Register      Login
Animal Production Science Animal Production Science Society
Food, fibre and pharmaceuticals from animals
Shopping Cart: ( empty )
You are here: Home > Journals > AN > AN17360
RESEARCH ARTICLE
Contents Vol 59(6)

Insights to optimise marketing decisions on pig-grower farms

S. V. Rodríguez-Sanchez A , L. M. Pla-Aragones B C E and R. De Castro D
+ Author Affiliations
- Author Affiliations

A Graduate Program in Systems Engineering, Universidad Autónoma de Nuevo León, AP 111-F, Ciudad Universitaria San Nicolás de los Garza, NL, 66450, México.

B Department of Mathematics, University of Lleida, Campus Cappont, c./Jaume II, 73, 25001 Lleida, Spain.

C Agrotecnio Research Center, 25198 Lleida, Spain.

D Department of Business Organisation, Management and Product Design, University of Girona, Campus Montilivi, 17003 Girona, Spain.

E Corresponding author. Email: lmpla@matematica.udl.cat

Animal Production Science 59(6) 1126-1135 https://doi.org/10.1071/AN17360
Submitted: 31 May 2017  Accepted: 4 May 2018   Published: 27 August 2018

Abstract

Modern pig production in a vertically integrated company is a highly specialised and industrialised activity, requiring increasingly complex and critical decision-making. The present paper focuses on the decisions made on the pig-grower farms operating on an all-in–all-out management policy at the last stage of pig production. Based on a mixed-integer linear-programming model, an assessment for specific parameters to support marketing decisions on farms without individual weight control is made. The analysis of several key factors affecting the optimal marketing policy, such as transportation cost, when and how many pigs to deliver to the abattoir and weight homogeneity of the batch, served to gain insight into marketing decisions. The results confirmed that not just the feeding program, but also the grading price system, transportation and batch homogeneity have an enormous impact on the optimal marketing policy of fattening farms in a vertically integrated company. In addition, within the range of conditions considered, a time window of 4 weeks was deemed as optimal for delivering animals to the abattoir and the subsequent revenue was 15% higher than with traditional marketing rules.

Additional keywords: pig production, optimal slaughtering.


References

Backus G, Dijkhuizen A (2002) The future of the European pork chain. In ‘Swine conference 2002’, 14 September 2002, Saint Paul, Minnesota, USA. (Ed. AD Leman) pp. 8–11.

Balogh P, Ertsey I, Fenyves V, Nagy L (2009) Analysis and optimization regarding the activity of a Hungarian Pig Sales and Purchase Cooperation. Studies in Agricultural Economics 109, 35–54.

Boland MA, Preckel PV, Schinckel AP (1993) Optimal hog slaughter weights under alternative pricing systems. Journal of Agricultural and Applied Economics 25, 148–163.
Optimal hog slaughter weights under alternative pricing systems.Crossref | GoogleScholarGoogle Scholar |

Boys KA, Li N, Preckel PV, Schinckel AP, Foster KA (2007) Economic replacement of a heterogeneous herd. American Journal of Agricultural Economics 89, 24–35.

Burt O (1993) Decision rules for the dynamic animal feeding problem. American Journal of Agricultural Economics 75, 190–202.
Decision rules for the dynamic animal feeding problem.Crossref | GoogleScholarGoogle Scholar |

Castro R (2001) Optimització del procés productiu d’engreixament del porcí. Un enfocament operatiu. PhD Thesis, University of Girona, Spain. Available at http://www.tdx.cat/bitstream/handle/10803/7710/trcv.pdf [Verified 10 August 2016]

Dominiak KN, Kristensen AR (2017) Prioritizing alarms from sensor-based detection models in livestock production: a review on model performance and alarm reducing methods. Computers and Electronics in Agriculture 133, 46–67.
Prioritizing alarms from sensor-based detection models in livestock production: a review on model performance and alarm reducing methods.Crossref | GoogleScholarGoogle Scholar |

Fernández J, Fabrega E, Soler J, Tibau J, Ruiz JL, Puigvert X, Manteca X (2011) Feeding strategy in group-housed growing pigs of four different breeds. Applied Animal Behaviour Science 134, 109–120.
Feeding strategy in group-housed growing pigs of four different breeds.Crossref | GoogleScholarGoogle Scholar |

Jørgensen E (1993) The influence of weighing precision on delivery decision in slaughter pig production. Acta Agriculturae Scandinavica Section A-Animal Science 43, 181–189.

Khamjan S, Piewthongngam K, Pathumnakul S (2013) Pig procurement plan considering pig growth and size distribution. Computers & Industrial Engineering 64, 886–894.
Pig procurement plan considering pig growth and size distribution.Crossref | GoogleScholarGoogle Scholar |

Kristensen A, Nielsen L, Nielsen M (2012) Optimal slaughter pig marketing with emphasis on information from on-line live weight assessment. Livestock Science 145, 95–108.
Optimal slaughter pig marketing with emphasis on information from on-line live weight assessment.Crossref | GoogleScholarGoogle Scholar |

Kure H (1997) Slaughter pig marketing management: utilization of highly biased herd-specific data. In ‘Proceedings of the first European conference for information technology in agriculture, 15–18 June, Copenhagen’. (Eds H Kure, I Thysen, AR Kristensen) pp. 465–470.

