#include "car.h" namespace { #define DIM 9 #define EDIM 9 #define MEDIM 9 typedef void (*Hfun)(double *, double *, double *); double mass; void set_mass(double x){ mass = x;} double rotational_inertia; void set_rotational_inertia(double x){ rotational_inertia = x;} double center_to_front; void set_center_to_front(double x){ center_to_front = x;} double center_to_rear; void set_center_to_rear(double x){ center_to_rear = x;} double stiffness_front; void set_stiffness_front(double x){ stiffness_front = x;} double stiffness_rear; void set_stiffness_rear(double x){ stiffness_rear = x;} const static double MAHA_THRESH_25 = 3.8414588206941227; const static double MAHA_THRESH_24 = 5.991464547107981; const static double MAHA_THRESH_30 = 3.8414588206941227; const static double MAHA_THRESH_26 = 3.8414588206941227; const static double MAHA_THRESH_27 = 3.8414588206941227; const static double MAHA_THRESH_29 = 3.8414588206941227; const static double MAHA_THRESH_28 = 3.8414588206941227; const static double MAHA_THRESH_31 = 3.8414588206941227; /****************************************************************************** * Code generated with SymPy 1.14.0 * * * * See http://www.sympy.org/ for more information. * * * * This file is part of 'ekf' * ******************************************************************************/ void err_fun(double *nom_x, double *delta_x, double *out_1814247348247547720) { out_1814247348247547720[0] = delta_x[0] + nom_x[0]; out_1814247348247547720[1] = delta_x[1] + nom_x[1]; out_1814247348247547720[2] = delta_x[2] + nom_x[2]; out_1814247348247547720[3] = delta_x[3] + nom_x[3]; out_1814247348247547720[4] = delta_x[4] + nom_x[4]; out_1814247348247547720[5] = delta_x[5] + nom_x[5]; out_1814247348247547720[6] = delta_x[6] + nom_x[6]; out_1814247348247547720[7] = delta_x[7] + nom_x[7]; out_1814247348247547720[8] = delta_x[8] + nom_x[8]; } void inv_err_fun(double *nom_x, double *true_x, double *out_2896416663387818009) { out_2896416663387818009[0] = -nom_x[0] + true_x[0]; out_2896416663387818009[1] = -nom_x[1] + true_x[1]; out_2896416663387818009[2] = -nom_x[2] + true_x[2]; out_2896416663387818009[3] = -nom_x[3] + true_x[3]; out_2896416663387818009[4] = -nom_x[4] + true_x[4]; out_2896416663387818009[5] = -nom_x[5] + true_x[5]; out_2896416663387818009[6] = -nom_x[6] + true_x[6]; out_2896416663387818009[7] = -nom_x[7] + true_x[7]; out_2896416663387818009[8] = -nom_x[8] + true_x[8]; } void H_mod_fun(double *state, double *out_3833245775098430450) { out_3833245775098430450[0] = 1.0; out_3833245775098430450[1] = 0.0; out_3833245775098430450[2] = 0.0; out_3833245775098430450[3] = 0.0; out_3833245775098430450[4] = 0.0; out_3833245775098430450[5] = 0.0; out_3833245775098430450[6] = 0.0; out_3833245775098430450[7] = 0.0; out_3833245775098430450[8] = 0.0; out_3833245775098430450[9] = 0.0; out_3833245775098430450[10] = 1.0; out_3833245775098430450[11] = 0.0; out_3833245775098430450[12] = 0.0; out_3833245775098430450[13] = 0.0; out_3833245775098430450[14] = 0.0; out_3833245775098430450[15] = 0.0; out_3833245775098430450[16] = 0.0; out_3833245775098430450[17] = 0.0; out_3833245775098430450[18] = 0.0; out_3833245775098430450[19] = 0.0; out_3833245775098430450[20] = 1.0; out_3833245775098430450[21] = 0.0; out_3833245775098430450[22] = 0.0; out_3833245775098430450[23] = 0.0; out_3833245775098430450[24] = 0.0; out_3833245775098430450[25] = 0.0; out_3833245775098430450[26] = 0.0; out_3833245775098430450[27] = 