-// flight.h -- define shared flight model parameters
+// flight.hxx -- define shared flight model parameters
//
// Written by Curtis Olson, started May 1997.
//
// (Log is kept at end of this file)
-#ifndef _FLIGHT_H
-#define _FLIGHT_H
-
-
-#include <Flight/Slew/slew.hxx>
+#ifndef _FLIGHT_HXX
+#define _FLIGHT_HXX
#ifndef __cplusplus
#endif
-/* Define the various supported flight models (most not yet implemented) */
-#define FG_SLEW 0 /* Slew (in MS terminology) */
-#define FG_LARCSIM 1 /* The only "real" model that is currently
- implemented */
-#define FG_ACM 2
-#define FG_SUPER_SONIC 3
-#define FG_HELICOPTER 4
-#define FG_AUTOGYRO 5
-#define FG_BALLOON 6
-#define FG_PARACHUTE 7
-#define FG_EXTERN_GPS 8 /* Driven via a serially connected GPS */
-#define FG_EXTERN_NET 9 /* Driven externally via the net */
-#define FG_EXTERN_NASA 10 /* Track the space shuttle ? */
+/* Required get_()
+
+ `FGState::get_Longitude ()'
+ `FGState::get_Latitude ()'
+ `FGState::get_Altitude ()'
+ `FGState::get_Phi ()'
+ `FGState::get_Theta ()'
+ `FGState::get_Psi ()'
+ `FGState::get_V_equiv_kts ()'
+
+ `FGState::get_Mass ()'
+ `FGState::get_I_xx ()'
+ `FGState::get_I_yy ()'
+ `FGState::get_I_zz ()'
+ `FGState::get_I_xz ()'
+
+ `FGState::get_V_north ()'
+ `FGState::get_V_east ()'
+ `FGState::get_V_down ()'
+
+ `FGState::get_P_Body ()'
+ `FGState::get_Q_Body ()'
+ `FGState::get_R_Body ()'
+
+ `FGState::get_Gamma_vert_rad ()'
+ `FGState::get_Climb_Rate ()'
+ `FGState::get_Alpha ()'
+ `FGState::get_Beta ()'
+
+ `FGState::get_Runway_altitude ()'
+
+ `FGState::get_Lon_geocentric ()'
+ `FGState::get_Lat_geocentric ()'
+ `FGState::get_Sea_level_radius ()'
+ `FGState::get_Earth_position_angle ()'
+
+ `FGState::get_Latitude_dot()'
+ `FGState::get_Longitude_dot()'
+ `FGState::get_Radius_dot()'
+
+ `FGState::get_Dx_cg ()'
+ `FGState::get_Dy_cg ()'
+ `FGState::get_Dz_cg ()'
+
+ `FGState::get_T_local_to_body_11 ()' ... `FGState::get_T_local_to_body_33 ()'
+
+ `FGState::get_Radius_to_vehicle ()'
+ */
+
+
+#include <Time/timestamp.hxx>
typedef double FG_VECTOR_3[3];
-/* This is based heavily on LaRCsim/ls_generic.h */
-typedef struct {
+
+// This is based heavily on LaRCsim/ls_generic.h
+class FGState {
+
+public:
+
+ // Define the various supported flight models (many not yet implemented)
+ enum {
+ // Slew (in MS terminology)
+ FG_SLEW = 0,
+
+ // The only "real" model that is currently implemented
+ FG_LARCSIM = 1,
+
+ FG_ACM = 2,
+ FG_SUPER_SONIC = 3,
+ FG_HELICOPTER = 4,
+ FG_AUTOGYRO = 5,
+ FG_BALLOON = 6,
+ FG_PARACHUTE = 7,
+
+ // Driven externally via a serial port, net, file, etc.
+ FG_EXTERNAL = 8
+ };
/*================== Mass properties and geometry values ==================*/
- double mass, i_xx, i_yy, i_zz, i_xz; /* Inertias */
-#define FG_Mass f->mass
-#define FG_I_xx f->i_xx
-#define FG_I_yy f->i_yy
-#define FG_I_zz f->i_zz
-#define FG_I_xz f->i_xz
-
- FG_VECTOR_3 d_pilot_rp_body_v; /* Pilot location rel to ref pt */
-#define FG_D_pilot_rp_body_v f->d_pilot_rp_body_v
-#define FG_Dx_pilot f->d_pilot_rp_body_v[0]
-#define FG_Dy_pilot f->d_pilot_rp_body_v[1]
-#define FG_Dz_pilot f->d_pilot_rp_body_v[2]
-
- FG_VECTOR_3 d_cg_rp_body_v; /* CG position w.r.t. ref. point */
-#define FG_D_cg_rp_body_v f->d_cg_rp_body_v
-#define FG_Dx_cg f->d_cg_rp_body_v[0]
-#define FG_Dy_cg f->d_cg_rp_body_v[1]
-#define FG_Dz_cg f->d_cg_rp_body_v[2]
+ // Inertias
+ double mass, i_xx, i_yy, i_zz, i_xz;
+ inline double get_Mass() const { return mass; }
+ inline double get_I_xx() const { return i_xx; }
+ inline double get_I_yy() const { return i_yy; }
+ inline double get_I_zz() const { return i_zz; }
+ inline double get_I_xz() const { return i_xz; }
+ inline void set_Inertias( double m, double xx, double yy,
+ double zz, double xz)
+ {
+ mass = m;
+ i_xx = xx;
+ i_yy = yy;
+ i_zz = zz;
+ i_xz = xz;
+ }
+
+ // Pilot location rel to ref pt
+ FG_VECTOR_3 d_pilot_rp_body_v;
+ // inline double * get_D_pilot_rp_body_v() {
+ // return d_pilot_rp_body_v;
+ // }
+ // inline double get_Dx_pilot() const { return d_pilot_rp_body_v[0]; }
+ // inline double get_Dy_pilot() const { return d_pilot_rp_body_v[1]; }
+ // inline double get_Dz_pilot() const { return d_pilot_rp_body_v[2]; }
+ /* inline void set_Pilot_Location( double dx, double dy, double dz ) {
+ d_pilot_rp_body_v[0] = dx;
+ d_pilot_rp_body_v[1] = dy;
+ d_pilot_rp_body_v[2] = dz;
+ } */
+
+ // CG position w.r.t. ref. point
+ FG_VECTOR_3 d_cg_rp_body_v;
+ // inline double * get_D_cg_rp_body_v() { return d_cg_rp_body_v; }
+ inline double get_Dx_cg() const { return d_cg_rp_body_v[0]; }
+ inline double get_Dy_cg() const { return d_cg_rp_body_v[1]; }
+ inline double get_Dz_cg() const { return d_cg_rp_body_v[2]; }
+ inline void set_CG_Position( double dx, double dy, double dz ) {
+ d_cg_rp_body_v[0] = dx;
+ d_cg_rp_body_v[1] = dy;
+ d_cg_rp_body_v[2] = dz;
+ }
/*================================ Forces =================================*/
- FG_VECTOR_3 f_body_total_v;
-#define FG_F_body_total_v f->f_body_total_v
-#define FG_F_X f->f_body_total_v[0]
-#define FG_F_Y f->f_body_total_v[1]
-#define FG_F_Z f->f_body_total_v[2]
-
- FG_VECTOR_3 f_local_total_v;
-#define FG_F_local_total_v f->f_local_total_v
-#define FG_F_north f->f_local_total_v[0]
-#define FG_F_east f->f_local_total_v[1]
-#define FG_F_down f->f_local_total_v[2]
-
- FG_VECTOR_3 f_aero_v;
-#define FG_F_aero_v f->f_aero_v
-#define FG_F_X_aero f->f_aero_v[0]
-#define FG_F_Y_aero f->f_aero_v[1]
-#define FG_F_Z_aero f->f_aero_v[2]
-
- FG_VECTOR_3 f_engine_v;
-#define FG_F_engine_v f->f_engine_v
-#define FG_F_X_engine f->f_engine_v[0]
-#define FG_F_Y_engine f->f_engine_v[1]
-#define FG_F_Z_engine f->f_engine_v[2]
-
- FG_VECTOR_3 f_gear_v;
-#define FG_F_gear_v f->f_gear_v
-#define FG_F_X_gear f->f_gear_v[0]
-#define FG_F_Y_gear f->f_gear_v[1]
-#define FG_F_Z_gear f->f_gear_v[2]
-
-/*================================ Moments ================================*/
-
- FG_VECTOR_3 m_total_rp_v;
-#define FG_M_total_rp_v f->m_total_rp_v
-#define FG_M_l_rp f->m_total_rp_v[0]
-#define FG_M_m_rp f->m_total_rp_v[1]
-#define FG_M_n_rp f->m_total_rp_v[2]
-
- FG_VECTOR_3 m_total_cg_v;
-#define FG_M_total_cg_v f->m_total_cg_v
-#define FG_M_l_cg f->m_total_cg_v[0]
-#define FG_M_m_cg f->m_total_cg_v[1]
-#define FG_M_n_cg f->m_total_cg_v[2]
-
- FG_VECTOR_3 m_aero_v;
-#define FG_M_aero_v f->m_aero_v
-#define FG_M_l_aero f->m_aero_v[0]
-#define FG_M_m_aero f->m_aero_v[1]
-#define FG_M_n_aero f->m_aero_v[2]
+ FG_VECTOR_3 f_body_total_v;
+ // inline double * get_F_body_total_v() { return f_body_total_v; }
+ // inline double get_F_X() const { return f_body_total_v[0]; }
+ // inline double get_F_Y() const { return f_body_total_v[1]; }
+ // inline double get_F_Z() const { return f_body_total_v[2]; }
+ /* inline void set_Forces_Body_Total( double x, double y, double z ) {
+ f_body_total_v[0] = x;
+ f_body_total_v[1] = y;
+ f_body_total_v[2] = z;
+ } */
+
+ FG_VECTOR_3 f_local_total_v;
+ // inline double * get_F_local_total_v() { return f_local_total_v; }
+ // inline double get_F_north() const { return f_local_total_v[0]; }
+ // inline double get_F_east() const { return f_local_total_v[1]; }
+ // inline double get_F_down() const { return f_local_total_v[2]; }
+ /* inline void set_Forces_Local_Total( double x, double y, double z ) {
+ f_local_total_v[0] = x;
+ f_local_total_v[1] = y;
+ f_local_total_v[2] = z;
+ } */
+
+ FG_VECTOR_3 f_aero_v;
+ // inline double * get_F_aero_v() { return f_aero_v; }
+ // inline double get_F_X_aero() const { return f_aero_v[0]; }
+ // inline double get_F_Y_aero() const { return f_aero_v[1]; }
+ // inline double get_F_Z_aero() const { return f_aero_v[2]; }
+ /* inline void set_Forces_Aero( double x, double y, double z ) {
+ f_aero_v[0] = x;
+ f_aero_v[1] = y;
+ f_aero_v[2] = z;
+ } */
+
+ FG_VECTOR_3 f_engine_v;
+ // inline double * get_F_engine_v() { return f_engine_v; }
+ // inline double get_F_X_engine() const { return f_engine_v[0]; }
+ // inline double get_F_Y_engine() const { return f_engine_v[1]; }
+ // inline double get_F_Z_engine() const { return f_engine_v[2]; }
+ /* inline void set_Forces_Engine( double x, double y, double z ) {
+ f_engine_v[0] = x;
+ f_engine_v[1] = y;
+ f_engine_v[2] = z;
+ } */
+
+ FG_VECTOR_3 f_gear_v;
+ // inline double * get_F_gear_v() { return f_gear_v; }
+ // inline double get_F_X_gear() const { return f_gear_v[0]; }
+ // inline double get_F_Y_gear() const { return f_gear_v[1]; }
+ // inline double get_F_Z_gear() const { return f_gear_v[2]; }
+ /* inline void set_Forces_Gear( double x, double y, double z ) {
+ f_gear_v[0] = x;
+ f_gear_v[1] = y;
+ f_gear_v[2] = z;
+ } */
+
+ /*================================ Moments ================================*/
+
+ FG_VECTOR_3 m_total_rp_v;
+ // inline double * get_M_total_rp_v() { return m_total_rp_v; }
+ // inline double get_M_l_rp() const { return m_total_rp_v[0]; }
+ // inline double get_M_m_rp() const { return m_total_rp_v[1]; }
+ // inline double get_M_n_rp() const { return m_total_rp_v[2]; }
+ /* inline void set_Moments_Total_RP( double l, double m, double n ) {
+ m_total_rp_v[0] = l;
+ m_total_rp_v[1] = m;
+ m_total_rp_v[2] = n;
+ } */
+
+ FG_VECTOR_3 m_total_cg_v;
+ // inline double * get_M_total_cg_v() { return m_total_cg_v; }
+ // inline double get_M_l_cg() const { return m_total_cg_v[0]; }
+ // inline double get_M_m_cg() const { return m_total_cg_v[1]; }
+ // inline double get_M_n_cg() const { return m_total_cg_v[2]; }
+ /* inline void set_Moments_Total_CG( double l, double m, double n ) {
+ m_total_cg_v[0] = l;
+ m_total_cg_v[1] = m;
+ m_total_cg_v[2] = n;
+ } */
+
+ FG_VECTOR_3 m_aero_v;
+ // inline double * get_M_aero_v() { return m_aero_v; }
+ // inline double get_M_l_aero() const { return m_aero_v[0]; }
+ // inline double get_M_m_aero() const { return m_aero_v[1]; }
+ // inline double get_M_n_aero() const { return m_aero_v[2]; }
+ /* inline void set_Moments_Aero( double l, double m, double n ) {
+ m_aero_v[0] = l;
+ m_aero_v[1] = m;
+ m_aero_v[2] = n;
+ } */
FG_VECTOR_3 m_engine_v;
-#define FG_M_engine_v f->m_engine_v
-#define FG_M_l_engine f->m_engine_v[0]
-#define FG_M_m_engine f->m_engine_v[1]
-#define FG_M_n_engine f->m_engine_v[2]
+ // inline double * get_M_engine_v() { return m_engine_v; }
+ // inline double get_M_l_engine() const { return m_engine_v[0]; }
+ // inline double get_M_m_engine() const { return m_engine_v[1]; }
+ // inline double get_M_n_engine() const { return m_engine_v[2]; }
+ /* inline void set_Moments_Engine( double l, double m, double n ) {
+ m_engine_v[0] = l;
+ m_engine_v[1] = m;
+ m_engine_v[2] = n;
+ } */
FG_VECTOR_3 m_gear_v;
-#define FG_M_gear_v f->m_gear_v
-#define FG_M_l_gear f->m_gear_v[0]
-#define FG_M_m_gear f->m_gear_v[1]
-#define FG_M_n_gear f->m_gear_v[2]
-
-/*============================== Accelerations ============================*/
+ // inline double * get_M_gear_v() { return m_gear_v; }
