MOD: remove static variables

2024-11-15 22:34:58 +00:00 · 2023-03-09 23:52:05 +01:00 · 2023-03-09 23:52:05 +01:00 · 5b44ec9965
commit 5b44ec9965
parent 40d3e96902
5 changed files with 121 additions and 111 deletions
--- a/src/algorithms/PVT/libs/rtklib_solver.cc
+++ b/src/algorithms/PVT/libs/rtklib_solver.cc
@ -2091,11 +2091,11 @@ bool Rtklib_Solver::get_PVT(const std::map<int, Gnss_Synchro> &gnss_observables_
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
                                        // User clock offset [s]
                                        //tmp_double = rx_position_and_time[3];
-                                        tmp_double = vtl_data.get_user_clock_offset_s();
+                                        tmp_double = vtl_engine.get_user_clock_offset_s();
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
                                        // ECEF POS X,Y,X [m] + ECEF VEL X,Y,X [m/s] + ECEF ACC X,Y,X [m/s] (9 x double)
-                                        std::vector<double> p_vec_m = vtl_data.get_position_ecef_m();
+                                        std::vector<double> p_vec_m = vtl_engine.get_position_ecef_m();
                                        tmp_double = p_vec_m[0];
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
                                        tmp_double = p_vec_m[1];
@ -2103,7 +2103,7 @@ bool Rtklib_Solver::get_PVT(const std::map<int, Gnss_Synchro> &gnss_observables_
                                        tmp_double = p_vec_m[2];
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
-                                        std::vector<double>  v_vec_m = vtl_data.get_velocity_ecef_m_s();
+                                        std::vector<double>  v_vec_m = vtl_engine.get_velocity_ecef_m_s();
                                        tmp_double = v_vec_m[0];
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
                                        tmp_double = v_vec_m[1];
@ -2111,7 +2111,7 @@ bool Rtklib_Solver::get_PVT(const std::map<int, Gnss_Synchro> &gnss_observables_
                                        tmp_double = v_vec_m[2];
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
-                                        std::vector<double>  a_vec_m = vtl_data.get_accel_ecef_m_s2();
+                                        std::vector<double>  a_vec_m = vtl_engine.get_accel_ecef_m_s2();
                                        tmp_double = a_vec_m[0];
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
                                        tmp_double = a_vec_m[1];
@ -2121,7 +2121,7 @@ bool Rtklib_Solver::get_PVT(const std::map<int, Gnss_Synchro> &gnss_observables_
                                        // position/velocity/acceleration variance/ (units^2)  (9 x double)
-                                        std::vector<double>  p_var_vec_m = vtl_data.get_position_var_ecef_m();
+                                        std::vector<double>  p_var_vec_m = vtl_engine.get_position_var_ecef_m();
                                        tmp_double = p_var_vec_m[0];
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
                                        tmp_double = p_var_vec_m[1];
@ -2130,7 +2130,7 @@ bool Rtklib_Solver::get_PVT(const std::map<int, Gnss_Synchro> &gnss_observables_
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
-                                        std::vector<double>  v_var_vec_m = vtl_data.get_velocity_var_ecef_m_s();
+                                        std::vector<double>  v_var_vec_m = vtl_engine.get_velocity_var_ecef_m_s();
                                        tmp_double = v_var_vec_m[0];
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
                                        tmp_double = v_var_vec_m[1];
@ -2138,7 +2138,7 @@ bool Rtklib_Solver::get_PVT(const std::map<int, Gnss_Synchro> &gnss_observables_
                                        tmp_double = v_var_vec_m[2];
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
-                                        vector<double>  a_var_vec_m = vtl_data.get_accel_var_ecef_m_s2();
+                                        vector<double>  a_var_vec_m = vtl_engine.get_accel_var_ecef_m_s2();
