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冰川冻土 2014

基于相机摄影测量的冰面反照率反演方法研究

DOI: 10.7522/j.issn.1000-0240.2014.0032, PP. 259-267

刘俊峰,陈仁升,宋耀选,何晓波,王岗

Keywords: 相机摄影测量,雪冰,反照率,祁连山,十一冰川

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Abstract:

雪冰反照率是冰川与积雪能量平衡计算的关键参数，也是观测的难点.为测量冰面反照率，试验采用相机摄影测量技术，在祁连山十一冰川开展了自动拍摄、并利用共线方程进行冰川正射制图，在此基础上于2012年7月28日-8月18日在冰川表面开展了不同海拔梯度的反照率观测.通过统计分析晴天与阴天观测反照率与对应点相机拍摄获取的RGB归一化指数之间的关系，对十一冰川进行冰面反照率参数化方法研究.结果表明晴天冰面反照率与RGB归一化指数存在明显的指数关系，拟合R2达到0.79；而阴天的统计关系较差，线性拟合R2仅为0.52.据此尝试利用晴天的拟合公式对整个冰面进行反照率参数化，计算表明在晴天冰川表面地形阴影区的反照率存在低估现象，而无阴影区的反照率估算结果可信度较高.利用2013年的反照率观测数据进行了参数化方案的验证，结果表明观测值与模拟值平均误差仅为0.037，表明利用RGB影像对反照率参数化具有一定的可用性和可靠性.

