Joint Communication–Motion Planning in Networked Robotic Systems

Zhang, Zixuan; Zhang, Bo; Wu, Yunlong

doi:10.3390/app12126261

Applied Sciences

2022

DOI: 10.3390/app12126261

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Joint Communication–Motion Planning in Networked Robotic Systems

Zixuan Zhang

Bo Zhang²,

Yunlong Wu³

Abstract: In the recent decade, many research efforts in robotic society have considered motion planning for maintaining connectivity in networked robotic system (NRS) by exploiting robotic autonomous mobility. On the other hand, cognitive radio (CR) in the communication society aims at fully exploiting the spectrum in a wireless network, while the motion planning is seldom considered, as a wireless device itself may not decide where to go. In this article, joint communication–motion planning (JCMP) is proposed to boost… Show more

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Cited by 2 publications

References 19 publications

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Optimization of Mobile Robotic Relay Operation for Minimal Average Wait Time

Hurst

Mostofi

2023

IEEE Trans. Wireless Commun.

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This paper studies the use of a multi-attribute auction in a communication system to bring about efficient relaying in a non-cooperative setting. We consider a system where a source seeks to offload data to an access point (AP) while balancing both the timeliness and energy-efficiency of the transmission. A deep fade in the communication channel (due to, e.g., a line-of-sight blockage) makes direct communication costly, and the source may alternatively rely on non-cooperative UEs to act as relays. We propose a multi-attribute auction to select a UE and to determine the duration and power of the transmission, with payments to the UE taking the form of energy sent via wireless power transfer (WPT). The quality of the channel from a UE to the AP constitutes private information, and bids consist of a transmission time and transmission power. We show that under a second-preferredoffer auction, truthful bidding by all candidate UEs forms a Nash Equilibrium. However, this auction is not incentive compatible, and we present a modified auction in which truthful bidding is in fact a dominant strategy. Extensive numerical experimentation illustrates the efficacy of our approach, which we compare to a cooperative baseline. We demonstrate that with as few as two candidates, our improved mechanism leads to as much as a 76 % reduction in energy consumption, and that with as few as three candidates, the transmission time decreases by as much as 55 %. Further, we see that as the number of candidates increases, the performance of our mechanism approaches that of the cooperative baseline. Overall, our findings highlight the potential of multi-attribute auctions to enhance the efficiency of data transfer in non-cooperative settings.

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Optimization of Mobile Robotic Relay Operation for Minimal Average Wait Time

Hurst

Mostofi

2023

IEEE Trans. Wireless Commun.

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Communication-Topology-preserving Motion Planning: Enabling Static Routing in UAV Networks

Huang,

Wu,

et al. 2023

ACM Trans. Sen. Netw.

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Unmanned Aerial Vehicle (UAV) swarm offers extended coverage and is a vital solution for many applications. A key issue in UAV swarm control is to cover all targets while maintaining connectivity among UAVs, referred to as a multi-target coverage problem. With existing dynamic routing protocols, the flying ad hoc network suffers outdated and incorrect route information due to frequent topology changes. This might lead to failures of time-critical tasks. One mitigation solution is to keep the physical topology unchanged, thus maintaining a fixed communication topology and enabling static routing. However, keeping physical topology unchanged may sacrifice the coverage. In this article, we propose to maintain a fixed communication topology among UAVs, which allows certain changes in physical topology, so that to maximize the coverage. We develop a distributed motion planning algorithm for the online multi-target coverage problem with the constraint of keeping communication topology intact. As the communication topology needs to be timely updated when UAVs leave or arrive at the swarm, we further design a topology-management protocol. Experimental results from the ns-3 simulator show that under our algorithms, UAV swarms of different sizes achieve significantly improved delay and loss ratio, efficient coverage, and rapid topology update.

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Joint Communication–Motion Planning in Networked Robotic Systems

Cited by 2 publications

References 19 publications

Optimization of Mobile Robotic Relay Operation for Minimal Average Wait Time

Optimization of Mobile Robotic Relay Operation for Minimal Average Wait Time

Communication-Topology-preserving Motion Planning: Enabling Static Routing in UAV Networks

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