Your search keyword '"Shen, Yifan"' showing total 6 results

1. Improving the accuracy of reconstructed terrestrial water storage during the GRACE/GRACE-FO gap based on a new variable filter reconstruction model.

Author

Yang, Shuai, Zheng, Wei, Yin, Wenjie, Chen, Zhiwei, and Shen, Yifan

Subjects

WATER storage, EMERGENCY management, STANDARD deviations, PEARSON correlation (Statistics), HYDROLOGIC cycle, HAZARD mitigation, DROUGHTS

Abstract

Terrestrial water storage (TWS) is a fundamental component of the global hydrological cycle. Understanding changes in TWS is essential for assessing the characteristics of drought and flood events in a region. However, the discontinuity between Gravity Recovery and Climate Experiment (GRACE) and GRACE Follow-On (GRACE-FO) severely affects and limits their applicability in long-term hydrological studies. In this study, a new variable filter reconstruction model (NVFRM) is proposed to reconstruct the TWS anomaly (TWSA) by combining the Gamma test (GT) and Long short-term memory (LSTM) neural network. The research findings reveal that the TWSA reconstructed by the NVFRM is consistent with the GRACE-FO during the testing period (June 2018–December 2020). It shows that the Pearson correlation coefficient (PR), Nash-Sutcliffe efficiency coefficient (NSE), and root mean square error (RMSE) are 0.91, 0.81, and 4.90 cm, respectively, which demonstrates the reliability of the NVFRM. More importantly, four drought events are identified by the drought severity index (DSI) derived from the reconstructed TWSA, including August 2003–April 20 April 200420 April 200411–September 20 June 2011,20 June 201118–September 2018, and September 2019–December 2019, respectively. Flood events are monitored based on the flood potential index (FPI), which is calculated by using the reconstructed TWSA and precipitation. Flood events in the Poyang Lake Basin are characterized by a high FPI index of 0.58, 0.52 and 0.32 in summer (June–August), indicating a greater probability of flooding. The NVFRM model proposed in this study provides an effective measure for filling the missing TWSA in regional hydrological research, which is of great significance for monitoring extreme hydrological events and facilitating disaster prevention and mitigation. [ABSTRACT FROM AUTHOR]

Published

2023

2. Improving the Resolution of GRACE/InSAR Groundwater Storage Estimations Using a New Subsidence Feature Weighted Combination Scheme.

Author

Wang, Qingqing, Zheng, Wei, Yin, Wenjie, Kang, Guohua, Huang, Qihuan, and Shen, Yifan

Subjects

LAND subsidence, GROUNDWATER, WATER table, WATER diversion, GROUNDWATER management, WATER storage

Abstract

GRACE observations and land subsidence data derived from InSAR both assess groundwater storage changes. However, GRACE data at local scales are restricted by the coarser spatial resolution of satellite systems, and inversion of Groundwater Storage Anomalies (GWSA) by InSAR requires extensive and unavailable lithological data. Here, we propose a New Subsidence Feature Weighted Combination (NSFWC) scheme to enhance the spatial resolution of GRACE-derived GWSA from 0.5° to 0.05°. This method can not only retain the spatial distribution of groundwater changes but also reflect local details related to surface subsidence. A case study was executed to evaluate the performance of the NSFWC scheme in the Beijing Plain, which has seriously overexploited groundwater. Results showed that the simulated GWSA were consistent with in situ measurements in most regions, with a correlation coefficient of 0.85 and an RMSE of 4.41 mm/year. Additionally, there were 22 overexploited wells in the Beijing Plain, although groundwater levels generally recovered after the South to North Water Diversion Project. Simultaneously, four cones of depression were detected by the InSAR technology, where the maximum cumulative subsidence and subsidence rate achieved −198.52 mm and −53.09 mm/year, respectively. This paper provides data support and technical guarantees for small-scale groundwater resources management. [ABSTRACT FROM AUTHOR]

Published

2023

3. Improved the Characterization of Flood Monitoring Based on Reconstructed Daily GRACE Solutions over the Haihe River Basin.

