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dc.contributor.authorLihoreau, M
dc.contributor.authorRaine, NE
dc.contributor.authorReynolds, AM
dc.contributor.authorStelzer, RJ
dc.contributor.authorLim, KS
dc.contributor.authorSmith, AD
dc.contributor.authorOsborne, JL
dc.contributor.authorChittka, L
dc.date.accessioned2014-01-28T14:50:19Z
dc.date.issued2012
dc.date.issued2012
dc.identifier.urihttp://qmro.qmul.ac.uk/jspui/handle/123456789/5427
dc.descriptionPMCID: PMC3462218en_US
dc.descriptionThis is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
dc.description.abstractCentral place foragers, such as pollinating bees, typically develop circuits (traplines) to visit multiple foraging sites in a manner that minimizes overall travel distance. Despite being taxonomically widespread, these routing behaviours remain poorly understood due to the difficulty of tracking the foraging history of animals in the wild. Here we examine how bumblebees (Bombus terrestris) develop and optimise traplines over large spatial scales by setting up an array of five artificial flowers arranged in a regular pentagon (50 m side length) and fitted with motion-sensitive video cameras to determine the sequence of visitation. Stable traplines that linked together all the flowers in an optimal sequence were typically established after a bee made 26 foraging bouts, during which time only about 20 of the 120 possible routes were tried. Radar tracking of selected flights revealed a dramatic decrease by 80% (ca. 1500 m) of the total travel distance between the first and the last foraging bout. When a flower was removed and replaced by a more distant one, bees engaged in localised search flights, a strategy that can facilitate the discovery of a new flower and its integration into a novel optimal trapline. Based on these observations, we developed and tested an iterative improvement heuristic to capture how bees could learn and refine their routes each time a shorter route is found. Our findings suggest that complex dynamic routing problems can be solved by small-brained animals using simple learning heuristics, without the need for a cognitive map.
dc.format.extente1001392 - ?
dc.languageeng
dc.subjectAnimals
dc.subjectBees
dc.subjectFlight, Animal
dc.subjectFlowers
dc.subjectMotion
dc.subjectPhotography
dc.subjectPollination
dc.subjectRadar
dc.subjectVideo Recording
dc.titleRadar tracking and motion-sensitive cameras on flowers reveal the development of pollinator multi-destination routes over large spatial scales.
dc.typeJournal Article
dc.identifier.doi10.1371/journal.pbio.1001392
dc.relation.isPartOfPLoS Biol
dc.relation.isPartOfPLoS Biol
pubs.author-urlhttp://www.ncbi.nlm.nih.gov/pubmed/23049479
pubs.issue9
pubs.organisational-group/Queen Mary University of London
pubs.organisational-group/Queen Mary University of London/Faculty of Science & Engineering
pubs.organisational-group/Queen Mary University of London/Faculty of Science & Engineering/Biological and Chemical Sciences - Staff
pubs.publication-statusPublished
pubs.volume10


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