/******************************************************************************* Header: LaRCsimIC.cxx Author: Tony Peden Date started: 10/9/99 ------------- Copyright (C) 1999 Anthony K. Peden (apeden@earthlink.net) ------------- 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. */ #include #include #include #include "FDM/LaRCsimIC.hxx" #include #include #include #include #include #include SG_USING_STD(cout); SG_USING_STD(endl); LaRCsimIC::LaRCsimIC(void) { vt=vtg=vw=vc=ve=0; mach=0; alpha=beta=gamma=0; theta=phi=psi=0; altitude=runway_altitude=hdot=alt_agl=0; latitude_gd=latitude_gc=longitude=0; u=v=w=0; vnorth=veast=vdown=0; vnorthwind=veastwind=vdownwind=0; lastSpeedSet=lssetvt; lastAltSet=lssetasl; get_atmosphere(); ls_geod_to_geoc( latitude_gd,altitude,&sea_level_radius,&latitude_gc); } LaRCsimIC::~LaRCsimIC(void) {} void LaRCsimIC::get_atmosphere(void) { Altitude=altitude; //set LaRCsim variable ls_atmos(Altitude, &density_ratio, &soundspeed, &T, &p); rho=density_ratio*SEA_LEVEL_DENSITY; } void LaRCsimIC::SetVcalibratedKtsIC( SCALAR tt) { vc=tt*KTS_TO_FPS; lastSpeedSet=lssetvc; vt=sqrt(1/density_ratio*vc*vc); } void LaRCsimIC::SetVtrueFpsIC( SCALAR tt) { vt=tt; lastSpeedSet=lssetvt; } void LaRCsimIC::SetMachIC( SCALAR tt) { mach=tt; vt=mach*soundspeed; lastSpeedSet=lssetmach; } void LaRCsimIC::SetVequivalentKtsIC(SCALAR tt) { ve=tt*KTS_TO_FPS; lastSpeedSet=lssetve; vt=sqrt(SEA_LEVEL_DENSITY/rho)*ve; } void LaRCsimIC::SetClimbRateFpmIC( SCALAR tt) { SetClimbRateFpsIC(tt/60.0); } void LaRCsimIC::SetClimbRateFpsIC( SCALAR tt) { vtg=vt+vw; cout << "vtg: " << vtg << endl; if(vtg > 0.1) { hdot = tt - vdownwind; gamma=asin(hdot/vtg); getTheta(); vdown=-1*hdot; cout << "hdot: " << hdot << endl; cout << "gamma: " << gamma*SGD_RADIANS_TO_DEGREES << endl; cout << "vdown: " << vdown << endl; } } void LaRCsimIC::SetFlightPathAngleRadIC( SCALAR tt) { gamma=tt; getTheta(); vtg=vt+vw; hdot=vtg*sin(tt); cout << "hdot: " << hdot << endl; vdown=-1*hdot; } void LaRCsimIC::SetPitchAngleRadIC(SCALAR tt) { if(alt_agl < (DEFAULT_AGL_ALT + 0.1) || vt < 10 ) theta=DEFAULT_PITCH_ON_GROUND; else theta=tt; getAlpha(); } void LaRCsimIC::SetUVWFpsIC(SCALAR vu, SCALAR vv, SCALAR vw) { u=vu; v=vv; w=vw; vt=sqrt(u*u+v*v+w*w); lastSpeedSet=lssetuvw; } void LaRCsimIC::SetVNEDAirmassFpsIC(SCALAR north, SCALAR east, SCALAR down ) { vnorthwind=north; veastwind=east; vdownwind=down; vw=sqrt(vnorthwind*vnorthwind + veastwind*veastwind + vdownwind*vdownwind); vtg=vt+vw; SetClimbRateFpsIC(-1*(vdown+vdownwind)); } void LaRCsimIC::SetAltitudeFtIC( SCALAR tt) { if(tt > (runway_altitude + DEFAULT_AGL_ALT)) { altitude=tt; } else { altitude=runway_altitude + DEFAULT_AGL_ALT; alt_agl=DEFAULT_AGL_ALT; theta=DEFAULT_PITCH_ON_GROUND; } lastAltSet=lssetasl; get_atmosphere(); //lets try to make sure the user gets what they intended switch(lastSpeedSet) { case lssetned: calcVtfromNED(); break; case lssetuvw: case lssetvt: SetVtrueFpsIC(vt); break; case lssetvc: SetVcalibratedKtsIC(vc*V_TO_KNOTS); break; case lssetve: SetVequivalentKtsIC(ve*V_TO_KNOTS); break; case lssetmach: SetMachIC(mach); break; } } void LaRCsimIC::SetAltitudeAGLFtIC( SCALAR tt) { alt_agl=tt; lastAltSet=lssetagl; altitude=runway_altitude + alt_agl; } void LaRCsimIC::SetRunwayAltitudeFtIC( SCALAR tt) { runway_altitude=tt; if(lastAltSet == lssetagl) altitude = runway_altitude + alt_agl; } void LaRCsimIC::calcVtfromNED(void) { //take the earth's rotation out of veast first //float veastner = veast- OMEGA_EARTH*sea_level_radius*cos( latitude_gd ); float veastner=veast; u = (vnorth - vnorthwind)*cos(theta)*cos(psi) + (veastner - veastwind)*cos(theta)*sin(psi) - (vdown - vdownwind)*sin(theta); v = (vnorth - vnorthwind)*(sin(phi)*sin(theta)*cos(psi) - cos(phi)*sin(psi)) + (veastner - veastwind)*(sin(phi)*sin(theta)*sin(psi) + cos(phi)*cos(psi)) + (vdown - vdownwind)*sin(phi)*cos(theta); w = (vnorth - vnorthwind)*(cos(phi)*sin(theta)*cos(psi) + sin(phi)*sin(psi)) + (veastner - veastwind)*(cos(phi)*sin(theta)*sin(psi) - sin(phi)*cos(psi)) + (vdown - vdownwind)*cos(phi)*cos(theta); vt = sqrt(u*u + v*v + w*w); } void LaRCsimIC::calcNEDfromVt(void) { float veastner; //get the body components of vt u = GetUBodyFpsIC(); v = GetVBodyFpsIC(); w = GetWBodyFpsIC(); //transform them to local axes and add on the wind components vnorth = u*cos(theta)*cos(psi) + v*(sin(phi)*sin(theta)*cos(psi) - cos(phi)*sin(psi)) + w*(cos(phi)*sin(theta)*cos(psi) + sin(phi)*sin(psi)) + vnorthwind; //need to account for the earth's rotation here veastner = u*cos(theta)*sin(psi) + v*(sin(phi)*sin(theta)*sin(psi) + cos(phi)*cos(psi)) + w*(cos(phi)*sin(theta)*sin(psi) - sin(phi)*cos(psi)) + veastwind; veast = veastner; //veast = veastner + OMEGA_EARTH*sea_level_radius*cos( latitude_gd ); vdown = u*sin(theta) + v*sin(phi)*cos(theta) + w*cos(phi)*cos(theta) + vdownwind; } void LaRCsimIC::SetVNEDFpsIC( SCALAR north, SCALAR east, SCALAR down) { vnorth=north; veast=east; vdown=down; SetClimbRateFpsIC(-1*vdown); lastSpeedSet=lssetned; calcVtfromNED(); } void LaRCsimIC::SetLatitudeGDRadIC(SCALAR tt) { latitude_gd=tt; ls_geod_to_geoc(latitude_gd,altitude,&sea_level_radius, &latitude_gc); } bool LaRCsimIC::getAlpha(void) { bool result=false; float guess=theta-gamma; xlo=xhi=0; xmin=-89; xmax=89; sfunc=&LaRCsimIC::GammaEqOfAlpha; if(findInterval(0,guess)){ if(solve(&alpha,0)){ result=true; } } return result; } bool LaRCsimIC::getTheta(void) { bool result=false; float guess=alpha+gamma; xlo=xhi=0; xmin=-89;xmax=89; sfunc=&LaRCsimIC::GammaEqOfTheta; if(findInterval(0,guess)){ if(solve(&theta,0)){ result=true; } } return result; } SCALAR LaRCsimIC::GammaEqOfTheta( SCALAR theta_arg) { SCALAR a,b,c; a=cos(alpha)*cos(beta)*sin(theta_arg); b=sin(beta)*sin(phi); c=sin(alpha)*cos(beta)*cos(phi); return sin(gamma)-a+(b+c)*cos(theta_arg); } SCALAR LaRCsimIC::GammaEqOfAlpha( SCALAR alpha_arg) { float a,b,c; a=cos(alpha_arg)*cos(beta)*sin(theta); b=sin(beta)*sin(phi); c=sin(alpha_arg)*cos(beta)*cos(phi); return sin(gamma)-a+(b+c)*cos(theta); } bool LaRCsimIC::findInterval( SCALAR x,SCALAR guess) { //void find_interval(inter_params &ip,eqfunc f,float y,float constant, int &flag){ int i=0; bool found=false; float flo,fhi,fguess; float lo,hi,step; step=0.1; fguess=(this->*sfunc)(guess)-x; lo=hi=guess; do { step=2*step; lo-=step; hi+=step; if(lo < xmin) lo=xmin; if(hi > xmax) hi=xmax; i++; flo=(this->*sfunc)(lo)-x; fhi=(this->*sfunc)(hi)-x; if(flo*fhi <=0) { //found interval with root found=true; if(flo*fguess <= 0) { //narrow interval down a bit hi=lo+step; //to pass solver interval that is as //small as possible } else if(fhi*fguess <= 0) { lo=hi-step; } } //cout << "findInterval: i=" << i << " Lo= " << lo << " Hi= " << hi << endl; } while((found == 0) && (i <= 100)); xlo=lo; xhi=hi; return found; } bool LaRCsimIC::solve( SCALAR *y,SCALAR x) { float x1,x2,x3,f1,f2,f3,d,d0; float eps=1E-5; float const relax =0.9; int i; bool success=false; //initializations d=1; x1=xlo;x3=xhi; f1=(this->*sfunc)(x1)-x; f3=(this->*sfunc)(x3)-x; d0=fabs(x3-x1); //iterations i=0; while ((fabs(d) > eps) && (i < 100)) { d=(x3-x1)/d0; x2=x1-d*d0*f1/(f3-f1); f2=(this->*sfunc)(x2)-x; //cout << "solve x1,x2,x3: " << x1 << "," << x2 << "," << x3 << endl; //cout << " " << f1 << "," << f2 << "," << f3 << endl; if(fabs(f2) <= 0.001) { x1=x3=x2; } else if(f1*f2 <= 0.0) { x3=x2; f3=f2; f1=relax*f1; } else if(f2*f3 <= 0) { x1=x2; f1=f2; f3=relax*f3; } //cout << i << endl; i++; }//end while if(i < 100) { success=true; *y=x2; } //cout << "Success= " << success << " Vcas: " << vcas*V_TO_KNOTS << " Mach: " << x2 << endl; return success; }