Пример #1
0
void Curves2Degs ()
{

	// convert rads to degs for IDT_WRAP curves

	PCURVE pCurve = _CurveRsc.pCurves;

	for (;;)
	{

		if (pCurve == NULL) break;

		if (pCurve->IndexType == IDT_WRAP)
		{

			pCurve->MinIndex = Rads2Degs (pCurve->MinIndex);
			pCurve->MaxIndex = Rads2Degs (pCurve->MaxIndex);
			pCurve->DeltaIndex = Rads2Degs (pCurve->DeltaIndex);

			ULong n;
			for (n=0; n<pCurve->cPoints; n++)
				pCurve->CurveData[n].index = Rads2Degs (pCurve->CurveData[n].index);

		}

		pCurve = pCurve->List.NextItem();
	}

}
Пример #2
0
//컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴
//Procedure		DerivativeBase
//Author		Andrew McRae
//Date			Tue 17 Jun 1997
//
//Description	Used to calibrate model with linearized
//				stability derivatives
//
//				This model is aerodynamically accurate
//				for small disturbances from level flight.
//
//Inputs		
//
//Returns	
//
//------------------------------------------------------------------------------
void Model::DerivativeBase ()
{

/*

	Stability Derivatives

	Forces X,Y,Z
	Moments L,M,N

	Velocity u,v,w
	Angular Velocity p,q,r
	Roll, Pitch, Yaw inputs a,b,c
	Downward Acceleration wd (za)

	(r = density)
	(everything has 0.5)

	Forces									Moments

	Forward		Stbd		Down			Roll		Pitch		Yaw

	Xu	rVS		Yu	...		Zu	rVS			Lu	...		Mu	rVSc	Nu	...
	Xv	...		Yv	rVS		Zv	...			Lv	rVSb	Mv	...		Nv	rVSb
	Xw	rVS		Yw	...		Zw	rVS			Lw	...		Mw	rVSc	Nw	...

	Xp	...		Yp	rVSb	Zp	...			Lp	rVSb2	Mp	...		Np	rVSb2
	Xq	rVSc	Yq	...		Zq	rVSc		Lq	...		Mq	rVSc2	Nq	...
	Xr	...		Yr	rVSb	Zr	...			Lr	rVSb2	Mr	...		Nr	rVSb2

	Xa	...		Ya	rV2S	Za	...			La	rV2Sb	Ma	...		Na	rV2Sb
	Xb	rV2S	Yb	...		Zb	rV2S		Lb	...		Mb	rV2Sc	Nb	...
	Xc	...		Yc	rV2S	Zc	...			Lc	rV2Sb	Mc	...		Nc	rV2Sb

	Xwd	rSc		Ywd	...		Zwd	rSc			Lwd	...		Mwd	rSc2	Nwd	...

*/

	typedef struct vel { FP u,v,w; } VEL;
	typedef struct rotvel { FP p,q,r; } ROTVEL;
	typedef struct ctrl { FP a,b,c; } CTRL;
	typedef struct acc { FP ud,vd,wd; } ACC;

	typedef struct veldervs { VEL X,Y,Z,L,M,N; } VELDERVS;
	typedef struct rotveldervs { ROTVEL X,Y,Z,L,M,N; } ROTVELDERVS;
	typedef struct ctrldervs { CTRL X,Y,Z,L,M,N; } CTRLDERVS;
	typedef struct accdervs { ACC X,Y,Z,L,M,N; } ACCDERVS;

	VELDERVS V;
	ROTVELDERVS RV;
	CTRLDERVS C;
	ACCDERVS A;

//DeadCode AMM 24Nov99 	MODEL_DT = 3;
	MODEL_LOOPS = 1;

	static Bool setup = TRUE;

	FP testalpha = -Degs2Rads ((FP)Elevator / 3000);
	if (testalpha > DEGS2RADS(10)) testalpha = DEGS2RADS(10);
	if (testalpha < DEGS2RADS(-10)) testalpha = DEGS2RADS(-10);

	if (setup)
	{

		// temp
		Pos.y = FT_3000;

		Vel.x = 0;
		Vel.y = 0;
		Vel.z = 150;

