Algorithms for sensor-based redistribution of nitrogen fertilizer in winter wheat

Berntsen, Jørgen; Thomsen, Anne Belinda; Schelde, Kirsten; Hansen, O. M.; Knudsen, Leif; Broge, Niels; Hougaard, H.; Hørfarter, R.

doi:10.1007/s11119-006-9000-2

Cited by 68 publications

(44 citation statements)

References 18 publications

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“…Lammel et al (2001) point out that the Yara N-sensor is valuable to avoid over-and under fertilization within a field resulting in increased yield, decreased lodging and more homogenous ripening. Other researchers accentuate that usage of the N-sensor only have resulted in small differences in yield (Berntsen and Thomsen et al 2006;Jørgensen et al 2006) and Zillmann et al (2006) point out that the N-sensor technology work when nitrogen is the main growth-limiting factor. The usage of Yara N-sensor reduces nitrogen leaching if areas with lower requirements for nitrogen fertilization within the field can be identified (Delin and Stenberg 2014).…”

Section: Experiences From Swedenmentioning

confidence: 99%

Promoting sustainable intensification in precision agriculture: review of decision support systems development and strategies

et al. 2016

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Precision agriculture provides important issues toward a more sustainable agriculture. Many farmers have the necessary technology to operate site-specifically, but they do not use it in practice, and thus available information and communications technology (ICT) systems are not used to their full potential. This paper addresses how to reduce the so-called ''problem of implementation'', based on the knowledge that participatory approaches during the design and development process is one of the most important factors to frame technology adoption. The development of sustainable ICT systems through theories and methodologies from the fields of human computer interaction and user-centered design (UCD) is presented and an ongoing Swedish project for development of an agricultural decision support system (AgriDSS) for nitrogen fertilization is used as an example to frame the issue. The overreaching aim is to develop AgriDSSs that are sustainable in design as well as through design by stressing the importance of participatory approaches for the successful development of AgriDSSs. The Swedish project has the intention to apply a UCD approach, and some pitfalls on starting to use this way of working is identified as well as some suggestions on how to reduce them through co-learning processes. Despite the challenges presented in this paper, ICT can contribute significantly to long-term sustainable development. Thus, several competences and scientific disciplines need to act in concert to help develop a sustainable development of agriculture via a transdisciplinary approach that can make an impact on society at many levels.

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Section: Experiences From Swedenmentioning

confidence: 99%

Promoting sustainable intensification in precision agriculture: review of decision support systems development and strategies

et al. 2016

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“…They showed variable-rate N applications would result in significant N savings compared to uniform N application, when using N priced at $0.55 kg −1 . Researchers in Europe and elsewhere (Schroder et al, 2000;Olfs et al, 2005;Berntsen et al, 2006;Tremblay and Belec, 2006;Zillmann et al, 2006) have also shown that this approach can be used to direct variable in-season N applications in cereal grains that improves NUE, crop harvest ability, and/or quality. Some of the aforementioned research involved use of the Yara N sensor system for variable N applications, which has been available for about a decade in Europe (Yara UK Limited, Lincolnshire, UK) as a commercialized service, and is being adopted by growers.…”

Section: Ground-based Remote Sensingmentioning

confidence: 99%

Responsive in-season nitrogen management for cereals

Shanahan

Kitchen

Raun

et al. 2008

Computers and Electronics in Agriculture

239

173

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“…One practical manner in which to apply N uptake maps produced through the models presented in this study could be to first determine a field average N requirement according to common practice (taking the above aspects into consideration), and then redistribute the average N according to the N uptake map. This redistribution need to take into account if other factors than N is expected to limit crop growth, but generally it has been demonstrated that a reasonable approach might be to move N from areas with the lowest and highest values to medium areas (Berntsen et al 2006), and algorithms built into some tractor-borne N sensors work this way (Söderström et al, 2004). Linear relationships between N uptake and N rate to apply have been reported (Flowers et al 2003), but these have been found to be highly unreliable and often site-specific (Samborski et al 2009).…”

Section: Improvements Through Design-based N Sensor Measurementsmentioning

confidence: 99%

Producing nitrogen (N) uptake maps in winter wheat by combining proximal crop measurements with Sentinel-2 and DMC satellite images in a decision support system for farmers

Piikki

Stenberg

Stadig³

et al. 2017

Acta Agriculturae Scandinavica, Section B — Soil & Plant Sc

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Responsive fertilisation of winter wheat (Triticum aestivum L.) is often adopted, with N applied two or three times between the developmental stages of tillering and booting. Satellite-based decision support systems (DSS) providing vegetation index maps calculated from satellite data are available to aid farmers in adjusting the topdressing nitrogen (N) rate site-specifically to the current season and to variations in growth conditions within the field. One example is the freely available CropSAT DSS used in Scandinavia, which provides farmers with raster maps of the modified soil-adjusted vegetation index (MSAVI2) calculated mainly from data obtained from satellites Sentinel-2 (ESA, EU) and DMC (DMCii Ltd, Guildford, UK). This study investigated the possibility of calibrating MSAVI2 maps with data from handheld proximal sensor measurements of N uptake covering the main agricultural regions in Sweden during growth stages Z30-45 on the Zadok scale, in order to facilitate farmers' decisions on N rate. More than 200 N-sensor measurements acquired during 2015 and 2016 in seven different winter wheat cultivars were combined with MSAVI2 values from CropSAT. It was found that N uptake could be predicted in a general, national model, i.e. for sites and dates other than those for which the calibration model was parameterised, with a mean absolute error of 11-15 kg N ha −1 . A cultivar-specific model performed better than this general model, but a regional model showed no improvement compared with the model parameterised with national data. Vegetation indices calculated from the two narrow bands of Sentinel-2 in the red edge-near infrared region of the crop canopy reflectance spectrum proved to be promising alternatives to the broadband index MSAVI2. Based on the results, we suggest that data from a monitoring programme involving handheld N sensor measurements can be integrated with a satellite-based DSS to upscale N uptake information. ARTICLE HISTORY

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Algorithms for sensor-based redistribution of nitrogen fertilizer in winter wheat

Cited by 68 publications

References 18 publications

Promoting sustainable intensification in precision agriculture: review of decision support systems development and strategies

Promoting sustainable intensification in precision agriculture: review of decision support systems development and strategies

Responsive in-season nitrogen management for cereals

Producing nitrogen (N) uptake maps in winter wheat by combining proximal crop measurements with Sentinel-2 and DMC satellite images in a decision support system for farmers

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