Your search keyword '"Guangzhi Rong"' showing total 20 results

1. Hazard Assessment of Earthquake Disaster Chains Based on Deep Learning—A Case Study of Mao County, Sichuan Province

Author

Yulin Su, Guangzhi Rong, Yining Ma, Junwen Chi, Xingpeng Liu, Jiquan Zhang, and Tiantao Li

Subjects

hazard assessment, earthquake disaster chains, geological disasters, deep neural networks (DNN) model, machine learning, Science

Abstract

Chain disasters often cause greater casualties and economic losses than single disasters. It plays an important role in the prevention and control to draw the susceptibility map and hazard map of geological hazards. To the best of our knowledge, the existing models are not suitable for the study of earthquake–geological disaster chains. Therefore, this study aims to establish a DNN model suitable for the study of earthquake–geological disaster chains. Firstly, nine key factors affecting geological disasters were selected and multi-source data sets were established based on geological disaster points in the study area. Secondly, the DNN model is trained to calculate the susceptibility of landslides and is discussed with the Support Vector Machine (SVM) model, Logistic Regression (LR) model, and Random Forest (RF) model. Finally, verify with the ROC curve. The verification results show that the DNN model has the highest accuracy among the proposed models. It is suitable for drawing geological hazard susceptibility maps and hazard maps. Therefore, it is proved that the model can be applied for the prediction of chain disasters and is a promising tool for geological hazard assessment.

Published

2022

2. Spatiotemporal Characteristics and Hazard Assessments of Maize (Zea mays L.) Drought and Waterlogging: A Case Study in Songliao Plain of China

Author

Rui Wang, Guangzhi Rong, Cong Liu, Walian Du, Jiquan Zhang, Zhijun Tong, and Xingpeng Liu

Subjects

TVDI, water stress, hazard assessment, maize, Science

Abstract

The Songliao Plain is the largest maize (Zea mays L.) cropland area in China and, thus, is most influenced by water stress. To mitigate the adverse impact of water stress on maize yield and quality, various agricultural irrigation strategies have been implemented. Based on land surface temperature and an enhanced vegetation index, this study constructed the temperature vegetation dryness index (TVDI) and combined the Hurst index and Sen trend to analyze the spatiotemporal characteristics of drought and waterlogging. From the correlation between TVDI and gross primary productivity, the weight coefficients of different growth cycles of maize were derived to determine the drought and waterlogging stresses on maize in Songliao Plain for 2000–2020. The drought hazard on the western side of Songliao Plain was high in the west and low in the east, whereas the waterlogging hazard was high in the east. Waterlogging likely persisted according to the spatiotemporal trends and patterns of drought and waterlogging. During the second growth cycle, maize was most severely affected by water stress. There was a spatial heterogeneity in the severity of the hazards and the stress degree of maize. For the reason that precipitation in the study area was concentrated between mid-late July and early August, maize was susceptible to drought stress during the first two growth stages. Irrigation concentrated in the early and middle stages of maize growth and development in the western part of the Songliao Plain reduced the drought stress-induced damage. Spatiotemporally-detected drought and waterlogging couplings and hazards for maize in the Songliao Plain for 2000–2020 provide actionable insights into the prevention and mitigation of such disasters and the implementation of water-saving irrigation practices at the regional scale.

Published

2023

3. Dynamic Evaluation of Agricultural Drought Hazard in Northeast China Based on Coupled Multi-Source Data

Author

Kaiwei Li, Chunyi Wang, Guangzhi Rong, Sicheng Wei, Cong Liu, Yueting Yang, Bilige Sudu, Ying Guo, Qing Sun, and Jiquan Zhang

Subjects

drought hazard, multi-source data, dynamic evaluation, drought and heat, Science

Abstract

As the climate warms, the impact of drought on plants has increased. We aimed to construct a comprehensive drought index (CDI), coupling soil-vegetation-atmosphere drought and heat conditions based on multi-source information, and to combine it with static and dynamic drought hazard evaluation models to analyze the spatial and temporal distribution characteristics of agricultural drought disasters and hazards during the growing season (May to September) in Northeast China (NEC). The results demonstrated that the CDI could combine the benefits of meteorology (standardized precipitation evapotranspiration index, SPEI), vegetation (vegetation health index, VHI), and soil (standardized soil moisture condition index, SMCI) indices. This was performed using a relative weighting method based on the remote sensing data of solar-induced chlorophyll fluorescence (SIF) to determine the weights of SPEI, VHI, and SMCI. The CDI for drought monitoring has the advantages of broad spatial range, long time range, and high accuracy, and can effectively reflect agricultural drought; the growing season in NEC showed a trend of becoming drier during 1982–2020. However, the trends of the drought index, the impact range of drought events, and the hazard of agricultural drought all turned around 2000. The drought hazard was highly significant (p < 0.001) and decreased from 2000 to 2020. The frequency of drought disasters was the highest, and the hazard was the greatest in May. The best level of climatic yield anomalies in maize were explained by drought hazard in August (R2 = 0.28). In the center and western portions of the study area, farmland and grassland areas were where higher levels of hazard were most commonly seen. The dynamic hazard index is significantly correlated with climatic yield anomalies and can reflect the actual impact of drought on crop yield. The study results serve as a scientific foundation for drought risk assessment and management, agricultural planning, and the formulation of drought adaptation policies, as well as for ensuring food security in China.

