Hi everyone
The paper I
read (Wójtowicz et al., 2015) summarize the various systems of Remote-Sensing used
in agriculture and gives a clear view over the common methods of Vegetation-Indices.
In agriculture, it is among other things of great importance to act in an
economic way. Applied on production means this the knowledge of the actual
state is worth the money and provides high yields as well as less deficit in
producer goods.
The use of Remote-Sensing
and the associated Vegetation-Indices, to generate information about the field,
is since the 1950’s a customary method; and with the improvements in technology
over the last 70 years, Remote-Sensing is nowadays in width application. (http://earthobservatory.nasa.gov/Features/RemoteSensing/)
The
astonishing about Remote Sensing is that electromagnetic radiation gives us an
idea of how healthy the plants are or if they for instance need nutrition. The
source of electromagnetic waves is first the sun, and because every surface on
earth reflects them on its own way, we can make assumptions whether it is for
example a house or a plant. Due to the fact that a plant in water stress or
nutrient undersupply has again another reflectance of the wavelength, we gain
lots of information about the biophysical features on the field. (http://lms.seos-project.eu/learning_modules/agriculture/agriculture-c00-p01.de.html)
Collecting
data in Remote-Sensing in the earlier days has been an expensive procedure, but
nowadays there are several ways to do so, and with the UAV’s (Unmanned aerial
vehicle) the prize became more reasonably. The three ways to gain remote-sensing
data are: Satellites, Airborne (Aircraft, UAV, Drone) and Ground-Based Methods.
The Vegetation-Indices
used in agriculture are ratios or differences of several wavelengths, such as
VIS (visible light, 380-780nm), NIR (near infrared, 780-3000nm), TIR (thermal
infrared, 7000-14000nm) and other more. The most frequently calculate
Vegetation-Index is the NDVI (normalized difference vegetation index), which determines
the density of green on a patch of land. More specialised statements can be
made with other Vegetation-Indices. As a further example, scientists can
estimate the nitrogen status of plants with the CI (chlorophyll index). The
high correlation between the indices and the biophysical characteristics is of
great use in agriculture and environmental-specific questions. Some application
examples:
- · Forecasting of yield
- · Nutritional requirements of plants
- · Detection of diseases and pest-damages
- · Assessment of water demands of plants
- · Weed control
In
combination with ground-truth samples and reducing fault factors, such as soil
background, Vegetation-Indices has very little susceptibility to errors. (Wójtowicz
et al., 2015)
For our project
in Schinznach-Dorf I suspect it would be good to know what’s the amount of
water running through the plants during a day. By using the UAV, we can produce
aerial images of the tree nursery and estimate how much water is in the soil by
using TIR-Data and the RRI (relative reflectance index). Probably the CWSI
could be helpful as well. Further investigations on that topic are necessary.
Find out which RS-Information are needed by the guys from the water-balance
team and developing a measurement design will be the next steps in our project.
Thanks for
reading
bye
Yield =
Ertrag
Susceptibility
= Anfälligkeit
Pest =
Schädlinge
article: Wójtowicz et al., 2015; http://agrobiol.sggw.pl/~cbcs/articles/CBCS_11_1_3.pdf
article: Wójtowicz et al., 2015; http://agrobiol.sggw.pl/~cbcs/articles/CBCS_11_1_3.pdf
