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Volumetric 3D Point Cloud Attribute Compression: Learned polynomial bilateral filter for prediction

Signal Processing 2023-11-23 v1

Abstract

We extend a previous study on 3D point cloud attribute compression scheme that uses a volumetric approach: given a target volumetric attribute function f:R3Rf : \mathbb{R}^3 \mapsto \mathbb{R}, we quantize and encode parameters θ\theta that characterize ff at the encoder, for reconstruction fθ^((x))f_{\hat{\theta}}(\mathbf(x)) at known 3D points (x)\mathbf(x) at the decoder. Specifically, parameters θ\theta are quantized coefficients of B-spline basis vectors Φl\mathbf{\Phi}_l (for order p2p \geq 2) that span the function space Fl(p)\mathcal{F}_l^{(p)} at a particular resolution ll, which are coded from coarse to fine resolutions for scalability. In this work, we focus on the prediction of finer-grained coefficients given coarser-grained ones by learning parameters of a polynomial bilateral filter (PBF) from data. PBF is a pseudo-linear filter that is signal-dependent with a graph spectral interpretation common in the graph signal processing (GSP) field. We demonstrate PBF's predictive performance over a linear predictor inspired by MPEG standardization over a wide range of point cloud datasets.

Keywords

Cite

@article{arxiv.2311.13533,
  title  = {Volumetric 3D Point Cloud Attribute Compression: Learned polynomial bilateral filter for prediction},
  author = {Tam Thuc Do and Philip A. Chou and Gene Cheung},
  journal= {arXiv preprint arXiv:2311.13533},
  year   = {2023}
}
R2 v1 2026-06-28T13:28:47.839Z