code of robot bike
Dependencies: SDFileSystem mbed
Fork of Robot_Bicycle by
main.cpp
- Committer:
- YCTung
- Date:
- 2016-07-10
- Revision:
- 6:bd469c945e41
- Parent:
- 5:2290732b2782
- Child:
- 7:b8413464d111
File content as of revision 6:bd469c945e41:
#include "mbed.h" #include "SDFileSystem.h" #include "RobotServo.h" #include "SensorFusion.h" #include "SPI_9dSensor.h" #include "RobotBicycleConst.h" #include "ZTC.h" //************************************************// //**************** Wiring Map ********************// //CK3 PC_10 | PC_11 MI3||re PC_9 | PC_8 rw //MO3 PC_12 | PD_2 || |-----------------| // 3.3V | E5V ||rs |PB_8 D15 | PC_6 |TX6 // BOOT0 | GND ||ra |PB_9 D14 | PC_5 | // |---------------| || |AVDD | U5V | // |NC | NC | || |GND | NC | // |NC | IOREF | ||rk |PA_5 D13 | PA_12|RX6 // |PA_13 | NRST | || |PA_6 D12 | PA_11| rl // |PA_14 | 3.3V | || |PA_7 D11 | PB_12| // |PA_15 | 5.0V | ||rb |PB_6 D10 | NC | // |GND | GND | || |PC_7 D9 | GND | // |PB_7 | GND | ||lb |PA_9 D8 | PB_2 |CSG // |PC_13 | VIN | || |-----------------| // |---------------| || |-----------------| // PC_14 | NC ||ll |PA_8 D7 | PB_1 |CSX // |---------------| ||lk |PB_10 D6 | PB_15|MO2 // |PC_15 | PA_0 A0| ||la |PB_4 D5 | PB_14|MI2 // |PH_0 | PA_1 A1| ||ls |PB_5 D4 | PB_13|CK2 // |PH_1 | PA_4 A2| ||le |PB_3 D3 | AGND | // |VBAT | PB_0 A3| ||lw |PA_10 D2 | PC_4 | //out|PC_2 | PC_1 A4| ||TX2|PA_2 D1 | NC | //out|PC_3 | PC_0 A5|IR ||RX2|PA_3 D0 | NC | // |---------------| || |-----------------| //************************************************// #define IR_FILT_CONST 1.0f * 2.0f * 3.14159f / 250.0f #define CNT2ZTCm 250 #define CNT2ZTCh 5 #define CNT2STRT 1250 AnalogIn analog_value(A5);//When using the ADC module, those pins connected to AnalogIn can't be used to output. Ticker timer1; Ticker timer2; Timeout timeout; DigitalOut pin_pc2(PC_2); DigitalOut pin_pc3(PC_3); Serial BT(PC_6, PA_12); SDFileSystem SD_card(PC_12, PC_11, PC_10, PD_2, "sd"); //mosi, miso, sck, cs, name //**** Variables from Arduino ****// int counter = 0; int i = 0; int8_t c = FIRST_POS; bool s = 0; int fusion_init = 0; int state_count = 0; uint8_t state_change = 0; uint16_t brake_count = 0; float V_meas = 0; float L_inver = 0; bool toggle = 0; //********************************// //***** Variables from RasPi *****// char BTCharR = 0; float Vx = 0.0; float Vx_old = 0.0; unsigned char pedal_state = 0; unsigned char sys_state = S_S; unsigned int count2ztc_h = 0; unsigned int count2ztc_m = 0; unsigned int count2straight = 0; unsigned int count_isr = 0; float T_total = 0.0; //********************************// bool resetting = 0; void timer1_interrupt(void); void timer2_interrupt(void); void reset_offset(void); void ready_to_go(void); void attimeout(void); int main() { pin_pc2 = pin_pc3 = 0; setupServo(); pc.baud(115200); setup_spi_sensor(); init_Sensors(); BT.baud(115200); reset_offset(); timer1.attach_us(&timer1_interrupt, 4000);//4.0ms interrupt period (250 Hz) timer2.attach_us(&timer2_interrupt, 4098);//4.098ms interrupt period (244 Hz) // SD_card.format(8, 3); // fprintf_data(0); pc.printf("System ready.