基于CryoSat-2数据的海冰厚度估算算法比较

季青; 庞小平; 赵羲; 程子桉

doi:10.13203/j.whugis20150279

基于CryoSat-2数据的海冰厚度估算算法比较

doi: 10.13203/j.whugis20150279

季青¹,
庞小平^1,2,,
赵羲^1,2,
程子桉¹

1.
武汉大学中国南极测绘研究中心, 湖北武汉, 430079;
2.
极地测绘科学国家测绘地理信息局重点实验室, 湖北武汉, 430079

基金项目: 国家自然科学基金资助项目(41301463);高等学校博士学科点专项科研新教师类基金资助项目(20130141120009);南北极环境综合考察及资源潜力评估专项基金资助项目(CHINARE2014-04-07)。

详细信息

作者简介:
季青,博士后,主要从事极地遥感与模型分析的研究。E-mail:jqwhu12@163.com

通讯作者: 庞小平,教授。E-mail:pxp@whu.edu.cn

中图分类号: P228.41;P237.9

Comparison of Sea Ice Thickness Retrieval Algorithms from CryoSat-2 Satellite Altimeter Data

JI Qing¹,
PANG Xiaoping^{1,2
,},
ZHAO Xi^1,2,
CHENG Zian¹

1.
Chinese Antarctic Center of Surveying and Mapping, Wuhan University, Wuhan 430079, China;
2.
Key Laboratory of Polar Surveying and Mapping, NASG, Wuhan 430079, China

Funds: The National Natural Science Foundation of China, No. 41301463;the Specialize Research Fund for the Doctoral Program of Higher Education of China, No.20130141120009;the Polar Environment Comprehensive Investigation and Assessment Programmes of China, No. CHINARE2014-04-07.

摘要: 以北极为研究区,使用CryoSat-2数据,利用现有海冰厚度卫星测高研究中4种主流算法(Laxon03算法、Kurtz09算法、Yi11算法和Laxon13算法)分别对北冰洋海冰厚度进行估算,并将估算结果与研究区IceBridge机载激光测高冰厚数据进行了比较,探索各算法海冰厚度估算的差异,寻找最优的估算算法,为估算长时序海冰厚度提供基础和参考。结果表明,4种算法估算的海冰厚度空间分布较为一致,但不同算法估算的结果差异较大,可达0.476 m;4种算法估算结果大小依次为Laxon03算法、Yi11算法、Laxon13算法、Kurtz09算法;4种算法估算的平均海冰厚度差异,在北极波弗特海海域最大,其次是北极中心海域、格陵兰和挪威海;Laxon13算法估算结果相对于IceBridge观测结果与其他算法相比,具有最小的平均偏差和均方根误差,是卫星测高估算海冰厚度的最优算法。
- 海冰厚度 /
- 卫星测高 /
- 最优算法 /
- CryoSat-2 /
- IceBridge
Abstract: Sea ice thickness is an important parameter and indicator of climate change, sensitive to ecosystem in Polar Regions. For accurate forecasting of climate change, sea ice mass balance, ocean circulation and sea-atmosphere interactions, it is required to have long term records of sea ice thickness. Satellite altimetry provide useful technology for obtaining time series sea ice thickness information on hemispheric scale. So far, four mainstream algorithms based on satellite altimeter data have been used to estimate sea ice thickness effectively. Different algorithms and parameter values as selected by different researchers will lead to results unsuitable for comparison and large uncertainties. To solve this problem, this study compared sea ice thickness over the Arctic research area retrieved from these four mainstream algorithms based on CryoSat-2 satellite altimeter data. Our results demonstrate that: (1) when compared to each other, the retrieved mean sea ice thickness estimated from these four algorithms have similar spatial distribution, but with larger difference in the value, up to 0.476 m;(2) the sequence of estimated sea ice thickness for the Arctic spatial average based on four algorithms is Laxon03 algorithm, Yi11 algorithm, Laxon13 algorithm and Kurtz09 algorithm;(3) the difference of the mean sea ice thickness from these four algorithms was higher in Beaufort Sea than in Central Arctic or Greenland Sea;(4) The Laxon13 algorithm was the optimal algorithm, with the minimum bias and RMSE when compared to IceBridge sea ice thickness measurements. These results can provide useful reference and basis for further study to improve algorithms, so as to quantify dynamic changes of sea ice thickness more accurately.
- sea ice thickness /
- satellite altimeter /
- optimal algorithm /
- CryoSat-2 /
- IceBridge

