Updates from JSBSim, including new turbine engine model from David Culp

[flightgear.git] / src / FDM / JSBSim / FGAuxiliary.cpp

/*%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
 
 Module:       FGAuxiliary.cpp
 Author:       Tony Peden, Jon Berndt
 Date started: 01/26/99
 Purpose:      Calculates additional parameters needed by the visual system, etc.
 Called by:    FGSimExec
 
 ------------- Copyright (C) 1999  Jon S. Berndt (jsb@hal-pc.org) -------------
 
 This program is free software; you can redistribute it and/or modify it under
 the terms of the GNU General Public License as published by the Free Software
 Foundation; either version 2 of the License, or (at your option) any later
 version.
 
 This program is distributed in the hope that it will be useful, but WITHOUT
 ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
 FOR A PARTICULAR PURPOSE.  See the GNU General Public License for more
 details.

 You should have received a copy of the GNU General Public License along with
 this program; if not, write to the Free Software Foundation, Inc., 59 Temple
 Place - Suite 330, Boston, MA  02111-1307, USA.

 Further information about the GNU General Public License can also be found on
 the world wide web at http://www.gnu.org.

FUNCTIONAL DESCRIPTION
--------------------------------------------------------------------------------
This class calculates various auxiliary parameters.

REFERENCES
  Anderson, John D. "Introduction to Flight", 3rd Edition, McGraw-Hill, 1989
                    pgs. 112-126
HISTORY
--------------------------------------------------------------------------------
01/26/99   JSB   Created

%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
INCLUDES
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%*/

#include "FGAuxiliary.h"
#include "FGAerodynamics.h"
#include "FGTranslation.h"
#include "FGRotation.h"
#include "FGAtmosphere.h"
#include "FGState.h"
#include "FGFDMExec.h"
#include "FGFCS.h"
#include "FGAircraft.h"
#include "FGPosition.h"
#include "FGOutput.h"
#include "FGInertial.h"
#include "FGMatrix33.h"
#include "FGColumnVector3.h"
#include "FGColumnVector4.h"
#include "FGPropertyManager.h"

namespace JSBSim {

static const char *IdSrc = "$Id$";
static const char *IdHdr = ID_AUXILIARY;

/*%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
CLASS IMPLEMENTATION
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%*/


FGAuxiliary::FGAuxiliary(FGFDMExec* fdmex) : FGModel(fdmex)
{
  Name = "FGAuxiliary";
  vcas = veas = mach = qbar = pt = 0;
  psl = rhosl = 1;
  earthPosAngle = 0.0;
  
  vPilotAccelN.InitMatrix();
  
  bind();
  
  Debug(0);
}

//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

FGAuxiliary::~FGAuxiliary()
{
  unbind();
  Debug(1);
}

//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

bool FGAuxiliary::Run()
{
  double A,B,D;

  if (!FGModel::Run()) {
    GetState();
    
    //caculate total temperature assuming isentropic flow
    tat=sat*(1 + 0.2*mach*mach);
    
    if (mach < 1) {   //calculate total pressure assuming isentropic flow
      pt=p*pow((1 + 0.2*mach*mach),3.5);
    } else {
      // shock in front of pitot tube, we'll assume its normal and use
      // the Rayleigh Pitot Tube Formula, i.e. the ratio of total
      // pressure behind the shock to the static pressure in front

      B = 5.76*mach*mach/(5.6*mach*mach - 0.8);

      // The denominator above is zero for Mach ~ 0.38, for which
      // we'll never be here, so we're safe

      D = (2.8*mach*mach-0.4)*0.4167;
      pt = p*pow(B,3.5)*D;
    }

    A = pow(((pt-p)/psl+1),0.28571);
    vcas = sqrt(7*psl/rhosl*(A-1));
    veas = sqrt(2*qbar/rhosl);

