NOT FINISHED YET!!! My first try to get a self built fully working Quadrocopter based on an mbed, a self built frame and some other more or less cheap parts.
main.cpp
- Committer:
- maetugr
- Date:
- 2012-11-28
- Revision:
- 27:9e546fa47c33
- Parent:
- 26:96a072233d7a
- Child:
- 28:ba6ca9f4def4
File content as of revision 27:9e546fa47c33:
#include "mbed.h" // Standard Library #include "LED.h" // LEDs framework for blinking ;) #include "PC.h" // Serial Port via USB by Roland Elmiger for debugging with Terminal (driver needed: https://mbed.org/media/downloads/drivers/mbedWinSerial_16466.exe) #include "L3G4200D.h" // Gyro (Gyroscope) #include "ADXL345.h" // Acc (Accelerometer) #include "HMC5883.h" // Comp (Compass) #include "BMP085_old.h" // Alt (Altitude sensor) #include "RC_Channel.h" // RemoteControl Chnnels with PPM #include "Servo_PWM.h" // Motor PPM using PwmOut #include "PID.h" // PID Library by Aaron Berk #include "IMU_Filter.h" // Class to calculate position angles #include "Mixer.h" // Class to calculate motorspeeds from Angles, Regulation and RC-Signals #define RATE 0.02 // speed of the interrupt for Sensors and PID #define P_VALUE 0.02 // PID values #define I_VALUE 20 // Werte die bis jetzt am besten funktioniert haben #define D_VALUE 0.004 //#define COMPASSCALIBRATE // decomment if you want to calibrate the Compass on start #define PC_CONNECTED // decoment if you want to debug per USB and your PC Timer GlobalTimer; // global time to calculate processing speed Ticker Datagetter; // timecontrolled interrupt to get data form IMU and RC // initialisation of hardware (see includes for more info) LED LEDs; #ifdef PC_CONNECTED PC pc(USBTX, USBRX, 115200); #endif LocalFileSystem local("local"); // Create the local filesystem under the name "local" FILE *Logger; L3G4200D Gyro(p28, p27); ADXL345 Acc(p28, p27); HMC5883 Comp(p28, p27); BMP085_old Alt(p28, p27); RC_Channel RC[] = {RC_Channel(p11,1), RC_Channel(p12,2), RC_Channel(p13,3), RC_Channel(p14,4)}; // no p19/p20 ! Servo_PWM ESC[] = {p21, p22, p23, p24}; // p21 - p26 only because PWM! IMU_Filter IMU; // don't write () after constructor for no arguments! Mixer MIX; // 0:X:Roll 1:Y:Pitch 2:Z:Yaw PID Controller[] = {PID(P_VALUE, I_VALUE, D_VALUE, RATE), PID(P_VALUE, I_VALUE, D_VALUE, RATE), PID(0.02, 100, 0.005, RATE)}; // TODO: RATE != dt immer anpassen // global variables bool armed = false; // this variable is for security unsigned long dt = 0; unsigned long time_for_dt = 0; unsigned long dt_read_sensors = 0; unsigned long time_read_sensors = 0; float tempangle = 0; // temporärer winkel für yaw mit kompass float controller_value[] = {0,0,0}; void get_Data() // method which is called by the Ticker Datagetter every RATE seconds { time_read_sensors = GlobalTimer.read_us(); // read data from sensors // ATTENTION! the I2C option repeated true is important because otherwise interrupts while bus communications cause crashes Gyro.read(); Acc.read(); // TODO: nicht jeder Sensor immer? höhe nicht so wichtig //Comp.read(); //Alt.Update(); TODO braucht zu lange zum auslesen! dt_read_sensors = GlobalTimer.read_us() - time_read_sensors; // meassure dt dt = GlobalTimer.read_us() - time_for_dt; // time in us since last loop time_for_dt = GlobalTimer.read_us(); // set new time for next measurement // TODO: RC_signal füllen!!! IMU.compute(dt, Gyro.data, Acc.data); MIX.compute(dt, IMU.angle, RC[2].read(), controller_value); // Arming / disarming if(RC[2].read() < 20 && RC[3].read() > 850) { armed = true; #ifdef LOGGER if(Logger == NULL) Logger = fopen("/local/log.csv", "a"); #endif } if((RC[2].read() < 30 && RC[3].read() < 30) || RC[3].read() < -10 || RC[2].read() < -10 || RC[1].read() < -10 || RC[0].read() < -10) { armed = false; #ifdef LOGGER if(Logger != NULL) { fclose(Logger); Logger = NULL; } #endif } if (armed) // for SECURITY! { // PID controlling if (!