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Edward Emelianov
2022-03-10 11:04:14 +03:00
parent 29560b7c0c
commit 733dbd75d2
1758 changed files with 14 additions and 26855 deletions
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F0:F030,F042,F072/Chiller/mainloop.c Normal file
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/*
* This file is part of the Chiller project.
* Copyright 2019 Edward V. Emelianov <edward.emelianoff@gmail.com>.
*
* 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 <http://www.gnu.org/licenses/>.
*/
#include "mainloop.h"
#include "hardware.h"
#include "adc.h"
int16_t Tset = 200; // temperature setpoint
int16_t NTCval[4] = {0,};
// common status for all functions from this file; pointer to this variable return @mainloop
static chiller_state retstatus = {
.common_state = ST_OK,
.heater_state = ST_OK,
.cooler_state = ST_OK,
.pump_state = ST_OK
};
/* error bit fields: */
// chiller_error==0 - no errors
#define CE_NOERROR (0)
// heater error (overheating)
#define CE_HEATER (1<<0)
// output was too hot
#define CE_OUTHOT (1<<1)
// output was too cool
#define CE_OUTCOOL (1<<2)
// no flow sensor pulses detected
#define CE_NOFLOW (1<<3)
// error code explaining why alarm is working
static uint8_t chiller_error;
static inline void increase_pump_pwm(){
uint16_t pwm = GET_PUMP_PWM();
if(pwm < 246){
SET_PUMP_PWM(pwm+10);
retstatus.pump_state = ST_FASTER;
}
}
static inline void decrease_pump_pwm(){
uint16_t pwm = GET_PUMP_PWM();
if(pwm > MIN_PUMP_PWM+9){
SET_PUMP_PWM(pwm-10);
retstatus.pump_state = 0; // "ST_SLOWER"
}
}
/**
* @brief binsrch - binary search for new good value
* @param oldval - previuos value
* @param curval - current value
* @param dir - direction (1 - increase, 0 - decrease)
* @return new value
*/
static inline uint16_t binsrch(uint16_t oldval, uint16_t curval, uint8_t dir){
if(oldval == curval){
if(dir) oldval = 256;
else oldval = 0;
}else{
if(dir){ // increase
if(oldval == 0) oldval = 256;
else if(oldval < curval){
oldval = 2*curval - oldval;
}
}else{ // decrease
if(curval == 0) oldval = 0;
else if(oldval > curval){
oldval = 2*curval - oldval;
}
}
}
oldval = (oldval + curval) / 2;
if(oldval > 255) oldval = 0;
return oldval;
}
// change PWM according to dir (1->up, 0->down)
static void change_heater_pwm(uint8_t dir){
static uint16_t oldpwm = 0;
uint16_t pwm = binsrch(oldpwm, GET_HEATER_PWM(), dir);
if(pwm != GET_HEATER_PWM()){
oldpwm = GET_HEATER_PWM();
SET_HEATER_PWM(pwm);
if(dir){ // up
retstatus.heater_state = ST_FASTER;
}else{ // down
if(pwm == 0) retstatus.heater_state = ST_OFF;
else retstatus.heater_state = 0; // "ST_SLOWER"
}
}
}
static void change_cooler_pwm(uint8_t dir){
uint16_t pwm = GET_COOLER_PWM();
if(dir){ // up
if(pwm < 224) SET_COOLER_PWM(pwm + 32);
else SET_COOLER_PWM(255);
if(pwm != GET_COOLER_PWM())
retstatus.cooler_state = ST_FASTER;
}else{ // down
if(pwm > MIN_COOLER_PWM + 31) SET_COOLER_PWM(pwm - 32);
else SET_COOLER_PWM(0);
if(pwm != GET_COOLER_PWM())
retstatus.cooler_state = GET_COOLER_PWM() ? 0 : ST_OFF; // "ST_SLOWER" / ST_OFF
}
}
/**
* @brief get_critical - check device for critical errors
* @return 1 if critical error occured
*/
static inline uint8_t get_critical(){
uint8_t ret = 0;
// critical state: heater can burn out!
// turn off heater & make signal
if(HEATER_TEMPERATURE > MAX_HEATER_T){
// change heater state to CRIT_HOFF
retstatus.heater_state = ST_CRITICAL;
if(GET_HEATER_PWM()){
SET_HEATER_PWM(0);
retstatus.heater_state |= ST_OFF;
}
chiller_error |= CE_HEATER;
ret = 1;
}
// very hot output: turn off heater, turn on cooler & make signal
if(OUTPUT_TEMPERATURE > MAX_OUTPUT_T){
// change chiller state to CRIT_HOT
retstatus.common_state = ST_CRITICAL;
if(GET_HEATER_PWM()){
SET_HEATER_PWM(0);
retstatus.heater_state = ST_OFF;
}
if(GET_COOLER_PWM() < 255){
SET_COOLER_PWM(255);
retstatus.cooler_state = ST_FASTER;
}
// if water @input is also too hot, turn pump to max speed
if(INPUT_TEMPERATURE > MAX_OUTPUT_T){
increase_pump_pwm();
}
chiller_error |= CE_OUTHOT;
ret = 1;
}
// very cool output: turn on heater (max power), turn off cooler & make signal
if(OUTPUT_TEMPERATURE < MIN_OUTPUT_T){
retstatus.common_state = ST_CRITICAL|ST_FASTER;
if(GET_HEATER_PWM() < 255){
SET_HEATER_PWM(255);
retstatus.heater_state = ST_FASTER;
}
if(GET_COOLER_PWM()){
SET_COOLER_PWM(0);
retstatus.cooler_state = ST_OFF;
}
chiller_error |= CE_OUTCOOL;
ret = 1;
}
// check flow rate & pump working
if(GET_PUMP_PWM() >= MIN_PUMP_PWM){ // pump working
if(flow_rate < MIN_FLOW_RATE){ // check pump
// change chiller state to CRIT_NOFLOW
retstatus.common_state = ST_CRITICAL|ST_OK;
// increase pump speed
//increase_pump_pwm();
retstatus.pump_state = ST_CRITICAL;
chiller_error |= CE_NOFLOW;
ret = 1;
}
}else{
// turn ON pump if PWM < minimal
// (pump should be never off!)
