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Introduction

This instructable will cover the basic steps that you need to follow to get started with open sources such as Watson nodes(Visual Recognition V3, Text To Speech) for IBM Bluemix, Node-RED, OpenCV, MQTT v3.1. MQTT(Message Queueing Telemetry Transport) is a Machine-To-Machine(M2M) or Internet of Things (IoT) connectivity protocol that was designed to be extremely lightweight and useful when low battery power consumption and low network bandwidth is at a premium. It was invented in 1999 by Dr. Andy Stanford-Clark and Arlen Nipper and is now an Oasis Standard.

I've already published an instructable of the Smart Gas Valve For Safety. In addition, I'm going to communicate between A Smart JPEG Camera and A Smart Gas Valve for M2M Communication by MQTT. Specifically, this instructable will cover how to code the Node-RED on Raspberry Pi2 as a MQTT client by connecting to your home wireless network and how to send sensor data. I will be using A Smart Gas Valve for M2M communication by MQTT.

- How to use the Bluemix platform (Docs)

https://console.ng.bluemix.net/docs/

Step 1: Table of Contents

  • Step 0: Introduction
  • Step 1: Table of Contents
  • Step 2: Bill of Materials
  • Step 3: Setting up the Camera & PIR Sensor with Raspberry Pi
  • Step 4: Programming NodeRED on Raspberry Pi2
  • Step 5: Setting up MQTT v3.1 on Raspberry Pi2
  • Step 6: Checking your NodeRED codes with MQTT on Raspberry Pi2
  • Step 7: Programming Python JPEG Camera
  • Step 8: Adding IBM Watson, IBM NoSQL DB, Play-Audio, and Twilio
  • Step 9: Adding autostart files for every boot
  • Step 10: Testing M2M Communication
  • Step 11: (Optional) Using OpenCV
  • Step 12: Download list
  • Step 13: List of references

Step 2: Bill of Materials

  • Wifi dongle X 1ea
  • PIR motion sensor X 1ea
  • Android smartphone's portable battery X 2ea
  • Nod-RED software X 1ea
    • Free open source
    • Use the version pre-installed in Raspbian Jessie image since November 2015
    • Installation guide
  • MQTT v3.1 software X 1ea
    • Free open source
    • Installation guide includes at Step 5
  • NodeRED's IBM Watson Nodes for Bluemix

    • Text to speech node X 1ea
    • Visual Recognition X 1ea
  • Speaker X 1ea

  • Minion X 1ea
    • You can easily buy it from eBay.

Step 3: Setting Up the Camera & PIR Sensor With Raspberry Pi

Assembly steps for Smart JPEG Camera

(1) Connect the Raspberry Pi2 with a PIR motion sensor as shown above in the circuit diagram.

(2) Connect the PIR motion sensor with Raspberry Pi2.

  • Raspberry Pi2 <----> PIR motion Sensor
    • 5V ---------------- VCC
    • GND ------------- GND
    • GPIO 18 -------- OUT

(4) Assemble carefully the Pi camera with Raspberry Pi2.

(5) Connect a portable battery with Raspberry Pi2. (Use any portable battery to connect with the same size connector cable on Raspberry Pi2. )

Assembly steps for Smart Gas Valve : here

Step 4: Programming NodeRED on Raspberry Pi2

How to start Node-RED on web-browser.

(1) Write down command shown below to a terminal window. node-red-start

(2) You can find an IP address as below. 'Once Node-RED has started, point a browser at http://169.254.170.40:1880' (It depends on your IP address)

(3) Open your web browser.

(4) Copy the IP address and paste on the web browser.

(5) It will display a visual editor of Node-RED on the web browser.

(6) You can start coding with visual editor on the web browser.

(7) Try dragging & dropping any node from the left-hand side to right-hand side. It's really easy to code. ( You can conveniently use the visual editor offline as well as online. ) Download the 'SmartGasValve_NodeRED.txt' file. (1) Click the number (1) at the right-hand side corner shown in NodeRED on the web browser.

(2) Click the Import button on the drop down menu.

(3) Open the Clipboard shown in the above 1st picture.

(4) Lastly, paste the given JSON format text of 'SmartJPGCameraNoCredits_NodeRED_ver0.1.txt' in Import nodes editor.

Step 5: Setting Up MQTT V3.1 on Raspberry Pi2

Setting up MQTT v3.1 on Raspberry Pi2

This message broker(Mosquitto) is supported by MQTT v3.1 and it is easily installed on the Raspberry Pi and somewhat less easy to configure. Next, we step through installing and configuring the Mosquitto broker. We are going to install & test the MQTT “mosquitto” on the terminal window.

curl -O http://repo.mosquitto.org/debian/mosquitto-repo.gpg.key
sudo apt-key add mosquitto-repo.gpg.key
rm mosquitto-repo.gpg.key
cd /etc/apt/sources.list.d/
sudo curl -O http://repo.mosquitto.org/debian/mosquitto-jessie.list
sudo apt-get update

Next install the broker and command line clients:

  • mosquitto – the MQTT broker (or in other words, a server)
  • mosquitto-clients – command line clients, very useful in debugging
  • python-mosquitto – the Python language bindings
sudo apt-get install mosquitto mosquitto-clients python-mosquitto

