Integration of UWB Radar on Mobile Robots for Continuous Obstacle and Environment Mapping

TL;DR

This paper demonstrates a UWB radar-based obstacle detection and environmental mapping method for mobile robots that functions effectively in poor visibility conditions without relying on visual sensors or fixed anchors.

Contribution

It introduces a novel processing pipeline for UWB radar data that enhances obstacle detection and mapping in unknown environments without fixed anchor nodes.

Findings

Achieves 73.42% precision and 83.38% recall in low-reflectivity scenarios

Reduces noise and multipath effects in UWB radar data

Effective obstacle detection across various materials

Abstract

This paper presents an infrastructure-free approach for obstacle detection and environmental mapping using ultra-wideband (UWB) radar mounted on a mobile robotic platform. Traditional sensing modalities such as visual cameras and Light Detection and Ranging (LiDAR) fail in environments with poor visibility due to darkness, smoke, or reflective surfaces. In these vision-impaired conditions, UWB radar offers a promising alternative. To this end, this work explores the suitability of robot-mounted UWB radar for environmental mapping in anchor-free, unknown scenarios. The study investigates how different materials (metal, concrete and plywood) and UWB radio channels (5 and 9) influence the Channel Impulse Response (CIR). Furthermore, a processing pipeline is proposed to achieve reliable mapping of detected obstacles, consisting of 3 steps: 1) target identification (based on CIR peak detection); 2) filtering (based on peak properties, signal-to-noise score, and phase-difference of arrival); and 3) clustering (based on distance estimation and angle-of-arrival estimation). The proposed approach successfully reduces noise and multipath effects, achieving high obstacle detection performance across a range of materials. Even in challenging low-reflectivity scenarios such as concrete, the method achieves a precision of 73.42% and a recall of 83.38% on channel 9. This work offers a foundation for further development of UWB-based localisation and mapping (SLAM) systems that do not rely on visual features and, unlike conventional UWB localisation systems, do not require fixed anchor nodes for triangulation.