The TASS Facenet Classifier uses Siamese Neural Networks and Triplet Loss to classify known and unknown faces, basically this means it calculates the distance between an image it is presented and a folder of known faces.
The project uses an UP2 (Up Squared) (A regular Linux desktop or Raspberry 3 and above will also work) the Intel Movidius for inference and the iotJumpWay for IoT connectivity.
With previous versions of TASS built using Tensorflow, TASS Movidius Inception V3 Classifier, the model had issues with the Openset Recognition Issue. TASS Facenet Classifier uses a directory of known images and when presented with a new image, will loop through each image basically measuring the distance between the known image and the presented image, it seems to overcome the issue so far in small testing environments of one or more people. In a large scenario this method will not be scalable, but is fine for small home projects etc.
Combining TASS Movidius Inception V3 Classifier (prone to open set recognition issues) and TASS Facenet Classifier will allow us to catch false positives and verify positive classifications using the name/ID of that prediction to quickly index into the images and make a single calculation to determine if Inception classified the person correctly or not using Facenet and making the project more scalable. The latest Inception version of the classifier will be uploaded to this repository soon.
- Install the Intel® NCSDK on a Linux development device.
- Clone & set up the repo.
- Install and download all requirements.
- Prepare your known and testing faces datasets.
- Test the TASS Facenet Classifier on the testing dataset.
- Run TASS Facenet Classifier on a live webcam
- Install the Intel® NCSDK API on a Raspberry Pi 3 / UP 2.
- Upload and run the program on an UP2 or Raspberry Pi 3
- Tested in Python 3.5
- 1 x Intel® Movidius
- 1 x Linux Desktop for Movidius development (Full SDK)
- 1 x Raspberry Pi 3 / UP Squared for the classifier / webcam
- 1 x Raspberry Pi 3 for IoT connected alarm
- 1 x Grove starter kit for IoT, Raspberry Pi edition
- 1 x Blue LED (Grove)
- 1 x Red LED (Grove)
- 1 x Buzzer (Grove)
The first thing you will need to do is to install the NCSDK on your development device.
$ mkdir -p ~/workspace
$ cd ~/workspace
$ git clone https://github.com/movidius/ncsdk.git
$ cd ~/workspace/ncsdk
$ make install
Next plug your Movidius into your device and issue the following commands:
$ cd ~/workspace/ncsdk
$ make examples
You will need to clone this repository to a location on your development terminal. Navigate to the directory you would like to download it to and issue the following commands.
$ git clone https://github.com/TASS-AI/TASS-Facenet.git
Once you have the repo, you will need to find the files in this folder located in TASS-Facenet.
Now you need to setup the software required for the classifier to run. The setup.sh script is a shell script that you can run on both your development device and Raspberry Pi 3 / UP Squared device.
Make sure you have installed the NCSDK on your developement machine, the following command assumes you are located in the TASS-Facenet directory.
The setup.sh file is an executable shell script that will do the following:
- Install the required packages named in requirements.txt
- Downloads the pretrained Facenet model (davidsandberg/facenet)
- Downloads the pretrained Inception V3 model
- Converts the Facenet model to a model that is compatible with the Intel® Movidius
To execute the script, enter the following command:
$ sh setup.sh
If you have problems running the above program and have errors try run the following command before executing the shell script. You may be getting errors due to the shell script having been edited on Windows, the following command will clean the setup file.
$ sed -i 's/\r//' setup.sh
$ sh setup.sh
Setup an iotJumpWay Location Device for IDC Classifier, ensuring you set up a camera node, as you will need the ID of the dummy camera for the project to work. Once your create your device add the location ID and Zone ID to the IoTJumpWay details in the confs file located at required/confs.json, also add the device ID and device name exactly, add the MQTT credentials to the IoTJumpWayMQTT .
You will need to edit your device and add the rules that will allow it to communicate autonomously with the other devices and applications on the network, but for now, these are the only steps that need doing at this point.
Follow the iotJumpWay Dev Program Location Device Doc to set up your devices.
{
"IoTJumpWay": {
"Location": 0,
"Zone": 0,
"Device": 0,
"DeviceName" : "",
"App": 0,
"AppName": ""
},
"Actuators": {},
"Cameras": [
{
"ID": 0,
"URL": 0,
"Name": "",
"Stream": "",
"StreamPort": 8080
}
],
"Sensors": {},
"IoTJumpWayMQTT": {
"MQTTUsername": "",
"MQTTPassword": ""
},
"ClassifierSettings":{
"NetworkPath":"",
"Graph":"model/tass.graph",
"Dlib":"model/dlib/shape_predictor_68_face_landmarks.dat",
"dataset_dir":"model/train/",
"TestingPath":"data/testing/",
"ValidPath":"data/known/",
"Threshold": 1.20
}
}
You need to set up two very small datasets. As we are using a pretrained Facenet model there is no training to do in this tutorial and we only need one image per known person. You should see the known and testing folders in the data directory, this is where you will store 1 image of each person you want to be identified by the network, and also a testing dataset that can include either known or unknown faces for testing. When you store the known data, you should name each image with the name you want them to be identified as in the system, in my testing I used images of me and two other random people, the 1 image used to represent myself in the known folder was named Adam
Now it is time to test out your classifier, on your development machine in the TASS-Facenet directory:
$ python3.5 Classifier.py
This will run the classifier test program, the program will first loop through your testing images, and once it sees a face it will loop through all of the known faces and match them against the faces, once it finds a match, or not, it will move on to the next image in your testing loop until all images have been classifier as known or unknown.
