bobbycar/controller/controller.ino

// *******************************************************************
//  Arduino Nano 3.3V example code
//  for   https://github.com/EmanuelFeru/hoverboard-firmware-hack-FOC
//
//  Copyright (C) 2019-2020 Emanuel FERU <aerdronix@gmail.com>
//
// *******************************************************************
// INFO:
// • This sketch uses the the Serial Software interface to communicate and send commands to the hoverboard
// • The built-in (HW) Serial interface is used for debugging and visualization. In case the debugging is not needed,
//   it is recommended to use the built-in Serial interface for full speed perfomace.
// • The data packaging includes a Start Frame, checksum, and re-syncronization capability for reliable communication
// 
// CONFIGURATION on the hoverboard side in config.h:
// • Option 1: Serial on Left Sensor cable (long wired cable)
//   #define CONTROL_SERIAL_USART2
//   #define FEEDBACK_SERIAL_USART2
//   // #define DEBUG_SERIAL_USART2
// • Option 2: Serial on Right Sensor cable (short wired cable) - recommended, so the ADCs on the other cable are still available
//   #define CONTROL_SERIAL_USART3
//   #define FEEDBACK_SERIAL_USART3
//   // #define DEBUG_SERIAL_USART3
// *******************************************************************

//https://github.com/rogerclarkmelbourne/Arduino_STM32   in arduino/hardware
//Board: Generic STM32F103C series
//Upload method: serial
//20k RAM 64k Flash
//may need 3v3 from usb ttl converter (hold down flash button while connecting). Holding down the power button is not needed in this case.
//Sometimes reconnecting the usb ttl converter to the pc helps just before pressing the upload button

// RX(green) is A10 , TX (blue) ist A9   (3v3 level)
//to flash set boot0 (the one further away from reset button) to 1 and press reset, flash, program executes immediately
//set boot0 back to 0 to run program on powerup

// ########################## DEFINES ##########################
#define SERIAL_CONTROL_BAUD   38400       // [-] Baud rate for HoverSerial (used to communicate with the hoverboard)
#define SERIAL_BAUD         115200      // [-] Baud rate for built-in Serial (used for the Serial Monitor)
#define START_FRAME         0xAAAA       // [-] Start frme definition for reliable serial communication

//#define DEBUG_RX                        // [-] Debug received data. Prints all bytes to serial (comment-out to disable)

//#define MAXADCVALUE 4095
#define ADC_CALIB_THROTTLE_MIN 2000
#define ADC_CALIB_THROTTLE_MAX 3120

#define PIN_POWERLED PA0 //Red LED inside Engine Start Button. Powered with 5V via transistor
#define PIN_POWERBUTTON PB8 //"Enginge Start" Button. connected To NC (=LOW). HIGH when pressed
#define POWERBUTTON_DOWN digitalRead(PIN_POWERBUTTON)

#define SENDPERIOD 50 //ms. delay for sending speed and steer data to motor controller via serial
#define PIN_THROTTLE PA4
#define PIN_BRAKE PA5

#define PIN_ENABLE PB9

#define PIN_MODESWITCH PB5 // LOW if pressed in ("down")
#define MODESWITCH_DOWN !digitalRead(PIN_MODESWITCH)
#define PIN_MODELED_GREEN PA12
#define PIN_MODELED_RED PA11

#define PIN_RELAISFRONT PB14 //connected to relais which presses the powerbutton of the hoverboard for the front wheels
#define PIN_RELAISREAR PB15 //connected to relais which presses the powerbutton of the hoverboard for the rear wheels

int testcounter=0;

long last_send = 0;


// Global variables
uint8_t idx1 = 0;                        // Index for new data pointer
uint16_t bufStartFrame1;                 // Buffer Start Frame
byte *p1;                                // Pointer declaration for the new received data
byte incomingByte1;
byte incomingBytePrev1;

//Same for Serial2
uint8_t idx2 = 0;                        // Index for new data pointer
uint16_t bufStartFrame2;                 // Buffer Start Frame
byte *p2;                                // Pointer declaration for the new received data
byte incomingByte2;
byte incomingBytePrev2;


typedef struct{
   uint16_t start;
   int16_t  speedLeft;
   int16_t  speedRight;
   uint16_t checksum;
} SerialCommand;
SerialCommand Command1;
SerialCommand Command2;

typedef struct{
   uint16_t start;
   int16_t  cmd1;
   int16_t  cmd2;
   int16_t  speedR;
   int16_t  speedL;
   int16_t  speedR_meas;
   int16_t  speedL_meas;
   int16_t  batVoltage;
   int16_t  boardTemp;
   int16_t  checksum;
} SerialFeedback;
SerialFeedback Feedback1;
SerialFeedback NewFeedback1;
SerialFeedback Feedback2;
SerialFeedback NewFeedback2;

// ########################## SETUP ##########################
void setup() 
{

  Serial.begin(115200); //Debug and Program. A9=TX1,  A10=RX1  (3v3 level)

