Paper Detail

Enhanced LLM Reasoning by Optimizing Reward Functions with Search-Driven Reinforcement Learning

Arash Ahmadi, Sarah Sharif, Yaser, Banad

Browse

Workflow Queues

arxiv Score 18.2

Published 2026-05-03 · First seen 2026-05-05

General AI

Open paper source

Abstract

Mathematical reasoning is a key benchmark for large language models. Reinforcement learning is a standard post-training mechanism for improving the reasoning capabilities of large language models, yet performance remains sensitive to the design of the reward function that drives policy optimization. This paper introduces a search-driven framework that treats the reward specification itself as an object of optimization. The setting of interest is one in which the base model is held fixed and the reward specification is the primary remaining design lever. Candidate reward functions are generated by a frontier language model, validated automatically, screened through 500-step Group Relative Policy Optimization (GRPO) training runs on a Llama-3.2-3B-Instruct base model with Low-Rank Adaptation (LoRA), and ranked by F1 on the GSM8K test set. Ranked summaries from prior rounds are then fed back into the next round of generation. Over five rounds, the search produces 50 candidate rewards. The mean F1 rises from 0.596 in Round 1 to 0.632 in Round 5, and the top individual reward reaches F1 = 0.787. Seven ensemble configurations of top-ranked rewards are evaluated. The best ensemble achieves F1 = 0.795 (95% bootstrap CI [0.756, 0.832]) and accuracy 0.660 [0.635, 0.686], a 0.19 absolute F1 gain over a base-rewards-only GRPO baseline (F1 = 0.609). Pairwise McNemar tests with Bonferroni correction show all five-or-more-reward configurations are statistically indistinguishable at α = 0.05/21. A three-seed re-training of the best ensemble yields F1 of 0.785. A randomly drawn 5-reward control collapses to F1 = 0.047, which shows that the ranked-feedback loop, not the additive signal of having more rewards, drives the gain.

Workflow Status

Review status
pending
Role
unreviewed
Read priority
now
Vote
Not set.
Saved
no
Collections
Not filed yet.
Next action
Not filled yet.

Reading Brief

No structured notes yet. Add `summary_sections`, `why_relevant`, `claim_impact`, or `next_action` in `papers.jsonl` to enrich this view.

Why It Surfaced

No ranking explanation is available yet.

Tags

No tags.

Similar Papers

KnowRL: Boosting LLM Reasoning via Reinforcement Learning with Minimal-Sufficient Knowledge Guidance 2026-04-14 · Score 15.5 General AI Optimizing LLM Prompt Engineering with DSPy Based Declarative Learning 2026-04-06 · Score 19.8 General AI Chart-RL: Policy Optimization Reinforcement Learning for Enhanced Visual Reasoning in Chart Question Answering with Vision Language Models 2026-04-03 · Score 10.8 General AI SOLE-R1: Video-Language Reasoning as the Sole Reward for On-Robot Reinforcement Learning 2026-03-30 · Score 11.8 General AI Autonomous Diffractometry Enabled by Visual Reinforcement Learning 2026-04-13 · Score 9.3 General AI

BibTeX

@article{ahmadi2026enhanced,
  title = {Enhanced LLM Reasoning by Optimizing Reward Functions with Search-Driven Reinforcement Learning},
  author = {Arash Ahmadi and Sarah Sharif and Yaser and Banad},
  year = {2026},
  abstract = {Mathematical reasoning is a key benchmark for large language models. Reinforcement learning is a standard post-training mechanism for improving the reasoning capabilities of large language models, yet performance remains sensitive to the design of the reward function that drives policy optimization. This paper introduces a search-driven framework that treats the reward specification itself as an object of optimization. The setting of interest is one in which the base model is held fixed and the },
  url = {https://arxiv.org/abs/2605.02073},
  keywords = {cs.CL},
  eprint = {2605.02073},
  archiveprefix = {arXiv},
}

Metadata

{}