BitRL: Reinforcement Learning with 1-bit Quantized Language Models for Resource-Constrained Edge Deployment
Abstract
The deployment of intelligent reinforcement learning (RL) agents on resource-constrained edge devices remains a fundamental challenge due to the substantial memory, computational, and energy requirements of modern deep learning systems. While large language models (LLMs) have emerged as powerful architectures for decision-making agents, their multi-billion parameter scale confines them to cloud-based deployment, raising concerns about latency, privacy, and connectivity dependence. We introduce BitRL, a framework for building RL agents using 1-bit quantized language models that enables practical on-device learning and inference under severe resource constraints. Leveraging the BitNet b1.58 architecture with ternary weights (-1, 0, +1) and an optimized inference stack, BitRL achieves 10-16x memory reduction and 3-5x energy efficiency improvements over full-precision baselines while maintaining 85-98 percent of task performance across benchmarks. We provide theoretical analysis of quantization as structured parameter perturbation, derive convergence bounds for quantized policy gradients under frozen-backbone architectures, and identify the exploration-stability trade-off in extreme quantization. Our framework systematically integrates 1-bit quantized language models with reinforcement learning for edge deployment and demonstrates effectiveness on commodity hardware.
Cite
@article{arxiv.2604.24273,
title = {BitRL: Reinforcement Learning with 1-bit Quantized Language Models for Resource-Constrained Edge Deployment},
author = {Md. Ashiq Ul Islam Sajid and Mohammad Sakib Mahmood and Md. Tareq Hasan and Md Abdur Rahim and Rafat Ara and Md. Arafat Hossain},
journal= {arXiv preprint arXiv:2604.24273},
year = {2026}
}
Comments
6pages, 1 Figure, IEEE International Conference of Frontiers of Engineering and Emerging Technologies 2026