0.0; out_3833245775098430450[28] = 0.0; out_3833245775098430450[29] = 0.0; out_3833245775098430450[30] = 1.0; out_3833245775098430450[31] = 0.0; out_3833245775098430450[32] = 0.0; out_3833245775098430450[33] = 0.0; out_3833245775098430450[34] = 0.0; out_3833245775098430450[35] = 0.0; out_3833245775098430450[36] = 0.0; out_3833245775098430450[37] = 0.0; out_3833245775098430450[38] = 0.0; out_3833245775098430450[39] = 0.0; out_3833245775098430450[40] = 1.0; out_3833245775098430450[41] = 0.0; out_3833245775098430450[42] = 0.0; out_3833245775098430450[43] = 0.0; out_3833245775098430450[44] = 0.0; out_3833245775098430450[45] = 0.0; out_3833245775098430450[46] = 0.0; out_3833245775098430450[47] = 0.0; out_3833245775098430450[48] = 0.0; out_3833245775098430450[49] = 0.0; out_3833245775098430450[50] = 1.0; out_3833245775098430450[51] = 0.0; out_3833245775098430450[52] = 0.0; out_3833245775098430450[53] = 0.0; out_3833245775098430450[54] = 0.0; out_3833245775098430450[55] = 0.0; out_3833245775098430450[56] = 0.0; out_3833245775098430450[57] = 0.0; out_3833245775098430450[58] = 0.0; out_3833245775098430450[59] = 0.0; out_3833245775098430450[60] = 1.0; out_3833245775098430450[61] = 0.0; out_3833245775098430450[62] = 0.0; out_3833245775098430450[63] = 0.0; out_3833245775098430450[64] = 0.0; out_3833245775098430450[65] = 0.0; out_3833245775098430450[66] = 0.0; out_3833245775098430450[67] = 0.0; out_3833245775098430450[68] = 0.0; out_3833245775098430450[69] = 0.0; out_3833245775098430450[70] = 1.0; out_3833245775098430450[71] = 0.0; out_3833245775098430450[72] = 0.0; out_3833245775098430450[73] = 0.0; out_3833245775098430450[74] = 0.0; out_3833245775098430450[75] = 0.0; out_3833245775098430450[76] = 0.0; out_3833245775098430450[77] = 0.0; out_3833245775098430450[78] = 0.0; out_3833245775098430450[79] = 0.0; out_3833245775098430450[80] = 1.0; } void f_fun(double *state, double dt, double *out_3477590770207651617) { out_3477590770207651617[0] = state[0]; out_3477590770207651617[1] = state[1]; out_3477590770207651617[2] = state[2]; out_3477590770207651617[3] = state[3]; out_3477590770207651617[4] = state[4]; out_3477590770207651617[5] = dt*((-state[4] + (-center_to_front*stiffness_front*state[0] + center_to_rear*stiffness_rear*state[0])/(mass*state[4]))*state[6] - 9.8100000000000005*state[8] + stiffness_front*(-state[2] - state[3] + state[7])*state[0]/(mass*state[1]) + (-stiffness_front*state[0] - stiffness_rear*state[0])*state[5]/(mass*state[4])) + state[5]; out_3477590770207651617[6] = dt*(center_to_front*stiffness_front*(-state[2] - state[3] + state[7])*state[0]/(rotational_inertia*state[1]) + (-center_to_front*stiffness_front*state[0] + center_to_rear*stiffness_rear*state[0])*state[5]/(rotational_inertia*state[4]) + (-pow(center_to_front, 2)*stiffness_front*state[0] - pow(center_to_rear, 2)*stiffness_rear*state[0])*state[6]/(rotational_inertia*state[4])) + state[6]; out_3477590770207651617[7] = state[7]; out_3477590770207651617[8] = state[8]; } void F_fun(double *state, double dt, double *out_3058811064297665734) { out_3058811064297665734[0] = 1; out_3058811064297665734[1] = 0; out_3058811064297665734[2] = 0; out_3058811064297665734[3] = 0; out_3058811064297665734[4] = 0; out_3058811064297665734[5] = 0; out_3058811064297665734[6] = 0; out_3058811064297665734[7] = 0; out_3058811064297665734[8] = 0; out_3058811064297665734[9] = 0; out_3058811064297665734[10] = 1; out_3058811064297665734[11] = 