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Amélie Marie Beucher
Artificial neural network for mapping and characterization of acid sulfate soils: Application to Sirppujoki River catchment, southwestern Finland
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Artificial neural network for mapping and characterization of acid sulfate soils : Application to Sirppujoki River catchment, southwestern Finland. / Beucher, A.; Siemssen, R.; Fröjdö, S. et al.
In: Geoderma, Vol. 247-248, 01.06.2015, p. 38-50.Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review
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TY - JOUR
T1 - Artificial neural network for mapping and characterization of acid sulfate soils
T2 - Application to Sirppujoki River catchment, southwestern Finland
AU - Beucher, A.
AU - Siemssen, R.
AU - Fröjdö, S.
AU - Österholm, P.
AU - Martinkauppi, A.
AU - Edén, P.
PY - 2015/6/1
Y1 - 2015/6/1
N2 - Acid sulfate (a.s.) soil mapping constitutes a fundamental step in order to plan and carry out effective mitigation at catchment scale. The main goal of this study was to assess the use of an artificial neural network (ANN) based on a Radial Basis Function (RBF) for a.s. soil mapping and characterization of soil properties relevant for environmental planning. This method was applied on the Sirppujoki River catchment (c. 440km2), located in southwestern Finland. It required using various evidential datalayers (quaternary geology, slope and aerogeophysics) and point datasets (i.e. soil profiles) and enabled the creation of probability maps for a.s. soil occurrence, as well as predictive maps for different soil properties (sulfur content, organic matter content and critical sulfur depth). For the most accurate a.s. soil probability map, the high and very high probability areas cover about 10% of the whole study area (c. 42km2) and contain all the known a.s. soil occurrences used as validation points. When considering the areas overlapping with the high and very high a.s. soil probability zones on the most accurate soil property predictive maps: (a) about 82% of these most probable areas display a predicted sulfur content between 0.3 and 1%, which is consistent with the values typically measured in the sulfidic horizons (i.e. between 0.2 and 1% in Finland); (b) the predicted organic matter content ranges between 5 and 15% in 98% of the areas of interest, indicating that sulfur contents greater than 0.3% are often associated with organic matter contents larger than 5%; (c) the very high a.s. soil probability areas mostly concur with the shallowest critical sulfide depth classes (0 to 0.4m). Notably, the use of laser scanning (i.e. Light Detection And Ranging, LiDAR) data enabled a more precise definition of the different a.s. soil probability areas, as well as the sulfur content and critical sulfide depth predictive modeling classes. Therefore, the RBF-based ANN method represents a promising approach for a.s. soil mapping and characterization, enabling the creation of reliable a.s. soil probability maps and soil property predictive maps at catchment scale.
AB - Acid sulfate (a.s.) soil mapping constitutes a fundamental step in order to plan and carry out effective mitigation at catchment scale. The main goal of this study was to assess the use of an artificial neural network (ANN) based on a Radial Basis Function (RBF) for a.s. soil mapping and characterization of soil properties relevant for environmental planning. This method was applied on the Sirppujoki River catchment (c. 440km2), located in southwestern Finland. It required using various evidential datalayers (quaternary geology, slope and aerogeophysics) and point datasets (i.e. soil profiles) and enabled the creation of probability maps for a.s. soil occurrence, as well as predictive maps for different soil properties (sulfur content, organic matter content and critical sulfur depth). For the most accurate a.s. soil probability map, the high and very high probability areas cover about 10% of the whole study area (c. 42km2) and contain all the known a.s. soil occurrences used as validation points. When considering the areas overlapping with the high and very high a.s. soil probability zones on the most accurate soil property predictive maps: (a) about 82% of these most probable areas display a predicted sulfur content between 0.3 and 1%, which is consistent with the values typically measured in the sulfidic horizons (i.e. between 0.2 and 1% in Finland); (b) the predicted organic matter content ranges between 5 and 15% in 98% of the areas of interest, indicating that sulfur contents greater than 0.3% are often associated with organic matter contents larger than 5%; (c) the very high a.s. soil probability areas mostly concur with the shallowest critical sulfide depth classes (0 to 0.4m). Notably, the use of laser scanning (i.e. Light Detection And Ranging, LiDAR) data enabled a more precise definition of the different a.s. soil probability areas, as well as the sulfur content and critical sulfide depth predictive modeling classes. Therefore, the RBF-based ANN method represents a promising approach for a.s. soil mapping and characterization, enabling the creation of reliable a.s. soil probability maps and soil property predictive maps at catchment scale.
KW - Acid sulfate soils
KW - Artificial neural network
KW - Radial basis function
KW - Soil probability mapping
KW - Soil property predictive modeling
UR - http://www.scopus.com/inward/record.url?scp=84923349199&partnerID=8YFLogxK
U2 - 10.1016/j.geoderma.2014.11.031
DO - 10.1016/j.geoderma.2014.11.031
M3 - Journal article
AN - SCOPUS:84923349199
VL - 247-248
SP - 38
EP - 50
JO - Geoderma
JF - Geoderma
SN - 0016-7061
ER -