speeduino-personal/speeduino/auxiliaries.ino

/*
Speeduino - Simple engine management for the Arduino Mega 2560 platform
Copyright (C) Josh Stewart
A full copy of the license may be found in the projects root directory
*/
//integerPID boostPID(&currentStatus.MAP, &boost_pwm_target_value, &boost_cl_target_boost, configPage3.boostKP, configPage3.boostKI, configPage3.boostKD, DIRECT); //This is the PID object if that algorithm is used. Needs to be global as it maintains state outside of each function call
integerPID boostPID(&MAPx100, &boost_pwm_target_value, &boostTargetx100, configPage3.boostKP, configPage3.boostKI, configPage3.boostKD, DIRECT); //This is the PID object if that algorithm is used. Needs to be global as it maintains state outside of each function call

/*
Fan control
*/
void initialiseFan()
{
  if(configPage4.fanInv) { fanHIGH = LOW, fanLOW = HIGH; }
  else { fanHIGH = HIGH, fanLOW = LOW; }
  digitalWrite(pinFan, fanLOW);         //Initiallise program with the fan in the off state
  currentStatus.fanOn = false;
}

void fanControl()
{
  if(configPage4.fanEnable)
  {
    int onTemp = (int)configPage4.fanSP - CALIBRATION_TEMPERATURE_OFFSET;
    int offTemp = onTemp - configPage4.fanHyster;

    if (!currentStatus.fanOn && currentStatus.coolant >= onTemp) { digitalWrite(pinFan,fanHIGH); currentStatus.fanOn = true; }
    if (currentStatus.fanOn && currentStatus.coolant <= offTemp) { digitalWrite(pinFan, fanLOW); currentStatus.fanOn = false; }
  }
}

#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
void initialiseAuxPWM()
{
  TCCR1B = 0x00;          //Disbale Timer1 while we set it up
  TCNT1  = 0;             //Reset Timer Count
  TIFR1  = 0x00;          //Timer1 INT Flag Reg: Clear Timer Overflow Flag
  TCCR1A = 0x00;          //Timer1 Control Reg A: Wave Gen Mode normal (Simply counts up from 0 to 65535 (16-bit int)
  TCCR1B = (1 << CS12);   //Timer1 Control Reg B: Timer Prescaler set to 256. 1 tick = 16uS. Refer to http://www.instructables.com/files/orig/F3T/TIKL/H3WSA4V7/F3TTIKLH3WSA4V7.jpg

  boost_pin_port = portOutputRegister(digitalPinToPort(pinBoost));
  boost_pin_mask = digitalPinToBitMask(pinBoost);
  vvt_pin_port = portOutputRegister(digitalPinToPort(pinVVT_1));
  vvt_pin_mask = digitalPinToBitMask(pinVVT_1);

  boost_pwm_max_count = 1000000L / (16 * configPage3.boostFreq * 2); //Converts the frequency in Hz to the number of ticks (at 16uS) it takes to complete 1 cycle. The x2 is there because the frequency is stored at half value (in a byte) to allow freqneucies up to 511Hz
  vvt_pwm_max_count = 1000000L / (16 * configPage3.vvtFreq * 2); //Converts the frequency in Hz to the number of ticks (at 16uS) it takes to complete 1 cycle
  //TIMSK1 |= (1 << OCIE1A); //Turn on the A compare unit (ie turn on the interrupt)  //Shouldn't be needed with closed loop as its turned on below
  TIMSK1 |= (1 << OCIE1B); //Turn on the B compare unit (ie turn on the interrupt)

  boostPID.SetOutputLimits(percentage(configPage1.boostMinDuty, boost_pwm_max_count) , percentage(configPage1.boostMaxDuty, boost_pwm_max_count));
  boostPID.SetTunings(configPage3.boostKP, configPage3.boostKI, configPage3.boostKD);
  boostPID.SetMode(AUTOMATIC); //Turn PID on

