def buildDeparturePhase(self): ''' this function manages the departure phases with a ground run and a climb ramp ''' print(self.className + ' ============== build the departure ground run =========== ') self.finalRoute = GroundRunLeg(runway=self.departureRunway, aircraft=self.aircraft, airport=self.departureAirport) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=self.departureAirport, fixListIndex=0) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) elapsedTimeSeconds = 0.0 self.finalRoute.buildDepartureGroundRun( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=elapsedTimeSeconds, distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) #print '==================== end of ground run ==================== ' initialWayPoint = self.finalRoute.getLastVertex().getWeight() distanceToFirstFixNautics = initialWayPoint.getDistanceMetersTo( self.getFirstWayPoint()) * Meter2NauticalMiles #print '==================== Initial Climb Ramp ==================== ' climbRamp = ClimbRamp(initialWayPoint=initialWayPoint, runway=self.departureRunway, aircraft=self.aircraft, departureAirport=self.departureAirport) ''' climb ramp of 5.0 nautics is not possible if first fix placed in between ''' climbRampLengthNautics = min(distanceToFirstFixNautics / 2.0, 5.0) climbRamp.buildClimbRamp( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=initialWayPoint.getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, climbRampLengthNautics=climbRampLengthNautics) self.finalRoute.addGraph(climbRamp) #print '============= initial condition for the route =================' initialWayPoint = self.finalRoute.getLastVertex().getWeight() lastLeg = self.finalRoute.getLastEdge() initialHeadingDegrees = lastLeg.getBearingTailHeadDegrees() print(self.className + ': last leg orientation= {0:.2f} degrees'.format( initialHeadingDegrees)) #'''============= add way point in the fix list =============== ''' self.insert(position='begin', wayPoint=initialWayPoint) #print self.className + ': fix list= {0}'.format(self.fixList) return initialHeadingDegrees, initialWayPoint
def buildDeparturePhase(self): """ this function manages the departure phases with a ground run and a climb ramp """ print self.className + " ============== build the departure ground run =========== " self.finalRoute = GroundRunLeg( runway=self.departureRunway, aircraft=self.aircraft, airport=self.departureAirport ) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=self.departureAirport, fixListIndex=0 ) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() elapsedTimeSeconds = 0.0 self.finalRoute.buildDepartureGroundRun( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=elapsedTimeSeconds, distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, ) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() # print '==================== end of ground run ==================== ' initialWayPoint = self.finalRoute.getLastVertex().getWeight() distanceToFirstFixNautics = initialWayPoint.getDistanceMetersTo(self.getFirstWayPoint()) * Meter2NauticalMiles # print '==================== Initial Climb Ramp ==================== ' climbRamp = ClimbRamp( initialWayPoint=initialWayPoint, runway=self.departureRunway, aircraft=self.aircraft, departureAirport=self.departureAirport, ) """ climb ramp of 5.0 nautics is not possible is first fix in between """ climbRampLengthNautics = min(distanceToFirstFixNautics / 2.0, 5.0) climbRamp.buildClimbRamp( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=initialWayPoint.getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, climbRampLengthNautics=climbRampLengthNautics, ) self.finalRoute.addGraph(climbRamp) # print '============= initial condition for the route =================' initialWayPoint = self.finalRoute.getLastVertex().getWeight() lastLeg = self.finalRoute.getLastEdge() initialHeadingDegrees = lastLeg.getBearingTailHeadDegrees() print self.className + ": last leg orientation= {0:.2f} degrees".format(initialHeadingDegrees) #'''============= add way point in the fix list =============== ''' self.insert(position="begin", wayPoint=initialWayPoint) # print self.className + ': fix list= {0}'.format(self.fixList) return initialHeadingDegrees, initialWayPoint
def buildArrivalPhase(self, initialHeadingDegrees): print( self.className + ': initial heading= {0:.2f} degrees'.format(initialHeadingDegrees)) print(self.className + '==================== add last turn ==================== ') if self.isDomestic() or self.isInBound(): endOfLastGreatCircleWayPoint = self.finalRoute.getLastVertex( ).getWeight() finalHeadingDegrees = self.arrivalRunway.getTrueHeadingDegrees() finalHeadingDegrees = math.fmod(finalHeadingDegrees + 180.0, 360.0) print(self.className + ': runway final heading= {0:.2f} degrees'.format( finalHeadingDegrees)) turnLeg = TurnLeg( initialWayPoint=endOfLastGreatCircleWayPoint, #finalWayPoint = self.firstGlideSlopeWayPoint, finalWayPoint=self.touchDownWayPoint, initialHeadingDegrees=initialHeadingDegrees, aircraft=self.aircraft, reverse=False) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=endOfLastGreatCircleWayPoint, fixListIndex=self.flightListIndex) distanceToLastFixMeters = distanceStillToFlyMeters ''' for the last turn => final heading towards the runway orientation ''' deltaTimeSeconds = 0.1 turnLeg.buildTurnLeg( deltaTimeSeconds=deltaTimeSeconds, elapsedTimeSeconds=endOfLastGreatCircleWayPoint. getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, finalHeadingDegrees=finalHeadingDegrees, lastTurn=True, bankAngleDegrees=5.0, arrivalRunway=self.arrivalRunway) self.finalRoute.addGraph(turnLeg) endOfTurnLegWayPoint = self.finalRoute.getLastVertex().getWeight() ''' ============= use touch-down way-point to compute distance to fly =============''' distanceStillToFlyMeters = endOfTurnLegWayPoint.getDistanceMetersTo( self.touchDownWayPoint) print(self.className + ': distance still to fly= {0:.2f} nautics'.format( distanceStillToFlyMeters * Meter2NauticalMiles)) #print '==================== add descent slope ================= ' descentGlideSlope = DescentGlideSlope( runway=self.arrivalRunway, aircraft=self.aircraft, arrivalAirport=self.arrivalAirport, descentGlideSlopeDegrees=3.0) flownDistanceMeters = self.finalRoute.getLengthMeters() distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=endOfTurnLegWayPoint, fixListIndex=self.flightListIndex) distanceToLastFixMeters = distanceStillToFlyMeters descentGlideSlope.buildGlideSlope( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=endOfTurnLegWayPoint.getElapsedTimeSeconds( ), initialWayPoint=endOfTurnLegWayPoint, flownDistanceMeters=flownDistanceMeters, distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters) self.finalRoute.addGraph(descentGlideSlope) endOfDescentGlideSlope = self.finalRoute.getLastVertex().getWeight( ) #print '================= add arrival ground run ================' arrivalGroundRun = GroundRunLeg(runway=self.arrivalRunway, aircraft=self.aircraft, airport=self.arrivalAirport) arrivalGroundRun.buildArrivalGroundRun( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=endOfDescentGlideSlope. getElapsedTimeSeconds(), initialWayPoint=endOfDescentGlideSlope) self.finalRoute.addGraph(arrivalGroundRun)
def buildSimulatedArrivalPhase(self): print( self.className + '=========== add final turn, descent and ground run ===================' ) arrivalGroundRun = GroundRunLeg(runway=self.arrivalRunway, aircraft=self.aircraft, airport=self.arrivalAirport) self.touchDownWayPoint = arrivalGroundRun.computeTouchDownWayPoint() # add touch down to constraint list self.constraintsList.append( ArrivalRunWayTouchDownConstraint(self.touchDownWayPoint)) print(self.touchDownWayPoint) ''' distance from last fix to touch down ''' distanceToLastFixNautics = self.touchDownWayPoint.getDistanceMetersTo( self.getLastWayPoint()) * Meter2NauticalMiles print( self.className + '===================== final 3 degrees descending glide slope ================' ) descentGlideSlope = DescentGlideSlope( runway=self.arrivalRunway, aircraft=self.aircraft, arrivalAirport=self.arrivalAirport, descentGlideSlopeDegrees=3.0) ''' if there is a fix nearer to 5 nautics of the touch-down then limit size of simulated glide slope ''' descentGlideSlopeSizeNautics = min(distanceToLastFixNautics / 2.0, 5.0) ''' build simulated glide slope ''' descentGlideSlope.buildSimulatedGlideSlope( descentGlideSlopeSizeNautics) self.firstGlideSlopeWayPoint = descentGlideSlope.getVertex( v=0).getWeight() print(self.className + ': top of arrival glide slope= {0}'.format( self.firstGlideSlopeWayPoint)) print( self.className + ' ================= need a turn leg to find the junction point the last way-point in the fix list to the top of the final glide slope' ) ''' initial heading is the orientation of the run-way ''' lastFixListWayPoint = self.wayPointsDict[self.fixList[-1]] initialHeadingDegrees = self.arrivalRunway.getTrueHeadingDegrees() print("=====> arrival runway - true heading degrees = {0}".format( initialHeadingDegrees)) lastTurnLeg = TurnLeg(initialWayPoint=self.firstGlideSlopeWayPoint, finalWayPoint=lastFixListWayPoint, initialHeadingDegrees=initialHeadingDegrees, aircraft=self.aircraft, reverse=True) lastTurnLeg.buildNewSimulatedArrivalTurnLeg( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=0.0, distanceStillToFlyMeters=0.0, simulatedAltitudeSeaLevelMeters=self.firstGlideSlopeWayPoint. getAltitudeMeanSeaLevelMeters(), flightPathAngleDegrees=3.0, bankAngleDegrees=5.0) descentGlideSlope.addGraph(lastTurnLeg) #print self.className + ': compute arrival phase length= {0:.2f} meters'.format(descentGlideSlope.getLengthMeters()) #descentGlideSlope.createXlsxOutputFile() #descentGlideSlope.createKmlOutputFile() ''' prepare next step ''' beginOfLastTurnLeg = lastTurnLeg.getVertex(v=0).getWeight() print(self.className + ': begin of last turn= {0}'.format(beginOfLastTurnLeg)) ''' add to constraint list ''' self.constraintsList.append( TargetApproachConstraint(beginOfLastTurnLeg)) ''' add the three last way-points in the fix list ''' self.insert(position='end', wayPoint=beginOfLastTurnLeg) ''' update the length of the flight path ''' self.distanceFromApproachToTouchDownMeters = descentGlideSlope.getLengthMeters( ) self.flightLengthMeters = self.computeLengthMeters( ) + descentGlideSlope.getLengthMeters() print(self.className + ': updated flight path length= {0:.2f} nautics'.format( self.flightLengthMeters * Meter2NauticalMiles)) ''' target approach fix is equal to the begin of the SIMULATED last turn leg ''' self.aircraft.setTargetApproachWayPoint(beginOfLastTurnLeg) self.aircraft.setArrivalRunwayTouchDownWayPoint(self.touchDownWayPoint) print(self.className + ': fix list= {0}'.format(self.fixList))
