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用于为物联网提供差异延迟的自适应信息传播控制

Adaptive Information Dissemination Control to Provide Diffdelay for the Internet of Things.

作者信息

Liu Xiao, Liu Anfeng, Huang Changqin

机构信息

School of Information Science and Engineering, Central South University, Changsha 410083, China.

School of Information Technology in Education, South China Normal University, Guangzhou 510631, China.

出版信息

Sensors (Basel). 2017 Jan 12;17(1):138. doi: 10.3390/s17010138.

DOI:10.3390/s17010138
PMID:28085097
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5298711/
Abstract

Applications running on the Internet of Things, such as the Wireless Sensor and Actuator Networks (WSANs) platform, generally have different quality of service (QoS) requirements. For urgent events, it is crucial that information be reported to the actuator quickly, and the communication cost is the second factor. However, for interesting events, communication costs, network lifetime and time all become important factors. In most situations, these different requirements cannot be satisfied simultaneously. In this paper, an adaptive communication control based on a differentiated delay (ACCDS) scheme is proposed to resolve this conflict. In an ACCDS, source nodes of events adaptively send various searching actuators routings (SARs) based on the degree of sensitivity to delay while maintaining the network lifetime. For a delay-sensitive event, the source node sends a large number of SARs to actuators to identify and inform the actuators in an extremely short time; thus, action can be taken quickly but at higher communication costs. For delay-insensitive events, the source node sends fewer SARs to reduce communication costs and improve network lifetime. Therefore, an ACCDS can meet the QoS requirements of different events using a differentiated delay framework. Theoretical analysis simulation results indicate that an ACCDS provides delay and communication costs and differentiated services; an ACCDS scheme can reduce the network delay by 11.111%-53.684% for a delay-sensitive event and reduce the communication costs by 5%-22.308% for interesting events, and reduce the network lifetime by about 28.713%.

摘要

运行在物联网上的应用程序,如无线传感器和执行器网络(WSANs)平台,通常有不同的服务质量(QoS)要求。对于紧急事件,关键是要迅速将信息报告给执行器,而通信成本是次要因素。然而,对于有趣的事件,通信成本、网络寿命和时间都成为重要因素。在大多数情况下,这些不同的要求无法同时满足。本文提出了一种基于差异化延迟的自适应通信控制(ACCDS)方案来解决这一冲突。在ACCDS中,事件的源节点在保持网络寿命的同时,根据对延迟的敏感程度自适应地发送各种搜索执行器路由(SARs)。对于延迟敏感事件,源节点向执行器发送大量SARs,以便在极短的时间内识别并通知执行器;因此,可以迅速采取行动,但通信成本较高。对于延迟不敏感事件,源节点发送较少的SARs以降低通信成本并提高网络寿命。因此,ACCDS可以使用差异化延迟框架满足不同事件的QoS要求。理论分析仿真结果表明,ACCDS提供了延迟和通信成本以及差异化服务;对于延迟敏感事件,ACCDS方案可以将网络延迟降低11.111%-53.684%,对于有趣事件,可以将通信成本降低5%-22.308%,并使网络寿命降低约28.713%。

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