Published

2022

4. Retrieving SPAD Values of Summer Maize Using UAV Hyperspectral Data Based on Multiple Machine Learning Algorithm

Author

Bilige Sudu, Guangzhi Rong, Suri Guga, Kaiwei Li, Feng Zhi, Ying Guo, Jiquan Zhang, and Yulong Bao

Subjects

UAV, hyperspectral data, successive projection algorithm, XGBoost, deep neural network (DNN), Science

Abstract

Using unmanned aerial vehicle (UAV) hyperspectral images to accurately estimate the chlorophyll content of summer maize is of great significance for crop growth monitoring, fertilizer management, and the development of precision agriculture. Hyperspectral imaging data, analytical spectral devices (ASD) data, and SPAD values of summer maize in different key growth periods were obtained under the conditions of a micro-spray strip drip irrigation water supply. The hyperspectral data were preprocessed by spectral transformation methods. Then, several algorithms including Findpeaks (FD), competitive adaptive reweighted sampling (CARS), successive projections algorithm (SPA), and CARS_SPA were used to extract the sensitive characteristic bands related to SPAD values from the hyperspectral image data obtained by UAV. Subsequently, four machine learning regression models including partial least squares regression (PLSR), random forest (RF), extreme gradient boosting (XGBoost), and deep neural network (DNN) were used to establish SPAD value estimation models. The results showed that the correlation coefficient between the ASD and UAV hyperspectral data was greater than 0.96 indicating that UAV hyperspectral image data could be used to estimate maize growth information. The characteristic bands selected by different algorithms were slightly different. The CARS_SPA algorithm could effectively extract sensitive hyperspectral characteristics. This algorithm not only greatly reduced the number of hyperspectral characteristics but also improved the multiple collinearity problem. The low frequency information of SSR in spectral transformation could significantly improve the spectral estimation ability for SPAD values of summer maize. In the accuracy verification of PLSR, RF, XGBoost, and the DNN inversion model based on SSR and CARS_SPA, the determination coefficients (R2) were 0.81, 0.42, 0.65, and 0.82, respectively. The inversion accuracy based on the DNN model was better than the other models. Compared with high-frequency information, low-frequency information (DNN model based on SSR and CARS_SPA) had a strong estimating ability for SPAD values in summer maize canopy. This study provides a reference and technical support for the rapid non-destructive testing of summer maize.

Published

2022

5. Comparison of Tree-Structured Parzen Estimator Optimization in Three Typical Neural Network Models for Landslide Susceptibility Assessment

Author

Guangzhi Rong, Kaiwei Li, Yulin Su, Zhijun Tong, Xingpeng Liu, Jiquan Zhang, Yichen Zhang, and Tiantao Li

Subjects

landslide susceptibility assessment, deep neural network, recurrent neural network, convolutional neural network, hyperparameter optimization, tree-structured Parzen estimator algorithm, Science

Abstract

Landslides pose a constant threat to the lives and property of mountain people and may also cause geomorphological destruction such as soil and water loss, vegetation destruction, and land cover change. Landslide susceptibility assessment (LSA) is a key component of landslide risk evaluation. There are many related studies, but few analyses and comparisons of models for optimization. This paper aims to introduce the Tree-structured Parzen Estimator (TPE) algorithm for hyperparameter optimization of three typical neural network models for LSA in Shuicheng County, China, as an example, and to compare the differences of predictive ability among the models in order to achieve higher application performance. First, 17 influencing factors of landslide multiple data sources were selected for spatial prediction, hybrid ensemble oversampling and undersampling techniques were used to address the imbalanced sample and small sample size problem, and the samples were randomly divided into a training set and validation set. Second, deep neural network (DNN), recurrent neural network (RNN), and convolutional neural network (CNN) models were adopted to predict the regional landslides susceptibility, and the TPE algorithm was used to optimize the hyperparameters respectively to improve the assessment capacity. Finally, to compare the differences and optimization effects of these models, several objective measures were applied for validation. The results show that the high-susceptibility regions mostly distributed in bands along fault zones, where the lithology is mostly claystone, sandstone, and basalt. The DNN, RNN, and CNN models all perform well in LSA, especially the RNN model. The TPE optimization significantly improves the accuracy of the DNN and CNN (3.92% and 1.52%, respectively), but does not improve the performance of the RNN. In summary, our proposed RNN model and TPE-optimized DNN and CNN model have robust predictive capability for landslide susceptibility in the study area and can also be applied to other areas containing similar geological conditions.

