A Precise and Scalable Indoor Positioning System Using Cross-Modal Knowledge Distillation

A Precise and Scalable Indoor Positioning System Using Cross-Modal Knowledge Distillation

User location has emerged as a pivotal factor in human-centered environments, driving applications like tracking, navigation, healthcare, and emergency response that align with Sustainable Development Goals (SDGs). However, accurate indoor localization remains challenging due to the limitations of G...

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Bibliographic Details
Main Authors: Hamada Rizk, Ahmed Elmogy, Mohamed Rihan, Hirozumi Yamaguchi
Format: Article
Language:English
Published: MDPI AG 2024-11-01
Series:Sensors
Subjects:
indoor localization
deep learning
fingerprinting
round trip time
knowledge distillation
Online Access:https://www.mdpi.com/1424-8220/24/22/7322
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Summary:User location has emerged as a pivotal factor in human-centered environments, driving applications like tracking, navigation, healthcare, and emergency response that align with Sustainable Development Goals (SDGs). However, accurate indoor localization remains challenging due to the limitations of GPS in indoor settings, where signal interference and reflections disrupt satellite connections. While Received Signal Strength Indicator (RSSI) methods are commonly employed, they are affected by environmental noise, multipath fading, and signal interference. Round-Trip Time (RTT)-based localization techniques provide a more resilient alternative but are not universally supported across access points due to infrastructure limitations. To address these challenges, we introduce <i>DistilLoc</i>: a cross-knowledge distillation framework that transfers knowledge from an RTT-based teacher model to an RSSI-based student model. By applying a teacher–student architecture, where the RTT model (teacher) trains the RSSI model (student), <i>DistilLoc</i> enhances RSSI-based localization with the accuracy and robustness of RTT without requiring RTT data during deployment. At the core of <i>DistilLoc</i>, the FNet architecture is employed for its computational efficiency and capacity to capture complex relationships among RSSI signals from multiple access points. This enables the student model to learn a robust mapping from RSSI measurements to precise location estimates, reducing computational demands while improving scalability. Evaluation in two cluttered indoor environments of varying sizes using Android devices and Google WiFi access points, <i>DistilLoc</i> achieved sub-meter localization accuracy, with median errors of 0.42 m and 0.32 m, respectively, demonstrating improvements of 267% over conventional RSSI methods and 496% over multilateration-based approaches. These results validate <i>DistilLoc</i> as a scalable, accurate solution for indoor localization, enabling intelligent, resource-efficient urban environments that contribute to SDG 9 (Industry, Innovation, and Infrastructure) and SDG 11 (Sustainable Cities and Communities).
ISSN:1424-8220

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