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@article{1260067d4aa44d8fae9ef065d3b04a91,
title = "Communication-free autonomous cooperative circumnavigation of unpredictable dynamic objects",
abstract = "Each of several speed-limited planar robots is driven by the acceleration, limited in magnitude. There is an unpredictable dynamic complex object, for example, a group of moving targets or an extended moving and deforming body. The robots should reach and then repeatedly trace a certain object-dependent moving and deforming curve that encircles the object and also achieve an effective self-deployment over it. This may be, for example, the locus of points at a desired mean distance or distance from a group of targets or a single extended object, respectively. Every robot has access to the nearest point of the curve and its own velocity and {"}sees{"}the objects within a finite sensing range. The robots have no communication facilities, cannot differentiate the peers, and are to be driven by a common law. Necessary conditions for the solvability of the mission are established. Under their slight and partly unavoidable enhancement, a new decentralized control strategy is proposed and shown to solve the mission, while excluding inter-robot collisions, and for the case of a steady curve, to evenly distribute the robots over the curve and to ensure a prespecified speed of their motion over it. These are justified via rigorous global convergence results and confirmed via computer simulations.",
keywords = "autonomous sensor-based reactive navigation, curve tracking, effective self-deployment, global convergence, multirobot scenario, unpredictably moving curve",
author = "Матвеев, {Алексей Серафимович} and Магеркин, {Валентин Вячеславович}",
year = "2021",
month = jun,
day = "9",
doi = "10.1017/s0263574721000667",
language = "English",
journal = "Robotica",
issn = "0263-5747",
publisher = "Cambridge University Press",

}

RIS

TY - JOUR

T1 - Communication-free autonomous cooperative circumnavigation of unpredictable dynamic objects

AU - Матвеев, Алексей Серафимович

AU - Магеркин, Валентин Вячеславович

PY - 2021/6/9

Y1 - 2021/6/9

N2 - Each of several speed-limited planar robots is driven by the acceleration, limited in magnitude. There is an unpredictable dynamic complex object, for example, a group of moving targets or an extended moving and deforming body. The robots should reach and then repeatedly trace a certain object-dependent moving and deforming curve that encircles the object and also achieve an effective self-deployment over it. This may be, for example, the locus of points at a desired mean distance or distance from a group of targets or a single extended object, respectively. Every robot has access to the nearest point of the curve and its own velocity and "sees"the objects within a finite sensing range. The robots have no communication facilities, cannot differentiate the peers, and are to be driven by a common law. Necessary conditions for the solvability of the mission are established. Under their slight and partly unavoidable enhancement, a new decentralized control strategy is proposed and shown to solve the mission, while excluding inter-robot collisions, and for the case of a steady curve, to evenly distribute the robots over the curve and to ensure a prespecified speed of their motion over it. These are justified via rigorous global convergence results and confirmed via computer simulations.

AB - Each of several speed-limited planar robots is driven by the acceleration, limited in magnitude. There is an unpredictable dynamic complex object, for example, a group of moving targets or an extended moving and deforming body. The robots should reach and then repeatedly trace a certain object-dependent moving and deforming curve that encircles the object and also achieve an effective self-deployment over it. This may be, for example, the locus of points at a desired mean distance or distance from a group of targets or a single extended object, respectively. Every robot has access to the nearest point of the curve and its own velocity and "sees"the objects within a finite sensing range. The robots have no communication facilities, cannot differentiate the peers, and are to be driven by a common law. Necessary conditions for the solvability of the mission are established. Under their slight and partly unavoidable enhancement, a new decentralized control strategy is proposed and shown to solve the mission, while excluding inter-robot collisions, and for the case of a steady curve, to evenly distribute the robots over the curve and to ensure a prespecified speed of their motion over it. These are justified via rigorous global convergence results and confirmed via computer simulations.

KW - autonomous sensor-based reactive navigation

KW - curve tracking

KW - effective self-deployment

KW - global convergence

KW - multirobot scenario

KW - unpredictably moving curve

UR - http://www.scopus.com/inward/record.url?scp=85108012638&partnerID=8YFLogxK

UR - https://www.mendeley.com/catalogue/a5bc4603-55ef-32fc-b3c7-59b76b368c68/

U2 - 10.1017/s0263574721000667

DO - 10.1017/s0263574721000667

M3 - Article

JO - Robotica

JF - Robotica

SN - 0263-5747

ER -

ID: 87315816