\r\n"); reset_pos(); lookuptable_steering(HANDLE_START); // lookuptable_steering(0); while(!interrupt) { if(BT.readable()) { BTCharR = BT.getc(); switch(BTCharR) { case 's': //reset_offset(); ready_to_go(); pc.printf("go\r\n"); pedal_state = 1; sys_state = L_PD; gamma_ref = 0.0; s = 1; break; ///start case 'a': pc.printf("stop\r\n"); pedal_state = 0; sys_state = S_S; Vx = 0.0; Vx_old = 0.0; gamma_ref = 0.0; count2ztc_h = 0; count2ztc_m = 0; s = 0; state_count = 0; break; ///stop // case 'm': pedal_state = 2; sys_state = M_PD; gamma_ref = 0.0; if(count2ztc_m >= CNT2ZTCm){sys_state = M_ZTC;} break; // case 'h': pedal_state = 3; sys_state = H_PD; gamma_ref = 0.0; if(count2ztc_h >= CNT2ZTCh){sys_state = H_ZTC;} break; case 'l': gamma_ref = DLT_GAMMA_REF; roll_ref = 0.0; count2straight = 0; break; ///left case 'r': gamma_ref = -DLT_GAMMA_REF; roll_ref = 0.0; count2straight = 0; break; ///right case 'f': gamma_ref = 0.0; roll_ref = 0.0; break; ///forward case 'c': gamma_ref = 0.0; reset_offset(); break; ///clear default: break; } BTCharR = 0; } sensorG_read_3axis(); sensorX_read_3axis(); get_9axis_scale(); get_9axis_data(pedal_state); L_inver = 0.0063f * V_meas - 0.005769f; } } void timer1_interrupt(void) { // pin_pc2 = !pin_pc2; V_meas = (analog_value.read() * 3.3f) * IR_FILT_CONST + V_meas * (1.0f - IR_FILT_CONST); // pc.printf("%d\t%d\t%d\r\n", filted_sensor_data(INDEX_ACCE_X, 1.8), filted_sensor_data(INDEX_ACCE_Y, 1.8), filted_sensor_data(INDEX_ACCE_Z, 1.8)); roll_fusion(axm,aym,azm,u3,u1,1); x1_hat_estimat(axm,aym,azm,u3,u2,Alpha); m_x1_hat(mx,my,mz,u3,u2,Alpha); m_x2_hat(mx,my,mz,u3,u1,Alpha); if(cosroll != 0) { droll_angle = lpf(u1, droll_angle_old, 62.8); droll_angle_old = droll_angle; dyaw_angle = lpf(u3/cosroll, dyaw_angle_old, 3.1416); dyaw_angle_old = dyaw_angle; // m_yaw_fusion(); ///cut off if(m_sinyaw <= -1.0f)m_sinyaw = -1.0f; else if(m_sinyaw >= 1.0f)m_sinyaw = 1.0f; else ; if(m_cosyaw <= -1.0f)m_cosyaw = -1.0f; else if(m_cosyaw >= 1.0f)m_cosyaw = 1.0f; else ; ///Controller if(sys_state == L_PD) { calc_PD(K_l, 0.0); calc_Gamma(u,15,b_h); gamma_rad = gamma_rad + L_PD_OFFSET; dphi_hat = 0.0; phi_hat = 0.0; yaw_angle = yaw_angle_old + dyaw_angle * sample_time; yaw_angle_old = yaw_angle; } else if(sys_state == M_PD) { calc_PD(K_m, 0.0); calc_Gamma(u,15,b_h); dphi_hat = 0.0; phi_hat = 0.0; yaw_angle = yaw_angle_old + dyaw_angle * sample_time; yaw_angle_old = yaw_angle; count2ztc_m++; if(count2ztc_m >= CNT2ZTCm){sys_state = M_ZTC;} } else if(sys_state == M_ZTC) { if(count2straight < CNT2STRT){count2straight++;} else{gamma_ref = 0.0; roll_ref = 0.0;} calc_PD(K_m, phi_hat); calc_Phi(K_mphi); calc_Gamma(u,15,b_h); yaw_angle = yaw_angle_old + dyaw_angle * sample_time; yaw_angle_old = yaw_angle; } else if(sys_state == H_PD) { calc_PD(K_h,0.0); calc_Gamma(u,15,b_h); dphi_hat = 0.0; phi_hat = 0.0; yaw_angle = yaw_angle_old + dyaw_angle * sample_time; yaw_angle_old = yaw_angle; // count2ztc_h++; if(count2ztc_h >= CNT2ZTCh){sys_state = H_ZTC;} } else if(sys_state == H_ZTC) { if(count2straight < CNT2STRT){count2straight++;} else{gamma_ref = 0.0; roll_ref = 0.0;} calc_PD(K_h, phi_hat); calc_Phi(K_hphi); calc_Gamma(u,15,b_h); yaw_angle = yaw_angle_old + dyaw_angle * sample_time; yaw_angle_old = yaw_angle; } else { u = 0.0; // calc_PD(K_l, 0.0); calc_Gamma(u,15,b_h); dphi_hat = 0.0; phi_hat = 0.0; yaw_angle = 0.0; yaw_angle_old = 0.0; } ///Anti-Windup anti_wdup(); // calc_Gamma(u,15,b_h); if(gamma_rad > 0.349f)gamma_rad = 0.349f; else if(gamma_rad < -0.349f)gamma_rad = -0.349f; else ; // printf("%d Roll:%9.6f dRoll:%9.6f u:%9.6f phi_hat:%9.6f gamma:%9.6f\r\n", sys_state, roll_angle, droll_angle, u, phi_hat, gamma_rad); ///Show results or Send datas gamma_degree = (short int)(gamma_rad*114.59f); if(gamma_degree > 40)gamma_degree = 40; else if(gamma_degree < -40)gamma_degree = -40; else ; ///Steering if(s == 1) { if(state_count > COUN2_HANDLE_START) { lookuptable_steering( gamma_degree ); } else { lookuptable_steering( gamma_degree + HANDLE_START_BAL); } } else { if(c == FIRST_POS) { if(state_change > 0) { lookuptable_steering(HANDLE_STOP); } else { if(!resetting) { lookuptable_steering(HANDLE_START); // lookuptable_steering(HANDLE_STRAIGHT); // lookuptable_steering( gamma_degree ); } else ; } } else lookuptable_steering( gamma_degree + HANDLE_START_BAL); } ///print file if(sys_state >= 1) { count_isr++; T_total = (float)sample_time*count_isr; ///Integrate Ax to get Vx Vx = Vx_old - axm_f*sample_time; Vx_old = Vx; // if(Vx >= v_low && sys_state < M_PD){pedal_state = 2; sys_state = M_PD; gamma_ref = 0.0;} // fprintf_data(1); } } else { roll_fusion(0,0,0,0,0,1); gamma_degree = 0; } } void timer2_interrupt(void) { // pin_pc3 = !pin_pc3; if(s == 1) // bluetooth start { i ++; if(i == Z_PEDAL_DIVIDER && state_change == 0) //start { i = 0; lookuptable_pedaling(c); c++; if(c == (FIRST_POS + TOT_STOP_POS)){c = FIRST_POS + TOT_STOP_POS + TOT_STOP_POS - 1;} else if(c >= TOT_FOOT_POS){c = 0;} state_count++; } else if(i == L_PEDAL_DIVIDER && state_change == 1) //low_v { i = 0; lookuptable_pedaling(c); c++; if(c == FIRST_POS){c = FIRST_POS + TOT_STOP_POS;} else if(c >= TOT_FOOT_POS){c = 0;} state_count++; } else if(i == M_PEDAL_DIVIDER && state_change == 2) //mid_v { i = 0; lookuptable_pedaling(c); c++; if(c == FIRST_POS){c = FIRST_POS + TOT_STOP_POS;} else if(c >= TOT_FOOT_POS){c = 0;} state_count++; } else if(i == M_PEDAL_DIVIDER && state_change == 3) //high_v { i = 0; lookuptable_pedaling(c); c++; if(c == FIRST_POS){c = FIRST_POS + TOT_STOP_POS;} else if(c >= TOT_FOOT_POS){c = 0;} } if(state_count == COUN2_LOW_V) { state_change = 1; } else if(state_count == COUN2_MID_V) { state_change = 2; } else if(state_count == COUN2_HIGH_V) { if(state_change == 2) { pc.printf("m\r\n"); // BT.printf("m\r\n"); pedal_state = 2; sys_state = M_PD; gamma_ref = 0.0; if(count2ztc_m >= CNT2ZTCm) { sys_state = M_ZTC; } } state_change = 3; } } else //s is 0 { if(c == FIRST_POS) { if(state_change > 0) { stop_pos(); brake_count++; if(brake_count >= 3*244) { state_change = 0; brake_count = 0; } } else { reset_pos(); } } else { i++; if(i == M_PEDAL_DIVIDER) { i = 0; lookuptable_pedaling(c); c++; if(c > FIRST_POS && c < (FIRST_POS + TOT_STOP_POS)){c = FIRST_POS;} else if(c >= TOT_FOOT_POS){c = 0;} } } } } void reset_offset(void) { pc.printf("Reseting gyro and accel-X offset...\r\n"); resetting = 1; timeout.attach(&attimeout, 2.0f); while(resetting) { reset_gyro_offset(); reset_acceX_offset(); } timeout.detach(); pc.printf("Done reseting.\r\n"); // pc.printf("%d\r\n", Acce_axis_zero[0]); } void ready_to_go(void) { resetting = 1; lookuptable_pedaling(FIRST_POS); lookuptable_steering(HANDLE_STRAIGHT); timeout.attach(&attimeout, 1.0f); while(resetting) { wait_ms(100); } timeout.detach(); } void attimeout(void) { resetting = 0; } //void attimeout2(void) //{ // preparing = 0; //}