Persistent clocks for batteryless sensing devices

Josiah Hester; Nicole Tobias; Amir Rahmati; Lanny Sitanayah; Daniel Holcomb; Kevin Fu; Wayne P. Burleson; Jacob Sorber

doi:10.1145/2903140

Persistent clocks for batteryless sensing devices

Josiah Hester
, Nicole Tobias
, Amir Rahmati
, Lanny Sitanayah
, Daniel Holcomb
, Kevin Fu
, Wayne P. Burleson
, Jacob Sorber

Computer Science

Clemson University
University of Massachusetts
University of Michigan, Ann Arbor

Research output: Contribution to journal › Article › peer-review

70 Scopus citations

Abstract

Sensing platforms are becoming batteryless to enable the vision of the Internet of Things, where trillions of devices collect data, interact with each other, and interact with people. However, these batteryless sensing platforms-that rely purely on energy harvesting-are rarely able to maintain a sense of time after a power failure. Thismakes working with sensor data that is time sensitive especially difficult.We propose two novel, zero-power timekeepers that use remanence decay to measure the time elapsed between power failures. Our approaches compute the elapsed time from the amount of decay of a capacitive device, either on-chip Static Random-Access Memory (SRAM) or a dedicated capacitor. This enables hourglass-like timers that give intermittently powered sensing devices a persistent sense of time. Our evaluation shows that applications using either timekeeper can keep time accurately through power failures as long as 45s with low overhead.

Original language	English
Article number	77
Journal	ACM Transactions on Embedded Computing Systems
Volume	15
Issue number	4
DOIs	https://doi.org/10.1145/2903140
State	Published - 2016

Keywords

Batteryless
CRFID
Clocks
RTC
Remanence timekeepers
SRAM

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10.1145/2903140

Cite this

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title = "Persistent clocks for batteryless sensing devices",

abstract = "Sensing platforms are becoming batteryless to enable the vision of the Internet of Things, where trillions of devices collect data, interact with each other, and interact with people. However, these batteryless sensing platforms-that rely purely on energy harvesting-are rarely able to maintain a sense of time after a power failure. Thismakes working with sensor data that is time sensitive especially difficult.We propose two novel, zero-power timekeepers that use remanence decay to measure the time elapsed between power failures. Our approaches compute the elapsed time from the amount of decay of a capacitive device, either on-chip Static Random-Access Memory (SRAM) or a dedicated capacitor. This enables hourglass-like timers that give intermittently powered sensing devices a persistent sense of time. Our evaluation shows that applications using either timekeeper can keep time accurately through power failures as long as 45s with low overhead.",

keywords = "Batteryless, CRFID, Clocks, RTC, Remanence timekeepers, SRAM",

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AU - Hester, Josiah

AU - Tobias, Nicole

AU - Rahmati, Amir

AU - Sitanayah, Lanny

AU - Holcomb, Daniel

AU - Fu, Kevin

AU - Burleson, Wayne P.

AU - Sorber, Jacob

PY - 2016

Y1 - 2016

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AB - Sensing platforms are becoming batteryless to enable the vision of the Internet of Things, where trillions of devices collect data, interact with each other, and interact with people. However, these batteryless sensing platforms-that rely purely on energy harvesting-are rarely able to maintain a sense of time after a power failure. Thismakes working with sensor data that is time sensitive especially difficult.We propose two novel, zero-power timekeepers that use remanence decay to measure the time elapsed between power failures. Our approaches compute the elapsed time from the amount of decay of a capacitive device, either on-chip Static Random-Access Memory (SRAM) or a dedicated capacitor. This enables hourglass-like timers that give intermittently powered sensing devices a persistent sense of time. Our evaluation shows that applications using either timekeeper can keep time accurately through power failures as long as 45s with low overhead.

KW - Batteryless

KW - CRFID

KW - Clocks

KW - RTC

KW - Remanence timekeepers

KW - SRAM

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U2 - 10.1145/2903140

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JO - ACM Transactions on Embedded Computing Systems

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Persistent clocks for batteryless sensing devices

Abstract

Keywords

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