📝 SummarXiv

Abstract

This paper proposes a high-accuracy radio map construction method tailored for environments where location information is affected by bursty errors. Radio maps are an effective tool for visualizing wireless environments. Although extensive research has been conducted on accurate radio map construction, most existing approaches assume noise-free location information during sensing. In practice, however, positioning errors ranging from a few to several tens of meters can arise due to device-based positioning systems (e.g., GNSS). Ignoring such errors during inference can lead to significant degradation in radio map accuracy. This study highlights that these errors often tend to be biased when using mobile devices as sensors. We introduce a novel framework that models these errors together with spatial correlation in radio propagation by embedding them as tunable parameters in the marginal log-likelihood function. This enables ex-post calibration of location uncertainty during radio map construction. Numerical results based on practical human mobility data demonstrate that the proposed method can limit RMSE degradation to approximately 0.25-0.29 dB, compared with Gaussian process regression using noise-free location data, whereas baseline methods suffer performance losses exceeding 1 dB.