DUDF: Differentiable Unsigned Distance Fields with Hyperbolic Scaling
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Fainstein, Miguel
Siless, Viviana
Iarussi, Emmanuel
Date:
2024Abstract
In recent years, there has been a growing interest in
training Neural Networks to approximate Unsigned Distance
Fields (UDFs) for representing open surfaces in the
context of 3D reconstruction. However, UDFs are nondifferentiable
at the zero level set which leads to significant
errors in distances and gradients, generally resulting
in fragmented and discontinuous surfaces. In this paper,
we propose to learn a hyperbolic scaling of the unsigned
distance field, which defines a new Eikonal problem
with distinct boundary conditions. This allows our formulation
to integrate seamlessly with state-of-the-art continuously
differentiable implicit neural representation networks,
largely applied in the literature to represent signed distance
fields. Our approach not only addresses the challenge of
open surface representation but also demonstrates significant
improvement in reconstruction quality and training
performance. Moreover, the unlocked field’s differentiability
allows the accurate computation of essential topological
properties such as normal directions and curvatures, pervasive
in downstream tasks such as rendering. Through extensive
experiments, we validate our approach across various
data sets and against competitive baselines. The results
demonstrate enhanced accuracy and up to an order of magnitude
increase in speed compared to previous methods.