[1]	IPCC. Climate Change 2013: the Physical Science Basis [M/OL]. http://www.ipcc.ch/report/ar5/wgl, 2013
[2]	Bourke R H, Garrett R P. Sea Ice Thickness Distribution in the Arctic Ocean [J]. Cold Regions Science and Technology, 1987, 13: 259-280
[3]	Hudson R. Annual Measurement of Sea-Ice Thickness Using an Upward-Looking Sonar [J]. Nature, 1990, 344(6262): 135-137
[4]	Shimoda H, Endoh T, Muramoto K, et al. Observations of Sea-Ice Conditions in the Antarctic Coastal Application of Remote Sensing to the Estimation of Sea-Ice Thickness Distribution Region Using Ship-Board Video Cameras [J]. Antarctic Record, 1997, 41(1): 355-365
[5]	Haas C. Evaluation of Ship-Based Electromagnetic-Inductive Thickness Measurements of Summer Sea-Ice in the Bellingshausen and Amundsen Seas Antarctica [J]. Cold Regions Science and Technology, 1998, 27: 1-16
[6]	Laxon S, Peacock N, Smith D. High Interannual Variability of Sea Ice in the Arctic Region [J]. Nature, 2003, 425(6961): 947-950
[7]	Kwok R, Zwally H J, Yi D. ICESat Observations of Arctic Sea Ice: A First Look [J]. Geophysical Research Letters, 2004, 31(16): L16401
[8]	Kwok R, Cunningham G F. ICESat over Arctic Sea Ice: Estimation of Snow Depth and Ice Thickness [J]. Journal of Geophysical Research, 2008, 113: C08010
[9]	Kurtz N T, Markus T, Cavalieri D J, et al. Estimation of Sea Ice Thickness Distributions Through the Combination of Snow Depth and Satellite Laser Altimetry Data [J]. Journal of Geophysical Research, 2009, 14(C10): C10007
[10]	Kurtz N T, Markus T, Cavalieri D J, et al. Comparison of ICESat Data with Airborne Laser Altimeter Measurements over Arctic Sea-Ice[J]. IEEE Transations on Geoscience and Remote Sensing,2008,40(7):1 913-1 924
[11]	Yi D, Zwally H J, Robbins J W. ICESat Observations of Seasonal and Interannual Variations of Sea-Ice Freeboard and Estimated Thickness in the Weddell Sea Antarctica (2003-2009) [J]. Annals of Glaciology, 2011, 52(9): 43-51
[12]	Kurtz N T, Markus T. Satellite Observations of Antarctic Sea Ice Thickness and Volume [J]. Journal of Geophysical Research: Oceans (1978-2012), 2012, 117(C8): C08025
[13]	Laxon S W, Giles K A, Ridout A L, et al. CryoSat-2 Estimates of Arctic Sea Ice Thickness and Volume [J]. Geophysical Research Letters, 2013, 40: 732-737
[14]	Kern S, Khvorostovsky K, Skourup H, et al. About Uncertainties in Sea Ice Thickness Retrieval from Satellite Radar Altimetry: Results from the ESA-CCI Sea Ice ECV Project Round Robin Exercise [J]. The Cryosphere Discussions, 2014, 8(2): 1 517-1 561
[15]	Ricker R, Hendricks S, Helm V, et al. Sensitivity of CryoSat-2 Arctic Sea-Ice Volume Trends on Radar-Waveform Interpretation [J]. The Cryosphere, 2014, 8(2): 1 831-1 871
[16]	Kwok R. Satellite Remote Sensing of Sea-Ice Thickness and Kinematics: A Review[J]. Journal of Glaciology, 2010, 56(200): 1 129-1 140
[17]	Warren S G, Rigor R G, Untersteiner N, et al. Snow Depth on Arctic Sea Ice [J]. Journal of Climate, 1999, 12(6): 1 814-1 829
[18]	Farrell S L, Kurtz N, Connor L N, et al. A First Assessment of Icebridge Snow and Ice Thickness Data over Arctic Sea Ice [J]. IEEE Transactions on Geoscience and Remote Sensing, 2012, 50(6): 2 098-2 111
[19]	Spreen G, Kern S, Stammer D, et al. Fram Strait Sea Ice Volume Export Estimated Between 2003 and 2008 from Satellite Data[J]. Geophysical Research Letters, 2009, 36(19):L19502

