Neural Implicit Action Fields: From Discrete Waypoints to Continuous Functions for Vision-Language-Action Models
Abstract
Despite the rapid progress of vision-language-action (VLA) models, the prevailing practice of predicting action chunks as discrete waypoints remains structurally misaligned with the intrinsic continuity of physical motion. This discretization arises naturally from fixed-rate robot data collection and the token-by-token prediction paradigm of large language models, but ties actions to rigid sampling rates, does not naturally support analytically consistent higher-order derivatives, and introduces quantization artifacts that hinder precise, compliant interaction. We propose Neural Implicit Action Fields (NIAF), which reformulates chunk-level action representation from discrete waypoints to continuous action functions. Using a vision-language model as a hierarchical spectral modulator over a learnable motion prior, NIAF synthesizes continuous-time action manifolds with arbitrary temporal resolution. This formulation enables analytical differentiation, allowing explicit supervision of velocity and regularization of higher-order derivative signals to promote mathematical consistency, physical plausibility, and control smoothness. Our approach achieves strong results on CALVIN and LIBERO across diverse backbones. Real-world experiments further confirm that NIAF supports stable impedance control, bridging policy-side action generation and execution-side smooth control.
Cite
@article{arxiv.2603.01766,
title = {Neural Implicit Action Fields: From Discrete Waypoints to Continuous Functions for Vision-Language-Action Models},
author = {Haoyun Liu and Jianzhuang Zhao and Xinyuan Chang and Tianle Shi and Chuanzhang Meng and Jiayuan Tan and Feng Xiong and Tong Lin and Dongjie Huo and Mu Xu and SongLin Dong and Zhiheng Ma and Yihong Gong and Sheng Zhong},
journal= {arXiv preprint arXiv:2603.01766},
year = {2026}
}
Comments
Accepted at ICML 2026