  Serial1.begin(38400); //control.  A2=TX2, A3=RX2 (Serial1 is Usart 2). Marked with "1" on connector
  Serial2.begin(38400); //control.  B10=TX3, B11=RX3 (Serial2 is Usart 3). Marked with "II" on connector
  
    
  Serial1.begin(SERIAL_CONTROL_BAUD);
  pinMode(PIN_POWERLED, OUTPUT);
  pinMode(PIN_ENABLE, OUTPUT);
  digitalWrite(PIN_ENABLE, HIGH); //keep power on
  pinMode(PIN_POWERBUTTON, INPUT_PULLUP);
  pinMode(PIN_MODESWITCH, INPUT_PULLUP);
  pinMode(PIN_MODELED_GREEN, OUTPUT);
  pinMode(PIN_MODELED_RED, OUTPUT);
  pinMode(PIN_RELAISFRONT, OUTPUT);
  pinMode(PIN_RELAISREAR, OUTPUT);
  pinMode(PIN_THROTTLE, INPUT);
  pinMode(PIN_BRAKE, INPUT);

  Serial.println("Initialized"); 
}

// ########################## SEND ##########################
void SendSerial1(int16_t uSpeedLeft, int16_t uSpeedRight)
{
  // Create command
  Command1.start    = (uint16_t)START_FRAME;
  Command1.speedLeft    = (int16_t)uSpeedLeft;
  Command1.speedRight    = (int16_t)uSpeedRight;
  Command1.checksum = (uint16_t)(Command1.start ^ Command1.speedLeft ^ Command1.speedRight);
  Serial1.write((uint8_t *) &Command1, sizeof(Command1)); 
}
void SendSerial2(int16_t uSpeedLeft, int16_t uSpeedRight)
{
  // Create command
  Command2.start    = (uint16_t)START_FRAME;
  Command2.speedLeft    = (int16_t)uSpeedLeft;
  Command2.speedRight    = (int16_t)uSpeedRight;
  Command2.checksum = (uint16_t)(Command2.start ^ Command2.speedLeft ^ Command2.speedRight);
  Serial2.write((uint8_t *) &Command2, sizeof(Command2)); 
}

// ########################## RECEIVE ##########################
void ReceiveSerial1()
{
  // Check for new data availability in the Serial buffer
  if ( Serial1.available() ) {
    incomingByte1    = Serial1.read();                                 // Read the incoming byte
    bufStartFrame1 = ((uint16_t)(incomingBytePrev1) << 8) +  incomingByte1;  // Construct the start frame    
  }
  else {
    return;
  }

  // If DEBUG_RX is defined print all incoming bytes
  #ifdef DEBUG_RX
    Serial.print(incomingByte1);
    return;
  #endif      
  
  // Copy received data
  if (bufStartFrame1 == START_FRAME) {                     // Initialize if new data is detected
    p1     = (byte *)&NewFeedback1;
    *p1++  = incomingBytePrev1;
    *p1++  = incomingByte1;   
    idx1   = 2;    
  } else if (idx1 >= 2 && idx1 < sizeof(SerialFeedback)) {  // Save the new received data
    *p1++  = incomingByte1; 
    idx1++;
  } 
  
  // Check if we reached the end of the package
  if (idx1 == sizeof(SerialFeedback)) {    
    uint16_t checksum;
    checksum = (uint16_t)(NewFeedback1.start ^ NewFeedback1.cmd1 ^ NewFeedback1.cmd2 ^ NewFeedback1.speedR ^ NewFeedback1.speedL
          ^ NewFeedback1.speedR_meas ^ NewFeedback1.speedL_meas ^ NewFeedback1.batVoltage ^ NewFeedback1.boardTemp);
  
    // Check validity of the new data
    if (NewFeedback1.start == START_FRAME && checksum == NewFeedback1.checksum) {
      // Copy the new data
      memcpy(&Feedback1, &NewFeedback1, sizeof(SerialFeedback));
    }
    idx1 = 0;  // Reset the index (it prevents to enter in this if condition in the next cycle)
    /*
      // Print data to built-in Serial
      Serial.print("1: ");   Serial.print(Feedback.cmd1);
      Serial.print(" 2: ");  Serial.print(Feedback.cmd2);
      Serial.print(" 3: ");  Serial.print(Feedback.speedR);
      Serial.print(" 4: ");  Serial.print(Feedback.speedL);
      Serial.print(" 5: ");  Serial.print(Feedback.speedR_meas);
      Serial.print(" 6: ");  Serial.print(Feedback.speedL_meas);
      Serial.print(" 7: ");  Serial.print(Feedback.batVoltage);
      Serial.print(" 8: ");  Serial.println(Feedback.boardTemp);
    } else {
      Serial.println("Non-valid data skipped");
    }*/
    
  }
  
  // Update previous states
  incomingBytePrev1  = incomingByte1;
}
void ReceiveSerial2()
{
  // Check for new data availability in the Serial buffer
  if ( Serial2.available() ) {
    incomingByte2    = Serial2.read();                                 // Read the incoming byte
    bufStartFrame2 = ((uint16_t)(incomingBytePrev2) << 8) +  incomingByte2;  // Construct the start frame    
  }
  else {
    return;
  }