		Ori.x.x = 1;
		Ori.x.y = 0;
		Ori.x.z = 0;
		Ori.y.x = 0;
		Ori.y.y = 1;
		Ori.y.z = 0;
		Ori.z.x = 0;
		Ori.z.y = 0;
		Ori.z.z = 1;

//		RotOriXVec (Ori, testalpha);

//		RotOriXVec (Ori, DEGS2RADS(5));
		RotOriYVec (Ori, DEGS2RADS(10));

		RotVel.x = 0;
		RotVel.y = 0;
		RotVel.z = 0;

		RotVel.y = 0.00105;	// 1 rpm
		RotVel.z = -0.00105;

		// temp end
		setup = FALSE;
	}

//	UpdateAirStruc ();

	Sky.Ambient (Pos.y, AmbDensity, AmbTemp, AmbPres);

	CalcAirVel ();

	GearTouched = FALSE;

	// Set Mass and Rot Inertia
	Mass = 0;
	NullVec (RotInertia);
	PMODEL pModel = ControlledAC->fly.pModel;

	PMASSPOINT pMass = MassList;
	while (pMass != NULL)
	{
		pMass->Process (pModel);
		pMass = pMass->List.NextItem ();
	}

//	ProcessEngines ();

	Mass = 617415;
	RotInertia.x = 1.49534e10;
	RotInertia.y = 3.59877e10;
	RotInertia.z = 4.98958e10;

	// WORK IN STANDARD UNITS

	// Calc Derivative Mutipliers
	FP B = (MainPlaneList->Area / MainPlaneList->Chord) * 0.01;
	FP Ch = MainPlaneList->Chord * 0.01;

	FP rS = 0.5 * (AmbDensity * 10000) * (MainPlaneList->Area * 0.0001);

	FP rVS = rS * AirSpeed;
	FP rVSb = rVS * B;
	FP rVSc = rVS * Ch;
	FP rVSb2 = rVSb * B;
	FP rVSc2 = rVSc * Ch;

	FP rV2S = rVS * AirSpeed;
	FP rV2Sb = rV2S * B;
	FP rV2Sc = rV2S * Ch;

	FP rSc = rS * Ch;
	FP rSc2 = rSc * Ch;

	// Get derivative inputs

	// Velocities
	FP u = -AirVel.z;
	FP v = -AirVel.x;
	FP w = AirVel.y;

	// Rotational velocities
	FP p = RotVel.z * 100;
	FP q = RotVel.x * 100;
	FP r = -RotVel.y * 100;

	// Calc Control inputs
	FP a = -((FP)Aileron * F2PIE * 20) / (32768 * 360);
	FP b = ((FP)Elevator * F2PIE * 20) / (32768 * 360);
	FP c = -((FP)Rudder * F2PIE * 20) / (32768 * 360);

	// Acceleration
	FP ud = 0;
	FP vd = 0;
	FP wd = 0;


	// Calc alpha
	FP alpha = CalcAngle (VecLen2D (u,v), w);
	if (alpha > DEGS2RADS(180)) alpha -= DEGS2RADS(360);
	alpha += DEGS2RADS (3);

//	alpha = testalpha;

//	if (alpha > DEGS2RADS(10)) alpha = DEGS2RADS(10);
//	if (alpha < DEGS2RADS(-10)) alpha = DEGS2RADS(-10);

	FP Sin = FSin (alpha);
	FP Cos = FCos (alpha);

	// Calc Cl, Cd

	FP Cl = alpha * 5.27;
	FP Cd = alpha * 0.29;

#ifdef PRINT_DERV_DATA
	PrintVar (30, 16, "alp %.2f  ", Rads2Degs(alpha));
	PrintVar (45, 16, "Cl %.2f  ", Cl);
	PrintVar (60, 16, "Cd %.2f  ", Cd);

	PrintVar (30, 18, "u %.4f  ", u);
	PrintVar (45, 18, "v %.4f  ", v);
	PrintVar (60, 18, "w %.4f  ", w);

	PrintVar (30, 19, "p %.4f  ", p);
	PrintVar (45, 19, "q %.4f  ", q);
	PrintVar (60, 19, "r %.4f  ", r);

