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03.02.2020 | S.I. : Applying Artificial Intelligence to the Internet of Things

Evidence of power-law behavior in cognitive IoT applications

verfasst von: Sujit Bebortta, Dilip Senapati, Nikhil Kumar Rajput, Amit Kumar Singh, Vipin Kumar Rathi, Hari Mohan Pandey, Amit Kumar Jaiswal, Jia Qian, Prayag Tiwari

Erschienen in: Neural Computing and Applications | Ausgabe 20/2020

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Abstract

The motivations induced due to the presence of scale-free characteristics of neural systems governed by the well-known power-law distribution of neuronal activities have led to its convergence with the Internet of things (IoT) framework. The IoT is one such framework, where the self-organization of the connected devices is a momentous aspect. The devices involved in these networks inherently relate to the collection of several consolidated devices like the sensory devices, consumer appliances, wearables, and other associated applications, which facilitate a ubiquitous connectivity among the devices. This is one of the most significant prerequisites of IoT systems as several interconnected devices need to be included in the convolution for the uninterrupted execution of the services. Thus, in order to understand the scalability and the heterogeneity of these interconnected devices, the exponent of power-law plays a significant role. In this paper, an analytical framework to illustrate the ubiquitous power-law behavior of the IoT devices is derived. An emphasis regarding the mathematical insights for the characterization of the dynamic behavior of these devices is conceptualized. The observations made in this direction are illustrated through simulation results. Further, the traits of the wireless sensor networks, in context with the contemporary scale-free architecture, are discussed.

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Titel: Evidence of power-law behavior in cognitive IoT applications
verfasst von: Sujit Bebortta
Dilip Senapati
Nikhil Kumar Rajput
Amit Kumar Singh
Vipin Kumar Rathi
Hari Mohan Pandey
Amit Kumar Jaiswal
Jia Qian
Prayag Tiwari
Publikationsdatum: 03.02.2020
Verlag: Springer London
Erschienen in: Neural Computing and Applications / Ausgabe 20/2020
Print ISSN: 0941-0643
Elektronische ISSN: 1433-3058
DOI: https://doi.org/10.1007/s00521-020-04705-0

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