A Self-Aware and Scalable Solution for Efficient Mobile-Cloud Hybrid Robotics

Akbar, Aamir; Lewis, Peter R.; Wanner, Elizabeth F.

doi:10.3389/frobt.2020.00102

Cited by 5 publications

(4 citation statements)

References 48 publications

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“…Shamshirband et al [5] presented a survey on work that has been previously carried out on the technique of a computational intelligence (CI)-based ID model, its classification with the implementation methods, and issues, and compared this technique with other techniques. Akbar et al [6] give a scalable solution for efficient mobile cloud hybrid (MCH) applications and also present previous related work on mobile cloud frameworks. They present multi-objective optimization (MOO) algorithms for the betterment of MCC usage, and give two scenarios to determine the best result for MOO as well as future MCH work on MCC.…”

Section: Literature Reviewmentioning

confidence: 99%

Mobile Cloud Computing: A Survey on Current Security Trends and Future Directions

Sheikh,

Butt,

Hanif

2023

Interact 2023

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Section: Literature Reviewmentioning

confidence: 99%

Mobile Cloud Computing: A Survey on Current Security Trends and Future Directions

Sheikh,

Butt,

Hanif

2023

Interact 2023

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“…Furthermore, the authors in [28] proposed a general-purpose Mobile Cloud Hybrid (MCH) framework. The proposed framework was used to optimize power consumption, and network usage of MCH applications developed for batterypowered Android-based devices [29] and robotics [30]. A similar type of framework for mobile cloud computing systems with a Computing Access Point (CAP) was proposed in [19].…”

Section: State-of-the-artmentioning

confidence: 99%

ARTNet: Ai-Based Resource Allocation and Task Offloading in a Reconfigurable Internet of Vehicular Networks

Akbar

Jan

et al. 2022

IEEE Trans. Netw. Sci. Eng.

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The convergence of Software-Defined Networking (SDN) and Internet of Vehicular (IoV) integrated with Fog Computing (FC), known as Software Defined Vehicular based FC (SDV-F), has recently been established to take advantage of both paradigms and efficiently control the wireless networks. SDV-F tackles numerous problems, such as scalability, load-balancing, energy consumption, and security. It lags, however, in providing a promising approach to enable ultra-reliable and delay-sensitive applications with high vehicle mobility over SDV-F. We propose ARTNet, an AI-based Vehicle-to-Everything (V2X) framework for resource distribution and optimized communication using the SDV-F architecture. ARTNet offers ultra-reliable and low-latency communications, particularly in highly dynamic environments, which is still a challenge in IoV. ARTNet is composed of intelligent agents/controllers, to make decisions intelligently about (i) maximizing resource utilization at the fog layer, and (ii) minimizing the average end-to-end delay of time-critical IoV applications. Moreover, ARTNet is designed to assign a task to fog nodes based on their states. Our experimental results show that considering a dynamic IoV environment, ARTNet can efficiently distribute the fog layer tasks while minimizing the delay.

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“…To provide a better QoE, multi-objective optimization (MOO) techniques have been used, in different domains, to minimize the trade-off between conflicting objectives. For example, MOO has been used to improve coverage of wireless nodes [22] in a network, to optimize the trade-off between two conflicting objectives (battery power consumption and network usage) of mobile-cloud hybrid applications for smartphones [23] and battery-powered robots [24]. In MOO algorithms, multiple objectives are treated simultaneously, subject to a set of constraints [25].…”

Section: Related Workmentioning

confidence: 99%

SDN-Enabled Adaptive and Reliable Communication in IoT-Fog Environment Using Machine Learning and Multiobjective Optimization

Akbar

Jan

Wang

2021

IEEE Internet Things J.

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The Internet of Things (IoT) has inspired the development of emerging new applications. Backed by the resourceful fog computing, the IoT devices are capable to meet the demands of tasks, even the most computationally-intensive ones. However, many existing IoT applications are unable to perform well, while communicating with the fog server due to different QoS requirements. Constantly changing traffic demands of applications is another challenge to consider. The demand for real-time applications includes communicating over a path that is less prone to delay. Moreover, applications that offload computationally-intensive tasks to the fog server need a reliable path that has lower probability of link failure. This results in a trade-off among continuously changing objectives, i.e., minimizing the end-to-end delay and maximizing the reliability of paths between IoT devices and the fog server. To tackle this problem, we propose a novel approach that considers an SDNenabled multi-hop scenario for the IoT-Fog environment. We evaluated the reliability level of links by employing the real-life network statistics recorded for a period of over 5 months. We use a multi-objective optimization (MOO) algorithm to search the Pareto-optimal paths by considering the two conflicting objectives. Our experimental evaluation considers two different applications -a real-time application (App-1) using UDP sockets and a task offloading application (App-2) using TCP sockets. Our results show that: (i) using MOO, the trade-off between the two objectives can be optimized, and (ii) the SDN controller was able to make adaptive decision on-the-fly to choose the best path from the Pareto-optimal set. The App-1, communicating over the selected path finished its execution in 13% less time than communicating over the shortest path. The App-2 had 41% less packet loss using the selected path compared to using the shortest path.

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A Self-Aware and Scalable Solution for Efficient Mobile-Cloud Hybrid Robotics

Cited by 5 publications

References 48 publications

Mobile Cloud Computing: A Survey on Current Security Trends and Future Directions

Mobile Cloud Computing: A Survey on Current Security Trends and Future Directions

ARTNet: Ai-Based Resource Allocation and Task Offloading in a Reconfigurable Internet of Vehicular Networks

SDN-Enabled Adaptive and Reliable Communication in IoT-Fog Environment Using Machine Learning and Multiobjective Optimization

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