#endif

	// Force Velocity dervs
	V.X.u = -Cd * u * rVS;			V.Y.u = 0 * u * rVS;	   		V.Z.u = -Cl * u * rVS;
	V.X.v = 0 * v * rVS;	   		V.Y.v = -0.546 * v * rVS;		V.Z.v = 0 * v * rVS;
	V.X.w = Cl * w * rVS;			V.Y.w = 0 * w * rVS;	   		V.Z.w = -Cd * w * rVS;

	// Moment Velocity dervs
	V.L.u = 0 * u * rVSb;			V.M.u = 0 * u * rVSc;			V.N.u = 0 * u * rVSb;
	V.L.v = -0.0654 * v * rVSb;		V.M.v = 0 * v * rVSc;			V.N.v = 0.118 * v * rVSb;
	V.L.w = 0 * w * rVSb;			V.M.w = -0.44 * w * rVSc;		V.N.w = 0 * w * rVSb;

	// *****************
	// * V.M.w is iffy *
	// *****************

	// Force RotVel dervs
	RV.X.p = 0;						RV.Y.p = 0 * p * rVSb;	  		RV.Z.p = 0;
	RV.X.q = 0 * q * rVSc;			RV.Y.q = 0;						RV.Z.q = 0 * q * rVSc;
	RV.X.r = 0;						RV.Y.r = 0.1435 * r * rVSb;		RV.Z.r = 0;

	// Moment RotVel dervs
	RV.L.p = -0.195 * p * rVSb2;	RV.M.p = 0;						RV.N.p = -0.008 * p * rVSb2;
	RV.L.q = 0;	   					RV.M.q = -0.032 * q * rVSc2;	RV.N.q = 0;
	RV.L.r = 0.0575 * r * rVSb2;	RV.M.r = 0;						RV.N.r = -0.067 * r * rVSb2;
	// Check M.q (c/2U ?????)


	// Force Control dervs
	C.X.a = 0;							C.Y.a = 0 * a * rV2S;				C.Z.a = 0;
	C.X.b = 0.43 * Sin * b * rV2S;		C.Y.b = 0;							C.Z.b = 0.43 * b * Cos * rV2S;
	C.X.c = 0;							C.Y.c = 0.149 * c * rV2S;			C.Z.c = 0;

	// Moment Control dervs
	C.L.a = -0.114 * a * rV2Sb;			C.M.a = 0;							C.N.a = 0.009 * a * rV2Sb;
	C.L.b = 0;							C.M.b = -0.934 * b * rV2Sc;			C.N.b = 0;
	C.L.c = 0.0057 * c * rV2Sb;			C.M.c = 0;							C.N.c = -0.069 * c * rV2Sb;

	// Z Acc dervs
	// use Cm alpha dot	in F94A derv tables

#ifdef PRINT_DERV_DATA
	PrintVar (30, 0, "V.X.u %.0f  ", V.X.u);
	PrintVar (45, 0, "V.Y.u %.0f  ", V.Y.u);
	PrintVar (60, 0, "V.Z.u %.0f  ", V.Z.u);

	PrintVar (30, 1, "V.X.v %.0f  ", V.X.v);
	PrintVar (45, 1, "V.Y.v %.0f  ", V.Y.v);
	PrintVar (60, 1, "V.Z.v %.0f  ", V.Z.v);

	PrintVar (30, 2, "V.X.w %.0f  ", V.X.w);
	PrintVar (45, 2, "V.Y.w %.0f  ", V.Y.w);
	PrintVar (60, 2, "V.Z.w %.0f  ", V.Z.w);

	PrintVar (30, 4, "V.L.u %.0f  ", V.L.u);
	PrintVar (45, 4, "V.M.u %.0f  ", V.M.u);
	PrintVar (60, 4, "V.N.u %.0f  ", V.N.u);

	PrintVar (30, 5, "V.L.v %.0f  ", V.L.v);
	PrintVar (45, 5, "V.M.v %.0f  ", V.M.v);
	PrintVar (60, 5, "V.N.v %.0f  ", V.N.v);

