English

Hydra-Nav: Object Navigation via Adaptive Dual-Process Reasoning

Robotics 2026-02-11 v1

Abstract

While large vision-language models (VLMs) show promise for object goal navigation, current methods still struggle with low success rates and inefficient localization of unseen objects--failures primarily attributed to weak temporal-spatial reasoning. Meanwhile, recent attempts to inject reasoning into VLM-based agents improve success rates but incur substantial computational overhead. To address both the ineffectiveness and inefficiency of existing approaches, we introduce Hydra-Nav, a unified VLM architecture that adaptively switches between a deliberative slow system for analyzing exploration history and formulating high-level plans, and a reactive fast system for efficient execution. We train Hydra-Nav through a three-stage curriculum: (i) spatial-action alignment to strengthen trajectory planning, (ii) memory-reasoning integration to enhance temporal-spatial reasoning over long-horizon exploration, and (iii) iterative rejection fine-tuning to enable selective reasoning at critical decision points. Extensive experiments demonstrate that Hydra-Nav achieves state-of-the-art performance on the HM3D, MP3D, and OVON benchmarks, outperforming the second-best methods by 11.1%, 17.4%, and 21.2%, respectively. Furthermore, we introduce SOT (Success weighted by Operation Time), a new metric to measure search efficiency across VLMs with varying reasoning intensity. Results show that adaptive reasoning significantly enhances search efficiency over fixed-frequency baselines.

Keywords

Cite

@article{arxiv.2602.09972,
  title  = {Hydra-Nav: Object Navigation via Adaptive Dual-Process Reasoning},
  author = {Zixuan Wang and Huang Fang and Shaoan Wang and Yuanfei Luo and Heng Dong and Wei Li and Yiming Gan},
  journal= {arXiv preprint arXiv:2602.09972},
  year   = {2026}
}
R2 v1 2026-07-01T10:30:01.707Z