Your search keyword '"Shaonan Zhu"' showing total 15 results

1. Increased Significance of Global Concurrent Hazards From 1981 to 2020

Author

Yilei Xu, Qiang Dai, Jingxuan Zhu, Yuanzhi Yao, Jun Zhang, Wenhui Li, Shaonan Zhu, Tongxiao Zeng, Yecheng Xu, and Dawei Han

Subjects

Environmental sciences, GE1-350, Ecology, QH540-549.5

Abstract

Abstract The spatiotemporal overlap of multiple hazards defines what we call concurrent hazards, which usually cause more severe damage than what an isolated hazard would. Investigations of concurrent hazards at the global scale are limited. Here we first developed a novel criterion system for identifying concurrent hazards and then recognized 1,614 concurrent hazards during 1981–2020 from the 121,214 records including earthquake, storm, landslide, volcanic, wildfire and flood. Sixteen hot spot regions suffering from concurrent hazards were recognized for the first time at the global scale. By comparing two periods, 1981–2000 and 2001–2020, we found that the gross relative impact (economic damage and death) of concurrent hazards has considerably aggravated (6.3–117.0 times) in the past two decades. The low‐income regions suffer more prominent increase (mostly 2–3 times of high‐income regions), implying the inequitable patterns of concurrent hazard impact due to socioeconomic development. This spatial disparity entails the establishment of multidisciplinary and cross‐regional collaborations in mitigating the impact of concurrent hazards.

Published

2024

2. Extraction of Spatiotemporal Information of Rainfall-Induced Landslides from Remote Sensing

Author

Tongxiao Zeng, Jun Zhang, Yulin Chen, and Shaonan Zhu

Subjects

landslide temporal identification, landslide spatial extraction, NDVI, hydrometeorological threshold, Science

Abstract

With global climate change and increased human activities, landslides increasingly threaten human safety and property. Precisely extracting large-scale spatiotemporal information on landslides is crucial for risk management. However, existing methods are either locally based or have coarse temporal resolution, which is insufficient for regional analysis. In this study, spatiotemporal information on landslides was extracted using multiple remote sensing data from Emilia, Italy. An automated algorithm for extracting spatial information of landslides was developed with NDVI datasets. Then, we established a landslide prediction model based on a hydrometeorological threshold of three-day soil moisture and three-day accumulated rainfall. Based on this model, the locations and dates of rainfall-induced landslides were identified. Then, we further matched these identified locations with the extracted landslides from remote sensing data and finally determined the occurrence time. This approach was validated with recorded landslides events in Emilia. Despite some temporal clustering, the overall trend matched historical records, accurately reflecting the dynamic impacts of rainfall and soil moisture on landslides. The temporal bias for 87.3% of identified landslides was within seven days. Furthermore, higher rainfall magnitude was associated with better temporal accuracy, validating the effectiveness of the model and the reliability of rainfall as a landslide predictor.

Published

2024

3. Spatial Downscaling of GPM Satellite Precipitation Data Using Extreme Random Trees

Author

Shaonan Zhu, Xiangyuan Wang, Donglai Jiao, Yiding Zhang, and Jiaxin Liu

Subjects

spatial downscaling, precipitation, vegetation regions, GPM, Meteorology. Climatology, QC851-999

Abstract

Obtaining precise and detailed precipitation data is crucial for analyzing watershed hydrology, ensuring sustainable water resource management, and monitoring events such as floods and droughts. Due to the complex relationship between precipitation and geographic factors, this study divides the entire country of China into eight vegetation zones based on different vegetation types. Within each vegetation zone, we employ a seasonally adjusted Extreme Random Trees approach to spatially downscale GPM (Global Precipitation Measurement) satellite monthly precipitation data. To validate the effectiveness of this method, we compare it with kriging interpolation and traditional global downscaling methods. By increasing the spatial resolution of the GPM monthly precipitation dataset from 0.1° to 0.01°, we evaluate the downscaled results and validate them against ground-level rain gauge data and GPM satellite precipitation data. The results indicate that the partitioned area prediction method outperforms other approaches, resulting in a precipitation dataset that not only achieves high accuracy but also offers finer spatial resolution compared to the original GPM precipitation dataset. Overall, this approach enhances the model’s capability to capture complex spatial features and demonstrates excellent generalization. The resulting higher-resolution precipitation dataset enables the creation of more accurate precipitation distribution maps, providing data support for regions lacking hydrological information. These data can be used to analyze seasonal precipitation patterns and reveal differences in precipitation across different seasons and geographic regions.

