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(1981)
Ecological consequences of foraging
W. Cooper (1995)
Foraging mode, prey chemical discrimination, and phylogeny in lizardsAnimal Behaviour, 50
(1979)
Niche segregation in desert lizards
(1991)
comparative history of lizard clades
E. Arnold (1989)
Towards a phylogeny and biogeography of the Lacertidae: relationships within an Old-World family of lizards derived from morphologyBulletin of the British Museum, Natural History. Zoology, 55
E. Arnold (1990)
Why do morphological phylogenies vary in quality ? An investigation based on the comparative history of lizard cladesProceedings of the Royal Society of London. B. Biological Sciences, 240
R. Bowker (1984)
Precision of Thermoregulation of Some African LizardsPhysiological Zoology, 57
R. Huey, E. Pianka (1981)
Ecological Consequences of Foraging ModeEcology, 62
R. Macarthur, E. Pianka (1966)
On Optimal Use of a Patchy EnvironmentThe American Naturalist, 100
R. Anderson (1993)
Analysis of Foraging in a Lizard, Cnemidophorus tigris: Salient Features and Environmental Effects
E. Arnold (1991)
Relationships of the South African lizards assigned to Aporosaura, Meroles and Pedioplanis (Reptilia : Lacertidae)Journal of Natural History, 25
G. Perry, I. Lampl, A. Lerner, D. Rothenstein, E. Shani, N. Sivan, Y. Werner (1990)
Foraging mode in lacertid lizards: variation and correlatesAmphibia-reptilia, 11
W. Magnusson, L. Paiva, R. Rocha, C. Franke, L. Kasper, A. Lima (1985)
The correlates of foraging mode in a community of brazilian lizardsHerpetologica, 41
J. Sites, J. Wright, L. Vitt (1994)
Biology of Whiptail lizards : genus CnemidophorusSystematic Biology, 43
(1994)
Feeding habits and reproductive biology of Australian pygopodid lizards
W. Cooper (1997)
Independent evolution of squamate olfaction and vomerolfaction and correlated evolution of vomerolfaction and lingual structureAmphibia-reptilia, 18
L. Vitt (1983)
Tail loss in lizards the significance of foraging and predator escape modesHerpetologica, 39
J. Webb, R. Shine (1994)
Feeding habits and reproductive biology of Australian pygopodid lizards of the genus AprasiaCopeia, 1994
R. Avery, A. Basker, C. Corti (1993)
"Scan" behaviour in Podarcis muralis: the use of vantage points by an actively foraging lizardAmphibia-reptilia, 14
(1961)
Structure as related to behavior in the organizations of populations of reptiles
R. McLaughlin (1989)
Search Modes of Birds and Lizards: Evidence for Alternative Movement PatternsThe American Naturalist, 133
(1996)
Variation and evolution of forked tongues
(1983)
Tail loss in lizards: the signi cance of foraging and predator escape
E. Drawer (1982)
ECOLOGICAL AND EVOLUTIONARY DETERMINANTS OF RELATIVE CLUTCH MASS IN LIZARDS
(1986)
A comparative approach to eld and laboratory studies in evolutionary biology
R. Avery (1993)
Experimental analysis of lizard pause-travel movement: pauses increase probability of prey captureAmphibia-reptilia, 14
E. Arnold, J. Burton, D. Ovenden (1980)
A Field Guide to the REPTILES AND AMPHIBIANS of Britain and Europe
W. Cooper, L. Vitt, J. Caldwell (1994)
Movement and substrate tongue flicks in phrynosomatid lizardsCopeia, 1994
R. Anderson, W. Karasov (1988)
Energetics of the Lizard Cnemidophorus Tigris and Life History Consequences of Food- Acquisition ModeEcological Monographs, 58
R. Avery (1991)
Temporal dynamics of a vigilance posture in the ruin lizard Podarcis siculaAmphibia-reptilia, 12
(1994)
vomerolfaction and lingual structure. Amphibia-Reptilia
(1994)
origin and its ecological and phylogenetic relationships
L. Taylor, E. Pianka (1986)
Ecology And Natural History Of Desert Lizards
W. Cooper, M. Whiting, J. Wyk (1997)
Foraging modes of cordyliform lizardsSouth African Journal of Zoology, 32
S. Wright (1992)
Adjusted P-values for simultaneous inferenceBiometrics, 48
W. Cooper (1997)
Correlated evolution of prey chemical discrimination with foraging, lingual morphology and vomeronasal chemoreceptor abundance in lizardsBehavioral Ecology and Sociobiology, 41
(1978)
Comparative diet of two Namib desert sand lizards ( Lacertidae )
(1994)
Chemical discrimination by tongue- icking in lizards: a review with hypotheses on
L. Vitt, J. Congdon (1978)
Body Shape, Reproductive Effort, and Relative Clutch Mass in Lizards: Resolution of a ParadoxThe American Naturalist, 112
W. Cooper (1994)
Chapter 5. Prey Chemical Discrimination, Foraging Mode, and Phylogeny
R. Pietruszka (1986)
Search tactics of desert lizards: how polarized are they?Animal Behaviour, 34
W. Cooper (1996)
Preliminary reconstructions of nasal chemosensory evolution in SquamataAmphibia-reptilia, 17
(1990)
Foraging mode
Bill Branch (1988)
Bill Branch's Field Guide to the Snakes and Other Reptiles of Southern Africa
AbstractMost lacertids are active foragers, but intrafamilial variation in foraging mode is greater than in most lizard families. We collected data on eight species of African lacertids to assess this variation. Both active and ambush foraging occurred within Pedioplanis and Meroles. Meroles ctenodactylus had a proportion of time moving and proportion of attacked prey detected while moving intermediate to those for actively foraging and ambushing Pedioplanis, but its number of movements per minute was exceptionally high. This species has a unique mixed foraging mode. Like active foragers, it seeks food by tongue-flicking while moving and spends a high percentage of the time moving. Like ambush foragers, it searches visually for prey during pauses between movements. Our findings confirm published data on four Kalahari lacertids. We discuss the history of foraging modes in advanced lacertids.
Amphibia-Reptilia – Brill
Published: Jan 1, 1999
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