Combining Snow Depth From FY-3C and In Situ Data Over the Tibetan Plateau Using a Nonlinear Analysis Method

Combining Snow Depth From FY-3C and In Situ Data Over the Tibetan Plateau Using a Nonlinear Analysis Method

Snow cover over the Tibetan Plateau plays a vital role in the regional and global climate system because it affects not only the climate but also the hydrological cycle and ecosystem. However, high-quality snow data are hindered due to the sparsity of observation networks and complex terrain in the...

Full description

Bibliographic Details
Main Authors: Aixia Feng, Feng Gao, Qiguang Wang, Aiqing Feng, Qiang Zhang, Yan Shi, Zhiqiang Gong, Guolin Feng, Yufei Zhao
Format: Article
Language:English
Published: Frontiers Media S.A. 2021-06-01
Series:Frontiers in Physics
Subjects:
snow depth
Tibetan Plateau
phase space reconstruction
FY-3C satellite
nonlinear analysis method
Online Access:https://www.frontiersin.org/articles/10.3389/fphy.2021.672288/full
id doaj-d5293e23dd82422baef70baa04420f1d
record_format Article
spelling doaj-d5293e23dd82422baef70baa04420f1d2021-06-11T04:31:33ZengFrontiers Media S.A.Frontiers in Physics2296-424X2021-06-01910.3389/fphy.2021.672288672288Combining Snow Depth From FY-3C and In Situ Data Over the Tibetan Plateau Using a Nonlinear Analysis MethodAixia Feng0Feng Gao1Qiguang Wang2Aiqing Feng3Qiang Zhang4Yan Shi5Zhiqiang Gong6Zhiqiang Gong7Guolin Feng8Guolin Feng9Yufei Zhao10Data Service Office, National Meteorological Information Center, China Meteorological Administration, Beijing, ChinaData Service Office, National Meteorological Information Center, China Meteorological Administration, Beijing, ChinaChina Meteorological Administration Training Center, China Meteorological Administration, Beijing, ChinaMeteorological Disaster Risk Management Division, National Climate Center, China Meteorological Administration, Beijing, ChinaData Service Office, National Meteorological Information Center, China Meteorological Administration, Beijing, ChinaData Service Office, National Meteorological Information Center, China Meteorological Administration, Beijing, ChinaCollege of Physics and Electronic Engineering, Changshu Institute of Technology, Changshu, ChinaLaboratory for Climate Studies, National Climate Center, China Meteorological Administration, Beijing, ChinaLaboratory for Climate Studies, National Climate Center, China Meteorological Administration, Beijing, ChinaCollege of Physics Science and Technology, Yangzhou University, Yangzhou, ChinaData Service Office, National Meteorological Information Center, China Meteorological Administration, Beijing, ChinaSnow cover over the Tibetan Plateau plays a vital role in the regional and global climate system because it affects not only the climate but also the hydrological cycle and ecosystem. However, high-quality snow data are hindered due to the sparsity of observation networks and complex terrain in the region. In this study, a nonlinear time series analysis method called phase space reconstruction was used to obtain the Tibetan Plateau snow depth by combining the FY-3C satellite data and in situ data for the period 2014–2017. This method features making a time delay reconstruction of a phase space to view the dynamics. Both of the grids and their nearby in situ snow depth time series were reconstructed with two appropriate parameters called time delay and embedding dimension. The values of the snow depth for grids were averaged over the in situ observations and retrieval of the satellite if their two parameters were the same. That implies that the two trajectories of the time series had the same evolution trend. Otherwise, the snow depth values for grids were averaged over the in situ observation. If there were no in situ sites within the grids, the retrieval of the satellite remained. The results show that the integrated Tibetan Plateau snow depth (ITPSD) had an average bias of –1.35 cm and 1.14 cm, standard deviation of the bias of 3.96 cm and 5.67 cm, and root mean square error of 4.18 cm and 5.79 cm compared with the in situ data and FY-3C satellite data, respectively. ITPSD expressed the issue that snow depth is usually overestimated in mountain regions by satellites. This is due to the introduction of more station observations using a dynamical statistical method to correct the biases in the satellite data.https://www.frontiersin.org/articles/10.3389/fphy.2021.672288/fullsnow depthTibetan Plateauphase space reconstructionFY-3C satellitenonlinear analysis method
