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Mechanistic models must link the field and the lab

Published online by Cambridge University Press:  19 March 2019

Alasdair I. Houston  and
Gaurav Malhotra
Alasdair I. Houston
Affiliation:
School of Biological Sciences, University of Bristol, Bristol BS8 1TQ, UK. a.i.houston@bristol.ac.ukhttp://www.bristol.ac.uk/biology/people/alasdair-i-houston/index.html
Gaurav Malhotra
Affiliation:
School of Psychological Science, University of Bristol, Bristol BS8 1TU, UK. gaurav.malhotra@bristol.ac.ukhttp://www.bristol.ac.uk/expsych/people/gaurav-malhotra/index.html
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Abstract

In the theory outlined in the target article, an animal forages continuously, making sequential decisions in a world where the amount of food and its uncertainty are fixed, but delays are variable. These assumptions contrast with the risk-sensitive foraging theory and create a problem for comparing the predictions of this model with many laboratory experiments that do not make these assumptions.

Type
Open Peer Commentary
Information
Behavioral and Brain Sciences , Volume 42 , 2019 , e42
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Copyright
Copyright © Cambridge University Press 2019 

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References

Abreu, B. F. & Kacelnik, A. (1999) Energy budgets and risk-sensitive foraging in starlings. Behavioral Ecology 10:338–45.Google Scholar
Bateson, M. & Kacelnik, A. (1997) Starlings’ preference for predictable and unpredictable delays to food. Animal Behaviour 53(6):1129–42. https://doi.org/10.1006/anbe.1996.0388.Google Scholar
Bednekoff, P. A. & Houston, A. I. (1994) Dynamic models of mass-dependent predation, risk-sensitive foraging, and premigratory fattening in birds. Ecology 75(4):1131–40.Google Scholar
Fawcett, T. W., Fallenstein, B., Higginson, A. D., Houston, A. I., Mallpress, D. E., Trimmer, P. C. & McNamara, J. M. (2014) The evolution of decision rules in complex environments. Trends in Cognitive Sciences 18(3):153–61.Google Scholar
Higginson, A. D., Fawcett, T. W., Trimmer, P. C., McNamara, J. M. & Houston, A. I. (2012) Generalized optimal risk allocation: Foraging and antipredator behavior in a fluctuating environment. The American Naturalist 180(5):589603.Google Scholar
Houston, A. & McNamara, J. (1985) The choice of two prey types that minimises the probability of starvation. Behavioral Ecology and Sociobiology 17(2):135–41.Google Scholar
Houston, A. I. (1991) Risk-sensitive foraging theory and operant psychology. Journal of the Experimental Analysis of Behavior 56(3):585–89.Google Scholar
Houston, A. I. (2009) Flying in the face of nature. Behavioural Processes 80(3):295305.Google Scholar
Houston, A. I. & McNamara, J. M. (1989) The value of food: Effects of open and closed economies. Animal Behaviour 37:546–62.Google Scholar
Houston, A. I. & McNamara, J. M. (1999) Models of adaptive behaviour: An approach based on state. Cambridge University Press.Google Scholar
Houston, A. I., Welton, N. J. & McNamara, J. M. (1997) Acquisition and maintenance costs in the long-term regulation of avian fat reserves. Oikos 78:331–40.Google Scholar
Kacelnik, A. & Bateson, M. (1996) Risky theories: The effects of variance on foraging decisions. American Zoologist 36:402–34. https://doi.org/10.1093/icb/36.4.402.Google Scholar
Kacelnik, A. & El Mouden, C. (2013) Triumphs and trials of the risk paradigm. Animal Behaviour 86(6):1117–29.Google Scholar
Mallpress, D. E., Fawcett, T. W., Houston, A. I. & McNamara, J. M. (2015) Risk attitudes in a changing environment: An evolutionary model of the fourfold pattern of risk preferences. Psychological Review 122(2):364.Google Scholar
McNamara, J. M. (1996) Risk-prone behaviour under rules which have evolved in a changing environment. American Zoologist 36(4):484–95.Google Scholar
McNamara, J. M. & Houston, A. I. (1992) Risk-sensitive foraging: A review of the theory. Bulletin of Mathematical Biology 54(2–3):355–78.Google Scholar
Orduna, V. & Bouzas, A. (2004) Energy budget versus temporal discounting as determinants of preference in risky choice. Behavioural Processes 67:147–56. http://dx.doi.org/10.1016/j.beproc.2004.03.019.Google Scholar
Stephens, D. W. (1981) The logic of risk-sensitive foraging preferences. Animal Behaviour 29(2):628–29.Google Scholar