Hostname: page-component-cd9895bd7-mkpzs Total loading time: 0 Render date: 2024-12-25T05:29:25.121Z Has data issue: false hasContentIssue false

Agricultural Vehicle Positioning and its Integration with a Large-Scale Land Information System

Published online by Cambridge University Press:  21 October 2009

Fraser MacLeod
Affiliation:
(Polytechnic of East London)

Abstract

Agriculture in the U.K. has, since the late 1940s, enjoyed government subsidy and insulation from free market forces. However, the post-war philosophy of ‘every acre counts’ no longer holds true in the face of surplus production and a growing public awareness of the countryside and environmental issues. Legislation relating to water pollution, public rights of way and price support mechanisms are all contributory factors to the radical changes which agriculture is undergoing at the present time. Investigations have shown a need within agriculture for the efficient use and handling of data relating to the land, and a need for new technology to exploit the inherent spatial variability of, for example, the soil. This paper will discuss the development of an agricultural vehicle positioning instrument and future research which will address the needs which have been identified.

Type
Research Article
Copyright
Copyright © The Royal Institute of Navigation 1991

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

1Bae, Y. H.Borgelt, S. CSchueller, J. K. and Stout, B. A. (1987). Determination of spatially variable yield maps. Paper No. 85-1533 International Winter Meeting of the American Society of Agricultural Engineers.Google Scholar
2Blunden, J.. and Curry, N. (1988). A future for our countryside. Basil Blackwell, Oxford.Google Scholar
3 Centre of Management in Agriculture (1984). The computer as farm management tool. British Institute of Management Foundation, Corby, U.K.Google Scholar
4Elliott, C. (1987). Fertilizing-blending and spreading on-the-go using computerized soil maps and radar guidance. Paper No. 871676 Society of Automotive Engineers Off-Highway and Powerplant Congress and Exposition. Milwaukee, USA.Google Scholar
5Foo, V. W. (1989). Automatic shape measurement for tunnel profiling. Land and Minerals Surveying 7, 350351.Google Scholar
6Goodwin, S. (1990). Footpath controls tightened. Independent newspaper, Sat. 24 February.Google Scholar
7Gorham, B. J. (1989a). Laser guidance system for tunnelling machines. Land and Minerals Surveying, 7, 422427.Google Scholar
8Gorham, B. J. (1989b). Automatic calibration of production robots from a single laser source. Land and Minerals Surveying, 7, 3740.Google Scholar
9Gorham, B. J. (1988). Measurement of spatial position using laser beams. Land and Minerals Surveying, 6, 121126Google Scholar
10Jahns, G. and Speckmenn, H. (1988). Requirements to standardize data transfer in CAA (computer aided agriculture). Paper No. 88–1060 International Summer Meeting of the American Society of Agricultural Engineers, Rapid City, USA.Google Scholar
11Larsen, W. E., Tyler, D. A. and Nielsen, G. A. (1988). Field navigation using the Global Positioning System. Paper No. 88-1604 International Winter Meeting of the American Society of Agricultural Engineers, Chicago, USA.Google Scholar
12MacLeod, F. (1989). New technology comes to the aid of the farmer. Land and Minerals Surveying, 7, 349350.Google Scholar
13MacLeod, M. (1989). Farming. Which Computer March.Google Scholar
14Monod, M. O. & Mechineau, D. (1988). Absolute field location. Paper No. 886393 AG ENG 88 Agricultural Engineering International Conference, Paris, France, March.Google Scholar
15Pack, B. (1980). Trends in computer applications for farmers. Farm Management Review, no. 14, June, pp. 138Google Scholar
16Palmer, R. J. (1989a). Techniques for navigating in a farm field. Navigation, 36, 337344.CrossRefGoogle Scholar
17Palmer, R. J. (1989b). Precise navigation, guidance and control services within the agricultural community. This Journal, 42, 1.Google Scholar
18Rehman, T.. (1983a). Computer applications: 4. Planning in farm management. Span, 26, 75.Google Scholar
19Rehman, T. (1983b). Computer applications: 3. Decision making in farm management. Span, 26, 37.Google Scholar
20Schueller, J. K. (1988). Machinery and systems for spatially variable crop production. Paper No. 88-1608 International Winter Meeting of the American Society of Agricultural Engineers, Chicago, USA.Google Scholar