  // If DEBUG_RX is defined print all incoming bytes
  #ifdef DEBUG_RX
    Serial.print(incomingByte2);
    return;
  #endif      
  
  // Copy received data
  if (bufStartFrame2 == START_FRAME) {                     // Initialize if new data is detected
    p2     = (byte *)&NewFeedback2;
    *p2++  = incomingBytePrev2;
    *p2++  = incomingByte2;   
    idx2   = 2;    
  } else if (idx2 >= 2 && idx2 < sizeof(SerialFeedback)) {  // Save the new received data
    *p2++  = incomingByte2; 
    idx2++;
  } 
  
  // Check if we reached the end of the package
  if (idx2 == sizeof(SerialFeedback)) {    
    uint16_t checksum;
    checksum = (uint16_t)(NewFeedback2.start ^ NewFeedback2.cmd1 ^ NewFeedback2.cmd2 ^ NewFeedback2.speedR ^ NewFeedback2.speedL
          ^ NewFeedback2.speedR_meas ^ NewFeedback2.speedL_meas ^ NewFeedback2.batVoltage ^ NewFeedback2.boardTemp);
  
    // Check validity of the new data
    if (NewFeedback2.start == START_FRAME && checksum == NewFeedback2.checksum) {
      // Copy the new data
      memcpy(&Feedback2, &NewFeedback2, sizeof(SerialFeedback));
    }
    idx2 = 0;  // Reset the index (it prevents to enter in this if condition in the next cycle)
    
  }
  
  // Update previous states
  incomingBytePrev2  = incomingByte2;
}

// ########################## LOOP ##########################


void loop() {
  //selfTest(); //start selftest, does not return

  ReceiveSerial1(); // Check for new received data

  if (millis()>2000 && POWERBUTTON_DOWN) {
    poweronBoards();
  }
    
  if (millis() - last_send > SENDPERIOD) {
    //Serial.print("powerbutton="); Serial.print(POWERBUTTON_DOWN); Serial.print(" modeswitch down="); Serial.println(MODESWITCH_DOWN);
    
    int _read=analogRead(PIN_THROTTLE);
    
    int16_t speedvalue=constrain( map(_read, ADC_CALIB_THROTTLE_MIN, ADC_CALIB_THROTTLE_MAX, 0, 1000 ) ,0, 1000);

    if (MODESWITCH_DOWN) {
      SendSerial1(speedvalue,0);
      SendSerial2(speedvalue,0);
      Serial.print("L_");
    }else{
      SendSerial1(0,speedvalue);
      SendSerial2(0,speedvalue);
      Serial.print("R_");
    }
    Serial.print("millis="); Serial.print(millis()); Serial.print(", adcthrottle="); Serial.print(_read); 
    Serial.print(", 1.L="); Serial.print(Command1.speedLeft); Serial.print(", 1.R="); Serial.print(Command1.speedRight);
    Serial.print(", 2.L="); Serial.print(Command2.speedLeft); Serial.print(", 2.R="); Serial.println(Command2.speedRight);

    last_send = millis();

    digitalWrite(PIN_POWERLED, !digitalRead(PIN_POWERLED));
    if (testcounter%3==0) {
      digitalWrite(PIN_MODELED_GREEN, !digitalRead(PIN_MODELED_GREEN));
    }
    if (testcounter%5==0) {
      digitalWrite(PIN_MODELED_RED, !digitalRead(PIN_MODELED_RED));
    }
    
    testcounter++;


    //Print Motor values
    Serial.print("cmd1");
    Serial.print(", ");  Serial.print("cmd2");
    Serial.print(",");  Serial.print("speedR");
    Serial.print(",");  Serial.print("speedL");
    Serial.print(", ");  Serial.print("speedR_meas");
    Serial.print(",");  Serial.print("speedL_meas");
    Serial.print(", ");  Serial.print("batVoltage");
    Serial.print(", ");  Serial.println("boardTemp");
    Serial.println();
    Serial.print("1: "); Serial.print(Feedback1.cmd1);
    Serial.print(", ");  Serial.print(Feedback1.cmd2);
    Serial.print(",");  Serial.print(Feedback1.speedR);
    Serial.print(",");  Serial.print(Feedback1.speedL);
    Serial.print(", ");  Serial.print(Feedback1.speedR_meas);
    Serial.print(",");  Serial.print(Feedback1.speedL_meas);
    Serial.print(", ");  Serial.print(Feedback1.batVoltage);
    Serial.print(", ");  Serial.println(Feedback1.boardTemp);
    Serial.println();
    Serial.print("2: "); Serial.print(Feedback2.cmd1);
    Serial.print(", ");  Serial.print(Feedback2.cmd2);
    Serial.print(",");  Serial.print(Feedback2.speedR);
    Serial.print(",");  Serial.print(Feedback2.speedL);
    Serial.print(", ");  Serial.print(Feedback2.speedR_meas);
    Serial.print(",");  Serial.print(Feedback2.speedL_meas);
    Serial.print(", ");  Serial.print(Feedback2.batVoltage);
    Serial.print(", ");  Serial.println(Feedback2.boardTemp);
  }

  if (millis()>30000 && POWERBUTTON_DOWN) {
    poweroff();
  }

}

// ########################## END ##########################


void poweroff() {

  //TODO: trigger Relais for Board 1
  // Wait for board to shut down
  //TODO: trigger Relais for Board 2
  // Wait for board to shut down
  
