Development and testing of a decision making based method to adjust automatically the harrowing intensity

Development and testing of a decision making based method to adjust automatically the harrowing intensity

Harrowing is often used to reduce weed competition, generally using a constant intensity across a whole field. The efficacy of weed harrowing in wheat and barley can be optimized, if site-specific conditions of soil, weed infestation and crop growth stage are taken into account. This study aimed to...

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Vol. 13; no. 5; pp. 6254 - 6271
Main Authors: Rueda-Ayala, Victor, Weis, Martin, Keller, Martina, Andújar, Dionisio, Gerhards, Roland
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 13-05-2013
Molecular Diversity Preservation International (MDPI)
Subjects:
Agricultural production
Cameras
crop-weed-soil sensors
crop-weed-soil variability
Crops, Agricultural - growth & development
Decision Making
Fuzzy Logic
Global positioning systems
GPS
Hordeum - growth & development
Plant Leaves - growth & development
precision weed control
Reproducibility of Results
selectivity
Sensors
site-specific harrowing
Triticum - growth & development
Weed Control - methods
Weeds
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Summary:Harrowing is often used to reduce weed competition, generally using a constant intensity across a whole field. The efficacy of weed harrowing in wheat and barley can be optimized, if site-specific conditions of soil, weed infestation and crop growth stage are taken into account. This study aimed to develop and test an algorithm to automatically adjust the harrowing intensity by varying the tine angle and number of passes. The field variability of crop leaf cover, weed density and soil density was acquired with geo-referenced sensors to investigate the harrowing selectivity and crop recovery. Crop leaf cover and weed density were assessed using bispectral cameras through differential images analysis. The draught force of the soil opposite to the direction of travel was measured with electronic load cell sensor connected to a rigid tine mounted in front of the harrow. Optimal harrowing intensity levels were derived in previously implemented experiments, based on the weed control efficacy and yield gain. The assessments of crop leaf cover, weed density and soil density were combined via rules with the aforementioned optimal intensities, in a linguistic fuzzy inference system (LFIS). The system was evaluated in two field experiments that compared constant intensities with variable intensities inferred by the system. A higher weed density reduction could be achieved when the harrowing intensity was not kept constant along the cultivated plot. Varying the intensity tended to reduce the crop leaf cover, though slightly improving crop yield. A real-time intensity adjustment with this system is achievable, if the cameras are attached in the front and at the rear or sides of the harrow.
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ISSN:1424-8220
1424-8220
DOI:10.3390/s130506254