#include "heater.h" /** \file \brief Manage heaters */ #include #include #include #include "arduino.h" #include "debug.h" #include "temp.h" #include "crc.h" #ifndef EXTRUDER #include "sersendf.h" #endif /// \struct heater_definition_t /// \brief simply holds pinout data- port, pin, pwm channel if used typedef struct { volatile uint8_t *heater_port; ///< pointer to port. DDR is inferred from this pointer too uint8_t heater_pin; ///< heater pin, not masked. eg for PB3 enter '3' here, or PB3_PIN or similar volatile uint8_t *heater_pwm; ///< pointer to 8-bit PWM register, eg OCR0A (8-bit) or ORC3L (low byte, 16-bit) } heater_definition_t; #undef DEFINE_HEATER /// \brief helper macro to fill heater definition struct from config.h // #define DEFINE_HEATER(name, port, pin, pwm) { &(port), (pin), &(pwm) }, #define DEFINE_HEATER(name, pin) { &(pin ## _WPORT), pin ## _PIN, (pin ## _PWM) }, static const heater_definition_t heaters[NUM_HEATERS] = { #include "config.h" }; #undef DEFINE_HEATER /** \var heaters_pid \brief this struct holds the heater PID factors PID is a fascinating way to control any closed loop control, combining the error (P), cumulative error (I) and rate at which we're approacing the setpoint (D) in such a way that when correctly tuned, the system will achieve target temperature quickly and with little to no overshoot At every sample, we calculate \f$OUT = k_P (S - T) + k_I \int (S - T) + k_D \frac{dT}{dt}\f$ where S is setpoint and T is temperature. The three factors kP, kI, kD are chosen to give the desired behaviour given the dynamics of the system. See http://www.eetimes.com/design/embedded/4211211/PID-without-a-PhD for the full story */ struct { int32_t p_factor; ///< scaled P factor int32_t i_factor; ///< scaled I factor int32_t d_factor; ///< scaled D factor int16_t i_limit; ///< scaled I limit, such that \f$-i_{limit} < i_{factor} < i_{limit}\f$ } heaters_pid[NUM_HEATERS]; /// \brief this struct holds the runtime heater data- PID integrator history, temperature history, sanity checker struct { int16_t heater_i; ///< integrator, \f$-i_{limit} < \sum{\Delta t} < i_{limit}\f$ uint16_t temp_history[TH_COUNT]; ///< store last TH_COUNT readings in a ring, so we can smooth out our differentiator uint8_t temp_history_pointer; ///< pointer to last entry in ring #ifdef HEATER_SANITY_CHECK uint16_t sanity_counter; ///< how long things haven't seemed sane uint16_t sane_temperature; ///< a temperature we consider sane given the heater settings #endif uint8_t heater_output; ///< this is the PID value we eventually send to the heater } heaters_runtime[NUM_HEATERS]; /// default scaled P factor, equivalent to 8.0 #define DEFAULT_P 8192 /// default scaled I factor, equivalent to 0.5 #define DEFAULT_I 512 /// default scaled D factor, equivalent to 24 #define DEFAULT_D 24576 /// default scaled I limit #define DEFAULT_I_LIMIT 384 /// this lives in the eeprom so we can save our PID settings for each heater typedef struct { int32_t EE_p_factor; int32_t EE_i_factor; int32_t EE_d_factor; int16_t EE_i_limit; uint16_t crc; ///< crc so we can use defaults if eeprom data is invalid } EE_factor; EE_factor EEMEM EE_factors[NUM_HEATERS]; /// \brief initialise heater subsystem /// Set directions, initialise PWM timers, read PID factors from