VENI: Variational Encoder for Natural Illumination
Abstract
Inverse rendering is an ill-posed problem, but priors like illumination priors, can simplify it. Existing work either disregards the spherical and rotation-equivariant nature of illumination environments or does not provide a well-behaved latent space. We propose a rotation-equivariant variational autoencoder that models natural illumination on the sphere without relying on 2D projections. To preserve the SO(2)-equivariance of environment maps, we use a novel Vector Neuron Vision Transformer (VN-ViT) as encoder and a rotation-equivariant conditional neural field as decoder. In the encoder, we reduce the equivariance from SO(3) to SO(2) using a novel SO(2)-equivariant fully connected layer, an extension of Vector Neurons. We show that our SO(2)-equivariant fully connected layer outperforms standard Vector Neurons when used in our SO(2)-equivariant model. Compared to previous methods, our variational autoencoder enables smoother interpolation in latent space and offers a more well-behaved latent space.
Keywords
Cite
@article{arxiv.2601.14079,
title = {VENI: Variational Encoder for Natural Illumination},
author = {Paul Walker and James A. D. Gardner and Andreea Ardelean and William A. P. Smith and Bernhard Egger},
journal= {arXiv preprint arXiv:2601.14079},
year = {2026}
}
Comments
Project Repo - https://github.com/paul-pw/veni Project page - https://paul-pw.github.io/veni