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Spherical Latent Motion Prior for Physics-Based Simulated Humanoid Control

Robotics 2026-03-03 v1

Abstract

Learning motion priors for physics-based humanoid control is an active research topic. Existing approaches mainly include variational autoencoders (VAE) and adversarial motion priors (AMP). VAE introduces information loss, and random latent sampling may sometimes produce invalid behaviors. AMP suffers from mode collapse and struggles to capture diverse motion skills. We present the Spherical Latent Motion Prior (SLMP), a two-stage method for learning motion priors. In the first stage, we train a high-quality motion tracking controller. In the second stage, we distill the tracking controller into a spherical latent space. A combination of distillation, a discriminator, and a discriminator-guided local semantic consistency constraint shapes a structured latent action space, allowing stable random sampling without information loss. To evaluate SLMP, we collect a two-hour human combat motion capture dataset and show that SLMP preserves fine motion detail without information loss, and random sampling yields semantically valid and stable behaviors. When applied to a two-agent physics-based combat task, SLMP produces human-like and physically plausible combat behaviors only using simple rule-based rewards. Furthermore, SLMP generalizes across different humanoid robot morphologies, demonstrating its transferability beyond a single simulated avatar.

Keywords

Cite

@article{arxiv.2603.01294,
  title  = {Spherical Latent Motion Prior for Physics-Based Simulated Humanoid Control},
  author = {Jing Tan and Weisheng Xu and Xiangrui Jiang and Jiaxi Zhang and Kun Yang and Kai Wu and Jiaqi Xiong and Shiting Chen and Yangfan Li and Yixiao Feng and Yuetong Fang and Yujia Zou and Yiqun Song and Renjing Xu},
  journal= {arXiv preprint arXiv:2603.01294},
  year   = {2026}
}
R2 v1 2026-07-01T10:58:16.708Z