft.get_configuration().get_seatsCoG().getEstimatedValue() * aircraft.get_weights().get_paxMassMax().getEstimatedValue()) / (aircraft.get_weights().get_paxMassMax().getEstimatedValue() + aircraft.get_weights().get_OEM().getEstimatedValue()), SI.METER)); get_cgMZFM() .calculateCGinMAC( aircraft.get_wing().get_xLEMacActualBRF(), aircraft.get_wing().get_xLEMacActualBRF(), Amount.valueOf(0., SI.METER), aircraft.get_wing().get_meanAerodChordActual()); // MTOM CG location _cgMTOM = new CenterOfGravity(); _cgMTOM.set_xBRF( Amount.valueOf( (_cgMZFM.get_xBRF().getEstimatedValue() * aircraft.get_weights().get_MZFM().getEstimatedValue() + aircraft.get_theFuelTank().get_fuelMass().getEstimatedValue() * aircraft.get_theFuelTank().get_cg().get_xBRF().getEstimatedValue()) / aircraft.get_weights().get_MTOM().getEstimatedValue(), SI.METER)); _cgMTOM.calculateCGinMAC( aircraft.get_wing().get_xLEMacActualBRF(), aircraft.get_wing().get_xLEMacActualBRF(), Amount.valueOf(0., SI.METER), aircraft.get_wing().get_meanAerodChordActual()); }
/** * Evaluate Cd using a parabolic polar curve * * @author Manuela Ruocco */ public double calculateCdAtAlpha(Amount<Angle> alpha) { double cdAirfoil; double clAirfoil = calculateClAtAlpha(alpha.getEstimatedValue()); cdAirfoil = get_cdMin() + Math.pow((clAirfoil - get_clAtCdMin()), 2) * get_kFactorDragPolar(); return cdAirfoil; }
public void setFinDiameter(Amount<Length> finDiameter) throws PropertyVetoException { if (finDiameter.equals(this.finDiameter)) return; this.finDiameter = finDiameter; generateGeometry(); }
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; }
public class Finocyl extends ExtrudedShapeGrain implements Validating { private Amount<Length> oD = Amount.valueOf(30, SI.MILLIMETER); private Amount<Length> iD = Amount.valueOf(10, SI.MILLIMETER); private Amount<Length> finWidth = Amount.valueOf(2, SI.MILLIMETER); private Amount<Length> finDiameter = Amount.valueOf(20, SI.MILLIMETER); private int finCount = 5; public Finocyl() { try { setLength(Amount.valueOf(70, SI.MILLIMETER)); } catch (PropertyVetoException e) { e.printStackTrace(); } generateGeometry(); } 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 Amount<Length> getOD() { return oD; } public void setOD(Amount<Length> od) throws PropertyVetoException { if (od.equals(this.oD)) return; this.oD = od; generateGeometry(); } public Amount<Length> getID() { return iD; } public void setID(Amount<Length> id) throws PropertyVetoException { if (id.equals(this.iD)) return; iD = id; generateGeometry(); } public Amount<Length> getFinWidth() { return finWidth; } public void setFinWidth(Amount<Length> finWidth) throws PropertyVetoException { if (finWidth.equals(this.finWidth)) return; this.finWidth = finWidth; generateGeometry(); } public Amount<Length> getFinDiameter() { return finDiameter; } public void setFinDiameter(Amount<Length> finDiameter) throws PropertyVetoException { if (finDiameter.equals(this.finDiameter)) return; this.finDiameter = finDiameter; generateGeometry(); } public int getFinCount() { return finCount; } public void setFinCount(int finCount) throws PropertyVetoException { if (finCount == this.finCount) return; this.finCount = finCount; generateGeometry(); } @Override public void validate() throws ValidationException { if (iD.equals(Amount.ZERO)) throw new ValidationException(this, "Invalid iD"); if (oD.equals(Amount.ZERO)) throw new ValidationException(this, "Invalid oD"); if (getLength().equals(Amount.ZERO)) throw new ValidationException(this, "Invalid Length"); if (iD.isGreaterThan(oD)) throw new ValidationException(this, "iD > oD"); } }