                                        tmp_double = a_var_vec_m[0];
                                        d_vtl_dump_file.write(reinterpret_cast<char *>(&tmp_double), sizeof(double));
                                        tmp_double = a_var_vec_m[1];
--- a/src/algorithms/PVT/libs/vtl_data.cc
+++ b/src/algorithms/PVT/libs/vtl_data.cc
@ -23,8 +23,6 @@ Vtl_Data::Vtl_Data()
 {
    epoch_tow_s = 0;
    sample_counter = 0;
    kf_state = arma::mat(11,1);
    kf_P = arma::mat(11,11);
 }
 void Vtl_Data::init_storage(int n_sats)
@ -69,88 +67,4 @@ void Vtl_Data::debug_print()
    // carrier_phase_rads.print("satellite accumulated carrier phases [rads]");
 }
 std::vector<double> Vtl_Data::get_position_ecef_m()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_state[0];
    temp[1] = kf_state[1];
    temp[2] = kf_state[2];
    return temp;
 }
 std::vector<double> Vtl_Data::get_velocity_ecef_m_s()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_state[3];
    temp[1] = kf_state[4];
    temp[2] = kf_state[5];
    return temp;
 }
 std::vector<double> Vtl_Data::get_accel_ecef_m_s2()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_state[6];
    temp[1] = kf_state[7];
    temp[2] = kf_state[8];
    return temp;
 }
 std::vector<double> Vtl_Data::get_position_var_ecef_m()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_P(0,0);
    temp[1] = kf_P(1,1);
    temp[2] = kf_P(2,2);
    return temp;
 }
 std::vector<double> Vtl_Data::get_velocity_var_ecef_m_s()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_P(3,3);
    temp[1] = kf_P(4,4);
    temp[2] = kf_P(5,5);
    return temp;
 }
 std::vector<double> Vtl_Data::get_accel_var_ecef_m_s2()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_P(6,6);
    temp[1] = kf_P(7,7);
    temp[2] = kf_P(8,8);
    return temp;
 }
 double Vtl_Data::get_latitude()
 {
    return -1.0;
 }
 double Vtl_Data::get_longitude()
 {
    return -1.0;
 }
 double Vtl_Data::get_height()
 {
    return -1.0;
 }
 double Vtl_Data::get_user_clock_offset_s()
 {
    double temp=0;
    temp=kf_state[9];
    return temp;
 }
--- a/src/algorithms/PVT/libs/vtl_data.h
+++ b/src/algorithms/PVT/libs/vtl_data.h
@ -62,16 +62,6 @@ public:
    double epoch_tow_s;       // current observation RX time [s]
    uint64_t sample_counter;  // current sample counter associated with RX time [samples from start]
    void debug_print();
    std::vector<double> get_position_ecef_m();   // get_position_ecef_m
    std::vector<double> get_velocity_ecef_m_s(); // get_velocity_ecef_m_s
    std::vector<double> get_accel_ecef_m_s2(); // get_accel_ecef_m_s2
    std::vector<double> get_position_var_ecef_m(); // get_position_var_ecef_m
    std::vector<double> get_velocity_var_ecef_m_s(); // get_velocity_var_ecef_m_s
    std::vector<double> get_accel_var_ecef_m_s2(); // get_accel_var_ecef_m_s2
    double get_latitude(); // get_latitude
    double get_longitude(); // get_longitude
    double get_height(); // get_height
    double get_user_clock_offset_s(); // get_user_clock_offset_s;
 };
--- a/src/algorithms/PVT/libs/vtl_engine.cc
+++ b/src/algorithms/PVT/libs/vtl_engine.cc
@ -22,25 +22,31 @@ using namespace std;
 Vtl_Engine::Vtl_Engine()
 {
    counter=0;
    refSampleCounter=0;
    n_of_states=11;
    kf_P_x = arma::eye(n_of_states, n_of_states) * 1.0;  //TODO: use a real value.; 
    kf_x = arma::zeros(n_of_states, 1);
 }
 Vtl_Engine::~Vtl_Engine()
 {
 }
-bool Vtl_Engine::vtl_loop(Vtl_Data& new_data)
+bool Vtl_Engine::vtl_loop(Vtl_Data new_data)
 {
    //TODO: Implement main VTL loop here
    using arma::as_scalar;
-    static uint64_t refSampleCounter = new_data.sample_counter;
+    if (refSampleCounter=0)
    {
        refSampleCounter=new_data.sample_counter;
    } 
    double delta_t_vtl = (new_data.sample_counter - refSampleCounter) / 5000000.0; 
    refSampleCounter = new_data.sample_counter;
    // ################## Kalman filter initialization ######################################
    //State variables
-    int n_of_states=11;
+
    static arma::mat kf_P_x = arma::eye(n_of_states, n_of_states) * 1.0;  //TODO: use a real value.; 
    static arma::mat kf_x = arma::zeros(n_of_states, 1);
    arma::mat kf_dx = arma::zeros(n_of_states, 1);
    // covariances (static)
@ -58,8 +64,7 @@ bool Vtl_Engine::vtl_loop(Vtl_Data& new_data)