Published

2021

6. Estimation of Frost Hazard for Tea Tree in Zhejiang Province Based on Machine Learning

Author

Jie Xu, Suri Guga, Guangzhi Rong, Dao Riao, Xingpeng Liu, Kaiwei Li, and Jiquan Zhang

Subjects

tea tree, frost disaster, machine learning, frost hazard, space distribution, Agriculture (General), S1-972

Abstract

Tea trees are the main economic crop in Zhejiang Province. However, spring cold is a frequent occurrence there, causing frost damage to the valuable tea buds. To address this, a regional frost-hazard early-warning system is needed. In this study, frost damage area was estimated based on topography and meteorology, as well as longitude and latitude. Based on support vector machine (SVM) and artificial neural networks (ANNs), a multi-class classification model was proposed to estimate occurrence of regional frost disasters using tea frost cases from 2017. Results of the two models were compared, and optimal parameters were adjusted through multiple iterations. The highest accuracies of the two models were 83.8% and 75%, average accuracies were 79.3% and 71.3%, and Kappa coefficients were 79.1% and 67.37%. The SVM model was selected to establish spatial distribution of spring frost damage to tea trees in Zhejiang Province in 2016. Pearson’s correlation coefficient between prediction results and meteorological yield was 0.79 (p < 0.01), indicating consistency. Finally, the importance of model factors was assessed using sensitivity analysis. Results show that relative humidity and wind speed are key factors influencing accuracy of predictions. This study supports decision-making for hazard prediction and defense for tea trees facing frost.

Published

2021

7. Spring Phenological Sensitivity to Climate Change in the Northern Hemisphere: Comprehensive Evaluation and Driving Force Analysis

Author

Kaiwei Li, Chunyi Wang, Qing Sun, Guangzhi Rong, Zhijun Tong, Xingpeng Liu, and Jiquan Zhang

Subjects

vegetation phenology, climate change, phenological sensitivity, start of the growing season, driving force, partial least squares regression, Science

Abstract

Plant phenology depends largely on temperature, but temperature alone cannot explain the Northern Hemisphere shifts in the start of the growing season (SOS). The spatio–temporal distribution of SOS sensitivity to climate variability has also changed in recent years. We applied the partial least squares regression (PLSR) method to construct a standardized SOS sensitivity evaluation index and analyzed the combined effects of air temperature (Tem), water balance (Wbi), radiation (Srad), and previous year’s phenology on SOS. The spatial and temporal distributions of SOS sensitivity to Northern Hemisphere climate change from 1982 to 2014 were analyzed using time windows of 33 and 15 years; the dominant biological and environmental drivers were also assessed. The results showed that the combined sensitivity of SOS to climate change (SCom) is most influenced by preseason temperature sensitivity. However, because of the asymmetric response of SOS to daytime/night temperature (Tmax/Tmin) and non-negligible moderating of Wbi and Srad on SOS, SCom was more effective in expressing the effect of climate change on SOS than any single climatic factor. Vegetation cover (or type) was the dominant factor influencing the spatial pattern of SOS sensitivity, followed by spring temperature (Tmin > Tmax), and the weakest was water balance. Forests had the highest SCom absolute values. A significant decrease in the sensitivity of some vegetation (22.2%) led to a decreasing trend in sensitivity in the Northern Hemisphere. Although temperature remains the main climatic factor driving temporal changes in SCom, the temperature effects were asymmetric between spring and winter (Tems/Temw). More moisture might mitigate the asymmetric response of SCom to spring/winter warming. Vegetation adaptation has a greater influence on the temporal variability of SOS sensitivity relative to each climatic factor (Tems, Temw, Wbi, Srad). More moisture might mitigate the asymmetric response of SCom to spring/winter warming. This study provides a basis for vegetation phenology sensitivity assessment and prediction.

Published

2021

8. Population amount risk assessment of extreme precipitation-induced landslides based on integrated machine learning model and scenario simulation

Author

Guangzhi Rong, Kaiwei Li, Zhijun Tong, Xingpeng Liu, Jiquan Zhang, Yichen Zhang, and Tiantao Li

Subjects

General Earth and Planetary Sciences

Published

2023

9. Early warning and scenario simulation of ecological security based on DPSIRM model and Bayesian network: A case study of east Liaohe river in Jilin Province, China

Author

Walian Du, Xiaoyu Liao, Zhijun Tong, Su Rina, Guangzhi Rong, Jiquan Zhang, Xingpeng Liu, and Enliang Guo

Subjects

Renewable Energy, Sustainability and the Environment, Strategy and Management, Building and Construction, Industrial and Manufacturing Engineering, General Environmental Science

Published

2023

10. Comparison of Tree-Structured Parzen Estimator Optimization in Three Typical Neural Network Models for Landslide Susceptibility Assessment

