On control under communicaiton constraints in autonomous multi-robot systems

Multi-robot systems have important applications, such as space explorations, underwater missions, and surveillance operations. In most of these cases robots need to exchange data through communication. Limitations in the communication system however impose constraints on the design of coordination s...

Full description

Bibliographic Details
Main Author: Speranzon, Alberto
Format: Others
Language:English
Published: KTH, Signaler, sensorer och system 2004
Subjects:
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-570
http://nbn-resolving.de/urn:isbn:91-7283-885-X
id ndltd-UPSALLA1-oai-DiVA.org-kth-570
record_format oai_dc
spelling ndltd-UPSALLA1-oai-DiVA.org-kth-5702013-01-08T13:10:59ZOn control under communicaiton constraints in autonomous multi-robot systemsengSperanzon, AlbertoKTH, Signaler, sensorer och systemStockholm : Signaler, sensorer och system2004Signal processingSignalbehandlingMulti-robot systems have important applications, such as space explorations, underwater missions, and surveillance operations. In most of these cases robots need to exchange data through communication. Limitations in the communication system however impose constraints on the design of coordination strategies. In this thesis we present three papers on cooperative control problems in which different communication constraints are considered. The first paper describes a rendezvous problem for a team of robots that exchanges position information through communication. A local control law for each robot should steer the team to a common meeting point when communicated data are quantized. The robots are not equipped with any sensors so the positions of other teammates are not measured. Two different types of quantized communication are considered: uniform and logarithmic. Logarithmic quantization is often preferable since it requires that fewer bits are communicated compared to when uniform quantization is used. For a class of feasible communication topologies, control laws that solve the rendezvous problem are derived. A hierarchical control structure is proposed in the second paper, for modelling autonomous underwater vehicles employed in finding a minimum of a scalar field. The controller is composed of two layers. The upper layer is the team controller, which is modeled as discrete-event system. It generates waypoints based on the simplex search optimization algorithm. The waypoints are used as target points by the lower control layer, which continuously steers each vehicle from the current to the next waypoint. It is shown that the communication of measurements is needed at each step for the team controller to generate unique waypoints. A protocol is proposed to reduce the amount of data to be exchanged, motivated by that underwater communication is costly in terms of energy. In the third paper, a probabilistic pursuit{evasion game is considered as an example to study constrained communication in multi-robot systems. This system can be used to model search-and-rescue operations and multi-robot exploration. Communication protocols based on time-triggered and event-triggered synchronization schemes are considered. It is shown that by limiting the communication to events when the probabilistic map updated by the individual pursuer contains new information, as measured by a map entropy, the utilization of the communication link can be considerably improved compared to conventional time-triggered communication. Licentiate thesis, monographinfo:eu-repo/semantics/masterThesistexthttp://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-570urn:isbn:91-7283-885-XTrita-S3-REG., 1404-2150 ; 0403application/pdfinfo:eu-repo/semantics/openAccess
collection NDLTD
language English
format Others
sources NDLTD
topic Signal processing
Signalbehandling
spellingShingle Signal processing
Signalbehandling
Speranzon, Alberto
On control under communicaiton constraints in autonomous multi-robot systems
description Multi-robot systems have important applications, such as space explorations, underwater missions, and surveillance operations. In most of these cases robots need to exchange data through communication. Limitations in the communication system however impose constraints on the design of coordination strategies. In this thesis we present three papers on cooperative control problems in which different communication constraints are considered. The first paper describes a rendezvous problem for a team of robots that exchanges position information through communication. A local control law for each robot should steer the team to a common meeting point when communicated data are quantized. The robots are not equipped with any sensors so the positions of other teammates are not measured. Two different types of quantized communication are considered: uniform and logarithmic. Logarithmic quantization is often preferable since it requires that fewer bits are communicated compared to when uniform quantization is used. For a class of feasible communication topologies, control laws that solve the rendezvous problem are derived. A hierarchical control structure is proposed in the second paper, for modelling autonomous underwater vehicles employed in finding a minimum of a scalar field. The controller is composed of two layers. The upper layer is the team controller, which is modeled as discrete-event system. It generates waypoints based on the simplex search optimization algorithm. The waypoints are used as target points by the lower control layer, which continuously steers each vehicle from the current to the next waypoint. It is shown that the communication of measurements is needed at each step for the team controller to generate unique waypoints. A protocol is proposed to reduce the amount of data to be exchanged, motivated by that underwater communication is costly in terms of energy. In the third paper, a probabilistic pursuit{evasion game is considered as an example to study constrained communication in multi-robot systems. This system can be used to model search-and-rescue operations and multi-robot exploration. Communication protocols based on time-triggered and event-triggered synchronization schemes are considered. It is shown that by limiting the communication to events when the probabilistic map updated by the individual pursuer contains new information, as measured by a map entropy, the utilization of the communication link can be considerably improved compared to conventional time-triggered communication.
author Speranzon, Alberto
author_facet Speranzon, Alberto
author_sort Speranzon, Alberto
title On control under communicaiton constraints in autonomous multi-robot systems
title_short On control under communicaiton constraints in autonomous multi-robot systems
title_full On control under communicaiton constraints in autonomous multi-robot systems
title_fullStr On control under communicaiton constraints in autonomous multi-robot systems
title_full_unstemmed On control under communicaiton constraints in autonomous multi-robot systems
title_sort on control under communicaiton constraints in autonomous multi-robot systems
publisher KTH, Signaler, sensorer och system
publishDate 2004
url http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-570
http://nbn-resolving.de/urn:isbn:91-7283-885-X
work_keys_str_mv AT speranzonalberto oncontrolundercommunicaitonconstraintsinautonomousmultirobotsystems
_version_ 1716511126606315520