+ // inline double get_M_l_gear() const { return m_gear_v[0]; }
+ // inline double get_M_m_gear() const { return m_gear_v[1]; }
+ // inline double get_M_n_gear() const { return m_gear_v[2]; }
+ /* inline void set_Moments_Gear( double l, double m, double n ) {
+ m_gear_v[0] = l;
+ m_gear_v[1] = m;
+ m_gear_v[2] = n;
+ } */
+
+ /*============================== Accelerations ============================*/
FG_VECTOR_3 v_dot_local_v;
-#define FG_V_dot_local_v f->v_dot_local_v
-#define FG_V_dot_north f->v_dot_local_v[0]
-#define FG_V_dot_east f->v_dot_local_v[1]
-#define FG_V_dot_down f->v_dot_local_v[2]
+ // inline double * get_V_dot_local_v() { return v_dot_local_v; }
+ // inline double get_V_dot_north() const { return v_dot_local_v[0]; }
+ // inline double get_V_dot_east() const { return v_dot_local_v[1]; }
+ // inline double get_V_dot_down() const { return v_dot_local_v[2]; }
+ /* inline void set_Accels_Local( double north, double east, double down ) {
+ v_dot_local_v[0] = north;
+ v_dot_local_v[1] = east;
+ v_dot_local_v[2] = down;
+ } */
FG_VECTOR_3 v_dot_body_v;
-#define FG_V_dot_body_v f->v_dot_body_v
-#define FG_U_dot_body f->v_dot_body_v[0]
-#define FG_V_dot_body f->v_dot_body_v[1]
-#define FG_W_dot_body f->v_dot_body_v[2]
+ // inline double * get_V_dot_body_v() { return v_dot_body_v; }
+ // inline double get_U_dot_body() const { return v_dot_body_v[0]; }
+ // inline double get_V_dot_body() const { return v_dot_body_v[1]; }
+ // inline double get_W_dot_body() const { return v_dot_body_v[2]; }
+ /* inline void set_Accels_Body( double u, double v, double w ) {
+ v_dot_local_v[0] = u;
+ v_dot_local_v[1] = v;
+ v_dot_local_v[2] = w;
+ } */
FG_VECTOR_3 a_cg_body_v;
-#define FG_A_cg_body_v f->a_cg_body_v
-#define FG_A_X_cg f->a_cg_body_v[0]
-#define FG_A_Y_cg f->a_cg_body_v[1]
-#define FG_A_Z_cg f->a_cg_body_v[2]
+ // inline double * get_A_cg_body_v() { return a_cg_body_v; }
+ // inline double get_A_X_cg() const { return a_cg_body_v[0]; }
+ // inline double get_A_Y_cg() const { return a_cg_body_v[1]; }
+ // inline double get_A_Z_cg() const { return a_cg_body_v[2]; }
+ /* inline void set_Accels_CG_Body( double x, double y, double z ) {
+ a_cg_body_v[0] = x;
+ a_cg_body_v[1] = y;
+ a_cg_body_v[2] = z;
+ } */
FG_VECTOR_3 a_pilot_body_v;
-#define FG_A_pilot_body_v f->a_pilot_body_v
-#define FG_A_X_pilot f->a_pilot_body_v[0]
-#define FG_A_Y_pilot f->a_pilot_body_v[1]
-#define FG_A_Z_pilot f->a_pilot_body_v[2]
+ // inline double * get_A_pilot_body_v() { return a_pilot_body_v; }
+ // inline double get_A_X_pilot() const { return a_pilot_body_v[0]; }
+ // inline double get_A_Y_pilot() const { return a_pilot_body_v[1]; }
+ // inline double get_A_Z_pilot() const { return a_pilot_body_v[2]; }
+ /* inline void set_Accels_Pilot_Body( double x, double y, double z ) {
+ a_pilot_body_v[0] = x;
+ a_pilot_body_v[1] = y;
+ a_pilot_body_v[2] = z;
+ } */
FG_VECTOR_3 n_cg_body_v;
-#define FG_N_cg_body_v f->n_cg_body_v
-#define FG_N_X_cg f->n_cg_body_v[0]
-#define FG_N_Y_cg f->n_cg_body_v[1]
-#define FG_N_Z_cg f->n_cg_body_v[2]
+ // inline double * get_N_cg_body_v() { return n_cg_body_v; }
+ // inline double get_N_X_cg() const { return n_cg_body_v[0]; }
+ // inline double get_N_Y_cg() const { return n_cg_body_v[1]; }
+ // inline double get_N_Z_cg() const { return n_cg_body_v[2]; }
+ /* inline void set_Accels_CG_Body_N( double x, double y, double z ) {
+ n_cg_body_v[0] = x;
+ n_cg_body_v[1] = y;
+ n_cg_body_v[2] = z;
+ } */
FG_VECTOR_3 n_pilot_body_v;
-#define FG_N_pilot_body_v f->n_pilot_body_v
-#define FG_N_X_pilot f->n_pilot_body_v[0]
-#define FG_N_Y_pilot f->n_pilot_body_v[1]
-#define FG_N_Z_pilot f->n_pilot_body_v[2]
+ // inline double * get_N_pilot_body_v() { return n_pilot_body_v; }
+ // inline double get_N_X_pilot() const { return n_pilot_body_v[0]; }
+ // inline double get_N_Y_pilot() const { return n_pilot_body_v[1]; }
+ // inline double get_N_Z_pilot() const { return n_pilot_body_v[2]; }
+ /* inline void set_Accels_Pilot_Body_N( double x, double y, double z ) {
+ n_pilot_body_v[0] = x;
+ n_pilot_body_v[1] = y;
+ n_pilot_body_v[2] = z;
+ } */
FG_VECTOR_3 omega_dot_body_v;
-#define FG_Omega_dot_body_v f->omega_dot_body_v
-#define FG_P_dot_body f->omega_dot_body_v[0]
-#define FG_Q_dot_body f->omega_dot_body_v[1]
-#define FG_R_dot_body f->omega_dot_body_v[2]
+ // inline double * get_Omega_dot_body_v() { return omega_dot_body_v; }
+ // inline double get_P_dot_body() const { return omega_dot_body_v[0]; }
+ // inline double get_Q_dot_body() const { return omega_dot_body_v[1]; }
+ // inline double get_R_dot_body() const { return omega_dot_body_v[2]; }
+ /* inline void set_Accels_Omega( double p, double q, double r ) {
+ omega_dot_body_v[0] = p;
+ omega_dot_body_v[1] = q;
+ omega_dot_body_v[2] = r;
+ } */
-/*============================== Velocities ===============================*/
+ /*============================== Velocities ===============================*/
FG_VECTOR_3 v_local_v;
-#define FG_V_local_v f->v_local_v
-#define FG_V_north f->v_local_v[0]
-#define FG_V_east f->v_local_v[1]
-#define FG_V_down f->v_local_v[2]
-
- FG_VECTOR_3 v_local_rel_ground_v; /* V rel w.r.t. earth surface */
-#define FG_V_local_rel_ground_v f->v_local_rel_ground_v
-#define FG_V_north_rel_ground f->v_local_rel_ground_v[0]
-#define FG_V_east_rel_ground f->v_local_rel_ground_v[1]
-#define FG_V_down_rel_ground f->v_local_rel_ground_v[2]
-
- FG_VECTOR_3 v_local_airmass_v; /* velocity of airmass (steady winds) */
