/*
Reprap heater funtions based on Sprinter
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see . */
/*
This softwarepart for Heatercontrol is based on Sprinter
big thanks to kliment (https://github.com/kliment/Sprinter)
*/
#include
#include "heater.h"
#include "fastio.h"
#include "pins.h"
#include "Sprinter.h"
#ifdef CONTROLLERFAN_PIN
void controllerFan(void);
#endif
#ifdef EXTRUDERFAN_PIN
void extruderFan(void);
#endif
// Manage heater variables. For a thermistor or AD595 thermocouple, raw values refer to the
// reading from the analog pin. For a MAX6675 thermocouple, the raw value is the temperature in 0.25
// degree increments (i.e. 100=25 deg).
int target_raw = 0;
int target_temp = 0;
int current_raw = 0;
int current_raw_maxval = -32000;
int current_raw_minval = 32000;
int tt_maxval;
int tt_minval;
int target_bed_raw = 0;
int current_bed_raw = 0;
unsigned long previous_millis_heater, previous_millis_bed_heater, previous_millis_monitor;
#ifdef PIDTEMP
volatile unsigned char g_heater_pwm_val = 0;
//unsigned char PWM_off_time = 0;
//unsigned char PWM_out_on = 0;
int temp_iState = 0;
int temp_dState = 0;
int prev_temp = 0;
int pTerm;
int iTerm;
int dTerm;
//int output;
int error;
int heater_duty = 0;
int temp_iState_min = 256L * -PID_INTEGRAL_DRIVE_MAX / PID_IGAIN;
int temp_iState_max = 256L * PID_INTEGRAL_DRIVE_MAX / PID_IGAIN;
#endif
#if defined(FAN_SOFT_PWM) && (FAN_PIN > -1)
volatile unsigned char g_fan_pwm_val = 0;
#endif
#ifdef AUTOTEMP
float autotemp_max=AUTO_TEMP_MAX;
float autotemp_min=AUTO_TEMP_MIN;
float autotemp_factor=AUTO_TEMP_FACTOR;
int autotemp_setpoint=0;
bool autotemp_enabled=true;
#endif
#ifndef HEATER_CURRENT
#define HEATER_CURRENT 255
#endif
#ifdef SMOOTHING
uint32_t nma = 0;
#endif
#ifdef WATCHPERIOD
int watch_raw = -1000;
unsigned long watchmillis = 0;
#endif
#ifdef MINTEMP
int minttemp = temp2analogh(MINTEMP);
#endif
#ifdef MAXTEMP
int maxttemp = temp2analogh(MAXTEMP);
#endif
#define HEAT_INTERVAL 250
#ifdef HEATER_USES_MAX6675
unsigned long max6675_previous_millis = 0;
int max6675_temp = 2000;
int read_max6675()
{
if (millis() - max6675_previous_millis < HEAT_INTERVAL)
return max6675_temp;
max6675_previous_millis = millis();
max6675_temp = 0;
#ifdef PRR
PRR &= ~(1<> 3;
}
return max6675_temp;
}
#endif
//------------------------------------------------------------------------
// Soft PWM for Heater and FAN
//------------------------------------------------------------------------
#if defined(PID_SOFT_PWM) || (defined(FAN_SOFT_PWM) && (FAN_PIN > -1))
void init_Timer2_softpwm(void)
{
// This is a simple SOFT PWM with 500 Hz for Extruder Heating
TIFR2 = (1 << TOV2); // clear interrupt flag
TCCR2B = (1 << CS22) | (1 << CS20); // start timer (ck/128 prescalar)
TCCR2A = 0;//(1 << WGM21); // Normal mode
TIMSK2 |= (1 << TOIE2);
#ifdef PID_SOFT_PWM
OCR2A = 128; // We want to have at least 500Hz or else it gets choppy