  //Timeout error handling

  digitalWrite(PIN_ENABLE, LOW); //poweroff own latch

  delay(1000);
  Serial.println("Still powered");
  //still powered on: set error status "power latch error"
}

void poweronBoards() {
  digitalWrite(PIN_RELAISFRONT,HIGH);
  delay(200);digitalWrite(PIN_RELAISFRONT,LOW);
  delay(50);
  digitalWrite(PIN_RELAISREAR,HIGH);
  delay(200);digitalWrite(PIN_RELAISREAR,LOW);
}


void selfTest() {
  digitalWrite(PIN_ENABLE,HIGH); //make shure latch is on
  Serial.println("Entering selftest");
  #define TESTDELAY 1000 //delay between test
  #define TESTTIME 500 //time to keep tested pin on

  delay(TESTDELAY); Serial.println("PIN_POWERLED");
  digitalWrite(PIN_POWERLED,HIGH); delay(TESTTIME); digitalWrite(PIN_POWERLED,LOW);

  delay(TESTDELAY); Serial.println("PIN_MODELED_GREEN");
  digitalWrite(PIN_MODELED_GREEN,LOW); delay(TESTTIME); digitalWrite(PIN_MODELED_GREEN,HIGH);

  delay(TESTDELAY); Serial.println("PIN_MODELED_RED");
  digitalWrite(PIN_MODELED_RED,LOW); delay(TESTTIME); digitalWrite(PIN_MODELED_RED,HIGH);

  delay(TESTDELAY); Serial.println("PIN_RELAISFRONT");
  digitalWrite(PIN_RELAISFRONT,HIGH); delay(TESTTIME); digitalWrite(PIN_RELAISFRONT,LOW);

  delay(TESTDELAY); Serial.println("PIN_RELAISREAR");
  digitalWrite(PIN_RELAISREAR,HIGH); delay(TESTTIME); digitalWrite(PIN_RELAISREAR,LOW);

  delay(TESTDELAY); Serial.println("ALL ON");
  digitalWrite(PIN_POWERLED,HIGH);
  digitalWrite(PIN_MODELED_GREEN,LOW);
  digitalWrite(PIN_MODELED_RED,LOW);
  digitalWrite(PIN_RELAISFRONT,HIGH);
  digitalWrite(PIN_RELAISREAR,HIGH);
  delay(TESTTIME*5);
  digitalWrite(PIN_POWERLED,LOW);
  digitalWrite(PIN_MODELED_GREEN,HIGH);
  digitalWrite(PIN_MODELED_RED,HIGH);
  digitalWrite(PIN_RELAISFRONT,LOW);
  digitalWrite(PIN_RELAISREAR,LOW);
  delay(TESTDELAY);

  Serial.println("Powers off latch at millis>=60000");
  Serial.println("Inputs:");
  while(true) { //Keep printing input values forever
    delay(100);
    Serial.print("millis="); Serial.print(millis()); Serial.print(", throttle ADC="); Serial.println(analogRead(PIN_THROTTLE));
    Serial.print("powerbutton down="); Serial.print(POWERBUTTON_DOWN); Serial.print(" modeswitch down="); Serial.println(MODESWITCH_DOWN);

    while (millis()>=60000) {
      digitalWrite(PIN_ENABLE, LOW); //poweroff own latch
      Serial.println(millis());
    }
  }

  
}
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`// *******************************************************************`
			`// Arduino Nano 3.3V example code`
			`// for https://github.com/EmanuelFeru/hoverboard-firmware-hack-FOC`
			`//`
			`// Copyright (C) 2019-2020 Emanuel FERU <aerdronix@gmail.com>`
			`//`
			`// *******************************************************************`
			`// INFO:`
			`// • This sketch uses the the Serial Software interface to communicate and send commands to the hoverboard`
			`// • The built-in (HW) Serial interface is used for debugging and visualization. In case the debugging is not needed,`
			`// it is recommended to use the built-in Serial interface for full speed perfomace.`
			`// • The data packaging includes a Start Frame, checksum, and re-syncronization capability for reliable communication`
			`//`
			`// CONFIGURATION on the hoverboard side in config.h:`
			`// • Option 1: Serial on Left Sensor cable (long wired cable)`
			`// #define CONTROL_SERIAL_USART2`
			`// #define FEEDBACK_SERIAL_USART2`
			`// // #define DEBUG_SERIAL_USART2`
			`// • Option 2: Serial on Right Sensor cable (short wired cable) - recommended, so the ADCs on the other cable are still available`
			`// #define CONTROL_SERIAL_USART3`
			`// #define FEEDBACK_SERIAL_USART3`
			`// // #define DEBUG_SERIAL_USART3`
			`// *******************************************************************`

