Continuous health monitoring is crucial to ensuring better health and taking preventive measures just-in-time. Existing battery-powered health wearables pose a significant limitation to continuous monitoring as batteries wear out after fixed energy cycles and need replacement. Ambient energy harvesting unlocks battery-free sensing but it suffers from spatio-temporal variability, making it unfit for health sensing. Intra-body power transfer (IBPT) provides an alternative energy source for battery-free operation, however, it can only provide limited energy in order to ensure wearer's safety. Existing system support is designed to maximize computational progress in a single energy cycle, thus wasting energy on computations that become stale in the next energy cycle. We instantiate an IBPT-powered health wearable capable of supporting multiple health sensors. To cope with lower incoming energy, we introduce BodyOS; a system support that exposes programming constructs for domain experts to ...
Bootstrapping Health Wearables Powered by Intra-Body Power Transfer / Ahmed, Saad; Yildiz, Eren; Holla, Shashank; Mohammed, Noor; Islam, Bashima; Yildirim, Kasim Sinan; Gummeson, Jeremy; Lee, Sunghoon Ivan; Hester, Josiah. - (2024), pp. 1-4. ( 2024 IEEE 20th International Conference on Body Sensor Networks (BSN) Chicago, IL, USA 15-17 October 2024) [10.1109/bsn63547.2024.10780616].
Bootstrapping Health Wearables Powered by Intra-Body Power Transfer
Yildirim, Kasim Sinan;
2024-01-01
Abstract
Continuous health monitoring is crucial to ensuring better health and taking preventive measures just-in-time. Existing battery-powered health wearables pose a significant limitation to continuous monitoring as batteries wear out after fixed energy cycles and need replacement. Ambient energy harvesting unlocks battery-free sensing but it suffers from spatio-temporal variability, making it unfit for health sensing. Intra-body power transfer (IBPT) provides an alternative energy source for battery-free operation, however, it can only provide limited energy in order to ensure wearer's safety. Existing system support is designed to maximize computational progress in a single energy cycle, thus wasting energy on computations that become stale in the next energy cycle. We instantiate an IBPT-powered health wearable capable of supporting multiple health sensors. To cope with lower incoming energy, we introduce BodyOS; a system support that exposes programming constructs for domain experts to ...I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione
