Modularity as a fish (Xenotoca eiseni) views it: conjoining geometric and nongeometric information for spatial reorientation.
about
Bonobos, chimpanzees, gorillas, and orang utans use feature and spatial cues in two spatial memory tasksSpatial reorientation by geometry in bumblebees.Navigation by environmental geometry: the use of zebrafish as a modelKindergarten children's sensitivity to geometry in mapsSpatial encoding in mountain chickadees: features overshadow geometry.Navigation as a source of geometric knowledge: young children's use of length, angle, distance, and direction in a reorientation task.Is there a geometric module for spatial orientation? Squaring theory and evidence.Two systems of spatial representation underlying navigation.Core knowledge of object, number, and geometry: a comparative and neural approach.25 years of research on the use of geometry in spatial reorientation: a current theoretical perspective.Fish intelligence, sentience and ethics.Avian cognition: examples of sophisticated capabilities in space and song.Place learning prior to and after telencephalon ablation in bamboo and coral cat sharks (Chiloscyllium griseum and Atelomycterus marmoratus).Potentiation and overshadowing between landmarks and environmental geometric cues.Adult but not aged C57BL/6 male mice are capable of using geometry for orientationMalleability in the development of spatial reorientation.Why size counts: children's spatial reorientation in large and small enclosures.Experimental setting affects the performance of guppies in a numerical discrimination task.Finding the best angle: pigeons (Columba livia) weight angular information more heavily than relative wall length in an open-field geometry task.Reorientation by geometric and landmark information in environments of different size.The orientation of homing pigeons (Columba livia f.d.) with and without navigational experience in a two-dimensional environment.Hippocampus and medial striatum dissociation during goal navigation by geometry or features in the domestic chick: An immediate early gene study.Goal orientation by geometric and feature cues: spatial learning in the terrestrial toad Rhinella arenarum.The shark Chiloscyllium griseum can orient using turn responses before and after partial telencephalon ablation.Growing in circles: rearing environment alters spatial navigation in fish.The geometric module in the rat: independence of shape and feature learning in a food finding task.Independent effects of geometry and landmark in a spontaneous reorientation task: a study of two species of fish.Activation of free sperm and dissociation of sperm bundles (spermatozeugmata) of an endangered viviparous fish, Xenotoca eiseni.Dissecting the geometric module: a sense linkage for metric and landmark information in animals' spatial reorientation.Visual discrimination of rotated 3D objects in Malawi cichlids (Pseudotropheus sp.): a first indication for form constancy in fishes.Spatial behavior in male and female crayfish (Orconectes rusticus): learning strategies and memory duration.Hippocampal formation is required for geometric navigation in pigeons.Influence of spatial environment on maze learning in an African mole-rat.Separate geometric and non-geometric modules for spatial reorientation: evidence from a lopsided animal brain.Sex differences in spatial cognition in an invertebrate: the cuttlefish.Spatial Reorientation: Effects of Verbal and Spatial Shadowing
P2860
Q33785587-6ADD05DD-E167-4295-A233-C6A2F6B5D6F5Q34279997-A397E86B-C3B2-4185-9716-F5515D3BE04EQ34536210-4F608BC6-8463-431A-8F39-BCCB0F1682E6Q35051360-B74F83BA-38FB-4531-BE48-EAB6F06D7846Q35101112-EC64EDBF-8DAE-41BC-8DE4-6784ADEBA823Q35836020-E26A0FB6-A602-4FEA-9556-B574F54D10A5Q36156781-A75C76B1-67CD-43A2-9F70-B559D9FF386CQ37770980-B6E81E33-A501-4CEE-A653-CBC7EEA2C7BDQ37980234-271C2DE9-1B65-4468-B039-4B9BEC188D06Q38086097-88A62268-DBB5-4E94-8738-A3F71A23D754Q38221307-15DDCCD9-ACED-47F1-B4B3-B064C26E5D65Q38564522-AD97EDE6-E844-457D-8BA4-BEF184B075A1Q39335172-A5A76237-B48F-42C1-9C56-C84C68B5AFF3Q42036523-50290F75-D506-4EF9-B42E-45DA8614C941Q42554630-99AD3AF8-C566-414C-B85E-6C0D151632FEQ44889706-6FDBE675-8B21-49D3-9014-4F3C31C76203Q45720080-BE69AC68-2C46-443D-B94A-0743024AD64EQ46486505-FC4F8210-4079-4AD3-82E0-29D7147429FCQ47355423-75B86BA2-B982-4267-9AFE-6E806DC49CF3Q47373736-8ABE276E-40C3-4122-BBD4-B76766ABFFCFQ47411725-03F9A93D-7A85-45A2-8278-6F51AC083155Q47635605-62C62D2D-17DC-4447-9618-B4802C110D27Q47722093-B145FD33-73C6-4752-9849-C94A84502D66Q47842047-B21447F8-848E-4327-ACD9-AFF94E54CCA9Q48393864-3B06C92C-E6EE-4566-A0D2-47A2377DD7DDQ48501402-72CDC3D0-196B-4982-BF46-33413012D0E5Q48502087-01A80FA0-D62F-4B8B-916D-674A2A7DD22BQ49684298-B73AACE2-BEC5-49CC-8533-E74FE20E3635Q50477320-B9CE1B92-A5C4-4E40-AD30-014C5FBFA15AQ50725488-BDE70ED5-BB32-4D46-B675-72A0381EA201Q50790479-7A93F175-A3B5-44C2-BD53-C2E7ABA823D9Q50792211-73E6D1B6-B162-4E56-AF00-8EC62E437639Q50955237-15D49C43-5BC1-445B-938F-CDFBAFACDECFQ51941798-E4CA7C59-CFA2-4B0C-9AD1-D107D38CE6A1Q51956298-FF9AFE5E-9F51-42C0-9E09-A83533CE7000Q58585309-BBD299BC-94FF-46D0-91CD-828C0A584A10
P2860
Modularity as a fish (Xenotoca eiseni) views it: conjoining geometric and nongeometric information for spatial reorientation.
description
2003 nî lūn-bûn
@nan
2003年の論文
@ja
2003年学术文章
@wuu
2003年学术文章
@zh
2003年学术文章
@zh-cn
2003年学术文章
@zh-hans
2003年学术文章
@zh-my
2003年学术文章
@zh-sg
2003年學術文章
@yue
2003年學術文章
@zh-hant
name
Modularity as a fish (Xenotoca ...... ion for spatial reorientation.
@en
Modularity as a fish
@nl
type
label
Modularity as a fish (Xenotoca ...... ion for spatial reorientation.
@en
Modularity as a fish
@nl
prefLabel
Modularity as a fish (Xenotoca ...... ion for spatial reorientation.
@en
Modularity as a fish
@nl
P1476
Modularity as a fish (Xenotoca ...... ion for spatial reorientation.
@en
P2093
Valeria Anna Sovrano
P304
P356
10.1037/0097-7403.29.3.199
P577
2003-07-01T00:00:00Z