			`//https://github.com/rogerclarkmelbourne/Arduino_STM32 in arduino/hardware`
			`//Board: Generic STM32F103C series`
			`//Upload method: serial`
			`//20k RAM 64k Flash`
			`//may need 3v3 from usb ttl converter (hold down flash button while connecting). Holding down the power button is not needed in this case.`
			`//Sometimes reconnecting the usb ttl converter to the pc helps just before pressing the upload button`

			`// RX(green) is A10 , TX (blue) ist A9 (3v3 level)`
			`//to flash set boot0 (the one further away from reset button) to 1 and press reset, flash, program executes immediately`
			`//set boot0 back to 0 to run program on powerup`

			`// ########################## DEFINES ##########################`
			`#define SERIAL_CONTROL_BAUD 38400 // [-] Baud rate for HoverSerial (used to communicate with the hoverboard)`
			`#define SERIAL_BAUD 115200 // [-] Baud rate for built-in Serial (used for the Serial Monitor)`
			`#define START_FRAME 0xAAAA // [-] Start frme definition for reliable serial communication`

			`//#define DEBUG_RX // [-] Debug received data. Prints all bytes to serial (comment-out to disable)`

working basic functionality for testing 2019-12-11 00:16:24 +00:00			`//#define MAXADCVALUE 4095`
			`#define ADC_CALIB_THROTTLE_MIN 2000`
			`#define ADC_CALIB_THROTTLE_MAX 3120`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
			`#define PIN_POWERLED PA0 //Red LED inside Engine Start Button. Powered with 5V via transistor`
			`#define PIN_POWERBUTTON PB8 //"Enginge Start" Button. connected To NC (=LOW). HIGH when pressed`
			`#define POWERBUTTON_DOWN digitalRead(PIN_POWERBUTTON)`

working basic functionality for testing 2019-12-11 00:16:24 +00:00			`#define SENDPERIOD 50 //ms. delay for sending speed and steer data to motor controller via serial`
			`#define PIN_THROTTLE PA4`
			`#define PIN_BRAKE PA5`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
			`#define PIN_ENABLE PB9`

			`#define PIN_MODESWITCH PB5 // LOW if pressed in ("down")`
			`#define MODESWITCH_DOWN !digitalRead(PIN_MODESWITCH)`
			`#define PIN_MODELED_GREEN PA12`
			`#define PIN_MODELED_RED PA11`

			`#define PIN_RELAISFRONT PB14 //connected to relais which presses the powerbutton of the hoverboard for the front wheels`
			`#define PIN_RELAISREAR PB15 //connected to relais which presses the powerbutton of the hoverboard for the rear wheels`

			`int testcounter=0;`

			`long last_send = 0;`


			`// Global variables`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`uint8_t idx1 = 0; // Index for new data pointer`
			`uint16_t bufStartFrame1; // Buffer Start Frame`
			`byte *p1; // Pointer declaration for the new received data`
			`byte incomingByte1;`
			`byte incomingBytePrev1;`

			`//Same for Serial2`
			`uint8_t idx2 = 0; // Index for new data pointer`
			`uint16_t bufStartFrame2; // Buffer Start Frame`
			`byte *p2; // Pointer declaration for the new received data`
			`byte incomingByte2;`
			`byte incomingBytePrev2;`

implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
			`typedef struct{`
			`uint16_t start;`
			`int16_t speedLeft;`
			`int16_t speedRight;`
			`uint16_t checksum;`
			`} SerialCommand;`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`SerialCommand Command1;`
			`SerialCommand Command2;`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
			`typedef struct{`
			`uint16_t start;`
			`int16_t cmd1;`
			`int16_t cmd2;`
			`int16_t speedR;`
			`int16_t speedL;`
			`int16_t speedR_meas;`
			`int16_t speedL_meas;`
			`int16_t batVoltage;`
			`int16_t boardTemp;`
			`int16_t checksum;`
			`} SerialFeedback;`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`SerialFeedback Feedback1;`
			`SerialFeedback NewFeedback1;`
			`SerialFeedback Feedback2;`
			`SerialFeedback NewFeedback2;`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
			`// ########################## SETUP ##########################`
			`void setup()`
			`{`

			`Serial.begin(115200); //Debug and Program. A9=TX1, A10=RX1 (3v3 level)`

working basic functionality for testing 2019-12-11 00:16:24 +00:00			`Serial1.begin(38400); //control. A2=TX2, A3=RX2 (Serial1 is Usart 2). Marked with "1" on connector`
			`Serial2.begin(38400); //control. B10=TX3, B11=RX3 (Serial2 is Usart 3). Marked with "II" on connector`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00

