Abstract

Technological advances have led to the emergence of wireless sensor nodes in wireless networks. Sensor nodes are usually battery powered and hence have strict energy constraints. As a result, energy conservation is very important in the wireless sensor network protocol design and the limited power resources are the biggest challenge in wireless network channels. Link adaptation techniques improve the link quality by adjusting medium access control (MAC) parameters such as frame size, data rate, and sleep time, thereby improving energy efficiency. In this paper we present an adaptive packet size strategy for energy efficient wireless sensor networks. The main goal is to reduce power consumption and extend the whole network life. In order to achieve this goal, the paper introduces the concept of a bounded MAB to find the optimal packet size to transfer by formulating different packet sizes for different arms under the channel condition. At the same time, in achieve fast convergence, we consider the bandwidth evaluation according to ACK. The experiment shows that the packet size is adaptive when the channel quality changes and our algorithm can obtain the optimal packet size. We observe that the MAB packet size adaptation scheme achieves the best energy efficiency across the whole simulation duration in comparison with the fixed frame size scheme, the random packet size and the extended Kalman filter (EKF).

Highlights

  • Sensing, processing and communication are integrated into a tiny wireless sensor network (WSN)device

  • We introduce bandwidth estimation based on ACK interval to evaluate the wireless channel quality and use the multi-armed bandit (MAB) model to find the optimal packet size for data transmissions

  • An adaptive packet size strategy for the energy efficiency of wireless sensor networks is proposed in this paper

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Summary

Introduction

They are used in inaccessible environments and maintenance is typically inconvenient or impossible because wireless sensor networks are robust and distributed. Compared to traditional wired networks, WSNs are relatively simple and inexpensive. Such networks can be extended by adding more devices without reworking and reconfiguring the whole network. The most direct application of sensor networks is in remote environmental monitoring. Considering the cost of sensor nodes (SNs), discarding sensor nodes without electricity is not feasible, and it may be impossible to replace the batteries of SNs. there is a huge demand for an energy conservation scheme to reduce energy consumption and prolong the lifetime of wireless sensor nodes [1,2]

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