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Engineering advances for input reduction and systems management to meet the challenges of global food and farming futures

Published online by Cambridge University Press:  19 November 2010

W. DAY
W. DAY
Affiliation:
Harpenden, Herts, England, UK
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Summary

Improvements in farming systems and food supply will come from: increased production efficiencies per unit land area or per unit input of key components such as water or fertilizer; from less negative impact on local and global environments, allowing sustainable biodiversity goals to be integrated with production performance; and from enhanced approaches to bringing global supply and demand in balance, allowing internationally agreed goals for biosphere stability to be shaped, managed and delivered. Each stage will deliver significant improvements to current farming approaches. Modern engineering methods and technology advances have enhanced productivity in all major industries, and farming is yet to make much progress by developing and adopting these technologies. Sensors, control and integrated management systems will be major features, delivering enhanced farming productivity per unit input and per person employed, complemented by decreased environmental impacts and lower losses in the food chain. New insights into modelling and interpreting systems' performance will provide key contributions to optimization and control under complex challenges.

Type
Foresight Project on Global Food and Farming Futures
Information
The Journal of Agricultural Science , Volume 149 , Issue S1: FORESIGHT PROJECT ON GLOBAL FOOD AND FARMING FUTURES , February 2011 , pp. 55 - 61
Copyright
Copyright © Cambridge University Press 2010