Author

Tiantao Li, Zhijun Tong, Guangzhi Rong, Xingpeng Liu, Kaiwei Li, Jiquan Zhang, Yichen Zhang, and Yulin Su

Subjects

Hyperparameter, Artificial neural network, Computer science, business.industry, Science, deep neural network, Estimator, convolutional neural network, Pattern recognition, Landslide, Convolutional neural network, Tree (data structure), landslide susceptibility assessment, tree-structured Parzen estimator algorithm, Recurrent neural network, Hyperparameter optimization, General Earth and Planetary Sciences, recurrent neural network, Artificial intelligence, hyperparameter optimization, business

Abstract

Landslides pose a constant threat to the lives and property of mountain people and may also cause geomorphological destruction such as soil and water loss, vegetation destruction, and land cover change. Landslide susceptibility assessment (LSA) is a key component of landslide risk evaluation. There are many related studies, but few analyses and comparisons of models for optimization. This paper aims to introduce the Tree-structured Parzen Estimator (TPE) algorithm for hyperparameter optimization of three typical neural network models for LSA in Shuicheng County, China, as an example, and to compare the differences of predictive ability among the models in order to achieve higher application performance. First, 17 influencing factors of landslide multiple data sources were selected for spatial prediction, hybrid ensemble oversampling and undersampling techniques were used to address the imbalanced sample and small sample size problem, and the samples were randomly divided into a training set and validation set. Second, deep neural network (DNN), recurrent neural network (RNN), and convolutional neural network (CNN) models were adopted to predict the regional landslides susceptibility, and the TPE algorithm was used to optimize the hyperparameters respectively to improve the assessment capacity. Finally, to compare the differences and optimization effects of these models, several objective measures were applied for validation. The results show that the high-susceptibility regions mostly distributed in bands along fault zones, where the lithology is mostly claystone, sandstone, and basalt. The DNN, RNN, and CNN models all perform well in LSA, especially the RNN model. The TPE optimization significantly improves the accuracy of the DNN and CNN (3.92% and 1.52%, respectively), but does not improve the performance of the RNN. In summary, our proposed RNN model and TPE-optimized DNN and CNN model have robust predictive capability for landslide susceptibility in the study area and can also be applied to other areas containing similar geological conditions.

Published

2021

11. Analysis of Characteristics of Dry–Wet Events Abrupt Alternation in Northern Shaanxi, China

Author

Guangzhi Rong, Jiquan Zhang, Junhui Wang, and Kaiwei Li

Subjects

Return period, Water supply for domestic and industrial purposes, Marginal distribution function, Cumulative distribution function, Geography, Planning and Development, Hydraulic engineering, Aquatic Science, return period, Biochemistry, Copula (probability theory), Joint probability distribution, Climatology, Alternation (formal language theory), copula, DWAAI, Precipitation, spatial distribution characteristics, TC1-978, TD201-500, Geology, Water Science and Technology

Abstract

In this study, Yulin city and Yan’an city in northern Shaanxi Province were taken as the study area. Based on the diurnal dry–wet events abrupt alternation index DWAAI, the joint probability distribution of two characteristic variables of “urgency” and “alternation” of dry–wet events abrupt alternation was established by using copula function, and the characteristics of dry–wet events abrupt alternation were analyzed. DWAAI was calculated from daily precipitation data and the applicability of the index was verified. On this basis, the two characteristic variables of “urgency” and “alternation” were separated, and the appropriate marginal distribution function was selected to fit them, and the correlation between the two variables was evaluated. Finally, the appropriate copula function was selected to fit the bivariate of each station, and the joint cumulative probability and recurrence period of the two variables were calculated. The results show that the DWAAI index is suitable for the identification of dry–wet events abrupt alternation in the study area. Light and moderate dry–wet events abrupt alternation occurs more frequently, while severe events rarely occur in the study area. The frequency of severe dry–wet events abrupt alternation in Jingbian station and its northern area is greater than that in the southern area, and the risk of dry–wet events abrupt alternation of disasters in the northern area is higher. The greater the degree of “urgency” and “alternation”, the greater the joint cumulative probability and the greater the return period. The return period of severe dry–wet events abrupt alternation was more than five years, while the return period of light and moderate dry–wet events abrupt alternation was less than five years.