Published

2023

4. Assessment of Population Exposure to Urban Flood at the Building Scale

Author

Shaonan Zhu, Qiang Dai, Binru Zhao, and Jiaqi Shao

Subjects

population exposure, population mapping, POIs, urban floods, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

The assessment of populations affected by urban flooding is crucial for flood prevention and mitigation but is highly influenced by the accuracy of population datasets. The population distribution is related to buildings during the urban floods, so assessing the population at the building scale is more rational for the urban floods, which is possible due to the abundance of multi-source data and advances in GIS technology. Therefore, this study assesses the populations affected by urban floods through population mapping at the building scale using highly correlated point of interest (POI) data. The population distribution is first mapped by downscaling the grid-based WorldPop population data to the building scale. Then, the population affected by urban floods is estimated by superimposing the population data sets onto flood areas, with flooding simulated by the LISFLOOD-FP hydrodynamic model. Finally, the proposed method is applied to Lishui City in southeast China. The results show that the population affected by urban floods is significantly reduced for different rainstorm scenarios when using the building-scale population instead of WorldPop. In certain areas, populations not captured by WorldPop can be identified using the building-scale population. This study provides a new method for estimating populations affected by urban flooding.

Published

2020

5. SVM based extraction of spatial relations in text.

Author

Xueying Zhang, Chunju Zhang, Chaoli Du, and Shaonan Zhu

Published

2011

6. Assessing the potential of different satellite soil moisture products in landslide hazard assessment

Author

Dawei Han, Shaonan Zhu, Lu Zhuo, Qiang Dai, Binru Zhao, and Qi Shen

Subjects

Topographic Wetness Index, Soil Science, Geology, Soil science, Landslide, SMAP, Spatial distribution, Pearson product-moment correlation coefficient, symbols.namesake, Infiltration (hydrology), Soil moisture variability, symbols, DNS root zone, Environmental science, Satellite, Computers in Earth Sciences, Satellite soil moisture, Water content, Remote sensing

Abstract

With the development of remote sensing technology, satellite-based soil moisture estimates become more and more available, and the potential of using satellite soil moisture products in landslide hazard assessment has been widely recognized. However, to our knowledge, there is a lack of studies exploring the performance difference of various satellite soil moisture products for such an application. Therefore, this study aims to compare several state-of-the-art satellite soil moisture products on their potentials in landslide applications. The selected products include the ESA CCI soil moisture dataset, the SMAP Level-3 (L3), enhanced Level-3 (L3), Level-4 (L4) surface, and Level-4 (L4) root zone soil moisture datasets. Specifically, the completeness of different datasets is calculated to assess their applicability in practical applications. To investigate the relationship between the soil moisture and the commonly used rainfall information in landslide predictions, the correlation study of the satellite soil moisture with the antecedent cumulated rainfall is also carried out. In addition, to explore whether the satellite soil moisture can provide valuable information for landslide hazard assessment, infiltration events are identified based on the time series of satellite soil moisture, and the significance of event characteristics (such as event duration, soil moisture change, etc.) in landslide occurrence is then investigated with Bayesian analysis. This study is carried out in a landslide-prone area, the Emilia-Romagna region in northern Italy. Results show that the SMAP L4 product does not have any missing values, beneficial to the continuous monitoring of landslides. As for the correlation relationship between soil moisture and antecedent cumulated rainfall, the SMAP L4 product also has more rational spatial distribution of the Pearson correlation coefficients compared with other datasets, which can be better explained by the distribution of slope and TWI (topographic wetness index). Bayesian analysis on the infiltration events shows that our prior knowledge of the probability of landslide occurrence is better improved by using the ‘SMAP L4 root zone soil moisture’-derived infiltration events, indicating its greater potential to be used for landslide hazard assessment in the study region.