  currentStatus.boostDuty = 0;
  boostCounter = 0;
}

void boostControl()
{
  if(configPage3.boostEnabled)
  {
    if(currentStatus.MAP < 100) { TIMSK1 &= ~(1 << OCIE1A); digitalWrite(pinBoost, LOW); return; } //Set duty to 0 and turn off timer compare
    MAPx100 = currentStatus.MAP * 100;

    boost_cl_target_boost = get3DTableValue(&boostTable, currentStatus.TPS, currentStatus.RPM) * 2; //Boost target table is in kpa and divided by 2
    //If flex fuel is enabled, there can be an adder to the boost target based on ethanol content
    if(configPage1.flexEnabled)
    {
      int16_t boostAdder = (((int16_t)configPage1.flexBoostHigh - (int16_t)configPage1.flexBoostLow) * currentStatus.ethanolPct) / 100;
      boostAdder = boostAdder + configPage1.flexBoostLow; //Required in case flexBoostLow is less than 0
      boost_cl_target_boost = boost_cl_target_boost + boostAdder;
    }

    boostTargetx100 = boost_cl_target_boost  * 100;
    currentStatus.boostTarget = boost_cl_target_boost >> 1; //Boost target is sent as a byte value to TS and so is divided by 2
    if(currentStatus.boostTarget == 0) { TIMSK1 &= ~(1 << OCIE1A); digitalWrite(pinBoost, LOW); return; } //Set duty to 0 and turn off timer compare if the target is 0

    if( (boostCounter & 31) == 1) { boostPID.SetTunings(configPage3.boostKP, configPage3.boostKI, configPage3.boostKD); } //This only needs to be run very infrequently, once every 32 calls to boostControl(). This is approx. once per second

    boostPID.Compute();
    currentStatus.boostDuty = (unsigned long)(boost_pwm_target_value * 100UL) / boost_pwm_max_count;
    TIMSK1 |= (1 << OCIE1A); //Turn on the compare unit (ie turn on the interrupt)
  }
  else { TIMSK1 &= ~(1 << OCIE1A); } // Disable timer channel

  boostCounter++;
}

void vvtControl()
{
  if(configPage3.vvtEnabled)
  {
    byte vvtDuty = get3DTableValue(&vvtTable, currentStatus.TPS, currentStatus.RPM);
    vvt_pwm_target_value = percentage(vvtDuty, vvt_pwm_max_count);
  }
#if defined(__AVR_ATmega1280__) || defined(__AVR_ATmega2560__)
  else { TIMSK1 &= ~(1 << OCIE1B); } // Disable timer channel
#endif
}

//The interrupt to control the Boost PWM
ISR(TIMER1_COMPA_vect)
{
  if (boost_pwm_state)
  {
    *boost_pin_port &= ~(boost_pin_mask);  // Switch pin to low
    OCR1A = TCNT1 + (boost_pwm_max_count - boost_pwm_cur_value);
    boost_pwm_state = false;
  }
  else
  {
    *boost_pin_port |= (boost_pin_mask);  // Switch pin high
    OCR1A = TCNT1 + boost_pwm_target_value;
    boost_pwm_cur_value = boost_pwm_target_value;
    boost_pwm_state = true;
  }
}

//The interrupt to control the VVT PWM
ISR(TIMER1_COMPB_vect)
{
  if (vvt_pwm_state)
  {
    *vvt_pin_port &= ~(vvt_pin_mask);  // Switch pin to low
    OCR1B = TCNT1 + (vvt_pwm_max_count - vvt_pwm_cur_value);
    vvt_pwm_state = false;
  }
  else
  {
    *vvt_pin_port |= (vvt_pin_mask);  // Switch pin high
    OCR1B = TCNT1 + vvt_pwm_target_value;
    vvt_pwm_cur_value = vvt_pwm_target_value;
    vvt_pwm_state = true;
  }
}

#elif defined (CORE_TEENSY) || defined(CORE_STM32)
//YET TO BE IMPLEMENTED ON TEENSY
void initialiseAuxPWM() { }
void boostControl() { }
void vvtControl() { }

#endif