    kf_S = arma::zeros(2 * new_data.sat_number, 2 * new_data.sat_number);  // kf_P_y innovation covariance matrix
    kf_K = arma::zeros(n_of_states, 2 * new_data.sat_number); ;
    // ################## Kalman Tracking ######################################
-    static uint32_t counter = 0;  //counter
+    counter++;        //uint64_t
    counter = counter + 1;        //uint64_t
    //new_data.kf_state.print("new_data kf initial");
    uint32_t closure_point=3;
@ -339,3 +344,88 @@ bool Vtl_Engine::kf_measurements(arma::mat &kf_yerr, int sat_number, arma::mat r
    }
    return -1;
 }
 std::vector<double> Vtl_Engine::get_position_ecef_m()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_x[0];
    temp[1] = kf_x[1];
    temp[2] = kf_x[2];
    return temp;
 }
 std::vector<double> Vtl_Engine::get_velocity_ecef_m_s()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_x[3];
    temp[1] = kf_x[4];
    temp[2] = kf_x[5];
    return temp;
 }
 std::vector<double> Vtl_Engine::get_accel_ecef_m_s2()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_x[6];
    temp[1] = kf_x[7];
    temp[2] = kf_x[8];
    return temp;
 }
 std::vector<double> Vtl_Engine::get_position_var_ecef_m()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_P_x(0,0);
    temp[1] = kf_P_x(1,1);
    temp[2] = kf_P_x(2,2);
    return temp;
 }
 std::vector<double> Vtl_Engine::get_velocity_var_ecef_m_s()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_P_x(3,3);
    temp[1] = kf_P_x(4,4);
    temp[2] = kf_P_x(5,5);
    return temp;
 }
 std::vector<double> Vtl_Engine::get_accel_var_ecef_m_s2()
 {
    std::vector<double> temp = {42,42,42};
    temp[0] = kf_P_x(6,6);
    temp[1] = kf_P_x(7,7);
    temp[2] = kf_P_x(8,8);
    return temp;
 }
 double Vtl_Engine::get_latitude()
 {
    return -1.0;
 }
 double Vtl_Engine::get_longitude()
 {
    return -1.0;
 }
 double Vtl_Engine::get_height()
 {
    return -1.0;
 }
 double Vtl_Engine::get_user_clock_offset_s()
 {
    double temp=0;
    temp = kf_x[9];
    return temp;
 }
--- a/src/algorithms/PVT/libs/vtl_engine.h
+++ b/src/algorithms/PVT/libs/vtl_engine.h
@ -42,11 +42,21 @@ public:
    void configure(Vtl_Conf config_);  //set config parameters
    //TODO: output functions here (output for tracking KF updates, VTL computed user PVT, etc...)
-    bool vtl_loop(Vtl_Data& new_data);
+    bool vtl_loop(Vtl_Data new_data);
    void reset();        // reset all internal states
    void debug_print();  // print debug information
    std::vector<TrackingCmd> trk_cmd_outs;  // vector holding the Tracking command states updates to be sent to tracking KFs
    std::vector<double> get_position_ecef_m();   // get_position_ecef_m
    std::vector<double> get_velocity_ecef_m_s(); // get_velocity_ecef_m_s
    std::vector<double> get_accel_ecef_m_s2(); // get_accel_ecef_m_s2
    std::vector<double> get_position_var_ecef_m(); // get_position_var_ecef_m
    std::vector<double> get_velocity_var_ecef_m_s(); // get_velocity_var_ecef_m_s
    std::vector<double> get_accel_var_ecef_m_s2(); // get_accel_var_ecef_m_s2
    double get_latitude(); // get_latitude
    double get_longitude(); // get_longitude
    double get_height(); // get_height
    double get_user_clock_offset_s(); // get_user_clock_offset_s;    
 private:
    Vtl_Conf config;
@ -67,6 +77,7 @@ private:
    arma::mat kf_P_x_ini;  // initial state error covariance matrix
    // arma::mat kf_P_x;      // state error covariance matrix
    arma::mat kf_P_x_pre;  // Predicted state error covariance matrix
    arma::mat kf_P_x;
    arma::mat kf_S;      // innovation covariance matrix
    arma::mat kf_F;  // state transition matrix
@ -84,6 +95,11 @@ private:
    // Gaussian estimator
    arma::mat kf_R_est;  // measurement error covariance
    uint32_t counter;
    int n_of_states;
    uint64_t refSampleCounter;
    bool kf_H_fill(arma::mat &kf_H, int sat_number, arma::colvec ax, arma::colvec ay, arma::colvec az, double kf_dt); // Observation Matrix constructor
    bool kf_F_fill(arma::mat &kf_F,double kf_dt); // System Matrix constructor
    bool obsv_calc(arma::mat &rho_pri,arma::mat &rhoDot_pri,arma::colvec &ax, arma::colvec &ay, arma::colvec &az,int sat_number,arma::mat sat_p,arma::mat sat_v,arma::mat kf_x); // Observables calculation