As is the case with most packages from Debian, the broker is immediately started. Since we have to configure it first, stop it.

sudo /etc/init.d/mosquitto stop

Now that the MQTT broker is installed on the Pi we will add some basic security.
Create a config file:

cd /etc/mosquitto/conf.d/

sudo nano mosquitto.conf

Let's stop anonymous clients connecting to our broker by adding a few lines to your config file. To control client access to the broker we also need to define valid client names and passwords. Add the lines:

allow_anonymous false

password_file /etc/mosquitto/conf.d/passwd

require_certificate false

Save and exit your editor (nano in this case).
From the current /conf.d directory, create an empty password file:

sudo touch passwd

We will use the mosquitto_passwd tool to create a password hash for user pi:

sudo mosquitto_passwd -c /etc/mosquitto/conf.d/passwd pi

You will be asked to enter your password twice. Enter the password you wish to use for the user you defined.

Testing Mosquitto on Raspberry Pi

Now that Mosquitto is installed we can perform a local test to see if it is working:
Open three terminal windows. In one, make sure the Mosquitto broker is running:

mosquitto

In the next terminal, run the command line subscriber:

mosquitto_sub -v -t 'topic/test'

You should see the first terminal window echo that a new client is connected.
In the next terminal, run the command line publisher:

mosquitto_pub -t 'topic/test' -m 'helloWorld'

You should see another message in the first terminal window saying another client is connected. You should also see this message in the subscriber terminal:

topic/test helloWorld

We have shown that Mosquitto is configured correctly and we can both publish and subscribe to a topic.
When you finish testing all, let's set up below that.

sudo /etc/init.d/mosquitto start

Step 6: Checking Your NodeRED Codes With MQTT on Raspberry Pi2

When you have already used the JSON format of the 'SmartGasValve_NodeRED.txt' on Node-RED, it's automatically set up & coded each data. I have already set up the each data in each node.

(1) Click each node.

(2) Check information inside each node has been prefilled.

(3) Please don't change the set data.

(The above can be customized for more advanced users.)

Step 7: Programming Python JPEG Camera

Programming Python JPEG Camera

First of all, you should test the camera module in the terminal window.

raspistill -o test.jpg

You should see the test.jpg in '/home/pi'

cd /home/pi 
mkdir pythonPir
cd pythonPir
sudo nano pircameraNodeRED.py

Type the below (the enclosed file) Or Put ‘pircameraNodeRED.py’ file into '/home/pi/pythonPir' folder.

import RPi.GPIO as GPIO 
import time
import picamera
import datetime 

timeFormat = 0

GPIO.setmode(GPIO.BCM)
GPIO.setup(17, GPIO.IN)  # For M2M Communication from Gas Valve signal
GPIO.setup(18, GPIO.IN)
camera = picamera.PiCamera()

while True:
        input17 = GPIO.input(17)  #Pin number 17 activates
        input18 = GPIO.input(18)  #Pin number 18 activates
        now = datetime.datetime.now()
        timeFormat = now.strftime("%Y%m%d_%H%M_%S.%s") #To put date and time in images

        if input17 == True or input18 == True:  #If PIR Sensor detects something, the Picamera will take.
                print('Motion_Detected_%s' %timeFormat)
                camera.capture('image_%s.jpg' %timeFormat) #To take a picture

                time.sleep(1) #sleeping time 1 second

When you finish typing, you should press the keys 'Control' + 'x' and press 'y' to save this file.

Making an image file server

cd /home/pi
mkdir camserver
sudo nano requirements.txt

Type the below (the enclosed file) Or Put ‘requirements.txt’ file into '/home/pi/camserver' folder.

numpy==1.10.1
websocket-client==0.35.0
websocket-server==0.4
ibmiotf==0.2.3
pip install --user -r requirements.txt

Execute an image file server in /home/pi/ below.

cd /home/pi
python -m SimpleHTTPServer 7000

Step 8: Adding IBM Watson, IBM NoSQL DB, Play-Audio, and Twilio

Searching the Nodes

Node-RED comes with a core set of useful nodes, but there are a growing number of additional nodes available for installing from both the Node-RED project as well as the wider community. You can search for available nodes in the Node-RED library or on the npm repository.

  • For example, we are going to search Twilio at the npm web. Click here.
  • Then, we are going to install Twilio on Raspberry pi.

Installing npm packaged node

To add additional nodes you must first install the npm tool, as it is not included in the default installation. The following commands install npm and then upgrade it to the latest 2.x version.

sudo apt-get update
sudo apt-get install npm
sudo npm install -g npm@2.x
hash -r
cd /home/pi/.node-red
  • For example, 'npm install node-red-{example node name}'
  • Copy the 'npm install node-red-node-twilio' from the npm web. Paste it on a terminal window.
  • Ex: node-red-node-watson, node-red-contrib-play-audio, node-red-dashboard, node-red-node-pidcontrol, and, node-red-node-cf-cloudant.

npm install node-red-node-twilio
  • You will need to restart Node-RED for it to pick-up the new nodes.
node-red-stop

node-red-start
  • Close your web browser and reopen the web browser.

