/******************************************************************* * MAIN() *******************************************************************/ int main(void) { long lEEPROMRetStatus; uint16_t i=0; uint8_t halted_latch = 0; // Set the clocking to run at 80 MHz from the PLL. // (Well we were at 80MHz with SYSCTL_SYSDIV_2_5 but according to the errata you can't // write to FLASH at frequencies greater than 50MHz so I slowed it down. I supposed we // could slow the clock down when writing to FLASH but then we need to find out how long // it takes for the clock to stabilize. This is on at the bottom of my list of things to do // for now) SysCtlClockSet(SYSCTL_SYSDIV_4_5 | SYSCTL_USE_PLL | SYSCTL_XTAL_16MHZ | SYSCTL_OSC_MAIN); // Initialize the device pinout. SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOA); SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOB); SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOC); SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOD); SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOE); SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOF); SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOG); SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOH); SysCtlPeripheralEnable(SYSCTL_PERIPH_GPIOJ); // Enable processor interrupts. IntMasterEnable(); // Setup the UART's my_uart_0_init(115200, (UART_CONFIG_WLEN_8 | UART_CONFIG_STOP_ONE | UART_CONFIG_PAR_NONE)); // command_handler_init overwrites the baud rate. We still need to configure the pins though my_uart_1_init(38400, (UART_CONFIG_WLEN_8 | UART_CONFIG_STOP_ONE | UART_CONFIG_PAR_NONE)); // Enable the command handler command_handler_init(); // We set the baud in here // Start the timers my_timer0_init(); my_timer1_init(); i2c_init(); motor_init(); qei_init(); gyro_init(); accel_init(); led_init(); //rc_radio_init(); //setupBluetooth(); // Initialize the EEPROM emulation region. lEEPROMRetStatus = SoftEEPROMInit(EEPROM_START_ADDR, EEPROM_END_ADDR, EEPROM_PAGE_SIZE); if(lEEPROMRetStatus != 0) UART0Send("EEprom ERROR!\n", 14); #if 0 // If ever we wanted to write some parameters to FLASH without the HMI // we could do it here. SoftEEPROMWriteDouble(kP_ID, 10.00); SoftEEPROMWriteDouble(kI_ID, 10.00); SoftEEPROMWriteDouble(kD_ID, 10.00); SoftEEPROMWriteDouble(ANG_ID, 0.0); SoftEEPROMWriteDouble(COMPC_ID, 0.99); #endif kP = SoftEEPROMReadDouble(kP_ID); kI = SoftEEPROMReadDouble(kI_ID); kD = SoftEEPROMReadDouble(kD_ID); commanded_ang = zero_ang = SoftEEPROMReadDouble(ANG_ID); COMP_C = SoftEEPROMReadDouble(COMPC_ID); pid_init(kP, kI, kD, &pid_ang); motor_controller_init(20, 100, 10, &mot_left); motor_controller_init(20, 100, 10, &mot_right); //pid_init(0.0, 0.0, 0.0, &pid_pos_left); //pid_init(0.0, 0.0, 0.0, &pid_pos_right); //UART0Send("Hello World!\n", 13); // Tell the HMI what the initial parameters are. print_params(1); while(1) { delta_t = myTimerValueGet(); myTimerZero(); sum_delta_t += delta_t; // Read our sensors accel_get_xyz_cal(&accel_x, &accel_y, &accel_z, true); gyro_get_y_cal(&gyro_y, false); // Calculate the pitch angle with the accelerometer only R = sqrt(pow(accel_x, 2) + pow(accel_z, 2)); accel_pitch_ang = (acos(accel_z / R)*(RAD_TO_DEG)) - 90.0 - zero_ang; //accel_pitch_ang = (double)((atan2(accel_x, -accel_z))*RAD_TO_DEG - 90.0); gyro_pitch_ang += (double)gyro_y*g_gyroScale*CONV_TO_SEC(delta_t); // Kalman filter //filtered_ang = kalman((double)accel_pitch_ang, ((double)gyro_y)*g_gyroScale, CONV_TO_SEC(delta_t)); filtered_ang = (COMP_C*(filtered_ang+((double)gyro_y*g_gyroScale*CONV_TO_SEC(delta_t)))) + ((1.0-COMP_C)*(double)accel_pitch_ang); // Skip the rest of the process until the angle stabilizes if(i < 250) { i++; continue; } // Tell the HMI what's going on every 100ms if(sum_delta_t >= 1000) { print_update(1); print_debug(0); //print_control_surfaces(0); led_toggle(); //print_angle(); sum_delta_t = 0; } // See if the HMI has anything to say command_handler(); //continue; // If we are leaning more than +/- FALL_ANG deg off center it's hopeless. // Turn off the motors in hopes of some damage control if( abs(filtered_ang) > FALL_ANG ) { if(halted_latch) continue; stop_motors(); halted_latch = 1; continue; } halted_latch = 0; motor_val = pid_controller(calc_commanded_angle(0), filtered_ang, delta_t, &pid_ang); motor_left = motor_right = motor_val; drive_motors(motor_left*left_mot_gain, motor_right*right_mot_gain); } }
// Begin control algorithm main method int main() { printf("Start of Control\r\n"); mot_Init(); // Declare variables for navdata int rc; nav_struct nav; // Initialize navdata rc = nav_Init(&nav); // Check if navdata initializes int nav_fail = 0; if (rc==0) { printf("navdata failed to initialize\n"); nav_fail = 1; } // Calibrate navdata rc=nav_FlatTrim(); if(rc) { printf("Failed navdata: retcode=%d\r\n",rc); nav_fail = 1; } // Kick off value getting thing in a separate thread! pthread_create(&image_processing_thread, NULL, process_images, NULL); int angle = getAngle(); printf("Angle: %i\r\n",angle); int dir = angle != 0 ? angle/abs(angle) : 0; /* //first pulse pulse(dir,pulseDuration); printf("Wait: %f\r\n",wait(angle)*1000000); for(int i=0; i<100; i++){ usleep(wait(angle)/100*1000000); checkKeypress(); } pulse(-dir,pulseDuration -.04); */ prevAngle = angle; // start timer gettimeofday(&t1, NULL); // PID Loop float s = .01; dir= 1; while(1) { checkKeypress(); if(waitToStart) continue; if(stopLoop) break; // Check navdata if navdata initiates if (nav_fail == 0) { checkNavdata(&nav); } pid_controller(); /* smallPulse(dir,.9); usleep(s * 1000000); smallPulse(dir,.9); usleep(1.5 * 1000000); printf("%f\n",s); if(dir > 0) dir = -1; else dir = 1; s+=.01; smallPulse(dir,.9); usleep(s * 1000000); smallPulse(dir,.9); usleep(1.5 * 1000000); printf("%f\n",s); s+=.01; */ //yield to other threads pthread_yield(); } // Cleanup // Delete the mutex pthread_mutex_destroy(&video_results_mutex); //close(sockfd); //close(newsockfd); // Close TCP socket //video_Close(&vid); // Close video thread mot_Close(); // Close motor thread printf("\nDone!\n"); return 0; }