A Statistical Characterization of Localization Performance in Wireless Networks

O’Lone, Christopher E.; Dhillon, Harpreet S.; Buehrer, R. Michael

doi:10.1109/twc.2018.2850310

Cited by 32 publications

(32 citation statements)

References 28 publications

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“…Also, SG is increasingly adopted in studying the joint localization and communication of users in a given propagation environment. In particular, the authors of [419], [420] use tools from SG and its inherent PP theory to evaluate the statistics of the number of BSs/anchors (i.e., nodes with known positions) that can participate in the localization procedure of users/agents (i.e., nodes with unknown positions) as a function of systemlevel parameters and channel impairments. Typically, there is a tradeoff, known as the hearability problem, that needs to be considered between communication requirements that ask for a strong signal from the desired BS and a poor one from interferers, versus localization that requires a good signal from most BSs.…”

Section: Stochastic Geometry As a Multi-objective Analytical Toolmentioning

confidence: 99%

New Trends in Stochastic Geometry for Wireless Networks: A Tutorial and Survey

et al. 2021

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Next generation wireless networks are expected to be highly heterogeneous, multi-layered, with embedded intelligence at both the core and edge of the network. In such a context, system-level performance evaluation will be very important to formulate relevant insights into tradeoffs that govern such a complex system. Over the past decade, stochastic geometry (SG) has emerged as a powerful analytical tool to evaluate system-level performance of wireless networks and capture their tendency towards heterogeneity. However, with the imminent onset of this crucial new decade, where global commercialization of fifthgeneration (5G) is expected to emerge and essential research questions related to beyond fifth-generation (B5G) are intended to be identified, we are wondering about the role that a powerful tool like SG should play. In this paper, we first aim to track and summarize the novel SG models and techniques developed during the last decade in the evaluation of wireless networks. Next, we will outline how SG has been used to capture the properties of emerging radio access networks (RANs) for 5G/B5G and quantify the benefits of key enabling technologies. Finally, we will discuss new horizons that will breathe new life into the use of SG in the foreseeable future. For instance, using SG to evaluate performance metrics in the visionary paradigm of molecular communications. Also, we will review how SG is envisioned to cooperate with machine learning seen as a crucial component in the race towards ubiquitous wireless intelligence. Another important insight is Grothendieck toposes considered as a powerful mathematical concept that can help to solve longstanding problems formulated in SG.

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Section: Stochastic Geometry As a Multi-objective Analytical Toolmentioning

confidence: 99%

New Trends in Stochastic Geometry for Wireless Networks: A Tutorial and Survey

et al. 2021

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“…In a cooperative location network [30], the prior position ambiguity of neighboring nodes affects the positioning accuracy. The settings are the same as those used to produce Figure 6.…”

Section: Analysis Of the Influence Of Position Ambiguitymentioning

confidence: 99%

Factor-Graph-Aided Three-Dimensional Faster Cooperative Positioning Algorithm

et al. 2021

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With the development of smart cities and 5G applications, there is an increasingly urgent need for cooperative positioning among all kinds of intelligent terminals. Existing cooperative positioning technology is primarily designed for two-dimensional positions, and the computing speed and positioning accuracy cannot meet the needs of smart cities. To solve these problems, this paper proposes a factor-graphaided three-dimensional faster cooperative positioning algorithm (FG-3DCP) that combines a factor graph and sum product theory to establish a cooperative localization model with many nodes. To reduce computational complexity and describe fast positioning, the parameter independence of the factor graph is used, and the positioning data of each node coordinate axis are calculated independently. Then, the positioning result is obtained by fusion, and the computing speed is markedly improved. The proposed algorithm was simulated and analyzed in terms of ranging error, position ambiguity, network topology and the number of nodes. When the proposed algorithm was compared to the existing non-Bayesian estimation cooperative position methods, the position performance improved more than 20%, and the convergence rate was the fastest in the 3D environment.

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“…Potential approach: To perform a comprehensive comparative study between I-WCP and D-WCP, incorporating the WCPP into the WDP placement problem could be examined. The WDP placement problem, such as the placement problem of mmWave SBSs in UDNs to improve coverage performance, is exhaustively researched by using stochastic geometry, stochastic optimization, and game theory analytical tools O'Lone et al (2017); Chatterjee et al (2018a); Han et al (2012). In this regard, a joint placement optimization framework could be devised to address the challenges of the WCPP and the WDP placement.…”

Section: Direct or Indirect Wcpmentioning

confidence: 99%

The wireless control plane: An overview and directions for future research

Mazied

ElNainay

Abdel-Rahman

et al. 2019

Journal of Network and Computer Applications

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Software-defined networking (SDN), which has been successfully deployed in the management of complex data centers, has recently been incorporated into a myriad of 5G networks to intelligently manage a wide range of heterogeneous wireless devices, software systems, and wireless access technologies. Thus, the SDN control plane needs to communicate wirelessly with the wireless data plane either directly or indirectly. The uncertainties in the wireless SDN control plane (WCP) make its design challenging. Both WCP schemes (direct WCP, D-WCP, and indirect WCP, I-WCP) have been incorporated into recent 5G networks; however, a discussion of their design principles and their design limitations is missing. This paper introduces an overview of the WCP design (I-WCP and D-WCP) and discusses its intricacies by reviewing its deployment in recent 5G networks. Furthermore, to facilitate synthesizing a robust WCP, this paper proposes a generic WCP framework using deep reinforcement learning (DRL) principles and presents a roadmap for future research.

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A Statistical Characterization of Localization Performance in Wireless Networks

Cited by 32 publications

References 28 publications

New Trends in Stochastic Geometry for Wireless Networks: A Tutorial and Survey

New Trends in Stochastic Geometry for Wireless Networks: A Tutorial and Survey

Factor-Graph-Aided Three-Dimensional Faster Cooperative Positioning Algorithm

The wireless control plane: An overview and directions for future research

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