Learned Nonlinear Predictor for Critically Sampled 3D Point Cloud Attribute Compression

Abstract

We study 3D point cloud attribute compression via a volumetric approach: assuming point cloud geometry is known at both encoder and decoder, parameters θ of a continuous attribute function f: R3 R are quantized to θ and encoded, so that discrete samples fθ(xi) can be recovered at known 3D points xi ∈ R3 at the decoder. Specifically, we consider a nested sequences of function subspaces F(p)l0 ⊂eq ·s ⊂eq F(p)L, where Fl(p) is a family of functions spanned by B-spline basis functions of order p, fl* is the projection of f on Fl(p) represented as low-pass coefficients Fl*, and gl* is the residual function in an orthogonal subspace Gl(p) (where Gl(p) Fl(p) = Fl+1(p)) represented as high-pass coefficients Gl*. In this paper, to improve coding performance over do2023volumetric, we study predicting fl+1* at level l+1 given fl* at level l and encoding of Gl* for the p=1 case (RAHT(1)). For the prediction, we formalize RAHT(1) linear prediction in MPEG-PCC in a theoretical framework, and propose a new nonlinear predictor using a polynomial of bilateral filter. We derive equations to efficiently compute the critically sampled high-pass coefficients Gl* amenable to encoding. We optimize parameters in our resulting feed-forward network on a large training set of point clouds by minimizing a rate-distortion Lagrangian. Experimental results show that our improved framework outperforms the MPEG G-PCC predictor by 11\%--12\% in bit rate.

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