References

[1]	Oerlemans J, Knap W H. A 1 year record of global radiation and albedo in the ablation zone of Morteratschgletscher, Switzerland[J]. Journal of Glaciology, 1998, 44(147): 231-238.
[2]	Ding Yongjian, Liu Shiyin, Li Jing, et al. The retreat of glaciers in response to recent climate warming in Western China[J]. Annals of Glaciology, 2006, 43(1): 97-105.
[3]	Yao Tandong, Wang Yongqing, Liu Shiyin, et al. Recent glacial retreat in High Asia in China and its impact on water resources in Northwest China[J]. Science in China (Series D: Earth Sciences), 2004, 47(12): 1065-1075.
[4]	Xiao Cunde, Liu Shiyin, Zhao Lin, et al. Observed changes of cryosphere in China over the second half of the 20th century: An overview[J]. Annals of Glaciology, 2007, 46(1): 382-390.
[5]	Knap W H, Brock B W, Oerlemans J, et al. Comparison of Landsat-TM derived and ground-based albedo of Haut Glacier d'Arolla[J]. International Journal of Remote Sensing, 1999, 20(17): 3293-3310.
[6]	Knap W H, Oerlemans J. The surface albedo of the Greenland ice sheet: satellite-derived and in situ measurements in the Sndre Strmfjord area during the 1991 melt season[J]. Journal of Glaciology, 1996, 42(141): 364-374.
[7]	Hall D K, Chang A T C, Foster J L. Comparison of in situ and Landsat-derived reflectance of Alaskan glaciers[J]. Remote Sensing of Environment, 1989, 28: 23-31.
[8]	Stroeve J, Nolin A, Steffen K. Comparison of AVHRR-derived and in situ surface albedo over the Greenland ice sheet[J]. Remote Sensing of Environment, 1997, 62(3): 262-276.
[9]	Koelemeijer R, Oerlemans J, Tjemkes S. Surface reflectance of Hintereisferner, Austria, from Landsat 5 TM imagery[J]. Annals of Glaciology, 1993, 17: 17-21.
[10]	Stroeve J C, Box J E, Gao Feng, et al. Accuracy assessment of the MODIS 16-day albedo product for snow: comparisons with Greenland in situ measurements[J]. Remote Sensing of Environment, 2005, 94: 46-60.
[11]	Hock R. Glacier melts: a review of processes and their modeling[J]. Progress in Physical Geography, 2005, 29(3): 362-391.
[12]	Stroeve J C, Box J E, Haran T. Commentary on comparison of MODIS snow cover and albedo products with ground observations over the mountainous terrain of Turkey[J]. Hydrology and Earth System Sciences Discussion, 2006, 3: 3655-3673.
[13]	Bai Zhongyuan, Ohata T. Variations of albedo on the Glacier No.1 at the headwater of Vrümqi River, Tianshan Mountains, during the summer ablation period[J]. Journal of Glaciology and Geocryology, 1989, 11(4): 311-324. [白重瑗, 大火田哲夫. 天山乌鲁木齐河源1号冰川夏季消融期内反射率的变化[J]. 冰川冻土, 1989, 11(4): 311-324.]
[14]	Jiang Xi, Wang Ninglian, He Jianqiao, et al. A study of parameterization of albedo on the Qiyi Glacier in Qilian Mountains, China[J]. Journal of Glaciology and Geocryology, 2011, 33(1): 30-37. [蒋熹, 王宁练, 贺建桥, 等. 祁连山七一冰川反照率的参数化研究[J]. 冰川冻土, 2011, 33(1): 30-37.]
[15]	Jiang Xi, Wang Ninglian, Pu Jianchen, et al. The albedo on the Qiyi Glacier in Qilian Mountains during the ablation period[J]. Journal of Glaciology and Geocryology, 2008, 30(5): 752-760. [蒋熹, 王宁练, 蒲健辰, 等. 夏季消融期祁连山"七一"冰川反照率初步研究[J]. 冰川冻土, 2008, 30(5): 752-760.]
[16]	Yang Xingguo, Qin Dahe, Zhang Tingjun, et al. Seasonal characteristics of surface radiative fluxes on the East Rongbuk Glacier in the north slope of Mt. Qomolangma (Mt. Everest) region[J]. Acta Meteorologica Sinica, 2010, 68(1): 19-31. [杨兴国, 秦大河, 张廷军, 等. 珠穆朗玛峰北坡绒布冰川表面辐射特征观测研究[J]. 气象学报, 2010, 68(1): 19-31.]
[17]	Sun Weijun, Qin Xiang, Ren Jiawen, et al. Surface energy balance in the accumulation zone of the Laohugou Glacier No.12 in the Qilian Mountains during ablation period[J]. Journal of Glaciology and Geocryology, 2011, 33(1): 38-46. [孙维君, 秦翔, 任贾文, 等. 祁连山老虎沟12号冰川积累区消融期能量平衡特征[J]. 冰川冻土, 2011, 33(1): 38-46.]
[18]	Wang Jie. The Spatiotemporal Variations and Parameterizations of Albedo on Nine Representative Glaciers in Western China. PhD Thesis, Lanzhou: Cold and Arid Regions Environmental and Engineering Research Institute, Chinese Academy of Sciences, 2012: 1-132. [王杰. 中国西部典型冰川反照率变化特征与参数化模拟. 博士论文, 兰州: 中国科学院寒区旱区环境与工程研究所, 2012: 1-132.]
[19]	Wang Jie, He Xiaobo, Ye Baisheng, et al. Variations of albedo on the Dongkemadi Glacier, Tanggula Range[J]. Journal of Glaciology and Geocryology, 2012, 34(1): 21-28. [王杰, 何晓波, 叶柏生, 等. 唐古拉山冬克玛底冰川反照率变化特征研究[J]. 冰川冻土, 2012, 34(1): 21-28.]
[20]	Mao Ruijuan, Jiang Xi, Guo Zhongming, et al. Study of the inversion precision of albedo on the Qiyi Glacier in the Qilian Mountain based on TM/ETM+ image[J]. Journal of Glaciology and Geocryology, 2013, 35(2): 301-309. [毛瑞娟, 蒋熹, 郭忠明, 等. 基于TM/ETM+影像反演祁连山七一冰川反照率精度比较研究[J]. 冰川冻土, 2013, 35(2): 301-309.]