0; out_3058811064297665734[12] = 0; out_3058811064297665734[13] = 0; out_3058811064297665734[14] = 0; out_3058811064297665734[15] = 0; out_3058811064297665734[16] = 0; out_3058811064297665734[17] = 0; out_3058811064297665734[18] = 0; out_3058811064297665734[19] = 0; out_3058811064297665734[20] = 1; out_3058811064297665734[21] = 0; out_3058811064297665734[22] = 0; out_3058811064297665734[23] = 0; out_3058811064297665734[24] = 0; out_3058811064297665734[25] = 0; out_3058811064297665734[26] = 0; out_3058811064297665734[27] = 0; out_3058811064297665734[28] = 0; out_3058811064297665734[29] = 0; out_3058811064297665734[30] = 1; out_3058811064297665734[31] = 0; out_3058811064297665734[32] = 0; out_3058811064297665734[33] = 0; out_3058811064297665734[34] = 0; out_3058811064297665734[35] = 0; out_3058811064297665734[36] = 0; out_3058811064297665734[37] = 0; out_3058811064297665734[38] = 0; out_3058811064297665734[39] = 0; out_3058811064297665734[40] = 1; out_3058811064297665734[41] = 0; out_3058811064297665734[42] = 0; out_3058811064297665734[43] = 0; out_3058811064297665734[44] = 0; out_3058811064297665734[45] = dt*(stiffness_front*(-state[2] - state[3] + state[7])/(mass*state[1]) + (-stiffness_front - stiffness_rear)*state[5]/(mass*state[4]) + (-center_to_front*stiffness_front + center_to_rear*stiffness_rear)*state[6]/(mass*state[4])); out_3058811064297665734[46] = -dt*stiffness_front*(-state[2] - state[3] + state[7])*state[0]/(mass*pow(state[1], 2)); out_3058811064297665734[47] = -dt*stiffness_front*state[0]/(mass*state[1]); out_3058811064297665734[48] = -dt*stiffness_front*state[0]/(mass*state[1]); out_3058811064297665734[49] = dt*((-1 - (-center_to_front*stiffness_front*state[0] + center_to_rear*stiffness_rear*state[0])/(mass*pow(state[4], 2)))*state[6] - (-stiffness_front*state[0] - stiffness_rear*state[0])*state[5]/(mass*pow(state[4], 2))); out_3058811064297665734[50] = dt*(-stiffness_front*state[0] - stiffness_rear*state[0])/(mass*state[4]) + 1; out_3058811064297665734[51] = dt*(-state[4] + (-center_to_front*stiffness_front*state[0] + center_to_rear*stiffness_rear*state[0])/(mass*state[4])); out_3058811064297665734[52] = dt*stiffness_front*state[0]/(mass*state[1]); out_3058811064297665734[53] = -9.8100000000000005*dt; out_3058811064297665734[54] = dt*(center_to_front*stiffness_front*(-state[2] - state[3] + state[7])/(rotational_inertia*state[1]) + (-center_to_front*stiffness_front + center_to_rear*stiffness_rear)*state[5]/(rotational_inertia*state[4]) + (-pow(center_to_front, 2)*stiffness_front - pow(center_to_rear, 2)*stiffness_rear)*state[6]/(rotational_inertia*state[4])); out_3058811064297665734[55] = -center_to_front*dt*stiffness_front*(-state[2] - state[3] + state[7])*state[0]/(rotational_inertia*pow(state[1], 2)); out_3058811064297665734[56] = -center_to_front*dt*stiffness_front*state[0]/(rotational_inertia*state[1]); out_3058811064297665734[57] = -center_to_front*dt*stiffness_front*state[0]/(rotational_inertia*state[1]); out_3058811064297665734[58] = dt*(-(-center_to_front*stiffness_front*state[0] + center_to_rear*stiffness_rear*state[0])*state[5]/(rotational_inertia*pow(state[4], 2)) - (-pow(center_to_front, 2)*stiffness_front*state[0] - pow(center_to_rear, 2)*stiffness_rear*state[0])*state[6]/(rotational_inertia*pow(state[4], 2))); out_3058811064297665734[59] = dt*(-center_to_front*stiffness_front*state[0] + center_to_rear*stiffness_rear*state[0])/(rotational_inertia*state[4]); out_3058811064297665734[60] = dt*(-pow(center_to_front, 