Author

Nie, Shengkun, Zheng, Wei, Yin, Wenjie, Zhong, Yulong, Shen, Yifan, and Li, Kezhao

Subjects

WATERSHEDS, FLOOD damage, CLIMATE extremes, WATER storage, FLOODS, CLIMATE change

Abstract

Flood events have caused huge disasters with regard to human life and economic development, especially short-term flood events that have occurred in recent years. Gravity Recovery and Climate Experiment (GRACE) satellites can directly detect the spatiotemporal characteristics of terrestrial water storage anomalies (TWSA), which play an important role in capturing flood signals. However, the monthly resolution of GRACE-derived TWSA limits its application in monitoring sub-monthly flood events. Therefore, this paper first reconstructs the daily TWSA based on a statistical model with near real-time precipitation and temperature as input variables, and then three daily flood monitoring indexes are developed based on the reconstructed TWSA. Furthermore, these indexes are employed to evaluate the temporal and spatial characteristics of the 2016 short-term flood event in the Haihe River basin (HRB), including the flood potential index (FPI), water storage deficit index (WSDI), and combined climate deviation index (CCDI). In contrast to previous studies, the temporal resolution of TWSA-based indexes is improved from the monthly scale to the daily scale, which largely improves the temporal characterization of flood monitoring. Results demonstrate that (1) among ten kinds of "Temperature-Precipitation" combinations, the reconstructed TWSA based on CN05.1-CN05.1 match well with the GRACE TWSA, as well as publicly available daily TWSA datasets with a Nash-Sutcliffe efficiency coefficient (NSE) of 0.96 and 0.52 ~ 0.81 respectively. (2) The short-term flood characteristics can be better characterized by the reconstructed daily TWSA based on CN05.1-CN05.1, reaching the peak of 216.19 mm on July 20 in the flood center. Additionally, the spatial characteristics of the equivalent water height (EWH) are detected to evolve from southwest to northeast during the short-term flood. (3) FPI, WSDI, and CCDI are proven to be effective in monitoring flood events in the HRB, which validates the reliability of the reconstructed daily TWSA. Moreover, compared to the 56% and 66% coverage of damage quantified by FPI and CCDI, the 45% damage coverage of the flood mapped by WSDI is more consistent with the governmental reports within the HRB. This paper is expected to provide a valuable reference for the assessment of short-term events caused by extreme climate change. [ABSTRACT FROM AUTHOR]

Published

2023

4. Inverted Algorithm of Groundwater Storage Anomalies by Combining the GNSS, GRACE/GRACE-FO, and GLDAS: A Case Study in the North China Plain.

Author

Shen, Yifan, Zheng, Wei, Zhu, Huizhong, Yin, Wenjie, Xu, Aigong, Pan, Fei, Wang, Qiang, and Zhao, Yelong

Subjects

*GLOBAL Positioning System, *WATER storage, *WATER management, *WATER shortages, *GROUNDWATER, *STANDARD deviations, *NATURAL disasters

Abstract

As the largest groundwater drainage region in China, the per capita water resources in the North China Plain (NCP) account for only one-seventh of the country's available water resources. Currently, the NCP is experiencing a serious water shortage due to the overexploitation of groundwater resources and a subsequent series of natural disasters. Thus, accurate regional assessments and effective water resource management policies are of critical importance. To accomplish this phenomenon, the daily terrestrial water storage anomaly (TWSA) over the NCP is calculated from the combination of the GNSS vertical deformation sequences (seasonal items) and GRACE (trend items). The groundwater storage anomaly (GWSA) in the NCP is obtained by subtracting the canopy water, soil water, and snow water equivalent components from the TWSA. The inversion results of this study are verified by comparisons with the Global Land Data Assimilation System (GLDAS) data products. The elevated annual amplitude areas are located in Beijing and Tianjin, and the Pearson correlation coefficient (PCC), root mean square error (RMSE), and Nash–Sutcliffe efficiency (NSE) between the two GWSA results are 0.67, 4.01 cm, and 0.61, respectively. This indicates that the methods proposed in this study are reliable. Finally, the groundwater drought index was calculated for the period from 2011 to 2021, and the results showed that 2019 was the driest year, with a drought severity index value of −0.12, indicative of slightly moderate drought conditions. By calculating and analyzing the annual GWSA, this work shows that the South–North Water Transfer Project does provide some regional drought mitigation. [ABSTRACT FROM AUTHOR]

Published

2022

5. Improving the Inversion Accuracy of Terrestrial Water Storage Anomaly by Combining GNSS and LSTM Algorithm and Its Application in Mainland China.