/** * This function calculates Cl at alpha of an airfoil. It calculates both in the linear trait and * non linear using a cubic interpolation * * @author Manuela Ruocco * @param double alpha: angle of attack in radians */ public double calculateClAtAlpha(double alpha) { // double clActual= MyMathUtils.getInterpolatedValue1DLinear(alphaArray.toArray(), clAirfoil, // alpha); // return clActual; double q = _clStar - _clAlpha.getEstimatedValue() * _alphaStar.getEstimatedValue(); if (alpha < _alphaStar.getEstimatedValue()) { _clCurrentViscid = _clAlpha.getEstimatedValue() * alpha + q; } else { double[][] matrixData = { { Math.pow(_alphaStall.getEstimatedValue(), 3), Math.pow(_alphaStall.getEstimatedValue(), 2), _alphaStall.getEstimatedValue(), 1.0 }, { 3 * Math.pow(_alphaStall.getEstimatedValue(), 2), 2 * _alphaStall.getEstimatedValue(), 1.0, 0.0 }, { 3 * Math.pow(_alphaStar.getEstimatedValue(), 2), 2 * _alphaStar.getEstimatedValue(), 1.0, 0.0 }, { Math.pow(_alphaStar.getEstimatedValue(), 3), Math.pow(_alphaStar.getEstimatedValue(), 2), _alphaStar.getEstimatedValue(), 1.0 } }; RealMatrix m = MatrixUtils.createRealMatrix(matrixData); double[] vector = {_clMax, 0, _clAlpha.getEstimatedValue(), _clStar}; double[] solSystem = MyMathUtils.solveLinearSystem(m, vector); double a = solSystem[0]; double b = solSystem[1]; double c = solSystem[2]; double d = solSystem[3]; _clCurrentViscid = a * Math.pow(alpha, 3) + b * Math.pow(alpha, 2) + c * alpha + d; } return _clCurrentViscid; }
public double calculateClAtAlphaLinear(Double alpha) { _clCurrent = alpha / _clAlpha.getEstimatedValue(); return _clCurrent; }
public class ConstraintUtils { private static final Amount<Duration> ZERO = Amount.valueOf(0, SI.SECOND); public static PeriodicTemporalConstraint createConstraint( EPlanElement element, Timepoint endpoint, Amount<Duration> earliest, Amount<Duration> latest, String rationale) { PeriodicTemporalConstraint constraint = ConstraintsFactory.eINSTANCE.createPeriodicTemporalConstraint(); constraint.getPoint().setElement(element); constraint.getPoint().setEndpoint(endpoint); constraint.setEarliest(earliest); constraint.setLatest(latest); constraint.setRationale(rationale); return constraint; } public static BinaryTemporalConstraint createConstraint( EPlanElement elementA, Timepoint endpointA, EPlanElement elementB, Timepoint endpointB, Amount<Duration> min, Amount<Duration> max, String rationale) { BinaryTemporalConstraint constraint = ConstraintsFactory.eINSTANCE.createBinaryTemporalConstraint(); constraint.getPointA().setElement(elementA); constraint.getPointA().setEndpoint(endpointA); constraint.getPointB().setElement(elementB); constraint.getPointB().setEndpoint(endpointB); constraint.setMinimumBminusA(min); constraint.setMaximumBminusA(max); constraint.setRationale(rationale); return constraint; } public static ConstraintPoint createConstraintPoint( EPlanElement planElement, Timepoint timepoint) { ConstraintPoint constraintPoint = ConstraintsFactory.eINSTANCE.createConstraintPoint(); constraintPoint.setElement(planElement); constraintPoint.setEndpoint(timepoint); return constraintPoint; } /* * Periodic constraint utilities */ public static Date getPeriodicConstraintEarliestDate(PeriodicTemporalConstraint constraint) { Amount<Duration> earliest = constraint.getEarliest(); if (earliest != null) { Date midnight = getPeriodicConstraintDate(constraint); if (midnight != null) { return DateUtils.add(midnight, earliest); } } return null; } public static Date getPeriodicConstraintLatestDate(PeriodicTemporalConstraint constraint) { Amount<Duration> latest = constraint.getLatest(); if (latest != null) { Date midnight = getPeriodicConstraintDate(constraint); if (midnight != null) { return DateUtils.add(midnight, latest); } } return null; } private static Date getPeriodicConstraintDate(PeriodicTemporalConstraint constraint) { ConstraintPoint point = constraint.getPoint(); Date date = point.getDate(); if (date == null) { return null; } return MissionCalendarUtils.getMidnight(date); } public static Amount<Duration> getPeriodicConstraintOffset(Date date) { if (date == null) { return null; } Date midnight = MissionCalendarUtils.getMidnight(date); Amount<Duration> offset = DateUtils.subtract(date, midnight); return offset; } /* * Attach/detach constraints */ public static void attachConstraint(final PeriodicTemporalConstraint constraint) { ConstraintsMember member = constraint.getPoint().getElement().getMember(ConstraintsMember.class, true); member.getPeriodicTemporalConstraints().add(constraint); } public static void detachConstraint(final PeriodicTemporalConstraint constraint) { ConstraintsMember member = constraint.getPoint().getElement().getMember(ConstraintsMember.class, true); member.getPeriodicTemporalConstraints().remove(constraint); } public static void attachConstraint(final BinaryTemporalConstraint constraint) { ConstraintsMember memberA = constraint.getPointA().getElement().getMember(ConstraintsMember.class, true); memberA.getBinaryTemporalConstraints().add(constraint); ConstraintsMember memberB = constraint.getPointB().getElement().getMember(ConstraintsMember.class, true); memberB.getBinaryTemporalConstraints().add(constraint); } public static void detachConstraint(final BinaryTemporalConstraint constraint) { EPlanElement elementA = constraint.getPointA().getElement(); if (elementA != null) { ConstraintsMember memberA = elementA.getMember(ConstraintsMember.class, true); memberA.getBinaryTemporalConstraints().remove(constraint); } EPlanElement elementB = constraint.getPointB().getElement(); if (elementB != null) { ConstraintsMember memberB = elementB.getMember(ConstraintsMember.class, true); memberB.getBinaryTemporalConstraints().remove(constraint); } } /* * Access constraints */ public static Collection<ConstraintsMember> getConstraintMembersRecursively(EPlan plan) { return EPlanUtils.getMembers(plan, ConstraintsMember.class); } public static List<PeriodicTemporalConstraint> getPeriodicConstraints( EPlanElement element, boolean mustExist) { ConstraintsMember constraintsMember = element.getMember(ConstraintsMember.class, mustExist); if (constraintsMember == null) { return Collections.emptyList(); } return constraintsMember.getPeriodicTemporalConstraints(); } /** * Gets the constraint with the Earliest and Latest Start or End of a plan element. * * @param element -- activity or group * @param whichEnd -- START or END * @return null if unconstrained, else the constraint */ public static PeriodicTemporalConstraint getPeriodicConstraint( EPlanElement element, Timepoint whichEnd) { List<PeriodicTemporalConstraint> periodicConstraints = getPeriodicConstraints(element, false); if (periodicConstraints == null) return null; for (PeriodicTemporalConstraint constraint : periodicConstraints) { if (whichEnd == constraint.getPoint().getEndpoint()) { return constraint; } } return null; } public static List<PeriodicTemporalConstraint> getPeriodicConstraints( EPlanElement element, Timepoint timepoint, boolean mustExist) { ConstraintsMember constraintsMember = element.getMember(ConstraintsMember.class, mustExist); if (constraintsMember == null) { return