Send Local Temp from chipKIT and Raspberry Pi to Exosite Cloud

Local Temp from chipKIT and Raspberry Pi published to Exosite Cloud
Local Temp from chipKIT and Raspberry Pi published to Exosite Cloud

The tutorial we’re sharing today is a follow-on post to the Local Temp with chipKIT and Raspberry Pi post, and is an example of how you can take the previous tutorial to the next level.

So, you’ve collected the temperature data via the chipKIT uC32 and the Basic I/O Shield, you’ve sent the data to the Raspberry Pi, but now what do you do with it? This tutorial will show you how to take that data and publish it to the cloud, the Exosite cloud to be sure! For more information on how to create your own IoT application, see a previous post about Exosite, a company that makes connecting devices, networks, and users a breeze via their cloud-based data platform.

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Local Temp with chipKIT and Raspberry Pi

Local Temperature from chipKIT uC32 & Basic I/O Shield sent to Raspberry Pi and displayed on screen via Python
Local Temperature from chipKIT uC32 & Basic I/O Shield sent to Raspberry Pi and displayed on screen via Python

The tutorial we’re sharing today shows you how to take temperature readings via chipKIT uC32 (or Uno32) and the Basic I/O Shield, and send this information to Raspberry Pi, where the sky is the limit with the things you can do. In this particular example, you can display the temperature readings in the GUI via a Python script.

Find the tutorial and more information on the RedAcacia blog.

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Temperature-Sensing Coffee Coaster with chipKIT

Using a chipKIT Pro MX7, Sam from Digilent has created a Temperature-Sensing Coaster! As he mentions in the post, now you can hit that perfect “Goldilocks” temperature; coffee that is not too hot, not too cold, but just right!

To find out more, visit Digilent’s blogpost.

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Serial Communication – I2C Temperature sensor output to OLED


In this project you will learn to use a basic functionality of chipKIT board, which is to use serial communication I2C bus to measure the room temperature and output the corresponding digital reading for it. I2C bus is a master slave bus, which communicates data from the processor on chipKIT board to other peripherals. More description on I2C communication can be found on the Wikipedia website.

Hardware Used:

The hardware used in this tutorial will be a chipKIT Uno32 along with a chipKIT Basic I/O Shield both manufactured by Digilent Inc.


The reference guide for each board, schematics and other resources are available on their individual homepages:


  1. Go to the chipKIT Basic I/O Shield homepage mentioned in the reference section. Download the zip file that contains libraries and documentation for using the Basic I/O Shield™ with the chipKIT MPIDE. Open the downloaded zip folder and copy the three IOShield folders in it. These three folders have the libraries and example programs for EEPROM, OLED and Temperature Sensor peripherals on IO shield.
  2. Now open the drive where you installed the mpide software, inside your mpide folder navigate through hardware > pic32 > libraries and paste the three IOShield folders in it.
  3. Close your mpide software, for the libraries to get included and the changes to take effect.
  4. On restarting the mpide software and navigating through File > Examples; you can find IOShieldEEPROM, IOShieldOled and IOShieldTemp folders with their demo examples being included.
  5. As an initial test, you can run the existing example code for temperature sensor peripheral of the IO Shield. To do this navigate through and open File > Examples > IOShieldOled > IOShield_Oled_Demo. 
  6. Once the new sketch is opened, click the Verify button and this will compile successfully unless the library file is not included properly.
  7. Make sure you connect the Uno32 board via the mini-B connector on board to an available port on your computer.
  8. Place the IO shield on top of the Uno32 board with a bit of a firm press.
  9. Once connected, in your MPIDE window, select Tools>Board>chipKIT UNO32 to identify the UNO32 Board as the target
  10. Next, select Tools>Serial Port>COMxx. This will depend on which port was assigned to the chipKIT UNO32 Board when first connected.
  11. To load your sketch onto the chipKIT UNO32 board’s Microcontroller, press the Upload button. This will compile your sketch (check for errors) and then send to the Microcontroller. Unless you type your own code in the sketch, you wouldn’t need to verify them before uploading.
  12. Once the code is done uploading, open the serial monitor from the toolbar and after a few seconds of delay the temperature will be displayed in Celsius and Fahrenheit as shown below, tempsensor1
  13. As a next step, the Organic LED present in the IO shield can be used to display the temperature.
  14. Make sure that the jumper settings for JP4 on chipKIT Uno32 board is configured as SPI Slave Select input mode. You can find the jumper settings in chipKIT Uno32 board reference manual from the Digilent website. Also, ensure that the jumpers JP6/JP8 are configured to be used as I2C communication lines.
  15. To make the temperature be displayed on OLED, create a new sketch, save it by giving a name and insert the code below in the sketch space.
    #include <IOShieldTemp.h>
    #include <IOShieldOled.h>
    #include <Wire.h>
    int tensc = 0;
    int onesc = 0;
    int dot_tensc = 0;
    int dot_onesc = 0;
    int tensf = 0;
    int onesf = 0;
    int dot_tensf = 0;
    int dot_onesf = 0;
    int tempC=0;
    int tempF=0;
    void setup()
    void loop() 
      float tempf, tempc;
      //Get Temperature in Celsius.
      tempc = IOShieldTemp.getTemp();
      // Convert the result to Fahrenheit.
      tempf = IOShieldTemp.convCtoF(tempc);
      //parse data for temperature in celcius
      dot_onesc = tempC%10;
      tempC = tempC/10;
      dot_tensc = tempC%10;
      tempC = tempC/10;
      onesc = tempC%10;
      tempC = tempC/10;
      tensc = tempC%10;
      //convert data to ASCII for temperature in celcius
       tensc = tensc+48;
       onesc = onesc+48;
       dot_tensc = dot_tensc+48;
       dot_onesc = dot_onesc+48;
      //parse data for temperature in Fahrenheit
      dot_onesf = tempF%10;
      tempF = tempF/10;
      dot_tensf = tempF%10;
      tempF = tempF/10;
      onesf = tempF%10;
      tempF = tempF/10;
      tensf = tempF%10;
      //convert data to ASCII for temperature in Fahrenheit
       tensf = tensf+48;
       onesf = onesf+48;
       dot_tensf = dot_tensf+48;
       dot_onesf = dot_onesf+48;
      //Clear the virtual buffer
      //Draw a rectangle over wrting then slide the rectagle
      //down slowly displaying all writing
        IOShieldOled.setCursor(0, 0);
        IOShieldOled.putString("Tempertaure is");
        IOShieldOled.setCursor(0, 2);
        IOShieldOled.setCursor(1, 2);
        IOShieldOled.setCursor(2, 2);
        IOShieldOled.setCursor(3, 2);
        IOShieldOled.setCursor(4, 2);
        IOShieldOled.setCursor(6, 2);
        IOShieldOled.putString(" Degrees C");
        IOShieldOled.setCursor(0, 3);
        IOShieldOled.setCursor(1, 3);
        IOShieldOled.setCursor(2, 3);
        IOShieldOled.setCursor(3, 3);
        IOShieldOled.setCursor(4, 3);
        IOShieldOled.setCursor(6, 3);
        IOShieldOled.putString(" Degrees F");
  16. In this code, the floating point values of temperature in celcius and fahrenheit are received, separated into digits by parsing the value and each digit is expressed in ASCII, aligning the position on OLED screen.
  17. To get more details on each function used with respect to OLED, open the IOShieldOLED folder which you downloaded from Digilent website and refer IOShield Library – Oeld.pdf. The same apply for functions for TEMP sensor too.
  18. To get the display, verify the code and upload it to the board. Once uploaded, you can see the temperature value displayed on OLED.
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