In order to be able to produce safe, uniform, cheap, environmentally- and welfare-friendly food products and market these products in an increasingly complex international agricultural market, livestock producers must have access to timely production related information. Especially the information related to feeding/nutritional issues is important, as feeding related costs are always significant part of variables costs for all types of livestock production. Therefore, automating the collection, analysis and use of production related information on livestock farms will be essential for improving livestock productivity in the future. Electronically-controlled livestock production systems with an information and communication technology (ICT) focus are required to ensure that information is collected in a cost effective and timely manner and readily acted upon on farms. New electronic and ICT related technologies introduced on farms as part of Precision Livestock Farming (PLF) systems will facilitate livestock management methods that are more responsive to market signals. The PLF technologies encompass methods for electronically measuring the critical components of the production system that indicate the efficiency of resource use, interpreting the information captured and controlling processes to ensure optimum efficiency of both resource use and livestock productivity. These envisaged real-time monitoring and control systems could dramatically improve production efficiency of livestock enterprises. However, further research and development is required, as some of the components of PLF systems are in different stages of development. In addition, an overall strategy for the adoption and commercial exploitation of PLF systems needs to be developed in collaboration with private companies. This article outlines the potential role PLF can play in ensuring that the best possible management processes are implemented on farms to improve farm profitability, quality of products, welfare of livestock and sustainability of the farm environment, especially as it related to intensive livestock species.

Precision Livestock Farming (PLF), precision feeding, control systems, automation, software-based technology, sensors, nutrition, pig farm

Adrian A M, Norwood S H, Mask P L. Producers' perceptions and attitudes toward precision agriculture technologies. Computers and Electronics in Agriculture, 2005; 48(3): 256-271.

Lewis T. Evolution of farm management information systems. Computers and Electronics in Agriculture, 1998; 19(3): 233-248.

Pedersen S M, Ferguson R B, Lark R M. A multinational survey of precision farming early adopters. Farm Management, 2001; 11(3): 147-162.

Thysen I. Agriculture in the information society. Journal of Agricultural Engineering Research, 2000; 76(3): 297-303.

Banhazi T M, Black J L. Precision livestock farming: A suite of electronic systems to ensure the application of best practice management on livestock farms. Australian Journal of Multi-disciplinary Engineering, 2009; 7(1): 1-14.

Cox S. Information technology: The global key to precision agriculture and sustainability. Computers and Electronics in Agriculture, 2002; 36(2-3): 93-111.

Lehr H. General conclusions and recommendations, in Multidisciplinary approach to acceptable and practical precision livestock farming for smes in europe and worldwide, Smith I G, Lehr H, Ed., 2011, European Commission: Halifax, UK. pp.179-188.

Maohua W. Possible adoption of precision agriculture for developing countries at the threshold of the new millennium. Computers and Electronics in Agriculture, 2001; 30(1-3): 45-50.

Niemi J K, Sevón-Aimonen M L, Pietola K, Stalder K J. The value of precision feeding technologies for grow-finish swine. Livestock Science, 2010; 129: 13-23.

Schmoldt D L. Precision agriculture and information technology. Computers and Electronics in Agriculture, 2001; 30(1-3): 5-7.

Zhang N, Wang M, Wang N. Precision agriculture--a worldwide overview. Computers and Electronics in Agriculture, 2002; 36(2-3): 113-132.

Schulze C, Spilke J, Lehner W. Data modeling for precision dairy farming within the competitive field of operational and analytical tasks. Computers and Electronics in Agriculture, 2007; 59(1-2): 39-55.

Stafford J V. Implementing precision agriculture in the 21st century. Journal of Agricultural Engineering Research, 2000; 76(3): 267-275.

