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SIMULATION MODEL OF EUROPEAN RED MITE POPULATION DYNAMICS DEVELOPED FOR A MINI-COMPUTER

Published online by Cambridge University Press:  31 May 2012

D. C. Herne  and
C. T. Lund
D. C. Herne
Affiliation:
Research Station, Agriculture Canada, Vineland Station, Ontario L0R 2E0
C. T. Lund
Affiliation:
Research Station, Agriculture Canada, Vineland Station, Ontario L0R 2E0
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Abstract

A simulation model is described for the population dynamics of the European red mite, Panonychus ulmi (Koch). The model incorporates the following features: (a) development rate is dependent on effective daily temperature; (b) division of each population component into distinct daily age classes; (c) emergence of individuals from each population component is dependent on a log-normal probability distribution, and a temperature related development vector to accumulate a measure of the temperature effect on development. Validation runs on a mini-computer in 1976 and 1977 adequately described actual population curves determined from daily orchard sampling. A model of this type which can be used with small computers should prove useful in investigating the main factors affecting the population dynamics, and control strategies for this and other pests.

Type
Articles
Information
The Canadian Entomologist , Volume 111 , Issue 4 , April 1979 , pp. 499 - 507
Copyright
Copyright © Entomological Society of Canada 1979

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References

Arnold, C. Y. 1960. Maximum-minimum temperatures as a basis for computing heat units. J. Am. Soc. hort. Sci. 74: 430435.Google Scholar
Berryman, A. A., and Pienaar, L. V.. 1974. Simulation: A powerful method of investigating the dynamics and management of insect populations. Environ. Ent. 3: 199207.CrossRefGoogle Scholar
Cagle, L. R. 1946. Life history of the European red mite. Tech. Bull. agric. Exp. Stn. 98. 19 pp.Google Scholar
Conway, G. R. 1970. Computer simulation as an aid to developing strategies for Anopheline control. Misc. Publ. ent. Soc. Am. 7: 181193.Google Scholar
Cranham, J. E. 1972. Influence of temperature on hatching of winter eggs of fruit-tree red spider mite, Panonychus ulmi (Koch). Ann. appl. Biol. 70: 119137.Google Scholar
Croft, B. A., Howes, J. L., and Welch, S. M.. 1976. A computer-based extension pest management delivery system. Environ. Ent. 5: 2034.CrossRefGoogle Scholar
Fulton, W. C. and Haynes, D. L.. 1977. The influence of population maturity on biological monitoring for pest management. Environ. Ent. 6: 174180.CrossRefGoogle Scholar
Hagley, E. A. C., Trottier, R., Herne, D. C., Hikichi, A., and Maitland, A.. 1978. Pest management in Ontario apple orchards. Agric. Can. Bull. Min. Supply Serv. Can. Cat. No. A52-50/1978. ISBN 0-662-10163-4. 32 pp.Google Scholar
Herne, D. H. C. and Trottier, R.. 1976. Relationship between hatching of eggs of European red mite and fruit bud development in Ontario peach and apple orchards. Proc. ent. Soc. Ont. 106: 48.Google Scholar
Hueck, H. J. 1953. The population dynamics of the fruit tree red spider (Metatetranychus ulmi (Koch) 1836, Acari, Tetranychidae) with special reference to the influence of DDT. Proefschr. Rijksuniv., Leiden, The Netherlands.Google Scholar
Rabbinge, R. 1976. Biological control of fruit-tree red spider mite. Wageningen, The Netherlands; Centre for Agricultural Publishing and Documentation, ISBN 90-220-0590-9. 228 pp.Google Scholar
Stinner, R. E., Rabb, R. L., and Bradley, J. R.. 1974. Population dynamics of Heliothis zea (Boddie) and H. virescens (F.) in North Carolina: A simulation model. Environ. Ent. 3: 163168.CrossRefGoogle Scholar