#include "mcu_wrapper_conf.h"
#include "pwm_sim.h"
T_project project = {0};
WINDING a;
EDRK edrk = EDRK_DEFAULT;
FLAG f = FLAG_DEFAULTS;
//X_PARALLEL_BUS x_parallel_bus_project = X_PARALLEL_BUS_DEFAULTS;
//int Unites2SecondBS[SIZE_ARR_CAN_UNITES_BS2BS] = { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,\
// 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,\
// 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,\
// 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0\
//};
//LOGSPARAMS logpar = LOGSPARAMS_DEFAULTS;
//OPTICAL_BUS_DATA optical_write_data = OPTICAL_BUS_DATA_DEFAULT;
//OPTICAL_BUS_DATA optical_read_data = OPTICAL_BUS_DATA_DEFAULT;
//SYNC_TOOLS_DATA sync_data = SYNC_TOOLS_DATA_DEFAULT;
//int flag_enable_can_from_mpu = 0;
//UNITES_CAN_SETUP unites_can_setup = UNITES_CAN_SETUP_DEFAULT;
//OSCIL_CAN oscil_can = OSCIL_CAN_DEFAULTS;
//int flag_special_mode_rs = 0;
//ALARM_LOG_CAN alarm_log_can = ALARM_LOG_CAN_CAN_DEFAULTS;
WRotorValues WRotor = WRotorValues_DEFAULTS;
WRotorValuesAngle WRotorPBus = WRotorValuesAngle_DEFAULTS;
void mcu_simulate_step(void)
{
int ff = 0;
static _iq Uzad1 = 0, Fzad = 0, Uzad2 = 0, Izad_out = 0, Uzad_from_master = 0;
int pwm_enable_calc_main;
_iq wd;
if (edrk.flag_second_PCH == 0) {
wd = uf_alg.winding_displacement_bs1;
}
else {
wd = uf_alg.winding_displacement_bs2;
}
detect_level_interrupt();
if (xpwm_time.where_interrupt == PWM_LOW_LEVEL_INTERRUPT ||
xpwm_time.one_or_two_interrupts_run == PWM_ONE_INTERRUPT_RUN)
{
pwm_enable_calc_main = 1;
}
else
{
pwm_enable_calc_main = 0;
}
ramp_all_zadanie(0); // ��� ��� �� ��������
calc_norm_ADC(0);
if (edrk.Mode_ScalarVectorUFConst == ALG_MODE_SCALAR_OBOROTS || edrk.Mode_ScalarVectorUFConst == ALG_MODE_SCALAR_POWER)
{
#if(_ENABLE_PWM_LINES_FOR_TESTS_PWM)
PWM_LINES_TK_20_ON;
#endif
simple_scalar(1, 0,
WRotor.iqWRotorCalcBeforeRegul1, WRotor.iqWRotorCalcBeforeRegul1, edrk.zadanie.iq_oborots_zad_hz_rmp,
edrk.temper_limit_koeffs.sum_limit,
edrk.zadanie.iq_Izad_rmp, edrk.iq_bpsi_normal,
analog.iqIm,
// analog.iqU_1_long+analog.iqU_2_long,
edrk.zadanie.iq_ZadanieU_Charge_rmp + edrk.zadanie.iq_ZadanieU_Charge_rmp,
analog.iqIin_sum,
edrk.zadanie.iq_power_zad_rmp, (filter.PowerScalar + edrk.iq_power_kw_another_bs),
edrk.master_Izad, edrk.MasterSlave,
&Fzad, &Uzad1, &Uzad2, &Izad_out);
test_calc_simple_dq_pwm24_Ing(Fzad, Uzad1, edrk.disable_alg_u_disbalance,
edrk.zadanie.iq_kplus_u_disbalance, edrk.zadanie.iq_k_u_disbalance, filter.iqU_1_fast, filter.iqU_2_fast,
0,
edrk.Uzad_max,
edrk.master_theta,
Uzad1, //edrk.master_Uzad,
edrk.MasterSlave,
edrk.flag_second_PCH,
&edrk.Kplus, &edrk.tetta_to_slave, &edrk.Uzad_to_slave);
} // end ALG_MODE_SCALAR
else
{
if (edrk.flag_second_PCH == 0) {
wd = uf_alg.winding_displacement_bs1;
}
else {
wd = uf_alg.winding_displacement_bs2;
}
analog_dq_calc_external(wd, uf_alg.tetta);
vectorControlConstId(edrk.zadanie.iq_power_zad_rmp, edrk.zadanie.iq_oborots_zad_hz_rmp,
WRotorPBus.RotorDirection1, WRotor.iqWRotorCalcBeforeRegul1,
edrk.Mode_ScalarVectorUFConst,
edrk.MasterSlave, edrk.zadanie.iq_Izad, wd,
edrk.master_theta, edrk.master_Iq, edrk.iq_power_kw_another_bs,
&edrk.tetta_to_slave, &edrk.Iq_to_slave, &edrk.P_to_master,
0, 0);
test_calc_vect_dq_pwm24_Ing(vect_control.iqTheta, vect_control.iqUdKm, vect_control.iqUqKm,
edrk.disable_alg_u_disbalance,
edrk.zadanie.iq_kplus_u_disbalance_rmp, edrk.zadanie.iq_k_u_disbalance_rmp,
filter.iqU_1_fast, filter.iqU_2_fast,
0,
edrk.Uzad_max,
edrk.MasterSlave,
edrk.flag_second_PCH,
&edrk.Kplus, &edrk.Uzad_to_slave);
analog.PowerFOC = edrk.P_to_master;
Fzad = vect_control.iqFstator;
Izad_out = edrk.Iq_to_slave;
}// end ALG_MODE_FOC
if (xpwm_time.one_or_two_interrupts_run == PWM_ONE_INTERRUPT_RUN)
write_swgen_pwm_times(PWM_MODE_RELOAD_FORCE);
else
{
if (pwm_enable_calc_main)
write_swgen_pwm_times(PWM_MODE_RELOAD_LEVEL_HIGH);
else
write_swgen_pwm_times(PWM_MODE_RELOAD_LEVEL_LOW);
}
}
void init_ramp_all_zadanie(void)
{
_iq rampafloat;
// rmp_fzad
edrk.zadanie.rmp_fzad.RampLowLimit = _IQ(-MAX_ZADANIE_F / NORMA_FROTOR); //0
edrk.zadanie.rmp_fzad.RampHighLimit = _IQ(MAX_ZADANIE_F / NORMA_FROTOR);
rampafloat = _IQ(1.0 / (2.0 * FREQ_PWM * T_NARAST_ZADANIE_F));
edrk.zadanie.rmp_fzad.RampPlus = rampafloat;
edrk.zadanie.rmp_fzad.RampMinus = -rampafloat;
edrk.zadanie.rmp_fzad.DesiredInput = 0;
edrk.zadanie.rmp_fzad.Out = 0;
// rmp_oborots_hz
edrk.zadanie.rmp_oborots_zad_hz.RampLowLimit = _IQ(MIN_ZADANIE_OBOROTS_ROTOR / 60.0 / NORMA_FROTOR); //0
edrk.zadanie.rmp_oborots_zad_hz.RampHighLimit = _IQ(MAX_ZADANIE_OBOROTS_ROTOR / 60.0 / NORMA_FROTOR);
rampafloat = _IQ(1.0 / (2.0 * FREQ_PWM * T_NARAST_ZADANIE_OBOROTS_ROTOR));
edrk.zadanie.rmp_oborots_zad_hz.RampPlus = rampafloat;
edrk.zadanie.rmp_oborots_zad_hz.RampMinus = -rampafloat;
edrk.zadanie.rmp_oborots_zad_hz.DesiredInput = 0;
edrk.zadanie.rmp_oborots_zad_hz.Out = 0;
//
edrk.zadanie.rmp_Izad.RampLowLimit = _IQ(0); //0
edrk.zadanie.rmp_Izad.RampHighLimit = _IQ(MAX_ZADANIE_I_M / NORMA_ACP);
rampafloat = _IQ(1.0 / (2.0 * FREQ_PWM * T_NARAST_ZADANIE_I_M));
edrk.zadanie.rmp_Izad.RampPlus = rampafloat;
edrk.zadanie.rmp_Izad.RampMinus = -rampafloat;
edrk.zadanie.rmp_Izad.DesiredInput = 0;
edrk.zadanie.rmp_Izad.Out = 0;
//
edrk.zadanie.rmp_ZadanieU_Charge.RampLowLimit = _IQ(0); //0
edrk.zadanie.rmp_ZadanieU_Charge.RampHighLimit = _IQ(MAX_ZADANIE_U_CHARGE / NORMA_ACP);