Published

2021

12. Spatial-Temporal Change of Land Use and Its Impact on Water Quality of East-Liao River Basin from 2000 to 2020

Author

Zhijun Tong, Jiquan Zhang, Dao Riao, Guangzhi Rong, Aru Han, Mingxi Zhang, and Xingpeng Liu

Subjects

Pollution, land use change, 010504 meteorology & atmospheric sciences, media_common.quotation_subject, Geography, Planning and Development, Drainage basin, 010501 environmental sciences, Aquatic Science, 01 natural sciences, Biochemistry, water quality, grey correlation degree, Land use, land-use change and forestry, transfer matrix, TD201-500, 0105 earth and related environmental sciences, Water Science and Technology, media_common, Hydrology, geography, geography.geographical_feature_category, Land use, Water supply for domestic and industrial purposes, business.industry, Lawn, Hydraulic engineering, Agriculture, Environmental science, Water quality, business, Surface runoff, TC1-978

Abstract

Land use change is an important driving force factor affecting the river water environment and directly affecting water quality. To analyze the impact of land use change on water quality change, this study first analyzed the land use change index of the study area. Then, the study area was divided into three subzones based on surface runoff. The relationship between the characteristics of land use change and the water quality grade was obtained by grey correlation analysis. The results showed that the land use types changed significantly in the study area since 2000, and water body and forest land were the two land types with the most significant changes. The transfer rate is cultivated field &gt, forest land &gt, construction land &gt, grassland &gt, unused land &gt, water body. The entropy value of land use information is represented as Area I &gt, Area III &gt, Area II. The shift range of gravity center is forest land &gt, water body &gt, cultivated field. There is a strong correlation between land use change index and water quality, which can be improved and managed by changing the land use type. It is necessary to establish ecological protection areas or functional areas in Area I, artificial lawns or plantations shall be built in the river around the water body to intercept pollutants from non-point source pollution in Area II, and scientific and rational farming in the lower reaches of rivers can reduce non-point source pollution caused by farming.

Published

2021

13. Estimation of Frost Hazard for Tea Tree in Zhejiang Province Based on Machine Learning

Author

Dao Riao, kaiwei Li, Xingpeng Liu, Guangzhi Rong, Jiquan Zhang, Suri Guga, and Jie Xu

Subjects

010504 meteorology & atmospheric sciences, Correlation coefficient, Agriculture (General), 0208 environmental biotechnology, frost disaster, 02 engineering and technology, Plant Science, 01 natural sciences, Wind speed, S1-972, Statistics, 0105 earth and related environmental sciences, Mathematics, Estimation, Tea tree, frost hazard, Hazard, 020801 environmental engineering, Support vector machine, Key factors, machine learning, Frost, tea tree, space distribution, Agronomy and Crop Science, Food Science

Abstract

Tea trees are the main economic crop in Zhejiang Province. However, spring cold is a frequent occurrence there, causing frost damage to the valuable tea buds. To address this, a regional frost-hazard early-warning system is needed. In this study, frost damage area was estimated based on topography and meteorology, as well as longitude and latitude. Based on support vector machine (SVM) and artificial neural networks (ANNs), a multi-class classification model was proposed to estimate occurrence of regional frost disasters using tea frost cases from 2017. Results of the two models were compared, and optimal parameters were adjusted through multiple iterations. The highest accuracies of the two models were 83.8% and 75%, average accuracies were 79.3% and 71.3%, and Kappa coefficients were 79.1% and 67.37%. The SVM model was selected to establish spatial distribution of spring frost damage to tea trees in Zhejiang Province in 2016. Pearson’s correlation coefficient between prediction results and meteorological yield was 0.79 (p &lt, 0.01), indicating consistency. Finally, the importance of model factors was assessed using sensitivity analysis. Results show that relative humidity and wind speed are key factors influencing accuracy of predictions. This study supports decision-making for hazard prediction and defense for tea trees facing frost.

Published

2021

14. Spring Phenological Sensitivity to Climate Change in the Northern Hemisphere: Comprehensive Evaluation and Driving Force Analysis

Author

Zhijun Tong, Xingpeng Liu, Chunyi Wang, Kaiwei Li, Guangzhi Rong, Jiquan Zhang, and Qing Sun

Subjects

0106 biological sciences, vegetation phenology, Daytime, 010504 meteorology & atmospheric sciences, Phenology, Science, Northern Hemisphere, partial least squares regression, Climate change, Growing season, Vegetation, Atmospheric sciences, 010603 evolutionary biology, 01 natural sciences, Water balance, phenological sensitivity, climate change, start of the growing season, driving force, General Earth and Planetary Sciences, Common spatial pattern, Environmental science, 0105 earth and related environmental sciences

