Drones can help optimize nitrogen fertilization in potato farming

Nitrogen in the crop can be measured using a satellite or manually in the field. However the method that is expected to see significant progress in the coming years is using multispectral cameras and sensors in drones

Nitrogen in the crop can be measured using a satellite or manually in the field. However the method that is expected to see significant progress in the coming years is using multispectral cameras and sensors in drones

七月 26, 2017

A research programme in the Netherlands, ‘Toward precision agriculture 2.0’ has included a group of potato farmers carrying out test runs with sensor observations by drones.

The drone images show exactly where they should apply more or less nitrogen on their fields, allowing farmers to use the product more efficiently.

Frits van Evert, expert in precision agriculture at Wageningen University & Research:
 

“Dutch potato farmers apply an average of some 250 kilograms of nitrogen per hectare per year.”

“It is applied in one session, just before or just after planting. Because weather conditions in the Netherlands vary significantly, more nitrogen may be lost in one year compared to another.”

“In other words, the 250 kilos can be way too much, or much too little; it is rarely exactly the right amount.”

Colour differences show nitrogen demand

According to Van Evert it is better to apply two thirds of the recommended amount of nitrogen at the start of cultivation, for example, and ‘ask’ the crop how it’s doing halfway through the season.

Advanced sensor observations provide the solution:

Frits van Evert:
 
“The level at which a plant reflects infrared, red and green light depends on the amount of nitrogen it contains.”

“A plant with too little nitrogen has minor colour variations compared to a plant with sufficient nitrogen and modern sensors can measure those differences.”

Measuring Nitrogen Uptake

Measuring how much nitrogen is taken up by potato plants can roughly be performed in three ways.
 
  • With a satellite: a low-cost solution, but unusable when cloudy.
  • With a sensor manually operated in the field or installed on a tractor: a reliable but costly method that hasn’t been widely accepted in practice.
  • With multispectral cameras and sensors in drones: this relatively new method is expected to make significant progress in the coming years.

Application on Akkerweb

Precision agriculture researcher Johan Booij from Wageningen University & Research explains how it works:
 
“The images captured by the drone of the potato field are converted into a map.”

“The farmer is sent this map by e-mail and can upload it via an app on Akkerweb which we developed with Agrifirm.”

“This software then rolls out advice for farmers as to where they should use more or less nitrogen, and which areas don’t need extra application.”

“While we have optimised the method for the use of the eBee-drone, developers of other drone types can make their sensor systems suitable too.”
(Click to enlarge) The drone image shows that the uptake of N in varies significantly within the field.

The drone image shows that the uptake of N in varies significantly within the field.

(Click to enlarge) An online application (akkerweb.eu) generates a map with nitrogen fertilisation advice

An online application (akkerweb.eu) generates a map with nitrogen fertilisation advice

(Click to enlarge) The fertilisation advice is converted (by akkerweb.eu) into an application map for the on-board computer of the tractor which controls he fertiliser spreader

The fertilisation advice is converted (by akkerweb.eu) into an application map for the on-board computer of the tractor which controls he fertiliser spreader


‘More precise and efficient’

Aaldrik Venhuizen, R&D Plant technical manager at the cooperative company Agrifirm, expects a great deal from the sensor observations with drones:
 
“Many farmers now use annual soil and leaf petiole analyses of representative field parts to determine whether extra nitrogen is needed.”

“Now there is a validated method that can not only determine far more precisely how much nitrogen should be applied, but also shows us the differences in nitrogen demand within fields.”

“This will lead to a much more efficient use of nitrogen.”
And that will benefit yields, costs and the environment.

According to Venhuizen the focus is currently on ware and starch potatoes, but he believes that expansion of the method for nitrogen measurements in seed potatoes would be a logical next step:
 
“And if it were up to me, we’d also make the method applicable to measurements in other crops, such as malting barley and wheat.”