rampafloat = _IQ(1.0 / (2.0 * FREQ_PWM * T_NARAST_ZADANIE_U_CHARGE));
edrk.zadanie.rmp_ZadanieU_Charge.RampPlus = rampafloat;
edrk.zadanie.rmp_ZadanieU_Charge.RampMinus = -rampafloat;
edrk.zadanie.rmp_ZadanieU_Charge.DesiredInput = 0;
edrk.zadanie.rmp_ZadanieU_Charge.Out = 0;
//
edrk.zadanie.rmp_k_u_disbalance.RampLowLimit = _IQ(0); //0
edrk.zadanie.rmp_k_u_disbalance.RampHighLimit = _IQ(MAX_ZADANIE_K_U_DISBALANCE);
rampafloat = _IQ(1.0 / (2.0 * FREQ_PWM * T_NARAST_ZADANIE_K_U_DISBALANCE));
edrk.zadanie.rmp_k_u_disbalance.RampPlus = rampafloat;
edrk.zadanie.rmp_k_u_disbalance.RampMinus = -rampafloat;
edrk.zadanie.rmp_k_u_disbalance.DesiredInput = 0;
edrk.zadanie.rmp_k_u_disbalance.Out = 0;
//
edrk.zadanie.rmp_kplus_u_disbalance.RampLowLimit = _IQ(0); //0
edrk.zadanie.rmp_kplus_u_disbalance.RampHighLimit = _IQ(MAX_ZADANIE_KPLUS_U_DISBALANCE);
rampafloat = _IQ(1.0 / (2.0 * FREQ_PWM * T_NARAST_ZADANIE_KPLUS_U_DISBALANCE));
edrk.zadanie.rmp_kplus_u_disbalance.RampPlus = rampafloat;
edrk.zadanie.rmp_kplus_u_disbalance.RampMinus = -rampafloat;
edrk.zadanie.rmp_kplus_u_disbalance.DesiredInput = 0;
edrk.zadanie.rmp_kplus_u_disbalance.Out = 0;
//
edrk.zadanie.rmp_kzad.RampLowLimit = _IQ(0); //0
edrk.zadanie.rmp_kzad.RampHighLimit = _IQ(MAX_ZADANIE_K_M);
rampafloat = _IQ(1.0 / (2.0 * FREQ_PWM * T_NARAST_ZADANIE_K_M));
edrk.zadanie.rmp_kzad.RampPlus = rampafloat;
edrk.zadanie.rmp_kzad.RampMinus = -rampafloat;
edrk.zadanie.rmp_kzad.DesiredInput = 0;
edrk.zadanie.rmp_kzad.Out = 0;
//
edrk.zadanie.rmp_powers_zad.RampLowLimit = _IQ(MIN_ZADANIE_POWER * 1000.0 / (NORMA_MZZ * NORMA_MZZ)); //0
edrk.zadanie.rmp_powers_zad.RampHighLimit = _IQ(MAX_ZADANIE_POWER * 1000.0 / (NORMA_MZZ * NORMA_MZZ));
rampafloat = _IQ(1.0 / (2.0 * FREQ_PWM * T_NARAST_ZADANIE_POWER));
edrk.zadanie.rmp_powers_zad.RampPlus = rampafloat;
edrk.zadanie.rmp_powers_zad.RampMinus = -rampafloat;
edrk.zadanie.rmp_powers_zad.DesiredInput = 0;
edrk.zadanie.rmp_powers_zad.Out = 0;
//
edrk.zadanie.rmp_limit_powers_zad.RampLowLimit = _IQ(0); //0
edrk.zadanie.rmp_limit_powers_zad.RampHighLimit = _IQ(MAX_ZADANIE_POWER * 1000.0 / (NORMA_MZZ * NORMA_MZZ));
rampafloat = _IQ(1.0 / (2.0 * FREQ_PWM * T_NARAST_ZADANIE_POWER));
edrk.zadanie.rmp_limit_powers_zad.RampPlus = rampafloat;
edrk.zadanie.rmp_limit_powers_zad.RampMinus = -rampafloat;
edrk.zadanie.rmp_limit_powers_zad.DesiredInput = 0;
edrk.zadanie.rmp_limit_powers_zad.Out = 0;
//
}
void ramp_all_zadanie(int flag_set_zero)
{
//////////////////////////////////////////////
if (flag_set_zero == 0)
edrk.zadanie.rmp_Izad.DesiredInput = edrk.zadanie.iq_Izad;
else
if (flag_set_zero == 2)
{
