Journal of Advancement in Parallel Computing

An emerging field of study called network analysis and optimization calls for a variety of entities, such as resource management, performance analysis, privacy-oriented evaluation, and increased availability. The dynamic advancements in technological edges contribute to smart innovation, such as smart cities and smart homes, by increasing availability, reducing latency, and increasing connectivity of devices that provide and control network resource management. In this paper, we look at how the Internet of Things (IoT)'s mobile edge computing affects the network's service quality in the same way that other computing fields do. Erlang formulas based on various assumptions during data transmission comprise the Erlang Performance Model (EPM), which we offer as an additional performance model. Using mathematical calculations of virtual parameters, the article provides a comprehensive understanding of queuing theories related to the field of First-In-First-Out (FIFO) in mobile edge networks. The paper demonstrated that Erlang equations could be on the other hand utilized in planning execution models as we showed. Analyzing performance results in less congestion and traffic during data transmission, improved grade and quality of service determination for users and smart communication providers, according to simulated MATLAB results.

Z. Ning, X. Kong, F. Xia, W. Hou, and X. Wang, “Green and sustainable cloud of things: Enabling collaborative edge computing,” IEEE Communications Magazine, vol. 57, no. 1, pp. 72–78, 2019.

T. X. Tran and D. Pompili, “Joint task offloading and resource allocation for multi-server mobile-edge computing networks,” IEEE Transactions on Vehicular Technology, vol. 68, no. 1, pp. 856–868, 2019.

C. Li, J. Bai, and J. Tang, “Joint optimization of data placement and scheduling for improving user experience in edge computing,” Journal of Parallel and Distributed Computing, vol. 125, pp. 93–105, 2019.

A. Brogi, S. Forti, and A. Ibrahim, “Predictive analysis to support fog application deployment,” Fog and Edge Computing: Principles and Paradigms, pp. 191–221, 2019.

S. Li, D. Zhai, P. Du, and T. Han, “Energy-efficient task offloading, load balancing, and resource allocation in mobile edge computing enabled IoT networks,” Science China Information Sciences, vol. 62, no. 2, p. 29307, 2019.

T. T. Nguyen, L. Le, and Q. Le-Trung, “Computation offloading in MIMO based mobile edge computing systems under perfect and imperfect CSI estimation,” IEEE Transactions on Services Computing, 2019.

J. Ren, Y. He, G. Huang, G. Yu, Y. Cai, and Z. Zhang, “An Edge-Computing Based Architecture for Mobile Augmented Reality,” IEEE Network, 2019.

S. Ammirato, F. Sofo, A. M. Felicetti, and C. Raso, “A methodology to support the adoption of IoT innovation and its application to the Italian bank branch security context,” European Journal of Innovation Management, vol. 22, no. 1, pp. 146–174, 2019.

B. Afzal, M. Umair, G. A. Shah, and E. Ahmed, “Enabling IoT platforms for social IoT applications: vision, feature mapping, and challenges,” Future Generation Computer Systems, vol. 92, pp. 718–731, 2019.

V. V. Sood, S. Sharma, and R. Khanna, “Performance Evaluation of Cognitive Internet of Things in Asynchronous Distributed Space-Time Block Codes over Two-Wave Diffuse Power Fading Channel,” in Engineering Vibration, Communication and Information Processing, Springer, 2019, pp. 131–141.