eeprom, etc void heater_init() { heater_t i; // setup pins for (i = 0; i < NUM_HEATERS; i++) { *(heaters[i].heater_port) &= ~MASK(heaters[i].heater_pin); // DDR is always 1 address below PORT. ugly code but saves ram and an extra field in heaters[] which will never be used anywhere but here *(heaters[i].heater_port - 1) |= MASK(heaters[i].heater_pin); if (heaters[i].heater_pwm) { *heaters[i].heater_pwm = 0; // this is somewhat ugly too, but switch() won't accept pointers for reasons unknown switch((uint16_t) heaters[i].heater_pwm) { case (uint16_t) &OCR0A: TCCR0A |= MASK(COM0A1); break; case (uint16_t) &OCR0B: TCCR0A |= MASK(COM0B1); break; case (uint16_t) &OCR2A: TCCR2A |= MASK(COM2A1); break; case (uint16_t) &OCR2B: TCCR2A |= MASK(COM2B1); break; #ifdef TCCR3A case (uint16_t) &OCR3AL: TCCR3A |= MASK(COM3A1); break; case (uint16_t) &OCR3BL: TCCR3A |= MASK(COM3B1); break; case (uint16_t) &OCR3CL: TCCR3A |= MASK(COM3C1); break; #endif #ifdef TCCR4A case (uint16_t) &OCR4AL: TCCR4A |= MASK(COM4A1); break; case (uint16_t) &OCR4BL: TCCR4A |= MASK(COM4B1); break; case (uint16_t) &OCR4CL: TCCR4A |= MASK(COM4C1); break; #endif #ifdef TCCR5A case (uint16_t) &OCR5AL: TCCR5A |= MASK(COM5A1); break; case (uint16_t) &OCR5BL: TCCR5A |= MASK(COM5B1); break; case (uint16_t) &OCR5CL: TCCR5A |= MASK(COM5C1); break; #endif } } #ifdef HEATER_SANITY_CHECK // 0 is a "sane" temperature when we're trying to cool down heaters_runtime[i].sane_temperature = 0; #endif #ifndef BANG_BANG // read factors from eeprom heaters_pid[i].p_factor = eeprom_read_dword((uint32_t *) &EE_factors[i].EE_p_factor); heaters_pid[i].i_factor = eeprom_read_dword((uint32_t *) &EE_factors[i].EE_i_factor); heaters_pid[i].d_factor = eeprom_read_dword((uint32_t *) &EE_factors[i].EE_d_factor); heaters_pid[i].i_limit = eeprom_read_word((uint16_t *) &EE_factors[i].EE_i_limit); // if ((heaters_pid[i].p_factor == 0) && (heaters_pid[i].i_factor == 0) && (heaters_pid[i].d_factor == 0) && (heaters_pid[i].i_limit == 0)) { if (crc_block(&heaters_pid[i].p_factor, 14) != eeprom_read_word((uint16_t *) &EE_factors[i].crc)) { heaters_pid[i].p_factor = DEFAULT_P; heaters_pid[i].i_factor = DEFAULT_I; heaters_pid[i].d_factor = DEFAULT_D; heaters_pid[i].i_limit = DEFAULT_I_LIMIT; } #endif /* BANG_BANG */ } } /// \brief Write PID factors to eeprom void heater_save_settings() { #ifndef BANG_BANG heater_t i; for (i = 0; i < NUM_HEATERS; i++) { eeprom_write_dword((uint32_t *) &EE_factors[i].EE_p_factor, heaters_pid[i].p_factor); eeprom_write_dword((uint32_t *) &EE_factors[i].EE_i_factor, heaters_pid[i].i_factor); eeprom_write_dword((uint32_t *) &EE_factors[i].EE_d_factor, heaters_pid[i].d_factor); eeprom_write_word((uint16_t *) &EE_factors[i].EE_i_limit, heaters_pid[i].i_limit); eeprom_write_word((uint16_t *) &EE_factors[i].crc, crc_block(&heaters_pid[i].p_factor, 14)); } #endif /* BANG_BANG */ } /** \brief run heater PID algorithm \param h which heater we're running the loop for \param t which temp sensor this heater is attached to \param current_temp the temperature that the associated temp sensor is reporting \param target_temp the temperature we're trying to achieve */ void heater_tick(heater_t h, temp_sensor_t t, uint16_t current_temp, uint16_t target_temp) { uint8_t pid_output; #ifndef BANG_BANG