Banhazi T M, Lehr H, Black J L, Crabtree H, Schofield P, Tscharke M, et al. Precision livestock farming: An international review of scientific and commercial aspects. International Journal of Agricultural and Biological Engineering, 2012; 5(3): 1-9

Banhazi T M, Tscharke M, Ferdous W M, Saunders C, Lee S H. Improved image analysis based system to reliably predict the live weight of pigs on farm: Preliminary results. Australian Journal of Multi-disciplinary Engineering, 2011; 8 (2): 107-119

Banhazi T M, Rutley D L, Pitchford W S. Identification of risk factors for sub-optimal housing conditions in australian piggeries - part iv: Emission factors and study recommendations. Journal of Agricultural Safety and Health, 2008; 14(1): 53-69.

Jongebreur A A. Strategic themes in agricultural and

bioresource engineering in the 21st century. Journal of Agricultural Engineering Research, 2000; 76(3): 227-236.

Munack A, Speckmann H. Communication technology is the backbone of precision agriculture. Agricultural Engineering International: the CIGR Journal of Scientific Research and Development, 2001; 3.

Babinszky L, Halas V. Innovative swine nutrition: Some present and potential applications of latest scientific findings for safe pork production. Italian Journal of Animal Science, 2009; 3(supplement 3): 7-20.

Frost A R, Parsons D J, Stacey K F, Robertson A P, Welch S K, Filmer D, et al. Progress towards the development of an integrated management system for broiler chicken production. Computers and Electronics in Agriculture, 2003; 39(3): 227-240.

Banhazi T, Black J L, Durack M. Australian precision livestock farming workshops. in Joint Conference of ECPA - ECPLF. 2003. Berlin, Germany: Wageningen Academic Publisher.

Banhazi T M, Lewis B, Tscharke M. The development and commercialisation aspects of a practical feed intake measurement instrumentation to be used in livestock buildings. Australian Journal of Multi-disciplinary Engineering, 2011; 8(2): 131-138.

Banhazi T M, Rutley D L, Parkin B J, Lewis B. Field evaluation of a prototype sensor for measuring feed disappearance in livestock buildings. Australian Journal of Multi-disciplinary Engineering, 2009; 7(1): 27-38.

Banhazi T M. User-friendly air quality monitoring system. Applied Engineering in Agriculture, 2009; 25(2): 281-290.

Brandl N, Jorgensen E. Determination of live weight of pigs from dimensions measured using image analysis. Computers and Electronics in Agriculture, 1996; 15(1): 57-72.

Schofield C P. Evaluation of image analysis as a means of estimating the weight of pigs. Journal of Agricultural Engineering Research, 1990; 47: 287-296.

Schofield C P, Marchant J A, White R P, Brandl N, Wilson M. Monitoring pig growth using a prototype imaging system. Journal of Agricultural Engineering Research, 1999; 72(3): 205-210.

Lopez J, Jesse G W, Becker B A, Ellersieck M R. Effects of temperature on the performance of finishing swine: Effect of a hot, diurnal temperature on average daily gain, feed intake, and feed efficiency. Journal of Animal Science, 1991; 69(5): 1843-1849.

Banhazi T M, Currie E, Reed S, Lee I B, Aarnink A J A. Controlling the concentrations of airborne pollutants in piggery buildings, in Sustainable animal production: The challenges and potential developments for professional farming. Aland A, Madec F, Ed., 2009. Wageningen Academic Publishers: Wageningen, The Netherlands. pp. 285-311.

Lee C, Giles L R, Bryden W L, Downing J L, Owens P C, Kirby A C, et al. Performance and endocrine responses of group housed weaner pigs exposed to the air quality of a commercial environment. Livestock Production Science, 2005; 93(3): 255-262.

Banhazi T M, Currie E, Quartararo M, Aarnink A J A. Controlling the concentrations of airborne pollutants in broiler buildings, in Sustainable animal production: The challenges and potential developments for professional farming, Aland A, Madec F, Ed., 2009. Wageningen Academic Publishers: Wageningen, The Netherlands. pp. 347-364.

Banhazi T M, Black J. The precision livestock farming journey: From a scientific dream towards commercial reality, in multidisciplinary approach to acceptable and practical precision livestock farming for smes in europe and worldwide. Smith I G, Lehr H, Ed., 2011. European Commission: Halifax, UK pp. 192-207.