Gaussian-Wiener Representation and Hierarchical Coding Scheme for Focal Stack Images

Abstract

Focal stack images (FoSIs) are a set of 2D images that captured one scene with serial focal depths. The redundancies of FoSIs mainly come from gradual focused depths changes rather than motion of objects. Conventional coding schemes cannot fully exploit such redundancies, leading to coding inefficiency. In this paper, we propose a new Gaussian-Wiener representation to model the gradual focused depths changes among FoSIs. In the representation, image degradation-restoration relations are utilized to describe the focus-defocus changing characteristics of FoSIs. Based on this representation, we propose a new hierarchical coding scheme for fully exploiting the inter-frame redundancies of FoSIs. In the scheme, a Gaussian-Wiener representation based inter prediction (GWR-IP) is presented by embedding Gaussian convolution and Wiener deconvolution into normal video encoder. Block-wise focus-defocus changing of FoSIs can be predicted in bi-directional manner by solving optimization problem. For higher coding efficiency, a Gaussian-Wiener representation based hierarchical prediction structure (GWR-HPS) is also designed and applied in the coding scheme. The proposed coding scheme is performed on 10 test sequences, including 5 synthetic scenes and 5 realistic scenes. Experimental results show that proposed coding scheme can obtain 2.640 dB PSNR gains and 51.830% bitrate savings on average of all test sequences in Low Delay P configuration, 2.123 dB PSNR gains and 43.975% bitrate savings in Low Delay B configuration, and 1.044 dB PSNR gains and 26.078% bitrate savings in Random Access configuration. Particularly, it achieves up to 65.544% bit rate savings and 3.901 dB PSNR increments for test sequence I09 in Low Delay P configuration. Furthermore, ablation test demonstrates that Gaussian representation contributes more on coding performance than Wiener representation and GWR-HPS.