Gabe Cohn scite author profile

Wearable sensor systems have been used in the ubiquitous computing community and elsewhere for applications such as activity and gesture recognition, health and wellness monitoring, and elder care. Although the power consumption of accelerometers has already been highly optimized, this work introduces a novel sensing approach which lowers the power requirement for motion sensing by orders of magnitude. We present an ultra-low-power method for passively sensing body motion using static electric fields by measuring the voltage at any single location on the body. We present the feasibility of using this sensing approach to infer the amount and type of body motion anywhere on the body and demonstrate an ultra-low-power motion detector used to wake up more power-hungry sensors. The sensing hardware consumes only 3.3 !W, and wake-up detection is done using an additional 3.3 !W (6.6 !W total).

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Finding Common Ground

Große-Puppendahl

Holz

Cohn

et al. 2017

160

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For more than two decades, capacitive sensing has played a prominent role in human-computer interaction research. Capacitive sensing has become ubiquitous on mobile, wearable, and stationary devices-enabling fundamentally new interaction techniques on, above, and around them. The research community has also enabled human position estimation and whole-body gestural interaction in instrumented environments. However, the broad field of capacitive sensing research has become fragmented by different approaches and terminology used across the various domains. This paper strives to unify the field by advocating consistent terminology and proposing a new taxonomy to classify capacitive sensing approaches. Our extensive survey provides an analysis and review of past research and identifies challenges for future work. We aim to create a common understanding within the field of human-computer interaction, for researchers and practitioners alike, and to stimulate and facilitate future research in capacitive sensing.

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GasSense: Appliance-Level, Single-Point Sensing of Gas Activity in the Home

Cohn

Gupta

Froehlich

et al. 2010

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Gabe Cohn

Disaggregated End-Use Energy Sensing for the Smart Grid

An ultra-low-power human body motion sensor using static electric field sensing

Finding Common Ground

GasSense: Appliance-Level, Single-Point Sensing of Gas Activity in the Home

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