This repository provides an implementation of an aesthetic and technical image quality model based on Google's research paper "NIMA: Neural Image Assessment". You can find a quick introduction on their Research Blog.
NIMA consists of two models that aim to predict the aesthetic and technical quality of images, respectively. The models are trained via transfer learning, where ImageNet pre-trained CNNs are used and fine-tuned for the classification task.
For more information on how we used NIMA for our specifc problem, we did a write-up on two blog posts:
- NVIDIA Developer Blog: Deep Learning for Classifying Hotel Aesthetics Photos
- Medium: Using Deep Learning to automatically rank millions of hotel images
The provided code allows to use any of the pre-trained models in Keras. We further provide Docker images for local CPU training and remote GPU training on AWS EC2, as well as pre-trained models on the AVA and TID2013 datasets.
Read the full documentation at: https://idealo.github.io/image-quality-assessment/.
Image quality assessment is compatible with Python 3.6 and is distributed under the Apache 2.0 license. We welcome all kinds of contributions, especially new model architectures and/or hyperparameter combinations that improve the performance of the currently published models (see Contribute).
Predictions from aesthetic model |
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Predictions from technical model |
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We provide trained models, for both aesthetic and technical classifications, that use MobileNet as the base CNN. The models and their respective config files are stored under models/MobileNet
. They achieve the following performance
Model | Dataset | EMD | LCC | SRCC |
---|---|---|---|---|
MobileNet aesthetic | AVA | 0.071 | 0.626 | 0.609 |
MobileNet technical | TID2013 | 0.107 | 0.652 | 0.675 |
In order to train remotely on AWS EC2
-
Install Docker Machine
-
Install AWS Command Line Interface
In order to run predictions on an image or batch of images you can run the prediction script
-
Single image file
./predict \ --docker-image nima-cpu \ --base-model-name MobileNet \ --weights-file $(pwd)/models/MobileNet/weights_mobilenet_technical_0.11.hdf5 \ --image-source $(pwd)/src/tests/test_images/42039.jpg
-
All image files in a directory
./predict \ --docker-image nima-cpu \ --base-model-name MobileNet \ --weights-file $(pwd)/models/MobileNet/weights_mobilenet_technical_0.11.hdf5 \ --image-source $(pwd)/src/tests/test_images
-
Download dataset (see instructions under Datasets)
-
Run the local training script (e.g. for TID2013 dataset)
./train-local \ --config-file $(pwd)/models/MobileNet/config_technical_cpu.json \ --samples-file $(pwd)/data/TID2013/tid_labels_train.json \ --image-dir /path/to/image/dir/local
This will start a training container from the Docker image nima-cpu
and create a timestamp train job folder under train_jobs
, where the trained model weights and logs will be stored. The --image-dir
argument requires the path of the image directory on your local machine.
In order to stop the last launched container run
bash CONTAINER_ID=$(docker ps -l -q) docker container stop $CONTAINER_ID
In order to stream logs from last launched container run
bash CONTAINER_ID=$(docker ps -l -q) docker logs $CONTAINER_ID --follow
-
Configure your AWS CLI. Ensure that your account has limits for GPU instances and read/write access to the S3 bucket specified in config file [link]
aws configure
-
Launch EC2 instance with Docker Machine. Choose an Ubuntu AMI based on your region (https://cloud-images.ubuntu.com/locator/ec2/). For example, to launch a
p2.xlarge
EC2 instance namedec2-p2
run (NB: change region, VPC ID and AMI ID as per your setup)docker-machine create --driver amazonec2 \ --amazonec2-region eu-west-1 \ --amazonec2-ami ami-58d7e821 \ --amazonec2-instance-type p2.xlarge \ --amazonec2-vpc-id vpc-abc \ ec2-p2
-
ssh into EC2 instance
docker-machine ssh ec2-p2
-
Update NVIDIA drivers and install nvidia-docker (see this blog post for more details)
# update NVIDIA drivers sudo add-apt-repository ppa:graphics-drivers/ppa -y sudo apt-get update sudo apt-get install -y nvidia-375 nvidia-settings nvidia-modprobe # install nvidia-docker wget -P /tmp https://github.com/NVIDIA/nvidia-docker/releases/download/v1.0.1/nvidia-docker_1.0.1-1_amd64.deb sudo dpkg -i /tmp/nvidia-docker_1.0.1-1_amd64.deb && rm /tmp/nvidia-docker_1.0.1-1_amd64.deb
-
Download dataset to EC2 instance (see instructions under Datasets). We recommend to save the AMI with the downloaded data for future use.
