Beyond the Dirac Delta: Mitigating Diversity Collapse in Reinforcement Fine-Tuning for Versatile Image Generation

Abstract

Reinforcement learning (RL) has emerged as a powerful paradigm for fine-tuning large-scale generative models, such as diffusion and flow models, to align with complex human preferences and user-specified tasks. A fundamental limitation remains the curse of diversity collapse, where the objective formulation and optimization landscape inherently collapse the policy to a Dirac delta distribution. To address this challenge, we propose DRIFT (DiveRsity-Incentivized Reinforcement Fine-Tuning for Versatile Image Generation), an innovative framework that systematically incentivizes output diversity throughout the on-policy fine-tuning process, reconciling strong task alignment with high generation diversity to enhance versatility essential for applications that demand diverse candidate generations. We approach the problem across three representative perspectives: i) sampling a reward-concentrated subset that filters out reward outliers to prevent premature collapse; ii) prompting with stochastic variations to expand the conditioning space, and iii) optimization of the intra-group diversity with a potential-based reward shaping mechanism. Experimental results show that DRIFT achieves superior Pareto dominance regarding task alignment and generation diversity, yielding a 9.08\%\!\! 43.46\% increase in diversity at equivalent alignment levels and a 59.65\% \!\! 65.86\% increase in alignment at equivalent levels of diversity.