Flying ad hoc networks : cooperative networking and resource allocation / Jingjing Wang, Chunxiao Jiang.
Wang, Jingjing.; Jiang, Chunxiao, 1987- author.
2022
TL589.4
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Title Flying ad hoc networks : cooperative networking and resource allocation / Jingjing Wang, Chunxiao Jiang.
Author Wang, Jingjing.
ISBN 9789811688508 (electronic bk.)
9811688508 (electronic bk.)
9811688494
9789811688492
DOI https://doi.org/10.1007/978-981-16-8850-8
Publication Details Singapore : Springer, 2022.
Language English
Description 1 online resource.
Item Number 10.1007/978-981-16-8850-8 doi
Call Number TL589.4
Dewey Decimal Classification 629.133/39
Summary Relying on unmanned autonomous flight control programs, unmanned aerial vehicles (UAVs) equipped with radio communication devices have been actively developed around the world. Given their low cost, flexible maneuvering and unmanned operation, UAVs have been widely used in both civilian operations and military missions, including environmental monitoring, emergency communications, express distribution, even military surveillance and attacks, for example. Given that a range of standards and protocols used in terrestrial wireless networks are not applicable to UAV networks, and that some practical constraints such as battery power and no-fly zone hinder the maneuverability capability of a single UAV, we need to explore advanced communication and networking theories and methods for the sake of supporting future ultra-reliable and low-latency applications. Typically, the full potential of UAV networks functionalities can be tapped with the aid of the cooperation of multiple drones relying on their ad hoc networking, in-network communications and coordinated control. Furthermore, some swarm intelligence models and algorithms conceived for dynamic negotiation, path programming, formation flight and task assignment of multiple cooperative drones are also beneficial in terms of extending UAVs functionalities and coverage, as well as of increasing their efficiency. We call the networking and cooperation of multiple drones as the terminology flying ad hoc network (FANET), and there indeed are numerous new challenges to be overcome before the idespread of so-called heterogeneous FANETs. In this book, we examine a range of technical issues in FANETs, from physical-layer channel modeling to MAC-layer resource allocation, while also introducing readers to UAV aided mobile edge computing techniques.
Bibliography, etc. Note Includes bibliographical references.
Access Note Access limited to authorized users.
Source of Description Online resource; title from PDF title page (SpringerLink, viewed February 23, 2022).
Added Author Jiang, Chunxiao, 1987- author.
Series Wireless networks (Springer (Firm))
Available in Other Form Print version: 9789811688492
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Intro
Preface
Contents
Acronyms
1 Introduction of Flying Ad Hoc Networks
1.1 Basic Classification and Regulation of UAVs
1.2 Differences Between FANET, VANET, MANET, and AANET
1.3 Compelling Applications of FANET
References
2 Communication Channels in FANET
2.1 UAV Communication Channel Characteristics
2.1.1 UAV Link Budget
2.1.2 UAV Channel Fading
2.1.3 Channel Impulse Response and Metrics
2.2 UAV Communication Channel Modeling
2.2.1 Air-to-Ground Channels
2.2.1.1 A2G Channels in Urban Areas
2.2.1.2 Low-Altitude Channels in Cellular Networks

2.2.1.3 A2G Channels in Rural and Over-Water Areas
2.2.1.4 Evaporation Duct for Over Sea
2.2.1.5 Aircraft Shadowing in A2G Channels
2.2.2 Air-to-Air Channels
2.2.3 UAV-MIMO Channels
2.2.3.1 UAV-MIMO Channel Modeling
2.2.3.2 Antenna Diversity
2.2.3.3 Spatial Multiplexing
2.3 Challenges and Open Issues
2.3.1 Antennas for UAV Channel Measurement
2.3.2 Channels of UAV Applications in IoT and 5G
2.3.3 Channels in Vertical Industrial Applications
2.3.4 Channels of UAV FSO Communications
References
3 Seamless Coverage Strategies of FANET

3.1 Introduction of Seamless Coverage Problems
3.1.1 Problem Domain and Challenges
3.1.2 State of the Art
3.2 UAV Seamless Coverage Strategy for Dense Urban Areas
3.2.1 System Model
3.2.2 Cyclic Recharging and Reshuffling Optimization
3.2.2.1 UAV Power Model
3.2.2.2 CRRS Constraint
3.2.3 Problem Formulation
3.2.4 Distributed Particle Swarm Optimization Aided Solution
3.2.4.1 Analysis and Simplification
3.2.4.2 Distributed-PSO Algorithm Design
3.2.4.3 Algorithmic Convergence Analysis
3.2.4.4 Algorithmic Complexity Analysis
3.2.5 Simulation Results

3.2.6 Conclusions
3.3 UAV Seamless Coverage Strategy for QoS-Guaranteed IoT
3.3.1 System Model
3.3.2 Problem Formulation
3.3.3 Block Coordinate Descent Based Joint Optimization
3.3.3.1 Node Assignment Scheduling
3.3.3.2 UAV Trajectory Planning
3.3.3.3 UAV Transmit Power Control
3.3.3.4 Algorithmic Architecture and Convergence Analysis
3.3.4 Simulation Results
3.3.4.1 Resulting Strategies
3.3.4.2 Energy Efficiency
3.3.4.3 Optimality Analysis
3.3.5 Conclusions
3.4 UAV Seamless Coverage Strategy for Minimum-Delay Placement
3.4.1 System Model

3.4.1.1 Physical Layer Model of the UAV-Enabled Network
3.4.1.2 Queuing Model and System Dynamics
3.4.1.3 ABS Placement Scheduling
3.4.2 Problem Formulation
3.4.3 Markov Decision Process Transformation
3.4.3.1 Constrained Markov Decision Process
3.4.3.2 The Lagrangian Approach
3.4.4 Backward Induction and R-Learning Based Optimization
3.4.4.1 Solution to the Problem in Case 1
3.4.4.2 Solution to the Problem in Case 2
3.4.4.3 Solution to the Problem in Case 3
3.4.4.4 Analysis of Computational Complexity
3.4.5 Simulation Results

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