[1]	高翔, 庞小平, 季青. 利用CryoSat-2测高数据研究南极威德尔海海冰出水高度时空变化 . 武汉大学学报 ● 信息科学版, 2021, 46(1): 125-132. doi: 10.13203/j.whugis20180504
[2]	程鹏飞, 文汉江, 刘焕玲, 董杰. 卫星大地测量学的研究现状及发展趋势 . 武汉大学学报 ● 信息科学版, 2019, 44(1): 48-54. doi: 10.13203/j.whugis20180356
[3]	汪海洪, 罗北. 计算测高卫星地面轨迹交叉点的快速数值算法 . 武汉大学学报 ● 信息科学版, 2017, 42(3): 293-298. doi: 10.13203/j.whugis20140866
[4]	肖峰, 李斐, 张胜凯, 袁乐先, 朱婷婷. 联合CryoSat-2测高数据和地面高程数据建立东南极拉斯曼丘陵地区DEM . 武汉大学学报 ● 信息科学版, 2017, 42(10): 1417-1422. doi: 10.13203/j.whugis20160011
[5]	袁乐先, 李斐, 张胜凯, 朱婷婷, 左耀文. 利用ICESat/GLAS数据研究北极海冰干舷高度 . 武汉大学学报 ● 信息科学版, 2016, 41(9): 1176-1182. doi: 10.13203/j.whugis20150690
[6]	张胜军, 金涛勇, 褚永海, 孔祥雪. Cryosat-2数据的大地水准面分辨能力研究 . 武汉大学学报 ● 信息科学版, 2016, 41(6): 759-764. doi: 10.13203/j.whugis20140829
[7]	墙强, 周春霞, 廖明生, 赵秋阳, 王泽民. 利用CryoSat-2测高数据研究东南极PANDA断面考察沿线高程变化 . 武汉大学学报 ● 信息科学版, 2016, 41(11): 1445-1449. doi: 10.13203/j.whugis20150271
[8]	张保军, 王泽民. 联合卫星重力、卫星测高和海洋资料研究全球海平面变化 . 武汉大学学报 ● 信息科学版, 2015, 40(11): 1453-1459. doi: 10.13203/j.whugis20150230
[9]	张胜军, 李建成, 褚永海, 孔祥雪. 基于Cryosat和Jason1GM数据的垂线偏差计算与分析 . 武汉大学学报 ● 信息科学版, 2015, 40(8): 1012-1017. doi: 10.13203/j.whugis20130796
[10]	张胜凯, 肖峰, 李斐, 鄂栋臣, 程晓. 基于CryoSat-2测高数据的南极局部地区DEM的建立与精度评定 . 武汉大学学报 ● 信息科学版, 2015, 40(11): 1434-1439. doi: 10.13203/j.whugis20150274
[11]	谢苏锐, 李斐, 赵杰臣, 张胜凯. 验潮与GPS联合监测南极中山站附近海冰厚度变化 . 武汉大学学报 ● 信息科学版, 2014, 39(10): 1153-1157.
[12]	金涛勇, 胡敏章, 蒋涛, 张守建. 卫星测高资料的电离层延迟改正交叉检验与误差分析 . 武汉大学学报 ● 信息科学版, 2012, 37(6): 658-661.
[13]	杨元德, 汪海洪, 鄂栋臣, 黄金维. 复杂海域ERS-1卫星测高波形的波形分类方法研究 . 武汉大学学报 ● 信息科学版, 2011, 36(1): 48-50.
[14]	金涛勇, 李建成, 王正涛, 蒋涛. 卫星测高逆气压改正及其对海平面变化的影响 . 武汉大学学报 ● 信息科学版, 2010, 35(9): 1017-1020.
[15]	黄谟涛, 王瑞, 翟国君, 欧阳永忠. 多代卫星测高数据联合平差及重力场反演 . 武汉大学学报 ● 信息科学版, 2007, 32(11): 988-993.
[16]	李建成, 褚永海, 姜卫平, 徐新禹. 利用卫星测高资料监测长江中下游湖泊水位变化 . 武汉大学学报 ● 信息科学版, 2007, 32(2): 144-147.
[17]	许军, 暴景阳, 刘雁春. 潮汐模型对利用卫星测高数据研究海平面变化的影响 . 武汉大学学报 ● 信息科学版, 2006, 31(6): 503-507.
[18]	文汉江, 章传银. 由ERS-2和TOPEX卫星测高数据推算的海面高异常的主成分分析 . 武汉大学学报 ● 信息科学版, 2006, 31(3): 221-223.
[19]	章传银, 李建成, 晁定波. 联合卫星测高和海洋物理数据计算近海稳态海面地形 . 武汉大学学报 ● 信息科学版, 2000, 25(6): 500-504.
[20]	周东旭, 冯义楷, 张化疑, 付延光, 唐秋华. 联合卫星测高和GNSS观测的天津沿海近25年相对海平面变化分析 . 武汉大学学报 ● 信息科学版, 0, 0(0): 0-0. doi: 10.13203/j.whugis20210532