-#define FG_V_local_airmass_v f->v_local_airmass_v
-#define FG_V_north_airmass f->v_local_airmass_v[0]
-#define FG_V_east_airmass f->v_local_airmass_v[1]
-#define FG_V_down_airmass f->v_local_airmass_v[2]
-
- FG_VECTOR_3 v_local_rel_airmass_v; /* velocity of veh. relative to */
- /* airmass */
-#define FG_V_local_rel_airmass_v f->v_local_rel_airmass_v
-#define FG_V_north_rel_airmass f->v_local_rel_airmass_v[0]
-#define FG_V_east_rel_airmass f->v_local_rel_airmass_v[1]
-#define FG_V_down_rel_airmass f->v_local_rel_airmass_v[2]
-
- FG_VECTOR_3 v_local_gust_v; /* linear turbulence components, L frame */
-#define FG_V_local_gust_v f->v_local_gust_v
-#define FG_U_gust f->v_local_gust_v[0]
-#define FG_V_gust f->v_local_gust_v[1]
-#define FG_W_gust f->v_local_gust_v[2]
-
- FG_VECTOR_3 v_wind_body_v; /* Wind-relative velocities in body axis */
-#define FG_V_wind_body_v f->v_wind_body_v
-#define FG_U_body f->v_wind_body_v[0]
-#define FG_V_body f->v_wind_body_v[1]
-#define FG_W_body f->v_wind_body_v[2]
+ // inline double * get_V_local_v() { return v_local_v; }
+ inline double get_V_north() const { return v_local_v[0]; }
+ inline double get_V_east() const { return v_local_v[1]; }
+ inline double get_V_down() const { return v_local_v[2]; }
+ inline void set_Velocities_Local( double north, double east, double down ) {
+ v_local_v[0] = north;
+ v_local_v[1] = east;
+ v_local_v[2] = down;
+ }
+
+ FG_VECTOR_3 v_local_rel_ground_v; // V rel w.r.t. earth surface
+ // inline double * get_V_local_rel_ground_v() { return v_local_rel_ground_v; }
+ // inline double get_V_north_rel_ground() const {
+ // return v_local_rel_ground_v[0];
+ // }
+ // inline double get_V_east_rel_ground() const {
+ // return v_local_rel_ground_v[1];
+ // }
+ // inline double get_V_down_rel_ground() const {
+ // return v_local_rel_ground_v[2];
+ // }
+ /* inline void set_Velocities_Ground(double north, double east, double down) {
+ v_local_rel_ground_v[0] = north;
+ v_local_rel_ground_v[1] = east;
+ v_local_rel_ground_v[2] = down;
+ } */
+
+ FG_VECTOR_3 v_local_airmass_v; // velocity of airmass (steady winds)
+ // inline double * get_V_local_airmass_v() { return v_local_airmass_v; }
+ // inline double get_V_north_airmass() const { return v_local_airmass_v[0]; }
+ // inline double get_V_east_airmass() const { return v_local_airmass_v[1]; }
+ // inline double get_V_down_airmass() const { return v_local_airmass_v[2]; }
+ /* inline void set_Velocities_Local_Airmass( double north, double east,
+ double down)
+ {
+ v_local_airmass_v[0] = north;
+ v_local_airmass_v[1] = east;
+ v_local_airmass_v[2] = down;
+ } */
+
+ FG_VECTOR_3 v_local_rel_airmass_v; // velocity of veh. relative to
+ // airmass
+ // inline double * get_V_local_rel_airmass_v() {
+ //return v_local_rel_airmass_v;
+ //}
+ // inline double get_V_north_rel_airmass() const {
+ //return v_local_rel_airmass_v[0];
+ //}
+ // inline double get_V_east_rel_airmass() const {
+ //return v_local_rel_airmass_v[1];
+ //}
+ // inline double get_V_down_rel_airmass() const {
+ //return v_local_rel_airmass_v[2];
+ //}
+ /* inline void set_Velocities_Local_Rel_Airmass( double north, double east,
+ double down)
+ {
+ v_local_rel_airmass_v[0] = north;
+ v_local_rel_airmass_v[1] = east;
+ v_local_rel_airmass_v[2] = down;
+ } */
+
+ FG_VECTOR_3 v_local_gust_v; // linear turbulence components, L frame
+ // inline double * get_V_local_gust_v() { return v_local_gust_v; }
+ // inline double get_U_gust() const { return v_local_gust_v[0]; }
+ // inline double get_V_gust() const { return v_local_gust_v[1]; }
+ // inline double get_W_gust() const { return v_local_gust_v[2]; }
+ /* inline void set_Velocities_Gust( double u, double v, double w)
+ {
+ v_local_gust_v[0] = u;
+ v_local_gust_v[1] = v;
+ v_local_gust_v[2] = w;
+ } */
+
+ FG_VECTOR_3 v_wind_body_v; // Wind-relative velocities in body axis
+ // inline double * get_V_wind_body_v() { return v_wind_body_v; }
+ // inline double get_U_body() const { return v_wind_body_v[0]; }
+ // inline double get_V_body() const { return v_wind_body_v[1]; }
+ // inline double get_W_body() const { return v_wind_body_v[2]; }
+ /* inline void set_Velocities_Wind_Body( double u, double v, double w)
+ {
+ v_wind_body_v[0] = u;
+ v_wind_body_v[1] = v;
+ v_wind_body_v[2] = w;
+ } */
double v_rel_wind, v_true_kts, v_rel_ground, v_inertial;
double v_ground_speed, v_equiv, v_equiv_kts;
double v_calibrated, v_calibrated_kts;
-#define FG_V_rel_wind f->v_rel_wind
-#define FG_V_true_kts f->v_true_kts
-#define FG_V_rel_ground f->v_rel_ground
-#define FG_V_inertial f->v_inertial
-#define FG_V_ground_speed f->v_ground_speed
-#define FG_V_equiv f->v_equiv
-#define FG_V_equiv_kts f->v_equiv_kts
-#define FG_V_calibrated f->v_calibrated
-#define FG_V_calibrated_kts f->v_calibrated_kts
-
- FG_VECTOR_3 omega_body_v; /* Angular B rates */
-#define FG_Omega_body_v f->omega_body_v
-#define FG_P_body f->omega_body_v[0]
-#define FG_Q_body f->omega_body_v[1]
-#define FG_R_body f->omega_body_v[2]
-
- FG_VECTOR_3 omega_local_v; /* Angular L rates */
-#define FG_Omega_local_v f->omega_local_v
-#define FG_P_local f->omega_local_v[0]
-#define FG_Q_local f->omega_local_v[1]
-#define FG_R_local f->omega_local_v[2]
-
- FG_VECTOR_3 omega_total_v; /* Diff btw B & L */
-#define FG_Omega_total_v f->omega_total_v
-#define FG_P_total f->omega_total_v[0]
-#define FG_Q_total f->omega_total_v[1]
-#define FG_R_total f->omega_total_v[2]
-
- FG_VECTOR_3 euler_rates_v;