			`Serial1.begin(SERIAL_CONTROL_BAUD);`
			`pinMode(PIN_POWERLED, OUTPUT);`
			`pinMode(PIN_ENABLE, OUTPUT);`
			`digitalWrite(PIN_ENABLE, HIGH); //keep power on`
			`pinMode(PIN_POWERBUTTON, INPUT_PULLUP);`
			`pinMode(PIN_MODESWITCH, INPUT_PULLUP);`
			`pinMode(PIN_MODELED_GREEN, OUTPUT);`
			`pinMode(PIN_MODELED_RED, OUTPUT);`
			`pinMode(PIN_RELAISFRONT, OUTPUT);`
			`pinMode(PIN_RELAISREAR, OUTPUT);`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`pinMode(PIN_THROTTLE, INPUT);`
			`pinMode(PIN_BRAKE, INPUT);`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
			`Serial.println("Initialized");`
			`}`

			`// ########################## SEND ##########################`
			`void SendSerial1(int16_t uSpeedLeft, int16_t uSpeedRight)`
			`{`
			`// Create command`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`Command1.start = (uint16_t)START_FRAME;`
			`Command1.speedLeft = (int16_t)uSpeedLeft;`
			`Command1.speedRight = (int16_t)uSpeedRight;`
			`Command1.checksum = (uint16_t)(Command1.start ^ Command1.speedLeft ^ Command1.speedRight);`
			`Serial1.write((uint8_t *) &Command1, sizeof(Command1));`
			`}`
			`void SendSerial2(int16_t uSpeedLeft, int16_t uSpeedRight)`
			`{`
			`// Create command`
			`Command2.start = (uint16_t)START_FRAME;`
			`Command2.speedLeft = (int16_t)uSpeedLeft;`
			`Command2.speedRight = (int16_t)uSpeedRight;`
			`Command2.checksum = (uint16_t)(Command2.start ^ Command2.speedLeft ^ Command2.speedRight);`
			`Serial2.write((uint8_t *) &Command2, sizeof(Command2));`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`}`

			`// ########################## RECEIVE ##########################`
			`void ReceiveSerial1()`
			`{`
			`// Check for new data availability in the Serial buffer`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`if ( Serial1.available() ) {`
			`incomingByte1 = Serial1.read(); // Read the incoming byte`
			`bufStartFrame1 = ((uint16_t)(incomingBytePrev1) << 8) + incomingByte1; // Construct the start frame`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`}`
			`else {`
			`return;`
			`}`

			`// If DEBUG_RX is defined print all incoming bytes`
			`#ifdef DEBUG_RX`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`Serial.print(incomingByte1);`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`return;`
			`#endif`

			`// Copy received data`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`if (bufStartFrame1 == START_FRAME) { // Initialize if new data is detected`
			`p1 = (byte *)&NewFeedback1;`
			`*p1++ = incomingBytePrev1;`
			`*p1++ = incomingByte1;`
			`idx1 = 2;`
			`} else if (idx1 >= 2 && idx1 < sizeof(SerialFeedback)) { // Save the new received data`
			`*p1++ = incomingByte1;`
			`idx1++;`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`}`

			`// Check if we reached the end of the package`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`if (idx1 == sizeof(SerialFeedback)) {`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`uint16_t checksum;`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`checksum = (uint16_t)(NewFeedback1.start ^ NewFeedback1.cmd1 ^ NewFeedback1.cmd2 ^ NewFeedback1.speedR ^ NewFeedback1.speedL`
			`^ NewFeedback1.speedR_meas ^ NewFeedback1.speedL_meas ^ NewFeedback1.batVoltage ^ NewFeedback1.boardTemp);`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
			`// Check validity of the new data`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`if (NewFeedback1.start == START_FRAME && checksum == NewFeedback1.checksum) {`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`// Copy the new data`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`memcpy(&Feedback1, &NewFeedback1, sizeof(SerialFeedback));`
			`}`
			`idx1 = 0; // Reset the index (it prevents to enter in this if condition in the next cycle)`
			`/*`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`// Print data to built-in Serial`
			`Serial.print("1: "); Serial.print(Feedback.cmd1);`
			`Serial.print(" 2: "); Serial.print(Feedback.cmd2);`
			`Serial.print(" 3: "); Serial.print(Feedback.speedR);`
			`Serial.print(" 4: "); Serial.print(Feedback.speedL);`
			`Serial.print(" 5: "); Serial.print(Feedback.speedR_meas);`
			`Serial.print(" 6: "); Serial.print(Feedback.speedL_meas);`
			`Serial.print(" 7: "); Serial.print(Feedback.batVoltage);`
			`Serial.print(" 8: "); Serial.println(Feedback.boardTemp);`
			`} else {`
			`Serial.println("Non-valid data skipped");`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`}*/`