def test_TurnLeg(self): print '==================== Turn Leg ==================== ' + time.strftime( "%c") atmosphere = Atmosphere() earth = Earth() acBd = BadaAircraftDatabase() aircraftICAOcode = 'A320' assert acBd.read() assert acBd.aircraftExists(aircraftICAOcode) assert acBd.aircraftPerformanceFileExists(aircraftICAOcode) print '==================== aircraft found ==================== ' + time.strftime( "%c") aircraft = BadaAircraft( ICAOcode=aircraftICAOcode, aircraftFullName=acBd.getAircraftFullName(aircraftICAOcode), badaPerformanceFilePath=acBd.getAircraftPerformanceFile( aircraftICAOcode), atmosphere=atmosphere, earth=earth) aircraft.dump() print '==================== Get Airport ==================== ' + time.strftime( "%c") airportsDB = AirportsDatabase() assert airportsDB.read() print '==================== Get Arrival Airport ==================== ' + time.strftime( "%c") Lisbonne = airportsDB.getAirportFromICAOCode('LPPT') print Lisbonne print '==================== find the run-ways ==================== ' + time.strftime( "%c") runWaysDatabase = RunWayDataBase() if runWaysDatabase.read(): print 'runways DB correctly read' print '==================== take off run-way ==================== ' + time.strftime( "%c") arrivalRunway = runWaysDatabase.getFilteredRunWays( airportICAOcode='LPPT', runwayName='') print arrivalRunway print '==================== Ground run ==================== ' + time.strftime( "%c") groundRun = GroundRunLeg(runway=arrivalRunway, aircraft=aircraft, airport=Lisbonne) touchDownWayPoint = groundRun.computeTouchDownWayPoint() print touchDownWayPoint groundRun.buildDepartureGroundRun(deltaTimeSeconds=1.0, elapsedTimeSeconds=0.0, distanceStillToFlyMeters=0.0, distanceToLastFixMeters=0.0) print '==================== Climb Ramp ==================== ' + time.strftime( "%c") initialWayPoint = groundRun.getLastVertex().getWeight() descentGlideSlope = DescentGlideSlope(runway=arrivalRunway, aircraft=aircraft, arrivalAirport=Lisbonne, descentGlideSlopeDegrees=3.0) ''' if there is a fix nearer to 5 nautics of the touch-down then limit size of simulated glide slope ''' descentGlideSlope.buildSimulatedGlideSlope( descentGlideSlopeSizeNautics=5.0) descentGlideSlope.createKmlOutputFile() firstGlideSlopeWayPoint = descentGlideSlope.getVertex(v=0).getWeight() print '==================== Climb Ramp ==================== ' + time.strftime( "%c") initialWayPoint = groundRun.getLastVertex().getWeight() print ' ================== turn leg end =============== ' wayPointsDb = WayPointsDatabase() assert (wayPointsDb.read()) Exona = wayPointsDb.getWayPoint('EXONA') Rosal = wayPointsDb.getWayPoint('ROSAL') print Rosal.getBearingDegreesTo(Exona) initialHeadingDegrees = arrivalRunway.getTrueHeadingDegrees() lastTurnLeg = TurnLeg(initialWayPoint=firstGlideSlopeWayPoint, finalWayPoint=Exona, initialHeadingDegrees=initialHeadingDegrees, aircraft=aircraft, reverse=True) deltaTimeSeconds = 1.0 lastTurnLeg.buildNewSimulatedArrivalTurnLeg( deltaTimeSeconds=deltaTimeSeconds, elapsedTimeSeconds=0.0, distanceStillToFlyMeters=0.0, simulatedAltitudeSeaLevelMeters=firstGlideSlopeWayPoint. getAltitudeMeanSeaLevelMeters(), flightPathAngleDegrees=3.0) lastTurnLeg.createKmlOutputFile() descentGlideSlope.addGraph(lastTurnLeg) #descentGlideSlope.createXlsxOutputFile() descentGlideSlope.createKmlOutputFile() print ' ================== turn leg end =============== '
def test_ClimbRamp(self): atmosphere = Atmosphere() earth = Earth() print '==================== Three Degrees climb slope ==================== '+ time.strftime("%c") acBd = BadaAircraftDatabase() aircraftICAOcode = 'A320' if acBd.read(): if ( acBd.aircraftExists(aircraftICAOcode) and acBd.aircraftPerformanceFileExists(aircraftICAOcode)): print '==================== aircraft found ==================== '+ time.strftime("%c") aircraft = BadaAircraft( ICAOcode = aircraftICAOcode, aircraftFullName = acBd.getAircraftFullName(aircraftICAOcode), badaPerformanceFilePath = acBd.getAircraftPerformanceFile(aircraftICAOcode), atmosphere = atmosphere, earth = earth) aircraft.dump() assert not(aircraft is None) print '==================== get Charles Gaulle airport ==================== '+ time.strftime("%c") airportsDB = AirportsDatabase() assert(airportsDB.read()) CharlesDeGaulle = airportsDB.getAirportFromICAOCode('LFPG') print CharlesDeGaulle assert not(aircraft is None) aircraft.setTargetCruiseFlightLevel(RequestedFlightLevel = 390, departureAirportAltitudeMSLmeters = CharlesDeGaulle.getAltitudeMeanSeaLevelMeters()) print '==================== Three Degrees climb slope==================== '+ time.strftime("%c") runWaysDatabase = RunWayDataBase() if runWaysDatabase.read(): print 'runways DB correctly read' runway = runWaysDatabase.getFilteredRunWays('LFPG') print runway print '==================== Ground Run ==================== '+ time.strftime("%c") groundRun = GroundRunLeg(runway=runway, aircraft=aircraft, airport=CharlesDeGaulle) groundRun.buildDepartureGroundRun(deltaTimeSeconds = 0.1, elapsedTimeSeconds = 0.0, distanceStillToFlyMeters = 100000.0, distanceToLastFixMeters = 100000.0) print '==================== Three Degrees climb slope==================== '+ time.strftime("%c") initialVertex = groundRun.getVertex(groundRun.getNumberOfVertices()-1) initialWayPoint = initialVertex.getWeight() climbRamp = ClimbRamp(initialWayPoint = initialWayPoint, runway=runway, aircraft=aircraft, departureAirport=CharlesDeGaulle) climbRamp.buildClimbRamp(deltaTimeSeconds = 0.1, elapsedTimeSeconds = 0.0, distanceStillToFlyMeters = 100000.0, distanceToLastFixMeters = 100000.0, climbRampLengthNautics = 5.0 ) groundRun.addGraph(climbRamp) groundRun.createKmlOutputFile() print "=========== ThreeDegreesGlideSlope end =========== " + time.strftime("%c")
def test_One(self): print('=========== main start ==================') aircraftICAOcode = 'A320' atmosphere = Atmosphere() assert (not (atmosphere is None)) earth = Earth() assert (not (earth is None)) acBd = BadaAircraftDatabase() assert acBd.read() if (acBd.aircraftExists(aircraftICAOcode) and acBd.aircraftPerformanceFileExists(aircraftICAOcode)): aircraft = BadaAircraft( ICAOcode=aircraftICAOcode, aircraftFullName=acBd.getAircraftFullName(aircraftICAOcode), badaPerformanceFilePath=acBd.getAircraftPerformanceFile( aircraftICAOcode), atmosphere=atmosphere, earth=earth) aircraft.dump() else: raise ValueError(': aircraft not found= ' + aircraftICAOcode) assert not (aircraft is None) print('================ load airports =================') airportsDB = AirportsDatabase() assert (airportsDB.read()) adepIcaoCode = 'LFML' departureAirport = airportsDB.getAirportFromICAOCode(adepIcaoCode) print(': departure airport= ' + str(departureAirport)) assert not (departureAirport is None) print('================ load runways =================') runWaysDatabase = RunWayDataBase() assert (runWaysDatabase.read()) print('==================== take off run-way ==================== ') departureRunway = runWaysDatabase.getFilteredRunWays(adepIcaoCode) print( '=========== minimum and maximum aircraft mass ==================') minMassKg = aircraft.getMinimumMassKilograms() print('aircraft minimum mass: ' + str(minMassKg) + ' kilograms') maxMassKg = aircraft.getMaximumMassKilograms() print('aircraft maximum mass: ' + str(maxMassKg) + ' kilograms') deltaMass = maxMassKg - minMassKg massKg = 39000.0 while (massKg < maxMassKg): massKg += 1000.0 print( '==================== set aircraft reference mass ==================== ' ) aircraft = BadaAircraft( ICAOcode=aircraftICAOcode, aircraftFullName=acBd.getAircraftFullName(aircraftICAOcode), badaPerformanceFilePath=acBd.getAircraftPerformanceFile( aircraftICAOcode), atmosphere=atmosphere, earth=earth) aircraft.setTargetCruiseFlightLevel( 310, departureAirport.getFieldElevationAboveSeaLevelMeters()) print( '==================== aircraft reference mass ==================== ' ) print('aircraft reference mass= ' + str(massKg) + ' Kilograms') aircraft.setAircraftMassKilograms(massKg) print( '==================== begin of ground run ==================== ' ) groundRunLeg = GroundRunLeg(runway=departureRunway, aircraft=aircraft, airport=departureAirport) groundRunLeg.buildDepartureGroundRun( deltaTimeSeconds=0.1, elapsedTimeSeconds=0.0, distanceStillToFlyMeters=500000.0, distanceToLastFixMeters=500000.0) groundRunLeg.computeLengthMeters() #groundRunLeg.createXlsxOutputFile() print( '==================== end of ground run ==================== ') initialWayPoint = groundRunLeg.getLastVertex().getWeight() print( '==================== dump aircraft speed profile ==================== ' ) aircraft.createStateVectorOutputFile(aircraftICAOcode + "-Mass-" + str(massKg)) print('=========== main end ==================')
print ( '==================== aircraft found ==================== '+ time.strftime("%c") ) aircraft = BadaAircraft(aircraftICAOcode, acBd.getAircraftPerformanceFile(aircraftICAOcode), atmosphere, earth) print ( '==========================' ) print ( runway ) airportIcaoCode = runway.getAirportICAOcode() airport = airportsDB.getAirportFromICAOCode(airportIcaoCode) print ( '==========================' ) print ( airport ) print ( '==================== ground run ==================== '+ time.strftime("%c") ) groundRun = GroundRunLeg(runway=runway, aircraft=aircraft, airport=airport) groundRun.buildDepartureGroundRun() initialWayPoint = groundRun.getLastVertex().getWeight() climbRamp = ClimbRamp(initialWayPoint=initialWayPoint, runway=runway, aircraft=aircraft, departureAirport=airport) climbRamp.buildClimbRamp() groundRun.addGraph(climbRamp) groundRun.createKmlOutputFile()