-#define FG_Euler_rates_v f->euler_rates_v
-#define FG_Phi_dot f->euler_rates_v[0]
-#define FG_Theta_dot f->euler_rates_v[1]
-#define FG_Psi_dot f->euler_rates_v[2]
- FG_VECTOR_3 geocentric_rates_v; /* Geocentric linear velocities */
-#define FG_Geocentric_rates_v f->geocentric_rates_v
-#define FG_Latitude_dot f->geocentric_rates_v[0]
-#define FG_Longitude_dot f->geocentric_rates_v[1]
-#define FG_Radius_dot f->geocentric_rates_v[2]
+ // inline double get_V_rel_wind() const { return v_rel_wind; }
+ // inline void set_V_rel_wind(double wind) { v_rel_wind = wind; }
+
+ // inline double get_V_true_kts() const { return v_true_kts; }
+ // inline void set_V_true_kts(double kts) { v_true_kts = kts; }
+
+ // inline double get_V_rel_ground() const { return v_rel_ground; }
+ // inline void set_V_rel_ground( double v ) { v_rel_ground = v; }
+
+ // inline double get_V_inertial() const { return v_inertial; }
+ // inline void set_V_inertial(double v) { v_inertial = v; }
+
+ // inline double get_V_ground_speed() const { return v_ground_speed; }
+ // inline void set_V_ground_speed( double v) { v_ground_speed = v; }
+
+ // inline double get_V_equiv() const { return v_equiv; }
+ // inline void set_V_equiv( double v ) { v_equiv = v; }
+
+ inline double get_V_equiv_kts() const { return v_equiv_kts; }
+ inline void set_V_equiv_kts( double kts ) { v_equiv_kts = kts; }
+
+ // inline double get_V_calibrated() const { return v_calibrated; }
+ // inline void set_V_calibrated( double v ) { v_calibrated = v; }
+
+ // inline double get_V_calibrated_kts() const { return v_calibrated_kts; }
+ // inline void set_V_calibrated_kts( double kts ) { v_calibrated_kts = kts; }
+
+ FG_VECTOR_3 omega_body_v; // Angular B rates
+ // inline double * get_Omega_body_v() { return omega_body_v; }
+ inline double get_P_body() const { return omega_body_v[0]; }
+ inline double get_Q_body() const { return omega_body_v[1]; }
+ inline double get_R_body() const { return omega_body_v[2]; }
+ inline void set_Omega_Body( double p, double q, double r ) {
+ omega_body_v[0] = p;
+ omega_body_v[1] = q;
+ omega_body_v[2] = r;
+ }
+
+ FG_VECTOR_3 omega_local_v; // Angular L rates
+ // inline double * get_Omega_local_v() { return omega_local_v; }
+ // inline double get_P_local() const { return omega_local_v[0]; }
+ // inline double get_Q_local() const { return omega_local_v[1]; }
+ // inline double get_R_local() const { return omega_local_v[2]; }
+ /* inline void set_Omega_Local( double p, double q, double r ) {
+ omega_local_v[0] = p;
+ omega_local_v[1] = q;
+ omega_local_v[2] = r;
+ } */
+
+ FG_VECTOR_3 omega_total_v; // Diff btw B & L
+ // inline double * get_Omega_total_v() { return omega_total_v; }
+ // inline double get_P_total() const { return omega_total_v[0]; }
+ // inline double get_Q_total() const { return omega_total_v[1]; }
+ // inline double get_R_total() const { return omega_total_v[2]; }
+ /* inline void set_Omega_Total( double p, double q, double r ) {
+ omega_total_v[0] = p;
+ omega_total_v[1] = q;
+ omega_total_v[2] = r;
+ } */
-/*=============================== Positions ===============================*/
+ FG_VECTOR_3 euler_rates_v;
+ // inline double * get_Euler_rates_v() { return euler_rates_v; }
+ // inline double get_Phi_dot() const { return euler_rates_v[0]; }
+ // inline double get_Theta_dot() const { return euler_rates_v[1]; }
+ // inline double get_Psi_dot() const { return euler_rates_v[2]; }
+ /* inline void set_Euler_Rates( double phi, double theta, double psi ) {
+ euler_rates_v[0] = phi;
+ euler_rates_v[1] = theta;
+ euler_rates_v[2] = psi;
+ } */
+
+ FG_VECTOR_3 geocentric_rates_v; // Geocentric linear velocities
+ // inline double * get_Geocentric_rates_v() { return geocentric_rates_v; }
+ inline double get_Latitude_dot() const { return geocentric_rates_v[0]; }
+ inline double get_Longitude_dot() const { return geocentric_rates_v[1]; }
+ inline double get_Radius_dot() const { return geocentric_rates_v[2]; }
+ inline void set_Geocentric_Rates( double lat, double lon, double rad ) {
+ geocentric_rates_v[0] = lat;
+ geocentric_rates_v[1] = lon;
+ geocentric_rates_v[2] = rad;
+ }
+
+ /*=============================== Positions ===============================*/
FG_VECTOR_3 geocentric_position_v;
-#define FG_Geocentric_position_v f->geocentric_position_v
-#define FG_Lat_geocentric f->geocentric_position_v[0]
-#define FG_Lon_geocentric f->geocentric_position_v[1]
-#define FG_Radius_to_vehicle f->geocentric_position_v[2]
+ // inline double * get_Geocentric_position_v() {
+ // return geocentric_position_v;
+ // }
+ inline double get_Lat_geocentric() const {
+ return geocentric_position_v[0];
+ }
+ inline double get_Lon_geocentric() const {
+ return geocentric_position_v[1];
+ }
+ inline double get_Radius_to_vehicle() const {
+ return geocentric_position_v[2];
+ }
+ inline void set_Radius_to_vehicle(double radius) {
+ geocentric_position_v[2] = radius;
+ }
+
+ inline void set_Geocentric_Position( double lat, double lon, double rad ) {
+ geocentric_position_v[0] = lat;
+ geocentric_position_v[1] = lon;
+ geocentric_position_v[2] = rad;
+ }
FG_VECTOR_3 geodetic_position_v;
-#define FG_Geodetic_position_v f->geodetic_position_v
-#define FG_Latitude f->geodetic_position_v[0]
-#define FG_Longitude f->geodetic_position_v[1]
-#define FG_Altitude f->geodetic_position_v[2]
-
- FG_VECTOR_3 euler_angles_v;
-#define FG_Euler_angles_v f->euler_angles_v
-#define FG_Phi f->euler_angles_v[0]
-#define FG_Theta f->euler_angles_v[1]