	PrintVar (30, 6, "V.L.w %.0f  ", V.L.w);
	PrintVar (45, 6, "V.M.w %.0f  ", V.M.w);
	PrintVar (60, 6, "V.N.w %.0f  ", V.N.w);


	PrintVar (30, 8, "RV.X.p %.0f  ", RV.X.p);
	PrintVar (45, 8, "RV.Y.p %.0f  ", RV.Y.p);
	PrintVar (60, 8, "RV.Z.p %.0f  ", RV.Z.p);

	PrintVar (30, 9, "RV.X.q %.0f  ", RV.X.q);
	PrintVar (45, 9, "RV.Y.q %.0f  ", RV.Y.q);
	PrintVar (60, 9, "RV.Z.q %.0f  ", RV.Z.q);

	PrintVar (30, 10, "RV.X.r %.0f  ", RV.X.r);
	PrintVar (45, 10, "RV.Y.r %.0f  ", RV.Y.r);
	PrintVar (60, 10, "RV.Z.r %.0f  ", RV.Z.r);

	PrintVar (30, 12, "RV.L.p %.0f  ", RV.L.p);
	PrintVar (45, 12, "RV.M.p %.0f  ", RV.M.p);
	PrintVar (60, 12, "RV.N.p %.0f  ", RV.N.p);

	PrintVar (30, 13, "RV.L.q %.0f  ", RV.L.q);
	PrintVar (45, 13, "RV.M.q %.0f  ", RV.M.q);
	PrintVar (60, 13, "RV.N.q %.0f  ", RV.N.q);

	PrintVar (30, 14, "RV.L.r %.0f  ", RV.L.r);
	PrintVar (45, 14, "RV.M.r %.0f  ", RV.M.r);
	PrintVar (60, 14, "RV.N.r %.0f  ", RV.N.r);

#endif

	// calc forces

	FCRD force;

	force.x = V.X.u + V.X.v + V.X.w + RV.X.p + RV.X.q + RV.X.r + C.X.a + C.X.b + C.X.c;
	force.y = V.Y.u + V.Y.v + V.Y.w + RV.Y.p + RV.Y.q + RV.Y.r + C.Y.a + C.Y.b + C.Y.c;
	force.z = V.Z.u + V.Z.v + V.Z.w + RV.Z.p + RV.Z.q + RV.Z.r + C.Z.a + C.Z.b + C.Z.c;

	NettForce.x = force.y;
	NettForce.y = -force.z;
	NettForce.z = force.x;

	// calc moments

	FCRD moment;
	moment.x = V.L.u + V.L.v + V.L.w + RV.L.p + RV.L.q + RV.L.r + C.L.a + C.L.b + C.L.c;
	moment.y = V.M.u + V.M.v + V.M.w + RV.M.p + RV.M.q + RV.M.r + C.M.a + C.M.b + C.M.c;
	moment.z = V.N.u + V.N.v + V.N.w + RV.N.p + RV.N.q + RV.N.r + C.N.a + C.N.b + C.N.c;

	NettMoment.x = moment.y * 100;
	NettMoment.y = -moment.z * 100;
	NettMoment.z = moment.x * 100;

	// Engines

	PTHRUSTPOINT pThrust = ThrustList;
	while (pThrust != NULL)
	{
		pThrust->Process ();
		NettForce.x += pThrust->Force.x;
		NettForce.y += pThrust->Force.y;
		NettForce.z += pThrust->Force.z;
		pThrust = pThrust->List.NextItem ();
	}


	MODLIMIT (NettForce.x, 600000);
	MODLIMIT (NettForce.y, 2500000);
	MODLIMIT (NettForce.z, 600000);

	MODLIMIT (NettMoment.x, 250000000);
	MODLIMIT (NettMoment.y, 250000000);
	MODLIMIT (NettMoment.z, 250000000);

