Indoor poultry farms require inspection robots to maintain precise environmental control, which is crucial for preventing the rapid spread of disease and large-scale bird mortality. However, the complex conditions within these facilities, characterized by areas of intense illumination and water accumulation, pose significant challenges. Traditional navigation methods that rely on a single sensor often perform poorly in such environments, resulting in issues like laser drift and inaccuracies in visual navigation line extraction. To overcome these limitations, we propose a novel composite navigation method that integrates both laser and vision technologies. This approach dynamically computes a fused yaw angle based on the real-time reliability of each sensor modality, thereby eliminating the need for physical navigation lines. Experimental validation in actual poultry house environments demonstrates that our method not only resolves the inherent drawbacks of single-sensor systems, but also significantly enhances navigation precision and operational efficiency. As such, it presents a promising solution for improving the performance of inspection robots in complex indoor poultry farming settings.
View on arXiv@article{lu2025_2504.08431,
title={ The Composite Visual-Laser Navigation Method Applied in Indoor Poultry Farming Environments },
author={ Jiafan Lu and Dongcheng Hu and Yitian Ye and Anqi Liu and Zixian Zhang and Xin Peng },
journal={arXiv preprint arXiv:2504.08431},
year={ 2025 }
}