Completion time minimization for UAV enabled data collection with communication link constrained

Wu, Binbin; Guo, Daoxing; Zhang, Xiaokai; Wang, Hongbin; Wang, Haichao; Jiang, Hao

doi:10.1049/cmu2.12378

Cited by 8 publications

(10 citation statements)

References 44 publications

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“…A similar proof can be found in Appendix A. □ C 3 can be converted to the stability constraint of virtual priority deficit queue F i (t ) that is, C 3 is satisfied when F i (t ) is mean rate stable [5]. Define the Lyapunov function as…”

Section: Problem Transformationmentioning

confidence: 99%

“…C 3 can be converted to the stability constraint of virtual priority deficit queue

F_i(t)

that is, C 3 is satisfied when

F_i(t)

is mean rate stable [5]. Define the Lyapunov function as

\begin{align} L(\Theta (t))=\frac{1}{2} \sum _{u_i \in \mathcal {U}} F_i^2(t) \end{align}

…”

Section: Priority‐aware Dqn‐based Intelligent Access Managementmentioning

confidence: 99%

“…The fifth generation (5G) mobile communication technology provides a feasible solution for real‐time data transmission of carbon footprint monitoring [4]. 5G possesses the advantages of low latency, high reliability, and large bandwidth, which can be integrated with edge computing to enable data uploading, processing, and analysis through cloud‐edge‐device collaboration [5]. However, massive device access of carbon footprint monitoring evokes access collision due to limited available spectrum, which further worsens access delay and service priority guarantee.…”

Section: Introductionmentioning

confidence: 99%

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Priority‐aware intelligent device access management for carbon footprint monitoring in sustainable cites and society

Wang

Liao

et al. 2022

IET Communications

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Carbon footprint monitoring provides significant basis for computing facilities to improve the computing efficiency and reduce the energy cost, which can enable low/zero carbon computing and facilitate the construction of sustainable cites. Massive sensing devices access to 5G base station to transmit collected carbon emission data, which requires intelligent access management. Fast uplink grant possesses the advantages of reducing signalling overhead and access conflicts while facing the problems of incomplete information and difficulty in guaranteeing priority constraint. This paper examines, the maximum access queuing delay minimization problem is formulated under the long‐term service priority constraint and the short‐term access management constraint. First, Lyapunov optimization is leveraged to decouple the long‐term service priority constraint and short‐term access management optimization, and decompose the long‐term stochastic optimization problem into a series of short‐term deterministic problems. Then, a priority‐aware deep Q‐network (DQN)‐based fast uplink grant access management (PDAC) algorithm is proposed to achieve intelligent access management with differentiated service priority requirements. PDAC utilizes DQN to handle non‐convex high‐dimensional optimization problem with service priority constraint to achieve intelligent access management and priority awareness. Simulation results demonstrate that PDAC outperforms the existing algorithms in access queuing delay, buffer queue backlog, and priority deficit fluctuation.

show abstract

Section: Problem Transformationmentioning

confidence: 99%

“…C 3 can be converted to the stability constraint of virtual priority deficit queue

F_i(t)

that is, C 3 is satisfied when

F_i(t)

is mean rate stable [5]. Define the Lyapunov function as

\begin{align} L(\Theta (t))=\frac{1}{2} \sum _{u_i \in \mathcal {U}} F_i^2(t) \end{align}

…”

Section: Priority‐aware Dqn‐based Intelligent Access Managementmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Priority‐aware intelligent device access management for carbon footprint monitoring in sustainable cites and society

Wang

Liao

et al. 2022

IET Communications

View full text Add to dashboard Cite

show abstract

“…Authors in [8] used a UAV-aided communication network to serve randomly moving users and proposed an adaptive deployment strategy. With the UAV being used to collect data of low-power ground sensor nodes in an obstacle environment, the completion time can be minimized by jointly optimizing the UAV trajectory and collection sequence of sensor nodes [9,10]. UAVs have significant advantages in high mobility, and a rational trajectory can effectively improve the quality of the network.…”

Section: Introductionmentioning

confidence: 99%

Joint mission planning and spectrum resources optimization for multi‐UAV reconnaissance

Liao

et al. 2022

IET Communications

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In this paper, the problem of mission planning and spectrum resource allocation for cooperative reconnaissance of ground targets with multiple unmanned aerial vehicles (UAVs) is studied. A joint mission planning and spectrum resource optimization algorithm for multi-UAVs is proposed to improve the information transmission rate by reusing the spectrum of existing users. The joint optimization problem is formulated as mixed-integer nonlinear programming. The block coordinate descent (BCD) method is further applied to achieve the optimal strategies of mission planning, channel allocation, and power control. Specifically, an improved genetic algorithm (GA) combined with the successive convex approximation (SCA) is used to solve the sub-problem of mission planning. For the channel allocation sub-problem, an iterative convergence channel allocation algorithm is proposed. Numerical results show that the proposed algorithm can achieve a higher UAV transmission rate and better robustness than existing algorithms.

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“…However, these studies did not consider the existence of obstacles in the paths of UAVs, whereas there can be many obstacles (e.g., buildings, mountains, big trees, and no-fly zone areas) in a UAV's trajectory that need to be avoided when it flies from one sensor to another. Although some studies considered obstacles in the UAV trajectories [16][17][18][19][20][21], they did not consider the UAV path as the Hamiltonian path, which is impractical because UAVs are battery-constrained devices and need to return to the base station (BS) to recharge their batteries after a given period of data collection.…”

Section: Introductionmentioning

confidence: 99%

OADC: An Obstacle-Avoidance Data Collection Scheme Using Multiple Unmanned Aerial Vehicles

2022

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Unmanned aerial vehicles (UAVs) are used widely for data collection in wireless sensor networks (WSNs). UAVs visit the sensors to collect the data. UAV-aided data collection is a challenging problem because different paths of a UAV, i.e., visiting orders of sensors, affect energy consumption and data delivery times. The problem becomes more difficult when there are obstacles in the path of the UAV. Thus, the UAV needs to take a detour to avoid them, resulting in different travel distances and times. Therefore, this study formulated the obstacle-aware path planning problem of UAVs, i.e., the obstacle-constrained distance minimization (OCDM) problem, as an integer linear programming problem (ILP) to minimize the total traveling distances of all UAVs while considering the UAVs’ flight time constraints. First, a possible detour-points-selection algorithm called vector rotation-angle-based obstacle avoidance (VRAOA) is proposed to find the detour points around each obstacle in the environment. Then, a genetic algorithm with VRAOA (GA w/VRAOA)is developed to find the trajectories of the UAVs, using the VRAOA and Dijkstra algorithm to find a detour path if there is an obstacle between any two sensors. Finally, simulations were performed for algorithm variants, where GA w/VRAOA outperformed others.

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Completion time minimization for UAV enabled data collection with communication link constrained

Cited by 8 publications

References 44 publications

Priority‐aware intelligent device access management for carbon footprint monitoring in sustainable cites and society

Priority‐aware intelligent device access management for carbon footprint monitoring in sustainable cites and society

Joint mission planning and spectrum resources optimization for multi‐UAV reconnaissance

OADC: An Obstacle-Avoidance Data Collection Scheme Using Multiple Unmanned Aerial Vehicles

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