			`}`

			`// Update previous states`
			`incomingBytePrev1 = incomingByte1;`
			`}`
			`void ReceiveSerial2()`
			`{`
			`// Check for new data availability in the Serial buffer`
			`if ( Serial2.available() ) {`
			`incomingByte2 = Serial2.read(); // Read the incoming byte`
			`bufStartFrame2 = ((uint16_t)(incomingBytePrev2) << 8) + incomingByte2; // Construct the start frame`
			`}`
			`else {`
			`return;`
			`}`

			`// If DEBUG_RX is defined print all incoming bytes`
			`#ifdef DEBUG_RX`
			`Serial.print(incomingByte2);`
			`return;`
			`#endif`

			`// Copy received data`
			`if (bufStartFrame2 == START_FRAME) { // Initialize if new data is detected`
			`p2 = (byte *)&NewFeedback2;`
			`*p2++ = incomingBytePrev2;`
			`*p2++ = incomingByte2;`
			`idx2 = 2;`
			`} else if (idx2 >= 2 && idx2 < sizeof(SerialFeedback)) { // Save the new received data`
			`*p2++ = incomingByte2;`
			`idx2++;`
			`}`

			`// Check if we reached the end of the package`
			`if (idx2 == sizeof(SerialFeedback)) {`
			`uint16_t checksum;`
			`checksum = (uint16_t)(NewFeedback2.start ^ NewFeedback2.cmd1 ^ NewFeedback2.cmd2 ^ NewFeedback2.speedR ^ NewFeedback2.speedL`
			`^ NewFeedback2.speedR_meas ^ NewFeedback2.speedL_meas ^ NewFeedback2.batVoltage ^ NewFeedback2.boardTemp);`

			`// Check validity of the new data`
			`if (NewFeedback2.start == START_FRAME && checksum == NewFeedback2.checksum) {`
			`// Copy the new data`
			`memcpy(&Feedback2, &NewFeedback2, sizeof(SerialFeedback));`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`}`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`idx2 = 0; // Reset the index (it prevents to enter in this if condition in the next cycle)`

implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`}`

			`// Update previous states`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`incomingBytePrev2 = incomingByte2;`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`}`

			`// ########################## LOOP ##########################`



			`void loop() {`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`//selfTest(); //start selftest, does not return`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
			`ReceiveSerial1(); // Check for new received data`

			`if (millis()>2000 && POWERBUTTON_DOWN) {`
			`poweronBoards();`
			`}`

			`if (millis() - last_send > SENDPERIOD) {`
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`//Serial.print("powerbutton="); Serial.print(POWERBUTTON_DOWN); Serial.print(" modeswitch down="); Serial.println(MODESWITCH_DOWN);`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`int _read=analogRead(PIN_THROTTLE);`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
working basic functionality for testing 2019-12-11 00:16:24 +00:00			`int16_t speedvalue=constrain( map(_read, ADC_CALIB_THROTTLE_MIN, ADC_CALIB_THROTTLE_MAX, 0, 1000 ) ,0, 1000);`

			`if (MODESWITCH_DOWN) {`
			`SendSerial1(speedvalue,0);`
			`SendSerial2(speedvalue,0);`
			`Serial.print("L_");`
			`}else{`
			`SendSerial1(0,speedvalue);`
			`SendSerial2(0,speedvalue);`
			`Serial.print("R_");`
			`}`
			`Serial.print("millis="); Serial.print(millis()); Serial.print(", adcthrottle="); Serial.print(_read);`
			`Serial.print(", 1.L="); Serial.print(Command1.speedLeft); Serial.print(", 1.R="); Serial.print(Command1.speedRight);`
			`Serial.print(", 2.L="); Serial.print(Command2.speedLeft); Serial.print(", 2.R="); Serial.println(Command2.speedRight);`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00
			`last_send = millis();`

			`digitalWrite(PIN_POWERLED, !digitalRead(PIN_POWERLED));`
			`if (testcounter%3==0) {`
			`digitalWrite(PIN_MODELED_GREEN, !digitalRead(PIN_MODELED_GREEN));`
			`}`
			`if (testcounter%5==0) {`
			`digitalWrite(PIN_MODELED_RED, !digitalRead(PIN_MODELED_RED));`
			`}`

			`testcounter++;`
working basic functionality for testing 2019-12-11 00:16:24 +00:00

