IEEE VIS 2024 Content: Improving Efficiency of Iso-Surface Extraction on Implicit Neural Representations Using Uncertainty Propagation

Improving Efficiency of Iso-Surface Extraction on Implicit Neural Representations Using Uncertainty Propagation

Haoyu Li -

Han-Wei Shen -

Room: Bayshore I

2024-10-16T12:42:00ZGMT-0600Change your timezone on the schedule page
2024-10-16T12:42:00Z
Exemplar figure, described by caption below
This image shows the iso-surface extraction results comparison between our approach on the right and the traditional approach on the left. We can only observe minor differences between them. The statistics of the missed iso-surface components also suggest our method preserves the accuracy while being much more efficient than the traditional iso-surface extraction method.
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Keywords

Iso-surface extraction, implicit neural representation, uncertainty propagation, affine arithmetic.

Abstract

Implicit Neural representations (INRs) are widely used for scientific data reduction and visualization by modeling the function that maps a spatial location to a data value. Without any prior knowledge about the spatial distribution of values, we are forced to sample densely from INRs to perform visualization tasks like iso-surface extraction which can be very computationally expensive. Recently, range analysis has shown promising results in improving the efficiency of geometric queries, such as ray casting and hierarchical mesh extraction, on INRs for 3D geometries by using arithmetic rules to bound the output range of the network within a spatial region. However, the analysis bounds are often too conservative for complex scientific data. In this paper, we present an improved technique for range analysis by revisiting the arithmetic rules and analyzing the probability distribution of the network output within a spatial region. We model this distribution efficiently as a Gaussian distribution by applying the central limit theorem. Excluding low probability values, we are able to tighten the output bounds, resulting in a more accurate estimation of the value range, and hence more accurate identification of iso-surface cells and more efficient iso-surface extraction on INRs. Our approach demonstrates superior performance in terms of the iso-surface extraction time on four datasets compared to the original range analysis method and can also be generalized to other geometric query tasks.