SET_PUMP_PWM(MIN_PUMP_PWM);
retstatus.pump_state = ST_FASTER;
}
return ret;
}
/**
* @brief check_alarm - check device status and turn off alarm if it is on
*/
static inline void check_alarm(){
if(!ALARM_STATE()) return;
// check errors & turn alarm OFF if there's no critical situations
if(chiller_error == CE_NOERROR){
// turn off alarm if there's no more errors
ALARM_OFF();
}else{
if(chiller_error & CE_HEATER){ // clear CE_HEATER if heater T is normal
if(HEATER_TEMPERATURE < NORMAL_HEATER_T){
chiller_error &= ~CE_HEATER;
}
}
if(chiller_error & CE_OUTHOT){ // clear CE_OUTHOT if Tout is normal
if(OUTPUT_TEMPERATURE < OUTPUT_T_H){
chiller_error &= ~CE_OUTHOT;
}
}
if(chiller_error & CE_OUTCOOL){ // clear CE_OUTCOOL if Tout is normal
if(OUTPUT_TEMPERATURE > OUTPUT_T_L){
chiller_error &= ~CE_OUTCOOL;
}
}
if(chiller_error & CE_NOFLOW){ // clear CE_NOFLOW if there's flow pulses
if(flow_rate > NORMAL_FLOW_RATE){
chiller_error &= ~CE_NOFLOW;
}
}
}
}
static inline void checkOutT(){
// check that T is between limits
int8_t hc = 0; // need heating or cooling?
if(OUTPUT_TEMPERATURE > Tset + TEMP_TOLERANCE) hc = -1; // need cooling
else if(OUTPUT_TEMPERATURE < Tset - TEMP_TOLERANCE) hc = 1; // need heating
if(hc){// out of limits -> check
if(hc > 0){ // need heating: turn off cooler & turn on heater
if(GET_COOLER_PWM()){
SET_COOLER_PWM(0);
retstatus.cooler_state = ST_OFF;
}
if(GET_HEATER_PWM() < 255){
SET_HEATER_PWM(255);
retstatus.heater_state = ST_FASTER;
}else{
// bad situation: need MORE heating!
}
}else{ // need cooling: turn off heater & turn on cooler
if(GET_HEATER_PWM()){
SET_HEATER_PWM(0);
retstatus.heater_state = ST_OFF;
}
if(GET_COOLER_PWM() < 255){
SET_COOLER_PWM(255);
retstatus.cooler_state = ST_FASTER;
}else{
// bad situation: need MORE cooling!
}
}
}else{ // T inside borders -> correct heating/cooling speed
// Tout > Tset -> heater PWM up & cooler PWM down
// else -> vice versa
uint8_t ht = 2; // don't need heater/cooler change
if(OUTPUT_TEMPERATURE < Tset - DT_TOLERANCE) ht = 1; // need heating
else if(OUTPUT_TEMPERATURE > Tset + DT_TOLERANCE) ht = 0; // need cooling
if(ht != 2){
change_heater_pwm(ht);
change_cooler_pwm(!ht);
}
}
// if all OK, make pump slower
if(retstatus.pump_state == ST_OK){
decrease_pump_pwm();
}
}
/**
* @brief mainloop - the main chiller loop
* by timer check current states & change them
*/
chiller_state *mainloop(){
static uint32_t lastTmeas = 0xffff; // Temperatures measurement time
static uint32_t lastTchk = 0xffff; // last state checking time
retstatus.common_state = ST_OK;
retstatus.heater_state = ST_OK;
retstatus.cooler_state = ST_OK;
retstatus.pump_state = ST_OK;
// 1. Get temperatures and check critical situations
if(Tms - lastTmeas < TMEASURE_MS) return &retstatus;
lastTmeas = Tms;
for(int i = 0; i < 4; ++i) // refresh NTC values
NTCval[i] = getNTC(i);
uint8_t alrm = get_critical();
// check cooler
if(GET_COOLER_PWM() > MIN_COOLER_PWM){ // cooler working
// air temperature is very hot - cooler useless
if(AIR_TEMPERATURE > OUTPUT_TEMPERATURE + TEMP_TOLERANCE){
// change cooler state to OFF
if(GET_COOLER_PWM()){
SET_COOLER_PWM(0);
retstatus.cooler_state = ST_OFF;
}
}
}else{
if(GET_COOLER_PWM()){
SET_COOLER_PWM(0);
retstatus.cooler_state = ST_OFF;
}
}
// check alarm
if(alrm){
ALARM_ON();
return &retstatus;
}
// there wasn't critical cases in this iteration, go further
check_alarm();
// Now check thermal data and decide what to do
if(Tms - lastTchk < TCHECK_MS) return &retstatus;
lastTchk = Tms;
checkOutT();
return &retstatus;
}