Abstract
This paper considers a single-hop wireless sensor network where a fusion center collects data from M energy harvesting wireless sensors. The harvested energy is stored losslessly in an infinite-capacity battery at each sensor. In each time slot, the fusion center schedules K sensors for data transmission over K orthogonal channels. The fusion center does not have direct knowledge on the battery states of sensors, or the statistics of their energy harvesting processes. The fusion center only has information of the outcomes of previous transmission attempts. It is assumed that the sensors are data backlogged, there is no battery leakage and the communication is error-free. An energy harvesting sensor can transmit data to the fusion center whenever being scheduled only if it has enough energy for data transmission. We investigate average throughput of Round-Robin type myopic policy both analytically and numerically under an average reward (throughput) criterion. We show that Round-Robin type myopic policy achieves optimality for some class of energy harvesting processes although it is suboptimal for a broad class of energy harvesting processes.
Highlights
IntroductionThe devices in an Internet of Things (IoT) structure are typically equipped with wireless sensors [2]
We show that Round-Robin type myopic policy achieves optimality for some class of energy harvesting processes it is suboptimal for a broad class of energy harvesting processes
Efficiency of the myopic policy (MP) is evaluated for the cases of infinite battery and finite battery with B = 50 (B = 50 implies that the battery of a sensor can store energy enough to send 50 data packets since we assume that each data packet transmission requires one unit of energy) at the time horizons varying from 0 to 2000 time slot (TS) via simulations
Summary
The devices in an IoT structure are typically equipped with wireless sensors [2]. Networks (WSNs) provide the opportunity of efficient data collection and transmission anywhere [3]. Energy harvesting (EH) [16] can facilitate WSN applications where replacing battery is not practical. Energy harvesting is a promising approach for the emerging IoT technology [17]. Energy may be harvested from the environment in several different ways (solar, piezoelectric, wind, etc.) [17]. As energy harvesters generally depend on uncontrollable energy resources and the amount of harvested energy is generally low [17,18], WSNs need robust, self-adaptive, energy efficient policies to optimize their reliable operation lifetime [19,20]
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