Tobis Programm forked to not destroy your golden files
Fork of Robocode by
source/Robot.cpp
- Committer:
- cittecla
- Date:
- 2017-04-19
- Revision:
- 62:c2fcf3b349e9
- Parent:
- 61:628f8a4e857c
- Child:
- 72:4e8a151d804e
File content as of revision 62:c2fcf3b349e9:
// Roboter file #include "mbed.h" #include "Robot.h" #include "EncoderCounter.h" #include "LowpassFilter.h" #include "IMU.h" #include "IRSensor.h" //Define I2C-Servoboard Consts #define ADRESS 0x40 #define MODE1 0x00 #define MODE2 0x01 #define PRESCALE 0xFE #define LED0_ON_L 0x06 #define LED0_ON_H 0x07 #define LED0_OFF_L 0x08 #define LED0_OFF_H 0x09 #define RESTART 0x80 #define SLEEP 0x10 const float PERIOD = 0.001f; // period of control task, given in [s] const float COUNTS_PER_TURN = 1200.0f; // resolution of encoder counter const float LOWPASS_FILTER_FREQUENCY = 300.0f; // frequency of lowpass filter for actual speed values, given in [rad/s] const float KN = 40.0f; // speed constant of motor, given in [rpm/V] const float KP = 0.2f; // speed controller gain, given in [V/rpm] const float MAX_VOLTAGE = 12.0f; // supply voltage for power stage in [V] const float MIN_DUTY_CYCLE = 0.02f; // minimum allowed value for duty cycle (2%) const float MAX_DUTY_CYCLE = 0.98f; // maximum allowed value for duty cycle (98%) const float correction_value = 2.45f; // correction value for desired speed LowpassFilter speedLeftFilter; LowpassFilter speedRightFilter; DigitalIn user(USER_BUTTON); //Motor stuff EncoderCounter counterLeft(PB_6, PB_7); EncoderCounter counterRight(PA_6, PC_7); DigitalOut enableMotorDriver(PB_2); PwmOut pwmLeft(PA_8); PwmOut pwmRight(PA_9); DigitalOut my_led(LED1); //Periphery for distance sensors AnalogIn distance(PB_1); AnalogIn distance2(PA_1); DigitalOut enable(PC_1); DigitalOut bit0(PH_1); DigitalOut bit1(PC_2); DigitalOut bit2(PC_3); IRSensor sensors[6]; //indicator leds arround robot DigitalOut leds[] = { PC_8, PC_6, PB_12, PA_7, PC_0, PC_9 }; //Periphery for the IMU SPI spi(PC_12, PC_11, PC_10); DigitalOut csG(PA_15); DigitalOut csXM(PD_2); IMU imu(spi, csG, csXM); //Periphery for I2C I2C i2c(PB_9, PB_8); DigitalOut Servo_enable(PA_10); //Color sensor DigitalIn red(PB_13); DigitalIn green(PC_4); short previousValueCounterRight = 0; short previousValueCounterLeft = 0; float desiredSpeedLeft = 0; float desiredSpeedRight = 0; float actualSpeedLeft; float actualSpeedRight; bool get_user() { return user; } void Robot_init_all() { Speedcontroller_init(); Sensor_init(); init_servo(60); } //speed controll void Speedcontroller_init() { // Initialisieren der PWM Ausgaenge pwmLeft.period(0.00005f); // PWM Periode von 50 us pwmLeft.period(0.00005f); // Setzt die Periode auf 50 μs pwmRight.period(0.00005f); pwmLeft = 0.5f; // Duty-Cycle von 50% pwmRight.period(0.00005f); // PWM Periode von 50 us pwmRight = 0.5f; // Duty-Cycle von 50% // Initialisieren von lokalen Variabeln previousValueCounterLeft = counterLeft.read(); previousValueCounterRight = counterRight.read(); speedLeftFilter.setPeriod(PERIOD); speedLeftFilter.setFrequency(LOWPASS_FILTER_FREQUENCY); speedRightFilter.setPeriod(PERIOD); speedRightFilter.setFrequency(LOWPASS_FILTER_FREQUENCY); desiredSpeedLeft = 0.0f; desiredSpeedRight = 0.0f; actualSpeedLeft = 0.0f; actualSpeedRight = 0.0f; Ticker t1; t1.attach( &speedCtrl, PERIOD); //desiredSpeedLeft = 50.0f+correction_value; //50 RPM //desiredSpeedRight = -50.0f; //50 RPM enableMotorDriver = 1; } void set_speed(float left, float right) { desiredSpeedLeft = left+correction_value; //50 RPM desiredSpeedRight = -right; //50 RPM } float get_speed_left() { return actualSpeedLeft; } float get_speed_right() { return actualSpeedRight; } void speedCtrl() { // Berechnen die effektiven Drehzahlen der Motoren in [rpm] short valueCounterLeft = counterLeft.read(); short valueCounterRight = counterRight.read(); short countsInPastPeriodLeft = valueCounterLeft-previousValueCounterLeft; short countsInPastPeriodRight = valueCounterRight-previousValueCounterRight; previousValueCounterLeft = valueCounterLeft; previousValueCounterRight = valueCounterRight; actualSpeedLeft = speedLeftFilter.filter((float)countsInPastPeriodLeft /COUNTS_PER_TURN/PERIOD*60.0f); actualSpeedRight = speedRightFilter.filter((float)countsInPastPeriodRight /COUNTS_PER_TURN/PERIOD*60.0f); // Berechnen der Motorspannungen Uout float voltageLeft = KP*(desiredSpeedLeft-actualSpeedLeft)+desiredSpeedLeft/KN; float voltageRight = KP*(desiredSpeedRight-actualSpeedRight)+desiredSpeedRight/KN; // Berechnen, Limitieren und Setzen der Duty-Cycle float dutyCycleLeft = 0.5f+0.5f*voltageLeft/MAX_VOLTAGE; if (dutyCycleLeft < MIN_DUTY_CYCLE) dutyCycleLeft = MIN_DUTY_CYCLE; else if (dutyCycleLeft > MAX_DUTY_CYCLE) dutyCycleLeft = MAX_DUTY_CYCLE; pwmLeft = dutyCycleLeft; float dutyCycleRight = 0.5f+0.5f*voltageRight/MAX_VOLTAGE; if (dutyCycleRight < MIN_DUTY_CYCLE) dutyCycleRight = MIN_DUTY_CYCLE; else if (dutyCycleRight > MAX_DUTY_CYCLE) dutyCycleRight = MAX_DUTY_CYCLE; pwmRight = dutyCycleRight; } //Sensors void Sensor_init() { for( int ii = 0; ii<6; ++ii) sensors[ii].init(&distance, &bit0, &bit1, &bit2, ii); } float getDistanceIR(int number) { return sensors[number]; } //Color bool get_color() { if (red == 0 && green == 1) { return 1; } else { return 0; } } //IMU float read_acc_x() { return imu.readAccelerationX(); } float read_acc_y() { return imu.readAccelerationY(); } float read_acc_z() { return imu.readAccelerationZ(); } float read_gyr_x() { return imu.readGyroX(); } float read_gyr_y() { return imu.readGyroY(); } float read_gyr_z() { return imu.readGyroZ(); } float read_heading() { double deg = (double)(180.0f/(double)M_PI*imu.readHeading()); return deg; } // Servo I2C void init_servo(int freq) { char data[2]; //Reset data[0] = (char) MODE1; data[1] = (char) SLEEP; i2c.write((ADRESS<<1), data,2); wait_ms(1); float prescaleval = 25000000.0; //25MHz prescaleval /= 4096.0f; //12-Bit prescaleval /= (float)freq; prescaleval -= 1.0f; char prescale = (char)(prescaleval); //0x64 bei 50Hz data[0] = (char) PRESCALE; data[1] = prescale; i2c.write((ADRESS<<1), data,2); data[0] = (char) MODE1; data[1] = 0x00; //wake up i2c.write((ADRESS<<1), data,2); wait_ms(1); data[0] = (char) MODE1; data[1] = 0x80; //do restart i2c.write((ADRESS<<1), data,2); wait_ms(1); data[0] = (char) MODE2; data[1] = (char) 0x04; i2c.write((ADRESS<<1), data,2); wait_ms(1); printf("init done...\r\n"); } void set_servo_position(int servo, int deg) { // Servo 0 = IR_left // Servo 2 = IR_right // Servo 4 = Arm_1 // Servo 6 = Arm_2 // Servo 8 = Grabber if (deg < 0 || deg > 4095) { deg = 300; } char data[2]; int16_t wert1 = (deg>>8); int16_t wert2 = (deg & 0xFF); printf("%x %x servo deg\r\n",wert1,wert2); data[0] = (char)LED0_ON_L+(4*servo); data[1] = 0x00; i2c.write((ADRESS<<1), data,2); data[0] = (char)LED0_ON_H+(4*servo); data[1] = 0x00; i2c.write((ADRESS<<1), data,2); data[0] = (char)LED0_OFF_L+(4*servo); data[1] = (char)wert2; i2c.write((ADRESS<<1), data,2); data[0] = (char)LED0_OFF_H+(4*servo); data[1] = (char)wert1; i2c.write((ADRESS<<1), data,2); } int getPWM(uint8_t servo) { char read = 255; char secondread = 255; char data; data = (char)(LED0_ON_L+(4*servo)); i2c.write((ADRESS<<1), &data, 1, 1); i2c.read((ADRESS<<1), &read, 1, 0); data = (char)(LED0_ON_H+(4*servo)); i2c.write((ADRESS<<1), &data, 1, 1); i2c.read((ADRESS<<1), &secondread, 1, 0); printf("LED %d ON_L: %x ON_H: %x\r\n",servo, read, secondread); return (int)read; } int getPRESCALE(void) { char read = 255; char data; data = (char)(PRESCALE); i2c.write((ADRESS<<1), &data, 1, 1); i2c.read((ADRESS<<1), &read, 1, 0); printf("read Prescale value: >>%x<<\r\n",read); return (int)read; } void enable_servos() { Servo_enable = 0; } void disable_servos() { Servo_enable = 1; }