Gene CheungViet Ho Tam Thuc Do2023-08-042023-08-042023-08-04https://hdl.handle.net/10315/41338We study 3D point cloud attribute compression using a volumetric approach: given a target volumetric attribute function $f : \mathbb{R}^3 \rightarrow \mathbb{R}$, we quantize and encode parameter vector $\theta$ that characterizes $f$ at the encoder, for reconstruction $f_{\hat{\theta}}(\x)$ at known 3D points $\x$'s at the decoder, where $\hat{\theta}$ is a quantized version of $\theta$. Extending a previous work Region Adaptive Hierarchical Transform (RAHT) that employs piecewise constant functions to span a nested sequence of function spaces, we propose a feedforward linear network that implements higher-order B-spline bases spanning function spaces without eigen-decomposition. Feedforward network architecture means that the system is amenable to end-to-end neural learning. The key to our network is space-varying convolution, similar to a graph operator, whose weights are computed from the known 3D geometry for normalization. We show that the number of layers in the normalization at the encoder is equivalent to the number of terms in a matrix inverse Taylor series. Experimental results on real-world 3D point clouds show up to 2-3 dB gain over RAHT in energy compaction and 20-30\% in bitrate reduction.Author owns copyright, except where explicitly noted. Please contact the author directly with licensing requests.EngineeringComputer scienceApplied mathematicsVolumetric Attribute Compression for 3D Point Clouds using Feedforward Network with Geometric AttentionElectronic Thesis or Dissertation2023-08-043D point cloud compressionSignal Processing