A loss function to evaluate agricultural decision-making under uncertainty: a case study of soil spectroscopy

A loss function to evaluate agricultural decision-making under uncertainty: a case study of soil spectroscopy

Modern sensor technologies can provide detailed information about soil variation which allows for more precise application of fertiliser to minimise environmental harm imposed by agriculture. However, growers should lose neither income nor yield from associated uncertainties of predicted nutrient co...

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Bibliographic Details
Published in:Precision agriculture Vol. 23; no. 4; pp. 1333 - 1353
Main Authors: Breure, T. S., Haefele, S. M., Hannam, J. A., Corstanje, R., Webster, R., Moreno-Rojas, S., Milne, A. E.
Format: Journal Article
Language:English
Published: New York Springer US 01-08-2022
Springer Nature B.V
Subjects:
Agricultural economics
Agriculture
Atmospheric Sciences
Biomedical and Life Sciences
Chemistry and Earth Sciences
Computer Science
Decision making
Fertilizer application
Fertilizers
Horticultural crops
Life Sciences
Nutrient concentrations
Phosphorus
Physics
Remote Sensing/Photogrammetry
Sensors
Soil Science & Conservation
Soils
Spectroscopy
Statistics for Engineering
Uncertainty
Variation
Precision agriculture
Proximal soil sensing
X-ray fluorescence
Variable-rate application
Geostatistics
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Summary:Modern sensor technologies can provide detailed information about soil variation which allows for more precise application of fertiliser to minimise environmental harm imposed by agriculture. However, growers should lose neither income nor yield from associated uncertainties of predicted nutrient concentrations and thus one must acknowledge and account for uncertainties. A framework is presented that accounts for the uncertainty and determines the cost–benefit of data on available phosphorus (P) and potassium (K) in the soil determined from sensors. For four fields, the uncertainty associated with variation in soil P and K predicted from sensors was determined. Using published fertiliser dose–yield response curves for a horticultural crop the effect of estimation errors from sensor data on expected financial losses was quantified. The expected losses from optimal precise application were compared with the losses expected from uniform fertiliser application (equivalent to little or no knowledge on soil variation). The asymmetry of the loss function meant that underestimation of P and K generally led to greater losses than the losses from overestimation. This study shows that substantial financial gains can be obtained from sensor-based precise application of P and K fertiliser, with savings of up to £121 ha −1 for P and up to £81 ha −1 for K, with concurrent environmental benefits due to a reduction of 4–17 kg ha −1 applied P fertiliser when compared with uniform application.
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ISSN:1385-2256
1573-1618
DOI:10.1007/s11119-022-09887-2