Message Delivery in the Plane by Robots with Different Speeds

Jared Coleman; Evangelos Kranakis; Danny Krizanc; Oscar Morales Ponce

doi:10.1007/978-3-030-91081-5_20

Message Delivery in the Plane by Robots with Different Speeds

Jared Coleman
, Evangelos Kranakis
, Danny Krizanc
, Oscar Morales Ponce

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Abstract

We study a fundamental cooperative message-delivery problem on the plane. Assume $n$ robots which can move in any direction, are placed arbitrarily on the plane. Robots each have their own maximum speed and can communicate with each other face-to-face (i.e., when they are at the same location at the same time). There are also two designated points on the plane, $S$ (the source) and $D$ (the destination). The robots are required to transmit the message from the source to the destination as quickly as possible by face-to-face message passing. We consider both the offline setting where all information (the locations and maximum speeds of the robots) are known in advance and the online setting where each robot knows only its own position and speed along with the positions of $S$ and $D$. In the offline case, we discover an important connection between the problem for two-robot systems and the well-known Apollonius circle which we employ to design an optimal algorithm. We also propose a $\sqrt 2$ approximation algorithm for systems with any number of robots. In the online setting, we provide an algorithm with competitive ratio $\frac 17 \left( 5+ 4 \sqrt{2} \right)$ for two-robot systems and show that the same algorithm has a competitive ratio less than $2$ for systems with any number of robots. We also show these results are tight for the given algorithm. Finally, we give two lower bounds (employing different arguments) on the competitive ratio of any online algorithm, one of $1.0391$ and the other of $1.0405$.

Original language	English
Title of host publication	Stabilization, Safety, and Security of Distributed Systems - 23rd International Symposium, SSS 2021, Proceedings
Editors	Colette Johnen, Elad Michael Schiller, Stefan Schmid
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	305-319
Number of pages	15
ISBN (Print)	9783030910808
DOIs	https://doi.org/10.1007/978-3-030-91081-5_20
State	Published - 2021
Externally published	Yes
Event	23rd International Symposium on Stabilization, Safety, and Security of Distributed Systems, SSS 2021 - Virtual, Online Duration: Nov 17 2021 → Nov 20 2021

Publication series

Name	Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)
Volume	13046 LNCS
ISSN (Print)	0302-9743
ISSN (Electronic)	1611-3349

Conference

Conference	23rd International Symposium on Stabilization, Safety, and Security of Distributed Systems, SSS 2021
City	Virtual, Online
Period	11/17/21 → 11/20/21

ASJC Scopus Subject Areas

Theoretical Computer Science
General Computer Science

Keywords

Delivery
Face-to-Face
Plane
Pony express
Robot
Speed

Access to Document

10.1007/978-3-030-91081-5_20

2109.12185v1

Cite this

Coleman, J., Kranakis, E., Krizanc, D., & Ponce, O. M. (2021). Message Delivery in the Plane by Robots with Different Speeds. In C. Johnen, E. M. Schiller, & S. Schmid (Eds.), Stabilization, Safety, and Security of Distributed Systems - 23rd International Symposium, SSS 2021, Proceedings (pp. 305-319). (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics); Vol. 13046 LNCS). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-030-91081-5_20

Message Delivery in the Plane by Robots with Different Speeds. / Coleman, Jared; Kranakis, Evangelos; Krizanc, Danny et al.
Stabilization, Safety, and Security of Distributed Systems - 23rd International Symposium, SSS 2021, Proceedings. ed. / Colette Johnen; Elad Michael Schiller; Stefan Schmid. Springer Science and Business Media Deutschland GmbH, 2021. p. 305-319 (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics); Vol. 13046 LNCS).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Coleman, J, Kranakis, E, Krizanc, D & Ponce, OM 2021, Message Delivery in the Plane by Robots with Different Speeds. in C Johnen, EM Schiller & S Schmid (eds), Stabilization, Safety, and Security of Distributed Systems - 23rd International Symposium, SSS 2021, Proceedings. Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics), vol. 13046 LNCS, Springer Science and Business Media Deutschland GmbH, pp. 305-319, 23rd International Symposium on Stabilization, Safety, and Security of Distributed Systems, SSS 2021, Virtual, Online, 11/17/21. https://doi.org/10.1007/978-3-030-91081-5_20

Coleman J, Kranakis E, Krizanc D, Ponce OM. Message Delivery in the Plane by Robots with Different Speeds. In Johnen C, Schiller EM, Schmid S, editors, Stabilization, Safety, and Security of Distributed Systems - 23rd International Symposium, SSS 2021, Proceedings. Springer Science and Business Media Deutschland GmbH. 2021. p. 305-319. (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)). doi: 10.1007/978-3-030-91081-5_20

Coleman, Jared ; Kranakis, Evangelos ; Krizanc, Danny et al. / Message Delivery in the Plane by Robots with Different Speeds. Stabilization, Safety, and Security of Distributed Systems - 23rd International Symposium, SSS 2021, Proceedings. editor / Colette Johnen ; Elad Michael Schiller ; Stefan Schmid. Springer Science and Business Media Deutschland GmbH, 2021. pp. 305-319 (Lecture Notes in Computer Science (including subseries Lecture Notes in Artificial Intelligence and Lecture Notes in Bioinformatics)).

