Temperature Log Example

This example describes how to store sensor data and process it on the computer. We are going to read environment temperature and save the values on a microSD card. After this we will connect the microSD card to the computer and analyze the obtained temperature values.

Required hardware #

Arduino Uno board

TMP36 analog temperature sensor

microSD breakout board

Formatted microSD card

Breadboard

Hook-up wires

The analog thermometer is connected to the A0 analog port on the Arduino board.

analog port on the Arduino board. The microSD breakout boards usually use an SPI interface to communicate. Arduino Uno provides SPI on pins 11 , 12 , and 13 . The CS pin can be connected to an arbitrary digital pin. We chose 10 .

Note If you are using another board model look at its pinout to connect to the SPI bus correctly.

Create a new project in XOD and name it something like temparature-log .

Source data #

As we use the TMP36 based thermometer we add a thermometer-tmp36 to the patch. This thermometer should be connected to an analog Arduino port. We connected our sensor to A0 , so set the PORT pin value to A0 .

to the patch. This thermometer should be connected to an analog Arduino port. We connected our sensor to , so set the pin value to . Next, we want to bind the temperature to a timestamp when it was read. For this place a system-time node. This node outputs time in seconds passed since the program start.

node. This node outputs time in seconds passed since the program start. If we want to update the data continuously we’d better number each new record. The count node will do it for us. Place it onto the patch and set the STEP value to 1.

By now we have three data sources on the patch.

Limit frequency #

We need to set a frequency of readings to limit the data volume and to give some time for the microSD board to flush the file after each record. The easiest way to do this is to use a clock node. Place it onto the patch and link with all three data sources.

The IVAL pin is responsible for the pulse generation frequency and, as a consequence, for extracting a new set of data. We decided to receive and record data 4 times per second, so we set IVAL value to 0.25 (=¼).

Format data #

We predict lots of data. For easier processing it is a good idea to format it as a table. Each row may represent a single record: the record number, record timestamp, and a temperature value read at that moment. To combine all data values and store them as a single string, use the join node. Place join onto the patch and link it with all data sources.

The D pin of the join node is used to delimit the values. With this pin you can set the a character or string you want to delimit the values.

There are numerous text-based formats for storing and exchanging data. The examples of such formats are CSV (Comma-Separated Values) or TSV (Tab-separated values). These text formats are used to store tabular data and to exchange it between different computer programs. Notably, spreadsheet applications such as Google Spreadsheets, Microsoft Excel, LibreOffice Calc can easily import such files. Look at a CSV file example which defines track durations for a music album:

No.,Title,Length 1,Hells Bells,5:12 2,Shoot to Thrill,5:17 3,What Do You Do for Money Honey,3:35 4,Givin’ the Dog a Bone,3:31 5,Let Me Put My Love into You,4:15 6,Back in Black,4:15 7,You Shook Me All Night Long,3:30 8,Have a Drink on Me,3:58 9,Shake a Leg,4:05 10,Rock And Roll Ain’t Noise Pollution,4:15

So, let’s use the TSV text-format for storing. To delimit the values with tabs place the \t character into the D pin of the join node. The backslash-t is a special escape-sequence to denote the TAB character because it can’t be easily printed and displayed in IDE.

Store data #

XOD provides an sd-log node to append text lines to the tail of the specified file stored on an SD card. Add the sd-log node onto the patch and set up its inputs:

Link its LINE pin with the join output.

pin with the output. The CS pin is used to set up the number of the chip select pin of the SPI interface on the Arduino board. In this example it is D10 .

pin is used to set up the number of the chip select pin of the SPI interface on the Arduino board. In this example it is . The FILE pin points to a particular file on the microSD card. Let’s name our data file temp-log.txt .

pin points to a particular file on the microSD card. Let’s name our data file . The W pin triggers a new write. Connect it with the DONE pin of the thermometer. With this link the sd-log makes a new record only when a new temperature value appears.

Here is the resulting program patch.

Measure temperature #

Upload the program to your board and optionally power it through a battery. You may connect and disconnect the device from the power source as many times as you wish. On every boot the log will be continued, so the data from previous sessions won’t be lost.

The ambient temperature changes slowly. To test the logger we force faster changes: we cool the thermometer in a fridge and heat it with a dryer.

When enough data is collected, take off the microSD card.

Analyze data #

Open the temp-log.txt file on your computer to see what is inside.

As you see, we’ve got a table with three columns and many rows. One row is for a single sample. The first column stores the record number (just ignore the 00 fraction part), the second column is the time value in seconds, and the last one is the actual temperature in Celsius. You may use various applications to analyze the data. For our example, let’s use Google Spreadsheets.

You can move data values to the spreadsheet in different ways:

Select all the data from the temp-log.txt file by pressing CTRL+A in your text editor. Copy what you’ve selected by pressing CTRL+C. Create a new Google Spreadsheet document, select the first cell in the table and press CTRL+V.

file by pressing CTRL+A in your text editor. Copy what you’ve selected by pressing CTRL+C. Create a new Google Spreadsheet document, select the first cell in the table and press CTRL+V. Create a new Google Spreadsheet document. Hit File -> Import.. -> Upload . Select the temp-log.txt file from the microSD card or drag-and-drop it into the field. Select the Tab separator type and import the data.

Once you input the data, you can visualize it.

Create a blank chart by hitting Insert -> Chart .

. Choose the Chart type . We chose the Smooth line chart .

. We chose the . Edit the X-AXIS and choose the time column as data.

and choose the time column as data. Edit the SERIES and choose the temperature column as data.

and choose the temperature column as data. Hit CUSTOMIZE -> Chart & axis title .

. Input the titles for the vertical and horizontal axes. We named them Temperature, C and Time .

and . Set the minimum and maximum bounds for the vertical and horizontal axes. We set the (10,90) bound for the Temperature, C axis and (0,3000) for the Time axis.

bound for the axis and for the axis. You can change the color of the line by hitting Series and choosing the color.

On the graph, you can clearly see the temperature change after our manipulations with the thermometer.

If you have got problems trying to repeat the guide, download the prepared project and open it in the IDE.

With the microSD card, you can store a significant amount of data that can not be stored in the memory of the controller. You can use any other sensor or even several different sensors to log and observe a physical process of your choice.