Collections.emptyList(); } List<PeriodicTemporalConstraint> result = new ArrayList<PeriodicTemporalConstraint>(); for (PeriodicTemporalConstraint constraint : constraintsMember.getPeriodicTemporalConstraints()) { ConstraintPoint point = constraint.getPoint(); if ((point.getElement() == element) && (point.getEndpoint() == timepoint)) { result.add(constraint); } } return result; } public static List<BinaryTemporalConstraint> getBinaryConstraints( EPlanElement element, boolean mustExist) { ConstraintsMember constraintsMember = element.getMember(ConstraintsMember.class, mustExist); if (constraintsMember == null) { return Collections.emptyList(); } return constraintsMember.getBinaryTemporalConstraints(); } public static List<BinaryTemporalConstraint> getBinaryConstraints( EPlanElement element, Timepoint timepoint, boolean mustExist) { ConstraintsMember constraintsMember = element.getMember(ConstraintsMember.class, mustExist); if (constraintsMember == null) { return Collections.emptyList(); } List<BinaryTemporalConstraint> result = new ArrayList<BinaryTemporalConstraint>(); for (BinaryTemporalConstraint constraint : constraintsMember.getBinaryTemporalConstraints()) { ConstraintPoint pointA = constraint.getPointA(); ConstraintPoint pointB = constraint.getPointB(); if (((pointA.getElement() == element) && (pointA.getEndpoint() == timepoint)) || ((pointB.getElement() == element) && (pointB.getEndpoint() == timepoint))) { result.add(constraint); } } return result; } public static List<BinaryTemporalConstraint> getBinaryStartConstraints( EPlanElement element, boolean mustExist) { return getBinaryConstraints(element, Timepoint.START, mustExist); } public static List<BinaryTemporalConstraint> getBinaryEndConstraints( EPlanElement element, boolean mustExist) { return getBinaryConstraints(element, Timepoint.END, mustExist); } /** * Given a particular constraint and EPlan (the context of the plan elements), this method will * determine the elements that the constraint constrains. * * @param constraint * @param ePlan * @return */ public static LinkedHashSet<EPlanElement> getConstrainedEPlanElements( BinaryTemporalConstraint constraint) { LinkedHashSet<EPlanElement> elements = new LinkedHashSet<EPlanElement>(); elements.add(constraint.getPointA().getElement()); elements.add(constraint.getPointB().getElement()); return elements; } /** * Creates a new binary constraint which is the reverse but equivalent to the original constraint. * For example, "A must end before B starts" can also be stated as "B must start after A ends". * * @param originalConstraint * @return */ public static BinaryTemporalConstraint reverseConstraint( BinaryTemporalConstraint originalConstraint) { if (originalConstraint == null) { // Might happen if an activity was removed or filtered out of an import. return null; } BinaryTemporalConstraint newConstraint = EMFUtils.copy(originalConstraint); newConstraint.getPointA().setElement(originalConstraint.getPointB().getElement()); newConstraint.getPointA().setEndpoint(originalConstraint.getPointB().getEndpoint()); newConstraint.getPointA().setAnchor(originalConstraint.getPointB().getAnchor()); newConstraint.getPointB().setElement(originalConstraint.getPointA().getElement()); newConstraint.getPointB().setEndpoint(originalConstraint.getPointA().getEndpoint()); newConstraint.getPointB().setAnchor(originalConstraint.getPointA().getAnchor()); if (originalConstraint.getMaximumBminusA() != null) { newConstraint.setMinimumBminusA(originalConstraint.getMaximumBminusA().opposite()); } else { newConstraint.setMinimumBminusA(null); } if (originalConstraint.getMinimumBminusA() != null) { newConstraint.setMaximumBminusA(originalConstraint.getMinimumBminusA().opposite()); } else { newConstraint.setMaximumBminusA(null); } return newConstraint; } /** * Returns a short description of the type of constraint. * * @param constraint * @param includeThat * @return null if the constraint is invalid */ public static String getDescription(BinaryTemporalConstraint constraint, boolean includeThat) { Amount<Duration> minimum = constraint.getMinimumBminusA(); Amount<Duration> maximum = constraint.getMaximumBminusA(); // construct the string if (minimum == null && maximum == null) { return null; } String minimumStr = minimum == null ? null : EnsembleAmountFormat.INSTANCE.formatAmount(minimum.abs()); String maximumStr = maximum == null ? null : EnsembleAmountFormat.INSTANCE.formatAmount(maximum.abs()); String string = ""; if (minimum == null && maximum != null) { // any time after if (maximum.approximates(ZERO)) { string += "anytime after"; } // at least after else if (maximum.isLessThan(ZERO)) { string += "at least " + maximumStr + " after"; } // at most before else { // max > 0 string += "at most " + maximumStr + " before"; } } else if (maximum == null && minimum != null) { // anytime before if (minimum.approximates(ZERO)) { string += "anytime before"; } // at most after else if (minimum.isLessThan(ZERO)) { string += "at most " + minimumStr + " after"; } // at least before else { // min > 0 string += "at least " + minimumStr + " before"; } } // at the same time else if (minimum != null && minimum.approximates(ZERO) && maximum != null && maximum.approximates(ZERO)) { string += "at the same time"; if (includeThat) { if (constraint.getPointB().hasEndpoint()) { string += " that"; } else { string += " as"; } } } // exactly else if (minimum != null && minimum.approximates(maximum)) { string += "exactly "; string += minimumStr; if (minimum.isLessThan(ZERO)) { string += " after"; } else { // min > 0 string += " before"; } } // between else { string += "between "; String minAndMaxStr; if (maximum != null && minimum != null && minimum.abs().isLessThan(maximum.abs())) { minAndMaxStr = minimumStr + " and " + maximumStr; } else { minAndMaxStr = maximumStr + " and " + minimumStr; } // after if (minimum != null && maximum != null && !minimum.isGreaterThan(ZERO) && !maximum.isGreaterThan(ZERO)) { // min <= 0 && max <= 0 string += minAndMaxStr; string += " after"; } // before else if (minimum != null && maximum != null && !minimum.isLessThan(ZERO) && !maximum.isLessThan(ZERO)) { // min >= 0 && max >= 0 string += minAndMaxStr; string += " before"; } // before and after else if (minimum != null && minimum.isLessThan(ZERO) && maximum != null && maximum.isGreaterThan(ZERO)) { string += maximumStr + " before and " + minimumStr + " after"; } else { return null; } } return string; } public static List<BinaryTemporalConstraint> convertChainToBinaryTemporalConstraints( TemporalChain chain) { List<BinaryTemporalConstraint> constraints = new ArrayList<BinaryTemporalConstraint>(); List<EPlanElement> chainedElements = chain.getElements(); for (int i = 1; i < chainedElements.size(); i++) { EPlanElement a = chainedElements.get(i - 1); EPlanElement b = chainedElements.get(i); BinaryTemporalConstraint constraint = createConstraint( a, Timepoint.END, b, Timepoint.START, AmountUtils.exactZero(SI.SECOND), null, ""); constraints.add(constraint); } return constraints; } public static boolean isAnchorable(EStructuralFeature feature) { String annotation = EMFUtils.getAnnotation(feature, "constraint", "anchor"); return Boolean.parseBoolean(annotation); } /** * Utility