Understanding Interdependencies among Fog System Characteristics

2022 IEEE 24th Conference on Business Informatics (CBI) Pub Date : 2022-06-01 DOI:10.1109/CBI54897.2022.00021

Maximilian Blume, S. Lins, Ali Sunvaev

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Abstract

Fog computing adds decentralized computing, storage, and networking capabilities with dedicated nodes as an intermediate layer between cloud data centers and edge devices to solve latency, bandwidth, and resilience issues. However, in-troducing a fog layer imposes new system design challenges. Fog systems not only exhibit a multitude of key system characteristics (e.g., security, resilience, interoperability) but are also beset with various interdependencies among their key characteristics that require developers' attention. Such interdependencies can either be trade-offs with improving the fog system on one characteristic impairing it on another, or synergies with improving the system on one characteristic also improving it on another. As system developers face a multifaceted and complex set of potential system design measures, it is challenging for them to oversee all potentially resulting interdependencies, mitigate trade-offs, and foster synergies. Until now, existing literature on fog system architecture has only analyzed such interdependencies in isolation for specific characteristics, thereby limiting the applicability and generalizability of their proposed system designs if other than the considered characteristics are critical. We aim to fill this gap by conducting a literature review to (1) synthesize the most relevant characteristics of fog systems and design measures to achieve them, and (2) derive interdependences among all key characteristics. From reviewing 147 articles on fog system architectures, we reveal 11 key characteristics and 39 interdependencies. We supplement the key characteristics with a description, reason for their relevance, and related design measures derived from literature to deepen the understanding of a fog system's potential and clarify semantic ambiguities. For the interdependencies, we explain and differentiate each one as positive (synergies) or negative (trade-offs), guiding practitioners and researchers in future design choices to avoid pitfalls and unleash the full potential of fog computing.

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了解雾系统特性之间的相互依赖关系

雾计算通过专用节点作为云数据中心和边缘设备之间的中间层，增加了分散的计算、存储和网络功能，以解决延迟、带宽和弹性问题。然而，引入雾层会给系统设计带来新的挑战。雾系统不仅展示了大量的关键系统特征(例如，安全性、弹性、互操作性)，而且还受到其关键特征之间各种相互依赖关系的困扰，需要开发人员的注意。这种相互依赖关系可以是一种权衡，即在一个特征上改进雾系统会损害另一个特征，也可以是在一个特征上改进系统同时在另一个特征上改进系统的协同作用。当系统开发人员面对多方面和复杂的潜在系统设计措施时，对他们来说，监督所有潜在的相互依赖性、减轻权衡和促进协同作用是具有挑战性的。到目前为止，关于雾系统架构的现有文献仅针对特定特征孤立地分析了这种相互依赖性，从而限制了他们提出的系统设计的适用性和通用性，如果考虑的其他特征是至关重要的。我们的目标是通过进行文献综述来填补这一空白，以(1)综合雾系统最相关的特征并设计实现这些特征的措施，以及(2)得出所有关键特征之间的相互依赖性。通过回顾147篇关于雾系统架构的文章，我们揭示了11个关键特征和39个相互依赖关系。我们补充了主要特征的描述，其相关性的原因，以及从文献中得出的相关设计措施，以加深对雾系统潜力的理解并澄清语义歧义。对于相互依赖关系，我们解释并区分每一个是积极的(协同作用)或消极的(权衡)，指导从业者和研究人员在未来的设计选择中避免陷阱，释放雾计算的全部潜力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE 24th Conference on Business Informatics (CBI)

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