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Optimal Agricultural Pest Management with Multiple Species

Published online by Cambridge University Press:  10 May 2017

Michael E. Wetzstein
Affiliation:
Department of Agricultural Economics, University of Georgia, Athens
Philip Szmedra
Affiliation:
Department of Agricultural Economics, University of Georgia, Athens
Wesley N. Musser
Affiliation:
Department of Agricultural and Resource Economics, Oregon State University
Charlene C. J. Chou
Affiliation:
Department of Agricultural Economics, University of Georgia
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Extract

Increased concern for the environmental effects of pesticides has led to considerable interest in optimal management strategies for controlling pest populations affecting agricultural production. This issue has been considered by a number of researchers (Feder and Regev; Hall and Norgaard; Hueth and Regev; Lazarus and Swanson; Marsolan and Rudd; and Talpaz and Frisbie). With the exception of Feder and Regev, these studies considered only one species. This approach involves serious limitations since a grower is generally confronted with multiple species during the production period For example, insect prey-predator relationships may exist in the field (Feder and Regev). Alternatively, as an insect pest develops through a number of growth stages, multiple pests in effect exist (Reichelderfer and Bender).

Type
Research Article
Copyright
Copyright © 1985 Northeastern Agricultural and Resource Economics Association 

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Footnotes

This research was partially funded by USDA Agreement 58-319V-1-052X.

References

Anderson, J. R., Dillon, J. L. and Hardaker, B. Agricultural Decision Analysis, Iowa State University Press, 1977.Google Scholar
Feder, G. and Regev, U., “Biological Interactions and Environmental Effects in the Economics of Pest Control.” J. Env. Econ. and Man. 2 (1975):7591.Google Scholar
Hall, D. C. and Norgaard, R. B., “On the Timing and Application of Pesticides.” Amer. J. Agr. Econ. 55 (1973):198201.Google Scholar
Hueth, D. and Regev, U., “Optimal Agricultural Pest Management with Increasing Pest Resistance,Amer. J. Agr. Econ. 56 (1974):543551.Google Scholar
Larkin, P. A.Exploitation in a Type of Predator-Prey Relationship,” J. Fish. Res. B. Can. 23 (1966):349356.Google Scholar
Lazarus, W. F. and Swanson, E. R.Insecticide Use and Crop Rotation under Risk: Rootworm Control in Corn.” Amer. J. Agr. Econ. 65 (1983):738747.Google Scholar
Marsolan, N. and Rudd, W., “Modeling and Optimal Control of Insect Pest Populations,Math. Biosc. 30 (1976):244321.Google Scholar
Regev, V., Gutierrez, A. P. and Feder, G.Pests as a Common Property Resource: A Case Study of Alfalfa Weevil Control.” Amer. J. Agr. Econ. 58 (1976):186197.Google Scholar
Reichelderfer, K. H. and Bender, F. E., “Application of a Simulation Approach to Evaluating Alternative Methods for the Control of Agricultural Pests,Amer. J. Agr. Econ. 61 (1979):258267.Google Scholar
Shoemaker, C., “Optimization of Agricultural Pest Management. II. Formulation of a Control Model.” Math. Biosc. 17 (1973a):357365.Google Scholar
Shoemaker, C., “Optimization of Agricultural Pest Management. III. Results and Extensions of a Model.” Math. Biosc. 18 (1973b):122.Google Scholar
Talpaz, H. and Frisbie, R.An Advanced Method for Economic Threshold Determination: A Positive Approach.” S. J. Agr. Econ. 7 (1975):1926.Google Scholar
Talpaz, H., Curry, G. L., Sharper, P. J., DeMichele, D. W., and Frisbie, R. E.Optimal Pesticide Application for Controlling the Boll Weevil on Cotton.” Amer. J. Agr. Econ. 60 (1978):469–75.Google Scholar