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Auto-Rubric: Learning From Implicit Weights to Explicit Rubrics for Reward Modeling

Machine Learning 2026-02-06 v2 Artificial Intelligence

Abstract

Conventional reward modeling relies on gradient descent over neural weights, creating opaque, data-hungry "black boxes." We propose a paradigm shift from implicit to explicit reward parameterization, recasting optimization from continuous weight spaces to the discrete space of natural language rubrics. We introduce a training-free framework based on iterative rubric learning: it locally induces discriminative criteria via verification-driven refinement, and globally compresses the candidate criteria pool into a compact core set by maximizing an information-theoretic coding rate objective. We organize the compressed core set into a hierarchical rubric structure -- high-level evaluation dimensions supported by concrete verification checks -- serving as an interpretable, portable reward function. Empirically, our approach challenges prevailing data scaling assumptions: using only 70 preference pairs, our rubric-guided judges outperform fully trained reward models on diverse benchmarks. For instance, Qwen3-8B equipped with our learned rubrics achieves 80.91% on RewardBench2, surpassing the specialized Skywork-Reward-V2-Qwen3-8B (78.20%). These results demonstrate that alignment signals are highly compressible and can be effectively captured through explicit symbolic search.

Keywords

Cite

@article{arxiv.2510.17314,
  title  = {Auto-Rubric: Learning From Implicit Weights to Explicit Rubrics for Reward Modeling},
  author = {Lipeng Xie and Sen Huang and Zhuo Zhang and Anni Zou and Yunpeng Zhai and Dingchao Ren and Kezun Zhang and Haoyuan Hu and Boyin Liu and Haoran Chen and Zhaoyang Liu and Bolin Ding},
  journal= {arXiv preprint arXiv:2510.17314},
  year   = {2026}
}
R2 v1 2026-07-01T06:47:07.310Z