Paper
Automated Testbed for Repeatable Evaluation of Ultra-Wideband Localization Performance
Authors
Alexander Kemptner, Julian Karoliny, Hannah Brunner, Andreas Gaich, Michael Neubauer, Fjolla Ademaj-Berisha, Filippo Casamassima, Walther Pachler, Shrief Rizkalla, Harald Witschnig, Andreas Springer, Hans-Peter Bernhard
Abstract
Testing Ultra-Wideband (UWB) systems is challenging, as multiple devices need to coordinate over lossy links and the systems' behavior is influenced by timing, synchronization, and environmental factors. Traditional testing is often insufficient to capture these complex interactions, highlighting the need for an overarching testbed infrastructure that can manage devices, control the environment, and make measurements and test scenarios repeatable. In this work, we present a highly automated testbed architecture built on Robot Operating System Version 2, integrating device management with environmental control and measurement systems. It includes an optical reference system, a controllable Autonomous Guided Vehicle to position devices within the environment, and time synchronization via Network Time Protocol (NTP). The testbed achieves a Root Mean Squared Error of 4.8 mm for positioning repeatability and 0.493$°$ for the orientation, and our NTP-based synchronization approach achieves a timing accuracy of below 1 ms. All testbed functionality can be controlled remotely through simple Python scripts to allow automated orchestration tasks such as conducting complex measurement scenarios. We demonstrate this with a measurement campaign on UWB localization, showing how it enables repeatable, observable, and fully controlled wireless experiments.
Metadata
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Raw Data (Debug)
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