English

Drivable Volumetric Avatars using Texel-Aligned Features

Computer Vision and Pattern Recognition 2022-07-21 v1

Abstract

Photorealistic telepresence requires both high-fidelity body modeling and faithful driving to enable dynamically synthesized appearance that is indistinguishable from reality. In this work, we propose an end-to-end framework that addresses two core challenges in modeling and driving full-body avatars of real people. One challenge is driving an avatar while staying faithful to details and dynamics that cannot be captured by a global low-dimensional parameterization such as body pose. Our approach supports driving of clothed avatars with wrinkles and motion that a real driving performer exhibits beyond the training corpus. Unlike existing global state representations or non-parametric screen-space approaches, we introduce texel-aligned features -- a localised representation which can leverage both the structural prior of a skeleton-based parametric model and observed sparse image signals at the same time. Another challenge is modeling a temporally coherent clothed avatar, which typically requires precise surface tracking. To circumvent this, we propose a novel volumetric avatar representation by extending mixtures of volumetric primitives to articulated objects. By explicitly incorporating articulation, our approach naturally generalizes to unseen poses. We also introduce a localized viewpoint conditioning, which leads to a large improvement in generalization of view-dependent appearance. The proposed volumetric representation does not require high-quality mesh tracking as a prerequisite and brings significant quality improvements compared to mesh-based counterparts. In our experiments, we carefully examine our design choices and demonstrate the efficacy of our approach, outperforming the state-of-the-art methods on challenging driving scenarios.

Keywords

Cite

@article{arxiv.2207.09774,
  title  = {Drivable Volumetric Avatars using Texel-Aligned Features},
  author = {Edoardo Remelli and Timur Bagautdinov and Shunsuke Saito and Tomas Simon and Chenglei Wu and Shih-En Wei and Kaiwen Guo and Zhe Cao and Fabian Prada and Jason Saragih and Yaser Sheikh},
  journal= {arXiv preprint arXiv:2207.09774},
  year   = {2022}
}
R2 v1 2026-06-25T01:04:34.437Z