Collecting Sensor Data
C/C++ (Arduino/Wiring), SparkFun MicroMod STM32 Processor, and SparkFun MicroMod Cellular Function Board
Don't see your favorite hardware here? Rest assured the Notecard works with virtually every MCU and SBC available. If you can't figure out how to complete this tutorial let us know in our forum and we can help you out.
Introduction
This tutorial should take approximately 40-50 minutes to complete.
In this tutorial, you'll learn how to take sensor readings from a Device and send readings to your Notecard and the Blues Notehub. You'll use C/C++ (Arduino/Wiring) running on a SparkFun MicroMod STM32 Processor wired up to SparkFun MicroMod Cellular Function Board hardware. If you would like to use a different language, board, or Notecarrier, modify the dropdowns at the top of this guide. And if you get stuck at any point, the full source code for each example is available on GitHub.
The tutorial uses mock sensor readings for simplicity, but feel free to hook up a physical sensor of your choice and use that instead.
Set up Hardware
First, you'll need to get all of your hardware connected. Follow the instructions below to connect your SparkFun MicroMod STM32 Processor and Notecard mounted on a SparkFun MicroMod Cellular Function Board.
In order to complete this guide, you'll need the following:
-
A SparkFun MicroMod Cellular Function Board - Blues Wireless Notecarrier
-
A SparkFun MicroMod Main Board, such as this single one or this double one.
-
A USB-C cable.
Once you have all the necessary hardware, refer to SparkFun's Hardware Assembly Guide for instructions on connecting everything. When you're done your setup should look something like this.
Create a Notehub Project
Now that your hardware is all connected, let's create a new Notehub project to receive sensor readings from your Notecard.
-
Navigate to notehub.io and log-in, or create a new account.
-
Using the New Project card, give your project a name and ProductUID.
note The ProductUID must be globally unique, so we recommend a namespaced name like
"com.your-company.your-name:your_product"
. -
Take note of your ProductUID. This identifier is used by Notehub to associate your Notecard to your project.
Write Firmware
Configure the Arduino IDE
For this portion of the guide, we'll be using the Arduino IDE, so be sure to install version 2.0+ if you haven't already.
Once installed, we'll need to add support for your SparkFun MicroMod STM32 Processor Board.
Configure the Arduino Boards Manager to use the MicroMod STM32 Processor
-
Start the Arduino IDE, open the Settings menu, and copy the following path
https://raw.githubusercontent.com/sparkfun/Arduino_Boards/main/IDE_Board_Manager/package_sparkfun_index.json
into the "Additional Board Manager URLs" field. If there's already something in the box, then add a comma to separate the URLs. -
Restart the Arduino IDE, then select the Tools > Board: [board name] > Boards Manager... menu.
-
In the search box, type "SparkFun STM32", find the SparkFun STM32 Boards result, and click its Install button.
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Once the installation completes, open the Tools > Boards menu and select SparkFun STM32 Boards > Generic STM32F4 series.
-
Next, open the Tools > Board Part number menu and select SparkFun MicroMod STM32F405 DFU.
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Connect your SparkFun MicroMod Main Board to your computer or laptop with a USB-C cable.
-
Finally, open the Tools > Port menu and select your device.
The MicroMod STM32 Processor requires the STM32Cube Programmer to compile firmware. If you don't already have the Programmer installed, you'll need to install it as a last step.
Communicating With Your Notecard
When communicating with the Notecard over I2C, you'll want to use the note-arduino library. The code snippets below provide everything you need to talk to the Notecard over I2C in Arduino.
Install the Notecard Arduino Library
-
To use the note-arduino library, you'll need to add it to the Arduino IDE.
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Click on Tools > Manage Libraries...
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Search for "Blues" in the input box and click the "Install" button next to the "Blues Wireless Notecard" result.
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Create a new sketch and select the Sketch > Include Library > Contributed Libraries > Blues Wireless Notecard menu option, to add the following include to your sketch:
#include <Notecard.h>
Set Up Your Notecard
-
Now, configure a Serial interface. You'll use this interface to log information later in your code.
#define usbSerial Serial
-
Next, add a definition for your ProductUID using the value you specified when creating your Notehub project.