	CalcAcc ();
//TempCode ARM 15Jul97 	{
//TempCode ARM 15Jul97 		OldAcc.x = Acc.x;
//TempCode ARM 15Jul97 		OldAcc.y = Acc.y;
//TempCode ARM 15Jul97 		OldAcc.z = Acc.z;
//TempCode ARM 15Jul97 
//TempCode ARM 15Jul97 		Acc.x = (NettForce.x / Mass);
//TempCode ARM 15Jul97 		Acc.y = (NettForce.y / Mass);
//TempCode ARM 15Jul97 		Acc.z = (NettForce.z / Mass);
//TempCode ARM 15Jul97 	}

	CalcRotAcc ();
//TempCode ARM 15Jul97 	{
//TempCode ARM 15Jul97 		OldRotAcc.x = RotAcc.x;
//TempCode ARM 15Jul97 		OldRotAcc.y = RotAcc.y;
//TempCode ARM 15Jul97 		OldRotAcc.z = RotAcc.z;
//TempCode ARM 15Jul97 
//TempCode ARM 15Jul97 		RotAcc.x = (NettMoment.x / RotInertia.x);
//TempCode ARM 15Jul97 		RotAcc.y = (NettMoment.y / RotInertia.y);
//TempCode ARM 15Jul97 		RotAcc.z = (NettMoment.z / RotInertia.z);
//TempCode ARM 15Jul97 	}
			
	TransInt (ALL);
//TempCode ARM 15Jul97 	{
//TempCode ARM 15Jul97 		FCRD acc;
//TempCode ARM 15Jul97 
//TempCode ARM 15Jul97 		acc.x = (OldAcc.x + Acc.x) * 0.5;
//TempCode ARM 15Jul97 		acc.y = (OldAcc.y + Acc.y) * 0.5;
//TempCode ARM 15Jul97 		acc.z = (OldAcc.z + Acc.z) * 0.5;
//TempCode ARM 15Jul97 
//TempCode ARM 15Jul97 		TnsPnt (acc, acc, Ori);
//TempCode ARM 15Jul97 
//TempCode ARM 15Jul97 		OldVel.x = Vel.x;
//TempCode ARM 15Jul97 		OldVel.y = Vel.y;
//TempCode ARM 15Jul97 		OldVel.z = Vel.z;
//TempCode ARM 15Jul97 
//TempCode ARM 15Jul97 		Vel.x += acc.x * MODEL_DT;
//TempCode ARM 15Jul97 		Vel.y += (acc.y - GRAVITY) * MODEL_DT;
//TempCode ARM 15Jul97 		Vel.z += acc.z * MODEL_DT;
//TempCode ARM 15Jul97 
//TempCode ARM 15Jul97 		OldPos.x = Pos.x;
//TempCode ARM 15Jul97 		OldPos.y = Pos.y;
//TempCode ARM 15Jul97 		OldPos.z = Pos.z;
//TempCode ARM 15Jul97 
//TempCode ARM 15Jul97 		Pos.x += ((OldVel.x + Vel.x) * MODEL_DT) * 0.5;
//TempCode ARM 15Jul97 		Pos.y += ((OldVel.y + Vel.y) * MODEL_DT) * 0.5;
//TempCode ARM 15Jul97 		Pos.z += ((OldVel.z + Vel.z) * MODEL_DT) * 0.5;
//TempCode ARM 15Jul97 	}

	RotInt (ALL);
//TempCode ARM 15Jul97 	{
//TempCode ARM 15Jul97 		OldRotVel.x = RotVel.x;
//TempCode ARM 15Jul97 		OldRotVel.y = RotVel.y;
//TempCode ARM 15Jul97 		OldRotVel.z = RotVel.z;
//TempCode ARM 15Jul97 
//TempCode ARM 15Jul97 		RotVel.x += ((OldRotAcc.x + RotAcc.x) * MODEL_DT) * 0.5;
//TempCode ARM 15Jul97 		RotVel.y += ((OldRotAcc.y + RotAcc.y) * MODEL_DT) * 0.5;
//TempCode ARM 15Jul97 		RotVel.z += ((OldRotAcc.z + RotAcc.z) * MODEL_DT) * 0.5;
//TempCode ARM 15Jul97 
//TempCode ARM 15Jul97 		RotVelInt ();
//TempCode ARM 15Jul97 	}

//	UpdateAirStruc ();

//	Ground ();

