Browse > Article
http://dx.doi.org/10.5389/KSAE.2006.48.7.073

Optimal Poultry Litter Management through GIS-based Transportation Analysis System  

Kang, M.S. (Biosystems Engineering Department, 200 Corley Building, Auburn University)
Srivastava, P. (Biosystems Engineering Department, Auburn University)
Fulton, J.P. (Biosystems Engineering Department, Auburn University)
Tyson, T. (Biosystems Engineering Department, Auburn University)
Owsley, W.F. (Animal Science Department, Auburn University)
Yoo, K.H. (Biosystems Engineering Department, Auburn University)
Publication Information
Journal of The Korean Society of Agricultural Engineers / v.48, no.7, 2006 , pp. 73-86 More about this Journal
Abstract
Concentrated poultry production in the State of Alabama, U.S.A. results in excessive poultry litter. Application of poultry litter to pastures and row crops serves as a cheap alternative to commercial fertilizer. However, over the years, poultry litter application to perennial forage crops in the Appalachian Plateau region of North Alabama has resulted in phosphorus (P) buildup in soils. Phosphorus index (P-index) and comprehensive nutrient management plans (CNMP) are often used as a best management practice (BMP) for proper land application of litter. Because nutrient management planning is often not done for small animal feeding operations (AFOs), and also because, in case of excess litter, litter transportation infrastructure has not been developed, over application of poultry litter to near by area is a common practice. To alleviate this problem, optimal poultry litter management and transportation infrastructure needs to be developed. This paper presents a methodology to optimize poultry litter application and transportation through efficient nutrient management planning and transportation network analysis. The goal was accomplished through implementation of three important modules, a P-Index module, a CNMP module, and a transportation network analysis module within ArcGIS, a Geographic Information System (GIS). The CNMP and P-Index modules assist with land application of poultry litter at a rate that is protective of water quality, while the transportation network analysis module helps transport excess litter to areas requiring litter in the Appalachian Plateau and Black Belt (a nutrient-deficient area) regions. Once fully developed and implemented, such a system will help alleviate water quality problems in the Appalachian Plateau region and poor soil fertility problems in the Black Belt region by optimizing land application and transportation. The utility of the methodology is illustrated through a hypothetical case study.
Keywords
Poultry litter; Broiler litter; Nutrient management; Network analysis; Geographic information system; Transportation; Optimization;
Citations & Related Records
Times Cited By KSCI : 1  (Citation Analysis)
연도 인용수 순위
1 Carpenter. S. R.. N. F. Caraco, D. L. Correll. R. W. Howarth. A. N. Sharpley. and V. H. Smith. 1998. Nonpoint Pollution of Surface Waters with Phosphorus and Nitrogen. Ecol. Appl, 8: 559-568   DOI   ScienceOn
2 Daniel. T. C.. A. N. Sharpley. and J. L. Lemunyon. 1998. Agricultural phosphorus and eutrophication: a symposium overview. J. Environ. Qual. 27: 251-257
3 USDA National Agricultural Statistics Service (USDA-NASS). 2005. Alabama Agricultural Statistics Bulletin 47: Poultry Review 2005. USDA national Agricultural Statistics Service Alabama Field Office: 39-42
4 Beuthe, M., B. Jourquin, J-F. Geerts. and C.K.N. Ha. 2001. Freight Transportation Demand Elasticities: A Geographic Multimodal Transportation Network Analysis. Transportation Research Part E 37: 253-266   DOI   ScienceOn
5 McKinley, B., M. Broome, and L. Oldham. 2000. Poultry Nutrient Management Through Livestock Feedstuffs. Mississippi State University Extension Service, M1146
6 Mitchell, C. C. and T. W. Tyson. 2000. Nutrient Management Planning for Small AFOs: Poultry Operations. Alabama Cooperative Extension System (ACES), Timely Information, ETP220-01-00: 1-14
