Agric. Econ. - Czech, 2018, 64(7):316-327 | DOI: 10.17221/255/2016-AGRICECON

A study of production and harvesting planning for the chicken industryOriginal Paper

Peng-Sheng YOU1, Yi-Chih HSIEH*,2
1 Department of Business Administration, National Chia-Yi University, ChiaYi, Taiwan
2 Department of Industrial Management, National Formosa University, Huwei, Yunlin, Taiwan

To order to raise chickens for meat, chicken farmers must select an appropriate breed and determine how many broilers to raise in each henhouse. This study proposes a mathematical programming model to develop a production planning and harvesting schedule for chicken farmers. The production planning comprises the number of batches of chickens to be raised in each henhouse, the number of chicks to be raised for each batch, what breed of chicken to raise, when to start raising and the duration of the raising period. The harvesting schedule focuses on when to harvest and how many broilers to harvest each time. Our aim was to develop proper production and harvesting schedules that enable chicken farmers to maximise profits over a planning period. The problem is a highly complicated one. We developed a hybrid heuristic approach to address the issue. The computational results have shown that the proposed model can help chicken farmers to deal with the problems of chicken-henhouse assignment, chicken raising and harvesting, and may thus contribute to increasing profits. A case study of a chicken farmer in Yunlin County (Taiwan) was carried out to illustrate the application of the proposed model. Sensitivity analysis was also conducted to explore the influence of parameter variations.

Keywords: chicken business, harvesting schedule, mathematical programming, production planning

Published: July 31, 2018  Show citation

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YOU P, HSIEH Y. A study of production and harvesting planning for the chicken industry. Agric. Econ. - Czech. 2018;64(7):316-327. doi: 10.17221/255/2016-AGRICECON.
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    References

    1. Bjørndal T. (1988): Optimal harvesting of farmed fish. Marine Resource Economics, 5: 139-159. Go to original source...
    2. Coleno F.C., Duru M. (1999): A model to find and test decision rules for turnout date and grazing area allocation for a dairy cow system in spring. Agricultural Systems, 61: 151-164. Go to original source...
    3. Crosson P., O'Kiely P., O'Mara F.P., Wallace M. (2006): The development of a mathematical model to investigate Irish beef production systems. Agricultural Systems, 89: 349-370. Go to original source...
    4. Engle C.R. (1997): Optimal resource allocation by fish farmers in Rwanda. Journal of Applied Aquaculture, 7: 1-17. Go to original source...
    5. Engle C.R., Kumar G., Bouras D. (2010): The economic trade-offs between stocking fingerlings and stockers a mixed integer multi-stage programming approach. Aquaculture Economics and Management, 14: 315-331. Go to original source...
    6. Forsberg O.I. (1996): Optimal stocking and harvesting of size-structured farmed fish: A multi-period linear programming approach. Mathematics and Computers in Simulation, 42: 299-305. Go to original source...
    7. Gradiz L., Sugimoto A., Ujihara K., Fukuhara S., Kahi A.K., Hirooka H. (2007): Beef cow-calf production system integrated with sugarcane production: simulation model development and application in Japan. Agricultural Systems, 94: 750-762. Go to original source...
    8. Hern R.L. (1994): An optimal management model for intensive aquaculture an application in Atlantic salmon. Australian Journal of Agricultural and Resource Economics, 38: 31-47. Go to original source...
    9. Kristensen A.R., Søllested T.A. (2004): A sow replacement model using Bayesian updating in a three-level hierarchic Markov process II. Optimization model. Livestock Production Science, 87: 25-36. Go to original source...
    10. McCarthy N., Janvry A.D., Sadoulet E. (1998): Land allocation under dual individual-collective use in Mexico. Journal of Development Economics, 56: 239-264. Go to original source...
    11. Moghaddam K.S., DePuy G.W. (2011): Farm management optimization using chance constrained programming method. Computers and Electronics in Agriculture, 77: 229-237. Go to original source...
    12. Ohlmann J.W., Jones P.C. (2011): An integer programming model for optimal pork marketing. Annals of Operations Research, 190: 271-287. Go to original source...
    13. Pathumnakul S., Piewthongngam K., Khamjan S. (2009): Integrating a shrimp-growth function, farming skills information, and a supply allocation algorithm to manage the shrimp supply chain. Computers and Electronics in Agriculture, 66: 93-105. Go to original source...
    14. Plà-Aragonés L.M. (2005): A stochastic model for planning swine facilities. In: WSC '05 Proceedings of the 37th conference on Winter simulation, Orlando, Dec 4-7, 2015: 2378-2384. Go to original source...
    15. Rodríguez S.V., Albornoz V.M., Plà L.M. (2009): A twostage stochastic programming model for scheduling replacements in sow farms. TOP, 17: 171-189. Go to original source...
    16. Rodríguez-Sánchez S.V., Plà-Aragonés L.M., Albornoz V.M. (2012): Modeling tactical planning decisions through a linear optimization model in sow farms. Livestock Science, 143: 162-171. Go to original source...
    17. Rupasinghe J.W., Kennedy J.O.S. (2006): Optimal batch lengths for barramundi farming under seasonal variations: A dynamic programming approach. In: Proceedings of the Thirteenth Biennial Conference of the International Institute of Fisheries Economics & Trade, July 11-14, 2006, Portsmouth.
    18. Stygar M., Makulska J. (2010): Application of mathematical modelling in beef herd management - a review. Annals of Animal Science, 10: 333-348.
    19. Tian X., Leung P.S., Lee D.J. (2000): Size economies and optimal scheduling in shrimp production: results from a computer simulation model. Aquacultural Engineering, 22: 289-307. Go to original source...
    20. Villalba D., Ripoll G., Ruiz R., Bernués A. (2010): Longterm stochastic simulation of mountain beef cattle herds under diverse management strategies. Agricultural Systems, 103: 210-220. Go to original source...
    21. Wang J.K., Leiman J. (2000): Optimizing multi-stage shrimp production systems. Aquacultural Engineering, 22: 243-254. Go to original source...
    22. Yu R., Leung P.S. (2005): Optimal harvesting strategies for a multi-cycle and multi-pond shrimp operation: A practical network model. Mathematics and Computers in Simulation, 68: 339-354. Go to original source...
    23. Yu R., Leung P.S., Bienfang P. (2009): Modeling partial harvesting in intensive shrimp culture: A network-flow approach. European Journal of Operational Research, 193: 262-271. Go to original source...
    24. Yu R., Leung P.S., Bjørndal T. (2006): Optimal partial harvesting schedule for aquaculture operations. Marine Resource Economics, 21: 301-315. Go to original source...

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