//	Instruments (ControlledAC);

}
Пример #3
0
//컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴컴
//Procedure		ProcessPistonEngine
//Author		Craig Beeston
//Date			Tue 11 Aug 98
//
//Description	Processes a piston engine
//					Calculates Thrust, Torque, Engine power and Engine speed
//
//Inputs		
//
//Returns	
//
//------------------------------------------------------------------------------
void Engine::ProcessPistonEngine (AirStrucPtr const ControlledAC)
{
	AircraftAnimData* adptr = (AircraftAnimData *)ControlledAC->Anim;
	SWord iDamage = 255 - (255 - UWord(adptr->ENGINELEFT)) * (255 - UWord(adptr->FRONT)) / 255;
	if(pThrustPoint->Pos.x > 0)
		iDamage = adptr->ENGINERIGHT;
	
	FP MaxSpeed = 2 * Rpm100 * 0.001047197;	//RPM 2 Rads/cs
	if(iDamage == 254)
		MaxSpeed = 0;
	FP fDamage = 1.0 - FP(iDamage) * (1.0 / 255.0);
		
//DEADCODE CB 04/11/99 	FP MinSpeed =     Rpm0   * 0.001047197;	//RPM 2 Rads/cs

//DEADCODE CB 04/11/99 	if (Speed < MinSpeed) Speed = MinSpeed;	
	if (Speed > MaxSpeed) Speed = MaxSpeed;	

	FP EngRPM    = Speed * 954.9296586;
	FP PropSpeed = Speed * GearRatio;
	FP PropSwirl = SlipRot * 0.5;

	const FP BladeFract = 0.60;

	FCRD Vel;
	CPrd(Vel, pThrustPoint->Pos, pModel->RotVel);
	Vel.z -= pModel->AirVel.z;				//Velocity of air ahead of prop
	
	FP PropAirVel = BladeFract * (PropSpeed - PropSwirl) * BladeRadius;
	FP InflowAng = CalcAngle (PropAirVel, PropVel);

//Automatic prop control for AI aircraft
	if((!Save_Data.flightdifficulty [FD_PROPPITCH]) || (ControlledAC != Persons2::PlayerSeenAC))
	{
		switch(PropType)
		{
			case PT_FIXED:
				break;

			case PT_2PITCH:
				if(EngRPM > 1.15 * Rpm100)
					PropSetting = 0;
				if(EngRPM < 0.7 * Rpm100)
					PropSetting = 1;
				break;

			case PT_VARIABLE:
				PropSetting = 1.0 - 1.15 * ControlledAC->vel_ / ControlledAC->classtype->maxvel;
				MODMAXMIN(PropSetting, 0.01, 1);
				break;

			case PT_CONSTSPEED:
				if(ThrottleSetting <= 75)
					PropSetting = 0;
				else
					PropSetting = (ThrottleSetting - 75.0) / 25.0;
//DEADCODE CSB 31/01/00 				PropSetting = FP(ThrottleSetting) * 0.01;
//DEADCODE CSB 31/01/00 				PropSetting = PropSetting * PropSetting * PropSetting;
				break;
		}
	}

	switch(PropType)
	{
		case PT_FIXED:
		{
			PropInc = PropMaxPitch;
			break;
		}
		case PT_2PITCH:
		{
			FP DesiredInc = PropMaxPitch;
			if(PropSetting > 0.5)
				DesiredInc = PropMinPitch;
			if(DesiredInc > PropInc)
			{
				PropInc += 0.002 * MODEL_ENGINE_DT;					//AMM 24Nov99
				if(PropInc > DesiredInc) PropInc = DesiredInc;
			}
			if(DesiredInc < PropInc)
			{
				PropInc -= 0.002 * MODEL_ENGINE_DT;					//AMM 24Nov99
				if(PropInc < DesiredInc) PropInc = DesiredInc;
			}
			break;
		}
		case PT_VARIABLE:
		{
			FP DesiredInc = PropMaxPitch;
			if(PropSetting > 0)
			{
				FP Ratio = 0.5 * (PropSetting + 1.0);
				DesiredInc = PropMinPitch * Ratio + PropMaxPitch * (1 - Ratio);
			}

