Introduction
This smart fire alarm application is part of a series of how-to Intel® IoT code sample exercises using the Intel® IoT Developer Kit, Intel® Edison development platform, cloud platforms, APIs, and other technologies.
From this exercise, developers will learn how to:
- Connect the Intel® Edison development platform, a computing platform designed for prototyping and producing IoT and wearable computing products.
- Interface with the Intel® Edison platform IO and sensor repository using MRAA and UPM from the Intel® IoT Developer Kit, a complete hardware and software solution to help developers explore the IoT and implement innovative projects.
- Run this code sample in Intel® XDK IoT Edition, an IDE for creating applications that interact with sensors and actuators, enabling a quick start for developing software for the Intel® Edison or Intel® Galileo board.
- Set up a web application server to store fire alarm data using Azure Redis Cache* from Microsoft* Azure*, cloud services for connecting IoT solutions including data analysis, machine learning, and a variety of productivity tools to simplify the process of connecting your sensors to the cloud and getting your IoT project up and running quickly.
- Invoke the services of the Twilio* API for sending text messages.
What it is
Using an Intel® Edison board, this project lets you create a smart fire alarm that:
- Constantly monitors for unsafe temperature levels;
- Issues an audible notification using the buzzer;
- Issues a visual notification using the LCD;
- Keeps track of fire events, using cloud-based data storage;
- Sends text messages to alert others of a possible fire.
How it works
This smart fire alarm monitors the ambient temperature using the Grove* Temperature Sensor.
If the temperature exceeds a certain threshold (set to 28 degrees Celsius in this example), it sounds an alarm through the buzzer and displays an alert on the LCD.
In addition, it can send a text message to a specified number through Twilio*, warning the recipient of a possible fire danger.
Optionally, it can log fire events using the Intel® IoT Example Datastore running in your own Microsoft* Azure* account.
Hardware requirements
Grove* Starter Kit Plus containing:
- Intel® Edison with an Arduino* breakout board
- Grove* Temperature Sensor
- Grove* Buzzer
- Grove* RGB LCD
Software requirements
- Intel® XDK IoT Edition
- Microsoft* Azure* account
- Twilio* account
How to set up
To begin, clone the Intel® IoT Examples repository with Git* on your computer as follows:
$ git clone https://github.com/intel-iot-devkit/how-to-code-samples.git
Want to download a .zip file? In your web browser, go to https://github.com/intel-iot-devkit/how-to-code-samples and click the Download ZIP button at the lower right. Once the .zip file is downloaded, uncompress it, and then use the files in the directory for this example.
Adding the program to Intel® XDK IoT Edition
In Intel® XDK IoT Edition, select Import Your Node.js Project:
Then, navigate to the directory where the example project exists, and select it:
You need to connect to your Intel® Edison board from your computer to send code to it.
Click the IoT Device menu at the bottom left. If your Intel® Edison is automatically recognized, select it.
Otherwise, select Add Manual Connection. In the Address field, type 192.168.2.15
. In the Port field, type 58888
. Click Connect to save your connection.
Installing the program manually on Intel® Edison
Alternatively, you can set up the code manually on the Intel® Edison board.
Clone the Intel® IoT Examples repository to your Intel® Edison board after you establish an SSH connection to it, as follows:
$ git clone https://github.com/intel-iot-devkit/how-to-code-samples.git
Then, navigate to the directory with this example.
To install Git* on Intel® Edison, if you don’t have it yet, establish an SSH connection to the board and run the following command:
$ opkg install git
Connecting the Grove* sensors
You need to have a Grove* Shield connected to an Arduino*-compatible breakout board to plug all the Grove* devices into the Grove* Shield. Make sure you have the tiny VCC switch on the Grove* Shield set to 5V.
Plug one end of a Grove* cable into the Grove* Temperature Sensor, and connect the other end to the A0 port on the Grove* Shield.
Plug one end of a Grove* cable into the Grove* Buzzer, and connect the other end to the D5 port on the Grove* Shield.
Plug one end of a Grove* cable into the Grove* RGB LCD, and connect the other end to any of the I2C ports on the Grove* Shield.
Manual Intel® Edison setup
If you're running this code on your Intel® Edison manually, you need to install some dependencies.
To obtain the Node.js* modules needed for this example to execute on Intel® Edison, run the following command:
npm install
Twilio* API key
To optionally send text messages, you need to register for an account and get an API key from the Twilio* web site:
You cannot send text messages without obtaining a Twilio* API key first. You can still run the example, but without the text messages.
Pass your Twilio* API key and authentication token to the sample program by modifying the TWILIO_ACCT_SID
and TWILIO_AUTH_TOKEN
keys in the config.json
file as follows:
{"TWILIO_ACCT_SID": "YOURAPIKEY","TWILIO_AUTH_TOKEN": "YOURTOKEN"
}
Microsoft* Azure* server setup
Optionally, you can store the data generated by this example program in a backend database deployed using Microsoft* Azure*, Node.js*, and a Redis* data store.
For information on how to set up your own cloud data server, go to:
https://github.com/intel-iot-devkit/intel-iot-examples-datastore
Configuring the example
To configure the example for sending optional text messages, obtain an API key from the Twilio* web site as explained above, and then change the TWILIO_ACCT_SID
and TWILIO_AUTH_TOKEN
keys in the config.json
file as follows:
{"TWILIO_ACCT_SID": "YOURAPIKEY","TWILIO_AUTH_TOKEN": "YOURTOKEN"
}
To configure the example for the optional Microsoft* Azure* data store, change the SERVER
and AUTH_TOKEN
keys in the config.json
file as follows:
{"SERVER": "http://intel-examples.azurewebsites.net/logger/fire-alarm","AUTH_TOKEN": "s3cr3t"
}
To configure the example for both the text messages and the Microsoft* Azure* data store, change the TWILIO_ACCT_SID
, TWILIO_AUTH_TOKEN
, SERVER
, and AUTH_TOKEN
keys in the config.json
file as follows:
{"TWILIO_ACCT_SID": "YOURAPIKEY","TWILIO_AUTH_TOKEN": "YOURTOKEN","SERVER": "http://intel-examples.azurewebsites.net/logger/fire-alarm","AUTH_TOKEN": "s3cr3t"
}
Running the program using Intel® XDK IoT Edition
When you're ready to run the example, make sure you saved all the files.
Click the Upload icon to upload the files to the Intel® Edison board.
Click the Run icon at the bottom of Intel® XDK IoT Edition. This runs the code on Intel® Edison.
If you made changes to the code, click Upload and Run. This runs the latest code with your changes on Intel® Edison.
You will see output similar to the above when the program is running.
Running the program manually
To run the example manually on Intel® Edison, establish an SSH connection to the board and execute the following command:
node index.js
Determining the Intel® Edison IP address
You can determine what IP address Intel® Edison is connected to by running the following command:
ip addr show | grep wlan
You will see the output similar to the following:
3: wlan0: <BROADCAST,MULTICAST,UP,LOWER_UP> mtu 1500 qdisc pfifo_fast qlen 1000
inet 192.168.1.13/24 brd 192.168.1.255 scope global wlan0
The IP address is shown next to inet
. In the example above, the IP address is 192.168.1.13
.
For a complete list of How-To Intel® IoT Code Samples, go to Intel® Developer Zone.
For more details about this code sample, go to GitHub*.