InferLoc: Hypothesis-based Joint Edge Inference and Localization in Sparse Sensor Networks

IF 3.9 4区 计算机科学 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS ACM Transactions on Sensor Networks Pub Date : 2023-07-12 DOI:https://dl.acm.org/doi/10.1145/3608477
Xuewei Bai, Yongcai Wang, Haodi Ping, Xiaojia Xu, Deying Li, Shuo Wang
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Abstract

Ranging-based localization is a fundamental problem in the Internet of Things (IoT) and Unmanned Aerial Vehicles (UAV) networks. However, the nodes’ limited-ranging scope and users’ broad coverage purpose inevitably cause network sparsity or subnetwork sparsity. The performances of existing localization algorithms are extremely unsatisfactory in sparse networks. A crucial way to deal with the sparsity is to exploit the hidden knowledge provided by the unmeasured edges, which inspires this paper to propose a hypothesis-based Joint Edge Inference and Localization algorithm, i.e., InferLoc. InferLoc mines the Unmeasured but Inferable Edges (UIEs). Each UIE is an unmeasured edge, but it is restricted through other edges in the network to be inside a rigid component, so it has only a limited number of possible lengths. We propose an efficient method to detect UIEs and geometric approaches to infer possible lengths for UIEs in 2D and 3D networks. The inferred possible lengths of UIEs are then treated as multiple hypotheses to determine the node locations and the lengths of UIEs simultaneously through a joint graph optimization process. In the joint graph optimization model, to make the 0/1 decision variables for hypotheses selection differentiable, differentiable functions are proposed to relax the 0/1 selections, and rounding is applied to select the final length after the optimization converges. We also prove the condition when a UIE can contribute to sparse localization. Extensive experiments show remarkably better accuracy and efficiency performances of InferLoc than the state-of-the-art network localization algorithms. In particular, it reduces the localization errors by more than \(90\% \) and speeds up the convergence time over 100 times than the widely used G2O-based methods in sparse networks.

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基于假设的稀疏传感器网络联合边缘推理与定位
基于测距的定位是物联网(IoT)和无人机(UAV)网络中的一个基本问题。然而,节点范围有限,用户覆盖目的广泛,不可避免地造成网络或子网稀疏。现有的定位算法在稀疏网络中的性能非常不理想。利用未测量边所提供的隐藏知识是处理稀疏性的关键方法,为此,本文提出了一种基于假设的联合边缘推断与定位算法,即interloc。InferLoc挖掘未测量但可推断的边缘(UIEs)。每个UIE都是一条未测量的边,但它通过网络中的其他边被限制在刚性组件内,因此它只有有限数量的可能长度。我们提出了一种有效的方法来检测uie和几何方法来推断二维和三维网络中uie的可能长度。然后将推断出的uie可能长度作为多个假设,通过联合图优化过程同时确定uie的节点位置和长度。在联合图优化模型中,为了使假设选择的0/1决策变量可微,提出了可微函数来放宽0/1选择,并采用舍入来选择优化收敛后的最终长度。我们还证明了UIE有助于稀疏定位的条件。大量实验表明,该算法的精度和效率明显优于当前最先进的网络定位算法。特别是,与稀疏网络中广泛使用的基于g20的方法相比,它将定位误差降低了\(90\% \)以上,收敛时间加快了100倍以上。
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来源期刊
ACM Transactions on Sensor Networks
ACM Transactions on Sensor Networks 工程技术-电信学
CiteScore
5.90
自引率
7.30%
发文量
131
审稿时长
6 months
期刊介绍: ACM Transactions on Sensor Networks (TOSN) is a central publication by the ACM in the interdisciplinary area of sensor networks spanning a broad discipline from signal processing, networking and protocols, embedded systems, information management, to distributed algorithms. It covers research contributions that introduce new concepts, techniques, analyses, or architectures, as well as applied contributions that report on development of new tools and systems or experiences and experiments with high-impact, innovative applications. The Transactions places special attention on contributions to systemic approaches to sensor networks as well as fundamental contributions.
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