def buildArrivalPhase(self, initialHeadingDegrees): print self.className + "==================== add last turn ==================== " if self.isDomestic() or self.isInBound(): endOfLastGreatCircleWayPoint = self.finalRoute.getLastVertex().getWeight() finalHeadingDegrees = self.arrivalRunway.getTrueHeadingDegrees() finalHeadingDegrees = math.fmod(finalHeadingDegrees + 180.0, 360.0) print self.className + ": runway final heading= {0:.2f} degrees".format(finalHeadingDegrees) turnLeg = TurnLeg( initialWayPoint=endOfLastGreatCircleWayPoint, # finalWayPoint = self.firstGlideSlopeWayPoint, finalWayPoint=self.touchDownWayPoint, initialHeadingDegrees=initialHeadingDegrees, aircraft=self.aircraft, reverse=False, ) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=endOfLastGreatCircleWayPoint, fixListIndex=self.flightListIndex ) distanceToLastFixMeters = distanceStillToFlyMeters """ for the last turn => final heading towards the runway orientation """ deltaTimeSeconds = 0.1 turnLeg.buildTurnLeg( deltaTimeSeconds=deltaTimeSeconds, elapsedTimeSeconds=endOfLastGreatCircleWayPoint.getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, finalHeadingDegrees=finalHeadingDegrees, lastTurn=True, bankAngleDegrees=5.0, ) self.finalRoute.addGraph(turnLeg) endOfTurnLegWayPoint = self.finalRoute.getLastVertex().getWeight() """ ============= use touch-down way-point to compute distance to fly =============""" distanceStillToFlyMeters = endOfTurnLegWayPoint.getDistanceMetersTo(self.touchDownWayPoint) print self.className + ": distance still to fly= {0:.2f} nautics".format( distanceStillToFlyMeters * Meter2NauticalMiles ) # print '==================== add descent slope ================= ' descentGlideSlope = DescentGlideSlope( runway=self.arrivalRunway, aircraft=self.aircraft, arrivalAirport=self.arrivalAirport, descentGlideSlopeDegrees=3.0, ) flownDistanceMeters = self.finalRoute.getLengthMeters() distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=endOfTurnLegWayPoint, fixListIndex=self.flightListIndex ) distanceToLastFixMeters = distanceStillToFlyMeters descentGlideSlope.buildGlideSlope( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=endOfTurnLegWayPoint.getElapsedTimeSeconds(), initialWayPoint=endOfTurnLegWayPoint, flownDistanceMeters=flownDistanceMeters, distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, ) self.finalRoute.addGraph(descentGlideSlope) endOfDescentGlideSlope = self.finalRoute.getLastVertex().getWeight() # print '================= add arrival ground run ================' arrivalGroundRun = GroundRunLeg( runway=self.arrivalRunway, aircraft=self.aircraft, airport=self.arrivalAirport ) arrivalGroundRun.buildArrivalGroundRun( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=endOfDescentGlideSlope.getElapsedTimeSeconds(), initialWayPoint=endOfDescentGlideSlope, ) self.finalRoute.addGraph(arrivalGroundRun)
def buildSimulatedArrivalPhase(self): print self.className + "=========== add final turn, descent and ground run ===================" arrivalGroundRun = GroundRunLeg(runway=self.arrivalRunway, aircraft=self.aircraft, airport=self.arrivalAirport) self.touchDownWayPoint = arrivalGroundRun.computeTouchDownWayPoint() print self.touchDownWayPoint """ distance from last fix to touch down """ distanceToLastFixNautics = ( self.touchDownWayPoint.getDistanceMetersTo(self.getLastWayPoint()) * Meter2NauticalMiles ) print self.className + "===================== final 3 degrees descending glide slope ================" descentGlideSlope = DescentGlideSlope( runway=self.arrivalRunway, aircraft=self.aircraft, arrivalAirport=self.arrivalAirport, descentGlideSlopeDegrees=3.0, ) """ if there is a fix nearer to 5 nautics of the touch-down then limit size of simulated glide slope """ descentGlideSlopeSizeNautics = min(distanceToLastFixNautics / 2.0, 5.0) """ build simulated glide slope """ descentGlideSlope.buildSimulatedGlideSlope(descentGlideSlopeSizeNautics) self.firstGlideSlopeWayPoint = descentGlideSlope.getVertex(v=0).getWeight() print self.className + ": top of arrival glide slope= {0}".format(self.firstGlideSlopeWayPoint) print self.className + " ================= need a turn leg to find the junction point the last way-point in the fix list to the top of the final glide slope" """ initial heading is the orientation of the run-way """ lastFixListWayPoint = self.wayPointsDict[self.fixList[-1]] initialHeadingDegrees = self.arrivalRunway.getTrueHeadingDegrees() lastTurnLeg = TurnLeg( initialWayPoint=self.firstGlideSlopeWayPoint, finalWayPoint=lastFixListWayPoint, initialHeadingDegrees=initialHeadingDegrees, aircraft=self.aircraft, reverse=True, ) lastTurnLeg.buildNewSimulatedArrivalTurnLeg( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=0.0, distanceStillToFlyMeters=0.0, simulatedAltitudeSeaLevelMeters=self.firstGlideSlopeWayPoint.getAltitudeMeanSeaLevelMeters(), flightPathAngleDegrees=3.0, bankAngleDegrees=5.0, ) descentGlideSlope.addGraph(lastTurnLeg) # print self.className + ': compute arrival phase length= {0:.2f} meters'.format(descentGlideSlope.getLengthMeters()) # descentGlideSlope.createXlsxOutputFile() # descentGlideSlope.createKmlOutputFile() """ prepare next step """ beginOfLastTurnLeg = lastTurnLeg.getVertex(v=0).getWeight() print self.className + ": begin of last turn= {0}".format(beginOfLastTurnLeg) """ add the three last way-points in the fix list """ self.insert(position="end", wayPoint=beginOfLastTurnLeg) """ update the length of the flight path """ self.distanceFromApproachToTouchDownMeters = descentGlideSlope.getLengthMeters() self.flightLengthMeters = self.computeLengthMeters() + descentGlideSlope.getLengthMeters() print self.className + ": updated flight path length= {0:.2f} nautics".format( self.flightLengthMeters * Meter2NauticalMiles ) """ target approach fix is equal to the begin of the SIMULATED last turn leg """ self.aircraft.setTargetApproachWayPoint(beginOfLastTurnLeg) self.aircraft.setArrivalRunwayTouchDownWayPoint(self.touchDownWayPoint) print self.className + ": fix list= {0}".format(self.fixList)
def test_TurnLeg(self): print '==================== Turn Leg ==================== '+ time.strftime("%c") atmosphere = Atmosphere() earth = Earth() acBd = BadaAircraftDatabase() aircraftICAOcode = 'A320' assert acBd.read() assert acBd.aircraftExists(aircraftICAOcode) assert acBd.aircraftPerformanceFileExists(aircraftICAOcode) print '==================== aircraft found ==================== '+ time.strftime("%c") aircraft = BadaAircraft(ICAOcode = aircraftICAOcode, aircraftFullName = acBd.getAircraftFullName(aircraftICAOcode), badaPerformanceFilePath = acBd.getAircraftPerformanceFile(aircraftICAOcode), atmosphere = atmosphere, earth = earth) aircraft.dump() print '==================== Get Airport ==================== '+ time.strftime("%c") airportsDB = AirportsDatabase() assert airportsDB.read() print '==================== Get Arrival Airport ==================== '+ time.strftime("%c") Lisbonne = airportsDB.getAirportFromICAOCode('LPPT') print Lisbonne print '==================== find the run-ways ==================== '+ time.strftime("%c") runWaysDatabase = RunWayDataBase() if runWaysDatabase.read(): print 'runways DB correctly read' print '==================== take off run-way ==================== '+ time.strftime("%c") arrivalRunway = runWaysDatabase.getFilteredRunWays( airportICAOcode = 'LPPT', runwayName = '') print arrivalRunway print '==================== Ground run ==================== '+ time.strftime("%c") groundRun = GroundRunLeg(runway = arrivalRunway, aircraft = aircraft, airport = Lisbonne) touchDownWayPoint = groundRun.computeTouchDownWayPoint() print touchDownWayPoint groundRun.buildDepartureGroundRun(deltaTimeSeconds = 1.0, elapsedTimeSeconds = 0.0, distanceStillToFlyMeters = 0.0, distanceToLastFixMeters = 0.0) print '==================== Climb Ramp ==================== '+ time.strftime("%c") initialWayPoint = groundRun.getLastVertex().getWeight() descentGlideSlope = DescentGlideSlope( runway = arrivalRunway, aircraft = aircraft, arrivalAirport = Lisbonne , descentGlideSlopeDegrees = 3.0) ''' if there is a fix nearer to 5 nautics of the touch-down then limit size of simulated glide slope ''' descentGlideSlope.buildSimulatedGlideSlope(descentGlideSlopeSizeNautics = 5.0) descentGlideSlope.createKmlOutputFile() firstGlideSlopeWayPoint = descentGlideSlope.getVertex(v=0).getWeight() print '==================== Climb Ramp ==================== '+ time.strftime("%c") initialWayPoint = groundRun.getLastVertex().getWeight() print ' ================== turn leg end =============== ' wayPointsDb = WayPointsDatabase() assert (wayPointsDb.read()) Exona = wayPointsDb.getWayPoint('EXONA') Rosal = wayPointsDb.getWayPoint('ROSAL') print Rosal.getBearingDegreesTo(Exona) initialHeadingDegrees = arrivalRunway.getTrueHeadingDegrees() lastTurnLeg = TurnLeg( initialWayPoint = firstGlideSlopeWayPoint, finalWayPoint = Exona, initialHeadingDegrees = initialHeadingDegrees, aircraft = aircraft, reverse = True) deltaTimeSeconds = 1.0 lastTurnLeg.buildNewSimulatedArrivalTurnLeg(deltaTimeSeconds = deltaTimeSeconds, elapsedTimeSeconds = 0.0, distanceStillToFlyMeters = 0.0, simulatedAltitudeSeaLevelMeters = firstGlideSlopeWayPoint.getAltitudeMeanSeaLevelMeters(), flightPathAngleDegrees = 3.0) lastTurnLeg.createKmlOutputFile() descentGlideSlope.addGraph(lastTurnLeg) #descentGlideSlope.createXlsxOutputFile() descentGlideSlope.createKmlOutputFile() print ' ================== turn leg end =============== '
assert runWaysDB.read() arrivalRunway = runWaysDB.getFilteredRunWays( arrivalAirportCode, 'Landing', aircraft.WakeTurbulenceCategory) print(arrivalRunway) aircraft.setArrivalAirportElevationMeters( arrivalAirport.getFieldElevationAboveSeaLevelMeters()) CAS = aircraft.computeLandingStallSpeedCasKnots() TAS = cas2tas( cas=CAS, altitude=arrivalAirport.getFieldElevationAboveSeaLevelMeters(), temp='std', speed_units='kt', alt_units='m', temp_units=default_temp_units, ) aircraft.initStateVector(elapsedTimeSeconds=0.0, trueAirSpeedMetersSecond=TAS, altitudeMeanSeaLevelMeters=arrivalAirport. getFieldElevationAboveSeaLevelMeters(), deltaDistanceFlownMeters=0.0) aircraft.setLandingConfiguration(0.0) groundRun = GroundRunLeg(runway=arrivalRunway, aircraft=aircraft, airport=arrivalAirport) groundRun.buildArrivalGroundRun(0.0) groundRun.createXlsxOutputFile() groundRun.createKmlOutputFile()
