posted on 2019-11-20, 09:22authored byDylan Walshe, Daniel McInerney, Ruben Van De Kerchove, Clémence Goyens, Preethi Balaji, Kenneth A. Byrne
Nutrient deficiency in forest stands has a negative impact on timber production. Although there are numerous studies
investigating nutrient deficiency in forests using remote sensing, research has usually focused on extracting nutrient/
pigment concentrations using hyperspectral imagery. Results of studies using this method of assessment are uncertain
at the canopy level. This study proposes using freely available multispectral imagery to identify nutrient deficiency in
commercially managed forest plantations. A classification map of nutrient deficient, healthy, and a third class, other,
for State spruce forests in the Republic of Ireland was constructed using multispectral Sentinel 2 images from Spring
and a Random Forest model. The forest area of interest (AOI) was Sitka spruce or Norway spruce plantations greater
than 12 years old. Results showed that the overall accuracy was 89% and the associated Kappa Index of agreement
was 79%. An unbiased area estimator was vital for an accurate estimate of the scale of nutrient deficiency, which
concluded that 23% of the AOI was nutrient deficient. Early detection of nutrient deficiency is crucial to mitigate
negative impacts on productivity so a time series analysis of the spectral response of healthy and nutrient deficient
classes using Google Earth Engine's Landsat 5, 7, and 8 archive was carried out. A control of known nutrient deficient
sites, as identified through foliar analysis, was used for comparison with the nutrient deficient and healthy training
data. The spectral response showed a decrease through time for all of the foliar analysis and training data using the
green (520–600 nm), red (630–690 nm), and SWIR spectra (1550–1700 nm) during Spring. This decreasing trend is
due to the growth of foliage, with the difference in spectral response between nutrient deficient and healthy stands
being attributed to the presence of chlorosis in stands suffering from nutrient deficiency. Spectral thresholds using
digital numbers for nutrient deficient stands were identified for an operational optimum age cohort of between
10–12 years old which will be used for early detection.
Funding
Using the Cloud to Streamline the Development of Mobile Phone Apps