Book contents
- Frontmatter
- Contents
- Preface to the second edition
- Acknowledgments
- 1 The evolution, development, and modification of behavior
- 2 Variation and selection: kineses
- 3 Reflexes
- 4 Direct orientation and feedback
- 5 Operant behavior
- 6 Reward and punishment
- 7 Feeding regulation: a model motivational system
- 8 The optimal allocation of behavior
- 9 Choice: dynamics and decision rules
- 10 Foraging and behavioral ecology
- 11 Stimulus control and cognition
- 12 Stimulus control and performance
- 13 Molar laws
- 14 Time and memory, I
- 15 Time and memory, II
- 16 Template learning
- 17 Learning, I
- 18 Models of classical conditioning
- 19 Learning, II
- 20 Learning, III: procedures
- 21 Comparative cognition
- Index
8 - The optimal allocation of behavior
Published online by Cambridge University Press: 05 March 2016
- Frontmatter
- Contents
- Preface to the second edition
- Acknowledgments
- 1 The evolution, development, and modification of behavior
- 2 Variation and selection: kineses
- 3 Reflexes
- 4 Direct orientation and feedback
- 5 Operant behavior
- 6 Reward and punishment
- 7 Feeding regulation: a model motivational system
- 8 The optimal allocation of behavior
- 9 Choice: dynamics and decision rules
- 10 Foraging and behavioral ecology
- 11 Stimulus control and cognition
- 12 Stimulus control and performance
- 13 Molar laws
- 14 Time and memory, I
- 15 Time and memory, II
- 16 Template learning
- 17 Learning, I
- 18 Models of classical conditioning
- 19 Learning, II
- 20 Learning, III: procedures
- 21 Comparative cognition
- Index
Summary
The last chapter looked at feeding as a typical motivational system and examined the effects of things like palatability, diet dilution, and brain damage on the amount eaten and how hard a rat will work for food. These effects can all be summarized by a simple, static feedback model that assumes that animals regulate eating rate. Chapter 7 did not deal with interactions among multiple motivational systems, or with work schedules other than fixed ratio. It did not look at the regulation of activities like running or lever pressing that do not fit into the traditional motivational trinity – hunger, thirst, and sex. It turns out that all these omissions – motivational interactions, other schedules, and “weakly” motivated activities – can be handled in the same way; that is, by an extension of the regulatory approach.
Animals regulate their rate of eating. This is hardly controversial: Food is essential to life and failure to regulate food intake, at least over the long term, is life-threatening. But experiment suggests that animals do more than this: They regulate even over periods of time too short to pose metabolic dangers, perhaps because of the need to anticipate the possibility of deprivation in the future. Moreover, eating is not the only thing regulated in this way: Essentially, everything the animal does tends to occur at a certain rate, and animals will take action to restore this equilibrium rate if it is perturbed in some way. Before I can explore how this works, I need first to explain some basic economic concepts, such as utility (value) and marginal utility, and the idea of a constraint.
I begin with a typical experimental situation used to study multiple activities, then describe a fundamental constraint to which all behavior is subject: limitation of time. This leads to the pioneering work of David Premack (1925–2015), who first experimented with “weak” reinforcers and proposed a general definition of reinforcement based on this work. Optimality (economic) models of operant behavior derive, in large part, from his proposal. The remainder of the chapter describes the optimality approach and shows how a wide range of experimental results can be summarized by two principles: that the marginal utility of any activity decreases with the amount available (the principle of diminishing marginal utility), and that animals act to maximize utility, subject to constraints of time and reinforcement schedule.
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- Adaptive Behavior and Learning , pp. 205 - 241Publisher: Cambridge University PressPrint publication year: 2016
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