collection DOAJ
language English
format Article
sources DOAJ
author Aixia Feng
Feng Gao
Qiguang Wang
Aiqing Feng
Qiang Zhang
Yan Shi
Zhiqiang Gong
Zhiqiang Gong
Guolin Feng
Guolin Feng
Yufei Zhao
spellingShingle Aixia Feng
Feng Gao
Qiguang Wang
Aiqing Feng
Qiang Zhang
Yan Shi
Zhiqiang Gong
Zhiqiang Gong
Guolin Feng
Guolin Feng
Yufei Zhao
Combining Snow Depth From FY-3C and In Situ Data Over the Tibetan Plateau Using a Nonlinear Analysis Method
Frontiers in Physics
snow depth
Tibetan Plateau
phase space reconstruction
FY-3C satellite
nonlinear analysis method
author_facet Aixia Feng
Feng Gao
Qiguang Wang
Aiqing Feng
Qiang Zhang
Yan Shi
Zhiqiang Gong
Zhiqiang Gong
Guolin Feng
Guolin Feng
Yufei Zhao
author_sort Aixia Feng
title Combining Snow Depth From FY-3C and In Situ Data Over the Tibetan Plateau Using a Nonlinear Analysis Method
title_short Combining Snow Depth From FY-3C and In Situ Data Over the Tibetan Plateau Using a Nonlinear Analysis Method
title_full Combining Snow Depth From FY-3C and In Situ Data Over the Tibetan Plateau Using a Nonlinear Analysis Method
title_fullStr Combining Snow Depth From FY-3C and In Situ Data Over the Tibetan Plateau Using a Nonlinear Analysis Method
title_full_unstemmed Combining Snow Depth From FY-3C and In Situ Data Over the Tibetan Plateau Using a Nonlinear Analysis Method
title_sort combining snow depth from fy-3c and in situ data over the tibetan plateau using a nonlinear analysis method
publisher Frontiers Media S.A.
series Frontiers in Physics
issn 2296-424X
publishDate 2021-06-01
description Snow cover over the Tibetan Plateau plays a vital role in the regional and global climate system because it affects not only the climate but also the hydrological cycle and ecosystem. However, high-quality snow data are hindered due to the sparsity of observation networks and complex terrain in the region. In this study, a nonlinear time series analysis method called phase space reconstruction was used to obtain the Tibetan Plateau snow depth by combining the FY-3C satellite data and in situ data for the period 2014–2017. This method features making a time delay reconstruction of a phase space to view the dynamics. Both of the grids and their nearby in situ snow depth time series were reconstructed with two appropriate parameters called time delay and embedding dimension. The values of the snow depth for grids were averaged over the in situ observations and retrieval of the satellite if their two parameters were the same. That implies that the two trajectories of the time series had the same evolution trend. Otherwise, the snow depth values for grids were averaged over the in situ observation. If there were no in situ sites within the grids, the retrieval of the satellite remained. The results show that the integrated Tibetan Plateau snow depth (ITPSD) had an average bias of –1.35 cm and 1.14 cm, standard deviation of the bias of 3.96 cm and 5.67 cm, and root mean square error of 4.18 cm and 5.79 cm compared with the in situ data and FY-3C satellite data, respectively. ITPSD expressed the issue that snow depth is usually overestimated in mountain regions by satellites. This is due to the introduction of more station observations using a dynamical statistical method to correct the biases in the satellite data.
topic snow depth
Tibetan Plateau
phase space reconstruction
FY-3C satellite
nonlinear analysis method
url https://www.frontiersin.org/articles/10.3389/fphy.2021.672288/full
work_keys_str_mv AT aixiafeng combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
AT fenggao combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
AT qiguangwang combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
AT aiqingfeng combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
AT qiangzhang combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
AT yanshi combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
AT zhiqianggong combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
AT zhiqianggong combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
AT guolinfeng combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
AT guolinfeng combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
AT yufeizhao combiningsnowdepthfromfy3candinsitudataoverthetibetanplateauusinganonlinearanalysismethod
_version_ 1721383749077172224

Similar Items