edrk.zadanie.rmp_Izad.DesiredInput = 0;
edrk.zadanie.rmp_Izad.Out = 0;
}
else
edrk.zadanie.rmp_Izad.DesiredInput = 0;
edrk.zadanie.rmp_Izad.calc(&edrk.zadanie.rmp_Izad);
edrk.zadanie.iq_Izad_rmp = edrk.zadanie.rmp_Izad.Out;
//////////////////////////////////////////////
edrk.zadanie.rmp_ZadanieU_Charge.DesiredInput = edrk.zadanie.iq_ZadanieU_Charge;
edrk.zadanie.rmp_ZadanieU_Charge.calc(&edrk.zadanie.rmp_ZadanieU_Charge);
edrk.zadanie.iq_ZadanieU_Charge_rmp = edrk.zadanie.rmp_ZadanieU_Charge.Out;
//////////////////////////////////////////////
if (flag_set_zero == 0)
edrk.zadanie.rmp_fzad.DesiredInput = edrk.zadanie.iq_fzad;
else
if (flag_set_zero == 2)
{
edrk.zadanie.rmp_fzad.DesiredInput = 0;
edrk.zadanie.rmp_fzad.Out = 0;
}
else
edrk.zadanie.rmp_fzad.DesiredInput = 0;
edrk.zadanie.rmp_fzad.calc(&edrk.zadanie.rmp_fzad);
edrk.zadanie.iq_fzad_rmp = edrk.zadanie.rmp_fzad.Out;
//////////////////////////////////////////////
edrk.zadanie.rmp_k_u_disbalance.DesiredInput = edrk.zadanie.iq_k_u_disbalance;
edrk.zadanie.rmp_k_u_disbalance.calc(&edrk.zadanie.rmp_k_u_disbalance);
edrk.zadanie.iq_k_u_disbalance_rmp = edrk.zadanie.rmp_k_u_disbalance.Out;
//////////////////////////////////////////////
edrk.zadanie.rmp_kplus_u_disbalance.DesiredInput = edrk.zadanie.iq_kplus_u_disbalance;
edrk.zadanie.rmp_kplus_u_disbalance.calc(&edrk.zadanie.rmp_kplus_u_disbalance);
edrk.zadanie.iq_kplus_u_disbalance_rmp = edrk.zadanie.rmp_kplus_u_disbalance.Out;
//////////////////////////////////////////////
if (flag_set_zero == 0)
edrk.zadanie.rmp_kzad.DesiredInput = edrk.zadanie.iq_kzad;
else
if (flag_set_zero == 2)
{
edrk.zadanie.rmp_kzad.DesiredInput = 0;
edrk.zadanie.rmp_kzad.Out = 0;
}
else
edrk.zadanie.rmp_kzad.DesiredInput = 0;
edrk.zadanie.rmp_kzad.calc(&edrk.zadanie.rmp_kzad);
edrk.zadanie.iq_kzad_rmp = edrk.zadanie.rmp_kzad.Out;
//////////////////////////////////////////////
if (flag_set_zero == 0)
edrk.zadanie.rmp_oborots_zad_hz.DesiredInput = edrk.zadanie.iq_oborots_zad_hz;
else
if (flag_set_zero == 2)
{
edrk.zadanie.rmp_oborots_zad_hz.DesiredInput = 0;
edrk.zadanie.rmp_oborots_zad_hz.Out = 0;
}
else
edrk.zadanie.rmp_oborots_zad_hz.DesiredInput = 0;
edrk.zadanie.rmp_oborots_zad_hz.calc(&edrk.zadanie.rmp_oborots_zad_hz);
edrk.zadanie.iq_oborots_zad_hz_rmp = edrk.zadanie.rmp_oborots_zad_hz.Out;
//////////////////////////////////////////////
if (flag_set_zero == 0)
edrk.zadanie.rmp_limit_powers_zad.DesiredInput = edrk.zadanie.iq_limit_power_zad;
else
if (flag_set_zero == 2)
{
edrk.zadanie.rmp_limit_powers_zad.DesiredInput = 0;
edrk.zadanie.rmp_limit_powers_zad.Out = 0;
}
else
edrk.zadanie.rmp_limit_powers_zad.DesiredInput = 0;
