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Factors Affecting Perceived Improvements in EnvironmentalQuality from Precision Farming

Published online by Cambridge University Press:  28 April 2015

Sherry L. Larkin
Affiliation:
Department of Food and Resource Economics, University of Florida, Gainesville, FL
Larry Perruso
Affiliation:
Southeast Fisheries Science Center, National Marine Fisheries Service, Miami, FL
Michele C. Marra
Affiliation:
Department of Agricultural and Resource Economics, North Carolina State University, Raleigh, NC
Roland K. Roberts
Affiliation:
Department of Agricultural Economics, University of Tennessee, Knoxville, TN
Burton C. English
Affiliation:
Department of Agricultural Economics, University of Tennessee, Knoxville, TN
James A. Larson
Affiliation:
Department of Agricultural Economics, University of Tennessee, Knoxville, TN
Rebecca L. Cochran
Affiliation:
Department of Agricultural Economics, University of Tennessee, Knoxville, TN
Steven W. Martin
Affiliation:
Department of Agricultural Economics, Delta Research and Extension Center, Mississippi State University, Stoneville, MS

Abstract

This study identified the factors that influenced whether farmers in theSoutheastern United States perceived an improvement in environmental qualityfrom adopting precision farming technologies (PFTs). Farmers with largerfarms or higher yields were more likely to believe that they observedpositive externalities associated with PFTs. Farmers who found PFTsprofitable or who believed input reduction was important had higherprobabilities whereas those with higher incomes or who were more dependenton farm income were less likely to perceive such benefits. Interestingly,the importance of environmental quality and length of time using PFTs werenot found to affect the probability of perceiving an improvement inenvironmental quality.

Type
Articles
Copyright
Copyright © Southern Agricultural Economics Association 2005

