/*************************************************************************** TITLE: c172_aero ---------------------------------------------------------------------------- FUNCTION: aerodynamics model based on constant stability derivatives ---------------------------------------------------------------------------- MODULE STATUS: developmental ---------------------------------------------------------------------------- GENEALOGY: Based on data from: Part 1 of Roskam's S&C text The FAA type certificate data sheet for the 172 Various sources on the net John D. Anderson's Intro to Flight text (NACA 2412 data) UIUC's airfoil data web site ---------------------------------------------------------------------------- DESIGNED BY: Tony Peden CODED BY: Tony Peden MAINTAINED BY: Tony Peden ---------------------------------------------------------------------------- MODIFICATION HISTORY: DATE PURPOSE BY 6/10/99 Initial test release ---------------------------------------------------------------------------- REFERENCES: Aero Coeffs: CL lift Cd drag Cm pitching moment Cy sideforce Cn yawing moment Croll,Cl rolling moment (yeah, I know. Shoot me.) Subscripts o constant i.e. not a function of alpha or beta a alpha adot d(alpha)/dt q pitch rate qdot d(q)/dt beta sideslip angle p roll rate r yaw rate da aileron deflection de elevator deflection dr rudder deflection s stability axes ---------------------------------------------------------------------------- CALLED BY: ---------------------------------------------------------------------------- CALLS TO: ---------------------------------------------------------------------------- INPUTS: ---------------------------------------------------------------------------- OUTPUTS: --------------------------------------------------------------------------*/ #include "ls_generic.h" #include "ls_cockpit.h" #include "ls_constants.h" #include "ls_types.h" #include #include #define NCL 11 #define DYN_ON_SPEED 33 /*20 knots*/ #ifdef USENZ #define NZ generic_.n_cg_body_v[2] #else #define NZ 1 #endif extern COCKPIT cockpit_; SCALAR interp(SCALAR *y_table, SCALAR *x_table, int Ntable, SCALAR x) { SCALAR slope; int i=1; float y; /* if x is outside the table, return value at x[0] or x[Ntable-1]*/ if(x <= x_table[0]) { y=y_table[0]; /* printf("x smaller than x_table[0]: %g %g\n",x,x_table[0]); */ } else if(x >= x_table[Ntable-1]) { y=y_table[Ntable-1]; /* printf("x larger than x_table[N]: %g %g %d\n",x,x_table[NCL-1],Ntable-1); */ } else /*x is within the table, interpolate linearly to find y value*/ { while(x_table[i] <= x) {i++;} slope=(y_table[i]-y_table[i-1])/(x_table[i]-x_table[i-1]); /* printf("x: %g, i: %d, cl[i]: %g, cl[i-1]: %g, slope: %g\n",x,i,y_table[i],y_table[i-1],slope); */ y=slope*(x-x_table[i-1]) +y_table[i-1]; } return y; } void aero( SCALAR dt, int Initialize ) { static int init = 0; static SCALAR trim_inc = 0.0002; SCALAR long_trim; SCALAR elevator, aileron, rudder; static SCALAR alpha_ind[NCL]={-0.087,0,0.175,0.209,0.24,0.262,0.278,0.303,0.314,0.332,0.367}; static SCALAR CLtable[NCL]={-0.14,0.31,1.21,1.376,1.51249,1.591,1.63,1.60878,1.53712,1.376,1.142}; /*Note that CLo,Cdo,Cmo will likely change with flap setting so they may not be declared static in the future */ static SCALAR CLadot=1.7; static SCALAR CLq=3.9; static SCALAR CLde=0.43; static SCALAR CLo=0; static SCALAR Cdo=0.031; static SCALAR Cda=0.13; /*Not used*/ static SCALAR Cdde=0.06; static SCALAR Cma=-0.89; static SCALAR Cmadot=-5.2; static SCALAR Cmq=-12.4; static SCALAR Cmo=-0.062; static SCALAR Cmde=-1.28; static SCALAR Clbeta=-0.089; static SCALAR Clp=-0.47; static SCALAR Clr=0.096; static SCALAR Clda=-0.178; static SCALAR Cldr=0.0147; static SCALAR Cnbeta=0.065; static SCALAR Cnp=-0.03; static SCALAR Cnr=-0.099; static SCALAR Cnda=-0.053; static SCALAR Cndr=-0.0657; static