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hydroponic-controller/include/temperature.h

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#ifndef _TEMPERATURE_H_
#define _TEMPERATURE_H_
mqttValueTiming timing_temperature_reservoir_a;
mqttValueTiming timing_temperature_reservoir_b;
mqttValueTiming timing_temperature_case;
#include <OneWire.h>
#include <DallasTemperature.h>
void printAddress(DeviceAddress deviceAddress);
//first address: 28FF6C1C7216058B
//second address:
#define ONE_WIRE_BUS 18 //GPIO pin
#define TEMPERATURE_PRECISION 12 //max is 12
#define READINTERVAL_DS18B20 1000 //ms
// Setup a oneWire instance to communicate with any OneWire devices (not just Maxim/Dallas temperature ICs)
OneWire oneWire(ONE_WIRE_BUS);
// Pass our oneWire reference to Dallas Temperature.
DallasTemperature sensors(&oneWire);
#define TEMPMEAN_SIZE 16
uint16_t tempCmean_pos=0;
// arrays to hold device addresses
DeviceAddress thermometerReservoirA={0x28,0xFF,0x6F,0x19,0x72,0x16,0x05,0x44};
float tempC_reservoir_a; //last reading
float tempCmean_reservoir_a_array[TEMPMEAN_SIZE];
float tempCmean_reservoir_a=DEVICE_DISCONNECTED_C;
//DeviceAddress thermometerAir={0x28,0xFF,0x6C,0x1C,0x72,0x16,0x05,0x8B};
DeviceAddress thermometerReservoirB={0x28,0xFF,0x30,0xBA,0x85,0x16,0x03,0xB5};
float tempC_reservoir_b; //last reading
float tempCmean_reservoir_b_array[TEMPMEAN_SIZE];
float tempCmean_reservoir_b=DEVICE_DISCONNECTED_C;
DeviceAddress thermometerCase={0x10,0x7E,0x22,0x99,0x01,0x08,0x00,0xA4};
float tempC_case; //last reading
float tempCmean_case_array[TEMPMEAN_SIZE];
float tempCmean_case=DEVICE_DISCONNECTED_C;
void temperature_setup() {
timing_temperature_reservoir_a.minchange=0.0;
timing_temperature_reservoir_a.maxchange=0.5;
timing_temperature_reservoir_a.mintime=2*1000;
timing_temperature_reservoir_a.maxtime=60*60*1000;
timing_temperature_reservoir_b.minchange=0.0;
timing_temperature_reservoir_b.maxchange=0.5;
timing_temperature_reservoir_b.mintime=2*1000;
timing_temperature_reservoir_b.maxtime=60*60*1000;
timing_temperature_case.minchange=0.0;
timing_temperature_case.maxchange=0.5;
timing_temperature_case.mintime=2*1000;
timing_temperature_case.maxtime=60*60*1000;
//initialize mean array
for (uint16_t i=0;i<TEMPMEAN_SIZE;i++) {
tempCmean_reservoir_a_array[i]=-127;
tempCmean_reservoir_b_array[i]=-127;
tempCmean_case_array[i]=-127;
}
sensors.begin();
delay(1000);
Serial.print("Locating devices...");
Serial.print("Found ");
Serial.print(sensors.getDeviceCount(), DEC);
Serial.println(" devices.");
delay(1000);
//Serial.print("Parasite power is: ");
//if (sensors.isParasitePowerMode()) Serial.println("ON");
//else Serial.println("OFF");
delay(1000);
//Just search for devices. Only needed when connecting a new sensor to find the address
oneWire.reset_search();
for (uint8_t i=0;i<sensors.getDeviceCount();i++){
DeviceAddress _addr;
if (!oneWire.search(_addr)) {
Serial.print("Error: Device not found");
String _text="Error: Device not found. id=";
_text.concat(i);
publishInfo("error/temperature",_text);
}else{
Serial.print("Found device. Address:");
printAddress(_addr);
}
Serial.println();
}
sensors.setResolution(thermometerReservoirA, TEMPERATURE_PRECISION);
sensors.setResolution(thermometerReservoirB, TEMPERATURE_PRECISION);
sensors.setResolution(thermometerCase, TEMPERATURE_PRECISION);
}
void temperature_loop(unsigned long loopmillis) {
static unsigned long last_read_ds18b20;
static bool flag_requestTemperatures=false;
if (loopmillis>last_read_ds18b20+READINTERVAL_DS18B20) {
if (loopmillis>last_read_ds18b20+READINTERVAL_DS18B20*10) { //timeout
Serial.println("Warn: Request Temperatures Timeout!");
publishInfo("error/temperature","Warn: Request Temperatures Timeout!");
flag_requestTemperatures=false;
}
if (!flag_requestTemperatures) {
sensors.requestTemperatures(); //this takes ~600ms
flag_requestTemperatures=true;
}
if (sensors.isConversionComplete()) {
flag_requestTemperatures=false;
last_read_ds18b20=loopmillis;
tempC_reservoir_a = sensors.getTempC(thermometerReservoirA);
if (tempC_reservoir_a == DEVICE_DISCONNECTED_C)
{
Serial.print(" Error reading: "); printAddress(thermometerReservoirA);
publishInfo("error/temperature","Error reading thermometerReservoirA");
}else{
tempCmean_reservoir_a_array[tempCmean_pos]=tempC_reservoir_a;
if (isValueArrayOKf(tempCmean_reservoir_a_array,TEMPMEAN_SIZE,DEVICE_DISCONNECTED_C)) {
tempCmean_reservoir_a=getMeanf(tempCmean_reservoir_a_array,TEMPMEAN_SIZE);
}else{
tempCmean_reservoir_a=DEVICE_DISCONNECTED_C;
}
}
tempC_reservoir_b = sensors.getTempC(thermometerReservoirB);
if (tempC_reservoir_b == DEVICE_DISCONNECTED_C)
{
Serial.print(" Error reading: "); printAddress(thermometerReservoirB);
publishInfo("error/temperature","Error reading thermometerReservoirB");
}else{
tempCmean_reservoir_b_array[tempCmean_pos]=tempC_reservoir_b;
if (isValueArrayOKf(tempCmean_reservoir_b_array,TEMPMEAN_SIZE,DEVICE_DISCONNECTED_C)) {
tempCmean_reservoir_b=getMeanf(tempCmean_reservoir_b_array,TEMPMEAN_SIZE);
}else{
tempCmean_reservoir_b=DEVICE_DISCONNECTED_C;
}
}
tempC_case = sensors.getTempC(thermometerCase);
if (tempC_case == DEVICE_DISCONNECTED_C)
{
Serial.print(" Error reading: "); printAddress(thermometerCase);
publishInfo("error/temperature","Error reading thermometerCase");
}else{
tempCmean_case_array[tempCmean_pos]=tempC_case;
if (isValueArrayOKf(tempCmean_case_array,TEMPMEAN_SIZE,DEVICE_DISCONNECTED_C)) {
tempCmean_case=getMeanf(tempCmean_case_array,TEMPMEAN_SIZE);
}else{
tempCmean_case=DEVICE_DISCONNECTED_C;
}
}
tempCmean_pos++;
tempCmean_pos%=TEMPMEAN_SIZE;
}
}
}
void printAddress(DeviceAddress deviceAddress)
{
for (uint8_t i = 0; i < 8; i++)
{
// zero pad the address if necessary
if (deviceAddress[i] < 16) Serial.print("0");
Serial.print(deviceAddress[i], HEX);
}
}
#endif
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