    // Pilot sensed accelerations are calculated here. This is used
    // for the coordinated turn ball instrument. Motion base platforms sometimes
    // use the derivative of pilot sensed accelerations as the driving parameter,
    // rather than straight accelerations.
    //
    // The theory behind pilot-sensed calculations is presented:
    //
    // For purposes of discussion and calculation, assume for a minute that the
    // pilot is in space and motionless in inertial space. She will feel
    // no accelerations. If the aircraft begins to accelerate along any axis or
    // axes (without rotating), the pilot will sense those accelerations. If
    // any rotational moment is applied, the pilot will sense an acceleration
    // due to that motion in the amount:
    //
    // [wdot X R]  +  [w X (w X R)]
    //   Term I          Term II
    //
    // where:
    //
    // wdot = omegadot, the rotational acceleration rate vector
    // w    = omega, the rotational rate vector
    // R    = the vector from the aircraft CG to the pilot eyepoint
    //
    // The sum total of these two terms plus the acceleration of the aircraft
    // body axis gives the acceleration the pilot senses in inertial space.
    // In the presence of a large body such as a planet, a gravity field also
    // provides an accelerating attraction. This acceleration can be transformed
    // from the reference frame of the planet so as to be expressed in the frame
    // of reference of the aircraft. This gravity field accelerating attraction
    // is felt by the pilot as a force on her tushie as she sits in her aircraft
    // on the runway awaiting takeoff clearance.
    //
    // In JSBSim the acceleration of the body frame in inertial space is given
    // by the F = ma relation. If the vForces vector is divided by the aircraft
    // mass, the acceleration vector is calculated. The term wdot is equivalent
    // to the JSBSim vPQRdot vector, and the w parameter is equivalent to vPQR.
    // The radius R is calculated below in the vector vToEyePt.
    
    vPilotAccel.InitMatrix();   
    if ( Translation->GetVt() > 1 ) {
       vPilotAccel =  Aerodynamics->GetForces() 
                  +  Propulsion->GetForces()
                  +  GroundReactions->GetForces();
       vPilotAccel /= MassBalance->GetMass();
       vToEyePt = Aircraft->GetXYZep() - MassBalance->GetXYZcg();
       vToEyePt *= inchtoft;
       vPilotAccel += Rotation->GetPQRdot() * vToEyePt;
       vPilotAccel += Rotation->GetPQR() * (Rotation->GetPQR() * vToEyePt);
    } else {
       vPilotAccel = -1*( State->GetTl2b() * Inertial->GetGravity() );
    }   

    vPilotAccelN = vPilotAccel/Inertial->gravity();
      
    
    earthPosAngle += State->Getdt()*Inertial->omega();
    return false;
  } else {
    return true;
  }
}

//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

double FGAuxiliary::GetHeadWind(void)
{
  double psiw,vw,psi;

  psiw = Atmosphere->GetWindPsi();
  psi = Rotation->Getpsi();
  vw = Atmosphere->GetWindNED().Magnitude();

  return vw*cos(psiw - psi);
}

//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

double FGAuxiliary::GetCrossWind(void)
{
  double psiw,vw,psi;

  psiw = Atmosphere->GetWindPsi();
  psi = Rotation->Getpsi();
  vw = Atmosphere->GetWindNED().Magnitude();

  return  vw*sin(psiw - psi);
}

//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

void FGAuxiliary::bind(void)
{
  typedef double (FGAuxiliary::*PMF)(int) const;
  PropertyManager->Tie("velocities/vc-fps", this,
                       &FGAuxiliary::GetVcalibratedFPS);
  PropertyManager->Tie("velocities/vc-kts", this,
                       &FGAuxiliary::GetVcalibratedKTS);
  PropertyManager->Tie("velocities/ve-fps", this,
                       &FGAuxiliary::GetVequivalentFPS);
  PropertyManager->Tie("velocities/ve-kts", this,
                       &FGAuxiliary::GetVequivalentKTS);
  PropertyManager->Tie("velocities/tat-r", this,
                       &FGAuxiliary::GetTotalTemperature);
  PropertyManager->Tie("velocities/pt-lbs_sqft", this,
                       &FGAuxiliary::GetTotalPressure);
                     
