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Introduction
This access control system application is part of a series of how-to Intel® Internet of Things (IoT) code sample exercises using the Intel® IoT Developer Kit, Intel® Edison board, Intel® IoT Gateway, cloud platforms, APIs, and other technologies.
From this exercise, developers will learn how to:
- Connect the Intel® Edison board or Intel® IoT Gateway, computing platforms designed for prototyping and producing IoT and wearable computing products.
- Interface with the Intel® Edison board or Arduino 101* (branded Genuino 101* outside the U.S.) 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.
- Set up a web application server to let users enter the access code to disable the alarm system and store this alarm data using Azure Redis Cache* from Microsoft Azure*, Redis Store* from IBM Bluemix*, or ElastiCache* using Redis* from Amazon Web Services (AWS)*, different 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.
- Set up a MQTT-based server using IoT Hub from Microsoft Azure*, IoT from IBM Bluemix*, or IoT from Amazon Web Services* (AWS), different cloud machine to machine messaging services based on the industry standard MQTT protocol.
What it is
Using an Intel® Edison board or Intel® IoT Gateway, this project lets you create a smart access control system that:
- monitors a motion sensor to detect when a person is in an area that requires authorization.
- can be accessed with your mobile phone via the built-in web interface to disable the alarm.
- keeps track of access, using cloud-based data storage.
How it works
This access control system provides the following user flow:
- Passive infrared (PIR) motion sensor looks for motion.
- User sets off the motion detector and has 30 seconds to enter the correct code in the browser.
- If the user fails to enter the code in the given time, the alarm goes off.
- If the user enters the correct code, the system waits for 30 seconds before allowing the user to pass.
Additionally, various events (looking-for-motion
, motion-detected
, invalid-code
, etc.) are logged.
Optionally, all data can be stored using the Intel® IoT Examples data store or an MQTT server running in your own Microsoft* Azure*, IBM* Bluemix*, or AWS account.
Hardware requirements
This sample can be used with either the Grove* Transportation and Safety Kit from Seeed Studio*, or else the Starter Kit for Intel® Edison/Galileo from DFRobot*.
Grove* Transportation and Safety Kit, containing:
- Intel® Edison with an Arduino-compatible breakout board or Intel® IoT Gateway with Intel® Arduino 101
- Grove* PIR Motion Sensor
- Grove* RGB LCD
DFRobot* Starter Kit for Intel® Edison, containing:
- Intel® Edison with an Arduino-compatible breakout board or Intel® IoT Gateway with Intel® Arduino 101
- PIR (Motion) Sensor.
- LCD Keypad Shield
Software requirements
- Microsoft Azure*, IBM Bluemix*, or AWS* account (optional)
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* PIR Motion Sensor, and connect the other end to the D4 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.
Connecting the DFRobot* sensors
You need to have a LCD Display Shield connected to an Arduino*-compatible breakout board to plug all the DFRobot* devices into the LCD Display Shield.
- Plug one end of a DFRobot* cable into the PIR (Motion) Sensor, and connect the other end to the A2 port on the LCD Display Shield.
Manual Intel® Edison setup
If you're running this code on your Intel® Edison board manually, you need to install some dependencies by establishing an SSH session to the board running the following commands.
To install Git* on the Intel® Edison board (if you don’t have it yet), establish an SSH connection to the board and run the following command:
$ opkg install git
To obtain the Python* packages needed for this example to execute on the Intel® Edison board:
Run the following commands to update to the latest version of Python's package installer:
$ pip install --upgrade pip setuptools
Run the following to update to the latest versions of the Intel MRAA and UPM libaries:
$ echo "src mraa-upm http://iotdk.intel.com/repos/3.5/intelgalactic/opkg/i586" > /etc/opkg/mraa-upm.conf
$ opkg update
$ opkg install mraa upm
Once the dependencies are installed you can install the example itself with the following command:
$ pip install --src ~/python/examples/ -e "git+https://github.com/intel-iot-devkit/how-to-code-samples.git#egg=iot_access_control&subdirectory=access-control/python"
The pip
command will install required Python dependencies, save the source code for the example in ~/python/examples/iot-access-control/ and link the package to the global Python site-packages folder.