2)*stiffness_front*state[0] - pow(center_to_rear, 2)*stiffness_rear*state[0])/(rotational_inertia*state[4]) + 1; out_3058811064297665734[61] = center_to_front*dt*stiffness_front*state[0]/(rotational_inertia*state[1]); out_3058811064297665734[62] = 0; out_3058811064297665734[63] = 0; out_3058811064297665734[64] = 0; out_3058811064297665734[65] = 0; out_3058811064297665734[66] = 0; out_3058811064297665734[67] = 0; out_3058811064297665734[68] = 0; out_3058811064297665734[69] = 0; out_3058811064297665734[70] = 1; out_3058811064297665734[71] = 0; out_3058811064297665734[72] = 0; out_3058811064297665734[73] = 0; out_3058811064297665734[74] = 0; out_3058811064297665734[75] = 0; out_3058811064297665734[76] = 0; out_3058811064297665734[77] = 0; out_3058811064297665734[78] = 0; out_3058811064297665734[79] = 0; out_3058811064297665734[80] = 1; } void h_25(double *state, double *unused, double *out_845892813044312576) { out_845892813044312576[0] = state[6]; } void H_25(double *state, double *unused, double *out_6744590887944551998) { out_6744590887944551998[0] = 0; out_6744590887944551998[1] = 0; out_6744590887944551998[2] = 0; out_6744590887944551998[3] = 0; out_6744590887944551998[4] = 0; out_6744590887944551998[5] = 0; out_6744590887944551998[6] = 1; out_6744590887944551998[7] = 0; out_6744590887944551998[8] = 0; } void h_24(double *state, double *unused, double *out_410909672515548225) { out_410909672515548225[0] = state[4]; out_410909672515548225[1] = state[5]; } void H_24(double *state, double *unused, double *out_673800745732374895) { out_673800745732374895[0] = 0; out_673800745732374895[1] = 0; out_673800745732374895[2] = 0; out_673800745732374895[3] = 0; out_673800745732374895[4] = 1; out_673800745732374895[5] = 0; out_673800745732374895[6] = 0; out_673800745732374895[7] = 0; out_673800745732374895[8] = 0; out_673800745732374895[9] = 0; out_673800745732374895[10] = 0; out_673800745732374895[11] = 0; out_673800745732374895[12] = 0; out_673800745732374895[13] = 0; out_673800745732374895[14] = 1; out_673800745732374895[15] = 0; out_673800745732374895[16] = 0; out_673800745732374895[17] = 0; } void h_30(double *state, double *unused, double *out_8727165463798361761) { out_8727165463798361761[0] = state[4]; } void H_30(double *state, double *unused, double *out_7174456855637391420) { out_7174456855637391420[0] = 0; out_7174456855637391420[1] = 0; out_7174456855637391420[2] = 0; out_7174456855637391420[3] = 0; out_7174456855637391420[4] = 1; out_7174456855637391420[5] = 0; out_7174456855637391420[6] = 0; out_7174456855637391420[7] = 0; out_7174456855637391420[8] = 0; } void h_26(double *state, double *unused, double *out_2811534710064499425) { out_2811534710064499425[0] = state[7]; } void H_26(double *state, double *unused, double *out_7960649866890943394) { out_7960649866890943394[0] = 0; out_7960649866890943394[1] = 0; out_7960649866890943394[2] = 0; out_7960649866890943394[3] = 0; out_7960649866890943394[4] = 0; out_7960649866890943394[5] = 0; out_7960649866890943394[6] = 0; out_7960649866890943394[7] = 1; out_7960649866890943394[8] = 0; } void h_27(double *state, double *unused, double *out_4116487184636980656) { out_4116487184636980656[0] = state[3]; } void H_27(double *state, double *unused, double *out_9048693146888216979) { out_9048693146888216979[0] = 0; out_9048693146888216979[1] = 0; out_9048693146888216979[2] = 0; out_9048693146888216979[3] = 1; out_9048693146888216979[4] = 