点击查看大图

计量

文章访问数: 999
HTML全文浏览量: 14
PDF下载量: 569
被引次数: 0

姓名
邮箱
手机号码
标题
留言内容
验证码

留言板

基于CryoSat-2数据的海冰厚度估算算法比较

doi: 10.13203/j.whugis20150279

作者简介:
季青,博士后,主要从事极地遥感与模型分析的研究。E-mail:jqwhu12@163.com

通讯作者: 庞小平,教授。E-mail:pxp@whu.edu.cn

Comparison of Sea Ice Thickness Retrieval Algorithms from CryoSat-2 Satellite Altimeter Data

计量

基于CryoSat-2数据的海冰厚度估算算法比较

doi: 10.13203/j.whugis20150279

1. 武汉大学中国南极测绘研究中心, 湖北武汉, 430079;

2. 极地测绘科学国家测绘地理信息局重点实验室, 湖北武汉, 430079

作者简介:
季青,博士后,主要从事极地遥感与模型分析的研究。E-mail:jqwhu12@163.com

通讯作者: 庞小平,教授。E-mail:pxp@whu.edu.cn

English Abstract

Comparison of Sea Ice Thickness Retrieval Algorithms from CryoSat-2 Satellite Altimeter Data

1. Chinese Antarctic Center of Surveying and Mapping, Wuhan University, Wuhan 430079, China;

2. Key Laboratory of Polar Surveying and Mapping, NASG, Wuhan 430079, China

全文HTML

目录

留言板

基于CryoSat-2数据的海冰厚度估算算法比较

doi: 10.13203/j.whugis20150279

作者简介: 季青,博士后,主要从事极地遥感与模型分析的研究。E-mail:jqwhu12@163.com

通讯作者: 庞小平,教授。E-mail:pxp@whu.edu.cn

Comparison of Sea Ice Thickness Retrieval Algorithms from CryoSat-2 Satellite Altimeter Data

计量

出版历程

基于CryoSat-2数据的海冰厚度估算算法比较

doi: 10.13203/j.whugis20150279

1. 武汉大学中国南极测绘研究中心, 湖北 武汉, 430079; 2. 极地测绘科学国家测绘地理信息局重点实验室, 湖北 武汉, 430079

作者简介: 季青,博士后,主要从事极地遥感与模型分析的研究。E-mail:jqwhu12@163.com

通讯作者: 庞小平,教授。E-mail:pxp@whu.edu.cn

English Abstract

Comparison of Sea Ice Thickness Retrieval Algorithms from CryoSat-2 Satellite Altimeter Data

1. Chinese Antarctic Center of Surveying and Mapping, Wuhan University, Wuhan 430079, China; 2. Key Laboratory of Polar Surveying and Mapping, NASG, Wuhan 430079, China

全文HTML

目录

作者简介:
季青,博士后,主要从事极地遥感与模型分析的研究。E-mail:jqwhu12@163.com

1. 武汉大学中国南极测绘研究中心, 湖北武汉, 430079;

2. 极地测绘科学国家测绘地理信息局重点实验室, 湖北武汉, 430079

作者简介:
季青,博士后,主要从事极地遥感与模型分析的研究。E-mail:jqwhu12@163.com

1. Chinese Antarctic Center of Surveying and Mapping, Wuhan University, Wuhan 430079, China;

2. Key Laboratory of Polar Surveying and Mapping, NASG, Wuhan 430079, China