Graph Fourier Transform with Negative Edges for Depth Image Coding
Abstract
Recent advent in graph signal processing (GSP) has led to the development of new graph-based transforms and wavelets for image / video coding, where the underlying graph describes inter-pixel correlations. In this paper, we develop a new transform called signed graph Fourier transform (SGFT), where the underlying graph G contains negative edges that describe anti-correlations between pixel pairs. Specifically, we first construct a one-state Markov process that models both inter-pixel correlations and anti-correlations. We then derive the corresponding precision matrix, and show that the loopy graph Laplacian matrix Q of a graph G with a negative edge and two self-loops at its end nodes is approximately equivalent. This proves that the eigenvectors of Q - called SGFT - approximates the optimal Karhunen-Lo`eve Transform (KLT). We show the importance of the self-loops in G to ensure Q is positive semi-definite. We prove that the first eigenvector of Q is piecewise constant (PWC), and thus can well approximate a piecewise smooth (PWS) signal like a depth image. Experimental results show that a block-based coding scheme based on SGFT outperforms a previous scheme using graph transforms with only positive edges for several depth images.
Keywords
Cite
@article{arxiv.1702.03105,
title = {Graph Fourier Transform with Negative Edges for Depth Image Coding},
author = {Weng-Tai Su and Gene Cheung and Chia-Wen Lin},
journal= {arXiv preprint arXiv:1702.03105},
year = {2017}
}
Comments
5 pages, submitted to submitted to IEEE International Conference on Image Processing, Beijing, China, September, 2017