WLAN Fingerprinting Indoor Positioning Accuracy: Assessing the Effects of Access Point Power and High Signal Correlation
Nicholaus, M. (2025). WLAN Fingerprinting Indoor Positioning Accuracy: Assessing the Effects of Access Point Power and High Signal Correlation. EKB Journal Management System, 25(3), 1-14. doi: 10.21608/ijicis.2025.348298.1371
Mrindoko Rashid Nicholaus. "WLAN Fingerprinting Indoor Positioning Accuracy: Assessing the Effects of Access Point Power and High Signal Correlation". EKB Journal Management System, 25, 3, 2025, 1-14. doi: 10.21608/ijicis.2025.348298.1371
Nicholaus, M. (2025). 'WLAN Fingerprinting Indoor Positioning Accuracy: Assessing the Effects of Access Point Power and High Signal Correlation', EKB Journal Management System, 25(3), pp. 1-14. doi: 10.21608/ijicis.2025.348298.1371
Nicholaus, M. WLAN Fingerprinting Indoor Positioning Accuracy: Assessing the Effects of Access Point Power and High Signal Correlation. EKB Journal Management System, 2025; 25(3): 1-14. doi: 10.21608/ijicis.2025.348298.1371

WLAN Fingerprinting Indoor Positioning Accuracy: Assessing the Effects of Access Point Power and High Signal Correlation

International Journal of Intelligent Computing and Information Sciences
Volume 25, Issue 3, September 2025, Pages 1-14    PDF (1.1 M)
Document Type: Original Article
DOI: 10.21608/ijicis.2025.348298.1371
Author
Mrindoko Rashid Nicholaus*
Department of Computer Science and Engineering, College of Information and Communication Technology, Mbeya University of Science and Technology, Mbeya, Tanzania
Abstract
Recently, localization systems tailored for indoor environments have been introduced, leveraging the existing wireless local area network (WLAN) infrastructure. These systems utilize position fingerprinting methods rather than direction-based or time-of-arrival approaches to determine the spatial positions of mobile users. Nevertheless, experimental studies on these systems indicate that factors such as signal attenuation and scattering caused by the higher density of walls significantly impact the accuracy and performance of indoor positioning. Furthermore, the accuracy of indoor positioning systems (IPS) may be compromised by variations in environmental factors, including alterations in height, the introduction or removal of a WLAN Access Point (AP), or modifications to AP power settings. This paper analyses the impact of AP power through a probabilistic analytical model that exclusively utilizes high signal relations to mitigate the effects of low signal relations on WLAN fingerprinting-based IPS, thereby enhancing accuracy performance. Through comprehensive experimental evaluations, the proposed algorithm demonstrates an improvement in the accuracy of the IPS by an average of 15.794 % as measured by the Root Mean Square Error (RMSE). The findings suggest that the integration of AP power and high signal relations can substantially enhance the accuracy performance of WLAN fingerprinting-based IPS.
Keywords
Wireless local area network; Indoor positioning system; Access point; Fingerprinting; Probabilistic
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