Published

2021

7. Estimation of rainfall erosivity based on WRF-derived raindrop size distributions

Author

Qiang Dai, Shuliang Zhang, Dawei Han, Jingxuan Zhu, Shaonan Zhu, and Guonian Lv

Subjects

010504 meteorology & atmospheric sciences, Meteorology, 0208 environmental biotechnology, 0207 environmental engineering, 02 engineering and technology, lcsh:Technology, 01 natural sciences, lcsh:TD1-1066, lcsh:Environmental technology. Sanitary engineering, 020701 environmental engineering, lcsh:Environmental sciences, 0105 earth and related environmental sciences, lcsh:GE1-350, lcsh:T, lcsh:Geography. Anthropology. Recreation, Numerical weather prediction, Siltation, 020801 environmental engineering, Current (stream), lcsh:G, Weather Research and Forecasting Model, Land degradation, Environmental science, Soil fertility, Soil conservation, Scale (map)

Abstract

Soil erosion can cause various ecological problems, such as land degradation, soil fertility loss, and river siltation. Rainfall is the primary water-driven force for soil erosion, and its potential effect on soil erosion is reflected by rainfall erosivity that relates to the raindrop kinetic energy. As it is difficult to observe large-scale dynamic characteristics of raindrops, all the current rainfall erosivity models use the function based on rainfall amount to represent the raindrops' kinetic energy. With the development of global atmospheric re-analysis data, numerical weather prediction techniques become a promising way to estimate rainfall kinetic energy directly at regional and global scales with high spatial and temporal resolutions. This study proposed a novel method for large-scale and long-term rainfall erosivity investigations based on the Weather Research and Forecasting (WRF) model, avoiding errors caused by inappropriate rainfall–energy relationships and large-scale interpolation. We adopted three microphysical parameterizations schemes (Morrison, WDM6, and Thompson aerosol-aware) to obtain raindrop size distributions, rainfall kinetic energy, and rainfall erosivity, with validation by two disdrometers and 304 rain gauges around the United Kingdom. Among the three WRF schemes, Thompson aerosol-aware had the best performance compared with the disdrometers at a monthly scale. The results revealed that high rainfall erosivity occurred in the west coast area at the whole country scale during 2013–2017. The proposed methodology makes a significant contribution to improving large-scale soil erosion estimation and for better understanding microphysical rainfall–soil interactions to support the rational formulation of soil and water conservation planning.

Published

2020

8. Accounting for satellite rainfall uncertainty in rainfall-triggered landslide forecasting

Author

Binru Zhao, Dawei Han, Jingqiao Mao, Lu Zhuo, Shaonan Zhu, and Qiang Dai

Subjects

Euclidean distance, Satellite rainfall, Meteorology, Rain gauge, Temporal resolution, Range (statistics), Hit rate, Landslide, Geology, Earth-Surface Processes, Constant false alarm rate

Abstract

With an increasing spatial/temporal resolution and accuracy of satellite rainfall products, their potential in landslide forecasting has gradually been recognized. Despite this, few studies have evaluated the effect of satellite rainfall uncertainty on landslide forecasting. In this study, a specific procedure is developed to account for the satellite rainfall uncertainty in rainfall-triggered landslide forecasting. We select the Emilia-Romagna region in northern Italy as the study area, and the NASA GPM-based IMERG Early Run product as the representative of satellite rainfall estimates. An error model for satellite rainfall is first constructed based on the distribution of GR|SR (gauge rainfall | satellite rainfall), which consists of a deterministic distortion component and a stochastic component. With the error model, the satellite rainfall uncertainty is characterized by generating the ensemble of probable “true rainfall” for each rainfall condition responsible for landslides. Then the generated rainfall ensembles are applied to the definition of rainfall thresholds using the bootstrap technique. Finally, the landslide forecasting performance of rainfall thresholds is evaluated with the criteria of hit rate, false alarm rate and the Euclidean distance to the perfect point. Results show that the simulated uncertainty band of the IMERG product encompasses most of the rain gauge measurements. The IMERG uncertainty also propagates to the rainfall thresholds, especially when rainfall events have long durations, the cumulated event rainfall that is likely to trigger landslides has a larger variation range. Besides, the landslide forecasting performance for thresholds that account for IMERG uncertainty varies a lot in terms of false alarm rate from 0.50 to 0.75, demonstrating that it is necessary to take into account the uncertainty associated with the IMERG Early Run product when using it to construct rainfall thresholds for landslide forecasting.