TIMSK2 |= (1 << OCIE2A); // enable timer2 output compare match interrupt
#endif
#if defined(FAN_SOFT_PWM) && (FAN_PIN > -1)
OCR2B = 128; // We want to have at least 500Hz or else it gets choppy
TIMSK2 |= (1 << OCIE2B); // enable timer2 output compare match interrupt
#endif
}
#endif
#if defined(PID_SOFT_PWM) || (defined(FAN_SOFT_PWM) && (FAN_PIN > -1))
ISR(TIMER2_OVF_vect)
{
//--------------------------------------
// Soft PWM, Heater, start PWM cycle
//--------------------------------------
#ifdef PID_SOFT_PWM
if(g_heater_pwm_val >= 2)
{
#if LED_PIN > -1
WRITE(LED_PIN,HIGH);
#endif
WRITE(HEATER_0_PIN,HIGH);
if(g_heater_pwm_val <= 253)
OCR2A = g_heater_pwm_val;
else
OCR2A = 192;
}
else
{
#if LED_PIN > -1
WRITE(LED_PIN,LOW);
#endif
WRITE(HEATER_0_PIN,LOW);
OCR2A = 192;
}
#endif
//--------------------------------------
// Soft PWM, Fan, start PWM cycle
//--------------------------------------
#if defined(FAN_SOFT_PWM) && (FAN_PIN > -1)
if(g_fan_pwm_val >= 2)
{
#if (FAN_PIN > -1)
WRITE(FAN_PIN,HIGH);
#endif
if(g_fan_pwm_val <= 253)
OCR2B = g_fan_pwm_val;
else
OCR2B = 128;
}
else
{
#if (FAN_PIN > -1)
WRITE(FAN_PIN,LOW);
#endif
OCR2B = 128;
}
#endif
}
#endif
#ifdef PID_SOFT_PWM
ISR(TIMER2_COMPA_vect)
{
if(g_heater_pwm_val > 253)
{
#if LED_PIN > -1
WRITE(LED_PIN,HIGH);
#endif
WRITE(HEATER_0_PIN,HIGH);
}
else
{
#if LED_PIN > -1
WRITE(LED_PIN,LOW);
#endif
WRITE(HEATER_0_PIN,LOW);
}
}
#endif
#if defined(FAN_SOFT_PWM) && (FAN_PIN > -1)
ISR(TIMER2_COMPB_vect)
{
if(g_fan_pwm_val > 253)
{
#if (FAN_PIN > -1)
WRITE(FAN_PIN,HIGH);
#endif
}
else
{
#if (FAN_PIN > -1)
WRITE(FAN_PIN,LOW);
#endif
}
}
#endif
//--------------------END SOFT PWM---------------------------
//-------------------- START PID AUTOTUNE ---------------------------
// Based on PID relay test
// Thanks to Erik van der Zalm for this idea to use it for Marlin
// Some information see:
// http://brettbeauregard.com/blog/2012/01/arduino-pid-autotune-library/
//------------------------------------------------------------------
#ifdef PID_AUTOTUNE
void PID_autotune(int PIDAT_test_temp)
{
float PIDAT_input = 0;
int PIDAT_input_help = 0;
unsigned char PIDAT_count_input = 0;
float PIDAT_max, PIDAT_min;
unsigned char PIDAT_PWM_val = 255;
unsigned char PIDAT_cycles=0;
bool PIDAT_heating = true;
unsigned long PIDAT_temp_millis = millis();
unsigned long PIDAT_t1=PIDAT_temp_millis;
unsigned long PIDAT_t2=PIDAT_temp_millis;
unsigned long PIDAT_T_check_AI_val = PIDAT_temp_millis;
unsigned char PIDAT_cycle_cnt = 0;
long PIDAT_t_high;
long PIDAT_t_low;
long PIDAT_bias= 127;
long PIDAT_d = 127;
float PIDAT_Ku, PIDAT_Tu;
float PIDAT_Kp, PIDAT_Ki, PIDAT_Kd;
#define PIDAT_TIME_FACTOR ((HEATER_CHECK_INTERVAL*256.0) / 1000.0)
showString(PSTR("PID Autotune start\r\n"));
target_temp = PIDAT_test_temp;
#ifdef BED_USES_THERMISTOR
WRITE(HEATER_1_PIN,LOW);
#endif
for(;;)
{
if((millis() - PIDAT_T_check_AI_val) > 100 )
