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Platypus - Indoor localization and identification through sensing electric potential changes in human bodies

 
: Große-Puppendahl, Tobias; Dellangnol, Xavier; Hatzfeld, Christian; Fu, Biying; Kupnik, Mario; Kuijper, Arjan; Hastall, Matthias R.; Scott, James; Gruteser, Marco

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Association for Computing Machinery -ACM-:
MobiSys 2016, 14th Annual International Conference on Mobile Systems, Applications, and Services. Proceedings : June 25-30, 2016, Singapore
New York: ACM, 2016
ISBN: 978-1-4503-4269-8
pp.17-30
International Conference on Mobile Systems, Applications, and Services (MobiSys) <14, 2016, Singapore>
English
Conference Paper
Fraunhofer IGD ()
capacitive sensor; indoor localization systems; human action recognition; Feature Classification; Guiding Theme: Smart City; Research Area: Human computer interaction (HCI); Research Area: Modeling (MOD)

Abstract
Platypus is the first system to localize and identify people by remotely and passively sensing changes in their body electric potential which occur naturally during walking. While it uses three or more electric potential sensors with a maximum range of 2 m, as a tag-free system it does not require the user to carry any special hardware. We describe the physical principles behind body electric potential changes, and a predictive mathematical model of how this affects a passive electric field sensor. By inverting this model and combining data from sensors, we infer a method for localizing people and experimentally demonstrate a median localization error of 0.16 m. We also use the model to remotely infer the change in body electric potential with a mean error of 8.8 % compared to direct contact-based measurements. We show how the reconstructed body electric potential differs from person to person and thereby how to perform identification. Based on short walking sequences of 5 s, we identify four users with an accuracy of 94 %, and 30 users with an accuracy of 75 %. We demonstrate that identification features are valid over multiple days, though change with footwear.

: http://publica.fraunhofer.de/documents/N-422277.html