def test_One(self): print('==================== departure airport ==================== ' + time.strftime("%c")) airportsDB = AirportsDatabase() assert (airportsDB.read()) CharlesDeGaulle = airportsDB.getAirportFromICAOCode('LFPG') print(CharlesDeGaulle) print('==================== arrival airport ==================== ' + time.strftime("%c")) MarseilleMarignane = airportsDB.getAirportFromICAOCode('LFML') print(MarseilleMarignane) print('==================== Great Circle ==================== ' + time.strftime("%c")) self.aircraft.setCurrentAltitudeSeaLevelMeters( elapsedTimeSeconds=0.0, altitudeMeanSeaLevelMeters=0.0, lastAltitudeMeanSeaLevelMeters=0.0, targetCruiseAltitudeMslMeters=10000.0) self.aircraft.initStateVector( elapsedTimeSeconds=0.0, trueAirSpeedMetersSecond=70.0, airportFieldElevationAboveSeaLevelMeters=152.0) self.aircraft.setTargetCruiseFlightLevel( RequestedFlightLevel=310, departureAirportAltitudeMSLmeters=152.0) print('==================== runways database ==================== ' + time.strftime("%c")) runWaysDatabase = RunWayDataBase() assert runWaysDatabase.read() arrivalRunway = runWaysDatabase.getFilteredRunWays( airportICAOcode='LFML', runwayName='') print('==================== Compute touch down ==================== ' + time.strftime("%c")) arrivalGroundRun = GroundRunLeg(runway=arrivalRunway, aircraft=self.aircraft, airport=MarseilleMarignane) touchDownWayPoint = arrivalGroundRun.computeTouchDownWayPoint() self.aircraft.setArrivalRunwayTouchDownWayPoint(touchDownWayPoint) print("=========== simulated descent glide slope =========== " + time.strftime("%c")) threeDegreesGlideSlope = DescentGlideSlope( runway=arrivalRunway, aircraft=self.aircraft, arrivalAirport=MarseilleMarignane) threeDegreesGlideSlope.buildSimulatedGlideSlope( descentGlideSlopeSizeNautics=5.0) approachWayPoint = threeDegreesGlideSlope.getLastVertex().getWeight() self.aircraft.setTargetApproachWayPoint(approachWayPoint) print('==================== Great Circle ==================== ' + time.strftime("%c")) greatCircle = GreatCircleRoute(initialWayPoint=CharlesDeGaulle, finalWayPoint=approachWayPoint, aircraft=self.aircraft) distanceStillToFlyMeters = CharlesDeGaulle.getDistanceMetersTo( approachWayPoint) greatCircle.computeGreatCircle( deltaTimeSeconds=1.0, elapsedTimeSeconds=0.0, distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceStillToFlyMeters) print('main great circle length= ' + str(greatCircle.computeLengthMeters()) + ' meters') greatCircle.createKmlOutputFile() greatCircle.createXlsxOutputFile()
class FlightPath(FlightPlan): flightPlan = None aircraftICAOcode = '' def __init__(self, route, aircraftICAOcode='A320', RequestedFlightLevel=330.0, cruiseMach=0.8, takeOffMassKilograms=62000.0): self.className = self.__class__.__name__ ''' init mother class ''' FlightPlan.__init__(self, route) ''' first bad and incomplete flight length ''' ''' missing last turn and glide slope ''' self.flightLengthMeters = self.computeLengthMeters() self.aircraftICAOcode = aircraftICAOcode self.aircraft = None self.getAircraft() assert isinstance(self.aircraft, BadaAircraft) and not (self.aircraft is None) self.aircraft.setAircraftMassKilograms(takeOffMassKilograms) assert RequestedFlightLevel >= 15.0 and RequestedFlightLevel <= 450.0 self.aircraft.setTargetCruiseFlightLevel( RequestedFlightLevel=RequestedFlightLevel, departureAirportAltitudeMSLmeters=self.getDepartureAirport( ).getFieldElevationAboveSeaLevelMeters()) self.aircraft.setTargetCruiseMach(cruiseMachNumber=cruiseMach) self.arrivalAirport = self.getArrivalAirport() if (self.arrivalAirport is None): print(self.className + ': there is no arrival airport => flight is out-bound !!!') #assert isinstance(self.arrivalAirport, Airport) and not(self.arrivalAirport is None) self.departureAirport = self.getDepartureAirport() assert isinstance(self.departureAirport, Airport) and not (self.departureAirport is None) def getAircraft(self): print(self.className + ': ================ get aircraft =================') atmosphere = Atmosphere() earth = Earth() acBd = BadaAircraftDatabase() assert acBd.read() if (acBd.aircraftExists(self.aircraftICAOcode) and acBd.aircraftPerformanceFileExists(self.aircraftICAOcode)): print(self.className + ': performance file= {0}'.format( acBd.getAircraftPerformanceFile(self.aircraftICAOcode))) self.aircraft = BadaAircraft( ICAOcode=self.aircraftICAOcode, aircraftFullName=acBd.getAircraftFullName( self.aircraftICAOcode), badaPerformanceFilePath=acBd.getAircraftPerformanceFile( self.aircraftICAOcode), atmosphere=atmosphere, earth=earth) self.aircraft.dump() else: raise ValueError(self.className + ': aircraft not found= ' + self.aircraftICAOcode) def printPassedWayPoint(self, finalWayPoint): minutes, seconds = divmod(finalWayPoint.getElapsedTimeSeconds(), 60) distanceFlownNautics = self.finalRoute.getLengthMeters( ) * Meter2NauticalMiles strMsg = ': passing way-point: {0} - alt= {1:.2f} meters - alt= {2:.2f} feet - already flown distance= {3:.2f} nautics'.format( finalWayPoint.getName(), finalWayPoint.getAltitudeMeanSeaLevelMeters(), finalWayPoint.getAltitudeMeanSeaLevelMeters() * Meter2Feet, distanceFlownNautics) elapsedTimeSeconds = finalWayPoint.getElapsedTimeSeconds() if elapsedTimeSeconds >= 60.0 and elapsedTimeSeconds < 3600.0: minutes, seconds = divmod(elapsedTimeSeconds, 60) strMsg += ' - real time = {0:.2f} seconds - {1:.2f} minutes {2:.2f} seconds'.format( elapsedTimeSeconds, minutes, seconds) else: minutes, seconds = divmod(elapsedTimeSeconds, 60) hours, minutes = divmod(minutes, 60) strMsg += ' - real time = {0:.2f} seconds - {1:.2f} hours {2:.2f} minutes {3:.2f} seconds'.format( elapsedTimeSeconds, hours, minutes, seconds) print(self.className + strMsg) def turnAndFly(self, tailWayPoint, headWayPoint, initialHeadingDegrees, headWayPointIndex): ''' execute a turn to align true heading and then fly a great circle ''' print( ' ================== one Turn Leg for each fix in the list =============== ' ) turnLeg = TurnLeg(initialWayPoint=tailWayPoint, finalWayPoint=headWayPoint, initialHeadingDegrees=initialHeadingDegrees, aircraft=self.aircraft, reverse=False) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=tailWayPoint, fixListIndex=headWayPointIndex) print(self.className + ': distance to last fix= {0:.2f} nautics'.format( distanceToLastFixMeters * Meter2NauticalMiles)) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) print(self.className + ': still to fly= {0:.2f} nautics'.format( distanceStillToFlyMeters * Meter2NauticalMiles)) endOfSimulation = turnLeg.buildTurnLeg( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=tailWayPoint.getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters) self.finalRoute.addGraph(turnLeg) if (endOfSimulation == False): print( ' ==================== end of turn leg ==================== ') endOfTurnLegWayPoint = self.finalRoute.getLastVertex().getWeight() lastLeg = self.finalRoute.getLastEdge() print(self.className + ': end of turn orientation= {0:.2f} degrees'.format( lastLeg.getBearingTailHeadDegrees())) '''==================== check if anticipated turn or fly by is applicable ''' anticipatedTurnWayPoint = None if (self.flightListIndex + 2) < len(self.fixList): ''' still another fix in the list ''' firstAngleDegrees = endOfTurnLegWayPoint.getBearingDegreesTo( headWayPoint) secondAngleDegrees = headWayPoint.getBearingDegreesTo( self.wayPointsDict[self.fixList[self.flightListIndex + 2]]) firstAngleRadians = math.radians(firstAngleDegrees) secondAngleRadians = math.radians(secondAngleDegrees) angleDifferenceDegrees = math.degrees( math.atan2( math.sin(secondAngleRadians - firstAngleRadians), math.cos(secondAngleRadians - firstAngleRadians))) print(self.className + ': difference= {0:.2f} degrees'.format( angleDifferenceDegrees)) tasMetersPerSecond = self.aircraft.getCurrentTrueAirSpeedMetersSecond( ) radiusOfTurnMeters = (tasMetersPerSecond * tasMetersPerSecond ) / (9.81 * math.tan(math.radians(15.0))) anticipatedTurnStartMeters = radiusOfTurnMeters * math.tan( math.radians((180.0 - abs(angleDifferenceDegrees)) / 2.0)) print(self.className + ': anticipated turn start from end point= {0:.2f} meters' .format(anticipatedTurnStartMeters)) if ((endOfTurnLegWayPoint.getDistanceMetersTo(headWayPoint) > (1.1 * anticipatedTurnStartMeters) and abs(angleDifferenceDegrees) > 30.)): print(self.className + ': Envisage anticipated Fly By turn !!!') bearingDegrees = math.fmod(firstAngleDegrees + 180.0, 360.0) anticipatedTurnWayPoint = headWayPoint.getWayPointAtDistanceBearing( Name='Anticipated-Turn-' + headWayPoint.getName(), DistanceMeters=anticipatedTurnStartMeters, BearingDegrees=bearingDegrees) headWayPoint = anticipatedTurnWayPoint print( ' ==================== great circle ======================== ') greatCircle = GreatCircleRoute( initialWayPoint=endOfTurnLegWayPoint, finalWayPoint=headWayPoint, aircraft=self.aircraft) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=endOfTurnLegWayPoint, fixListIndex=headWayPointIndex) print(self.className + ': distance to last fix= {0} nautics'.format( distanceToLastFixMeters * Meter2NauticalMiles)) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) print(self.className + ': still to fly= {0} nautics'.format( distanceStillToFlyMeters * Meter2NauticalMiles)) endOfSimulation = greatCircle.computeGreatCircle( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=endOfTurnLegWayPoint.getElapsedTimeSeconds( ), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters) ''' update final route ''' self.finalRoute.addGraph(greatCircle) print( ' ================== end of great circle ================== ') finalWayPoint = self.finalRoute.getLastVertex().getWeight() #print self.className + ': current end way point= ' + str(finalWayPoint) lastLeg = self.finalRoute.getLastEdge() finalHeadingDegrees = lastLeg.getBearingTailHeadDegrees() #print