?-Domain VVC Rate Control Based on Nash Equilibrium

With a significant Rate-Distortion (RD) improvement than H.265/HEVC, Versatile Video Coding (VVC) has set a new milestone in lossy video compression. It also incorporates the emerging ?-domain rate control technique, aiming at a higher visual quality under a fixed bit constraint. However, the challenge remains how to efficiently allocate bits to all frames and Coding Tree Units (CTUs). In this paper, we propose an effective solution by formulating the above task as a Nash equilibrium problem, where all CTUs are treated as players that bargains with each other. By introducing ?-domain RD models, a constrained optimization is derived with no closed-form solution. We then propose a two-step strategy to address this issue: a Newton method to iteratively calculate an intermediate variable, and a final solution of Nash equilibrium to obtain an approximately optimal ?. Finally, we utilize the derived 1 to perform an effective CTU-level bit allocation, which is the very first attempt to introduce Nash equilibrium in ?-domain rate control. Experimental results with Common Test Conditions (CTC) demonstrate the effectiveness and superiority of our method, which outperforms the state-of-the-art CTU-level rate allocation algorithms for VVC.

Automated summary

In this paper, a solution is proposed to address the bit allocation problem in VVC video compression by formulating it as a Nash equilibrium problem. By introducing ?-domain RD models, a constrained optimization problem is derived and solved using a Newton method and Nash equilibrium. Experimental results demonstrate the effectiveness and superiority of the proposed method.