Abstract

Predicting the future trajectories of ecological systems is increasingly important as the magnitude of anthropogenic perturbation of the earth systems grows. We distinguish between two types of predictability: the intrinsic or theoretical predictability of a system and the realized predictability that is achieved using available models and parameterizations. We contend that there are strong limits on the intrinsic predictability of ecological systems that arise from inherent characteristics of biological systems. While the realized predictability of ecological systems can be limited by process and parameter misspecification or uncertainty, we argue that the intrinsic predictability of ecological systems is widely and strongly limited by computational irreducibility. When realized predictability is low relative to intrinsic predictability, prediction can be improved through improved model structure or specification of parameters. Computational irreducibility, however, asserts that future states of the system cannot be derived except through computation of all of the intervening states, imposing a strong limit on the intrinsic or theoretical predictability. We argue that ecological systems are likely to be computationally irreducible because of the difficulty of pre-stating the relevant features of ecological niches, the complexity of ecological systems and because the biosphere can enable its own novel system states or adjacent possible. We argue that computational irreducibility is likely to be pervasive and to impose strong limits on the potential for prediction in ecology.

Highlights

  • Ecological systems are strongly impacted by anthropogenically induced perturbations such as global climate change and the spread of nonnative species (Beckage et al 2008, Stevens and Beckage 2009)

  • Are ecological systems fundamentally predictable? What are the limits to prediction in ecological systems? The assumption underlying efforts to predict ecological responses to anthropogenic perturbations is that their responses are, predictable

  • We believe that it is important to create a framework for understanding the potential for and limits to prediction in ecological systems

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Summary

Stuart Kauffman University of Vermont

Follow this and additional works at: https://scholarworks.uvm.edu/calsfac Part of the Climate Commons, Community Health Commons, Human Ecology Commons, Nature and Society Relations Commons, Place and Environment Commons, and the Sustainability Commons.

INTRODUCTION
COMPUTATIONAL IRREDUCIBILITY
ECOLOGICAL EXAMPLES
IMPLICATIONS FOR PREDICTION
SUMMARY
LITERATURE CITED

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