2 research outputs found
Loosely Coupled Odometry, UWB Ranging, and Cooperative Spatial Detection for Relative Monte-Carlo Multi-Robot Localization
As mobile robots become more ubiquitous, their deployments grow across use
cases where GNSS positioning is either unavailable or unreliable. This has led
to increased interest in multi-modal relative localization methods.
Complementing onboard odometry, ranging allows for relative state estimation,
with ultra-wideband (UWB) ranging having gained widespread recognition due to
its low cost and centimeter-level out-of-box accuracy. Infrastructure-free
localization methods allow for more dynamic, ad-hoc, and flexible deployments,
yet they have received less attention from the research community. In this
work, we propose a cooperative relative multi-robot localization where we
leverage inter-robot ranging and simultaneous spatial detections of objects in
the environment. To achieve this, we equip robots with a single UWB transceiver
and a stereo camera. We propose a novel Monte-Carlo approach to estimate
relative states by either employing only UWB ranges or dynamically integrating
simultaneous spatial detections from the stereo cameras. We also address the
challenges for UWB ranging error mitigation, especially in non-line-of-sight,
with a study on different LSTM networks to estimate the ranging error. The
proposed approach has multiple benefits. First, we show that a single range is
enough to estimate the accurate relative states of two robots when fusing
odometry measurements. Second, our experiments also demonstrate that our
approach surpasses traditional methods such as multilateration in terms of
accuracy. Third, to increase accuracy even further, we allow for the
integration of cooperative spatial detections. Finally, we show how ROS 2 and
Zenoh can be integrated to build a scalable wireless communication solution for
multi-robot systems. The experimental validation includes real-time deployment
and autonomous navigation based on the relative positioning method