#define productUID "com.your-company.your-name:your_product"
-
Above the
setup()
andloop()
functions, declare a global object to represent the Notecard.Notecard notecard;
-
In the
setup()
function, initialize theusbSerial
object and tell the Notecard library to use this serial object for sending debug output.delay(2500); usbSerial.begin(115200);
-
Initialize an instance of the Notecard class and initialize an I2C connection to the Notecard using the
notecard.begin()
function. Then, usesetDebugOutputStream()
to link the debug output tousbSerial
with the following code:notecard.begin(); notecard.setDebugOutputStream(usbSerial);
-
Now, we'll configure the Notecard. Using the
hub.set
request, we associate this Notecard with the ProductUID of your project and set the Notecard to operate incontinuous
mode, which indicates that the device should immediately make a connection to Notehub and keep it active.J *req = notecard.newRequest("hub.set"); JAddStringToObject(req, "product", productUID); JAddStringToObject(req, "mode", "continuous"); notecard.sendRequest(req);
The lines above build-up a JSON object by adding two string values for product and mode, and then fires the request off to the Notecard with the
sendRequest()
function.
Flash Your Firmware
-
Enter bootloader mode on your MicroMod STM32 Processor by pressing and holding the BOOT button, pressing RESET, then releasing both buttons. Then, click the Upload button (right arrow icon) to flash firmware to your device.
View the Serial Log
Now that your firmware is running on your device, you can use a Serial Monitor to view device output. If you are using an STLINK programmer, you will need to connect a second Micro USB cable from your computer directly to your STM32-based host to view serial output.
Complete the instructions below in your preferred IDE.
-
Open the Arduino Serial Monitor. If everything has been connected and configured properly, you'll see a few debug messages, including the JSON object you sent, as well as the response from the Notecard
{}
.
Read from the sensor
Now that you've configured your Arduino to communicate with the Notecard, let's grab some pseudo sensor readings.
If you have your own sensor, feel free to hook it up and use your own values instead of this tutorial's mocked ones.
Install the NotecardPseudoSensor Library
-
To generate mock sensor readings you'll use the NotecardPseudoSensor library. To add the library to Arduino IDE start by clicking on Tools > Manage Libraries...
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Search for “NotecardPseudoSensor” in the input box and click the Install button next to the “Blues Wireless Notecard Pseudo Sensor” result.
Gather Sensor Readings
-
Add the following include to the top of your sketch:
#include <NotecardPseudoSensor.h>
-
Next, include the following
namespace
under your includes.using namespace blues;
-
After that, create an instance of
NotecardPseudoSensor
with the line of code below. Place this directly under your existingNotecard notecard
statement.NotecardPseudoSensor sensor(notecard);
-
Finally, place the following code in your
loop
function, which generates mock temperature and humidity readings, prints them to the console, and then waits 15 seconds before exiting the loop.float temperature = sensor.temp(); float humidity = sensor.humidity(); usbSerial.print("Temperature = "); usbSerial.print(temperature); usbSerial.println(" *C"); usbSerial.print("Humidity = "); usbSerial.print(humidity); usbSerial.println(" %"); delay(15000);
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Upload this code to your SparkFun MicroMod STM32 Processor. Open the Serial Monitor and you'll see temperature and humidity readings every 15 seconds.
Send Sensor Readings to the Notecard
Now that we're getting sensor readings, let's send these to our Notecard.
-
To send a sensor reading to the Notecard, we'll need to construct a new JSON request to the
note.add
API that includes a new Notefile name (sensors.qo
), sets thesync
field to true to instruct the Notecard to sync to Notehub immediately, and finally, sets thebody
to the sensor temperature and humidity. Add the following inloop
right after theusbSerial
commands to print out readings.J *req = notecard.newRequest("note.add"); if (req != NULL) { JAddStringToObject(req, "file", "sensors.qo"); JAddBoolToObject(req, "sync", true); J *body = JAddObjectToObject(req, "body"); if (body) { JAddNumberToObject(body, "temp", temperature); JAddNumberToObject(body, "humidity", humidity); } notecard.sendRequest(req); }
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Upload this code to your device. After reboot, the Serial monitor will update to display the response from the
note.add
request (the total number of Notes in the notefile) each time you add a new reading.
Concerned about the size of note-arduino
? You can
communicate with the Notecard without using the library.
View Data in Notehub
Once you start capturing readings, your Notecard will initiate a connection to Notehub and will start transferring Notes. Depending on signal strength and coverage in your area, it may take a few minutes for your Notecard to connect to Notehub and transfer data.
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Return to notehub.io and open your project. You should see your notecard in the Devices view.
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Now, click on the Events left menu item. Once your sensor Notes start syncing, they'll show up here.
