Policy-DRIFT: Dynamic Reward-Informed Flow Trajectory Steering
摘要
Skin-friction drag induced by wall-bounded turbulent flows accounts for a substantial fraction of energy consumption across commercial aerospace, wind energy, and marine transport. Its active reduction is one of the highest-value targets in engineering fluid dynamics. Deep reinforcement learning (DRL) has emerged as the leading approach for real-time flow control, yet its performance ceiling is set not by algorithmic capability but by reward structure, the naive scalar objective does not optimally reflect the underlying physics. Policy-DRIFT bypasses this ceiling by relocating reward information from policy gradients to generative model inference: a conditional flow matching model (CFM) constructs a physically-grounded manifold of realisable flow states spanning multiple control regimes, Terminal Reward Guidance (TRG) steers samples toward reward-maximising targets at inference, and a lightweight DRL policy, structurally decoupled from reward quality, tracks these full-field targets via root-mean-squared error (RMSE) minimisation. The test case is turbulent channel flow simulated using direct numerical simulation (DNS) at friction Reynolds number of , which is the canonical benchmark for wall-bounded turbulence. Policy-DRIFT achieves drag reduction approaching the theoretical upper bound, which is higher than the DRL benchmark, while consuming 37 less actuation energy. Our approach combines generative methods with active flow control, marking a paradigm shift towards controlling complex physical systems efficiently.
引用
@article{arxiv.2605.14022,
title = {Policy-DRIFT: Dynamic Reward-Informed Flow Trajectory Steering},
author = {Atharva Mahajan and Abhijeet Vishwasrao and Yuning Wang and Ricardo Vinuesa},
journal= {arXiv preprint arXiv:2605.14022},
year = {2026}
}