Optimisation of soil VIS–NIR sensor-based variable rate application system of soil phosphorus

Optimisation of soil VIS–NIR sensor-based variable rate application system of soil phosphorus

Uniform phosphorous fertilisation has economical, ecological and agronomical shortcomings. This study was undertaken to optimise the variable rate (VR) elemental P application using a previously developed on-the-go visible (VIS) and near infrared (NIR) soil sensor. This VIS–NIR sensor consists of a...

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Bibliographic Details
Published in:Soil & tillage research Vol. 94; no. 1; pp. 239 - 250
Main Authors: Maleki, M.R., Mouazen, A.M., Ramon, H., De Baerdemaeker, J.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01-05-2007
Elsevier
Subjects:
agricultural soils
Agronomy. Soil science and plant productions
Biological and medical sciences
equations
fertilizer application
Fundamental and applied biological sciences. Psychology
General agronomy. Plant production
Near infrared
Nitrogen, phosphorus, potassium fertilizations
On-the-go
Phosphorous fertilisation
phosphorus
portable equipment
sensors
Soil science
Soil sensor
soil spectra
Soil-plant relationships. Soil fertility. Fertilization. Amendments
spectral analysis
spectrophotometers
statistical models
Variable rate technology
Visible
On-the-go
Visible
Phosphorous fertilisation
Variable rate technology
Soil sensor
Near infrared
Measurement sensor
Phosphorus
Visible spectrometry
Phosphorus fertilization
Optimization
Near infrared radiation
Reflection spectrometry
Soils
Near infrared spectrometry
Application rates
Soil science
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Summary:Uniform phosphorous fertilisation has economical, ecological and agronomical shortcomings. This study was undertaken to optimise the variable rate (VR) elemental P application using a previously developed on-the-go visible (VIS) and near infrared (NIR) soil sensor. This VIS–NIR sensor consists of a chisel unit, to which the optical unit to detect soil extractable phosphorous (P-ext) was attached. A mobile, fibre-type VIS–NIR spectrophotometer (Zeiss Corona 45 visnir, Germany ) with a measurement range between 305 and 1711 nm was used to measure soil spectra in reflectance mode. On-the-go measurement of soil spectra was carried out in two fields (A and B) situated near Leuven in Belgium. From the spectra, P-ext was calculated in soil and subsequently the required elemental P was determined. Different averaging windows (AW) of the predicted P-ext from successive spectra (2–22) and five recommendation classification intervals (RCI) of elemental P of 20, 10, 5, 2 and 1 kg ha −1 were assigned and tested. The VR of elemental P was compared with uniform rate (UR) application. Results showed that among the five RCIs, the minimum elemental P application rate was for interval of 5 kg ha −1, with small differences of among the different RCIs. In the fields under study, the amount of elemental P fertiliser according to the VR approach was higher than the UR application with an extra elemental P of 4 and 2.38 kg ha −1 for fields A and B, respectively. However, this higher elemental P fertiliser recommendation of VR is only valid when an equal number of samples (1200 in field A and 660 in field B) is considered for both VR and UR methods. Larger amounts of elemental P fertiliser were needed for plots and/or fields having higher variation in measured P-ext. The results also showed that in both fields the application rate decreased with larger AWs. Averaging of less than five P-ext successive values was not a proper choice with any RCIs due to the large deviation between the target and classified elemental P into the different RCIs. The combination of RCI 5 and AW between 10 and 15 is recommended to provide a good matching between uniform and applied elemental P at low cost.
Bibliography:http://dx.doi.org/10.1016/j.still.2006.07.016
ISSN:0167-1987
1879-3444
DOI:10.1016/j.still.2006.07.016