edrk.zadanie.rmp_limit_powers_zad.calc(&edrk.zadanie.rmp_limit_powers_zad);
edrk.zadanie.iq_limit_power_zad_rmp = edrk.zadanie.rmp_limit_powers_zad.Out;
//////////////////////////////////////////////
if (flag_set_zero == 0)
{
if (edrk.zadanie.iq_power_zad > edrk.zadanie.iq_limit_power_zad_rmp)
edrk.zadanie.rmp_powers_zad.DesiredInput = edrk.zadanie.iq_limit_power_zad_rmp;
else
edrk.zadanie.rmp_powers_zad.DesiredInput = edrk.zadanie.iq_power_zad;
}
else
if (flag_set_zero == 2)
{
edrk.zadanie.rmp_powers_zad.DesiredInput = 0;
edrk.zadanie.rmp_powers_zad.Out = 0;
}
else
edrk.zadanie.rmp_powers_zad.DesiredInput = 0;
edrk.zadanie.rmp_powers_zad.calc(&edrk.zadanie.rmp_powers_zad);
edrk.zadanie.iq_power_zad_rmp = edrk.zadanie.rmp_powers_zad.Out;
}
unsigned int ReadMemory(unsigned long addr)
{
unsigned int returnval = 0;
if (addr == ADR_SAW_VALUE)
returnval = t1sim.tcnt;
//return (*(volatile int *)(addr));
return returnval;
}
void WriteMemory(unsigned long addr, unsigned int data)
{
//(*(volatile int *)( addr )) = data;
}
void project_read_all_pbus2()
{
}
#pragma DATA_SECTION(break_result_1,".fast_vars");
_iq break_result_1 = 0;
#pragma DATA_SECTION(break_result_2,".fast_vars");
_iq break_result_2 = 0;
#pragma DATA_SECTION(break_result_3,".fast_vars");
_iq break_result_3 = 0;
#pragma DATA_SECTION(break_result_4,".fast_vars");
_iq break_result_4 = 0;
//void read_in_sensor_line1(T_cds_in_rotation_sensor *rs){
//
//}
//
//void read_in_sensor_line2(T_cds_in_rotation_sensor *rs){
//
//}
//void read_command_reg(T_cds_in_rotation_sensor *rs){
//
//}
//void write_command_reg(T_cds_in_rotation_sensor *rs){
//
//}
//void tune_sampling_time(T_rotation_sensor *rs){
//
//}
//void wait_for_registers_updated(T_cds_in_rotation_sensor *rs){
//
//}
//void read_direction_in_plane(T_cds_in_rotation_sensor *rs){
//
//}
//void sensor_set(T_rotation_sensor *rs)
//{
//
//}
//void sensor_read(T_rotation_sensor *rs)
//{
//
//}
//void update_sensors_data(T_rotation_sensor *rs)
//{
// // rs->in_plane.write.regs.comand_reg.bit.update_registers = 1;
// // write_command_reg(&rs->in_plane);
//// rs->in_plane.write.regs.comand_reg.bit.update_registers = 0;
//}
//void angle_sensor_read(T_cds_angle_sensor *as)
//{}
//
//void angle_plane_set(T_cds_angle_sensor *rs)
//{}
//void in_plane_set(T_cds_in_rotation_sensor* rs)
//{}
//
//void in_sensor_read1(T_cds_in_rotation_sensor *rs)
//{}
//
//void in_sensor_read2(T_cds_in_rotation_sensor *rs)
//{}
// unsigned int BWC_Started()
// {
// }
void start_pwm(void) {}
void stop_pwm(void) {}
int get_real_in_mbox(int a, int b) {}
void update_uom(void) {}
void inc_RS_timeout_cicle(void) {}
void inc_CAN_timeout_cicle(void) {}
void pause_1000(void) {}