method that determines if the feature is relevant to the anchor * * @param point * @param planElement * @param feature * @return */ public static boolean isAnchorPointForElement( ConstraintPoint point, EPlanElement planElement, EStructuralFeature feature) { return !point.hasEndpoint() && point.getElement() == planElement && feature.getName().equals(point.getAnchor()); } public static boolean areAnchorsAllowed() { return EnsembleProperties.getBooleanPropertyValue("constraint.anchor.allowed", false); } public static boolean isNested(List<EPlanElement> elements) { Set<String> hierarchy = new HashSet(); for (EPlanElement element : elements) { while (element instanceof EPlanChild && (((EPlanChild) element).getParent() instanceof EPlanChild)) { EPlanElement parent = ((EPlanChild) element).getParent(); hierarchy.add(parent.getPersistentID()); element = parent; } } for (EPlanElement element : elements) { if (hierarchy.contains(element.getPersistentID())) { return true; } } return false; } /** * Returns true if all elements have the same parent * * @param elements * @return */ public static boolean sameParent(List<? extends EPlanElement> elements) { EObject firstParent = elements.get(0).eContainer(); for (EPlanElement element : elements) { EObject parent = element.eContainer(); if (firstParent != parent) { return false; } } return true; } public static boolean sameType(List<EPlanElement> elements) { Class clazz = null; for (EPlanElement element : elements) { if (clazz == null) { clazz = element.getClass(); } else if (element.getClass() != clazz) { return false; } } return true; } }
public void setFinWidth(Amount<Length> finWidth) throws PropertyVetoException { if (finWidth.equals(this.finWidth)) return; this.finWidth = finWidth; generateGeometry(); }
public void calculateClvsAlpha() { int nValue = 50; double alphaMin = Math.toRadians(-5); double alphaMax = Math.toRadians(25); alphaArray.linspace(alphaMin, alphaMax, nValue); double alpha; double q = _clStar - _clAlpha.getEstimatedValue() * _alphaStar.getEstimatedValue(); clAirfoil = new double[nValue]; for (int i = 0; i < nValue; i++) { alpha = alphaArray.get(i); if (alpha < _alphaStar.getEstimatedValue()) { clAirfoil[i] = _clAlpha.getEstimatedValue() * alpha + q; } else { double[][] matrixData = { { Math.pow(_alphaStall.getEstimatedValue(), 3), Math.pow(_alphaStall.getEstimatedValue(), 2), _alphaStall.getEstimatedValue(), 1.0 }, { 3 * Math.pow(_alphaStall.getEstimatedValue(), 2), 2 * _alphaStall.getEstimatedValue(), 1.0, 0.0 }, { 3 * Math.pow(_alphaStar.getEstimatedValue(), 2), 2 * _alphaStar.getEstimatedValue(), 1.0, 0.0 }, { Math.pow(_alphaStar.getEstimatedValue(), 3), Math.pow(_alphaStar.getEstimatedValue(), 2), _alphaStar.getEstimatedValue(), 1.0 } }; RealMatrix m = MatrixUtils.createRealMatrix(matrixData); double[] vector = {_clMax, 0, _clAlpha.getEstimatedValue(), _clStar}; double[] solSystem = MyMathUtils.solveLinearSystem(m, vector); double a = solSystem[0]; double b = solSystem[1]; double c = solSystem[2]; double d = solSystem[3]; clAirfoil[i] = a * Math.pow(alpha, 3) + b * Math.pow(alpha, 2) + c * alpha + d; } } }