Step 9: Adding Autostart Files for Every Boot.

How to make autostart files at every boot.

  • Mosquitto
cd /etc/xdg/autostart/
sudo nano flyMosquitto.desktop

Type the below (this will enclose the file) Or Put ‘flyMosquitto.desktop’ file into autostart folder.

[Desktop Entry] 
Type=Application
Name=flyMosquitto
Comment=Fly my mosquitto
Exec=cd /etc/mosquitto/conf.d/
Exec=mosquitto
  • Node-RED
sudo systemctl enable nodered.service
  • Python JPEG Camera
cd /etc/xdg/autostart/
sudo nano pircameraNodeRED.desktop

Type the description below or put the ‘pircameraNodeRED.desktop’ file into /etc/xdg/autostart/ folder.

[Desktop Entry]
Type=Application
Name=pircameraNodeRED.py
Comment=Start my security camera
NoDisplay=false
Exec=python /home/pi/pythonPir/pircameraNodeRED.py
NotShowIn=GNOME;KDE;XFCE;
Name[en_US]=pircamera.py
  • Image file Server
cd /etc/xdg/autostart/
sudo nano imageFileServer.desktop

Type the description below or put the ‘imageFileServer.desktop’ file into /etc/xdg/autostart/ folder.

[Desktop Entry]
Type=Application 
Name=imageFileServer 
Comment=Start an image file server 
NoDisplay=false 
Exec=cd /home/pi 
Exec=python -m SimpleHTTPServer 7000

Step 10: Testing M2M Communication.

Importing the enclosed files in each NodeRED.

(1) Using a smart JPEG camera

Import the 'M2M_SmartJPGCamera.txt' into the NodeRED of the smart JPEG camera.

(2) Using a smart gas valve

Import the 'M2M_SmartGasValve.txt' into the NodeRED of the smart gas valve.

(3) Check an IP address of the smart gas valve in the Raspberry Pi2.

Type 'ifconfig' on a terminal window as shown below.

ifconfig

When you see the IP address, copy the IP address in a terminal window.

(4) Put the IP address into the MQTT node in other Raspberry Pi2.

  1. Click the MQTT node.
  2. Put the IP address into Server.

Step 11: (Optional) Using OpenCV

Installing & Using OpenCV on Raspberry Pi2

We have already used the IBM Watson Visual Recognition. Watson Visual Recognition is very excellent whereas we can't use it without connecting wifi. OpenCV is possible to use without internet connection but It's not very easy for a beginner to install & code into OpenCV. So, I'm going to install the OpenCV.

  • Install dependencies

sudo apt-get update
sudo apt-get install build-essential
sudo apt-get install cmake git libgtk2.0-dev pkg-config libavcodec-dev libavformat-dev libswscale-dev python-dev python-numpy libjpeg-dev libpng-dev libtiff-dev libjasper-dev
  • (Optional) Install OpenCV 2
sudo apt-get install python-opencv
  • Install OpenCV 3
unzip ~/Downloads/opencv-3.1.0.zip
cd opencv-3.1.0/
mkdir build
cd build/
cmake -DCMAKE_BUILD_TYPE=Debug -DBUILD_TESTS=NO -DBUILD_PERF_TESTS=NO ..
make -j3
sudo make install
sudo ldconfig
  • Check which version of OpenCV you have in Python
python
import cv2
cv2.__version__
  • Run the simple face detect sample, and look at its code to see how it works:
  • Before, you should connect an USB-cam with Raspberry Pi2
cd /home/pi
cd opencv-3.1.0
python ./facedetect.py
<p>Awesome, i wanna do something like this. You know if I could do this through a SIM card instead of Wifi connection? The camera conected to internet by 3G to be able to view the image from anywhere in a cellphone.</p>
<p>That's right! You could search 3G modules from Adafruits.</p>
I would like to achieve it as stand-alone version, do not need to connect to the Internet, and I also want to use neural networks for image recognition, is it possible?
<p>You can do it. First of all, you should learn about Machine Learning. Anyway, it's possible but it could be slow.</p>
<p>Yes It is possible. Good luck! You can use the TensorFlow library on Raspberry Pi.</p>
<p>Congrats on your first prize!! :)</p>
Thank you. This is my first experience. You are really awesome!! Because you got many prizes.
<p>Ah yes ....... But you are only as good as your last instructable ;) </p><p>I look forward to your next offering!</p>
<p>This is a great way to hide the camera, so many kids have minions toys!</p>
<p>You might like my AI robot. I improved many things compare to A smart JPEG camera for home security. </p><p>https://www.instructables.com/id/IBM-Watson-Cloud-Robot/</p>
<p>That's right. This minion can automatically communicate with other things such as TV, Gas valve and so on.</p>
<p>Awesome project, good work and instructions</p><p>let the minions invade the world :) </p>
<p>Thank you. That's right. It's really possible. </p>

About This Instructable

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Bio: I am a keen IoT inventor as a hobbyist in Sydney and very passionate about IoT and Algorithms such as MACHINE LEARNING, COMPUTATIONAL STATISTICS and ... More »
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