{
PIDAT_T_check_AI_val = millis();
PIDAT_cycle_cnt++;
#ifdef HEATER_USES_THERMISTOR
current_raw = analogRead(TEMP_0_PIN);
current_raw = 1023 - current_raw;
PIDAT_input_help += analog2temp(current_raw);
PIDAT_count_input++;
#elif defined HEATER_USES_AD595
current_raw = analogRead(TEMP_0_PIN);
PIDAT_input_help += analog2temp(current_raw);
PIDAT_count_input++;
#elif defined HEATER_USES_MAX6675
current_raw = read_max6675();
PIDAT_input_help += analog2temp(current_raw);
PIDAT_count_input++;
#endif
}
if(PIDAT_cycle_cnt >= 10 )
{
PIDAT_cycle_cnt = 0;
PIDAT_input = (float)PIDAT_input_help / (float)PIDAT_count_input;
PIDAT_input_help = 0;
PIDAT_count_input = 0;
PIDAT_max=max(PIDAT_max,PIDAT_input);
PIDAT_min=min(PIDAT_min,PIDAT_input);
if(PIDAT_heating == true && PIDAT_input > PIDAT_test_temp)
{
if(millis() - PIDAT_t2 > 5000)
{
PIDAT_heating = false;
PIDAT_PWM_val = (PIDAT_bias - PIDAT_d);
PIDAT_t1 = millis();
PIDAT_t_high = PIDAT_t1 - PIDAT_t2;
PIDAT_max = PIDAT_test_temp;
}
}
if(PIDAT_heating == false && PIDAT_input < PIDAT_test_temp)
{
if(millis() - PIDAT_t1 > 5000)
{
PIDAT_heating = true;
PIDAT_t2 = millis();
PIDAT_t_low = PIDAT_t2 - PIDAT_t1;
if(PIDAT_cycles > 0)
{
PIDAT_bias += (PIDAT_d*(PIDAT_t_high - PIDAT_t_low))/(PIDAT_t_low + PIDAT_t_high);
PIDAT_bias = constrain(PIDAT_bias, 20 ,235);
if(PIDAT_bias > 127) PIDAT_d = 254 - PIDAT_bias;
else PIDAT_d = PIDAT_bias;
showString(PSTR(" bias: ")); Serial.print(PIDAT_bias);
showString(PSTR(" d: ")); Serial.print(PIDAT_d);
showString(PSTR(" min: ")); Serial.print(PIDAT_min);
showString(PSTR(" max: ")); Serial.println(PIDAT_max);
if(PIDAT_cycles > 2)
{
PIDAT_Ku = (4.0*PIDAT_d)/(3.14159*(PIDAT_max-PIDAT_min));
PIDAT_Tu = ((float)(PIDAT_t_low + PIDAT_t_high)/1000.0);
showString(PSTR(" Ku: ")); Serial.print(PIDAT_Ku);
showString(PSTR(" Tu: ")); Serial.println(PIDAT_Tu);
PIDAT_Kp = 0.60*PIDAT_Ku;
PIDAT_Ki = 2*PIDAT_Kp/PIDAT_Tu;
PIDAT_Kd = PIDAT_Kp*PIDAT_Tu/8;
showString(PSTR(" Clasic PID \r\n"));
//showString(PSTR(" Kp: ")); Serial.println(PIDAT_Kp);
//showString(PSTR(" Ki: ")); Serial.println(PIDAT_Ki);
//showString(PSTR(" Kd: ")); Serial.println(PIDAT_Kd);
showString(PSTR(" CFG Kp: ")); Serial.println((unsigned int)(PIDAT_Kp*256));
showString(PSTR(" CFG Ki: ")); Serial.println((unsigned int)(PIDAT_Ki*PIDAT_TIME_FACTOR));
showString(PSTR(" CFG Kd: ")); Serial.println((unsigned int)(PIDAT_Kd*PIDAT_TIME_FACTOR));
PIDAT_Kp = 0.30*PIDAT_Ku;
PIDAT_Ki = PIDAT_Kp/PIDAT_Tu;
PIDAT_Kd = PIDAT_Kp*PIDAT_Tu/3;
showString(PSTR(" Some overshoot \r\n"));
showString(PSTR(" CFG Kp: ")); Serial.println((unsigned int)(PIDAT_Kp*256));
showString(PSTR(" CFG Ki: ")); Serial.println((unsigned int)(PIDAT_Ki*PIDAT_TIME_FACTOR));
showString(PSTR(" CFG Kd: ")); Serial.println((unsigned int)(PIDAT_Kd*PIDAT_TIME_FACTOR));
/*
PIDAT_Kp = 0.20*PIDAT_Ku;
PIDAT_Ki = 2*PIDAT_Kp/PIDAT_Tu;
PIDAT_Kd = PIDAT_Kp*PIDAT_Tu/3;