Abstract

Plant phenology depends largely on temperature, but temperature alone cannot explain the Northern Hemisphere shifts in the start of the growing season (SOS). The spatio–temporal distribution of SOS sensitivity to climate variability has also changed in recent years. We applied the partial least squares regression (PLSR) method to construct a standardized SOS sensitivity evaluation index and analyzed the combined effects of air temperature (Tem), water balance (Wbi), radiation (Srad), and previous year’s phenology on SOS. The spatial and temporal distributions of SOS sensitivity to Northern Hemisphere climate change from 1982 to 2014 were analyzed using time windows of 33 and 15 years; the dominant biological and environmental drivers were also assessed. The results showed that the combined sensitivity of SOS to climate change (SCom) is most influenced by preseason temperature sensitivity. However, because of the asymmetric response of SOS to daytime/night temperature (Tmax/Tmin) and non-negligible moderating of Wbi and Srad on SOS, SCom was more effective in expressing the effect of climate change on SOS than any single climatic factor. Vegetation cover (or type) was the dominant factor influencing the spatial pattern of SOS sensitivity, followed by spring temperature (Tmin > Tmax), and the weakest was water balance. Forests had the highest SCom absolute values. A significant decrease in the sensitivity of some vegetation (22.2%) led to a decreasing trend in sensitivity in the Northern Hemisphere. Although temperature remains the main climatic factor driving temporal changes in SCom, the temperature effects were asymmetric between spring and winter (Tems/Temw). More moisture might mitigate the asymmetric response of SCom to spring/winter warming. Vegetation adaptation has a greater influence on the temporal variability of SOS sensitivity relative to each climatic factor (Tems, Temw, Wbi, Srad). More moisture might mitigate the asymmetric response of SCom to spring/winter warming. This study provides a basis for vegetation phenology sensitivity assessment and prediction.

Published

2021

15. Rainfall Induced Landslide Susceptibility Mapping Based on Bayesian Optimized Random Forest and Gradient Boosting Decision Tree Models—A Case Study of Shuicheng County, China

Author

Si Alu, Kaiwei Li, Yichen Zhang, Jiquan Zhang, Yulin Su, Guangzhi Rong, and Tiantao Li

Subjects

lcsh:Hydraulic engineering, Gradient boosting decision tree, 010504 meteorology & atmospheric sciences, Computer science, Geography, Planning and Development, Bayesian probability, Aquatic Science, 010502 geochemistry & geophysics, computer.software_genre, 01 natural sciences, Biochemistry, lcsh:Water supply for domestic and industrial purposes, lcsh:TC1-978, Sample problem, gradient boosting decision tree, 0105 earth and related environmental sciences, Water Science and Technology, Bayesian optimization, Hyperparameter, lcsh:TD201-500, Landslide, Landslide susceptibility, Random forest, imbalanced sample, landslide susceptibility mapping, Data mining, computer, random forest

Abstract

Among the most frequent and dangerous natural hazards, landslides often result in huge casualties and economic losses. Landslide susceptibility mapping (LSM) is an excellent approach for protecting and reducing the risks by landslides. This study aims to explore the performance of Bayesian optimization (BO) in the random forest (RF) and gradient boosting decision tree (GBDT) model for LSM and applied in Shuicheng County, China. Multiple data sources are used to obtain 17 conditioning factors of landslides, Borderline-SMOTE and Randomundersample methods are combined to solve the imbalanced sample problem. RF and GBDT models before and after BO are adopted to calculate the susceptibility value of landslides and produce LSMs and these models were compared and evaluated using multiple validation approach. The results demonstrated that the models we proposed all have high enough model accuracy to be applied to produce LSM, the performance of the RF is better than the GBDT model without BO, while after adopting the Bayesian optimized hyperparameters, the prediction accuracy of the RF and GBDT models is improved by 1% and 7%, respectively and the Bayesian optimized GBDT model is the best for LSM in this four models. In summary, the Bayesian optimized RF and GBDT models, especially the GBDT model we proposed for landslide susceptibility assessment and LSM construction has a very good application performance and development prospects.

Published

2020

16. Ecological risk and early warning of soil compound pollutants (HMs, PAHs, PCBs and OCPs) in an industrial city, Changchun, China

Author

Yanan Chen, Jingyao Peng, Jiquan Zhang, Qing Xia, and Guangzhi Rong

Subjects

China, 010504 meteorology & atmospheric sciences, Soil test, Health, Toxicology and Mutagenesis, 010501 environmental sciences, Toxicology, 01 natural sciences, Soil, Metals, Heavy, Hydrocarbons, Chlorinated, Soil Pollutants, Ecological risk, Cities, Pesticides, Polycyclic Aromatic Hydrocarbons, 0105 earth and related environmental sciences, Pollutant, Warning system, Organochlorine pesticide, Heavy metals, General Medicine, Contamination, Pollution, Polychlorinated Biphenyls, Environmental chemistry, Environmental science, Environmental Pollutants, Industrial city, Environmental Monitoring

Abstract

Soil ecological risk caused by compound pollutants is a topic that deserves increasing attention, and soil risk early warning is a more in-depth discussion on this topic. In this study, we collected soil samples from Changchun, a typical industrial city, and determined the contents of 13 heavy metals (HMs) (0.00 mg kg−1-6380 mg kg−1), 16 polycyclic aromatic hydrocarbons (PAHs) (0.00 mg kg−1-27.7 mg kg−1), 7 polychlorinated biphenyls (PCBs) (0.30 μg kg−1-168 μg kg−1), and 8 organochlorine pesticides (OCPs) (0.00 mg kg−1-4.52 mg kg−1). The soil ecological risks of compound pollutants were assessed. The results showed that PAHs were the greatest risk pollutants, followed by PCBs and HMs, and OCPs were the smallest risk pollutants. Most of the ecological risks of compound pollutants were classified as “moderate severity” level according to the (contamination severity index) CSI evaluation criteria. With the help of modern industrial economic theory, through the analysis of the annual accumulation of pollutants, it is possible to predict the future pollutant content in Changchun, and the soil risks could be forewarned. The results showed that if active measures were not taken to reduce the accumulation of PAHs in Changchun soil, the CSI-PAHs would be classified as “ultra-high severity” level in 2035.

