Your search keyword '"valley depth"' showing total 3 results

1. Comparison of Different Machine Learning Methods for Predicting Cation Exchange Capacity Using Environmental and Remote Sensing Data.

Author

Saidi, Sanaz, Ayoubi, Shamsollah, Shirvani, Mehran, Azizi, Kamran, and Zeraatpisheh, Mojtaba

Subjects

*SOIL moisture, *REMOTE sensing, *MACHINE learning, *STANDARD deviations, *SILT loam, *SUPPORT vector machines

Abstract

This study was conducted to examine the capability of topographic features and remote sensing data in combination with other auxiliary environmental variables (geology and geomorphology) to predict CEC by using different machine learning models ((random forest (RF), k-nearest neighbors (kNNs), Cubist model (Cu), and support vector machines (SVMs)) in the west of Iran. Accordingly, the collection of ninety-seven soil samples was performed from the surface layer (0–20 cm), and a number of soil properties and X-ray analyses, as well as CEC, were determined in the laboratory. The X-ray analysis showed that the clay types as the main dominant factor on CEC varied from illite to smectite. The results of modeling also displayed that in the training dataset based on 10-fold cross-validation, RF was identified as the best model for predicting CEC (R2 = 0.86; root mean square error: RMSE = 2.76; ratio of performance to deviation: RPD = 2.67), whereas the Cu model outperformed in the validation dataset (R2 = 0.49; RMSE = 4.51; RPD = 1.43)). RF, the best and most accurate model, was thus used to prepare the CEC map. The results confirm higher CEC in the early Quaternary deposits along with higher soil development and enrichment with smectite and vermiculite. On the other hand, lower CEC was observed in mountainous and coarse-textured soils (silt loam and sandy loam). The important variable analysis also showed that some topographic attributes (valley depth, elevation, slope, terrain ruggedness index—TRI) and remotely sensed data (ferric oxides, normalized difference moisture index—NDMI, and salinity index) could be considered as the most imperative variables explaining the variability of CEC by the best model in the study area. [ABSTRACT FROM AUTHOR]

Published

2022

2. Comparison of Different Machine Learning Methods for Predicting Cation Exchange Capacity Using Environmental and Remote Sensing Data

Author

Sanaz Saidi, Shamsollah Ayoubi, Mehran Shirvani, Kamran Azizi, and Mojtaba Zeraatpisheh

Subjects

clay type, mineralogy, remote sensing indices, valley depth, soil modeling, machine learning, Chemical technology, TP1-1185

Abstract

This study was conducted to examine the capability of topographic features and remote sensing data in combination with other auxiliary environmental variables (geology and geomorphology) to predict CEC by using different machine learning models ((random forest (RF), k-nearest neighbors (kNNs), Cubist model (Cu), and support vector machines (SVMs)) in the west of Iran. Accordingly, the collection of ninety-seven soil samples was performed from the surface layer (0–20 cm), and a number of soil properties and X-ray analyses, as well as CEC, were determined in the laboratory. The X-ray analysis showed that the clay types as the main dominant factor on CEC varied from illite to smectite. The results of modeling also displayed that in the training dataset based on 10-fold cross-validation, RF was identified as the best model for predicting CEC (R2 = 0.86; root mean square error: RMSE = 2.76; ratio of performance to deviation: RPD = 2.67), whereas the Cu model outperformed in the validation dataset (R2 = 0.49; RMSE = 4.51; RPD = 1.43)). RF, the best and most accurate model, was thus used to prepare the CEC map. The results confirm higher CEC in the early Quaternary deposits along with higher soil development and enrichment with smectite and vermiculite. On the other hand, lower CEC was observed in mountainous and coarse-textured soils (silt loam and sandy loam). The important variable analysis also showed that some topographic attributes (valley depth, elevation, slope, terrain ruggedness index—TRI) and remotely sensed data (ferric oxides, normalized difference moisture index—NDMI, and salinity index) could be considered as the most imperative variables explaining the variability of CEC by the best model in the study area.

Published

2022

3. The definitions of stream heads on dems and their effects on stream numbers and length

Author

Nakayama, Daichi

Subjects

valley depth, DEMs, exterior links, drainage area, stream head definition

Abstract

Three topographical parameters, drainage area. exterior links and valley depth, are calculated as the criteria to define stream heads on digital elevation models in this study. Their variations effect on Horton-Strahler ordered stream numbers and length. Three topographical parameters are classified into two types. "Successive" and "non-successive" parameter is determined by whether it increases successively from upstream or not. The differences between two parameters cause whether stream numbers decrements and length increments associated with threshold increments have fluctuations or not. Moreover, order transition styles of successive parameters are singledirectional, such as lower order to higher order stream, and those of non-successive parameters are bi-directional. This indicates that Horton-Strahler ordered streams are largely influenced by the threshold parameters.

Published

1997