private void initializeAerodynamics(Airfoil airf, AirfoilEnum airfoilName) { switch (airfoilName) { case NACA23_018: _id = airf.getId() + "1" + idCounter + "99"; idCounter++; airf.setName(AirfoilEnum.NACA23_018); _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-1.2), SI.RADIAN); _clAlpha = Amount.valueOf(6.3, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(9.5), SI.RADIAN); // end-of-linearity _clStar = 1.3; _alphaStall = Amount.valueOf(Math.toRadians(16.0), SI.RADIAN); _clMax = 1.65; // 1.8; _cdMin = 0.00675; _clAtCdMin = 0.3; _kFactorDragPolar = 0.004; _aerodynamicCenterX = 0.243; _cmAC = -0.02; _cmACStall = -0.09; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case NACA23_015: airf.setName(AirfoilEnum.NACA23_015); _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-1.1), SI.RADIAN); _clAlpha = Amount.valueOf(6.3, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(10), SI.RADIAN); // end-of-linearity _clStar = 1.2; _alphaStall = Amount.valueOf(Math.toRadians(18.0), SI.RADIAN); _clMax = 1.7; // 1.6; _cdMin = 0.00625; _clAtCdMin = 0.1; _kFactorDragPolar = 0.004; _aerodynamicCenterX = 0.243; _cmAC = -0.02; _cmACStall = -0.07; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case NACA23_012: airf.setName(AirfoilEnum.NACA23_012); _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-1.32), SI.RADIAN); _clAlpha = Amount.valueOf(6.3, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(14), SI.RADIAN); // end-of-linearity _clStar = 1.6; _alphaStall = Amount.valueOf(Math.toRadians(18), SI.RADIAN); _clMax = 1.8; // 1.5; _cdMin = 0.00575; _clAtCdMin = 0.23; _kFactorDragPolar = 0.004; _aerodynamicCenterX = 0.247; _cmAC = -0.03; _cmACStall = -0.09; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case NACA65_209: _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-1.3), SI.RADIAN); _clAlpha = Amount.valueOf(5.96, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(11), SI.RADIAN); // end-of-linearity _clStar = 1.1; _alphaStall = Amount.valueOf(Math.toRadians(17.0), SI.RADIAN); _clMax = 1.6; _cdMin = 0.025; _clAtCdMin = 0.2; _kFactorDragPolar = 0.0035; _aerodynamicCenterX = 0.25; _cmAC = -0.07; _cmACStall = -0.09; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case NACA65_206: _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-1.4), SI.RADIAN); _clAlpha = Amount.valueOf(6.13, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(10.0), SI.RADIAN); // end-of-linearity _clStar = _clAlpha.getEstimatedValue() * _alphaStar.getEstimatedValue(); _alphaStall = Amount.valueOf(Math.toRadians(15.0), SI.RADIAN); _clMax = 1.3; _cdMin = 0.025; _clAtCdMin = 0.2; _kFactorDragPolar = 0.0035; _aerodynamicCenterX = 0.25; _cmAC = -0.07; _cmACStall = -0.09; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case NACA0012: airf.setName(AirfoilEnum.NACA0012); _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(0), SI.RADIAN); _clAlpha = Amount.valueOf(6.92, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(11), SI.RADIAN); // end-of-linearity _clStar = 1.23; _alphaStall = Amount.valueOf(Math.toRadians(20.1), SI.RADIAN); _clMax = 1.86; // 1.5; _cdMin = 0.0055; _clAtCdMin = 0.0; _kFactorDragPolar = 0.0035; _aerodynamicCenterX = 0.25; _cmAC = 0.0; _cmACStall = -0.09; _cmAlphaAC = 0.; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; case DFVLR_R4: airf.setName(AirfoilEnum.DFVLR_R4); _id = airf.getId() + "1" + idCounter + "99"; idCounter++; _theAirfoil = airf; geometry = airf.getGeometry(); _alphaZeroLift = Amount.valueOf(Math.toRadians(-3.75), SI.RADIAN); _clAlpha = Amount.valueOf(6.3, SI.RADIAN.inverse()); _alphaStar = Amount.valueOf(Math.toRadians(11), SI.RADIAN); // end-of-linearity _clStar = 1.53; _alphaStall = Amount.valueOf(Math.toRadians(16.75), SI.RADIAN); _clMax = 1.7671; // 1.5; _cdMin = 0.0056; _clAtCdMin = 0.0; _kFactorDragPolar = 0.075; _aerodynamicCenterX = 0.25; _cmAC = -0.1168; _cmACStall = -0.0515; _cmAlphaAC = 0.0015; calculateMachCr = new CalculateMachCr(); calculateCdWaveDrag = new CalculateCdWaveDrag(); break; default: break; } }