UAV-Assisted Wireless Powered Cooperative Mobile Edge Computing: Joint Offloading, CPU Control, and Trajectory Optimization

Liu, Yuan; Xiong, Ke; Ni, Qiang; Fan, Pingyi; Letaief, Khaled B.

doi:10.1109/jiot.2019.2958975

Cited by 200 publications

(91 citation statements)

References 37 publications

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“…In addition, each tier is composed of 120×120 square tile grids with the unit length of one side, i.e., 1m. All the AUEs adopt the Ka-band sharing the same 8,8) , (15,20)] and the acceleration vector a[k] are always set to (0, 0). The positive weighting factor are set to λ 1 =0.9, and λ 2 =10 −15 , respectively.…”

Section: Simulation Resultsmentioning

confidence: 99%

“…An attractive solution is to apply far-field wireless power transfer (WPT) to provide a controllable, sustainable, and longer-range energy supply for the AUEs [5]. Recently, the integration of far-field WPT into the MEC system has gained many research interests, aiming to improve the system performance by optimizing task offloading and resource allocation jointly [6]- [8]. However, these works mainly focus on the use of radio frequency (RF)based WPT at the terrestrial or aerial infrastructure to prolong the lifetime of energy-limited UEs on the ground.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Privacy-Aware Wireless Power Transfer for Aerial Computation Offloading via Colonel Blotto Game

Wang¹,

Zhang²,

Min³

et al. 2020

Preprint

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In this paper, a laser-powered aerial mobile edge computing (MEC) architecture is proposed, where a high-altitude platform (HAP) integrated with an MEC server transfers laser energy to charge aerial user equipments (AUEs) for offloading their computation tasks to the HAP. Particularly, we identify a new privacy vulnerability caused by the transmission of wireless power transfer (WPT) signaling in the presence of a malicious smart attacker (SA). To address this vulnerability, the interaction between the HAP and the SA in their allocation of tile grids as charging points to the AUEs in laser-enabled WPT is formulated as a Colonel Blotto game (CBG), which models the competition of two players for limited resources over multiple battlefields for a finite time horizon. Moreover, the utility function that each player receives over a battlefield is developed by identifying the tradeoff between privacy protection level and energy consumption of each AUE. We further obtain the mixed-strategy Nash equilibrium for the modified CBG with asymmetric players. Simulation results are presented to show the effectiveness of this game framework.

show abstract

Section: Simulation Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Privacy-Aware Wireless Power Transfer for Aerial Computation Offloading via Colonel Blotto Game

Wang¹,

Zhang²,

Min³

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…And an energy-effective cooperative resource allocation policy for the WPT-MEC system was also proposed in [16] to guarantee the fairness of mobile users. In addition, Liu et al in [17] presented a UAV-assisted WPT-MEC system, and studied the joint optimization of task offloading, CPU control, and trajectory design. There are still some existing works considering cache-aided WPT-IoT networks.…”

Section: A Wireless Power Transfer In Iotmentioning

confidence: 99%

Blockchain-Based Incentive Energy-Knowledge Trading in IoT: Joint Power Transfer and AI Design

Lin

Bashir

et al. 2022

IEEE Internet Things J.

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Recently, edge artificial intelligence techniques (e.g., federated edge learning) are emerged to unleash the potential of big data from Internet of Things (IoT). By learning knowledge on local devices, data privacy-preserving and quality of service (QoS) are guaranteed. Nevertheless, the dilemma between the limited on-device battery capacities and the high energy demands in learning is not resolved. When the on-device battery is exhausted, the edge learning process will have to be interrupted. In this paper, we propose a novel Wirelessly Powered Edge intelliGence (WPEG) framework, which aims to achieve a stable, robust, and sustainable edge intelligence by energy harvesting (EH) methods. Firstly, we build a permissioned edge blockchain to secure the peer-to-peer (P2P) energy and knowledge sharing in our framework. To maximize edge intelligence efficiency, we then investigate the wirelessly-powered multi-agent edge learning model and design the optimal edge learning strategy. Moreover, by constructing a two-stage Stackelberg game, the underlying energy-knowledge trading incentive mechanisms are also proposed with the optimal economic incentives and power transmission strategies. Finally, simulation results show that our incentive strategies could optimize the utilities of both parties compared with classic schemes, and our optimal learning design could realize the optimal learning efficiency.

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“…where g U k denotes the small-scale fast fading power component following the unit mean exponential distribution [14] [16]. A is the path loss constant.…”

Section: System Modelmentioning

confidence: 99%

“…Recently, a UAV-enabled WPT architecture has been proposed, which employs the UAV as an energy transmitter to provide energy for ground equipment. This framework endows the system with excellent performance in improving the computing capability [7] [11], increasing the system capacity [12] and reducing the energy consumption of the system [13] [14] [15]. Considering the imperfect ground infrastructure in the IoRT network, it is necessary to develop UAV-enabled WPT edge computing system owing to the flexible deployment and low operation cost of the UAV.…”

Section: Introductionmentioning

confidence: 99%

Joint Stochastic Computational Resource and UAV Trajectory for Wireless-Powered Space-Air-Ground IoRT Networks

et al. 2020

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The space-air-ground (SAG) network boosts the application for the imperfect ground infrastructure in Internet of remote things (IoRT) networks. Considering the limited battery life of IoRT devices and the difficulty of replacement, unmanned aerial vehicle (UAV) is deployed in SAG networks to assist wireless power transmission (WPT) in order to achieve sustainable device operation and enhanced computational capability. In this paper, a three-layer SAG network is proposed to serve IoRT devices. Given the intricate and unpredictable environment of the IoRT SAG network, the tasks need to be timely processed by the IoRT devices without prior knowledge, which remains an ongoing challenge on available resources management. Thus, an online resource scheduling scheme that jointly optimizes CPU cycle frequency, power control and UAV trajectory planning is developed. We aim to maximize the long-term time-averaged total system computation rate while satisfying network stability and sustainability. The studied problem is a nonlinear stochastic optimization problem, which is decoupled into three sub-problems by leveraging Lyapunov optimization. Furthermore, we propose an online algorithm, namely JCPUI, to obtain the optimal CPU cycle frequency, power control, and UAV trajectory planning. Besides, performance analysis is provided for the proposed JCPUI, which elaborates that the control parameter V affects the trade-off of the total system computation rate and system stability. Simulation results validate the theoretical analysis and demonstrate the effectiveness of JCPUI. INDEX TERMS Internet of remote things (IoRT), space-air-ground (SAG), wireless power transfer (WPT), unmanned aerial vehicle (UAV), stochastic optimization.

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UAV-Assisted Wireless Powered Cooperative Mobile Edge Computing: Joint Offloading, CPU Control, and Trajectory Optimization

Cited by 200 publications

References 37 publications

Privacy-Aware Wireless Power Transfer for Aerial Computation Offloading via Colonel Blotto Game

Privacy-Aware Wireless Power Transfer for Aerial Computation Offloading via Colonel Blotto Game

Blockchain-Based Incentive Energy-Knowledge Trading in IoT: Joint Power Transfer and AI Design

Joint Stochastic Computational Resource and UAV Trajectory for Wireless-Powered Space-Air-Ground IoRT Networks

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