nilut

NILUT @ AAAI 2024

NILUT: Conditional Neural Implicit 3D Lookup Tables for Image Enhancement

The 38th Annual AAAI Conference on Artificial Intelligence (AAAI), 2024, Vancouver

arXiv colab demo Kaggle Dataset Tweet Paper page

Marcos V. Conde, Javier Vazquez-Corral, Michael S. Brown, Radu Timofte

TL;DR NILUT uses neural representations for controllable photorealistic image enhancement. πŸš€ Demo Tutorial and pretrained models available. Try it on colab!

NILUT


3D lookup tables (3D LUTs) are a key component for image enhancement. Modern image signal processors (ISPs) have dedicated support for these as part of the camera rendering pipeline. Cameras typically provide multiple options for picture styles, where each style is usually obtained by applying a handcrafted 3D LUT.

We propose a Neural Implicit LUT (NILUT), an implicitly defined continuous 3D color transformation parameterized by a neural network. We show that NILUTs are capable of accurately emulating real 3D LUTs. Moreover, a NILUT can be extended to incorporate multiple styles into a single network with the ability to blend styles implicitly. Our approach is memory-efficient, controllable and can complement previous methods, including learned ISPs.

✏️ Topics Image Enhancement, Image Editing, Color Manipulation, Tone Mapping, Presets

⚠️ Website and repo in progress. See also AISP for image signal processing code and papers.


Steps to fit a simple 3D LUT

  1. Get a 3D LUT as a .cube file. We provide a sample 3D LUT in dataset/cube-files.
  2. Generate a Hald image. You can check the script hald.py and run it with python hald.py. You can also download here a simple hald. This will be our input image I.
  3. Load the 3D LUT using the specific software (e.g. Lightroom) and apply it to the hald. This will be our β€œenahnced” target image I’ that reflects the 3D LUT style.
  4. You can now fit.py the 3D LUT transformation using the hald as I and the modified hald as I’.
python fit.py --in dataset/halds/Original_Image.png --target dataset/halds/LUT01_ContrastLUT.png --steps 1000 --units 128 --layers 2

In less than 30s you have it! Now your complex 3D LUT is just 3dlut.pt, is compact and differentiable, ready to use and plug&play in image processing/enhancement pipelines. You can run this instantly after forking this repo. See below more details and explanations.


Pre-trained models sample models are available at models/. We provide nilutx3style.pt a NILUT that encodes three 3D LUT styles (1,3,4) with high accuracy. Download the model here.

Demo Tutorial in nilut-multiblend.ipynb we provide a simple tutorial on how to use NILUT for multi-style image enhancement and blending. You can run it directly on colab in a few minutes. The corresponding training code will be released soon.

Simple Training check nilut.ipynb to see how to fit professional 3D LUT into a NILUT.

Dataset Download the complete dataset (13 Gb) from kaggle here. The complete folder MIT5K-100-3DLUT/ includes 100 images from the Adobe MIT 5K Dataset. The images were processed using professional 3D LUTs on Adobe Lightroom. For demo purposes, we include a sample dataset in releases, you can download it here. The structure of this dataset is:

dataset/
β”œβ”€β”€ 001_blend.png
β”œβ”€β”€ 001_LUT01.png
β”œβ”€β”€ 001_LUT02.png
β”œβ”€β”€ 001_LUT03.png
β”œβ”€β”€ 001_LUT04.png
β”œβ”€β”€ 001_LUT05.png
β”œβ”€β”€ 001_LUT08.png
β”œβ”€β”€ 001_LUT10.png
└── 001.png
...

where 001.png is the input unprocessed image, 001_LUTXX.png is the result of applying each corresponding LUT and 001_blend.png is the example target for evaluating sytle-blending (in the example the blending is between styles 1,3, and 4 with equal weights 0.33). The complete dataset includes 100 images (e.g. 001.png) and their enhanced variants for each 3D LUT (e.g. 001_LUT01.png).

How do we learn?

The complete E2E tutorial example on how to fit a NILUT is at nilut.ipynb

NILUT Fit

We use Hald images, a graphical representation of a 3D LUT in the form of a color table that contains all of the color gradations of the 3D LUT. Considering the input RGB space Hald, and the resultant one after applying a 3D LUT, we can use such pairs for training our models. You can read the details in our paper Section 4.

For example, we can represent the RGB color space (i.e. all the possible intensities) considering 256^3 = 16.78M points. This set of points can be represented as an image of dimension 4096Γ—4096Γ—3 (below, left). We can sample less points and build the hald image of the RGB space smaller β€” see dataset/halds/Original_Image.png.

These images are available (together with the 3D LUT file) in our dataset. Download here a simple hald.

Hald

You can read more about this here: https://3dlutcreator.com/3d-lut-creatorβ€”materials-and-luts.html

3D LUT video

Why is this interesting?

CNILUT paper

Frequent questions

where is the full dataset?

We host the dataset on Kaggle, you can download it here (13 Gb). The dataset includes 100 images (e.g. 001.png) and their enhanced variants for each 3D LUT (e.g. 001_LUT01.png).

You can download a demo dataset to test out the model fitting and pre-trained models. The 3D LUTs (.cube) are released under CC 4.0 license. The images are from Adobe MIT5K dataset and therefore keeps the original license.

how the style interpolation works?

First of all, is a cool feature, we are working on it, and more work in that direction is coming :) The implicit style blending is similar to the interpolation in other implicit neural representations (INRs) – pixel interpolation in 2D INRs such as SIREN, novel view synthesis in 3D with NeRF. The more training points, the better the interpolation function is. In our example nilut-multiblend.ipynb we provide a CNILUT with encoded 3D LUT styles and trained on the blending basis [0.33, 0.33, 0.33] (i.e. equal contribution of each style). To achieve β€œany” blending, more training points are required to learn the manifold of styles, for example [0.5, 0.5, 0] [0.5, 0, 0.5] [0, 0.5, 0.5] etc. Training can take time, but once it is trained, a simple MLP encodes multiple 3D LUTs and can accurately blend them, moreover, since the model is constrained to pixel-wise transformations, no artifacts are introduced.


Hope you like it πŸ€— If you find this interesting/insightful/inspirational or you use it, do not forget to acknowledge our work:

@inproceedings{conde2024nilut,
  title={NILUT: Conditional Neural Implicit 3D Lookup Tables for Image Enhancement},
  author={Conde, Marcos V and Vazquez-Corral, Javier and Brown, Michael S and Timofte, Radu},
  booktitle={Proceedings of the AAAI Conference on Artificial Intelligence},
  year={2024}
}

Contact marcos.conde[at]uni-wuerzburg.de