0; out_9048693146888216979[5] = 0; out_9048693146888216979[6] = 0; out_9048693146888216979[7] = 0; out_9048693146888216979[8] = 0; } void h_29(double *state, double *unused, double *out_1915699176115514220) { out_1915699176115514220[0] = state[1]; } void H_29(double *state, double *unused, double *out_7684688199951783604) { out_7684688199951783604[0] = 0; out_7684688199951783604[1] = 1; out_7684688199951783604[2] = 0; out_7684688199951783604[3] = 0; out_7684688199951783604[4] = 0; out_7684688199951783604[5] = 0; out_7684688199951783604[6] = 0; out_7684688199951783604[7] = 0; out_7684688199951783604[8] = 0; } void h_28(double *state, double *unused, double *out_6496658557271199005) { out_6496658557271199005[0] = state[0]; } void H_28(double *state, double *unused, double *out_2602289182882253030) { out_2602289182882253030[0] = 1; out_2602289182882253030[1] = 0; out_2602289182882253030[2] = 0; out_2602289182882253030[3] = 0; out_2602289182882253030[4] = 0; out_2602289182882253030[5] = 0; out_2602289182882253030[6] = 0; out_2602289182882253030[7] = 0; out_2602289182882253030[8] = 0; } void h_31(double *state, double *unused, double *out_9104190579401499048) { out_9104190579401499048[0] = state[8]; } void H_31(double *state, double *unused, double *out_7334441764657591918) { out_7334441764657591918[0] = 0; out_7334441764657591918[1] = 0; out_7334441764657591918[2] = 0; out_7334441764657591918[3] = 0; out_7334441764657591918[4] = 0; out_7334441764657591918[5] = 0; out_7334441764657591918[6] = 0; out_7334441764657591918[7] = 0; out_7334441764657591918[8] = 1; } #include #include typedef Eigen::Matrix DDM; typedef Eigen::Matrix EEM; typedef Eigen::Matrix DEM; void predict(double *in_x, double *in_P, double *in_Q, double dt) { typedef Eigen::Matrix RRM; double nx[DIM] = {0}; double in_F[EDIM*EDIM] = {0}; // functions from sympy f_fun(in_x, dt, nx); F_fun(in_x, dt, in_F); EEM F(in_F); EEM P(in_P); EEM Q(in_Q); RRM F_main = F.topLeftCorner(MEDIM, MEDIM); P.topLeftCorner(MEDIM, MEDIM) = (F_main * P.topLeftCorner(MEDIM, MEDIM)) * F_main.transpose(); P.topRightCorner(MEDIM, EDIM - MEDIM) = F_main * P.topRightCorner(MEDIM, EDIM - MEDIM); P.bottomLeftCorner(EDIM - MEDIM, MEDIM) = P.bottomLeftCorner(EDIM - MEDIM, MEDIM) * F_main.transpose(); P = P + dt*Q; // copy out state memcpy(in_x, nx, DIM * sizeof(double)); memcpy(in_P, P.data(), EDIM * EDIM * sizeof(double)); } // note: extra_args dim only correct when null space projecting // otherwise 1 template void update(double *in_x, double *in_P, Hfun h_fun, Hfun H_fun, Hfun Hea_fun, double *in_z, double *in_R, double *in_ea, double MAHA_THRESHOLD) { typedef Eigen::Matrix ZZM; typedef Eigen::Matrix ZDM; typedef Eigen::Matrix XEM; //typedef Eigen::Matrix EZM; typedef Eigen::Matrix X1M; typedef Eigen::Matrix XXM; double in_hx[ZDIM] = {0}; double in_H[ZDIM * DIM] = {0}; double in_H_mod[EDIM * DIM] = {0}; double delta_x[EDIM] = {0}; double x_new[DIM] = {0}; // state x, P Eigen::Matrix z(in_z); EEM P(in_P); ZZM pre_R(in_R); // functions from sympy h_fun(in_x, in_ea, in_hx); H_fun(in_x, in_ea, in_H); ZDM pre_H(in_H); // get y (y = z - hx) Eigen::Matrix pre_y(in_hx); pre_y = z - pre_y; X1M y; XXM H; XXM R; if (Hea_fun){ typedef Eigen::Matrix ZAM; double in_Hea[ZDIM * EADIM] = {0}; Hea_fun(in_x, in_ea, in_Hea); ZAM Hea(in_Hea); XXM A = Hea.transpose().fullPivLu().kernel(); y = A.transpose() * pre_y; H = A.transpose() * pre_H; R = A.transpose() * pre_R * A; } else { y = pre_y; H = pre_H; R = pre_R; } // get modified H H_mod_fun(in_x, in_H_mod); DEM H_mod(in_H_mod); XEM H_err = H * H_mod; // Do mahalobis distance test if (MAHA_TEST){ XXM a = (H_err * P * H_err.transpose() + R).inverse(); double maha_dist = y.transpose() * a * y; if (maha_dist > MAHA_THRESHOLD){ R = 1.0e16 * R; } } // Outlier resilient weighting double weight = 1;//(1.5)/(1 + y.squaredNorm()/R.sum()); // kalman gains and I_KH XXM S = ((H_err * P) * H_err.transpose()) + R/weight; XEM KT = S.fullPivLu().solve(H_err * P.transpose()); //EZM K = KT.transpose(); TODO: WHY DOES THIS NOT COMPILE? //EZM K = S.fullPivLu().solve(H_err * P.transpose()).transpose(); //std::cout << "Here is the matrix rot:\n" << K << std::endl; EEM I_KH = Eigen::Matrix::Identity() - (KT.transpose() * H_err); // update state by injecting dx Eigen::Matrix dx(delta_x); dx = (KT.transpose() * y); memcpy(delta_x, dx.data(), EDIM * sizeof(double)); err_fun(in_x, delta_x, x_new); Eigen::Matrix x(x_new); // update cov P = ((I_KH * P) * I_KH.transpose()) + ((KT.transpose() * R) * KT); // copy out state memcpy(in_x, x.data(), DIM * sizeof(double)); memcpy(in_P, P.data(), EDIM * EDIM * sizeof(double)); memcpy(in_z, y.data(), y.rows() * sizeof(double)); } } extern "C" { void car_update_25(double *in_x, double *in_P, double *in_z, double *in_R, double *in_ea) { update<1, 3, 0>(in_x, in_P, h_25, H_25, NULL, in_z, in_R, in_ea, MAHA_THRESH_25); } void car_update_24(double *in_x, double *in_P, double *in_z, double *in_R, double *in_ea) { update<2, 3, 0>(in_x, in_P, h_24, H_24, NULL, in_z, in_R, in_ea, MAHA_THRESH_24); } void car_update_30(double *in_x, double *in_P, double *in_z, double *in_R, double *in_ea) { update<1, 3, 0>(in_x, in_P, h_30, H_30, NULL, in_z, in_R, in_ea, MAHA_THRESH_30); } void car_update_26(double *in_x, double *in_P, double *in_z, double *in_R, double *in_ea) { update<1, 3, 0>(in_x, in_P, h_26, H_26, NULL, in_z, in_R, in_ea, MAHA_THRESH_26); } void car_update_27(double *in_x, double *in_P, double *in_z, double *in_R, double *in_ea) { update<1, 3, 0>(in_x, in_P, h_27, H_27, NULL, in_z, in_R, in_ea, MAHA_THRESH_27); } void car_update_29(double *in_x, double *in_P, double *in_z, double *in_R, double *in_ea) { update<1, 3, 0>(in_x, in_P, h_29, H_29, NULL, in_z, in_R, in_ea, MAHA_THRESH_29); } void car_update_28(double *in_x, double *in_P, double *in_z, double *in_R, double *in_ea) { update<1, 3, 0>(in_x, in_P, h_28, H_28, NULL, in_z, in_R, in_ea, MAHA_THRESH_28); } void car_update_31(double *in_x, double *in_P, double *in_z, double *in_R, double *in_ea) { update<1, 3, 0>(in_x, in_P, h_31, H_31, NULL, in_z, in_R, in_ea, MAHA_THRESH_31); } void car_err_fun(double *nom_x, double *delta_x, double *out_1814247348247547720) { err_fun(nom_x, delta_x, out_1814247348247547720); } void car_inv_err_fun(double *nom_x, double *true_x, double *out_2896416663387818009) { inv_err_fun(nom_x, true_x, out_2896416663387818009); } void car_H_mod_fun(double *state, double *out_3833245775098430450) { H_mod_fun(state, out_3833245775098430450); } void car_f_fun(double *state, double dt, double *out_3477590770207651617) { f_fun(state, dt, out_3477590770207651617); } void car_F_fun(double *state, double dt, double *out_3058811064297665734) { F_fun(state, dt, out_3058811064297665734); } void car_h_25(double *state, double *unused, double *out_845892813044312576) { h_25(state, unused, out_845892813044312576); } void car_H_25(double *state, double *unused, double *out_6744590887944551998) { H_25(state, unused, out_6744590887944551998); } void car_h_24(double *state, double *unused, double *out_410909672515548225) { h_24(state, unused, out_410909672515548225); } void car_H_24(double *state, double *unused, double *out_673800745732374895) { H_24(state, unused, out_673800745732374895); } void car_h_30(double *state, double *unused, double *out_8727165463798361761) { h_30(state, unused, out_8727165463798361761); } void car_H_30(double *state, double *unused, double *out_7174456855637391420) { H_30(state, unused, out_7174456855637391420); } void car_h_26(double *state, double *unused, double *out_2811534710064499425) { h_26(state, unused, out_2811534710064499425); } void car_H_26(double *state, double *unused, double *out_7960649866890943394) { H_26(state, unused, out_7960649866890943394); } void car_h_27(double *state, double *unused, double *out_4116487184636980656) { h_27(state, unused, out_4116487184636980656); } void car_H_27(double *state, double *unused, double *out_9048693146888216979) { H_27(state, unused, out_9048693146888216979); } void car_h_29(double *state, double *unused, double *out_1915699176115514220) { h_29(state, unused, out_1915699176115514220); } void car_H_29(double *state, double *unused, double *out_7684688199951783604) { H_29(state, unused, out_7684688199951783604); } void car_h_28(double *state, double *unused, double *out_6496658557271199005) { h_28(state, unused, out_6496658557271199005); } void car_H_28(double *state, double *unused, double *out_2602289182882253030) { H_28(state, unused, out_2602289182882253030); } void car_h_31(double *state, double *unused, double *out_9104190579401499048) { h_31(state, unused, out_9104190579401499048); } void car_H_31(double *state, double *unused, double *out_7334441764657591918) { H_31(state, unused, out_7334441764657591918); } void car_predict(double *in_x, double *in_P, double *in_Q, double dt) { predict(in_x, in_P, in_Q, dt); } void car_set_mass(double x) { set_mass(x); } void car_set_rotational_inertia(double x) { set_rotational_inertia(x); } void car_set_center_to_front(double x) { set_center_to_front(x); } void car_set_center_to_rear(double x) { set_center_to_rear(x); } void car_set_stiffness_front(double x) { set_stiffness_front(x); } void car_set_stiffness_rear(double x) { set_stiffness_rear(x); } } const EKF car = { .name = "car", .kinds = { 25, 24, 30, 26, 27, 29, 28, 31 }, .feature_kinds = { }, .f_fun = car_f_fun, .F_fun = car_F_fun, .err_fun = car_err_fun, .inv_err_fun = car_inv_err_fun, .H_mod_fun = car_H_mod_fun, .predict = car_predict, .hs = { { 25, car_h_25 }, { 24, car_h_24 }, { 30, car_h_30 }, { 26, car_h_26 }, { 27, car_h_27 }, { 29, car_h_29 }, { 28, car_h_28 }, { 31, car_h_31 }, }, .Hs = { { 25, car_H_25 }, { 24, car_H_24 }, { 30, car_H_30 }, { 26, car_H_26 }, { 27, car_H_27 }, { 29, car_H_29 }, { 28, car_H_28 }, { 31, car_H_31 }, }, .updates = { { 25, car_update_25 }, { 24, car_update_24 }, { 30, car_update_30 }, { 26, car_update_26 }, { 27, car_update_27 }, { 29, car_update_29 }, { 28, car_update_28 }, { 31, car_update_31 }, }, .Hes = { }, .sets = { { "mass", car_set_mass }, { "rotational_inertia", car_set_rotational_inertia }, { "center_to_front", car_set_center_to_front }, { "center_to_rear", car_set_center_to_rear }, { "stiffness_front", car_set_stiffness_front }, { "stiffness_rear", car_set_stiffness_rear }, }, .extra_routines = { }, }; ekf_lib_init(car)