-#define FG_Psi f->euler_angles_v[2]
-
-/*======================= Miscellaneous quantities ========================*/
-
- double t_local_to_body_m[3][3]; /* Transformation matrix L to B */
-#define FG_T_local_to_body_m f->t_local_to_body_m
-#define FG_T_local_to_body_11 f->t_local_to_body_m[0][0]
-#define FG_T_local_to_body_12 f->t_local_to_body_m[0][1]
-#define FG_T_local_to_body_13 f->t_local_to_body_m[0][2]
-#define FG_T_local_to_body_21 f->t_local_to_body_m[1][0]
-#define FG_T_local_to_body_22 f->t_local_to_body_m[1][1]
-#define FG_T_local_to_body_23 f->t_local_to_body_m[1][2]
-#define FG_T_local_to_body_31 f->t_local_to_body_m[2][0]
-#define FG_T_local_to_body_32 f->t_local_to_body_m[2][1]
-#define FG_T_local_to_body_33 f->t_local_to_body_m[2][2]
-
- double gravity; /* Local acceleration due to G */
-#define FG_Gravity f->gravity
-
- double centrifugal_relief; /* load factor reduction due to speed */
-#define FG_Centrifugal_relief f->centrifugal_relief
-
- double alpha, beta, alpha_dot, beta_dot; /* in radians */
-#define FG_Alpha f->alpha
-#define FG_Beta f->beta
-#define FG_Alpha_dot f->alpha_dot
-#define FG_Beta_dot f->beta_dot
+ // inline double * get_Geodetic_position_v() { return geodetic_position_v; }
+ inline double get_Latitude() const { return geodetic_position_v[0]; }
+ inline void set_Latitude(double lat) { geodetic_position_v[0] = lat; }
+ inline double get_Longitude() const { return geodetic_position_v[1]; }
+ inline void set_Longitude(double lon) { geodetic_position_v[1] = lon; }
+ inline double get_Altitude() const { return geodetic_position_v[2]; }
+ inline void set_Altitude(double altitude) {
+ geodetic_position_v[2] = altitude;
+ }
+ inline void set_Geodetic_Position( double lat, double lon, double alt ) {
+ geodetic_position_v[0] = lat;
+ geodetic_position_v[1] = lon;
+ geodetic_position_v[2] = alt;
+ }
+
+ FG_VECTOR_3 euler_angles_v;
+ // inline double * get_Euler_angles_v() { return euler_angles_v; }
+ inline double get_Phi() const { return euler_angles_v[0]; }
+ inline double get_Theta() const { return euler_angles_v[1]; }
+ inline double get_Psi() const { return euler_angles_v[2]; }
+ inline void set_Euler_Angles( double phi, double theta, double psi ) {
+ euler_angles_v[0] = phi;
+ euler_angles_v[1] = theta;
+ euler_angles_v[2] = psi;
+ }
+
+
+ /*======================= Miscellaneous quantities ========================*/
+
+ double t_local_to_body_m[3][3]; // Transformation matrix L to B
+ // inline double * get_T_local_to_body_m() { return t_local_to_body_m; }
+ inline double get_T_local_to_body_11() const {
+ return t_local_to_body_m[0][0];
+ }
+ inline double get_T_local_to_body_12() const {
+ return t_local_to_body_m[0][1];
+ }
+ inline double get_T_local_to_body_13() const {
+ return t_local_to_body_m[0][2];
+ }
+ inline double get_T_local_to_body_21() const {
+ return t_local_to_body_m[1][0];
+ }
+ inline double get_T_local_to_body_22() const {
+ return t_local_to_body_m[1][1];
+ }
+ inline double get_T_local_to_body_23() const {
+ return t_local_to_body_m[1][2];
+ }
+ inline double get_T_local_to_body_31() const {
+ return t_local_to_body_m[2][0];
+ }
+ inline double get_T_local_to_body_32() const {
+ return t_local_to_body_m[2][1];
+ }
+ inline double get_T_local_to_body_33() const {
+ return t_local_to_body_m[2][2];
+ }
+ inline void set_T_Local_to_Body( double m[3][3] ) {
+ int i, j;
+ for ( i = 0; i < 3; i++ ) {
+ for ( j = 0; j < 3; j++ ) {
+ t_local_to_body_m[i][j] = m[i][j];
+ }
+ }
+ }
+
+ double gravity; // Local acceleration due to G
+ // inline double get_Gravity() const { return gravity; }
+ // inline void set_Gravity(double g) { gravity = g; }
+
+ double centrifugal_relief; // load factor reduction due to speed
+ // inline double get_Centrifugal_relief() const { return centrifugal_relief; }
+ // inline void set_Centrifugal_relief(double cr) { centrifugal_relief = cr; }
+
+ double alpha, beta, alpha_dot, beta_dot; // in radians
+ inline double get_Alpha() const { return alpha; }
+ inline void set_Alpha( double a ) { alpha = a; }
+ inline double get_Beta() const { return beta; }
+ inline void set_Beta( double b ) { beta = b; }
+ // inline double get_Alpha_dot() const { return alpha_dot; }
+ // inline void set_Alpha_dot( double ad ) { alpha_dot = ad; }
+ // inline double get_Beta_dot() const { return beta_dot; }
+ // inline void set_Beta_dot( double bd ) { beta_dot = bd; }
double cos_alpha, sin_alpha, cos_beta, sin_beta;
-#define FG_Cos_alpha f->cos_alpha
-#define FG_Sin_alpha f->sin_alpha
-#define FG_Cos_beta f->cos_beta
-#define FG_Sin_beta f->sin_beta
+ // inline double get_Cos_alpha() const { return cos_alpha; }
+ // inline void set_Cos_alpha( double ca ) { cos_alpha = ca; }
+ // inline double get_Sin_alpha() const { return sin_alpha; }
+ // inline void set_Sin_alpha( double sa ) { sin_alpha = sa; }
+ // inline double get_Cos_beta() const { return cos_beta; }
+ // inline void set_Cos_beta( double cb ) { cos_beta = cb; }
+ // inline double get_Sin_beta() const { return sin_beta; }
+ // inline void set_Sin_beta( double sb ) { sin_beta = sb; }
double cos_phi, sin_phi, cos_theta, sin_theta, cos_psi, sin_psi;
-#define FG_Cos_phi f->cos_phi
-#define FG_Sin_phi f->sin_phi
-#define FG_Cos_theta f->cos_theta
-#define FG_Sin_theta f->sin_theta
-#define FG_Cos_psi f->cos_psi
-#define FG_Sin_psi f->sin_psi
-
- double gamma_vert_rad, gamma_horiz_rad; /* Flight path angles */
-#define FG_Gamma_vert_rad f->gamma_vert_rad