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References

Batte, M.T., and Arnholt, M.W.. “Precision Farming Adoption and Use in Ohio: Case Studies of Six Leading-Edge Adopters.Computers and Electronics in Agriculture 38,2(February 2003): 125–39.10.1016/S0168-1699(02)00143-6Google Scholar
Cowan, T. Precision Agriculture and Site-specific Management: Current Status and Emerging Policy Issues. Congressional Research Service (CRS) Report RL30630, August 2000.Google Scholar
Cox, D.R., and Snell, E.J.. The Analysis of Binary Data, 2nd ed. London: Chapman and Hall, 1989.Google Scholar
Daberkow, S.G., and McBride, W.D.. “Farm and Operator Characteristics Affecting the Awareness and Adoption of Precision Agriculture Technologies in the U.S.Precision Agriculture 4,2(June 2003): 163–77.10.1023/A:1024557205871Google Scholar
Daberkow, S., Fernandez-Cornejo, J., and Padgitt, M.. “Precision Agriculture Adoption Continues to Grow.” Agricultural Outlook. Washington, DC: U.S. Department of Agriculture, Economic Research Service, November 2002, pp. 3538.Google Scholar
Fernandez-Cornejo, J., Daberkow, S., and McBride, W.D.. “Decomposing the Size Effect on the Adoption of Innovations: Agrobiotechnology and Precision Agriculture.AgBioForum 4,2(2001):124-36.Google Scholar
Griffin, T.W., Lowenberg-DeBoer, J., Lambert, D.M., Peone, J., Payne, T., and Daberkow, S.G.. “Adoption, Profitability, and Making Better Use of Precision Farming Data.” Staff Paper #04-06. Department of Agricultural Economics, Purdue University, June 2004.Google Scholar
Gunningham, N.Incentives to Improve Farm Management: EMS, Supply-Chains and Civil Society.” Paper presented to OECD Expert Workshop on Environmental Indicators, New Zealand, March 2004.Google Scholar
Hatfield, J.Precision Agriculture and Environmental Quality: Challenges for Research and Education.” The National Arbor Day Foundation. Internet site: www.arborday.org (Accessed July 2000).Google Scholar
Kennedy, P. A Guide to Econometrics, 3rd ed. Cambridge, MA: The MIT Press, 1992.Google Scholar
Khanna, M.Sequential Adoption of Site-Specific Technologies and Its Implications for Nitrogen Productivity: A Double Selectivity Model.American Journal of Agricultural Economics 83(Febraary 2001):3551.10.1111/0002-9092.00135Google Scholar
Lambert, D., and Lowenberg-DeBoer, J.. Precision Agriculture Profitability Review. Site-specific Management Center, School of Agriculture, Purdue University, September 2000.Google Scholar
Larson, W.E., Lamb, J.A., Khakural, B.R., Fergusen, R.B., and Rehm, G.W.. “Potential of Site-specific Management for Non-Point Environmental Protection.” The Site-Specific Management for Agricultural Systems, Madison, WI, 1997.Google Scholar
Lohr, L., Parker, T., and Higley, L.. “Farmers Risk Assessment for Voluntary Insecticide Reduction.Ecological Economics 30,1(July 1999): 121–30.10.1016/S0921-8009(98)00103-7Google Scholar
McBride, W.D., and Daberkow, S.G.. “Information and the Adoption of Precision Farming Technologies.Journal of Agribusiness 21,1 (Spring 2003):2138.Google Scholar
Napier, T.L., Robinson, J., and Tucker, M.. “Adoption of Precision Farming within Three Midwest Watersheds.Journal of Soil and Water Conservation 55(2000):135–41.Google Scholar
Nind, C.EMS and Land Valuation: The Potential for Land Valuation to Drive the Adoption of Environmental Management Systems in Agriculture.” RIRDC Publication No. 02/040. Rural Industries Research & Development Corporation, Department of Agriculture, Western Australia, May 2002.Google Scholar
Norton, G.W., and Swinton, S.M.. “Precision Agriculture: Global Prospects and Environmental Implications.” Tomorrow's Agriculture: Incentives, Institutions, Infrastructure and Innovations: Proceedings of the 24:h International Conference of Agricultural Economists, 2000. Peters, G.H. and Pingali, P., eds., pp. 269–86. London: Ashgate, 2001.Google Scholar
Roberts, R.K., Mahajanashetti, S.B., English, B.C., Larson, J.A., and Tyler, D.D.. “Variable Rate Nitrogen Application on Corn Fields: The Role of Spatial Variability and Weather.Journal of Agricultural and Applied Economics 34,1 (April 2002): 111–29.10.1017/S1074070800002182Google Scholar
Roberts, R.K., English, B.C., Larson, J.A., Cochran, R.L., Goodman, B., Larkin, S., Marra, M., Martin, S., Shurley, D., and Reeves, J.. “Adoption of Site-specific Information and Variable-Rate Technologies in Cotton Precision Farming.Journal of Agricultural and Applied Economics 36,1(April 2004): 143–58.10.1017/S107407080002191XGoogle Scholar
Swinton, S.M., and Lowenberg-DeBoer, J.. “Evaluating the Profitability of Site-specific Farming.” Journal of Production Agriculture 11(1998):439–46.10.2134/jpa1998.0439Google Scholar
Swinton, S.M., and Lowenberg-DeBoer, J.. “Global Adoption of Precision Agriculture Technologies: Who, When and Why?Third European Conference on Precision Agriculture. Montpellier, France: Agro Montpellier (ENSAM). (2001):557–62.Google Scholar
Wang, D., Prato, T., Qui, Z., Kitchen, N.F., and Sudduth, K.A.. “Economic and Environmental Evaluation of Variable Rate Nitrogen and Lime Application for Claypen Soil Fields.Precision Agriculture 4,1 (March 2003):3552.Google Scholar
Watkins, K.B., Lu, Y.C., and Huang, W.Y.. “Economic and Environmental Feasibility of Variable Rate Nitrogen Fertilizer Applications with Carry-Over Effects.Journal of Agricultural and Resource Economics 23(1998):401–26.Google Scholar
Zilberman, D., and Marra, M.C.. “Agricultural Externalities.” Agricultural and Environmental Resource Economics. Carlson, G.A., Zilberman, D., and Miranowski, J., eds. New York: Oxford University Press, 1993.Google Scholar