			if(DesiredInc > PropInc)
			{
				PropInc += 0.002 * MODEL_ENGINE_DT;					//AMM 24Nov99
				if(PropInc > DesiredInc) PropInc = DesiredInc;
			}
			if(DesiredInc < PropInc)
			{
				PropInc -= 0.002 * MODEL_ENGINE_DT;					//AMM 24Nov99
				if(PropInc < DesiredInc) PropInc = DesiredInc;
			}
			break;
		}
		case PT_CONSTSPEED:
		{
			FP DesiredRpm = Rpm100 * (0.7 + 0.45 * PropSetting);
			FP PropPitchRate = (EngRPM - DesiredRpm) * 0.00001;
			PropInc += PropPitchRate * MODEL_ENGINE_DT;				//AMM 24Nov99
			break;
		}
	}	

	MODMAXMIN(PropInc, PropMinPitch, PropMaxPitch);

	FP BladeSpeed = FSqrt(PropAirVel * PropAirVel + PropVel * PropVel);
	FP BladeQS  =  0.5 * pModel->AmbDensity * BladeSpeed * BladeArea;
	
//DeadCode AMM 29Jun99 	J = PropVel / ((PropSpeed - PropSwirl) * 0.75 * BladeRadius);	//Only Used for Text Screen

	FP BladeL = 4.53 * (PropInc - InflowAng);
	FP BladeD = 0.005 + (0.071 * BladeL * BladeL);	
	MODMAXMIN(BladeL, -1.0, 1.5);

	BladeL *= BladeQS;
	BladeD *= BladeQS;

	Thrust = BladeL * PropAirVel - BladeD * PropVel;
	Torque = BladeD * PropAirVel + BladeL * PropVel;
	Torque *= BladeRadius * 0.5;	//effective overall moment


//Engine Power Output
	Power100 = pPower100->GetValue (EngRPM / Rpm100);
	Power0   = pPower0->GetValue (EngRPM / Rpm100);

	FP fPower  = 0;
	FP dTorque = 0;

	ComplexEngineProcess(ControlledAC, fDamage, fPower, dTorque);

	const FP MinThrottle = 0.125;
	FP PowerFract = MinThrottle + ThrottleSetting * (1 - MinThrottle) * 0.01;

	PowerFract *= fPower;

	FP oldpower = Power;
	Power = Power0 + ((Power100 - Power0) * PowerFract);
	
	if((oldpower <= 0) && (Power > 0))
		Trans_Obj.LaunchEngineStartup((mobileitem*)ControlledAC, *ControlledAC->currworld);

	if((oldpower > 0) && (Power <= 0) && (ControlledAC == Persons2::PlayerSeenAC))
		_Miles.PlayOnce(FIL_SFX_ENGINE_COUGH,Save_Data.vol.engine);		//RJS 27Sep00

	Power *= pPowerAlt->GetValue(pModel->Pos.y * 0.01);
	Power *= p0;


