Introduction: Temperature Measurement Using TMP112 and Particle Photon
TMP112 High-Accuracy, Low-Power, Digital Temperature Sensor I2C MINI module. The TMP112 is ideal for extended temperature measurement. This device offers an accuracy of ±0.5°C without requiring calibration or external component signal conditioning.
In this tutorial the interfacing of the TMP112 sensor module with particle photon has been illustrated. To read the temperature values, we have used arduino with an I2c adapter.This I2C adapter makes the connection to the sensor module easy and more reliable.
Step 1: Hardware Required:
Step 2: Hardware Hookup:
The hardware hookup section basically explains the wiring connections required between the sensor and the particle photon. Ensuring correct connections is the basic necessity while working on any system for the desired output. So, the requisite connections are as follows:
The TMP112 will work over I2C . Here is the example wiring diagram, demonstrating how to wire up each interface of the sensor.
Out-of-the-box, the board is configured for an I2C interface, as such we recommend using this hookup if you’re otherwise agnostic. All you need is four wires!
Only four connections are required Vcc, Gnd, SCL and SDA pins and these are connected with the help of I2C cable.
These connections are demonstrated in the pictures above.
Step 3: Code for Temperature Measurement:
Lets start with the particle code now.
While using the sensor module with the arduino, we include application.h and spark_wiring_i2c.h library. "application.h" and spark_wiring_i2c.h library contains the functions which facilitate the i2c communication between the sensor and the particle.
The entire particle code is given below for the convenience of the user:
<p>#include<application.h> </p><p>#include<spark_wiring_i2c.h> </p><p>// TMP112 I2C address is 0x48(72)</p><p>#define Addr 0x48</p><p>double cTemp = 0.0, fTemp = 0.0;</p><p>void setup() </p><p>{ </p><p>// Set variable </p><p>Particle.variable("i2cdevice", "TMP112"); </p><p>Particle.variable("cTemp", cTemp); </p><p>// Initialise I2C communication as MASTER </p><p>Wire.begin(); </p><p>// Initialise Serial communication, set baud rate = 9600 </p><p>Serial.begin(9600); </p><p>// Start I2C Transmission </p><p>Wire.beginTransmission(Addr); </p><p>// Select configuration register </p><p>Wire.write(0x01); </p><p>// Continuous conversion, comparator mode, 12-bit resolution </p><p>Wire.write(0x60); </p><p>Wire.write(0xA0); </p><p>// Stop I2C Transmission </p><p>Wire.endTransmission(); </p><p>delay(300); </p><p>}
</p><p>void loop()</p><p>{ </p><p>unsigned int data[2]; </p><p>// Start I2C Transmission </p><p>Wire.beginTransmission(Addr); </p><p>// Select temperature data register </p><p>Wire.write(0x00); </p><p>// Stop I2C Transmission </p><p>Wire.endTransmission(); </p><p>delay(300); </p><p>// Request 2 bytes of data </p><p>Wire.requestFrom(Addr, 2); </p><p>// Read 2 bytes of data </p><p>// temp msb, temp lsb </p><p>if(Wire.available() == 2) </p><p>{ </p><p>data[0] = Wire.read(); </p><p>data[1] = Wire.read(); </p><p>} </p><p>// Convert the data to 12-bits </p><p>int temp = ((data[0] * 256) + (data[1])) / 16; </p><p>if(temp > 2048) </p><p>{ </p><p>temp -= 4096; </p><p>} </p><p>cTemp = temp * 0.0625; </p><p>fTemp = cTemp * 1.8 + 32; </p><p>// Output data to dashboard </p><p>Particle.publish("Temperature in Celsius : ", String(cTemp)); </p><p>delay(1000); </p><p>Particle.publish("Temperature in Fahrenheit: ", String(fTemp)); </p><p>delay(1000); </p><p>}</p>Particle.variable() function creates the variables to store the output of the sensor and Particle.publish() function displays the output on the dashboard of the site.
The sensor output is shown in the picture above for your reference.
Step 4: Applications:
Various applications incorporating TMP112 low power, high accuracy digital temperature sensor include Power-Supply Temperature Monitoring, Computer Peripheral Thermal Protection, Battery Management as well as office machines.