SCALAR Cybeta=-0.31; static SCALAR Cyp=-0.037; static SCALAR Cyr=0.21; static SCALAR Cyda=0.0; static SCALAR Cydr=0.187; /*nondimensionalization quantities*/ /*units here are ft and lbs */ static SCALAR cbar=4.9; /*mean aero chord ft*/ static SCALAR b=35.8; /*wing span ft */ static SCALAR Sw=174; /*wing planform surface area ft^2*/ static SCALAR rPiARe=0.054; /*reciprocal of Pi*AR*e*/ SCALAR W=Mass/INVG; SCALAR CLwbh,CL,cm,cd,cn,cy,croll,cbar_2V,b_2V,qS,qScbar,qSb,ps,rs; SCALAR F_X_wind,F_Y_wind,F_Z_wind,W_X,W_Y,W_Z; if (Initialize != 0) { } /* LaRCsim uses: Cm > 0 => ANU Cl > 0 => Right wing down Cn > 0 => ANL so: elevator > 0 => AND -- aircraft nose down aileron > 0 => right wing up rudder > 0 => ANL */ if(Aft_trim) long_trim = long_trim - trim_inc; if(Fwd_trim) long_trim = long_trim + trim_inc; /*scale pct control to degrees deflection*/ if ((Long_control+long_trim) <= 0) elevator=(Long_control+long_trim)*28*DEG_TO_RAD; else elevator=(Long_control+long_trim)*23*DEG_TO_RAD; aileron = Lat_control*17.5*DEG_TO_RAD; rudder = Rudder_pedal*16*DEG_TO_RAD; /* The aileron travel limits are 20 deg. TEU and 15 deg TED but since we don't distinguish between left and right we'll use the average here (17.5 deg) */ /*calculate rate derivative nondimensionalization (is that a word?) factors */ /*hack to avoid divide by zero*/ /*the dynamic terms might be negligible at low ground speeds anyway*/ if(V_rel_wind > DYN_ON_SPEED) { cbar_2V=cbar/(2*V_rel_wind); b_2V=b/(2*V_rel_wind); } else { cbar_2V=0; b_2V=0; } /*calcuate the qS nondimensionalization factors*/ qS=Dynamic_pressure*Sw; qScbar=qS*cbar; qSb=qS*b; /*transform the aircraft rotation rates*/ ps=-P_body*Cos_alpha + R_body*Sin_alpha; rs=-P_body*Sin_alpha + R_body*Cos_alpha; /* printf("Wb: %7.4f, Ub: %7.4f, Alpha: %7.4f, elev: %7.4f, ail: %7.4f, rud: %7.4f\n",W_body,U_body,Alpha*RAD_TO_DEG,elevator*RAD_TO_DEG,aileron*RAD_TO_DEG,rudder*RAD_TO_DEG); printf("Theta: %7.4f, Gamma: %7.4f, Beta: %7.4f, Phi: %7.4f, Psi: %7.4f\n",Theta*RAD_TO_DEG,Gamma_vert_rad*RAD_TO_DEG,Beta*RAD_TO_DEG,Phi*RAD_TO_DEG,Psi*RAD_TO_DEG); */ /* sum coefficients */ CLwbh = interp(CLtable,alpha_ind,NCL,Alpha); CL = CLo + CLwbh + (CLadot*Alpha_dot + CLq*Theta_dot)*cbar_2V + CLde*elevator; cd = Cdo + rPiARe*CL*CL + Cdde*elevator; cy = Cybeta*Beta + (Cyp*ps + Cyr*rs)*b_2V + Cyda*aileron + Cydr*rudder; cm = Cmo + Cma*Alpha + (Cmq*Theta_dot + Cmadot*Alpha_dot)*cbar_2V + Cmde*(elevator+long_trim); cn = Cnbeta*Beta + (Cnp*ps + Cnr*rs)*b_2V + Cnda*aileron + Cndr*rudder; croll=Clbeta*Beta + (Clp*ps + Clr*rs)*b_2V + Clda*aileron + Cldr*rudder; /* printf("CL: %7.4f, Cd: %7.4f, Cm: %7.4f, Cy: %7.4f, Cn: %7.4f, Cl: %7.4f\n",CL,cd,cm,cy,cn,croll); */ /*calculate wind axes forces*/ F_X_wind=-1*cd*qS; F_Y_wind=cy*qS; F_Z_wind=-1*CL*qS; /* printf("V_rel_wind: %7.4f, Fxwind: %7.4f Fywind: %7.4f Fzwind: %7.4f\n",V_rel_wind,F_X_wind,F_Y_wind,F_Z_wind); */ /*calculate moments and body axis forces */ /*find body-axis components of weight*/ /*with earth axis to body axis transform */ W_X=-1*W*Sin_theta; W_Y=W*Sin_phi*Cos_theta; W_Z=W*Cos_phi*Cos_theta; /* requires ugly wind-axes to body-axes transform */ F_X_aero = W_X + F_X_wind*Cos_alpha*Cos_beta - F_Y_wind*Cos_alpha*Sin_beta - F_Z_wind*Sin_alpha; F_Y_aero = W_Y + F_X_wind*Sin_beta + F_Y_wind*Cos_beta; F_Z_aero = W_Z*NZ + F_X_wind*Sin_alpha*Cos_beta - F_Y_wind*Sin_alpha*Sin_beta + F_Z_wind*Cos_alpha; /*no axes transform here */ M_l_aero = croll*qSb; M_m_aero = cm*qScbar; M_n_aero = cn*qSb; /* printf("I_yy: %7.4f, qScbar: %7.4f, qbar: %7.4f, Sw: %7.4f, cbar: %7.4f, 0.5*rho*V^2: %7.4f\n",I_yy,qScbar,Dynamic_pressure,Sw,cbar,0.5*0.0023081*V_rel_wind*V_rel_wind); printf("Fxbody: %7.4f Fybody: %7.4f Fzbody: %7.4f Weight: %7.4f\n",F_X_wind,F_Y_wind,F_Z_wind,W); printf("Maero: %7.4f Naero: %7.4f Raero: %7.4f\n",M_m_aero,M_n_aero,M_l_aero); */ }