-#define FG_Gamma_horiz_rad f->gamma_horiz_rad
+ // inline double get_Cos_phi() const { return cos_phi; }
+ // inline void set_Cos_phi( double cp ) { cos_phi = cp; }
+ // inline double get_Sin_phi() const { return sin_phi; }
+ // inline void set_Sin_phi( double sp ) { sin_phi = sp; }
+ // inline double get_Cos_theta() const { return cos_theta; }
+ // inline void set_Cos_theta( double ct ) { cos_theta = ct; }
+ // inline double get_Sin_theta() const { return sin_theta; }
+ // inline void set_Sin_theta( double st ) { sin_theta = st; }
+ // inline double get_Cos_psi() const { return cos_psi; }
+ // inline void set_Cos_psi( double cp ) { cos_psi = cp; }
+ // inline double get_Sin_psi() const { return sin_psi; }
+ // inline void set_Sin_psi( double sp ) { sin_psi = sp; }
+
+ double gamma_vert_rad, gamma_horiz_rad; // Flight path angles
+ inline double get_Gamma_vert_rad() const { return gamma_vert_rad; }
+ inline void set_Gamma_vert_rad( double gv ) { gamma_vert_rad = gv; }
+ // inline double get_Gamma_horiz_rad() const { return gamma_horiz_rad; }
+ // inline void set_Gamma_horiz_rad( double gh ) { gamma_horiz_rad = gh; }
double sigma, density, v_sound, mach_number;
-#define FG_Sigma f->sigma
-#define FG_Density f->density
-#define FG_V_sound f->v_sound
-#define FG_Mach_number f->mach_number
+ // inline double get_Sigma() const { return sigma; }
+ // inline void set_Sigma( double s ) { sigma = s; }
+ // inline double get_Density() const { return density; }
+ // inline void set_Density( double d ) { density = d; }
+ // inline double get_V_sound() const { return v_sound; }
+ // inline void set_V_sound( double v ) { v_sound = v; }
+ // inline double get_Mach_number() const { return mach_number; }
+ // inline void set_Mach_number( double m ) { mach_number = m; }
double static_pressure, total_pressure, impact_pressure;
double dynamic_pressure;
-#define FG_Static_pressure f->static_pressure
-#define FG_Total_pressure f->total_pressure
-#define FG_Impact_pressure f->impact_pressure
-#define FG_Dynamic_pressure f->dynamic_pressure
+ // inline double get_Static_pressure() const { return static_pressure; }
+ // inline void set_Static_pressure( double sp ) { static_pressure = sp; }
+ // inline double get_Total_pressure() const { return total_pressure; }
+ // inline void set_Total_pressure( double tp ) { total_pressure = tp; }
+ // inline double get_Impact_pressure() const { return impact_pressure; }
+ // inline void set_Impact_pressure( double ip ) { impact_pressure = ip; }
+ // inline double get_Dynamic_pressure() const { return dynamic_pressure; }
+ // inline void set_Dynamic_pressure( double dp ) { dynamic_pressure = dp; }
double static_temperature, total_temperature;
-#define FG_Static_temperature f->static_temperature
-#define FG_Total_temperature f->total_temperature
+ // inline double get_Static_temperature() const { return static_temperature; }
+ // inline void set_Static_temperature( double t ) { static_temperature = t; }
+ // inline double get_Total_temperature() const { return total_temperature; }
+ // inline void set_Total_temperature( double t ) { total_temperature = t; }
double sea_level_radius, earth_position_angle;
-#define FG_Sea_level_radius f->sea_level_radius
-#define FG_Earth_position_angle f->earth_position_angle
+ inline double get_Sea_level_radius() const { return sea_level_radius; }
+ inline void set_Sea_level_radius( double r ) { sea_level_radius = r; }
+ inline double get_Earth_position_angle() const {
+ return earth_position_angle;
+ }
+ inline void set_Earth_position_angle(double a) {
+ earth_position_angle = a;
+ }
double runway_altitude, runway_latitude, runway_longitude;
double runway_heading;
-#define FG_Runway_altitude f->runway_altitude
-#define FG_Runway_latitude f->runway_latitude
-#define FG_Runway_longitude f->runway_longitude
-#define FG_Runway_heading f->runway_heading
+ inline double get_Runway_altitude() const { return runway_altitude; }
+ inline void set_Runway_altitude( double alt ) { runway_altitude = alt; }
+ // inline double get_Runway_latitude() const { return runway_latitude; }
+ // inline void set_Runway_latitude( double lat ) { runway_latitude = lat; }
+ // inline double get_Runway_longitude() const { return runway_longitude; }
+ // inline void set_Runway_longitude( double lon ) { runway_longitude = lon; }
+ // inline double get_Runway_heading() const { return runway_heading; }
+ // inline void set_Runway_heading( double h ) { runway_heading = h; }
double radius_to_rwy;
-#define FG_Radius_to_rwy f->radius_to_rwy
-
- FG_VECTOR_3 d_cg_rwy_local_v; /* CG rel. to rwy in local coords */
-#define FG_D_cg_rwy_local_v f->d_cg_rwy_local_v
-#define FG_D_cg_north_of_rwy f->d_cg_rwy_local_v[0]
-#define FG_D_cg_east_of_rwy f->d_cg_rwy_local_v[1]
-#define FG_D_cg_above_rwy f->d_cg_rwy_local_v[2]
-
- FG_VECTOR_3 d_cg_rwy_rwy_v; /* CG relative to rwy, in rwy coordinates */
-#define FG_D_cg_rwy_rwy_v f->d_cg_rwy_rwy_v
-#define FG_X_cg_rwy f->d_cg_rwy_rwy_v[0]
-#define FG_Y_cg_rwy f->d_cg_rwy_rwy_v[1]
-#define FG_H_cg_rwy f->d_cg_rwy_rwy_v[2]
-
- FG_VECTOR_3 d_pilot_rwy_local_v; /* pilot rel. to rwy in local coords */
-#define FG_D_pilot_rwy_local_v f->d_pilot_rwy_local_v
-#define FG_D_pilot_north_of_rwy f->d_pilot_rwy_local_v[0]
-#define FG_D_pilot_east_of_rwy f->d_pilot_rwy_local_v[1]
-#define FG_D_pilot_above_rwy f->d_pilot_rwy_local_v[2]
-
- FG_VECTOR_3 d_pilot_rwy_rwy_v; /* pilot rel. to rwy, in rwy coords. */
