Parameterized complexity of coverage in multi-interface IoT networks: Pathwidth

IF 6 3区 计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS Internet of Things Pub Date : 2024-08-28 DOI:10.1016/j.iot.2024.101353
Alessandro Aloisio , Alfredo Navarra
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Abstract

The Internet of Things (IoT) has emerged as one of the growing fields in digital technology over the past decade. A primary goal of IoT is to connect physical objects to the Internet to provide various services. Due to the vast number and diversity of these objects, referred to as devices, IoT must tackle both traditional and novel theoretical and practical network problems. Among these, multi-interface problems are well-known and have been extensively studied.

This research focuses on one of the newest multi-interface models that fits well within the IoT context. It is known as the Coverage in the budget-constrained multi-interface problem, where the budget represents the total amount of energy in the network, and coverage refers to the model’s goal of activating all required communications among IoT devices. Since most IoT devices are battery-powered, energy consumption must be considered to extend the network’s lifespan. This means selecting the most energy-efficient interface configuration that allows all desired connections to function. To achieve this, both global energy consumption and the local number of active interfaces are limited. Moreover, this model also incentivize devices to turn on the available interfaces to create a more performant network. Finally, this model also takes into account the performance of the networks assigning a profit to devices that activate interfaces and realize connections.

This problem can be represented using an undirected graph where each vertex represents a device, and each edge represents a desired connection. Every device is equipped with a set of available interfaces that can be used to facilitate transmission among the devices. The final goal is to activate a subset of the available interfaces that maximize the total profit, while not violating the constraints.

This problem has been recognized as NP-hard, which is why we decided to investigate the decision version from the perspective of fixed-parameter tractability (FPT) theory. FPT is an advanced area of complexity theory that aims to identify the core complexity of a combinatorial problem by incorporating parameters into the time complexity domain.

We provide two fixed-parameter tractability results, each describing an FPT algorithm. One algorithm is based on the well-known pathwidth parameter, the number of available interfaces, and the maximum available energy. The other algorithm considers pathwidth, the number of available interfaces, and an upper bound on the optimal profit. Finally, we show that these two algorithms can be applied to the maximization version of the problem.

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多接口物联网网络覆盖的参数化复杂性:路径宽度
过去十年来,物联网(IoT)已成为数字技术领域不断发展的领域之一。物联网的主要目标是将物理对象连接到互联网,以提供各种服务。由于这些被称为设备的物体数量庞大、种类繁多,物联网必须解决传统和新颖的理论和实际网络问题。在这些问题中,多接口问题是众所周知的,并且已经得到了广泛的研究。本研究的重点是最新的多接口模型之一,它非常适合物联网环境。它被称为预算受限多接口问题中的覆盖率,其中预算代表网络中的能源总量,而覆盖率指的是该模型的目标,即激活物联网设备间所有需要的通信。由于大多数物联网设备都由电池供电,因此必须考虑能耗以延长网络的使用寿命。这意味着要选择最节能的接口配置,使所有需要的连接都能正常运行。为此,必须限制全局能耗和本地活动接口的数量。此外,该模型还鼓励设备打开可用接口,以创建性能更高的网络。最后,该模型还考虑到了网络的性能,为激活接口和实现连接的设备分配了利润。每个设备都配有一组可用接口,可用于促进设备间的传输。最终目标是激活可用接口的一个子集,使总利润最大化,同时不违反约束条件。这个问题已被公认为 NP 难,因此我们决定从固定参数可计算性(FPT)理论的角度来研究决策版本。FPT 是复杂性理论的一个高级领域,旨在通过将参数纳入时间复杂性域来确定组合问题的核心复杂性。其中一种算法基于众所周知的路径宽度参数、可用接口数量和最大可用能量。另一种算法则考虑了路径宽度、可用接口数量和最优利润上限。最后,我们展示了这两种算法可以应用于问题的最大化版本。
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来源期刊
Internet of Things
Internet of Things Multiple-
CiteScore
3.60
自引率
5.10%
发文量
115
审稿时长
37 days
期刊介绍: Internet of Things; Engineering Cyber Physical Human Systems is a comprehensive journal encouraging cross collaboration between researchers, engineers and practitioners in the field of IoT & Cyber Physical Human Systems. The journal offers a unique platform to exchange scientific information on the entire breadth of technology, science, and societal applications of the IoT. The journal will place a high priority on timely publication, and provide a home for high quality. Furthermore, IOT is interested in publishing topical Special Issues on any aspect of IOT.
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