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http://dx.doi.org/10.3837/tiis.2015.09.009

Non-cooperative interference radio localization with binary proximity sensors  

Wu, Qihui (College of Communications Engineering, PLA University of Science and Technology)
Yue, Liang (College of Communications Engineering, PLA University of Science and Technology)
Wang, Long (College of Communications Engineering, PLA University of Science and Technology)
Ding, Guoru (College of Communications Engineering, PLA University of Science and Technology)
Publication Information
KSII Transactions on Internet and Information Systems (TIIS) / v.9, no.9, 2015 , pp. 3432-3448 More about this Journal
Abstract
Interference can cause serious problems in our daily life. Traditional ways in localizing a target can't work well when it comes to the source of interference for it may take an uncooperative or even resistant attitude towards localization. To tackle this issue, we take the BPSN (Binary Proximity Sensor Networks) and consider a passive way in this paper. No cooperation is needed and it is based on simple sensor node suitable for large-scale deployment. By dividing the sensing field into different patches, when enough patches are formed, good localization accuracy can be achieved with high resolution. Then we analyze the relationship between sensing radius and localization error, we find that in a finite region where edge effect can't be ignored, the trend between sensing radius and localization error is not always consistent. Through theoretical analysis and simulation, we explore to determine the best sensing radius to achieve high localization accuracy.
Keywords
Interference; localization; binary sensor network; sensing radius; patch;
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