Published

2022

9. Modeling the high-resolution dynamic exposure to flooding in a city region

Author

Qiang Dai, Lu Zhuo, Dawei Han, Shaonan Zhu, Xuehong Zhu, and Shuliang Zhang

Subjects

dynamic exposure, 010504 meteorology & atmospheric sciences, Population, 010501 environmental sciences, 01 natural sciences, lcsh:Technology, lcsh:TD1-1066, Hydrology (agriculture), parasitic diseases, lcsh:Environmental technology. Sanitary engineering, Natural disaster, education, Risk management, lcsh:Environmental sciences, 0105 earth and related environmental sciences, lcsh:GE1-350, urban flooding, education.field_of_study, Flood myth, business.industry, lcsh:T, Flooding (psychology), fungi, lcsh:Geography. Anthropology. Recreation, food and beverages, agent-based model, humanities, City region, Travel behavior, resident travel behaviour, lcsh:G, Environmental science, business, Water resource management, geographic locations

Abstract

Urban flooding exposure is generally investigated with the assumption of stationary disasters and disaster-hit bodies during an event, and thus it cannot satisfy the increasingly elaborate modeling and management of urban floods. In this study, a comprehensive method was proposed to simulate dynamic exposure to urban flooding considering residents' travel behavior. First, a flood simulation was conducted using the LISFLOOD-FP model to predict the spatiotemporal distribution of flooding. Second, an agent-based model was used to simulate residents' movements during the urban flooding period. Finally, to study the evolution and patterns of urban flooding exposure, the exposure of population, roads, and buildings to urban flooding was simulated using Lishui, China, as a case study. The results showed that water depth was the major factor affecting total urban exposure in Lishui. Urban exposure to fluvial flooding was concentrated along the river, while exposure to pluvial flooding was dispersed throughout the area (independent from the river). Additionally, the population distribution on weekends was more variable than on weekdays and was more sensitive to floods. In addition, residents' response behavior (based on their subjective consciousness) may result in increased overall exposure. This study presents the first fully formulated method for dynamic urban flood exposure simulation at a high spatiotemporal resolution. The quantitative results of this study can provide fundamental information for urban flood disaster vulnerability assessment, socioeconomic loss assessment, urban disaster risk management, and emergency response plan establishment.

Published

2019

10. Modelling the high-resolution dynamic exposure to flood in city-region

Author

Xuehong Zhu, Qiang Dai, Dawei Han, Lu Zhuo, Shaonan Zhu, and Shuliang Zhang

Abstract

Urban flooding exposure is generally investigated with the assumption of stationary disasters and disaster-bearing bodies within an event, and thus cannot satisfy the increasingly elaborative modelling and management of urban flood. In this study, a comprehensive method was developed to simulate dynamic exposure to urban flooding considering residents’ travel behavior. First, a flood simulation was conducted using the LISFLOOD-FP model to predict the spatio-temporal distribution of flooding. Second, an agent-based model was used to simulate residents’ movements during the period of urban flooding. Finally, to study the evolution and patterns of urban flooding exposure, the exposure of population, roads, and buildings to urban flooding was simulated using Lishui, China as the case study. The results indicated evident spatio-temporal variations in urban flooding and population distribution. Additionally, the exposure increased with increasing rainfall and flooding severity. The urban area near the Oujiang River was the most severely flooded and indicated the largest amount of exposure of population, roads, and buildings. Furthermore, the impacts of flooding on roads were greater than those on population and on buildings. This study presents the first fully formulated method for dynamic urban flood exposure simulation at high spatio-temporal resolution. The results of this study can provide baseline data for determining urban flood disaster vulnerability, socioeconomic loss assessment, urban disaster risk management, and for establishing emergency response plans.

