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Research PaperResearchia:202607.17004

MeanFlowNFT: Bringing Forward-Process RL to Average-Velocity Generators

Yushi Huang

Abstract

MeanFlow generators achieve fast few-step sampling by predicting average velocities over time intervals, making them attractive for efficient generation. Reinforcement learning (RL) has become a powerful way to align diffusion and flow models with human preferences and task-specific objectives. In particular, DiffusionNFT offers an efficient forward-process RL framework that does not require reverse-process trajectories or likelihood estimation. However, applying such RL methods to MeanFlow rema...

Submitted: July 17, 2026Subjects: Machine Learning; Data Science

Description / Details

MeanFlow generators achieve fast few-step sampling by predicting average velocities over time intervals, making them attractive for efficient generation. Reinforcement learning (RL) has become a powerful way to align diffusion and flow models with human preferences and task-specific objectives. In particular, DiffusionNFT offers an efficient forward-process RL framework that does not require reverse-process trajectories or likelihood estimation. However, applying such RL methods to MeanFlow remains underexplored. DiffusionNFT optimizes instantaneous velocities, whereas MeanFlow samples with average velocities. To bridge this gap, we introduce MeanFlowNFT. Inspired by the MeanFlow identity, which bridges average and instantaneous velocities, we construct an induced instantaneous-velocity predictor. We apply the DiffusionNFT objective to this predictor, making reward optimization well-defined for MeanFlow. Sampling remains based on the average velocity, preserving MeanFlow's fast few-step generation. We further prove that MeanFlowNFT inherits DiffusionNFT's strict policy-improvement guarantee. Experiments on image and video generation show that MeanFlowNFT consistently improves baselines. Moreover, it outperforms prior state-of-the-art RL-tuned few-step generators on most metrics (66 of 88 on SD3.5-M), and can even surpass multi-step RL-tuned diffusion while using only a few sampling steps. For instance, on Wan 2.1, 44-step MeanFlowNFT reaches a VBench score of 84.3384.33, surpassing 5050-step LongCat-Video RL (82.5782.57).


Source: arXiv:2607.15273v1 - http://arxiv.org/abs/2607.15273v1 PDF: https://arxiv.org/pdf/2607.15273v1 Original Link: http://arxiv.org/abs/2607.15273v1

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Date:
Jul 17, 2026
Topic:
Data Science
Area:
Machine Learning
Comments:
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