self.className + ': last leg orientation= {0:.2f} degrees'.format(finalHeadingDegrees) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) print( self.className + ': still to fly= {0:.2f} meters - still to fly= {1:.2f} nautics' .format(distanceStillToFlyMeters, distanceStillToFlyMeters * Meter2NauticalMiles)) ''' print the way point that has been passed right now ''' self.printPassedWayPoint(finalWayPoint) ''' return to caller ''' return endOfSimulation, finalHeadingDegrees, finalWayPoint.getElapsedTimeSeconds( ), anticipatedTurnWayPoint def loopThroughFixList(self, initialHeadingDegrees, elapsedTimeSeconds): anticipatedTurnWayPoint = None ''' start loop over the fix list ''' ''' assumption: fix list does not contain departure and arrival airports ''' self.flightListIndex = 0 ''' loop over the fix list ''' endOfSimulation = False while (endOfSimulation == False) and (self.flightListIndex < len(self.fixList)): #print self.className + ': initial heading degrees= ' + str(initialHeadingDegrees) + ' degrees' ''' get the next fix ''' if (anticipatedTurnWayPoint is None): fix = self.fixList[self.flightListIndex] ''' tail way point to reach ''' tailWayPoint = self.wayPointsDict[fix] else: ''' we do not use the next fix but the anticipated turn way point ''' tailWayPoint = anticipatedTurnWayPoint tailWayPoint.setElapsedTimeSeconds(elapsedTimeSeconds) if (self.flightListIndex + 1) < len(self.fixList): ''' next way point is still in the fix list => not yet the arrival airport ''' headWayPoint = self.wayPointsDict[self.fixList[ self.flightListIndex + 1]] print(headWayPoint) ''' turn and fly ''' endOfSimulation, initialHeadingDegrees, elapsedTimeSeconds, anticipatedTurnWayPoint = self.turnAndFly( tailWayPoint=tailWayPoint, headWayPoint=headWayPoint, initialHeadingDegrees=initialHeadingDegrees, headWayPointIndex=self.flightListIndex) ''' prepare for next loop ''' self.flightListIndex += 1 ''' return final heading of the last great circle ''' return endOfSimulation, initialHeadingDegrees def buildDeparturePhase(self): ''' this function manages the departure phases with a ground run and a climb ramp ''' print(self.className + ' ============== build the departure ground run =========== ') self.finalRoute = GroundRunLeg(runway=self.departureRunway, aircraft=self.aircraft, airport=self.departureAirport) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=self.departureAirport, fixListIndex=0) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) elapsedTimeSeconds = 0.0 self.finalRoute.buildDepartureGroundRun( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=elapsedTimeSeconds, distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) #print '==================== end of ground run ==================== ' initialWayPoint = self.finalRoute.getLastVertex().getWeight() distanceToFirstFixNautics = initialWayPoint.getDistanceMetersTo( self.getFirstWayPoint()) * Meter2NauticalMiles #print '==================== Initial Climb Ramp ==================== ' climbRamp = ClimbRamp(initialWayPoint=initialWayPoint, runway=self.departureRunway, aircraft=self.aircraft, departureAirport=self.departureAirport) ''' climb ramp of 5.0 nautics is not possible if first fix placed in between ''' climbRampLengthNautics = min(distanceToFirstFixNautics / 2.0, 5.0) climbRamp.buildClimbRamp( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=initialWayPoint.getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, climbRampLengthNautics=climbRampLengthNautics) self.finalRoute.addGraph(climbRamp) #print '============= initial condition for the route =================' initialWayPoint = self.finalRoute.getLastVertex().getWeight() lastLeg = self.finalRoute.getLastEdge() initialHeadingDegrees = lastLeg.getBearingTailHeadDegrees() print(self.className + ': last leg orientation= {0:.2f} degrees'.format( initialHeadingDegrees)) #'''============= add way point in the fix list =============== ''' self.insert(position='begin', wayPoint=initialWayPoint) #print self.className + ': fix list= {0}'.format(self.fixList) return initialHeadingDegrees, initialWayPoint def buildSimulatedArrivalPhase(self): print( self.className + '=========== add final turn, descent and ground run ===================' ) arrivalGroundRun = GroundRunLeg(runway=self.arrivalRunway, aircraft=self.aircraft, airport=self.arrivalAirport) self.touchDownWayPoint = arrivalGroundRun.computeTouchDownWayPoint() # add touch down to constraint list self.constraintsList.append( ArrivalRunWayTouchDownConstraint(self.touchDownWayPoint)) print(self.touchDownWayPoint) ''' distance from last fix to touch down ''' distanceToLastFixNautics = self.touchDownWayPoint.getDistanceMetersTo( self.getLastWayPoint()) * Meter2NauticalMiles print( self.className + '===================== final 3 degrees descending glide slope ================' ) descentGlideSlope = DescentGlideSlope( runway=self.arrivalRunway, aircraft=self.aircraft, arrivalAirport=self.arrivalAirport, descentGlideSlopeDegrees=3.0) ''' if there is a fix nearer to 5 nautics of the touch-down then limit size of simulated glide slope ''' descentGlideSlopeSizeNautics = min(distanceToLastFixNautics / 2.0, 5.0) ''' build simulated glide slope ''' descentGlideSlope.buildSimulatedGlideSlope( descentGlideSlopeSizeNautics) self.firstGlideSlopeWayPoint = descentGlideSlope.getVertex( v=0).getWeight() print(self.className + ': top of arrival glide slope= {0}'.format( self.firstGlideSlopeWayPoint)) print( self.className + ' ================= need a turn leg to find the junction point the last way-point in the fix list to the top of the final glide slope' ) ''' initial heading is the orientation of the run-way ''' lastFixListWayPoint = self.wayPointsDict[self.fixList[-1]] initialHeadingDegrees = self.arrivalRunway.getTrueHeadingDegrees() print("=====> arrival runway - true heading degrees = {0}".format( initialHeadingDegrees)) lastTurnLeg = TurnLeg(initialWayPoint=self.firstGlideSlopeWayPoint, finalWayPoint=lastFixListWayPoint, initialHeadingDegrees=initialHeadingDegrees, aircraft=self.aircraft, reverse=True) lastTurnLeg.buildNewSimulatedArrivalTurnLeg( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=0.0, distanceStillToFlyMeters=0.0, simulatedAltitudeSeaLevelMeters=self.firstGlideSlopeWayPoint. getAltitudeMeanSeaLevelMeters(), flightPathAngleDegrees=3.0, bankAngleDegrees=5.0) descentGlideSlope.addGraph(lastTurnLeg) #print self.className + ': compute arrival phase length= {0:.2f} meters'.format(descentGlideSlope.getLengthMeters()) #descentGlideSlope.createXlsxOutputFile() #descentGlideSlope.createKmlOutputFile() ''' prepare next step ''' beginOfLastTurnLeg = lastTurnLeg.getVertex(v=0).getWeight() print(self.className + ': begin of last turn= {0}'.format(beginOfLastTurnLeg)) ''' add to constraint list ''' self.constraintsList.append( TargetApproachConstraint(beginOfLastTurnLeg)) ''' add the three last way-points in the fix list ''' self.insert(position='end', wayPoint=beginOfLastTurnLeg) ''' update the length of the flight path ''' self.distanceFromApproachToTouchDownMeters = descentGlideSlope.getLengthMeters( ) self.flightLengthMeters = self.computeLengthMeters( ) + descentGlideSlope.getLengthMeters() print(self.className + ': updated flight path length= {0:.2f} nautics'.format( self.flightLengthMeters * Meter2NauticalMiles)) ''' target approach fix is equal to the begin of the SIMULATED last turn leg ''' self.aircraft.setTargetApproachWayPoint(beginOfLastTurnLeg) self.aircraft.setArrivalRunwayTouchDownWayPoint(self.touchDownWayPoint) print(self.className + ': fix list= {0}'.format(self.fixList)) def buildArrivalPhase(self, initialHeadingDegrees): print( self.className + ': initial heading= {0:.2f} degrees'.format(initialHeadingDegrees)) print(self.className + '==================== add last turn ==================== ') if self.isDomestic() or self.isInBound(): endOfLastGreatCircleWayPoint = self.finalRoute.getLastVertex( ).getWeight() finalHeadingDegrees = self.arrivalRunway.getTrueHeadingDegrees() finalHeadingDegrees = math.fmod(finalHeadingDegrees + 180.0, 360.0) print(self.className + ': runway final heading= {0:.2f} degrees'.format( finalHeadingDegrees)) turnLeg = TurnLeg( initialWayPoint=endOfLastGreatCircleWayPoint, #finalWayPoint = self.firstGlideSlopeWayPoint, finalWayPoint=self.touchDownWayPoint, initialHeadingDegrees=initialHeadingDegrees, aircraft=self.aircraft, reverse=False) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=endOfLastGreatCircleWayPoint, fixListIndex=self.flightListIndex) distanceToLastFixMeters = distanceStillToFlyMeters ''' for the last turn => final heading towards the runway orientation ''' deltaTimeSeconds = 0.1 turnLeg.buildTurnLeg( deltaTimeSeconds=deltaTimeSeconds, elapsedTimeSeconds=endOfLastGreatCircleWayPoint. getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, finalHeadingDegrees=finalHeadingDegrees, lastTurn=True, bankAngleDegrees=5.0, arrivalRunway=self.arrivalRunway) self.finalRoute.addGraph(turnLeg) endOfTurnLegWayPoint = self.finalRoute.getLastVertex().getWeight() ''' ============= use touch-down way-point to compute distance to fly =============''' distanceStillToFlyMeters = endOfTurnLegWayPoint.getDistanceMetersTo( self.touchDownWayPoint) print(self.className + ': distance still to fly= {0:.2f} nautics'.format( distanceStillToFlyMeters * Meter2NauticalMiles)) #print '==================== add descent slope ================= ' descentGlideSlope = DescentGlideSlope( runway=self.arrivalRunway, aircraft=self.aircraft, arrivalAirport=self.arrivalAirport, descentGlideSlopeDegrees=3.0) flownDistanceMeters = self.finalRoute.getLengthMeters() distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters( ) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=endOfTurnLegWayPoint, fixListIndex=self.flightListIndex) distanceToLastFixMeters = distanceStillToFlyMeters descentGlideSlope.buildGlideSlope( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=endOfTurnLegWayPoint.getElapsedTimeSeconds( ), initialWayPoint=endOfTurnLegWayPoint, flownDistanceMeters=flownDistanceMeters, distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters) self.finalRoute.addGraph(descentGlideSlope) endOfDescentGlideSlope = self.finalRoute.getLastVertex().getWeight( ) #print '================= add arrival ground run ================' arrivalGroundRun = GroundRunLeg(runway=self.arrivalRunway, aircraft=self.aircraft, airport=self.arrivalAirport) arrivalGroundRun.buildArrivalGroundRun( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=endOfDescentGlideSlope. getElapsedTimeSeconds(), initialWayPoint=endOfDescentGlideSlope) self.finalRoute.addGraph(arrivalGroundRun) def computeFlight(self, deltaTimeSeconds): ''' main entry to compute a whole flight ''' self.deltaTimeSeconds = deltaTimeSeconds assert not (self.aircraft is None) assert not (self.departureRunway is None) assert not (self.departureAirport is None) if self.isDomestic() or self.isOutBound(): initialHeadingDegrees, initialWayPoint = self.buildDeparturePhase() if self.isDomestic() or self.isInBound(): assert not (self.arrivalAirport is None) self.buildSimulatedArrivalPhase() #print '==================== Loop over the fix list ==================== ' endOfSimulation, initialHeadingDegrees = self.loopThroughFixList( initialHeadingDegrees=initialHeadingDegrees, elapsedTimeSeconds=initialWayPoint.getElapsedTimeSeconds()) if (endOfSimulation == False): #print '=========== build arrival phase ==============' self.buildArrivalPhase(initialHeadingDegrees) print(self.className + ' ========== delta mass status ==============') print(self.className + ': initial mass= {0:.2f} kilograms = {1:.2f} pounds'.format( self.aircraft.getAircraftInitialMassKilograms(), self.aircraft.getAircraftInitialMassKilograms() * Kilogram2Pounds)) print(self.className + ': final mass= {0:.2f} kilograms = {1:.2f} pounds'.format( self.aircraft.getAircraftCurrentMassKilograms(), self.aircraft.getAircraftCurrentMassKilograms() * Kilogram2Pounds)) print(self.className + ': diff mass= {0:.2f} kilograms = {1:.2f} pounds'.format( self.aircraft.getAircraftInitialMassKilograms() - self.aircraft.getAircraftCurrentMassKilograms(), (self.aircraft.getAircraftInitialMassKilograms() - self.aircraft.getAircraftCurrentMassKilograms()) * Kilogram2Pounds)) print(self.className + ' ========== delta mass status ==============') def createFlightOutputFiles(self): ''' build outputs ''' self.finalRoute.createXlsxOutputFile() self.finalRoute.createKmlOutputFile() ''' add a prefix to the file path to identify the departure and arrival airport ''' filePrefix = '' if not (self.departureAirport is None): filePrefix = self.departureAirport.getICAOcode() if not (self.arrivalAirport is None): filePrefix += '-' + self.arrivalAirport.getICAOcode() self.aircraft.createStateVectorOutputFile(filePrefix) print('{0} - final route length= {1:.2f} nautics'.format( self.className, self.finalRoute.getLengthMeters() * Meter2NauticalMiles))
class FlightPath(FlightPlan): flightPlan = None aircraftICAOcode = "" def __init__( self, route, aircraftICAOcode="A320", RequestedFlightLevel=330.0, cruiseMach=0.8, takeOffMassKilograms=62000.0 ): self.className = self.__class__.__name__ FlightPlan.__init__(self, route) """ first bad and incomplete flight length """ """ missing last turn and glide slope """ self.flightLengthMeters = self.computeLengthMeters() self.aircraftICAOcode = aircraftICAOcode self.aircraft = None self.getAircraft() assert isinstance(self.aircraft, BadaAircraft) and not (self.aircraft is None) self.aircraft.setAircraftMassKilograms(takeOffMassKilograms) assert RequestedFlightLevel >= 15.0 and RequestedFlightLevel <= 450.0 self.aircraft.setTargetCruiseFlightLevel( RequestedFlightLevel=RequestedFlightLevel, departureAirportAltitudeMSLmeters=self.getDepartureAirport().getFieldElevationAboveSeaLevelMeters(), ) self.aircraft.setTargetCruiseMach(cruiseMachNumber=cruiseMach) self.arrivalAirport = self.getArrivalAirport() if self.arrivalAirport is None: print self.className + ": there is no arrival airport => flight is outbound !!!" # assert isinstance(self.arrivalAirport, Airport) and not(self.arrivalAirport is None) self.departureAirport = self.getDepartureAirport() assert isinstance(self.departureAirport, Airport) and not (self.departureAirport is None) def getAircraft(self): print self.className + ": ================ get aircraft =================" atmosphere = Atmosphere() earth = Earth() acBd = BadaAircraftDatabase() assert acBd.read() if acBd.aircraftExists(self.aircraftICAOcode) and acBd.aircraftPerformanceFileExists(self.aircraftICAOcode): print self.className + ": performance file= {0}".format( acBd.getAircraftPerformanceFile(self.aircraftICAOcode) ) self.aircraft = BadaAircraft( ICAOcode=self.aircraftICAOcode, aircraftFullName=acBd.getAircraftFullName(self.aircraftICAOcode), badaPerformanceFilePath=acBd.getAircraftPerformanceFile(self.aircraftICAOcode), atmosphere=atmosphere, earth=earth, ) self.aircraft.dump() else: raise ValueError(self.className + ": aircraft not found= " + self.aircraftICAOcode) def printPassedWayPoint(self, finalWayPoint): minutes, seconds = divmod(finalWayPoint.getElapsedTimeSeconds(), 60) distanceFlownNautics = self.finalRoute.getLengthMeters() * Meter2NauticalMiles strMsg = ": passing waypoint: {0} - alt= {1:.2f} meters - alt= {2:.2f} feet - distance= {3:.2f} nautics".format( finalWayPoint.getName(), finalWayPoint.getAltitudeMeanSeaLevelMeters(), finalWayPoint.getAltitudeMeanSeaLevelMeters() * Meter2Feet, distanceFlownNautics, ) elapsedTimeSeconds = finalWayPoint.getElapsedTimeSeconds() if elapsedTimeSeconds >= 60.0 and elapsedTimeSeconds < 3600.0: minutes, seconds = divmod(elapsedTimeSeconds, 60) strMsg += " - real time = {0:.2f} seconds - {1:.2f} minutes {2:.2f} seconds".format( elapsedTimeSeconds, minutes, seconds ) else: minutes, seconds = divmod(elapsedTimeSeconds, 60) hours, minutes = divmod(minutes, 60) strMsg += " - real time = {0:.2f} seconds - {1:.2f} hours {2:.2f} minutes {3:.2f} seconds".format( elapsedTimeSeconds, hours, minutes, seconds ) print self.className + strMsg def turnAndFly(self, tailWayPoint, headWayPoint, initialHeadingDegrees, headWayPointIndex): """ execute a turn to align true heading and then fly a great circle """ print " ================== one Turn Leg for each fix in the list =============== " turnLeg = TurnLeg( initialWayPoint=tailWayPoint, finalWayPoint=headWayPoint, initialHeadingDegrees=initialHeadingDegrees, aircraft=self.aircraft, reverse=False, ) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=tailWayPoint, fixListIndex=headWayPointIndex ) print self.className + ": distance to last fix= {0} nautics".format( distanceToLastFixMeters * Meter2NauticalMiles ) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() print self.className + ": still to fly= {0} nautics".format(distanceStillToFlyMeters * Meter2NauticalMiles) endOfSimulation = turnLeg.buildTurnLeg( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=tailWayPoint.getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, ) self.finalRoute.addGraph(turnLeg) if endOfSimulation == False: print " ==================== end of turn leg ==================== " endOfTurnLegWayPoint = self.finalRoute.getLastVertex().getWeight() lastLeg = self.finalRoute.getLastEdge() print self.className + ": end of turn orientation= {0:.2f} degrees".format( lastLeg.getBearingTailHeadDegrees() ) """==================== check if anticipated turn or fly by is applicable """ anticipatedTurnWayPoint = None if (self.flightListIndex + 2) < len(self.fixList): """ still another fix in the list """ firstAngleDegrees = endOfTurnLegWayPoint.getBearingDegreesTo(headWayPoint) secondAngleDegrees = headWayPoint.getBearingDegreesTo( self.wayPointsDict[self.fixList[self.flightListIndex + 2]] ) firstAngleRadians = math.radians(firstAngleDegrees) secondAngleRadians = math.radians(secondAngleDegrees) angleDifferenceDegrees = math.degrees( math.atan2( math.sin(secondAngleRadians - firstAngleRadians), math.cos(secondAngleRadians - firstAngleRadians), ) ) print self.className + ": difference= {0:.2f} degrees".format(angleDifferenceDegrees) tasMetersPerSecond = self.aircraft.getCurrentTrueAirSpeedMetersSecond() radiusOfTurnMeters = (tasMetersPerSecond * tasMetersPerSecond) / (9.81 * math.tan(math.radians(15.0))) anticipatedTurnStartMeters = radiusOfTurnMeters * math.tan( math.radians((180.0 - abs(angleDifferenceDegrees)) / 2.0) ) print self.className + ": anticipated turn start from end point= {0:.2f} meters".format( anticipatedTurnStartMeters ) if ( endOfTurnLegWayPoint.getDistanceMetersTo(headWayPoint) > (1.1 * anticipatedTurnStartMeters) and abs(angleDifferenceDegrees) > 30.0 ): print self.className + ": Envisage anticipated Fly By turn !!!!!!!!!!!!!!!!!!!!!!!!!" bearingDegrees = math.fmod(firstAngleDegrees + 180.0, 360.0) anticipatedTurnWayPoint = headWayPoint.getWayPointAtDistanceBearing( Name="Anticipated-Turn-" + headWayPoint.getName(), DistanceMeters=anticipatedTurnStartMeters, BearingDegrees=bearingDegrees, ) headWayPoint = anticipatedTurnWayPoint print " ==================== great circle ======================== " greatCircle = GreatCircleRoute( initialWayPoint=endOfTurnLegWayPoint, finalWayPoint=headWayPoint, aircraft=self.aircraft ) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=endOfTurnLegWayPoint, fixListIndex=headWayPointIndex ) print self.className + ": distance to last fix= {0} nautics".format( distanceToLastFixMeters * Meter2NauticalMiles ) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() print self.className + ": still to fly= {0} nautics".format(distanceStillToFlyMeters * Meter2NauticalMiles) endOfSimulation = greatCircle.computeGreatCircle( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=endOfTurnLegWayPoint.getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, ) """ update final route """ self.finalRoute.addGraph(greatCircle) print " ================== end of great circle ================== " finalWayPoint = self.finalRoute.getLastVertex().getWeight() # print self.className + ': current end way point= ' + str(finalWayPoint) lastLeg = self.finalRoute.getLastEdge() finalHeadingDegrees = lastLeg.getBearingTailHeadDegrees() # print self.className + ': last leg