Published

2020

17. Debris Flow Susceptibility Assessment Using the Integrated Random Forest Based Steady-State Infinite Slope Method: A Case Study in Changbai Mountain, China

Author

Zhenhua Dong, Emmanuel Kazuva, Yichen Zhang, Jiquan Zhang, Yongbin Bao, Alu Si, and Guangzhi Rong

Subjects

debris flow susceptibility assessment, lcsh:TD201-500, Steady state, lcsh:Hydraulic engineering, 010504 meteorology & atmospheric sciences, Heuristic (computer science), random forest model, Geography, Planning and Development, Probabilistic logic, random forest model based steady state infinite slope method, Terrain, Soil science, Aquatic Science, 010502 geochemistry & geophysics, 01 natural sciences, Biochemistry, Random forest, Debris flow, lcsh:Water supply for domestic and industrial purposes, lcsh:TC1-978, Geology, 0105 earth and related environmental sciences, Water Science and Technology, steady state infinite slope method

Abstract

Debris flow events often pose significant damage and are a threat to infrastructure and even livelihoods. Recent studies have mainly focused on determining the susceptibility of debris flow using deterministic or heuristic/probabilistic models. However, each type of model has its own significant advantages with some irreparable disadvantages. The random forest model, which is sensitive to the region where the terrain conditions are suitable for the occurrence of debris flow, was applied along with the steady-state infinite slope method, which is capable of describing the initiation mechanism of debris flow. In this manner, a random-forest-based steady-state infinite slope method was used to conduct susceptibility assessment of debris-flow at Changbai mountain area. Results showed that the assessment accuracy of the proposed random-forest-based steady-state infinite slope method reached 90.88%, however, the accuracy of just the random forest model or steady-state infinite slope method was only 88.48% or 60.45%, respectively. Compared with the single-model assessment results, the assessment accuracy of the proposed method improved by 2.4% and 30.43%, respectively. Meanwhile, the debris-flow-prone area of the proposed method was reduced. The random-forest-based steady-state infinite slope method inherited the excellent diagnostic performance of the random-forest models in the region where the debris flow disaster already occurred, meanwhile, this method further refined the debris-flow-prone area from the suitable terrain area based on physico-mechanical properties, thus, the performance of this method was better than those of the other two models.

Published

2020

18. Analysis of Drought Characteristics in Northern Shaanxi Based on Copula Function

Author

Kaiwei Li, Jiquan Zhang, Guangzhi Rong, and Junhui Wang

Subjects

joint return period, Return period, Geography, Planning and Development, SPI, drought, Aquatic Science, Biochemistry, Copula (probability theory), Generalized Pareto distribution, Joint probability distribution, parasitic diseases, Precipitation, High severity, TD201-500, Short duration, Water Science and Technology, Water supply for domestic and industrial purposes, Cumulative distribution function, fungi, food and beverages, Hydraulic engineering, copula, Environmental science, run theory, Northern Shaanxi, Physical geography, TC1-978

Abstract

Precipitation is low and drought occurs frequently in Northern Shaanxi. To study the characteristics and occurrence and development of drought events in Northern Shaanxi is beneficial to the prevention and control of drought disasters. Based on the monthly rainfall data of 10 meteorological stations in Northern Shaanxi from 1960 to 2019, the characteristic variables of drought events at each meteorological station in Northern Shaanxi were extracted by using run theory and copula function. The joint probability distribution and recurrence period were obtained by combining the duration and intensity of drought, and the relationship between drought characteristics and crop drought affected area was studied. The results show that (1) from 1960 to 2019, drought events mainly occurred in Northern Shaanxi with long duration and low severity, short duration and high severity, or short duration and low severity, among which the frequency of drought events that occurred in Yuyang and Baota districts was higher. The frequency of light drought and extreme drought was more in the south and less in the north, while the frequency of moderate drought and severe drought was more in the north and less in the south. (2) The optimal edge distribution of drought intensity and drought duration in Northern Shaanxi is generalized Pareto distribution, and the optimal fitting function is Frank copula function. The greater the duration and intensity of drought, the greater the cumulative probability and return period. (3) The actual recurrence interval and the theoretical recurrence interval of drought events in Northern Shaanxi were close, and the error was only 0.1–0.3a. The results of the joint return period can accurately reflect the actual situation, and this study can provide effective guidance for the prevention and management of agricultural dryland in Northern Shaanxi.

