On the Optimality of Task Offloading in Mobile Edge Computing Environments

Alghamdi, Ibrahim; Anagnostopoulos, Christos; Pezaros, Dimitrios P.

doi:10.1109/globecom38437.2019.9014081

Cited by 14 publications

(33 citation statements)

References 23 publications

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“…1). This supports applications requiring pro-active decision making for: (i) allocating tasks/analytics queries only to relevant ENs based on their synopses studied in [30] and [49], (ii) share and update ML models in Federated Learning [5] for environmental monitoring based on synopses and network load, (iii) transfer tasks for ML models training & inference ENs based on network congestion [36], and (iv) separating context data by distributively gathering similar data to same datasets studied in [28]. As exemplified in Fig.…”

Section: A Edge Computing Infrastructurementioning

confidence: 85%

Proactive & Time-Optimized Data Synopsis Management at the Edge

Kolomvatsos

Anagnostopoulos

Koziri

et al. 2020

IEEE Trans. Knowl. Data Eng.

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Internet of Things offers the infrastructure for smooth functioning of autonomous context-aware devices being connected towards the Cloud. Edge Computing (EC) relies between the IoT and Cloud providing significant advantages. One advantage is to perform local data processing (limited latency, bandwidth preservation) with real time communication among IoT devices, while multiple nodes become hosts of the collected data (reported by IoT devices). In this work, we provide a mechanism for the exchange of data synopses (summaries of extracted knowledge) among EC nodes that are necessary to give the knowledge on the data present in EC environments. The overarching aim is to intelligently decide on when nodes should exchange data synopses in light of efficient execution of tasks. We enhance such a decision with a stochastic optimization model based on the Theory of Optimal Stopping. We provide the fundamentals of our model and the relevant formulations on the optimal time to disseminate data synopses to network edge nodes. We report a comprehensive experimental evaluation and comparative assessment related to the optimality achieved by our model and the positive effects on EC.

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Section: A Edge Computing Infrastructurementioning

confidence: 85%

Proactive & Time-Optimized Data Synopsis Management at the Edge

Kolomvatsos

Anagnostopoulos

Koziri

et al. 2020

IEEE Trans. Knowl. Data Eng.

Self Cite

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“…Common methods are primal-dual optimization [10,11], nonlinear optimization [7,12,13] and mixedinteger linear programming problem [14,15]. In [10], an online truthful mechanism based on the primal-dual optimization framework integrating computation and communication resource allocation is proposed .…”

Section: Related Workmentioning

confidence: 99%

“…Bai et al [12] conceived an energy-efficient computation offloading technique for UAV-MEC systems and formulated many energy-efficiency problems, which are then transformed into convex problems. In [13], Alghamdi et al tackled the MEC problem by adopting the principles of optimal stopping theory contributing to two time-optimized sequential decision-making models. Guo et al [14] forced on the problem of assigning resources for offloading the computationally intensive tasks of mobile applications.…”

Section: Related Workmentioning

confidence: 99%

Adaptive offloading in mobile-edge computing for ultra-dense cellular networks based on genetic algorithm

Liao

Peng

et al. 2021

J Cloud Comp

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With the combination of Mobile Edge Computing (MEC) and the next generation cellular networks, computation requests from end devices can be offloaded promptly and accurately by edge servers equipped on Base Stations (BSs). However, due to the densified heterogeneous deployment of BSs, the end device may be covered by more than one BS, which brings new challenges for offloading decision, that is whether and where to offload computing tasks for low latency and energy cost. This paper formulates a multi-user-to-multi-servers (MUMS) edge computing problem in ultra-dense cellular networks. The MUMS problem is divided and conquered by two phases, which are server selection and offloading decision. For the server selection phases, mobile users are grouped to one BS considering both physical distance and workload. After the grouping, the original problem is divided into parallel multi-user-to-one-server offloading decision subproblems. To get fast and near-optimal solutions for these subproblems, a distributed offloading strategy based on a binary-coded genetic algorithm is designed to get an adaptive offloading decision. Convergence analysis of the genetic algorithm is given and extensive simulations show that the proposed strategy significantly reduces the average latency and energy consumption of mobile devices. Compared with the state-of-the-art offloading researches, our strategy reduces the average delay by 56% and total energy consumption by 14% in the ultra-dense cellular networks.

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“…In our previous work [29,30,31], we proposed a set of lightweight sequential decision making models adopting the principle of OST. In particular, in our work in [29,30], we proposed a Delay Tolerant Offloading (DTO) decision making in mobile edge computing environment.…”

Section: Related Workmentioning

confidence: 99%