showString(PSTR(" No overshoot \r\n"));
showString(PSTR(" CFG Kp: ")); Serial.println((unsigned int)(PIDAT_Kp*256));
showString(PSTR(" CFG Ki: ")); Serial.println((unsigned int)(PIDAT_Ki*PIDAT_TIME_FACTOR));
showString(PSTR(" CFG Kd: ")); Serial.println((unsigned int)(PIDAT_Kd*PIDAT_TIME_FACTOR));
*/
}
}
PIDAT_PWM_val = (PIDAT_bias + PIDAT_d);
PIDAT_cycles++;
PIDAT_min = PIDAT_test_temp;
}
}
#ifdef PID_SOFT_PWM
g_heater_pwm_val = PIDAT_PWM_val;
#else
analogWrite_check(HEATER_0_PIN, PIDAT_PWM_val);
#if LED_PIN>-1
analogWrite_check(LED_PIN, PIDAT_PWM_val);
#endif
#endif
}
if(PIDAT_input > (PIDAT_test_temp + 20))
{
showString(PSTR("PID Autotune failed! Temperature to high\r\n"));
return;
}
if(millis() - PIDAT_temp_millis > 2000)
{
PIDAT_temp_millis = millis();
showString(PSTR("ok T:"));
Serial.print(PIDAT_input);
showString(PSTR(" @:"));
Serial.println((unsigned char)PIDAT_PWM_val*1);
}
if(((millis() - PIDAT_t1) + (millis() - PIDAT_t2)) > (10L*60L*1000L*2L))
{
showString(PSTR("PID Autotune failed! timeout\r\n"));
return;
}
if(PIDAT_cycles > 5)
{
showString(PSTR("PID Autotune finished ! Place the Kp, Ki and Kd constants in the configuration.h\r\n"));
return;
}
}
}
#endif
//---------------- END AUTOTUNE PID ------------------------------
void updatePID()
{
#ifdef PIDTEMP
temp_iState_min = (256L * -PID_INTEGRAL_DRIVE_MAX) / PID_Ki;
temp_iState_max = (256L * PID_INTEGRAL_DRIVE_MAX) / PID_Ki;
#endif
}
void manage_heater()
{
//Temperatur Monitor for repetier
if((millis() - previous_millis_monitor) > 250 )
{
previous_millis_monitor = millis();
if(manage_monitor <= 1)
{
showString(PSTR("MTEMP:"));
Serial.print(millis());
if(manage_monitor<1)
{
showString(PSTR(" "));
Serial.print(analog2temp(current_raw));
showString(PSTR(" "));
Serial.print(target_temp);
showString(PSTR(" "));
#ifdef PIDTEMP
Serial.println(heater_duty);
#else
#if (HEATER_0_PIN > -1)
if(READ(HEATER_0_PIN))
Serial.println(255);
else
Serial.println(0);
#else
Serial.println(0);
#endif
#endif
}
#if THERMISTORBED!=0
else
{
showString(PSTR(" "));
Serial.print(analog2tempBed(current_bed_raw));
showString(PSTR(" "));
Serial.print(analog2tempBed(target_bed_raw));
showString(PSTR(" "));
#if (HEATER_1_PIN > -1)
if(READ(HEATER_1_PIN))
Serial.println(255);
else
Serial.println(0);
#else
Serial.println(0);
#endif
}
#endif
}
}
// ENDE Temperatur Monitor for repetier
if((millis() - previous_millis_heater) < HEATER_CHECK_INTERVAL )
return;
previous_millis_heater = millis();
#ifdef HEATER_USES_THERMISTOR
current_raw = analogRead(TEMP_0_PIN);
#ifdef DEBUG_HEAT_MGMT
log_int("_HEAT_MGMT - analogRead(TEMP_0_PIN)", current_raw);
log_int("_HEAT_MGMT - NUMTEMPS", NUMTEMPS);
#endif
// When using thermistor, when the heater is colder than targer temp, we get a higher analog reading than target,
// this switches it up so that the reading appears lower than target for the control logic.