Published

2021

19. Hazard Mapping of the Rainfall–Landslides Disaster Chain Based on GeoDetector and Bayesian Network Models in Shuicheng County, China

Author

Yichen Zhang, Jiquan Zhang, Lina Han, Guangzhi Rong, Si Alu, and Kaiwei Li

Subjects

Hazard mapping, lcsh:Hydraulic engineering, 010504 meteorology & atmospheric sciences, Computer science, Landslide classification, GeoDetector model, Geography, Planning and Development, 0211 other engineering and technologies, disaster chain, Word error rate, 02 engineering and technology, Aquatic Science, computer.software_genre, 01 natural sciences, Biochemistry, lcsh:Water supply for domestic and industrial purposes, lcsh:TC1-978, Natural hazard, Bayesian network model, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Water Science and Technology, lcsh:TD201-500, Emergency management, business.industry, Bayesian network, Landslide, Matthews correlation coefficient, Data mining, business, computer, landslide hazard mapping

Abstract

Landslides are among the most frequent natural hazards in the world. Rainfall is an important triggering factor for landslides and is responsible for topples, slides, and debris flows&mdash, three of the most important types of landslides. However, several previous relevant research studies covered general landslides and neglected the rainfall&ndash, topples&ndash, slides&ndash, debris flows disaster chain. Since landslide hazard mapping (LHM) is a critical tool for disaster prevention and mitigation, this study aimed to build a GeoDetector and Bayesian network (BN) model framework for LHM in Shuicheng County, China, to address these geohazards. The GeoDetector model will be used to screen factors, eliminate redundant information, and discuss the interaction between elements, while the BN model will be used for constructing a causality disaster chain network to determine the probability and risk level of the three types of landslides. The practicability of the BN model was confirmed by error rate and scoring rules validation. The prediction accuracy results were tested using overall accuracy, Matthews correlation coefficient, relative operating characteristics curve, and seed cell area index. The proposed framework is demonstrated to be sufficiently accurate to construct the complex LHM. In summary, the combination of the GeoDetector and BN model is very promising for spatial prediction of landslides.

Published

2020

20. Pollution, Sources and Human Health Risk Assessment of Potentially Toxic Elements in Different Land Use Types under the Background of Industrial Cities

Author

Guangzhi Rong, Jiquan Zhang, Zhijun Tong, Qing Ma, Jingyao Peng, Qing Xia, Xingpeng Liu, and Yanan Chen

Subjects

Pollution, Index (economics), 010504 meteorology & atmospheric sciences, Soil test, media_common.quotation_subject, lcsh:TJ807-830, Geography, Planning and Development, lcsh:Renewable energy sources, 010501 environmental sciences, Management, Monitoring, Policy and Law, Disease cluster, 01 natural sciences, Human health, Environmental protection, lcsh:Environmental sciences, 0105 earth and related environmental sciences, media_common, toxic elements, lcsh:GE1-350, Health risk assessment, Land use, Renewable Energy, Sustainability and the Environment, lcsh:Environmental effects of industries and plants, industrial cities, land use types, source identification, lcsh:TD194-195, health risk assessment, Environmental science, Risk assessment

Abstract

Residents in industrial cities may be exposed to potentially toxic elements (PTEs) in soil that increase chronic disease risks. In this study, six types of PTEs (Zn, As, Cr, Ni, Cu, and Pb) in 112 surface soil samples from three land use types&mdash, industrial land, residential land, and farmland&mdash, in Tonghua City, Jilin Province were measured. The geological accumulation index and pollution load index were calculated to assess the pollution level of metal. Meanwhile, the potential ecological risk index, hazard index, and carcinogenic risk were calculated to assess the environmental risks. The spatial distribution map was determined by the ordinary kriging method, and the sources of PTEs were identified by factor analysis and cluster analysis. The average concentrations of Zn, As, Cr, Ni, Cu, and Pb were 266.57, 15.72, 72.41, 15.04, 20.52, and 16.30 mg/kg, respectively. The results of the geological accumulation index demonstrated the following: Zn pollution was present in all three land use types, As pollution in industrial land cannot be neglected, Cr pollution in farmland was higher than that in the other two land use types. The pollution load index decreased in the order of industrial land &gt, farmland &gt, residential land. Multivariate statistical analysis divided the six PTEs into three groups by source: Zn and As both originated from industrial activities, vehicle emissions were the main source of Pb, and Ni and Cu were derived from natural parent materials. Meanwhile, Cr was found to come from a mixture of artificial and natural sources. The soil environment in the study area faced ecological risk from moderate pollution levels mainly contributed by As. PTEs did not pose a non-carcinogenic risk to humans, however, residents of the three land use types all faced estimated carcinogenic risks caused by Cr, and As in industrial land also posed high estimated carcinogenic risk to human health. The conclusion of this article provides corresponding data support to the government's policy formulation of remediating different types of land and preventing exposure and related environmental risks.

Published

2020