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References

REFERENCES

Annetts, J. E. & Audsley, E. (2002). Multiple objective linear programming for environmental farm planning. Journal of the Operational Research Society 53, 933943.CrossRefGoogle Scholar
Antonopoulou, E., Karetsos, S. T., Maliappis, M. & Sideridis, A. B. (2009). Web and mobile technologies in a prototype DSS for major field crops. Computers and Electronics in Agriculture 70, 292301.CrossRefGoogle Scholar
Bakker, T., van Asselt, K., Bontsema, J., Müller, J. & van Straten, G. (2010). Systematic design of an autonomous platform for robotic weeding. Journal of Terramechanics 47, 6373.CrossRefGoogle Scholar
Dabbene, F., Gay, P. & Sacco, N. (2008). Optimisation of fresh-food supply chains in uncertain environments, Part I: Background and methodology. Biosystems Engineering 99, 348359.CrossRefGoogle Scholar
Dawson, J. J. C. & Smith, P. (2007). Carbon losses from soil and its consequences for land-use management. Science of the Total Environment 382, 165190.CrossRefGoogle ScholarPubMed
Gerbens-Leenes, P. W., Moll, H. C. & Schoot Uiterkamp, A. J. M. (2003). Design and development of a measuring method for environmental sustainability in food production systems. Ecological Economics 46, 231248.CrossRefGoogle Scholar
Gnansounou, E., Dauriat, A., Villegas, J. & Panichelli, L. (2009). Life cycle assessment of biofuels: energy and greenhouse gas balances. Bioresource Technology 100, 49194930.CrossRefGoogle ScholarPubMed
Goel, P. K., Prasher, S. O., Landry, J. A., Patel, R. M., Bonnell, R. B., Viau, A. A. & Miller, J. R. (2003). Potential of airborne hyperspectral remote sensing to detect nitrogen deficiency and weed infestation in corn. Computers and Electronics in Agriculture 38, 99124.CrossRefGoogle Scholar
Hatfield, J. L., Gitelson, A. A., Schepers, J. S. & Walthall, C. L. (2008). Application of spectral remote sensing for agronomic decisions. Agronomy Journal 100, S117S131.CrossRefGoogle Scholar
Huang, Y., Lan, Y., Thomson, S. J., Fang, A., Hoffmann, W. C. & Lacey, R. E. (2010). Development of soft computing and applications in agricultural and biological engineering. Computers and Electronics in Agriculture 71, 107127.CrossRefGoogle Scholar
Jansen, R. M. C., Hofstee, J. W., Wildt, J., Verstappen, F. W. A., Bouwmeester, H. J., Posthumus, M. A. & van Henten, E. J. (2009). Health monitoring of plants by their emitted volatiles: trichome damage and cell membrane damage are detectable at greenhouse scale. Annals of Applied Biology 154, 441452.CrossRefGoogle Scholar
Karmakar, S., Laguë, C., Agnew, J. & Landry, H. (2007). Integrated decision support system (DSS) for manure management: a review and perspective. Computers and Electronics in Agriculture 57, 190201.CrossRefGoogle Scholar
Kondo, N. (2010). Automation on fruit and vegetable grading system and food traceability. Trends in Food Science and Technology 21, 145152.CrossRefGoogle Scholar
Lark, R. M. & Wheeler, H. C. (2003). A method to investigate within-field variation of the response of combinable crops to an input. Agronomy Journal 95, 10931104.CrossRefGoogle Scholar
Luong, J. H. T., Male, K. B. & Glennon, J. D. (2008). Biosensor technology: technology push versus market pull. Biotechnology Advances 26, 492500.CrossRefGoogle ScholarPubMed
Meisterling, K., Samaras, C. & Schweizer, V. (2009). Decisions to reduce greenhouse gases from agriculture and product transport: LCA case study of organic and conventional wheat. Journal of Cleaner Production 17, 222230CrossRefGoogle Scholar
Nayak, M., Kotian, A., Marathe, S. & Chakravortty, D. (2009). Detection of microorganisms using biosensors – a smarter way towards detection techniques. Biosensors and Bioelectronics 25, 661667.CrossRefGoogle ScholarPubMed
Oliver, Y. M., Robertson, M. J. & Wong, M. T. F. (2010). Integrating farmer knowledge, precision agriculture tools, and crop simulation modelling to evaluate management options for poor-performing patches in cropping fields. European Journal of Agronomy 32, 4050.CrossRefGoogle Scholar
Parsons, D. J., Benjamin, L. R., Clarke, J., Ginsburg, D., Mayes, A., Milne, A. E. & Wilkinson, D. J. (2009). Weed Manager – A model-based decision support system for weed management in arable crops. Computers and Electronics in Agriculture 65, 155167.CrossRefGoogle Scholar
Rumpf, T., Mahlein, A.-K., Steiner, U., Oerke, E.-C., Dehne, H.-W. & Plümer, L. (2010). Early detection and classification of plant diseases with Support Vector Machines based on hyperspectral reflectance. Computers and Electronics in Agriculture 74, 9199.CrossRefGoogle Scholar
Sinfield, J. V., Fagerman, D. & Colic, O. (2010). Evaluation of sensing technologies for on-the-go detection of macro-nutrients in cultivated soils. Computers and Electronics in Agriculture 70, 118.CrossRefGoogle Scholar
Slaughter, D. S., Giles, D. K. & Downey, D. (2008). Autonomous robotic weed control systems: a review. Computers and Electronics in Agriculture 61, 6378.CrossRefGoogle Scholar
Spooner, A. D., Bessant, C., Turner, C., Knobloch, H. & Chambers, M. (2009). Evaluation of a combination of SIFT-MS and multivariate data analysis for the diagnosis of Mycobacterium bovis in wild badgers. Analyst 134, 19221927.CrossRefGoogle ScholarPubMed
Sylvester-Bradley, R. & Kindred, D. R. (2009). Analysing nitrogen responses of cereals to prioritize routes to the improvement of nitrogen use efficiency. Journal of Experimental Botany 60, 19391951.CrossRefGoogle Scholar
Thakur, M. & Hurburgh, C. R. (2009). Framework for implementing traceability system in the bulk grain supply chain. Journal of Food Engineering 95, 617626.CrossRefGoogle Scholar
Tillett, N. D., Hague, T., Grundy, A. C. & Dedousis, A. P. (2008). Mechanical within-row weed control for transplanted crops using computer vision. Biosystems Engineering 99, 171178.CrossRefGoogle Scholar
Tullberg, J. (in press). Tillage, traffic and sustainability – a challenge for ISTRO. Soil and Tillage Research, in press, doi:10.1016/j.still.2010.08.008.Google Scholar
Velasco-Garcia, M. & Mottram, T. T. (2003). Biosensor technology addressing agricultural problems. Biosystems Engineering 84, 112.CrossRefGoogle Scholar
Voulodimos, A. S., Patrikakis, C. Z., Sideridis, A. B., Ntafis, V. A. & Xylouri, E. M. (2010). A complete farm management system based on animal identification using RFID technology. Computers and Electronics in Agriculture 70, 380388.CrossRefGoogle Scholar
Wang, N., Zhang, N. & Wang, M. (2006). Wireless sensors in agriculture and food industry – recent development and future perspective. Computers and Electronics in Agriculture 50, 114.CrossRefGoogle Scholar
Wolfert, J., Verdouw, C. N., Verloop, C. M. & Beulens, A. J. M. (2010). Organizing information integration in agri-food – a method based on a service-oriented architecture and living lab approach. Computers and Electronics in Agriculture 70, 389405.CrossRefGoogle Scholar
Xu, Y. F., Velasco-Garcia, M. & Mottram, T. T. (2005). Quantitative analysis of the response of an electrochemical biosensor for progesterone in milk. Biosensors and Bioelectronics 20, 20612070.CrossRefGoogle ScholarPubMed
Zhang, N., Wang, M. & Wang, N. (2002). Precision agriculture – a worldwide overview. Computers and Electronics in Agriculture 36, 113132.CrossRefGoogle Scholar