basic version
Dependencies: C12832_lcd USBHost mbed
main.cpp
- Committer:
- cathal66
- Date:
- 2015-01-29
- Revision:
- 9:88d70b0c1b8b
- Parent:
- 8:b22ef9f44549
- Child:
- 10:6059097698f7
- Child:
- 11:f4639eb91e5f
File content as of revision 9:88d70b0c1b8b:
#include "mbed.h" #include "rtos.h" #include "C12832_lcd.h" //Varible float sonarDistance; float servoPosition; //Mutex Mutex sonarDistance_mutex; //Init Mutex for sensor value Mutex servoPosition_mutex; //Init Mutex for servo value //I/O AnalogIn sonarPin(p17); //Assign pin to read sonar sensor PwmOut servoPin(p21); //Assign pin for servo output PwmOut myled1(LED1); //Assign pin for LED1 PwmOut myled2(LED2); //Assign pin for LED2 PwmOut myled3(LED3); //Assign pin for LED3 PwmOut myled4(LED4); //Assign pin for LED4 //LCD Setup C12832_LCD lcd; //setup LCD screen void sonarSensor(void const *args){ while(true){ sonarDistance_mutex.lock(); //Mutex lock for the Servo value sonarDistance = sonarPin.read(); //Read analog voltage and store in variable sonarDistance_mutex.unlock(); //Mutex unlock for the Servo value Thread::wait(10); //Pause thread for 10msec } //End of While loop } //End of Thread void servoControl(void const *args){ while(true){ servoPosition_mutex.lock(); //Mutex lock for the Servo value servoPin.write(servoPosition/2); //Write servo value to servo pin servoPosition_mutex.unlock(); //Mutex unlock for the Servo value } //end of while loop } //end of thread void logic(void const *args) { int Size=16; float Average_4[16]; //number of value in the array float Average_Sum=0; while(true) { for(int i=0;i<Size;i++) { Average_Sum = Average_Sum-Average_4[i]; //Remove the 4th oldest value from the average sum sonarDistance_mutex.lock(); //Mutex lock for the Sonar value Average_4[i]= sonarDistance; //Add the new value to the array sonarDistance_mutex.unlock(); //Mutex unlock for the Sonar value Average_Sum = Average_Sum + Average_4[i]; //Add the new array value to the sum servoPosition_mutex.lock(); //Mutex lock for the servo value servoPosition = Average_Sum/Size; //Divide the array by the number of element in the array servoPosition_mutex.unlock(); //Mutex unlock for the servo value }//end for loop }//end of while loop }//End of thread void display(void const *args){ while(true){ sonarDistance_mutex.lock(); //Mutex lock for the sonar value servoPosition_mutex.lock(); //Mutex lock for the servo value lcd.cls(); //Clear the lcd lcd.locate(0,0); //Cursor postion on the lcd lcd.printf("Sonar : %3.6f \nServo : %3.6f \nSCIENCE!",sonarDistance,servoPosition); sonarDistance_mutex.unlock(); //Mutex unlock for the sonar value servoPosition_mutex.unlock(); //Mutex unlock for the servo value Thread::wait(200); //Thread Wait } } void LED_meter(void const *args) { float LED_distance = 0; //Create var to store sonar distance while(true) { sonarDistance_mutex.lock(); //Mutex lock for the sonar value LED_distance=sonarDistance; //Store value of sonar sensor in LED_distance sonarDistance_mutex.unlock(); //Mutex unlock for the sonar value if(LED_distance<=0.15) { myled1.write(((LED_distance-0.15)*-1)*20); //PWM the LED from 0% to 100% } else { myled1 = 0; //Turn off LED } if(LED_distance<=0.10) { myled2.write(((LED_distance-0.10)*-1)*20); //PWM the LED from 0% to 100% } else { myled2 = 0; //Turn off LED } if(LED_distance<=0.05) { myled3.write(((LED_distance-0.05)*-1)*40); //PWM the LED from 0% to 100% } else { myled3 = 0; //Turn off LED } if(LED_distance<=0.025) { myled4.write(((LED_distance-0.025)*-1)*40); //PWM the LED from 0% to 100% //s2=0.1; } else { myled4 = 0; //Turn off LED //s2=1; } } } int main(){ sonarDistance = 0.0f; servoPosition = 0.0f; Thread sonarSensor_thread(sonarSensor); Thread servoControl_thread(servoControl); Thread logic_thread(logic); Thread display_thread(display); Thread LED_meter_thread(LED_meter); while(true) { } }