Using a ‘network of practice’ approach to match grazing decision-support system design with farmer practice
C. R. Eastwood A C , B. T. Dela Rue A and D. I. Gray BA DairyNZ Ltd, Hamilton 3240, New Zealand.
B Massey University, Palmerston North 4474, New Zealand.
C Corresponding author. Email: callum.eastwood@dairynz.co.nz
Animal Production Science 57(7) 1536-1542 https://doi.org/10.1071/AN16465
Submitted: 19 July 2016 Accepted: 11 November 2016 Published: 21 December 2016
Abstract
The use of pasture measurement tools and decision-support systems (DSS) for grazing management remains limited on New Zealand dairy farms. However, effective use of such tools provides opportunities to optimise pasture grown and pasture harvested. The present study used a mixed-method qualitative research approach to investigate pasture data and technology use for grazing decision making, through interviews and workshops with farmers, rural professionals, commercial software developers and a panel of farming-system specialists. Results suggest that different drivers for use of pasture data and DSS exist between farm owner-operators and corporate farming operations. Larger multi-farm businesses are collecting pasture data for use at a governance level as well as for operational decision making. Understanding the seasonal influences on decision making, and incorporating major regional differences such as pasture growth rates and impact of irrigation use, provides guidance on how to better match DSS to farmer practice. Study participants identified a need for greater integration of software tools to connect in-paddock data capture with real-time feedback. Also, data integration is needed to enable the transfer of information across different platforms for corporate farming operations. Rural professionals used commercial grazing DSS products, but also constructed their own spreadsheets to enable functionality and reporting not available in the DSS products. The research highlighted a need for farmer-orientated tools that are flexible to incorporate differences in user goals, decision making, mobility and desired outputs. Key attributes identified were seasonality, simplicity, ability to trial before purchase, flexibility in application, scalability to match farm systems, and integration with other tools. Future research and design of DSS tools requires a focus on co-creation with farmers, to merge scientific and practical knowledge.
Additional keywords: agricultural innovations, farm management, grazing management, precision farming.
References
Botha N, Atkins K (2006) The design, utility and adoption of decision support systems in the New Zealand pastoral industry. In ‘Proceedings of APEN international conference 2006’, Beechworth, Victoria, Australia, 6–8 March 2006. Available at http://www.regional.org.au/au/apen/2006/refereed/5/2869_bothan.htm [Verified 17 October 2016]Bryman A (2001) ‘Social research methods.’ (Oxford University Press: Oxford, UK)
Cerf M, Jeuffroy M-H, Prost L, Meynard J-M (2012) Participatory design of agricultural decision support tools: taking account of the use situations. Agronomy for Sustainable Development 32, 899–910.
| Participatory design of agricultural decision support tools: taking account of the use situations.Crossref | GoogleScholarGoogle Scholar |
Chapman DF, Hill J, Tharmaraj J, Beca D, Kenny SN, Jacobs JL (2014) Increasing home-grown forage consumption and profit in non-irrigated dairy systems. 1. Rationale, systems design and management. Animal Production Science 54, 221–233.
| Increasing home-grown forage consumption and profit in non-irrigated dairy systems. 1. Rationale, systems design and management.Crossref | GoogleScholarGoogle Scholar |
Dobos RC, Fulkerson WJ (2004) A database program to assist in the allocation of pasture and supplements to grazing dairy cows. Environmental Modelling & Software 19, 581–589.
| A database program to assist in the allocation of pasture and supplements to grazing dairy cows.Crossref | GoogleScholarGoogle Scholar |
Eastwood CR, Kenny S (2009) Art or science? Heuristic versus data driven grazing management on dairy farms. Extension Farming Systems Journal 5, 95–102.
Eastwood CR, Yule I (2015) Challenges and opportunities for precision dairy farming in New Zealand. Farm Policy Journal 12, 33–41.
Eastwood CR, Chapman DF, Paine MS (2012) Networks of practice for co-construction of agricultural decision support systems: case studies of precision dairy farms in Australia. Agricultural Systems 108, 10–18.
| Networks of practice for co-construction of agricultural decision support systems: case studies of precision dairy farms in Australia.Crossref | GoogleScholarGoogle Scholar |
Eastwood CR, Jago JG, Edwards JP, Burke JK (2016) Getting the most out of advanced farm management technologies: roles of technology suppliers and dairy industry organisations in supporting precision dairy farmers. Animal Production Science 56, 1752–1760.
Gray DI (2001) The tactical management processes used by pastoral-based dairy farmers: a multiple-case study of experts. PhD Thesis, Massey University, Palmerston North, New Zealand.
Jago J, Eastwood C, Kerrisk K, Yule I (2013) Precision dairy farming in Australasia: adoption, risks and opportunities. Animal Production Science 53, 907–916.
King WM, Rennie GM, Dalley DE, Dynes RA, Upsdell MP (2010) Pasture mass estimation by the C-DAX pasture meter: regional calibrations for New Zealand. In ‘Proceedings of the 4th Australasian dairy science symposium 2010: meeting the challenges for pasture-based dairying’, 31 August–2 September 2010, Lincoln University, Christchurch, New Zealand, pp. 223–238. (Caxton Press: Christchurch)
Kresse W, Danko DM (2012) ‘Springer handbook of geographic information.’ (Springer Science & Business Media: New York)
Lynch T, Gregor S (2004) User participation in decision support systems development: influencing system outcomes. European Journal of Information Systems 13, 286–301.
| User participation in decision support systems development: influencing system outcomes.Crossref | GoogleScholarGoogle Scholar |
MacDonald KA, Glassey CB, Rawnsley RP (2010) The emergence, development and effectiveness of decision rules for pasture based dairy systems. In ‘Proceedings of the 4th Australasian dairy science symposium 2010: meeting the challenges for pasture-based dairying’, 31 August–2 September 2010, Lincoln University, Christchurch, New Zealand, pp. 199–209. (Caxton Press: Christchurch)
McCarthy S, Hirst C, Donaghy D, Gray D, Wood B (2014) Opportunities to improve grazing management. Proceedings of the New Zealand Grassland Association 76, 75–79.
McCown RL (2002) Changing systems for supporting farmers’ decisions: problems, paradigms, and prospects. Agricultural Systems 74, 179–220.
| Changing systems for supporting farmers’ decisions: problems, paradigms, and prospects.Crossref | GoogleScholarGoogle Scholar |
Nuthall PL (2012) The intuitive world of farmers: the case of grazing management systems and experts. Agricultural Systems 107, 65–73.
| The intuitive world of farmers: the case of grazing management systems and experts.Crossref | GoogleScholarGoogle Scholar |
Nuthall PL, Bishop-Hurley GJ (1996) Expert systems for animal feeding management Part II: farmers’ attitudes. Computers and Electronics in Agriculture 14, 23–41.
| Expert systems for animal feeding management Part II: farmers’ attitudes.Crossref | GoogleScholarGoogle Scholar |
Parker WJ (1999) Farm performance measurement: linking monitoring to business strategy. Proceedings of the New Zealand Society of Animal Production 59, 6–13.
Romera A, Beukes P, Clark D, Clark C, Tait A (2013) Pasture growth model to assist management on dairy farms: testing the concept with farmers. Grassland Science 59, 20–29.
| Pasture growth model to assist management on dairy farms: testing the concept with farmers.Crossref | GoogleScholarGoogle Scholar |
Tomic D, Iwersen M, Auer W (2016) Cow time budget and beyond: experience with the Smartbow system. In ‘International precision dairy farming conference, Leeuwarden, The Netherlands, 21–23 June 2016. pp. 81–88. (Wageningen Academic Publishers: The Netherlands)