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title = "Message Delivery in the Plane by Robots with Different Speeds",

abstract = "We study a fundamental cooperative message-delivery problem on the plane. Assume \$n\$ robots which can move in any direction, are placed arbitrarily on the plane. Robots each have their own maximum speed and can communicate with each other face-to-face (i.e., when they are at the same location at the same time). There are also two designated points on the plane, \$S\$ (the source) and \$D\$ (the destination). The robots are required to transmit the message from the source to the destination as quickly as possible by face-to-face message passing. We consider both the offline setting where all information (the locations and maximum speeds of the robots) are known in advance and the online setting where each robot knows only its own position and speed along with the positions of \$S\$ and \$D\$. In the offline case, we discover an important connection between the problem for two-robot systems and the well-known Apollonius circle which we employ to design an optimal algorithm. We also propose a \$\textbackslash{}sqrt 2\$ approximation algorithm for systems with any number of robots. In the online setting, we provide an algorithm with competitive ratio \$\textbackslash{}frac 17 \textbackslash{}left( 5+ 4 \textbackslash{}sqrt\{2\} \textbackslash{}right)\$ for two-robot systems and show that the same algorithm has a competitive ratio less than \$2\$ for systems with any number of robots. We also show these results are tight for the given algorithm. Finally, we give two lower bounds (employing different arguments) on the competitive ratio of any online algorithm, one of \$1.0391\$ and the other of \$1.0405\$.",

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N2 - We study a fundamental cooperative message-delivery problem on the plane. Assume $n$ robots which can move in any direction, are placed arbitrarily on the plane. Robots each have their own maximum speed and can communicate with each other face-to-face (i.e., when they are at the same location at the same time). There are also two designated points on the plane, $S$ (the source) and $D$ (the destination). The robots are required to transmit the message from the source to the destination as quickly as possible by face-to-face message passing. We consider both the offline setting where all information (the locations and maximum speeds of the robots) are known in advance and the online setting where each robot knows only its own position and speed along with the positions of $S$ and $D$. In the offline case, we discover an important connection between the problem for two-robot systems and the well-known Apollonius circle which we employ to design an optimal algorithm. We also propose a $\sqrt 2$ approximation algorithm for systems with any number of robots. In the online setting, we provide an algorithm with competitive ratio $\frac 17 \left( 5+ 4 \sqrt{2} \right)$ for two-robot systems and show that the same algorithm has a competitive ratio less than $2$ for systems with any number of robots. We also show these results are tight for the given algorithm. Finally, we give two lower bounds (employing different arguments) on the competitive ratio of any online algorithm, one of $1.0391$ and the other of $1.0405$.

AB - We study a fundamental cooperative message-delivery problem on the plane. Assume $n$ robots which can move in any direction, are placed arbitrarily on the plane. Robots each have their own maximum speed and can communicate with each other face-to-face (i.e., when they are at the same location at the same time). There are also two designated points on the plane, $S$ (the source) and $D$ (the destination). The robots are required to transmit the message from the source to the destination as quickly as possible by face-to-face message passing. We consider both the offline setting where all information (the locations and maximum speeds of the robots) are known in advance and the online setting where each robot knows only its own position and speed along with the positions of $S$ and $D$. In the offline case, we discover an important connection between the problem for two-robot systems and the well-known Apollonius circle which we employ to design an optimal algorithm. We also propose a $\sqrt 2$ approximation algorithm for systems with any number of robots. In the online setting, we provide an algorithm with competitive ratio $\frac 17 \left( 5+ 4 \sqrt{2} \right)$ for two-robot systems and show that the same algorithm has a competitive ratio less than $2$ for systems with any number of robots. We also show these results are tight for the given algorithm. Finally, we give two lower bounds (employing different arguments) on the competitive ratio of any online algorithm, one of $1.0391$ and the other of $1.0405$.

KW - Delivery

KW - Face-to-Face

KW - Plane

KW - Pony express

KW - Robot

KW - Speed

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Y2 - 17 November 2021 through 20 November 2021

ER -

Message Delivery in the Plane by Robots with Different Speeds

Abstract

Publication series

Conference

ASJC Scopus Subject Areas

Keywords

Access to Document

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