			`//Print Motor values`
			`Serial.print("cmd1");`
			`Serial.print(", "); Serial.print("cmd2");`
			`Serial.print(","); Serial.print("speedR");`
			`Serial.print(","); Serial.print("speedL");`
			`Serial.print(", "); Serial.print("speedR_meas");`
			`Serial.print(","); Serial.print("speedL_meas");`
			`Serial.print(", "); Serial.print("batVoltage");`
			`Serial.print(", "); Serial.println("boardTemp");`
			`Serial.println();`
			`Serial.print("1: "); Serial.print(Feedback1.cmd1);`
			`Serial.print(", "); Serial.print(Feedback1.cmd2);`
			`Serial.print(","); Serial.print(Feedback1.speedR);`
			`Serial.print(","); Serial.print(Feedback1.speedL);`
			`Serial.print(", "); Serial.print(Feedback1.speedR_meas);`
			`Serial.print(","); Serial.print(Feedback1.speedL_meas);`
			`Serial.print(", "); Serial.print(Feedback1.batVoltage);`
			`Serial.print(", "); Serial.println(Feedback1.boardTemp);`
			`Serial.println();`
			`Serial.print("2: "); Serial.print(Feedback2.cmd1);`
			`Serial.print(", "); Serial.print(Feedback2.cmd2);`
			`Serial.print(","); Serial.print(Feedback2.speedR);`
			`Serial.print(","); Serial.print(Feedback2.speedL);`
			`Serial.print(", "); Serial.print(Feedback2.speedR_meas);`
			`Serial.print(","); Serial.print(Feedback2.speedL_meas);`
			`Serial.print(", "); Serial.print(Feedback2.batVoltage);`
			`Serial.print(", "); Serial.println(Feedback2.boardTemp);`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`}`

working basic functionality for testing 2019-12-11 00:16:24 +00:00			`if (millis()>30000 && POWERBUTTON_DOWN) {`
implement connected buttons and testfunction 2019-12-08 17:14:28 +00:00			`poweroff();`
			`}`

			`}`

			`// ########################## END ##########################`


			`void poweroff() {`

			`//TODO: trigger Relais for Board 1`
			`// Wait for board to shut down`
			`//TODO: trigger Relais for Board 2`
			`// Wait for board to shut down`

			`//Timeout error handling`

			`digitalWrite(PIN_ENABLE, LOW); //poweroff own latch`

			`delay(1000);`
			`Serial.println("Still powered");`
			`//still powered on: set error status "power latch error"`
			`}`

			`void poweronBoards() {`
			`digitalWrite(PIN_RELAISFRONT,HIGH);`
			`delay(200);digitalWrite(PIN_RELAISFRONT,LOW);`
			`delay(50);`
			`digitalWrite(PIN_RELAISREAR,HIGH);`
			`delay(200);digitalWrite(PIN_RELAISREAR,LOW);`
			`}`





			`void selfTest() {`
			`digitalWrite(PIN_ENABLE,HIGH); //make shure latch is on`
			`Serial.println("Entering selftest");`
			`#define TESTDELAY 1000 //delay between test`
			`#define TESTTIME 500 //time to keep tested pin on`

			`delay(TESTDELAY); Serial.println("PIN_POWERLED");`
			`digitalWrite(PIN_POWERLED,HIGH); delay(TESTTIME); digitalWrite(PIN_POWERLED,LOW);`

			`delay(TESTDELAY); Serial.println("PIN_MODELED_GREEN");`
			`digitalWrite(PIN_MODELED_GREEN,LOW); delay(TESTTIME); digitalWrite(PIN_MODELED_GREEN,HIGH);`

			`delay(TESTDELAY); Serial.println("PIN_MODELED_RED");`
			`digitalWrite(PIN_MODELED_RED,LOW); delay(TESTTIME); digitalWrite(PIN_MODELED_RED,HIGH);`

			`delay(TESTDELAY); Serial.println("PIN_RELAISFRONT");`
			`digitalWrite(PIN_RELAISFRONT,HIGH); delay(TESTTIME); digitalWrite(PIN_RELAISFRONT,LOW);`

			`delay(TESTDELAY); Serial.println("PIN_RELAISREAR");`
			`digitalWrite(PIN_RELAISREAR,HIGH); delay(TESTTIME); digitalWrite(PIN_RELAISREAR,LOW);`

			`delay(TESTDELAY); Serial.println("ALL ON");`
			`digitalWrite(PIN_POWERLED,HIGH);`
			`digitalWrite(PIN_MODELED_GREEN,LOW);`
			`digitalWrite(PIN_MODELED_RED,LOW);`
			`digitalWrite(PIN_RELAISFRONT,HIGH);`
			`digitalWrite(PIN_RELAISREAR,HIGH);`
			`delay(TESTTIME*5);`
			`digitalWrite(PIN_POWERLED,LOW);`
			`digitalWrite(PIN_MODELED_GREEN,HIGH);`
			`digitalWrite(PIN_MODELED_RED,HIGH);`
			`digitalWrite(PIN_RELAISFRONT,LOW);`
			`digitalWrite(PIN_RELAISREAR,LOW);`
			`delay(TESTDELAY);`

			`Serial.println("Powers off latch at millis>=60000");`
			`Serial.println("Inputs:");`
			`while(true) { //Keep printing input values forever`
			`delay(100);`
			`Serial.print("millis="); Serial.print(millis()); Serial.print(", throttle ADC="); Serial.println(analogRead(PIN_THROTTLE));`
			`Serial.print("powerbutton down="); Serial.print(POWERBUTTON_DOWN); Serial.print(" modeswitch down="); Serial.println(MODESWITCH_DOWN);`

			`while (millis()>=60000) {`
			`digitalWrite(PIN_ENABLE, LOW); //poweroff own latch`
			`Serial.println(millis());`
			`}`
			`}`



			`}`