-
Run the remote EC2 training script (e.g. for AVA dataset)
./train-ec2 \ --docker-machine ec2-p2 \ --config-file $(pwd)/models/MobileNet/config_aesthetic_gpu.json \ --samples-file $(pwd)/data/AVA/ava_labels_train.json \ --image-dir /path/to/image/dir/remote
The training progress will be streamed to your terminal. After the training has finished, the train outputs (logs and best model weights) will be stored on S3 in a timestamped folder. The S3 output bucket can be specified in the config file. The --image-dir
argument requires the path of the image directory on your remote instance.
We welcome all kinds of contributions and will publish the performances from new models in the performance table under Trained models.
For example, to train a new aesthetic NIMA model based on InceptionV3 ImageNet weights, you just have to change the base_model_name
parameter in the config file models/MobileNet/config_aesthetic_gpu.json
to "InceptionV3". You can also control all major hyperparameters in the config file, like learning rate, batch size, or dropout rate.
See the Contribution guide for more details.
This project uses two datasets to train the NIMA model:
For training on AWS EC2 we recommend to build a custom AMI with the AVA images stored on it. This has proven much more viable than copying the entire dataset from S3 to the instance for each training job.
The train script requires JSON label files in the format
[
{
"image_id": "231893",
"label": [2,8,19,36,76,52,16,9,3,2]
},
{
"image_id": "746672",
"label": [1,2,7,20,38,52,20,11,1,3]
},
...
]
The label for each image is the normalized or un-normalized frequency distribution of ratings 1-10.
For the AVA dataset these frequency distributions are given in the raw data files. For the TID2013 dataset we inferred the normalized frequency distribution, i.e. probability distribution, by finding the maximum entropy distribution that satisfies the mean score. The code to generate the TID2013 labels can be found under data/TID2013/get_labels.py
.
For both datasets we provide train and test set label files stored under
data/AVA/ava_labels_train.json
data/AVA/ava_labels_test.json
and
data/TID2013/tid2013_labels_train.json
data/TID2013/tid2013_labels_test.json
For the AVA dataset we randomly assigned 90% of samples to the train set, and 10% to the test set, and throughout training a 5% validation set will be split from the training set to evaluate the training performance after each epoch. For the TID2013 dataset we split the train/test sets by reference images, to ensure that no reference image, and any of its distortions, enters both the train and test set.
TensorFlow versions of both the technical and aesthetic MobileNet models are provided,
along with the script to generate them from the original Keras files, under the contrib/tf_serving
directory.
There is also an already configured TFS Dockerfile
that you can use.
To get predictions from the aesthetic or technical model:
- Build the NIMA TFS Docker image
docker build -t tfs_nima contrib/tf_serving
- Run a NIMA TFS container with
docker run -d --name tfs_nima -p 8500:8500 tfs_nima
- Install python dependencies to run TF serving sample client
virtualenv -p python3 contrib/tf_serving/venv_tfs_nima source contrib/tf_serving/venv_tfs_nima/bin/activate pip install -r contrib/tf_serving/requirements.txt
- Get predictions from aesthetic or technical model by running the sample client
python -m contrib.tf_serving.tfs_sample_client --image-path src/tests/test_images/42039.jpg --model-name mobilenet_aesthetic python -m contrib.tf_serving.tfs_sample_client --image-path src/tests/test_images/42039.jpg --model-name mobilenet_technical
Please cite Image Quality Assessment in your publications if this is useful for your research. Here is an example BibTeX entry:
@misc{idealods2018imagequalityassessment,
title={Image Quality Assessment},
author={Christopher Lennan and Hao Nguyen and Dat Tran},
year={2018},
howpublished={\url{https://github.com/idealo/image-quality-assessment}},
}
See LICENSE for details.