//#define ENGINE_DATA
#ifdef ENGINE_DATA
//DeadCode CSB 27/10/99	/* TEST CODE CSB 27/10/99 */if(pModel->bACM)
/* TEST CODE CSB 27/10/99 */{
//DEADCODE CSB 11/01/00 /* TEST CODE CSB 29/09/99 */	PrintVar(40, 15, "Gravity  %.3f ", FP(pModel->Inst.I_NormalAcc));
//DEADCODE CSB 11/01/00 /* TEST CODE CSB 29/09/99 */	PrintVar(40, 16, "IAS      %.2f ", FP(pModel->Speed * FSqrt (pModel->AmbDensity / 0.0001225)));
//DEADCODE CSB 11/01/00 /* TEST CODE CSB 29/09/99 */	PrintVar(40, 17, "Vel      %.2f ", FP(ControlledAC->vel_ * 0.0001));
//DEADCODE CSB 11/01/00 /* TEST CODE CSB 29/09/99 */	PrintVar(40, 18, "DesRpm   %.2f ", FP(pModel->ModelPropSetting));
/* TEST CODE CSB 29/09/99 */	PrintVar(20, 15, "Power    %.0f ", FP(Power / 745.7));
/* TEST CODE CSB 29/09/99 */	PrintVar(20, 16, "RPM      %.0f ", FP(EngRPM));
/* TEST CODE CSB 29/09/99 */	PrintVar(20, 17, "Prop Inc %.2f ", FP(Rads2Degs(PropInc)));
/* TEST CODE CSB 29/09/99 */	PrintVar(20, 18, "Vel      %.2f ", FP(-pModel->AirVel.z));
/* TEST CODE CSB 29/09/99 */	PrintVar(20, 19, "PropVel  %.2f ", FP(PropVel));
/* TEST CODE CSB 29/09/99 */	PrintVar(20, 20, "SlipVel  %.2f ", FP(SlipVel));
/* TEST CODE CSB 29/09/99 */	PrintVar(20, 21, "Alpha    %.2f ", FP(Rads2Degs(PropInc - InflowAng)));
/* TEST CODE CSB 29/09/99 */	PrintVar(20, 24, "ROC fpm  %.0f ", FP(pModel->Vel.y * 3.2808 * 60.0));
/* TEST CODE CSB 29/09/99 */	PrintVar(20, 22, "Thrust   %.1f ", FP(Thrust));
/* TEST CODE CSB 29/09/99 */	PrintVar(20, 23, "Eff      %.3f ", FP(Thrust * -pModel->AirVel.z / Power));
/* TEST CODE CSB 27/10/99 */}
#endif


	FP EngTorque = 0;
	if(Speed > 0) 
		EngTorque = Power / Speed;
	
	EngTorque += dTorque;

//Slipstream Conditions
	FP OldSlipRot = SlipRot;
	FP SlipInertia = BladeRadius * BladeRadius * BladeRadius * BladeRadius 
		              * 0.5 * FPIE * PropVel * pModel->AmbDensity;
	if(SlipInertia > 0)
		SlipRot	   = (Torque / SlipInertia + OldSlipRot) * 0.5;
	else
		SlipRot = 0;
	if(SlipRot > PropSpeed) SlipRot = PropSpeed;

	FP OldSlipVel = SlipVel;
	FP PropArea = FPIE * BladeRadius * BladeRadius;
	FP TempSlip = 2 * Thrust / (pModel->AmbDensity * PropArea) + Vel.z * Vel.z;
	if (TempSlip < 0) SlipVel = -Vel.z;
	else 
		SlipVel = sqrt(TempSlip);
	SlipVel = (SlipVel + OldSlipVel) * 0.5;
	PropVel = 0.5 * (0.5 * (Vel.z + SlipVel) + PropVel);

// calc engine speed
	FP EngRotAcc = (EngTorque - Torque * GearRatio) / MoI;

//DeadCode CSB 27/10/99		if (!Save_Data.flightdifficulty [FD_THRUSTPOWERCONTROL])
//DeadCode CSB 27/10/99			EngRotAcc *= 2;												//Fast Spooling

//DEADCODE AMM 24/11/99 	Speed += pModel->MODEL_DT * EngRotAcc;
	Speed += MODEL_ENGINE_DT * EngRotAcc; //AMM 24/11/99


	if(Speed < 0) Speed = 0;
	
//DEADCODE CB 04/11/99 	if (Speed < MinSpeed) Speed = MinSpeed;		
	if (Speed > MaxSpeed) Speed = MaxSpeed;		
				

	Torque	= -Torque * RotateDirection;//(EngTorque - Torque / GearRatio);				//Reacted into Airframe

	if (Save_Data.flightdifficulty [FD_SLIPSTREAMEFFECTS])
	{
		FCRD TempRot;
		CopyVec(pModel->RotVel, TempRot);
		TempRot.z += Speed * RotateDirection;

		moment.x = TempRot.x * PropInertia.x;
		moment.y = TempRot.y * PropInertia.y;
		moment.z = TempRot.z * PropInertia.z;
		
		CPrd(moment, moment, TempRot);
		moment.x *= -1;
		moment.y *= -1;
		moment.z *= -1;
	}
	else 
		NullVec(moment);
}