-#define FG_D_pilot_rwy_rwy_v f->d_pilot_rwy_rwy_v
-#define FG_X_pilot_rwy f->d_pilot_rwy_rwy_v[0]
-#define FG_Y_pilot_rwy f->d_pilot_rwy_rwy_v[1]
-#define FG_H_pilot_rwy f->d_pilot_rwy_rwy_v[2]
-
- double climb_rate; /* in feet per second */
-#define FG_Climb_Rate f->climb_rate
-
-} fgFLIGHT, *pfgFlight;
-
-
-extern fgFLIGHT cur_flight_params;
-
-
-/* General interface to the flight model routines */
-
-/* Initialize the flight model parameters */
-int fgFlightModelInit(int model, fgFLIGHT *f, double dt);
-
-/* Run multiloop iterations of the flight model */
-int fgFlightModelUpdate(int model, fgFLIGHT *f, int multiloop);
-
-/* Set the altitude (force) */
-void fgFlightModelSetAltitude(int model, fgFLIGHT *f, double alt_meters);
-
-
-#endif /* _FLIGHT_H */
+ // inline double get_Radius_to_rwy() const { return radius_to_rwy; }
+ // inline void set_Radius_to_rwy( double r ) { radius_to_rwy = r; }
+
+ FG_VECTOR_3 d_cg_rwy_local_v; // CG rel. to rwy in local coords
+ // inline double * get_D_cg_rwy_local_v() { return d_cg_rwy_local_v; }
+ // inline double get_D_cg_north_of_rwy() const { return d_cg_rwy_local_v[0]; }
+ // inline double get_D_cg_east_of_rwy() const { return d_cg_rwy_local_v[1]; }
+ // inline double get_D_cg_above_rwy() const { return d_cg_rwy_local_v[2]; }
+ /* inline void set_CG_Rwy_Local( double north, double east, double above )
+ {
+ d_cg_rwy_local_v[0] = north;
+ d_cg_rwy_local_v[1] = east;
+ d_cg_rwy_local_v[2] = above;
+ } */
+
+ FG_VECTOR_3 d_cg_rwy_rwy_v; // CG relative to rwy, in rwy coordinates
+ // inline double * get_D_cg_rwy_rwy_v() { return d_cg_rwy_rwy_v; }
+ // inline double get_X_cg_rwy() const { return d_cg_rwy_rwy_v[0]; }
+ // inline double get_Y_cg_rwy() const { return d_cg_rwy_rwy_v[1]; }
+ // inline double get_H_cg_rwy() const { return d_cg_rwy_rwy_v[2]; }
+ /* inline void set_CG_Rwy_Rwy( double x, double y, double h )
+ {
+ d_cg_rwy_rwy_v[0] = x;
+ d_cg_rwy_rwy_v[1] = y;
+ d_cg_rwy_rwy_v[2] = h;
+ } */
+
+ FG_VECTOR_3 d_pilot_rwy_local_v; // pilot rel. to rwy in local coords
+ // inline double * get_D_pilot_rwy_local_v() { return d_pilot_rwy_local_v; }
+ // inline double get_D_pilot_north_of_rwy() const {
+ //return d_pilot_rwy_local_v[0];
+ // }
+ // inline double get_D_pilot_east_of_rwy() const {
+// return d_pilot_rwy_local_v[1];
+// }
+ // inline double get_D_pilot_above_rwy() const {
+ //return d_pilot_rwy_local_v[2];
+ // }
+ /* inline void set_Pilot_Rwy_Local( double north, double east, double above )
+ {
+ d_pilot_rwy_local_v[0] = north;
+ d_pilot_rwy_local_v[1] = east;
+ d_pilot_rwy_local_v[2] = above;
+ } */
+
+ FG_VECTOR_3 d_pilot_rwy_rwy_v; // pilot rel. to rwy, in rwy coords.
+ // inline double * get_D_pilot_rwy_rwy_v() { return d_pilot_rwy_rwy_v; }
+ // inline double get_X_pilot_rwy() const { return d_pilot_rwy_rwy_v[0]; }
+ // inline double get_Y_pilot_rwy() const { return d_pilot_rwy_rwy_v[1]; }
+ // inline double get_H_pilot_rwy() const { return d_pilot_rwy_rwy_v[2]; }
+ /* inline void set_Pilot_Rwy_Rwy( double x, double y, double h )
+ {
+ d_pilot_rwy_rwy_v[0] = x;
+ d_pilot_rwy_rwy_v[1] = y;
+ d_pilot_rwy_rwy_v[2] = h;
+ } */
+
+ double climb_rate; // in feet per second
+ inline double get_Climb_Rate() const { return climb_rate; }
+ inline void set_Climb_Rate(double rate) { climb_rate = rate; }
+
+ FGTimeStamp valid_stamp; // time this record is valid
+ FGTimeStamp next_stamp; // time this record is valid
+ inline FGTimeStamp get_time_stamp() const { return valid_stamp; }
+ inline void stamp_time() { valid_stamp = next_stamp; next_stamp.stamp(); }
+
+ // Extrapolate FDM based on time_offset (in usec)
+ void extrapolate( int time_offset );
+
+};
+
+
+extern FGState cur_fdm_state;
+
+
+// General interface to the flight model routines
+
+// Initialize the flight model parameters
+int fgFlightModelInit(int model, FGState& f, double dt);
+
+// Run multiloop iterations of the flight model
+int fgFlightModelUpdate(int model, FGState& f, int multiloop, int jitter);
+
+// Set the altitude (force)
+void fgFlightModelSetAltitude(int model, double alt_meters);
+
+
+#endif // _FLIGHT_HXX
// $Log$
+// Revision 1.11 1999/01/19 17:52:07 curt
+// Working on being able to extrapolate a new position and orientation
+// based on a position, orientation, and time offset.
+//
+// Revision 1.10 1999/01/09 13:37:33 curt
+// Convert fgTIMESTAMP to FGTimeStamp which holds usec instead of ms.
+//
+// Revision 1.9 1999/01/08 19:27:38 curt
+// Fixed AOA reading on HUD.
+// Continued work on time jitter compensation.
+//
+// Revision 1.8 1999/01/08 03:23:52 curt
+// Beginning work on compensating for sim time vs. real world time "jitter".
+//
+// Revision 1.7 1998/12/18 23:37:09 curt
+// Collapsed out the FGState variables not currently needed. They are just
+// commented out and can be readded easily at any time. The point of this
+// exersize is to determine which variables were or were not currently being
+// used.
+//
+// Revision 1.6 1998/12/05 15:54:12 curt
+// Renamed class fgFLIGHT to class FGState as per request by JSB.
+//
+// Revision 1.5 1998/12/04 01:29:40 curt
+// Stubbed in a new flight model called "External" which is expected to be driven
+// from some external source.
+//
+// Revision 1.4 1998/12/03 04:25:03 curt
+// Working on fixing up new fgFLIGHT class.
+//
+// Revision 1.3 1998/12/03 01:16:41 curt
+// Converted fgFLIGHT to a class.
+//
// Revision 1.2 1998/10/16 23:27:41 curt
// C++-ifying.
//