9th International Conference on Pervasive Computing Technologies for Healthcare

Research Article

Inductive Power Transfer for On-body Sensors. Defining a design space for safe, wirelessly powered on-body health sensors.

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  • @INPROCEEDINGS{10.4108/icst.pervasivehealth.2015.259139,
        author={Paul Worgan and Lindsay Clare and Plamen Proynov and Bernard Stark and David Coyle},
        title={Inductive Power Transfer for On-body Sensors. Defining a design space for safe, wirelessly powered on-body health sensors. },
        proceedings={9th International Conference on Pervasive Computing Technologies for Healthcare},
        publisher={IEEE},
        proceedings_a={PERVASIVEHEALTH},
        year={2015},
        month={8},
        keywords={on-body sensing inductive power wireless power transfer healthcare safety compliance},
        doi={10.4108/icst.pervasivehealth.2015.259139}
    }
    
  • Paul Worgan
    Lindsay Clare
    Plamen Proynov
    Bernard Stark
    David Coyle
    Year: 2015
    Inductive Power Transfer for On-body Sensors. Defining a design space for safe, wirelessly powered on-body health sensors.
    PERVASIVEHEALTH
    ICST
    DOI: 10.4108/icst.pervasivehealth.2015.259139
Paul Worgan1,*, Lindsay Clare1, Plamen Proynov1, Bernard Stark1, David Coyle1
  • 1: University of Bristol
*Contact email: p.worgan@bristol.ac.uk

Abstract

Designers of on-body health sensing devices face a difficult choice. They must either minimise the power consumption of devices, which in reality means reducing the sensing capabilities, or build devices that require regular battery changes or recharging. Both options limit the effectiveness of devices. Here we investigate an alternative. This paper presents a method of designing safe, wireless, inductive power transfer into on-body sensor products. This approach can produce sensing devices that can be worn for longer durations without the need for human intervention, whilst also having greater sensing and data capture capabilities. The paper addresses significant challenges in achieving this aim, in particular: device safety, sufficient power transfer, and human factors regarding device geometry. We show how to develop a device that meets stringent international safety guidelines for electromagnetic energy on the body and describe a design space that allows designers to make trade-offs that balance power transfer with other constraints, e.g. size and bulk, that affect the wearability of devices. Finally we describe a rapid experimental method to investigate the optimal placement of on-body devices and the actual versus theoretical power transfer for on-body, inductively powered devices.