Author

Shen, Yifan, Zheng, Wei, Yin, Wenjie, Xu, Aigong, Zhu, Huizhong, Wang, Qingqing, and Chen, Zhiwei

Subjects

*GLOBAL Positioning System, *WATER storage, *STANDARD deviations, *WATERSHEDS, *PEARSON correlation (Statistics), *DEEP learning

Abstract

Densely distributed Global Navigation Satellite System (GNSS) stations can invert the terrestrial water storage anomaly (TWSA) with high precision. However, the uneven distribution of GNSS stations greatly limits the application of TWSA inversion. The purpose of this study was to compensate for the spatial coverage of GNSS stations by simulating the vertical deformation in unobserved grids. First, a new deep learning weight loading inversion model (DWLIM) was constructed by combining the long short-term memory (LSTM) algorithm, inverse distance weight, and the crustal load model. DWLIM is beneficial for improving the inversion accuracy of TWSA based on the GNSS vertical displacement. Second, the DWLIM-based and traditional GNSS-derived TWSA methods were utilized to derive TWSA over mainland China. Furthermore, the TWSA results were compared with the TWSA solutions of the Gravity Recovery and Climate Experiment (GRACE) and Global Land Data Assimilation System (GLDAS) model. The results indicate that the maximum Pearson's correlation coefficient (PCC), Nash–Sutcliffe efficiency (NSE) coefficient, and root mean square error (RMSE) equal 0.81, 0.61, and 2.18 cm, respectively. The accuracy of DWLIM was higher than that of the traditional GNSS inversion method according to PCC, NSE, and RMSE, which were increased by 67.11, 128.15, and 22.75%. The inversion strategy of DWLIM can effectively improve the accuracy of TWSA inversion in regions with unevenly distributed GNSS stations. Third, this study investigated the variation characteristics of TWSA based on DWLIM in 10 river basins over mainland China. The analysis shows that the TWSA amplitudes of Songhua and Liaohe River basins are significantly higher than those of the other basins. Moreover, TWSA sequences in each river basin contain annual seasonal signals, and the wave peaks of TWSA estimates emerge between June and July. Overall, DWLIM provides a useful measure to derive TWSA in regions where GNSS stations are uneven or sparse. [ABSTRACT FROM AUTHOR]

Published

2022

6. Inverted Algorithm of Terrestrial Water-Storage Anomalies Based on Machine Learning Combined with Load Model and Its Application in Southwest China.

Author

Shen, Yifan, Zheng, Wei, Yin, Wenjie, Xu, Aigong, Zhu, Huizhong, Yang, Shuai, and Su, Kai

Subjects

*WATER storage, *MACHINE learning, *GLOBAL Positioning System, *PEARSON correlation (Statistics), *PROBLEM solving

Abstract

Dense Global Position System (GPS) arrays can be used to invert the terrestrial water-storage anomaly (TWSA) with higher accuracy. However, the uneven distribution of GPS stations greatly limits the application of GPS to derive the TWSA. Aiming to solve this problem, we grid the GPS array using regression to raise the reliability of TWSA inversion. First, the study uses the random forest (RF) model to simulate crustal deformation in unobserved grids. Meanwhile, the new Machine-Learning Loading-Inverted Method (MLLIM) is constructed based on the traditional GPS derived method to raise the truthfulness of TWSA inversion. Second, this research selects southwest China as the study region, the MLLIM and traditional GPS inversion methods are used to derive the TWSA, and the inverted results are contrasted with datasets of the Gravity Recovery and Climate Experiment (GRACE) Mascon and the Global Land Data Assimilation System (GLDAS) model. The comparison shows that values of Pearson Correlation Coefficient (PCC) between the MLLIM and GRACE and GRACE Follow-On (GRACE-FO) are equal to 0.91 and 0.88, respectively; and the values of R-squared (R2) are equal to 0.76 and 0.65, respectively; the values of PCC and R2 between MLLIM and GLDAS solutions are equal to 0.79 and 0.65. Compared with the traditional GPS inversion, the MLLIM improves PCC and R2 by 8.85% and 7.99% on average, which indicates that the MLLIM can improve the accuracy of TWSA inversion more than the traditional GPS method. Third, this study applies the MLLIM to invert the TWSA in each province of southwest China and combines the precipitation to analyze the change of TWSA in each province. The results are as follows: (1) The spatial distribution of TWSA and precipitation is coincident, which is highlighted in southwest Yunnan and southeast Guangxi; (2) this study compares TWSA of MLLIM with GRACE and GLDAS solutions in each province, which indicates that the maximum value of PCC is as high as 0.86 and 0.94, respectively, which indicates the MLLIM can be used to invert the TWSA in the regions with sparse GPS stations. The TWSA based on the MLLIM can be used to fill the vacancy between GRACE and GRACE-FO. [ABSTRACT FROM AUTHOR]

Published

2021