int16_t heater_p; int16_t heater_d; int16_t t_error = target_temp - current_temp; #endif /* BANG_BANG */ if (h >= NUM_HEATERS || t >= NUM_TEMP_SENSORS) return; #ifndef BANG_BANG heaters_runtime[h].temp_history[heaters_runtime[h].temp_history_pointer++] = current_temp; heaters_runtime[h].temp_history_pointer &= (TH_COUNT - 1); // PID stuff // proportional heater_p = t_error; // integral heaters_runtime[h].heater_i += t_error; // prevent integrator wind-up if (heaters_runtime[h].heater_i > heaters_pid[h].i_limit) heaters_runtime[h].heater_i = heaters_pid[h].i_limit; else if (heaters_runtime[h].heater_i < -heaters_pid[h].i_limit) heaters_runtime[h].heater_i = -heaters_pid[h].i_limit; // derivative // note: D follows temp rather than error so there's no large derivative when the target changes heater_d = heaters_runtime[h].temp_history[heaters_runtime[h].temp_history_pointer] - current_temp; // combine factors int32_t pid_output_intermed = ( ( (((int32_t) heater_p) * heaters_pid[h].p_factor) + (((int32_t) heaters_runtime[h].heater_i) * heaters_pid[h].i_factor) + (((int32_t) heater_d) * heaters_pid[h].d_factor) ) / PID_SCALE ); // rebase and limit factors if (pid_output_intermed > 255) pid_output = 255; else if (pid_output_intermed < 0) pid_output = 0; else pid_output = pid_output_intermed & 0xFF; #ifdef DEBUG if (debug_flags & DEBUG_PID) sersendf_P(PSTR("T{E:%d, P:%d * %ld = %ld / I:%d * %ld = %ld / D:%d * %ld = %ld # O: %ld = %u}\n"), t_error, heater_p, heaters_pid[h].p_factor, (int32_t) heater_p * heaters_pid[h].p_factor / PID_SCALE, heaters_runtime[h].heater_i, heaters_pid[h].i_factor, (int32_t) heaters_runtime[h].heater_i * heaters_pid[h].i_factor / PID_SCALE, heater_d, heaters_pid[h].d_factor, (int32_t) heater_d * heaters_pid[h].d_factor / PID_SCALE, pid_output_intermed, pid_output); #endif #else if (current_temp >= target_temp) pid_output = BANG_BANG_OFF; else pid_output = BANG_BANG_ON; #endif #ifdef HEATER_SANITY_CHECK // check heater sanity // implementation is a moving window with some slow-down to compensate for thermal mass if (target_temp > (current_temp + (TEMP_HYSTERESIS*4))) { // heating if (current_temp > heaters_runtime[h].sane_temperature) // hotter than sane- good since we're heating unless too hot heaters_runtime[h].sane_temperature = current_temp; else { if (heaters_runtime[h].sanity_counter < 40) heaters_runtime[h].sanity_counter++; else { heaters_runtime[h].sanity_counter = 0; // ratchet up expected temp heaters_runtime[h].sane_temperature++; } } // limit to target, so if we overshoot by too much for too long an error is flagged if (heaters_runtime[h].sane_temperature > target_temp) heaters_runtime[h].sane_temperature = target_temp; } else if (target_temp < (current_temp - (TEMP_HYSTERESIS*4))) { // cooling if (current_temp < heaters_runtime[h].sane_temperature) // cooler than sane- good since we're cooling heaters_runtime[h].sane_temperature = current_temp; else { if (heaters_runtime[h].sanity_counter < 125) heaters_runtime[h].sanity_counter++; else { heaters_runtime[h].sanity_counter = 0; // ratchet down expected temp heaters_runtime[h].sane_temperature--; } } // if we're at or below 60 celsius, don't freak out if we can't drop any more. if (current_temp <= 240) heaters_runtime[h].sane_temperature = current_temp; // limit to target, so if we don't cool down for too long an error is flagged else if (heaters_runtime[h].sane_temperature < target_temp) heaters_runtime[h].sane_temperature = target_temp; } // we're within HYSTERESIS of our target else { heaters_runtime[h].sane_temperature = current_temp; heaters_runtime[h].sanity_counter = 0; } // compare where we're at to where we should be if (labs((int16_t)(current_temp - heaters_runtime[h].sane_temperature)) > (TEMP_HYSTERESIS*4)) { // no change, or change in wrong direction for a long time- heater is broken! pid_output = 0; sersendf_P(PSTR("!! heater %d or temp sensor %d broken- temp is %d.%dC, target is %d.%dC, didn't reach %d.%dC in %d0 milliseconds\n"), h, t, current_temp >> 2, (current_temp & 3) * 25, target_temp >> 2, (target_temp & 3) * 25, heaters_runtime[h].sane_temperature >> 2, (heaters_runtime[h].sane_temperature & 3) * 25, heaters_runtime[h].sanity_counter); } #endif /* HEATER_SANITY_CHECK */ heater_set(h, pid_output); } /** \brief manually set PWM output \param index the heater we're setting the output for \param value the PWM value to write anything done by this function is overwritten by heater_tick above if the heater has an associated temp sensor */ void heater_set(heater_t index, uint8_t value) { if (index >= NUM_HEATERS) return; heaters_runtime[index].heater_output = value; if (heaters[index].heater_pwm) { *(heaters[index].heater_pwm) = value; #ifdef DEBUG if (debug_flags & DEBUG_PID) sersendf_P(PSTR("PWM{%u = %u}\n"), index, OCR0A); #endif } else { if (value >= 8) *(heaters[index].heater_port) |= MASK(heaters[index].heater_pin); else *(heaters[index].heater_port) &= ~MASK(heaters[index].heater_pin); } } /** \brief turn off all heaters for emergency stop */ uint8_t heaters_all_off() { uint8_t i; for (i = 0; i < NUM_HEATERS; i++) { if (heaters_runtime[i].heater_output > 0) return 0; } return 255; } /** \brief set heater P factor \param index heater to change factor for \param p scaled P factor */ void pid_set_p(heater_t index, int32_t p) { #ifndef BANG_BANG if (index >= NUM_HEATERS) return; heaters_pid[index].p_factor = p; #endif /* BANG_BANG */ } /** \brief set heater I factor \param index heater to change I factor for \param i scaled I factor */ void pid_set_i(heater_t index, int32_t i) { #ifndef BANG_BANG if (index >= NUM_HEATERS) return; heaters_pid[index].i_factor = i; #endif /* BANG_BANG */ } /** \brief set heater D factor \param index heater to change D factor for \param d scaled D factor */ void pid_set_d(heater_t index, int32_t d) { #ifndef BANG_BANG if (index >= NUM_HEATERS) return; heaters_pid[index].d_factor = d; #endif /* BANG_BANG */ } /** \brief set heater I limit \param index heater to set I limit for \param i_limit scaled I limit */ void pid_set_i_limit(heater_t index, int32_t i_limit) { #ifndef BANG_BANG if (index >= NUM_HEATERS) return; heaters_pid[index].i_limit = i_limit; #endif /* BANG_BANG */ } #ifndef EXTRUDER /** \brief send heater debug info to host \param i index of heater to send info for */ void heater_print(uint16_t i) { sersendf_P(PSTR("P:%ld I:%ld D:%ld Ilim:%u crc:%u "), heaters_pid[i].p_factor, heaters_pid[i].i_factor, heaters_pid[i].d_factor, heaters_pid[i].i_limit, crc_block(&heaters_pid[i].p_factor, 14)); } #endif