Published

2018

11. Method of Toponym Database Updating Based on Web Crawler

Author

Chunju Zhang, Xitao Xu, Xueying Zhang, and Shaonan Zhu

Subjects

Information retrieval, Computer science, Web crawler

Published

2011

12. Syntactic Rules of Spatial Relations in Natural Language

Author

Shaonan Zhu and Xueying Zhang

Subjects

Computer science, business.industry, Object language, Semantic interpretation, computer.software_genre, Linguistics, Bridging (programming), Spatial relation, Sequence alignment algorithm, Information system, Artificial intelligence, business, computer, Natural language, Natural language processing, Test data

Abstract

Spatial relations are the main part of geographical information in natural language. Their extraction and semantic interpretation play a significant role in bridging the gap between geographical information system and natural language. Normally spatial relations are described with certain spatial terms and syntactic rules in natural language. To overcome the disadvantage of manual induction of syntactic rules, this paper proposes a new machine learning approach based on a sequence alignment algorithm. Firstly, the description instances of spatial relations in a large-scale annotated corpus are extracted and analyzed, and the sequence alignment algorithm is used to calculate the pattern similarity between instances of spatial relations. Then, the instances with high similarity are generalized aspopularly used syntactic rules. Finally, these rules are used for extraction spatial relations in a test data to evaluate their validation. The experimental results indicate that the generalized rules can achieve better performance than those rules induced according to occurrence frequency in the corpus.

Published

2013

13. SVM based extraction of spatial relations in text

Author

Chaoli Du, Xueying Zhang, Chunju Zhang, and Shaonan Zhu

Subjects

Geospatial analysis, Computer science, business.industry, Feature vector, Feature extraction, Spatial intelligence, computer.software_genre, Spatial query, Information extraction, Spatial relation, Artificial intelligence, business, computer, Spatial analysis, Natural language processing

Abstract

Natural language text describes the nature of people's internal representation of space. It is investigated that 80% of unstructured text has location expressions e.g. place names and spatial relations. In the past few years, text has become a most important geospatial data resource as well as survey, map, satellite images and GPS. The most previous research focused on the recognition of place names in text and its integration with map services. Spatial relations play an important role in the fields of spatial data modelling, spatial query, spatial analysis, spatial reasoning and map generalization. Spatial relations in text are described in natural language with qualitative spatial expressions including place names, spatial terms, prepositions, verbs and so on. And these expressions are combined with certain syntactic patterns to represent their semantic functions. An instance of spatial relation in text can be simply formalized as (C1, P1, C2, P2, C3), where P1 and P2 are place names, and C1, C2 and C3 are the context. Support Vector Machine (SVM) is a pattern recognition method popularly used in information extraction from text. This paper investigates the extraction of spatial relations based on SVM model which can implement the recognition of spatial expressions and their classification synchronously. For the SVM model, a set of feature vectors are specified, such as lexical tokens, spatial terms, syntactic structures and geographical feature types of place names, and a multi-label classifier is presented to solve the multi-classification problem. Finally, an experimental evaluation is explored in a Chinese annotation corpus. This study proves that spatial terms are important indicators for identification of spatial relations in text. However, there is serious ambiguity of their classification. Therefore, integration of much more context information could potentially improve the performance of extraction of spatial relations in text.

Published

2011

14. Transshipments in dual-channel supply chain

Author

Shaonan, Zhu, primary and Qiuhong, Zhao, additional

Published

2011

15. Contextual spatial relations based spatial modelling of vague place names.

Author

Xueying Zhang and Shaonan Zhu

Published

2010