7 Verma, A. and S. L. Dhingra. 2005. Optimal Urban Rail Transit Corridor Identification within Integrated Framework Using Geographical Information System. Journal of Urban Planning and Development, ASCE 131(2): 98-111   DOI   ScienceOn
8 Adams. J. F. and C. C. Mitchell. 2000. Soil test Nutrient Recommendations for Alabama Crops. Agronomy and Soils, College of Agriculture, Auburn University (http://www.ag.auburn.edu/agrn//croprecs/ NutrientRecslndex.html#crops)
9 Mitchell, C. C. and S. Tu. 2005. Long-Term Evaluation of Poultry Litter as a Source of Nitrogen for Cotton and Corn. Agronomy Journal, American Society of Agronomy 97: 399-407   DOI   ScienceOn
10 Bukenya, J. O., J. Befecadu, H. S. Jones. K. C. Reddy. and A. Baiyee-Moi. 1999. Economic Feasibility of Substituting Fresh Poultry Litter for Ammomium Nitrate in Cotton Production. The Annual Meetings of the Northeast Agricultural and Resource Economics Association
11 Koncz, N. A. and T. M. Adams. 2002. A Data Model for Multi-Dimensional Transportation Applications. Int. J. Geographical Information Science 16(6): 551-569   DOI   ScienceOn
12 Mitchell, C. C. and J. O. Donald. 1995. The value and use of poultry manures as fertilizer. Alabama Cooperative Extension System (ACES) Cir. No. ANR 244. Auburn University, AL
13 Bagley, C. P. and R. R. Evans. 1998. Poultry Litter as a Feed or Fertilizer in Livestock Operations. Mississippi State University Extension Service
14 Alabama Department Environment Management (ADEM). 1999. National pollutant discharge elimination system for owners and operator of animal feeding operations and concentrated animal feeding operations. Ala. Dep, Environ. Mgmt., Field Operations Div., Water Qual. Programs, Chapter 335-6-7. Montgomery, AL
15 Kingery, W. L., C. W. Wood, D. P. Delaney. J. C. Williams. and G. L. Mullins. 1994. Impact of Long-Term Land Application of Poultry Litter on Environmentally Related Soil Properties. J. Environ. Qual. 23: 139-147   DOI   ScienceOn
16 Miller, H. J. and S. L. Shaw. 2001. Geographic Information Systems for Transportation - Principles and Applications. Oxford University Press, Inc., New York, USA
17 ESRI. 2005. ArcGIS 9- ArcGIS Network Analyst Tutorial. 380 New York Street. Redl.ands, CA, USA
18 Moore, P. A., Jr. Moore. 1998. Best Management Practices for Poultry Manure Utilization that Enhance Agricultural Productivity and Reduce Pollution. pp. 89-24, In J. Hatfield and B. A. Stewart (ed.) Animal Waste Utilization: Effective use of manure as a soil resource, Ann Arbor Press, Chelsea, ME
19 USDA Natural Resources Conservation Service (USDA-NRCS). 2001. Phosphorus Index for Alabama: A Planning Tool to Assess & Manage P Movement. USDA Natural Resources Conservation Service, Agronomy Technical Note (AL-72), Auburn, Alabama
20 Binford. G. D. Hansen. and B. Malone. 2001. Poultry Litter: resource or Waste-, Nutrient Management Notes. Delaware Nutrient Management Program 2(3)
21 Han, K., S. Minty, and A. Clayton. 2003. Developing Geographic Information Systems Platforms for Multi-jurisdictional Transportation Analysis: Framework and Techniques for Spatial Data Sharing, Can. J. Civ. Eng. 30: 808-818
22 Cabrera. M. L. and J. T. Sims. 2000. Beneficial Use of Poultry By-Products: Challenges and Opportunities: 425-450. In J. F. Power and W. A. Dick (ed.) Land Application of Agriculture. Industrial, and Municipal By-Products. SSSA Book Ser. 6. SSSA, Madison. WI
23 Naber, E. C. and E. C., A. J. Bermudez. 1998. The Ohio State University Poultry Manure Management and Utilization Problem and Opportunities. Extension Bulletin 804
24 Ritter, F. W. 2000. Potential Impact of Land Application of By-Products on Ground and Surface Water Quality: 263-288. In J. F. Power and W. A. Dick (ed.) Land Application of Agriculture, Industrial, and Municipal By-Products, SSSA Book Ser. 6, SSSA, Madison, WI
25 Suh, K., J. J. Lee, Y. M. Huh, H. J. Kim, and H. J. Yi. 2004. Development of An Optimal Routes Selection Model Considering Price Characteristics of Agricultural Products. Journal of The Korean Society of Agricultural Engineers 46(1): 121-131   과학기술학회마을   DOI   ScienceOn