Joint Optimization of Computation Offloading, Data Compression, Energy Harvesting, and Application Scenarios in Fog Computing

Bai, Wenle; Ma, Ziyang; Han, Yanchun; Wu, Menglong; Zhao, Zhongyuan; Li, Mengkun; Wang, Chengcai

doi:10.1109/access.2021.3067702

Cited by 8 publications

(5 citation statements)

References 31 publications

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“…e task offloaded to the fog will be redistributed by the algorithm, and some will be further offloaded to the cloud server. According to [9,11,14,15], it is known that the offloading backhaul data is extremely small, much smaller than of the offloaded, so the return cost is chosen to be ignored. Let the transmission rate between users and F-AP be B F ; then, the transmission time to the fog is…”

Section: Problem Formulationmentioning

confidence: 99%

“…Moreover, the processing speed of the local device, the fog server, and the cloud server is set to f L � 2.1 × 10 8 cycle/s, f F � 5 × 10 9 cycle/s, and f C � 10 × 10 9 cycle/s [9], respectively. e wireless transmission rate between the local and F-AP is 15 Mbps and from the fog to cloud is 40 Mbps [15]. Besides, ϕ � 100cycle/s, T limit � 1200ms, H � 500, and c � 1J/s are further set.…”

Section: Evaluation and Simulationmentioning

confidence: 99%

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Randomization-Based Dynamic Programming Offloading Algorithm for Mobile Fog Computing

Bai

Yang

Zhang

et al. 2021

Security and Communication Networks

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Offloading to fog servers makes it possible to process heavy computational load tasks in local devices. However, since the generation problem of offloading decisions is an N-P problem, it cannot be solved optimally or traditionally, especially in multitask offloading scenarios. Hence, this paper has proposed a randomization-based dynamic programming offloading algorithm, based on genetic optimization theory, to solve the offloading decision generation problem in mobile fog computing. The algorithm innovatively designs a dynamic programming table-filling approach, i.e., iteratively generates a set of randomized offloading decisions. If some in these sets improve the decisions in the DP table, then they will be merged into the table. The iterated DP table is also used to improve the set of decisions generated in the iteration to obtain the optimal offloading approximate solution. Extensive simulations show that the proposed DPOA can generate decisions within 3 ms and the benefit is especially significant when users are in multitask offloading scenarios.

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Section: Problem Formulationmentioning

confidence: 99%

Section: Evaluation and Simulationmentioning

confidence: 99%

Randomization-Based Dynamic Programming Offloading Algorithm for Mobile Fog Computing

Bai

Yang

Zhang

et al. 2021

Security and Communication Networks

Self Cite

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“…Biswas et al [80] focused on reducing the energy loss problem and designing an energy-efficient data transfer scenario between IoT devices and clouds. Bai et al [81] suggested a joint computation offloading, data compression, energy harvesting, and application scenarios algorithm for FC. Maher et al [82] introduced a data backup system based on multicloud and FC.…”

Section: E Data Utility Based Algorithmsmentioning

confidence: 99%

Energy Coherent Fog Networks Using Multi-Sink Wireless Sensor Networks

et al. 2021

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Fog computing (FC) models the cloud computing paradigm expedient by bridging the breach between centralized data servers and diverse terrestrially distributed applications. It wields various wireless sensor networks (WSNs) that sprawl in the core of any IoT applications. Consequently, the operation of fog network turns on the efficiency of WSNs operation, while the all-inclusive network energy consumption depends on both FC and WSNs operation. This paper addresses how dissimilar organizations of a fog network can influence its effectiveness and energy savings. Chiefly, it appraises whether deploying multisink nodes in close enough vicinity to the fog nodes can give in energy savings and foster coherent data communication between WSNs and fog networks. To assess the multi-sink assignment problem the following four criteria are used: (i) Distance from the fog network nodes; (ii) Nodes degree; (iii) Sink nodes energy; and (iv) Sink nodes processing capabilities. This paper suggests four novel solutions to the multisink connectivity for some challenges of fog networks deeming: (i) Window Nondominant Set (WNS); (ii) Evaluation Based Approach (EBA); (iii) Harris Hawks Optimizer (HHO); and (iv) Modified HHO (MHHO). Distinct sets of experiments are conducted to check out algorithmic performance. The performance of all algorithms is measured and then compared to each other in terms of power consumption, runtime, packet loss, and localization error. One of the key supremacies of our approaches is the utilization of fog network for sensor networks data processing, principally with the large-scale networks. Yet, the communication challenges could need further study due to the limited communication range of the sensors.

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“…Among these solutions, harvesting energy from RF signals neither demands complex energy harvesting equipments nor depends time-variant energy resources. Such advantages of this energy harvesting solution induce it to become a bright candidate deployed in small-size users in 5G mobile communications or IoT to provision energy, linger the life-time, and enhance energy efficiency [6][7][8]. Currently, this solution can be carried out through SWIPT (simultaneous wireless information and power transfer) [9][10][11] or relaying communications [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Impact of Artificial Noise on Security Capability of Energy Harvesting Overlay Networks

Ho-Van

Do-Dac

2021

Wireless Communications and Mobile Computing

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Artificial noise, energy harvesting, and overlay communications can assure design metrics of modern wireless networks such as data security, energy efficiency, and spectrum utilization efficiency. This paper studies impact of artificial noise on security capability of energy harvesting overlay networks in which the cognitive transmitter capable of self-powering its operation by harvesting radio frequency energy and self-securing its communications against eavesdroppers by generating artificial noise amplifies and forwards the signal of the primary transmitter as well as transmits its individual signal concurrently. To quantify this impact, the current paper firstly suggests accurate expressions of crucial security performance indicators. Then, computer simulations are supplied to corroborate these expressions. Finally, numerous results are demonstrated to expose insights into this impact from which optimum specifications are determined. Notably, primary/cognitive communications can be secured at distinct degrees by flexibly controlling multiple specifications of the suggested system model.

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Joint Optimization of Computation Offloading, Data Compression, Energy Harvesting, and Application Scenarios in Fog Computing

Cited by 8 publications

References 31 publications

Randomization-Based Dynamic Programming Offloading Algorithm for Mobile Fog Computing

Randomization-Based Dynamic Programming Offloading Algorithm for Mobile Fog Computing

Energy Coherent Fog Networks Using Multi-Sink Wireless Sensor Networks

Impact of Artificial Noise on Security Capability of Energy Harvesting Overlay Networks

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