[21]	Mao Ruijuan, Wu Hongbo, He Jianqiao, et al. Spatiotemporal variation of albedo of Muztagh Glacier in the Kunlun Mountains and its relation to dust[J]. Journal of Glaciology and Geocryology, 2013, 35(5): 1133-1142. [毛瑞娟, 吴红波, 贺建桥, 等. 昆仑山木孜塔格冰川反照率变化特征及其与粉尘的关系[J]. 冰川冻土, 2013, 35(5): 1133-1142.]
[22]	Liu Shiyin, Ding Yongjian, Li Jing, et al. Glaciers in response to recent climate warming in Western China[J]. Quaternary Sciences, 2006, 26(5): 762-771. [刘时银, 丁永建, 李晶, 等. 中国西部冰川对近期气候变暖的响应[J]. 第四纪研究, 2006, 26(5): 762-771.]
[23]	Bernard é, Friedt J M, Tolle F, et al. Monitoring seasonal snow dynamics using ground based high resolution photography (Austre Lovénbreen, Svalbard, 79°N)[J]. ISPRS Journal of Photogrammetry and Remote Sensing, 2013, 75: 92-100.
[24]	Kerr T, Clark M, Hendrikx J, et al. Snow distribution in a steep mid-latitude alpine catchment[J]. Advances in Water Resources, 2013, 55: 17-24.
[25]	Farinotti D, Magnusson J, Huss M, et al. Snow accumulation distribution inferred from time-lapse photography and simple modeling[J]. Hydrological Processes, 2010, 24: 2087-2097.
[26]	Schmidt S, Weber B, Winiger M. Analyses of seasonal snow disappearance in an alpine valley from micro- to meso-scale (Loetschemtal, Switzerland)[J]. Hydrological Processes, 2009, 23: 1041-1051.
[27]	Dumont M, Arnaud Y, Six D, et al. Retrieval of glacier surface albedo using terrestrial photography[J]. La Houille Blanche, 2009, 18: 102-108.
[28]	Boush W, Munroe J S, Fagre D B. Development of a spatial analysis method using ground-based repeat photography to detect changes in the alpine treeline ecotone, Glacier National Park, Montana, USA[J]. Arctic, Antarctic and Alpine Research, 2007, 39(2): 297-308.
[29]	Corripio J G. Snow surface albedo estimation using terrestrial photography[J]. International Journal of Remote Sensing, 2004, 25(24): 5705-5729.
[30]	Zhang Yingsong, Liu Shiyin, Shangguan Donghui. Ground multi-based digital photogrammetry for surveying the Heigou Glacier No.8 in the Mt. Bogda, Tianshan Mountains[J]. Journal of Glaciology and Geocryology, 2012, 34(5): 1184-1189. [张盈松, 刘时银, 上官冬辉. 地面多基线数字摄影测量在冰川测量中的应用——以博格达峰黑沟8号冰川为例[J]. 冰川冻土, 2012, 34(5): 1184-1189.]
[31]	Landstaedter R, Kaufmann V. Change detection of a mountain slope by means of ground-based photogrammetry: A case study in the Austrian Alps[C]//4th ICA Mountain Cartography Workshop, Vall de Núria, Catalonia, Spain, September 30-October 2, 2004.
[32]	Durand Y, Guyomarc'h G, Merindol L, et al. Improvement of a numerical snow drift model and field validation[J]. Cold Regions Science and Technology, 2005, 43: 93-103.
[33]	Dumont M, Sirguey P, Arnaud Y, et al. Monitoring spatial and temporal variations of surface albedo on Sant Sorlin Glacier (French Alps) using terrestrial photography[J]. The Cryosphere, 2011, 5: 759-771.
[34]	Dumont M, Durand Y, Arnaud Y, et al. Variational assimilation of albedo in a snowpack model an reconstruction of the spatial distribution of an alpine glacier[J]. Journal of Glaciology, 2012, 58(207): 151-164.
[35]	Sirguey P, Mathieu R, Arnaud Y. Subpixel monitoring of the seasonal snow cover with MODIS at 250 m spatial resolution in the Southern Alps of New Zealand: methodology and accuracy assessment[J]. Remote Sensing of Environment, 2009, 113: 160-181.
[36]	Javier G C, Yves D, Gilbert B H, et al. Land-based remote sensing of snow for the validation of a snow transport model[J]. Cold Regions Science and Technology, 2004, 39: 93-104.
[37]	Tong Qingxi, Zheng Lanfen, Wang Jinnian, et al. Study on imaging spectrometer remote sensing information for wetland vegetation[J]. Journal of Remote Sensing, 1997, 1(1): 40-57. [童庆禧, 郑兰芬, 王晋年, 等. 湿地植被成像光谱遥感研究[J]. 遥感学报, 1997, 1(1): 40-57.]
[38]	Feng Wenhao. Close-Range Photogrammetry[M]. Wuhan: Wuhan University Press, 2002: 1-16.
[39]	Wendler G, Kelley J. On the albedo of snow in Antarctica: A contribution to I.A.G.O.[J]. Journal of Glaciology, 1988, 34(116): 19-25.
[40]	Hubley R C. Measurements of diurnal variations in snow albedo on Lemon Creek Glacier, Alaska[J]. Journal of Glaciology, 1955, 2(18): 560-563.
[41]	Chen Jizu, Qin Xiang, Wu Jinkui, et al. Simulating the energy and mass balance on the Laohugou Glacier No.12 in the Qilian Mountains[J]. Journal of Glaciology and Geocryology, 2014, 36(1): 38-47. [陈记祖, 秦翔, 吴锦奎, 等. 祁连山老虎沟12号冰川表面能量和物质平衡模拟[J]. 冰川冻土, 2014, 36(1): 38-47.]

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