Use Environment Variables
Environment variables are a Notehub state and settings management feature that allow you to set variables in key-value pairs, and intelligently synchronize those values across devices and fleets of devices.
In this section you'll learn how environment variables work by creating a variable that determines how often your firmware should take sensor readings.
Using Environment Variables in Firmware
The Notecard provides a set of requests for working with environment variables.
The most common of these requests is env.get
,
which allows you to retrieve the value of an environment variable.
Complete the steps below to use the env.get
request to retrieve and use the
reading_interval
environment variable.
-
In
setup()
, adjust your existinghub.set
configuration to set thesync
argument totrue
. Whensync
istrue
, the Notecard synchronizes inbound environment variable changes as soon as they're made in Notehub.J *req = notecard.newRequest("hub.set"); JAddStringToObject(req, "product", productUID); JAddStringToObject(req, "mode", "continuous"); JAddBoolToObject(req, "sync", true); // ADD THIS LINE notecard.sendRequest(req);
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Next, place the following new function at the bottom of your sketch.
// This function assumes you’ll set the reading_interval environment variable to // a positive integer. If the variable is not set, set to 0, or set to an invalid // type, this function returns a default value of 60. int getSensorInterval() { int sensorIntervalSeconds = 60; J *req = notecard.newRequest("env.get"); if (req != NULL) { JAddStringToObject(req, "name", "reading_interval"); J* rsp = notecard.requestAndResponse(req); int readingIntervalEnvVar = atoi(JGetString(rsp, "text")); if (readingIntervalEnvVar > 0) { sensorIntervalSeconds = readingIntervalEnvVar; } notecard.deleteResponse(rsp); } return sensorIntervalSeconds; }
-
Then, add this line after the
#include
lines at the top of the file.int getSensorInterval();
-
Next, find the
delay(15000)
line at the bottom of yourloop()
function, and replace it with the code below.int sensorIntervalSeconds = getSensorInterval(); usbSerial.print("Delaying "); usbSerial.print(sensorIntervalSeconds); usbSerial.println(" seconds"); delay(sensorIntervalSeconds * 1000);
With this code in place, your firmware now uses the reading_interval
environment
variable to determine how many seconds to delay in between sensor readings. If you
flash this updated code to your device and open your serial monitor, you can see
the device using the default value for reading_interval
of 60 seconds.
Setting an Environment Variable
Now we have our device programmed to retrieve an Environment Variable from Notehub, we will create that variable. Environment variables can be set in the Notehub UI or through the Notehub API. In this tutorial you'll learn how to set the values through the Notehub UI. If you'd like to instead set environment variables through the Notehub API, refer to environment variable requests in the Project API.
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Return to your Notehub project, go the the Devices page, and double click your device. You should see a screen that looks like this.
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Click the Environment tab.
-
Under the Device environment variables header, define a new environment variable named
reading_interval
and set its value to30
.
Now that you have an environment variable set you should see it immediately reflected on your device.
And with that, you've used your first environment variable on your Notecard!
To see the real power of environment variables in action, try returning to Notehub
and updating your device's reading_interval
with your serial monitor open. Your
firmware will retrieve the updated value and start using it immediately.
This tutorial had you use several configuration settings that are best used when you have your Notecard connected to mains power.
-
In the
hub.set
request, settingmode
to"continuous"
tells the Notecard to maintain an active network connection. -
In the
hub.set
request, settingsync
totrue
tells the Notecard to immediately synchronize inbound Notes and environment variables from Notehub. -
In the
note.add
request, settingsync
totrue
tells the Notecard to immediately synchronize all outbound Notes to Notehub.
Because each of these settings cause the Notecard to use more power, you
may wish to disable them if you plan to transition your project to battery power.
You can run the command below to put your Notecard into periodic
mode with
the sync
argument turned off.
{
"req": "hub.set",
"mode": "periodic",
"sync": false,
"outbound": 60,
"inbound": 120
}
Learn more about optimizing the Notecard for low-power scenarios in Low Power Design.
Next Steps
Congratulations! You've successfully connected your SparkFun MicroMod STM32 Processor to your Notecard and built a basic IoT project.
If you're following the Blues Quickstart, next we recommend learning how to send (and visualize) your data in a cloud application:
Use the Notecard to Send DataSet Up Your MicrocontrollerBuild Your First IoT App With Blues- Send Data to Your Cloud
At any time, if you find yourself stuck, please reach out on the community forum.