#include <OneWire.h>
#include <DallasTemperature.h>
// Data wire is plugged into port 2 on the Arduino
#define ONE_WIRE_BUS 2
// 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);
// arrays to hold device addresses
DeviceAddress insideThermometer, outsideThermometer;
// function that will be called when an alarm condition exists during DallasTemperatures::processAlarms();
void newAlarmHandler(const uint8_t* deviceAddress)
{
Serial.println("Alarm Handler Start");
printAlarmInfo(deviceAddress);
printTemp(deviceAddress);
Serial.println();
Serial.println("Alarm Handler Finish");
}
void printCurrentTemp(DeviceAddress deviceAddress)
{
printAddress(deviceAddress);
printTemp(deviceAddress);
Serial.println();
}
void printAddress(const DeviceAddress deviceAddress)
{
Serial.print("Address: ");
for (uint8_t i = 0; i < 8; i++)
{
if (deviceAddress[i] < 16) Serial.print("0");
Serial.print(deviceAddress[i], HEX);
}
Serial.print(" ");
}
void printTemp(const DeviceAddress deviceAddress)
{
float tempC = sensors.getTempC(deviceAddress);
if (tempC != DEVICE_DISCONNECTED_C)
{
Serial.print("Current Temp C: ");
Serial.print(tempC);
}
else Serial.print("DEVICE DISCONNECTED");
Serial.print(" ");
}
void printAlarmInfo(const DeviceAddress deviceAddress)
{
char temp;
printAddress(deviceAddress);
temp = sensors.getHighAlarmTemp(deviceAddress);
Serial.print("High Alarm: ");
Serial.print(temp, DEC);
Serial.print("C");
Serial.print(" Low Alarm: ");
temp = sensors.getLowAlarmTemp(deviceAddress);
Serial.print(temp, DEC);
Serial.print("C");
Serial.print(" ");
}
void setup(void)
{
// start serial port
Serial.begin(9600);
Serial.println("Dallas Temperature IC Control Library Demo");
// Start up the library
sensors.begin();
// locate devices on the bus
Serial.print("Found ");
Serial.print(sensors.getDeviceCount(), DEC);
Serial.println(" devices.");
// search for devices on the bus and assign based on an index
if (!sensors.getAddress(insideThermometer, 0)) Serial.println("Unable to find address for Device 0");
if (!sensors.getAddress(outsideThermometer, 1)) Serial.println("Unable to find address for Device 1");
Serial.print("Device insideThermometer ");
printAlarmInfo(insideThermometer);
Serial.println();
Serial.print("Device outsideThermometer ");
printAlarmInfo(outsideThermometer);
Serial.println();
// set alarm ranges
Serial.println("Setting alarm temps...");
sensors.setHighAlarmTemp(insideThermometer, 26);
sensors.setLowAlarmTemp(insideThermometer, 22);
sensors.setHighAlarmTemp(outsideThermometer, 25);
sensors.setLowAlarmTemp(outsideThermometer, 21);
Serial.print("New insideThermometer ");
printAlarmInfo(insideThermometer);
Serial.println();
Serial.print("New outsideThermometer ");
printAlarmInfo(outsideThermometer);
Serial.println();
// attach alarm handler
sensors.setAlarmHandler(&newAlarmHandler);
}
void loop(void)
{
// ask the devices to measure the temperature
sensors.requestTemperatures();
// if an alarm condition exists as a result of the most recent
// requestTemperatures() request, it exists until the next time
// requestTemperatures() is called AND there isn't an alarm condition
// on the device
if (sensors.hasAlarm())
{
Serial.println("Oh noes! There is at least one alarm on the bus.");
}
// call alarm handler function defined by sensors.setAlarmHandler
// for each device reporting an alarm
sensors.processAlarms();
if (!sensors.hasAlarm())
{
// just print out the current temperature
printCurrentTemp(insideThermometer);
printCurrentTemp(outsideThermometer);
}
delay(1000);
}