L’Observatori del Porcí (2015) Annual report 2015. Grupo de Gestión Porcina Departamento de Producción Animal, Universidad de Lleida, Spain. Available at http://agricultura.gencat.cat/web/.content/de_departament/de02_estadistiques_observatoris/08_observatoris_sectorials/04_observatori_porci/informes_anuals/fitxers_estatics/CAT_Informe-sector-porci-2015_20160814.pdf [Verified 16 June 2016]

Li N, Preckel P, Foster K, Schinckel A (2003) Analysis of economically optimal nutrition and marketing strategies for Paylean® usage in hog production. Journal of Agricultural and Resource Economics 28, 272–286.

Nadal-Roig E, Pla LM (2014) Multiperiod planning tool for multisite pig production systems. Journal of Animal Science 92, 4154–4160.
Multiperiod planning tool for multisite pig production systems.Crossref | GoogleScholarGoogle Scholar |

Nasirahmadi A, Edwards SA, Sturm B (2017) Implementation of machine vision for detecting behaviour of cattle and pigs. Livestock Science 202, 25–38.
Implementation of machine vision for detecting behaviour of cattle and pigs.Crossref | GoogleScholarGoogle Scholar |

Neethirajan S, Tuteja SK, Huang S-T, Kelton D (2017) Recent advancement in biosensors technology for animal and livestock health management. Biosensors & Bioelectronics 98, 398–407.
Recent advancement in biosensors technology for animal and livestock health management.Crossref | GoogleScholarGoogle Scholar |

Niemi JK (2006) A dynamic programming model for optimising feeding and slaughter decisions regarding fattening pigs. Agriculture and Food Science 15, 121
A dynamic programming model for optimising feeding and slaughter decisions regarding fattening pigs.Crossref | GoogleScholarGoogle Scholar |

Nils T, Kristensen AR, Jørgensen E (2005) A framework for decision support related to infectious diseases in slaughter pig fattening units. Agricultural Systems 85, 120–137.
A framework for decision support related to infectious diseases in slaughter pig fattening units.Crossref | GoogleScholarGoogle Scholar |

National Research Council (1998) ‘Nutrient requirements of swine.’ 10th rev. edn. (The National Academies Press: Washington, DC)

Ohlmann J, Jones P (2011) An integer programming model for optimal pork marketing. Annals of Operations Research 190, 271–287.
An integer programming model for optimal pork marketing.Crossref | GoogleScholarGoogle Scholar |

Perez C, de Castro R, Font i Furnols M (2009) The pork industry: a supply chain perspective. British Food Journal 111, 257–274.
The pork industry: a supply chain perspective.Crossref | GoogleScholarGoogle Scholar |

Pla LM, Rodriguez SV, Rebillas V (2013) A mixed integer linear programming model for optimal delivery of fattened pigs to the abattoir. Journal of Applied Operations Research 5, 164–175.

Pourmoayed R, Nielsen LR, Kristensen AR (2016) A hierarchical Markov decision process modelling feeding and marketing decisions of growing pigs. European Journal of Operational Research 250, 925–938.
A hierarchical Markov decision process modelling feeding and marketing decisions of growing pigs.Crossref | GoogleScholarGoogle Scholar |

Rijpkema WA, Hendrix EMT, Rossi R, van der Vorst JGAJ (2016) Application of stochastic programming to reduce uncertainty in quality-based supply planning of abattoirs. Annals of Operations Research Society 239, 613–624.
Application of stochastic programming to reduce uncertainty in quality-based supply planning of abattoirs.Crossref | GoogleScholarGoogle Scholar |

Rodríguez SV, Pla LM, Faulin J (2014) New opportunities in operation research to improve pork supply chain efficiency. Annals of Operations Research 219, 5–23.
New opportunities in operation research to improve pork supply chain efficiency.Crossref | GoogleScholarGoogle Scholar |

Schinckel A, Craig B (2002) Evaluation of alternative nonlinear mixed effects models of swine growth. The Professional Animal Scientist 18, 219–226.
Evaluation of alternative nonlinear mixed effects models of swine growth.Crossref | GoogleScholarGoogle Scholar |

Støier S, Larsen HD, Aaslyng MD, Lykke L (2016) Improved animal welfare, the right technology and increased business. Meat Science 120, 71–77.
Improved animal welfare, the right technology and increased business.Crossref | GoogleScholarGoogle Scholar |

Taylor DH (2006) Strategic consideration in the development of lean agri-food supply chains: a case study of the UK pork sector. Supply Chain Management 11, 271–280.
Strategic consideration in the development of lean agri-food supply chains: a case study of the UK pork sector.Crossref | GoogleScholarGoogle Scholar |