Building on our previous work in 2D node mapping, this paper extends and generalizes the methodology to 3D, enabling the reconstruction of relative spatial configurations using only inter-node distance measurements. This approach leverages minimal ranging information, offering a simple and lightweight calibration tool for localization infrastructures. We formalize the problem, define the theoretical upper bound for the noise-to-distance ratio, and establish the maximum allowable deviation from the motions prescribed by the algorithm. While no real-world experiments are included, simulation results validate the mathematical framework, with prior work confirming the effectiveness of both the concept and the technology through experimental validation.
Santoro, L., Brunelli, D., Fontanelli, D. (2025). Universal Calibration Framework for Localization Infrastructures Using Distance-Only Measurements. Piscataway, NJ, USA : Institute of Electrical and Electronics Engineers Inc. [10.1109/i2mtc62753.2025.11079033].
Universal Calibration Framework for Localization Infrastructures Using Distance-Only Measurements
Brunelli, Davide;
2025
Abstract
Building on our previous work in 2D node mapping, this paper extends and generalizes the methodology to 3D, enabling the reconstruction of relative spatial configurations using only inter-node distance measurements. This approach leverages minimal ranging information, offering a simple and lightweight calibration tool for localization infrastructures. We formalize the problem, define the theoretical upper bound for the noise-to-distance ratio, and establish the maximum allowable deviation from the motions prescribed by the algorithm. While no real-world experiments are included, simulation results validate the mathematical framework, with prior work confirming the effectiveness of both the concept and the technology through experimental validation.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