orientation= {0:.2f} degrees'.format(finalHeadingDegrees) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() print self.className + ": still to fly= {0:.2f} meters - still to fly= {1:.2f} nautics".format( distanceStillToFlyMeters, distanceStillToFlyMeters * Meter2NauticalMiles ) """ print the way point that has been passed right now """ self.printPassedWayPoint(finalWayPoint) """ return to caller """ return endOfSimulation, finalHeadingDegrees, finalWayPoint.getElapsedTimeSeconds(), anticipatedTurnWayPoint def loopThroughFixList(self, initialHeadingDegrees, elapsedTimeSeconds): anticipatedTurnWayPoint = None """ start loop over the fix list """ """ fix list does not contain departure and arrival airports """ self.flightListIndex = 0 """ loop over the fix list """ endOfSimulation = False while (endOfSimulation == False) and (self.flightListIndex < len(self.fixList)): # print self.className + ': initial heading degrees= ' + str(initialHeadingDegrees) + ' degrees' """ get the next fix """ if anticipatedTurnWayPoint is None: fix = self.fixList[self.flightListIndex] """ tail way point to reach """ tailWayPoint = self.wayPointsDict[fix] else: """ we do not use the next fix but the anticipated turn way point """ tailWayPoint = anticipatedTurnWayPoint tailWayPoint.setElapsedTimeSeconds(elapsedTimeSeconds) if (self.flightListIndex + 1) < len(self.fixList): """ next way point is still in the fix list => not yet the arrival airport """ headWayPoint = self.wayPointsDict[self.fixList[self.flightListIndex + 1]] """ turn and fly """ endOfSimulation, initialHeadingDegrees, elapsedTimeSeconds, anticipatedTurnWayPoint = self.turnAndFly( tailWayPoint=tailWayPoint, headWayPoint=headWayPoint, initialHeadingDegrees=initialHeadingDegrees, headWayPointIndex=self.flightListIndex, ) """ prepare for next loop """ self.flightListIndex += 1 """ return final heading of the last great circle """ return endOfSimulation, initialHeadingDegrees def buildDeparturePhase(self): """ this function manages the departure phases with a ground run and a climb ramp """ print self.className + " ============== build the departure ground run =========== " self.finalRoute = GroundRunLeg( runway=self.departureRunway, aircraft=self.aircraft, airport=self.departureAirport ) distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=self.departureAirport, fixListIndex=0 ) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() elapsedTimeSeconds = 0.0 self.finalRoute.buildDepartureGroundRun( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=elapsedTimeSeconds, distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, ) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() # print '==================== end of ground run ==================== ' initialWayPoint = self.finalRoute.getLastVertex().getWeight() distanceToFirstFixNautics = initialWayPoint.getDistanceMetersTo(self.getFirstWayPoint()) * Meter2NauticalMiles # print '==================== Initial Climb Ramp ==================== ' climbRamp = ClimbRamp( initialWayPoint=initialWayPoint, runway=self.departureRunway, aircraft=self.aircraft, departureAirport=self.departureAirport, ) """ climb ramp of 5.0 nautics is not possible is first fix in between """ climbRampLengthNautics = min(distanceToFirstFixNautics / 2.0, 5.0) climbRamp.buildClimbRamp( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=initialWayPoint.getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, climbRampLengthNautics=climbRampLengthNautics, ) self.finalRoute.addGraph(climbRamp) # print '============= initial condition for the route =================' initialWayPoint = self.finalRoute.getLastVertex().getWeight() lastLeg = self.finalRoute.getLastEdge() initialHeadingDegrees = lastLeg.getBearingTailHeadDegrees() print self.className + ": last leg orientation= {0:.2f} degrees".format(initialHeadingDegrees) #'''============= add way point in the fix list =============== ''' self.insert(position="begin", wayPoint=initialWayPoint) # print self.className + ': fix list= {0}'.format(self.fixList) return initialHeadingDegrees, initialWayPoint def buildSimulatedArrivalPhase(self): print self.className + "=========== add final turn, descent and ground run ===================" arrivalGroundRun = GroundRunLeg(runway=self.arrivalRunway, aircraft=self.aircraft, airport=self.arrivalAirport) self.touchDownWayPoint = arrivalGroundRun.computeTouchDownWayPoint() print self.touchDownWayPoint """ distance from last fix to touch down """ distanceToLastFixNautics = ( self.touchDownWayPoint.getDistanceMetersTo(self.getLastWayPoint()) * Meter2NauticalMiles ) print self.className + "===================== final 3 degrees descending glide slope ================" descentGlideSlope = DescentGlideSlope( runway=self.arrivalRunway, aircraft=self.aircraft, arrivalAirport=self.arrivalAirport, descentGlideSlopeDegrees=3.0, ) """ if there is a fix nearer to 5 nautics of the touch-down then limit size of simulated glide slope """ descentGlideSlopeSizeNautics = min(distanceToLastFixNautics / 2.0, 5.0) """ build simulated glide slope """ descentGlideSlope.buildSimulatedGlideSlope(descentGlideSlopeSizeNautics) self.firstGlideSlopeWayPoint = descentGlideSlope.getVertex(v=0).getWeight() print self.className + ": top of arrival glide slope= {0}".format(self.firstGlideSlopeWayPoint) print self.className + " ================= need a turn leg to find the junction point the last way-point in the fix list to the top of the final glide slope" """ initial heading is the orientation of the run-way """ lastFixListWayPoint = self.wayPointsDict[self.fixList[-1]] initialHeadingDegrees = self.arrivalRunway.getTrueHeadingDegrees() lastTurnLeg = TurnLeg( initialWayPoint=self.firstGlideSlopeWayPoint, finalWayPoint=lastFixListWayPoint, initialHeadingDegrees=initialHeadingDegrees, aircraft=self.aircraft, reverse=True, ) lastTurnLeg.buildNewSimulatedArrivalTurnLeg( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=0.0, distanceStillToFlyMeters=0.0, simulatedAltitudeSeaLevelMeters=self.firstGlideSlopeWayPoint.getAltitudeMeanSeaLevelMeters(), flightPathAngleDegrees=3.0, bankAngleDegrees=5.0, ) descentGlideSlope.addGraph(lastTurnLeg) # print self.className + ': compute arrival phase length= {0:.2f} meters'.format(descentGlideSlope.getLengthMeters()) # descentGlideSlope.createXlsxOutputFile() # descentGlideSlope.createKmlOutputFile() """ prepare next step """ beginOfLastTurnLeg = lastTurnLeg.getVertex(v=0).getWeight() print self.className + ": begin of last turn= {0}".format(beginOfLastTurnLeg) """ add the three last way-points in the fix list """ self.insert(position="end", wayPoint=beginOfLastTurnLeg) """ update the length of the flight path """ self.distanceFromApproachToTouchDownMeters = descentGlideSlope.getLengthMeters() self.flightLengthMeters = self.computeLengthMeters() + descentGlideSlope.getLengthMeters() print self.className + ": updated flight path length= {0:.2f} nautics".format( self.flightLengthMeters * Meter2NauticalMiles ) """ target approach fix is equal to the begin of the SIMULATED last turn leg """ self.aircraft.setTargetApproachWayPoint(beginOfLastTurnLeg) self.aircraft.setArrivalRunwayTouchDownWayPoint(self.touchDownWayPoint) print self.className + ": fix list= {0}".format(self.fixList) def buildArrivalPhase(self, initialHeadingDegrees): print self.className + "==================== add last turn ==================== " if self.isDomestic() or self.isInBound(): endOfLastGreatCircleWayPoint = self.finalRoute.getLastVertex().getWeight() finalHeadingDegrees = self.arrivalRunway.getTrueHeadingDegrees() finalHeadingDegrees = math.fmod(finalHeadingDegrees + 180.0, 360.0) print self.className + ": runway final heading= {0:.2f} degrees".format(finalHeadingDegrees) turnLeg = TurnLeg( initialWayPoint=endOfLastGreatCircleWayPoint, # finalWayPoint = self.firstGlideSlopeWayPoint, finalWayPoint=self.touchDownWayPoint, initialHeadingDegrees=initialHeadingDegrees, aircraft=self.aircraft, reverse=False, ) distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=endOfLastGreatCircleWayPoint, fixListIndex=self.flightListIndex ) distanceToLastFixMeters = distanceStillToFlyMeters """ for the last turn => final heading towards the runway orientation """ deltaTimeSeconds = 0.1 turnLeg.buildTurnLeg( deltaTimeSeconds=deltaTimeSeconds, elapsedTimeSeconds=endOfLastGreatCircleWayPoint.getElapsedTimeSeconds(), distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, finalHeadingDegrees=finalHeadingDegrees, lastTurn=True, bankAngleDegrees=5.0, ) self.finalRoute.addGraph(turnLeg) endOfTurnLegWayPoint = self.finalRoute.getLastVertex().getWeight() """ ============= use touch-down way-point to compute distance to fly =============""" distanceStillToFlyMeters = endOfTurnLegWayPoint.getDistanceMetersTo(self.touchDownWayPoint) print self.className + ": distance still to fly= {0:.2f} nautics".format( distanceStillToFlyMeters * Meter2NauticalMiles ) # print '==================== add descent slope ================= ' descentGlideSlope = DescentGlideSlope( runway=self.arrivalRunway, aircraft=self.aircraft, arrivalAirport=self.arrivalAirport, descentGlideSlopeDegrees=3.0, ) flownDistanceMeters = self.finalRoute.getLengthMeters() distanceStillToFlyMeters = self.flightLengthMeters - self.finalRoute.getLengthMeters() distanceToLastFixMeters = self.computeDistanceToLastFixMeters( currentPosition=endOfTurnLegWayPoint, fixListIndex=self.flightListIndex ) distanceToLastFixMeters = distanceStillToFlyMeters descentGlideSlope.buildGlideSlope( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=endOfTurnLegWayPoint.getElapsedTimeSeconds(), initialWayPoint=endOfTurnLegWayPoint, flownDistanceMeters=flownDistanceMeters, distanceStillToFlyMeters=distanceStillToFlyMeters, distanceToLastFixMeters=distanceToLastFixMeters, ) self.finalRoute.addGraph(descentGlideSlope) endOfDescentGlideSlope = self.finalRoute.getLastVertex().getWeight() # print '================= add arrival ground run ================' arrivalGroundRun = GroundRunLeg( runway=self.arrivalRunway, aircraft=self.aircraft, airport=self.arrivalAirport ) arrivalGroundRun.buildArrivalGroundRun( deltaTimeSeconds=self.deltaTimeSeconds, elapsedTimeSeconds=endOfDescentGlideSlope.getElapsedTimeSeconds(), initialWayPoint=endOfDescentGlideSlope, ) self.finalRoute.addGraph(arrivalGroundRun) def computeFlight(self, deltaTimeSeconds): """ main entry to compute a whole flight """ self.deltaTimeSeconds = deltaTimeSeconds assert not (self.aircraft is None) assert not (self.departureRunway is None) assert not (self.departureAirport is None) if self.isDomestic() or self.isOutBound(): initialHeadingDegrees, initialWayPoint = self.buildDeparturePhase() if self.isDomestic() or self.isInBound(): assert not (self.arrivalAirport is None) self.buildSimulatedArrivalPhase() # print '==================== Loop over the fix list ==================== ' endOfSimulation, initialHeadingDegrees = self.loopThroughFixList( initialHeadingDegrees=initialHeadingDegrees, elapsedTimeSeconds=initialWayPoint.getElapsedTimeSeconds() ) if endOfSimulation == False: # print '=========== build arrival phase ==============' self.buildArrivalPhase(initialHeadingDegrees) print self.className + " ========== delta mass status ==============" print self.className + ": initial mass= {0:.2f} kilograms = {1:.2f} pounds".format( self.aircraft.getAircraftInitialMassKilograms(), self.aircraft.getAircraftInitialMassKilograms() * Kilogram2Pounds, ) print self.className + ": final mass= {0:.2f} kilograms = {1:.2f} pounds".format( self.aircraft.getAircraftCurrentMassKilograms(), self.aircraft.getAircraftCurrentMassKilograms() * Kilogram2Pounds, ) print self.className + ": diff mass= {0:.2f} kilograms = {1:.2f} pounds".format( self.aircraft.getAircraftInitialMassKilograms() - self.aircraft.getAircraftCurrentMassKilograms(), (self.aircraft.getAircraftInitialMassKilograms() - self.aircraft.getAircraftCurrentMassKilograms()) * Kilogram2Pounds, ) print self.className + " ========== delta mass status ==============" def createFlightOutputFiles(self): """ build outputs """ self.finalRoute.createXlsxOutputFile() self.finalRoute.createKmlOutputFile() """ add a prefix to the file path to identify the departure and arrival airport """ filePrefix = "" if not (self.departureAirport is None): filePrefix = self.departureAirport.getICAOcode() if not (self.arrivalAirport is None): filePrefix += "-" + self.arrivalAirport.getICAOcode() self.aircraft.createStateVectorOutputFile(filePrefix) print self.className + ": final route length= {0} nautics".format( self.finalRoute.getLengthMeters() * Meter2NauticalMiles )
departureAirport = airportsDB.getAirportFromICAOCode('EGLL') assert not (departureAirport is None) print('========== ' + str(arrivalRunway) + ' =================') airportIcaoCode = arrivalRunway.getAirportICAOcode() arrivalAirport = airportsDB.getAirportFromICAOCode(airportIcaoCode) print('arrival airport= {0}'.format(arrivalAirport)) aircraft.setArrivalAirportElevationMeters( arrivalAirport.fieldElevationAboveSeaLevelMeters) print( '=========== add final turn, descent and ground run ===================' ) arrivalGroundRun = GroundRunLeg(runway=arrivalRunway, aircraft=aircraft, airport=arrivalAirport) touchDownWayPoint = arrivalGroundRun.computeTouchDownWayPoint() print(touchDownWayPoint) print( '===================== final 3 degrees descending glide slope ================' ) dummyDescentGlideSlope = DescentGlideSlope(runway=arrivalRunway, aircraft=aircraft, arrivalAirport=arrivalAirport, descentGlideSlopeDegrees=3.0) dummyDescentGlideSlope.buildSimulatedGlideSlope() firstGlideSlopeWayPoint = dummyDescentGlideSlope.getVertex(v=0).getWeight() print('=============== init aircraft state vector =================')
def test_Two(self): t0 = time.clock() print ( " ========== Great Circle ======= time start= ", t0 ) atmosphere = Atmosphere() earth = Earth() print ( '==================== Great Circle ==================== '+ time.strftime("%c") ) acBd = BadaAircraftDatabase() aircraftICAOcode = 'A320' if acBd.read(): if ( acBd.aircraftExists(aircraftICAOcode) and acBd.aircraftPerformanceFileExists(aircraftICAOcode)): print ( '==================== aircraft found ==================== '+ time.strftime("%c") ) aircraft = BadaAircraft(ICAOcode = aircraftICAOcode, aircraftFullName = acBd.getAircraftFullName(aircraftICAOcode), badaPerformanceFilePath = acBd.getAircraftPerformanceFile(aircraftICAOcode), atmosphere = atmosphere, earth = earth) print ( aircraft ) else: print ( '==================== airport database ==================== '+ time.strftime("%c") ) airportsDB = AirportsDatabase() assert not(airportsDB is None) wayPointsDb = WayPointsDatabase() assert (wayPointsDb.read()) initialWayPoint = wayPointsDb.getWayPoint('TOU') finalWayPoint = wayPointsDb.getWayPoint('ALIVA') print ( initialWayPoint.getBearingDegreesTo(finalWayPoint) ) print ( finalWayPoint.getBearingDegreesTo(initialWayPoint) ) ''' departure ground run => initial speed is null ''' trueAirSpeedMetersSecond = 70.0 elapsedTimeSeconds = 0.0 aircraft.setCurrentAltitudeSeaLevelMeters( elapsedTimeSeconds = 0.0 , altitudeMeanSeaLevelMeters = 0.0, lastAltitudeMeanSeaLevelMeters = 0.0, targetCruiseAltitudeMslMeters = 10000.0) aircraft.initStateVector( elapsedTimeSeconds = 0.0, trueAirSpeedMetersSecond = 70.0, airportFieldElevationAboveSeaLevelMeters = 152.0) aircraft.setTargetCruiseFlightLevel(RequestedFlightLevel = 310, departureAirportAltitudeMSLmeters = 152.0) print ( "=========== simulated descent glide slope =========== " + time.strftime("%c") ) MarseilleMarignane = airportsDB.getAirportFromICAOCode('LFML') print ( '==================== runways database ==================== '+ time.strftime("%c") ) runWaysDatabase = RunWayDataBase() assert runWaysDatabase.read() runway = runWaysDatabase.getFilteredRunWays(airportICAOcode = 'LFML', runwayName = '') arrivalGroundRun = GroundRunLeg( runway = runway, aircraft = aircraft, airport = MarseilleMarignane ) touchDownWayPoint = arrivalGroundRun.computeTouchDownWayPoint() aircraft.setArrivalRunwayTouchDownWayPoint(touchDownWayPoint) threeDegreesGlideSlope = DescentGlideSlope(runway = runway, aircraft = aircraft, arrivalAirport = MarseilleMarignane ) threeDegreesGlideSlope.buildSimulatedGlideSlope(descentGlideSlopeSizeNautics = 5.0) approachWayPoint = threeDegreesGlideSlope.getLastVertex().getWeight() aircraft.setTargetApproachWayPoint(approachWayPoint) ''' ==================================''' greatCircle = GreatCircleRoute(initialWayPoint = initialWayPoint, finalWayPoint = finalWayPoint, aircraft = aircraft) distanceStillToFlyMeters = initialWayPoint.getDistanceMetersTo(approachWayPoint) greatCircle.computeGreatCircle( deltaTimeSeconds = 0.1, elapsedTimeSeconds = 0.0, distanceStillToFlyMeters = distanceStillToFlyMeters, distanceToLastFixMeters = distanceStillToFlyMeters) print ( 'main great circle length= ' + str(greatCircle.computeLengthMeters()) + ' meters' ) greatCircle.createKmlOutputFile() greatCircle.createXlsxOutputFile()
def test_ClimbRamp(self): atmosphere = Atmosphere() earth = Earth() print '==================== Three Degrees climb slope ==================== ' + time.strftime( "%c") acBd = BadaAircraftDatabase() aircraftICAOcode = 'A320' if acBd.read(): if (acBd.aircraftExists(aircraftICAOcode) and acBd.aircraftPerformanceFileExists(aircraftICAOcode)): print '==================== aircraft found ==================== ' + time.strftime( "%c") aircraft = BadaAircraft( ICAOcode=aircraftICAOcode, aircraftFullName=acBd.getAircraftFullName( aircraftICAOcode), badaPerformanceFilePath=acBd.getAircraftPerformanceFile( aircraftICAOcode), atmosphere=atmosphere, earth=earth) aircraft.dump() assert not (aircraft is None) print '==================== get Charles Gaulle airport ==================== ' + time.strftime( "%c") airportsDB = AirportsDatabase() assert (airportsDB.read()) CharlesDeGaulle = airportsDB.getAirportFromICAOCode('LFPG') print CharlesDeGaulle assert not (aircraft is None) aircraft.setTargetCruiseFlightLevel( RequestedFlightLevel=390, departureAirportAltitudeMSLmeters=CharlesDeGaulle. getAltitudeMeanSeaLevelMeters()) print '==================== Three Degrees climb slope==================== ' + time.strftime( "%c") runWaysDatabase = RunWayDataBase() if runWaysDatabase.read(): print 'runways DB correctly read' runway = runWaysDatabase.getFilteredRunWays('LFPG') print runway print '==================== Ground Run ==================== ' + time.strftime( "%c") groundRun = GroundRunLeg(runway=runway, aircraft=aircraft, airport=CharlesDeGaulle) groundRun.buildDepartureGroundRun(deltaTimeSeconds=0.1, elapsedTimeSeconds=0.0, distanceStillToFlyMeters=100000.0, distanceToLastFixMeters=100000.0) print '==================== Three Degrees climb slope==================== ' + time.strftime( "%c") initialVertex = groundRun.getVertex(groundRun.getNumberOfVertices() - 1) initialWayPoint = initialVertex.getWeight() climbRamp = ClimbRamp(initialWayPoint=initialWayPoint, runway=runway, aircraft=aircraft, departureAirport=CharlesDeGaulle) climbRamp.buildClimbRamp(deltaTimeSeconds=0.1, elapsedTimeSeconds=0.0, distanceStillToFlyMeters=100000.0, distanceToLastFixMeters=100000.0, climbRampLengthNautics=5.0) groundRun.addGraph(climbRamp) groundRun.createKmlOutputFile() print "=========== ThreeDegreesGlideSlope end =========== " + time.strftime( "%c")
else: raise ValueError('runways not read correctly') print('==================== find the run-ways ==================== ' + time.strftime("%c")) for runway in runWaysDB.getRunWays(): print('==================== aircraft found ==================== ' + time.strftime("%c")) aircraft = BadaAircraft( aircraftICAOcode, acBd.getAircraftPerformanceFile(aircraftICAOcode), atmosphere, earth) print('==================== run-way ==================== ') print(runway) airportIcaoCode = runway.getAirportICAOcode() departureAirport = airportsDB.getAirportFromICAOCode(airportIcaoCode) print('====================== departure airport =================') print(departureAirport) print('==================== ground run ==================== ') groundRun = GroundRunLeg(runway=runway, aircraft=aircraft, airport=departureAirport) groundRun.buildDepartureGroundRun(elapsedTimeSeconds=0.0, distanceStillToFlyMeters=600000.0) groundRun.createKmlOutputFile()