Energy-Aware Approaches for Energy Harvesting Powered Wireless Sensor Nodes

Intensive research on energy harvesting powered wireless sensor nodes (WSNs) has been driven by the needs of reducing the power consumption by the WSNs and increasing the power generated by energy harvesters. The mismatch between the energy generated by the harvesters and the energy demanded by the...

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Bibliographic Details
Published inIEEE sensors journal Vol. 17; no. 7; pp. 2165 - 2173
Main Authors Ruan, Tingwen, Chew, Zheng Jun, Zhu, Meiling
Format Journal Article
LanguageEnglish
Published New York IEEE 01.04.2017
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Capacitors
Energy
Energy flow
Energy harvesting
Energy management
Energy storage
energy-aware interface
energy-aware program
Nodes
Piezoelectricity
Power consumption
Power demand
Sensors
Threshold voltage
Vibration measurement
Wings (aircraft)
Wireless communication
Wireless sensor networks
wireless sensor nodes
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Summary:Intensive research on energy harvesting powered wireless sensor nodes (WSNs) has been driven by the needs of reducing the power consumption by the WSNs and increasing the power generated by energy harvesters. The mismatch between the energy generated by the harvesters and the energy demanded by the WSNs is always a bottleneck as the ambient environmental energy is limited and time varying. This paper introduces a combined energy-aware interface with an energy-aware program to deal with the mismatch through managing the energy flow from the energy storage capacitor to the WSNs. These two energy-aware approaches were implemented in a custom developed vibration energy harvesting powered WSN. The experimental results show that, with the 3.2-mW power generated by a piezoelectric energy harvester under an emulated aircraft wing strain loading of 600 με at 10 Hz, the combined energy-aware approaches enable the WSN to have a significantly reduced sleep current from 28.3 μA of a commercial WSN to 0.95 μA and enable the WSN operations for a long active time of about 1.15 s in every 7.79 s to sample and transmit a large number of data (388 B), rather than a few ten milliseconds and a few bytes, as demanded by vibration measurement. When the approach was not used, the same amount of energy harvested was not able to power the WSN to start, not mentioning to enabling the WSN operation, which highlighted the importance and the value of the energy-aware approaches in enabling energy harvesting powered WSN operation successfully.
ISSN:1530-437X
1558-1748
DOI:10.1109/JSEN.2017.2665680