English

ActQuant: Sub-4-bit Action-Guided Quantization for Vision-Language-Action Models

Computer Vision and Pattern Recognition 2026-05-26 v1 Artificial Intelligence

Abstract

Vision-Language-Action (VLA) models exhibit remarkable action generation for embodied intelligence, but their heavy compute make deployment on edge platforms impractical. Aggressive, sub-4-bit weight quantization is the natural solution, yet existing post-training quantization (PTQ) methods suffer severe performance degradation in this regime. To address this, we introduce ActQuant, an action-guided mixed-precision PTQ framework that operates in two stages: (1) an inter-tensor bit allocator that assigns each weight matrix a single bit-width based on how much it contributes to predicting the agent's actions; (2) an intra-tensor scale optimizer tunes per-block quantization scales using action-aware curvature, so that dynamic range is concentrated on the weights most influential for control. To deliver the on-device benefits of our aggressive quantization, we further introduce OmniModel.cpp, an agentic conversion pipeline that ports architectures into a native C/C++ runtime with efficient low-bit kernels. We evaluate ActQuant both in simulation and on a real-world 6-DoF UR3 arm, with all models deployed through OmniModel.cpp. On the LIBERO benchmark, ActQuant is the only method that operates at or below 3 bits-per-weight, retaining 95.0% on OpenVLA-OFT and 94.8% on π0.5\pi_{0.5}. Pushed further, ActQuant reaches 2.5 bpw at 90.1% on OpenVLA-OFT, compressing the backbone from 14.3 GB to 2.7 GB (5.3×\times). On the physical UR3 arm, π0.5\pi_{0.5} quantized with ActQuant retains the baseline's success rate while reducing the memory footprint by 2.5×\times.

Keywords

Cite

@article{arxiv.2605.24011,
  title  = {ActQuant: Sub-4-bit Action-Guided Quantization for Vision-Language-Action Models},
  author = {Arash Akbari and Arman Akbari and Masih Eskandar and Qitao Tan and Yixiao Chen and Jingwu Luo and Bertha Pangaribuan and Liyun Zhang and Jennifer Dy and Geng Yuan and Xue Lin and Gaowen Liu and Stratis Ioannidis and Yanzhi Wang},
  journal= {arXiv preprint arXiv:2605.24011},
  year   = {2026}
}