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Synthetic Dataset Generation for Object-to-model Deep Learning

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Synthetic dataset generation for object-to-model deep learning in industrial applications

The project is published in PeerJ Computer Science.

The original full report of the project can be found here.

The short demo video can be found here.

About the project

The availability of large image data sets has been a crucial factor in the success of deep learning-based classification and detection methods. Yet, while data sets for everyday objects are widely available, data for specific industrial use-cases (e.g., identifying packaged products in a warehouse) remains scarce. In such cases, the data sets have to be created from scratch, placing a crucial bottleneck on the deployment of deep learning techniques in industrial applications. We present work carried out in collaboration with a leading UK online supermarket, with the aim of creating a computer vision system capable of detecting and identifying unique supermarket products in a warehouse setting. To this end, we demonstrate a framework for using data synthesis to create an end-to-end deep learning pipeline, beginning with real-world objects and culminating in a trained model. Our method is based on the generation of a synthetic dataset from 3D models obtained by applying photogrammetry techniques to real-world objects. Using 100K synthetic images for 10 classes, an InceptionV3 convolutional neural network was trained, which achieved accuracy of 96% on a separately acquired test set of real supermarket product images. The image generation process supports automatic pixel annotation. This eliminates the prohibitively expensive manual annotation typically required for detection tasks. Based on this readily available data, a one-stage RetinaNet detector was trained on the synthetic, annotated images to produce a detector that can accurately localize and classify the specimen products in real-time.

This project was conducted for Software Engineering Practice and Group project (CO 530), MSc in Computing Science at Imperial College London, and was awarded for "Corporate Partnership Programme Commendation for Group Project" (2017-18 Sponsored Prizes).

Product Classification Demo

Product Detection Demo

Design Choices

Standard Pipeline Design vs Custom Pipeline Design

Under the standard design that is applied to most deep learning projects, a pre-existing data set would be used to train a neural network, which would then be evaluated and optimised.

While the standard pipeline works well when a high-quality data set is available, given the challenges described above inherent in the data set we were provided with, the standard pipeline designed was not considered to be a viable option.

Specifically, instead of training a neural network on a pre-existing data set, we decided to generate our own data and to curate our own data set using 3D modelling and Image Rendering techniques.

Image Rendering

An interface between the generated 3D models and the input to the neural network was also necessary, using 3D models as the direct input to a classifier is is highly complex and would not achieve our goal of producing a scalable system for classifying 2D images.

We developed an image rendering system that would take a 3D model as its input and produce a set of training images as its output, given a number of rendering parameters θ as shown in the figure above. The system would use the 3D model to produce multiple images showcasing the modelled product from all possible viewpoints, at different scale, under various lighting conditions, with different amounts of occlusion and with varying backgrounds.

A classifier trained on such generated data is expected to be robust to varying backgrounds, light conditions, occlusion, scale and pose. Furthermore, it allows the user to tailor the training set to a particular environment for which the image classifier will be deployed.

Final System Design

Our final system design shown in the figure below incorporated the key design choices describe above. These resulted in a custom neural network pipeline which goes from generation of 3D models to a customised evaluation suite used to optimise classification accuracy.

The individual component functionality is outlined as follows.

  • Data Generation: provides 3D models of 10 products in .obj format. These models include textures and colour representations of the product and have to be of high enough quality to produce realistic product images in the next stage.
  • Data Processing (Image Rendering): produces a specified number of training images for each product which vary product pose, lighting, background and occlusions. The type of background can be specified by the user. Both the rendered product and a background from a database are combined to create a unique training image in .jpeg format.
  • Neural Network: the produced images are fed into a pre-trained convolutional neural network. The resulting retrained classifier should be able to classify real product images.
  • Evaluation and Optimisation: the outlined approach to training data generation means that the training data can be tailored based on results. Therefore, a custom evaluation and optimization suite is required that is not provided in sufficient in detail in off-the-shelf solutions.

Installation & Dependencies

Activate correct CUDA version to link TF to GPU

create a file in your home directory called .bash_profile with content and save:

if [ -f /vol/cuda/8.0.61-cudnn.7.0.2/setup.sh ]
then
   . /vol/cuda/8.0.61-cudnn.7.0.2/setup.sh
fi

(The above code is for Imperial Collge London Lab PC environment)

then log out and log in again or restart bash.

Create Virtual Environment

The first step is to install virtualenv.

pip install virtualenv

The next is to initialise the virtual environment with

virtualenv -p python3 venv

Get into the virtualenv

source venv/bin/activate

Install all the dependencies within the virtual environment.

pip install -r requirements.txt

How to run each program

Integrated Pipeline: main.py

provide paths to validation and test set, currently pointing to the example folders provided with this repository.

provide the path to your blender installation in bl_path = 'PATH/TO/BLENDER/INSTALLATION'

Choose all parameters in main.py for rendering and neural network training, save and run

$python main.py

Rendering API

README can be found in /src/rendering.

Training and Evaluation

README can be found in /kerasmodels.

iPhone App

README can be found in /iPhone_app.

Flask

README can be found in /flask_webserver.

Project Team Members

Should you have any questions regarding how to run the above, please contact one of the project team members.