We present Move-Then-Operate, a Vision language action framework that explicitly decouples robotic manipulation into two distinct behavioral phases: coarse relocation (move) and contact-critical interaction (operate). Unlike monolithic policies that conflate these heterogeneous regimes, our architecture employs a dual-expert policy routed by a learnable phase selector, introducing a structural inductive bias that isolates phase-specific dynamics. Phase labels are automatically generated via an MLLM-based pipeline conditioned on lightweight contextual cues such as end-effector velocity and subtask decomposition to ensure alignment with human motor patterns. Evaluated on the RoboTwin2 benchmark, our method achieves an average success rate of 68.9%, outperforming the monolithic π0 baseline by 24%. It matches or exceeds models trained on 10× more data and reaches peak performance in 40% fewer training steps, demonstrating that architectural disentanglement of move and operate phases is a highly effective and efficient strategy for mastering high-precision manipulation.
Cite
@article{arxiv.2604.23620,
title = {Move-Then-Operate: Behavioral Phasing for Human-Like Robotic Manipulation},
author = {Haoming Xu and Lei Lei and Jie Gu and Chu Tang and Jingmin Chen and Ruiqi Wang},
journal= {arXiv preprint arXiv:2604.23620},
year = {2026}
}