(RC[0].read() == -100)) { //Controller[0].setSetPoint(-(int)((RC[0].read()-440)/440.0*90.0)); //Controller[1].setSetPoint(-(int)((RC[1].read()-430)/430.0*90.0)); //Controller[2].setSetPoint(-(int)((RC[3].read()-424)/424.0*180.0)); // TODO: muss später += werden } for(int i=0;i<3;i++) { Controller[i].setProcessValue(IMU.angle[i]); controller_value[i] = Controller[i].compute() - 1000; } // Set new motorspeeds for(int i=0;i<4;i++) ESC[i] = (int)MIX.Motor_speed[i]; #ifdef LOGGER // Writing Log for(int i = 0; i < 3; i++) { fprintf(Logger, "%f;", angle[i]); fprintf(Logger, "%f;", controller_value[i]); } fprintf(Logger, "\r\n"); #endif } else { for(int i=0;i<4;i++) // for security reason, set every motor to zero speed ESC[i] = 0; for(int i=0;i<3;i++) Controller[i].reset(); // TODO: schon ok so? anfangspeek?! } } int main() { // main programm for initialisation and debug output NVIC_SetPriority(TIMER3_IRQn, 1); // set priorty of tickers below hardware interrupts (standard priority is 0)(this is to prevent the RC interrupt from waiting until ticker is finished) #ifdef LOGGER Logger = fopen("/local/log.csv", "w"); // Prepare Logfile for(int i = 0; i < 3; i++) { fprintf(Logger, "angle[%d];", i); fprintf(Logger, "controller_value[%d];", i); } fprintf(Logger, "\r\n"); fclose(Logger); Logger = NULL; #endif // Prepare PID Controllers for(int i=0;i<3;i++) { Controller[i].setInputLimits(-90.0, 90.0); Controller[i].setOutputLimits(0.0, 2000.0); Controller[i].setBias(1000); Controller[i].setMode(MANUAL_MODE);//AUTO_MODE); Controller[i].setSetPoint(0); } //Controller[2].setInputLimits(-180.0, 180.0); // yaw 360 grad TODO: Yawsteuerung mit -180 bis 180 grad #ifdef PC_CONNECTED #ifdef COMPASSCALIBRATE pc.locate(10,5); pc.printf("CALIBRATING"); Comp.calibrate(60); #endif // init screen pc.locate(10,5); pc.printf("Flybed v0.2"); #endif LEDs.roll(2); // Start! GlobalTimer.start(); Datagetter.attach(&get_Data, RATE); // start to get data all RATEms while(1) { #ifdef PC_CONNECTED pc.locate(30,0); // PC output pc.printf("dt:%dms dt_sensors:%dus Altitude:%6.1fm ", dt/1000, dt_read_sensors, Alt.CalcAltitude(Alt.Pressure)); pc.locate(5,1); if(armed) pc.printf("ARMED!!!!!!!!!!!!!"); else pc.printf("DIS_ARMED "); pc.locate(5,3); pc.printf("Roll:%6.1f Pitch:%6.1f Yaw:%6.1f ", IMU.angle[0], IMU.angle[1], IMU.angle[2]); pc.locate(5,5); pc.printf("Gyro.data: X:%6.1f Y:%6.1f Z:%6.1f", Gyro.data[0], Gyro.data[1], Gyro.data[2]); pc.locate(5,8); pc.printf("Acc.data: X:%6d Y:%6d Z:%6d", Acc.data[0], Acc.data[1], Acc.data[2]); pc.locate(5,11); pc.printf("PID Result:"); for(int i=0;i<3;i++) pc.printf(" %d: %6.1f", i, controller_value[i]); pc.locate(5,14); pc.printf("RC: roll: %d pitch: %d ", -(int)((RC[0].read()-440)/440.0*90.0), -(int)((RC[1].read()-430)/430.0*90.0)); pc.locate(10,15); pc.printf("Debug_Yaw: Comp:%6.1f tempangle:%6.1f ", Comp.get_angle(), tempangle); pc.locate(10,16); pc.printf("Comp_data: %6.1f %6.1f %6.1f |||| %6.1f ", Comp.data[0], Comp.data[1], Comp.data[2], Comp.get_angle()); pc.locate(10,17); //pc.printf("Comp_scale: %6.4f %6.4f %6.4f ", Comp.scale[0], Comp.scale[1], Comp.scale[2]); no more accessible its private pc.locate(10,18); pc.printf("Comp_data: %6.1f %6.1f %6.1f |||| %6.1f ", Comp.data[0], Comp.data[1], Comp.data[2], Comp.get_angle()); pc.locate(10,19); pc.printf("RC0: %4d :[", RC[0].read()); for (int i = 0; i < RC[0].read()/17; i++) pc.printf("="); pc.printf(" "); pc.locate(10,20); pc.printf("RC1: %4d :[", RC[1].read()); for (int i = 0; i < RC[1].read()/17; i++) pc.printf("="); pc.printf(" "); pc.locate(10,21); pc.printf("RC2: %4d :[", RC[2].read()); for (int i = 0; i < RC[2].read()/17; i++) pc.printf("="); pc.printf(" "); pc.locate(10,22); pc.printf("RC3: %4d :[", RC[3].read()); for (int i = 0; i < RC[3].read()/17; i++) pc.printf("="); pc.printf(" "); #endif wait(0.01); if(armed){ LEDs.rollnext(); } else { for(int i=1;i<=4;i++) LEDs.set(i); } } }