-- Total Difference is: 1.7931939363479614
-- NO MATCH
-- Total Difference is: 0.8448524475097656
-- MATCH Adam-2.jpg
Now comes the good part, realtime facial recognition and identification.
WebCam.py should connect to the local webcam on your device, process the frames and send them to a local server that is started by this same program. Be sure to edit the ID and Name values of the Cameras section of required/confs.json section using the details provided when setting up the configs, and add the URL of the IP of your device ie: http://192.168.1.200 to the Stream value and you can change StreamPort to whatever you want. These two fields will determine the address that you access your camera on, using the previous IP (Stream) and the StreamPort as 8080 the address would be http://192.168.1.200:8080/index.html.
"Cameras": [
{
"ID": 0,
"URL": 0,
"Name": "",
"Stream": "",
"StreamPort": 8080
}
The program uses a dlib model to recognize faces in the frames / mark the facial points on the frame, and Facenet to determine whether they are a known person or not. Below are the outputs around the time that the above photo was taken. You will see that the program publishes to the Warnings channel of the iotJumpWay, this is currently the name for the channel that handles device to device communication via rules.
-- Saved frame
-- Total Difference is: 1.0537698864936829
-- MATCH
-- Published: 30
-- Published to Device Warnings Channel
If you would like to use the IDC Classifier on the edge, this tutorial has been tested on the UP2 and the Raspberry Pi. You can install the NCSDK on your UP Squared / Raspberry Pi 3 device, this will be used by the classifier to carry out inference on local images or images received via the API we will create. Make sure you have the Movidius plugged in to the edge device and follow the guide below:
$ mkdir -p ~/workspace
$ cd ~/workspace
$ git clone https://github.com/movidius/ncsdk.git
$ cd ~/workspace/ncsdk/api/src
$ make
$ sudo make install
$ cd ~/workspace
$ git clone https://github.com/movidius/ncappzoo
$ cd ncappzoo/apps/hello_ncs_py
$ python3 hello_ncs.py
Now you need to upload the required files to the UP Squared / Raspberry Pi 3. Copy the TASS-Facenet directory from your development machine to your UP Squared / Raspberry Pi 3 then navigate to the home directory of the project on your device and run the following command.
$ pip3 install -r requirements.txt --user
You can use the TASS Facenet Classifier on UP Squared / Raspberry Pi 3 by entering the following command in the TASS-Facenet directory of your UP Squared / Raspberry Pi 3:
$ python3.5 Classifier.py
WebCam.py connects to a local webcam on your device or IP cam, processes the frames and sends them to a local server that is started by this same program. Be sure to edit the ID and Name values of the Cameras section of required/confs.json section using the details provided when setting up the configs, and add the URL of the IP of your device ie: http://192.168.1.200 to the Stream value and you can change StreamPort to whatever you want. These two fields will determine the address that you access your camera on, using the previous IP (Stream) and the StreamPort as 8080 the address would be http://192.168.1.200:8080/index.html.
You can process / stream a webcam using the TASS Facenet Classifier on UP Squared / Raspberry Pi 3 by entering the following command in the TASS-Facenet directory of your UP Squared / Raspberry Pi 3:
$ python3.5 WebCam.py
Server.py will launch a local server that will make the TASS Facenet Classifier accessible as an API endpoint on your local network. The next step is to use the provided client to send images to this API, but you can also use this for Desktop / Mobile applications and other IoT devices / applications.
For extra security it is also possible to add an A record to your web domain's DNS Zone pointing a sub domain to your public IP, then with port forwarding you can forward requests to the IP/Port of the API, combining this with services such as LetsEncrypt will allow you to send requests to your API from the outside world over an encrypted connection.
You can start the TASS Facenet Classifier on UP Squared / Raspberry Pi 3 by entering the following command in the TASS-Facenet directory of your UP Squared / Raspberry Pi 3:
$ python3.5 Server.py
Now leave this connection and open a new terminal session to your device.
The final program of this project allows you to send testing images from the data/testing/ directory to the API for classification.
You can start sending images to TASS Facenet Classifier Server on UP Squared / Raspberry Pi 3 by entering the following command in the TASS-Facenet directory of your UP Squared / Raspberry Pi 3:
$ python3.5 Client.py
- Uses code from Intel® movidius/ncsdk (movidius/ncsdk Github)
- Uses code from Intel® davidsandberg/facenet (davidsandberg/facenet Github)
Please read CONTRIBUTING.md for details on our code of conduct, and the process for submitting pull requests to us.
We use SemVer for versioning. For the versions available, see the tags on this repository.
This project is licensed under the MIT License - see the LICENSE.md file for details
We use issues to track bugs and general requests related to using this project.
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