Multiple constraints rate distortion optimization for a video encoder control

Abstract

Current video coding standards like HEVC, VP9, VVC, AV1, etc., involve partitioning a picture into coding tree units (CTU), typically corresponding to 64x64 or 128x128 picture areas. Each CTU is partitioned into coding blocks following a recursive coding tree. In recently published perceptual video encoding methods, the CTU is used as the spatial unit to assign a QP value in a given picture area. Such an approach fits well with the usual rate distortion optimization used to decide the coding tree representation of a CTU since a constant QP is used inside the CTU. Thus Lagrangian rate distortion optimization works in such a situation. However, for some applications, finer spatial granularity may be desired with an adaptive QP. A perceptual video coding scheme may use a codec agnostic QP allocation process that proceeds on a 16x16 block basis. The issue raised in such a case is that the rate distortion trade-off among split modes no more works with the Lagrangian method. This paper proposes several methods to perform the rate distortion optimization of a coding tree in the situation where multiple QPs may be assigned inside the same CTU. First a theoretical method to solve the problem is described. It consists in a coding tree RD optimization using multiple Lagrange parameters. Then some simpler empirical methods which emulate the theoretical approach are proposed. Experimental results show the benefit of the proposed methods on top of VP9 and HEVC video encoders.