Intel® IoT Gateway setup
You can run this example using an Intel® IoT Gateway connected to an Arduino 101*(branded Genuino 101* outside the U.S.).
Make sure your Intel® IoT Gateway is setup using Intel® IoT Gateway Software Suite, by following the directions on the web site here:
https://software.intel.com/en-us/getting-started-with-intel-iot-gateways-and-iotdk
To install and run the example, you will need to install Python setuptools. This is easy to do, by running:
$ wget https:
Once these dependencies are installed you can install the example itself with the following command:
$ pip install --src ~/python/examples/ -e "git+https://github.com/intel-iot-devkit/how-to-code-samples.git#egg=iot_access_control&subdirectory=access-control/python"
The pip
command will install required Python dependencies, save the source code for the example in ~/python/examples/iot-access-control/ and link the package to the global Python site-packages folder.
The Arduino 101 needs to have the Firmata* firmware installed. If you have IMRAA installed on your gateway, this will be done automatically. Otherwise, install the StandardFirmata or ConfigurableFirmata sketch manually on to your Arduino 101.
You will also need to configure the config.json
in the example to use the Arduino 101. See the section "Configuring the example" below.
Data store server setup
Optionally, you can store the data generated by this sample program in a back-end database deployed using Microsoft Azure*, IBM Bluemix*, or AWS*, along with 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
MQTT server setup
You can also optionally store the data generated by this sample program using MQTT, a machine-to-machine messaging server. You can use MQTT to connect to Microsoft Azure*, IBM Bluemix*, or AWS*.
For information on how to connect to your own cloud MQTT messaging server, go to:
https://github.com/intel-iot-devkit/intel-iot-examples-mqtt
Configuring the example
When the example is installed through pip
the config.json file that holds the configuration for the example lives in ~/python/examples/iot_access_control/access-control/python/iot_access_control/config.json.
To configure the example for the Grove* kit, just leave the kit
key in the config.json set to grove
. To configure the example for the DFRobot* kit, change the kit
key in the config.json to dfrobot
as follows:
{
"kit": "dfrobot",
"CODE": "4321"
}
To configure the example for the Arduino 101, add a PLATFORM
key with the value firmata
to the config.json, as follows:
{
"kit": "dfrobot",
"CODE": "4321",
"PLATFORM": "firmata"
}
To configure the example for the optional Microsoft Azure*, IBM Bluemix*, or AWS* data store, add the SERVER
and AUTH_TOKEN
keys in the config.json file below the "CODE" key as follows:
{
"kit": "grove",
"CODE": "4321",
"SERVER": "http://intel-examples.azurewebsites.net/logger/access-control",
"AUTH_TOKEN": "s3cr3t"
}
For information on how to configure the example for the optional Microsoft Azure*, IBM Bluemix*, or AWS* MQTT messaging server, go to:
https://github.com/intel-iot-devkit/intel-iot-examples-mqtt/
Running the program
Once the program is installed and configured as detailed above, you can execute the program by running the following command in an SSH session to the board:
$ python -m iot_access_control
Disabling the alarm
The alarm is disabled using a single-page web interface served directly from the Intel® Edison board while the sample program is running.
The web server runs on port 3000
, so if the Intel® Edison board is connected to Wi-Fi* on 192.168.1.13
, the address to browse to if you are on the same network is http://192.168.1.13:3000
.
Determining the Intel® Edison board's IP address
You can determine what IP address the Intel® Edison board is connected to by running the following command:
ip addr show | grep wlan
You will see 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
.
IMPORTANT NOTICE: This software is sample software. It is not designed or intended for use in any medical, life-saving or life-sustaining systems, transportation systems, nuclear systems, or for any other mission-critical application in which the failure of the system could lead to critical injury or death. The software may not be fully tested and may contain bugs or errors; it may not be intended or suitable for commercial release. No regulatory approvals for the software have been obtained, and therefore software may not be certified for use in certain countries or environments.