int xerror(unsigned int er_ID, void* CallBackRef) {}
void func_unpack_answer_from_Ingeteam(unsigned int a) {}
void unpack_answer_from_MPU_SVU_CAN(unsigned int a) {}
void start_break_pwm() {}
void stop_break_pwm() {}
void stop_wdog() {}
void start_pwm_b() {}
void start_pwm_a() {}
void stop_pwm_b() {}
void stop_pwm_a() {}
void fillADClogs() {}
void break_resistor_managment_calc() {}
void break_resistor_managment_init() {}
void break_resistor_managment_update() {}
void break_resistor_recup_calc() {}
void break_resistor_set_closed() {}
void DetectI_Out_BreakFase() {}
void test_mem_limit() {}
void set_start_mem() {}
void getFastLogs() {}
void detect_I_M_overload() {}
void sync_inc_error() {}
void optical_bus_read() {}
void optical_bus_write(void){}
void i_led1_on_off(int i) {}
void modbus_table_can_in(void) {}
//void init_eva_timer2() {}
//void init_evb_timer3() {}
//void start_eva_timer2() {}
//void start_evb_timer3() {}
//int enable_er0_control() {}
//void i_led2_on_off() {}
//int InitXilinxSpartan2E(void (*int_handler)()) {}
//void start_int13_interrupt() {}
//void project_read_errors_controller() {}
//void project_run_init_all_plates() {}
//void calc_temper_acdrive() {}
//void calc_temper_edrk() {}
//void SendAll2SecondBS() {}
//void clear_errors() {}
//void clear_warnings() {}
//void detect_error_all() {}
//void read_plane_errors() {}
//void init_detect_overloads() {}
//void check_all_power_limits() {}
//void clear_mem() {}
//void modbusNetworkSharing() {}
//void modbusNetworkSharingCAN() {}
//void fillLogArea() {}
//void clear_table_remoute() {}
//void update_progress_load_hmi() {}
//void get_command_HMI() {}
//void update_svu_modbus_table() {}
//void calc_limit_overheat() {}
//void project_prepare_config() {}
//void pump_control() {}
//void start_wdog() {}
//void global_time_interrupt() {}
//void optical_bus_read_write_interrupt() {}
//void setup_sync_line() {}
//void setup_sync_int() {}
//void start_sync_interrupt() {}
//void rotorInit() {}
//void get_adr_pcb_controller() {}
//void InitCan() {}
//void CAN_cycle_send() {}
//int CAN_cycle_free(int box) {}
//int CAN_cycle_full_free(int box, int statistics_flag) {}
//int get_real_out_mbox(int type_box, int box) {}
//int CAN_may_be_send_cycle_fifo(void) {}
//void start_can_interrupt() {}
//void clear_modbus_table_in() {}
//void clear_modbus_table_out() {}
//void initModbusTable() {}
//void RS232_WorkingWith() {}
//void sbor_shema() {}
//void pwm_test_lines_start() {}
//void pwm_test_lines_stop() {}
//void KickDog() {}
void init_flag_a(void)
{
unsigned int i = 0;
int *pStr = (int*)&f;
for (i = 0; i < sizeof(f) / sizeof(int); i++) {
*(pStr + i) = 0;
}
}