BERTL_CHEL18
/
Func_Bertl_Ultra
ultra sonic sensor asdded
Fork of func_Bertl by
main.cpp
- Committer:
- bulmecisco
- Date:
- 2015-01-22
- Revision:
- 6:be710baf53ec
- Parent:
- 5:7b091d085c70
- Child:
- 7:cb6947e1f1d3
File content as of revision 6:be710baf53ec:
/*********************************** * name: func_Bertl v 0.3 * author: PE HTL BULME * email: pe@bulme.at * description: * functions for Bertl The Robot * *************************************/ #include "mbed.h" #include "config.h" bool Start(); void ShutOff(); void Move(); bool FrontIsClear(); bool MoveMeasure(int time, int& left, int& right); bool MoveTicks(int ticks); void TurnBack(); void TurnLeftTicks(int ticks); void TurnLeftTime(int ms); void TurnLeft(); void TurnLedOn(int16_t led); void TurnLedOff(int16_t led); void MoveMore(int anzahl); void Back(); bool WaitUntilButtonPressed(); // Eigene Funktionsdefinitionen hier // ************* Hauptprogramm ************ int main() { // while(!Start()) {} // wait to start wait_ms(200); Move(); TurnLeft(); Move(); TurnLeftTicks(2000); // Anzahl der MotorSensorwerte ShutOff(); return 0; } bool Start() { DEBUG_PRINT("Debug level: %d", (int) DEBUG); i2c.frequency(40000); // I2C Frequenz 40kHz while(WaitUntilButtonPressed()) { } return true; } void ShutOff() { MotorR_FORWARD = MotorL_FORWARD = 0; // motor OFF MotorR_EN=MotorL_EN=0; // motor disable } void Move() { int count=0, left=0, right=0; // initialise variables MotorR_EN=MotorL_EN=1; // both motor ENABLE while(count<1000) { MotorR_FORWARD = MotorL_FORWARD = 1;// both motor forward ON LED_D10 = SensorL; // LED D10 blinks if(SensorL == 1) left++; if(SensorR == 1) right++; LED_D13 = SensorR; // LED D13 blinks count++; wait_ms(1); // wait for 1 ms } //DEBUG_PRINT("SensorL: %d SensorR: %d\right\n", left, right); MotorR_FORWARD = MotorL_FORWARD = 0; // both motor off MotorR_EN=MotorL_EN=0; wait_ms(250); } bool FrontIsClear() { char cmd[3]; // array for I2C int16_t btns; bool wert; cmd[0] = 0x06; cmd[1] = 0x00; i2c.write(addr, cmd, 2); // define Port0 = Out cmd[0]=0x01; i2c.write(addr, cmd, 1); i2c.read(addr|1, cmd, 1); btns = cmd[0]; if( btns & (BTN_FL|BTN_FM|BTN_FR)) wert = false; else wert = true; DEBUG_PRINT("\right\nWERT: %d \right\n", wert); return wert; } /* use in main(): int left=0, right=0; MoveMeasure(1000, left, right); pc.printf("\r\nleft= %d right= %d\r\n", left, right); */ bool MoveMeasure(int time, int& left, int& right) { int count=0; //, left=0, right=0; MotorR_EN=MotorL_EN=1; MotorR_FORWARD = MotorL_FORWARD = 1; while(count<time) { MotorR_FORWARD = MotorL_FORWARD = 1; LED_D10 = SensorL; if(SensorL == 1) left++; if(SensorR == 1) right++; LED_D13 = SensorR; count++; wait_ms(1); } DEBUG_PRINT("SensorL: %d SensorR: %d\right\n", left, right); MotorR_FORWARD = MotorL_FORWARD = 0; MotorR_EN=MotorL_EN=0; wait_ms(500); return true; } bool MoveTicks(int ticks) { int count=0, left=0, right=0; //Variable count auf 0 setzen MotorR_EN=MotorL_EN=1; // Beide Motoren ENABLE while(ticks--) { // mache solang ticks MotorR_FORWARD = MotorL_FORWARD = 1; // Beide Motoren vorwärts EIN LED_D10 = SensorL; // LED D10 blinkt if(SensorL == 1) left++; if(SensorR == 1) right++; LED_D13 = SensorR; // LED D13 blinkt count++; wait_ms(1); // warte 1 mSekunde } DEBUG_PRINT("SensorL: %d SensorR: %d anzahl: %d\right\n", left, right, count); MotorR_FORWARD = MotorL_FORWARD = 0; // Motoren AUS MotorR_EN=MotorL_EN=0; //wait_ms(250); return true; } void TurnBack() { MotorR_EN=1; MotorR_REVERSE = 1; wait_ms(750); MotorR_REVERSE = 0; MotorR_EN=0; wait_ms(250); } void TurnLeftTicks(int ticks) { MotorR_EN=1; MotorL_EN=1; int left=0, right=0; while(ticks--) { MotorR_FORWARD = MotorL_REVERSE = 1; LED_D10 = SensorL; if(SensorL == 1) left++; if(SensorR == 1) right++; LED_D13 = SensorR; wait_ms(1); } DEBUG_PRINT("\right\nTurnLeft: SensorL: %d SensorR: %d \right\n", left, right); MotorL_REVERSE = MotorR_FORWARD = 0; MotorL_EN=MotorR_EN=0; wait_ms(250); } void TurnLeftTime(int ms) { MotorR_EN=1; // motor right ENABLE MotorR_FORWARD = 1; // motor right forward ON wait_ms(ms); // wait for ms MotorR_FORWARD = 0; // motor right OFF MotorR_EN=0; wait_ms(250); // only to step the robot } void TurnLeft() { MotorR_EN=1; // motor right ENABLE MotorR_FORWARD = 1; // motor right forward ON wait_ms(500); // wait 500 ms (90°) MotorR_FORWARD = 0; // motor right forward OFF MotorR_EN=0; wait_ms(250); // only to step the robot } bool WaitUntilButtonPressed() { char cmd[3]; int16_t btns; bool wert; cmd[0] = 0x06; cmd[1] = 0x00; i2c.write(addr, cmd, 2); // Define Port0 = Out cmd[0]=0x01; i2c.write(addr, cmd, 1); i2c.read(addr|1, cmd, 1); btns = cmd[0]; if( btns & (0xFF)) wert = false; else wert = true; DEBUG_PRINT("\right\nWERT: %d \right\n", wert); return wert; } void TurnLedOn(int16_t led) { char cmd[3]; cmd[0] = 0x02; cmd[1] = ~led; i2c.write(addr, cmd, 2); wait(0.5); } void TurnLedOff(int16_t led) { char cmd[3]; cmd[0] = 0x02; cmd[1] = led; i2c.write(addr, cmd, 2); wait(0.5); } /* void TurnAllLedOff() { TurnLedOff(LED_ALL); } void TurnAllLedOn() { TurnLedOn(LED_ALL); } void MoveMore(int anzahl) { for(int i=0; i < anzahl; i++) Move(); } void Back() { TurnLeftTicks(150); TurnLeftTicks(150); } void MoveWhileFrontIsClear() { while(FrontIsClear()) { MoveTicks(30); } } void LedTest() { TurnLedOn(LED_FL1 |LED_FR1); wait(1); TurnAllLedOn(); wait(1); TurnLedOff(LED_FL1 |LED_FR1); } */