current_raw = 1023 - current_raw;
#elif defined HEATER_USES_AD595
current_raw = analogRead(TEMP_0_PIN);
#elif defined HEATER_USES_MAX6675
current_raw = read_max6675();
#endif
//MIN / MAX save to display the jitter of Heaterbarrel
if(current_raw > current_raw_maxval)
current_raw_maxval = current_raw;
if(current_raw < current_raw_minval)
current_raw_minval = current_raw;
#ifdef SMOOTHING
if (!nma) nma = SMOOTHFACTOR * current_raw;
nma = (nma + current_raw) - (nma / SMOOTHFACTOR);
current_raw = nma / SMOOTHFACTOR;
#endif
#ifdef WATCHPERIOD
if(watchmillis && millis() - watchmillis > WATCHPERIOD)
{
if(watch_raw + 1 >= current_raw)
{
target_temp = target_raw = 0;
WRITE(HEATER_0_PIN,LOW);
#ifdef PID_SOFT_PWM
g_heater_pwm_val = 0;
#else
analogWrite(HEATER_0_PIN, 0);
#if LED_PIN>-1
WRITE(LED_PIN,LOW);
#endif
#endif
}
else
{
watchmillis = 0;
}
}
#endif
//If tmp is lower then MINTEMP stop the Heater
//or it os better to deaktivate the uutput PIN or PWM ?
#ifdef MINTEMP
if(current_raw <= minttemp)
target_temp = target_raw = 0;
#endif
#ifdef MAXTEMP
if(current_raw >= maxttemp)
{
target_temp = target_raw = 0;
#if (ALARM_PIN > -1)
WRITE(ALARM_PIN,HIGH);
#endif
}
#endif
#if (TEMP_0_PIN > -1) || defined (HEATER_USES_MAX6675) || defined (HEATER_USES_AD595)
#ifdef PIDTEMP
int current_temp = analog2temp(current_raw);
error = target_temp - current_temp;
int delta_temp = current_temp - prev_temp;
prev_temp = current_temp;
pTerm = ((long)PID_Kp * error) / 256;
const int H0 = min(HEATER_DUTY_FOR_SETPOINT(target_temp),HEATER_CURRENT);
heater_duty = H0 + pTerm;
if(error < 30)
{
temp_iState += error;
temp_iState = constrain(temp_iState, temp_iState_min, temp_iState_max);
iTerm = ((long)PID_Ki * temp_iState) / 256;
heater_duty += iTerm;
}
int prev_error = abs(target_temp - prev_temp);
int log3 = 1; // discrete logarithm base 3, plus 1
if(prev_error > 81){ prev_error /= 81; log3 += 4; }
if(prev_error > 9){ prev_error /= 9; log3 += 2; }
if(prev_error > 3){ prev_error /= 3; log3 ++; }
dTerm = ((long)PID_Kd * delta_temp) / (256*log3);
heater_duty += dTerm;
heater_duty = constrain(heater_duty, 0, HEATER_CURRENT);
#ifdef PID_SOFT_PWM
if(target_raw != 0)
g_heater_pwm_val = (unsigned char)heater_duty;
else
g_heater_pwm_val = 0;
#else
if(target_raw != 0)
analogWrite(HEATER_0_PIN, heater_duty);
else
analogWrite(HEATER_0_PIN, 0);
#if LED_PIN>-1
if(target_raw != 0)
analogWrite(LED_PIN, constrain(LED_PWM_FOR_BRIGHTNESS(heater_duty),0,255));
else
analogWrite(LED_PIN, 0);
#endif
#endif
#else
if(current_raw >= target_raw)
{
WRITE(HEATER_0_PIN,LOW);
#if LED_PIN>-1
WRITE(LED_PIN,LOW);
#endif
}
else
{
if(target_raw != 0)
{
WRITE(HEATER_0_PIN,HIGH);
#if LED_PIN > -1
WRITE(LED_PIN,HIGH);
#endif
}
}
#endif
#endif
if(millis() - previous_millis_bed_heater < BED_CHECK_INTERVAL)
return;
previous_millis_bed_heater = millis();
#ifndef TEMP_1_PIN
return;
#endif
#if TEMP_1_PIN == -1
return;
#else
#ifdef BED_USES_THERMISTOR
current_bed_raw = analogRead(TEMP_1_PIN);
#ifdef DEBUG_HEAT_MGMT
log_int("_HEAT_MGMT - analogRead(TEMP_1_PIN)", current_bed_raw);
log_int("_HEAT_MGMT - BNUMTEMPS", BNUMTEMPS);
#endif
// If using thermistor, when the heater is colder than targer temp, we get a higher analog reading than target,
// this switches it up so that the reading appears lower than target for the control logic.
