Book contents
- Frontmatter
- Contents
- List of contributors
- 1 Introduction to wildlife population growth rates
- 2 Population growth rate and its determinants: an overview
- 3 Demographic, mechanistic and density-dependent determinants of population growth rate: a case study in an avian predator
- 4 Estimating density dependence in time-series of age-structured populations
- 5 Pattern of variation in avian population growth rates
- 6 Determinants of human population growth
- 7 Two complementary paradigms for analysing population dynamics
- 8 Complex numerical responses to top-down and bottom-up processes in vertebrate populations
- 9 The numerical response: rate of increase and food limitation in herbivores and predators
- 10 Populations in variable environments: the effect of variability in a species' primary resource
- 11 Trophic interactions and population growth rates: describing patterns and identifying mechanisms
- 12 Behavioural models of population growth rates: implications for conservation and prediction
- 13 Comparative ungulate dynamics: the devil is in the detail
- 14 Population growth rate as a basis for ecological risk assessment of toxic chemicals
- 15 Population growth rates: issues and an application
- References
- Glossary of abbreviations
- Author index
- Subject index
12 - Behavioural models of population growth rates: implications for conservation and prediction
Published online by Cambridge University Press: 20 May 2010
- Frontmatter
- Contents
- List of contributors
- 1 Introduction to wildlife population growth rates
- 2 Population growth rate and its determinants: an overview
- 3 Demographic, mechanistic and density-dependent determinants of population growth rate: a case study in an avian predator
- 4 Estimating density dependence in time-series of age-structured populations
- 5 Pattern of variation in avian population growth rates
- 6 Determinants of human population growth
- 7 Two complementary paradigms for analysing population dynamics
- 8 Complex numerical responses to top-down and bottom-up processes in vertebrate populations
- 9 The numerical response: rate of increase and food limitation in herbivores and predators
- 10 Populations in variable environments: the effect of variability in a species' primary resource
- 11 Trophic interactions and population growth rates: describing patterns and identifying mechanisms
- 12 Behavioural models of population growth rates: implications for conservation and prediction
- 13 Comparative ungulate dynamics: the devil is in the detail
- 14 Population growth rate as a basis for ecological risk assessment of toxic chemicals
- 15 Population growth rates: issues and an application
- References
- Glossary of abbreviations
- Author index
- Subject index
Summary
Introduction
A common justification of ecological research is that it allows predictions of the consequences of environmental change. There is a considerable need to be able to make realistic and justifiable predictions. With many environmental issues, such as genetically modified (GM) crops, climate change, habitat loss and exploitation, there is an urgent need to be able to produce quantified predictions. Such quantified predictions are essential for policy-makers if they are to consider ecological consequences within their framework of social and economic costs and benefits (Sutherland & Watkinson 2001).
Conservation biologists regularly carry out analyses (usually referred to as population-viability analyses) to evaluate the likelihood of a population persisting in the presence of existing or novel conditions (for reviews see Beissinger & Westphal (1998); Norris & Stillman (2002)). These are then often used to determine the conservation measures required to maintain the population, such as the release of additional individuals, a reduction in exploitation levels or the expansion of the available habitat (see Beissinger (1995); Green et al. (1996); Hiraldo et al. (1996); Root (1998) for a range of avian examples that illustrate these applications).
The basic elements of all population models are the population growth rate in the absence of interspecific competition, the extent of density dependence and the level of stochasticity (Burgman et al. 1992). However, in practice, population-viability analyses very rarely use measured parameters for density dependence, particularly when models are applied to the management of endangered species due to the paucity of data (see Green & Hirons (1991)).
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- Chapter
- Information
- Wildlife Population Growth Rates , pp. 225 - 248Publisher: Cambridge University PressPrint publication year: 2003
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