  PropertyManager->Tie("accelerations/a-pilot-x-ft_sec2", this,1,
                       (PMF)&FGAuxiliary::GetPilotAccel);
  PropertyManager->Tie("accelerations/a-pilot-y-ft_sec2", this,2,
                       (PMF)&FGAuxiliary::GetPilotAccel);
  PropertyManager->Tie("accelerations/a-pilot-z-ft_sec2", this,3,
                       (PMF)&FGAuxiliary::GetPilotAccel);
  PropertyManager->Tie("accelerations/n-pilot-x-norm", this,1,
                       (PMF)&FGAuxiliary::GetNpilot);
  PropertyManager->Tie("accelerations/n-pilot-y-norm", this,2,
                       (PMF)&FGAuxiliary::GetNpilot);
  PropertyManager->Tie("accelerations/n-pilot-z-norm", this,3,
                       (PMF)&FGAuxiliary::GetNpilot);
  PropertyManager->Tie("position/epa-rad", this,
                       &FGAuxiliary::GetEarthPositionAngle);
  /* PropertyManager->Tie("atmosphere/headwind-fps", this,
                       &FGAuxiliary::GetHeadWind,
                       true);
  PropertyManager->Tie("atmosphere/crosswind-fps", this,
                       &FGAuxiliary::GetCrossWind,
                       true); */
}

//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

void FGAuxiliary::unbind(void)
{
  PropertyManager->Untie("velocities/vc-fps");
  PropertyManager->Untie("velocities/vc-kts");
  PropertyManager->Untie("velocities/ve-fps");
  PropertyManager->Untie("velocities/ve-kts");
  PropertyManager->Untie("accelerations/a-pilot-x-ft_sec2");
  PropertyManager->Untie("accelerations/a-pilot-y-ft_sec2");
  PropertyManager->Untie("accelerations/a-pilot-z-ft_sec2");
  PropertyManager->Untie("accelerations/n-pilot-x-norm");
  PropertyManager->Untie("accelerations/n-pilot-y-norm");
  PropertyManager->Untie("accelerations/n-pilot-z-norm");
  PropertyManager->Untie("position/epa-rad");
  /* PropertyManager->Untie("atmosphere/headwind-fps");
  PropertyManager->Untie("atmosphere/crosswind-fps"); */

}

//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

void FGAuxiliary::GetState(void)
{
  qbar = Translation->Getqbar();
  mach = Translation->GetMach();
  p = Atmosphere->GetPressure();
  rhosl = Atmosphere->GetDensitySL();
  psl = Atmosphere->GetPressureSL();
  sat = Atmosphere->GetTemperature();
}

//%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
//    The bitmasked value choices are as follows:
//    unset: In this case (the default) JSBSim would only print
//       out the normally expected messages, essentially echoing
//       the config files as they are read. If the environment
//       variable is not set, debug_lvl is set to 1 internally
//    0: This requests JSBSim not to output any messages
//       whatsoever.
//    1: This value explicity requests the normal JSBSim
//       startup messages
//    2: This value asks for a message to be printed out when
//       a class is instantiated
//    4: When this value is set, a message is displayed when a
//       FGModel object executes its Run() method
//    8: When this value is set, various runtime state variables
//       are printed out periodically
//    16: When set various parameters are sanity checked and
//       a message is printed out when they go out of bounds

void FGAuxiliary::Debug(int from)
{
  if (debug_lvl <= 0) return;

  if (debug_lvl & 1) { // Standard console startup message output
    if (from == 0) { // Constructor

    }
  }
  if (debug_lvl & 2 ) { // Instantiation/Destruction notification
    if (from == 0) cout << "Instantiated: FGAuxiliary" << endl;
    if (from == 1) cout << "Destroyed:    FGAuxiliary" << endl;
  }
  if (debug_lvl & 4 ) { // Run() method entry print for FGModel-derived objects
  }
  if (debug_lvl & 8 ) { // Runtime state variables
  }
  if (debug_lvl & 16) { // Sanity checking
  }
  if (debug_lvl & 64) {
    if (from == 0) { // Constructor
      cout << IdSrc << endl;
      cout << IdHdr << endl;
    }
  }
}

} // namespace JSBSim