current_bed_raw = 1023 - current_bed_raw;
#elif defined BED_USES_AD595
current_bed_raw = analogRead(TEMP_1_PIN);
#endif
#ifdef MINTEMP
if(current_bed_raw >= target_bed_raw || current_bed_raw < minttemp)
#else
if(current_bed_raw >= target_bed_raw)
#endif
{
WRITE(HEATER_1_PIN,LOW);
}
else
{
WRITE(HEATER_1_PIN,HIGH);
}
#endif
#ifdef CONTROLLERFAN_PIN
controllerFan(); //Check if fan should be turned on to cool stepper drivers down
#endif
#ifdef EXTRUDERFAN_PIN
extruderFan(); //Check if fan should be turned on to cool extruder down
#endif
}
#if defined (HEATER_USES_THERMISTOR) || defined (BED_USES_THERMISTOR)
int temp2analog_thermistor(int celsius, const short table[][2], int numtemps)
{
int raw = 0;
byte i;
for (i=1; i raw)
{
celsius = table[i-1][1] +
(raw - table[i-1][0]) *
(table[i][1] - table[i-1][1]) /
(table[i][0] - table[i-1][0]);
break;
}
}
// Overflow: Set to last value in the table
if (i == numtemps) celsius = table[i-1][1];
return celsius;
}
#endif
#if defined (HEATER_USES_AD595) || defined (BED_USES_AD595)
int analog2temp_ad595(int raw)
{
return raw * 500 / 1024;
}
#endif
#if defined (HEATER_USES_MAX6675) || defined (BED_USES_MAX6675)
int analog2temp_max6675(int raw)
{
return raw / 4;
}
#endif
#ifdef CONTROLLERFAN_PIN
unsigned long lastMotor = 0; //Save the time for when a motor was turned on last
unsigned long lastMotorCheck = 0;
void controllerFan()
{
if ((millis() - lastMotorCheck) >= 2500) //Not a time critical function, so we only check every 2500ms
{
lastMotorCheck = millis();
if(!READ(X_ENABLE_PIN) || !READ(Y_ENABLE_PIN) || !READ(Z_ENABLE_PIN) || !READ(E_ENABLE_PIN)) //If any of the drivers are enabled...
{
lastMotor = millis(); //... set time to NOW so the fan will turn on
}
if ((millis() - lastMotor) >= (CONTROLLERFAN_SEC*1000UL) || lastMotor == 0) //If the last time any driver was enabled, is longer since than CONTROLLERSEC...
{
WRITE(CONTROLLERFAN_PIN, LOW); //... turn the fan off
}
else
{
WRITE(CONTROLLERFAN_PIN, HIGH); //... turn the fan on
}
}
}
#endif
#ifdef EXTRUDERFAN_PIN
unsigned long lastExtruderCheck = 0;
void extruderFan()
{
if ((millis() - lastExtruderCheck) >= 2500) //Not a time critical function, so we only check every 2500ms
{
lastExtruderCheck = millis();
if (analog2temp(current_raw) < EXTRUDERFAN_DEC)
{
WRITE(EXTRUDERFAN_PIN, LOW); //... turn the fan off
}
else
{
WRITE(EXTRUDERFAN_PIN, HIGH); //... turn the fan on
}
}
}
#endif