天山云杉雪盖面积估算树冠截留雪水当量实验分析

doi:10.13866/j.azr.2020.02.08

摘要/Abstract

摘要： 雪水当量是一个能直观反映出积雪水资源量的重要指标，准确而全面地获取天山云杉树冠截留雪水当量信息，对于提高天山水资源量计算精度方面具有重要意义。本文以天山云杉树苗为研究对象，通过模拟降雪，进行降雪截留实验研究。利用数码照相机获取云杉的雪盖面积、高精度天平称量树冠上截留的雪水质量，进而建立起云杉树苗雪盖面积和雪水当量之间的关系。实验结果表明：多株云杉树苗多次模拟降雪，树冠截留的雪水当量和垂直朝下数字摄影获得的雪盖面积之间拟合曲线趋于一致，且拟合回归方程满足y=21.235x²-1.457x（R²=0.9925）；通过云杉多次模拟降雪实验，构建云杉雪盖面积与树冠截留的雪水当量模型，提出一套利用雪盖面积较为准确估算树冠截留雪水当量的科学方法，为天山云杉树冠截留降雪及其雪水当量提供高精度估算模型。

关键词: 天山云杉, 树苗, 模拟降雪, 雪盖面积, 数字照片, 雪水当量, 估算模型

Abstract: The snow water equivalent is an important indicator that can directly reflect the amount of snow waterresources.An accurate and comprehensive acquisition of snow water equivalent data intercepted by the Tianshan spruce canopy is of considerable significance to improve the calculation accuracy of the Tianshan water resources.In this study,experiments were conducted to investigate the snow interception of spruce using simulated snow and the Tianshan spruce saplings.The snow cover area of the spruce was obtained using a camera,and the mass of the spruce canopy interception water was measured using a highprecision balance.Further,the relation between the snow cover area and the snow water equivalent was established.The experimental results show that the fitting curves between the snow water equivalent of the spruce canopy interception water and the spruce snow cover area obtained via vertical downward digital photography tend to be consistent for multiple spruce saplings over several simulated snowfall events; the fitted regression equation is y=21.235x²-1.457x(R²=0.992 5).Using repeated simulations of the spruce snowfall experiment,the snow cover and snow water equivalent of the spruce canopy interception models were obtained. Accordingly, a scientific method has been proposed to estimate the snow water equivalent of the spruce canopy interception based on the snow cover to provide a highprecision estimation model with respect to the intercepted snowfall and snow water equivalent of the Tianshan spruce canopy.

Key words: Tianshan spruce, sapling, simulated snowfall, snow cover area, digital photo, snow water equivalent, estimation model

王毅帆, 谢玲, 常顺利, 刘素红, 玛丽亚木·玛木提, 米尔扎提·依明, 阿卜杜外力·阿卜杜克热木. 天山云杉雪盖面积估算树冠截留雪水当量实验分析[J]. 干旱区研究, 2020, 37(2): 341-348.

WANG Yifan, XIE Ling, CHANG Shunli, LIU Suhong, Mariam Mamuti, Mirzati Yimin, Abdowli Abdukrmu. Experimental analysis for estimating the canopy snow water equivalent intercepted by the snow cover area of the Tianshan spruce[J]. Arid Zone Research, 2020, 37(2): 341-348.

参考文献

［1］Adam J C,Hamlet A F,Lettenmaier D P.Implications of global climate change for snowmelt hydrology in the twentyfirst century［J］.Hydrological Processes,2010,23(7):962-972.
［2］Shi J,Dozier J.Estimation of snow water equivalence using SIRC/XSAR.I.Inferring snow density and subsurface properties［J］.IEEE Transactions on Geoscience & Remote Sensing,2000,38(6):2465-2474.
［3］肖洋,张淑兰,宋国华.森林冠层影响降雪截留过程的研究进展［J］.水科学进展,2017,28(3):144-153.［Xiao Yang,Zhang Shulan,Song Guohua.Review on the influence of forest canopy on the process of snowfall interception［J］.Advances in Water Science,2017,28(3):144-153.］
［4］赵文宇.基于被动微波遥感和MODIS产品的天山雪水当量降尺度研究［D］.石河子：石河子大学,2016.［Zhao Wenyu.A Downscaling Method for Snow Water Equivalent Using Passive Microwave Remote Data and MODIS Products in the Tianshan Mountains［D］.Shihezi:Shihezi University,2016.］
［5］唐志光,王建,梁继,等.基于MODIS的青藏高原雪线高度遥感监测［J］.遥感技术与应用,2015,30(4):767-774.［Tang Zhiguang,Wang Jian,Liang Ji,et al.Monitoring of snowline altitude over the Tibetan Plateau based on MODIS Data［J］.Remote Sensing Technology and Application,2015,30(4):767-774.］
［6］阚希,张永宏,曹庭,等.利用多光谱卫星遥感和深度学习方法进行青藏高原积雪判识［J］.测绘学报,2016,45(10):1210-1221.［Kan Xi,Zhang Yonghong,Cao Ting,et al.Snow cover recognition for QinghaiTibetan Plateau using deep learning and multispectral remote sensing［J］.Acta Geodaetica et Cartographica Sinica,2016,45(10):1210-1221.］
［7］肖雄新,张廷军.基于被动微波遥感的积雪深度和雪水当量反演研究进展［J］.地球科学进展,2018,33(6):590-605.［Xiao Xiongxin,Zhang Tingjun.Passive microwave remote sensing of snow depth and snow water equivalent:overview［J］.Advances in Earth Science,2018,33(6):590-605.］
［8］曹云刚,刘闯.从AVHRR到MODIS的雪盖制图研究进展［J］.地理与地理信息科学,2005，21(5):15-19.［Cao Yungang,Liu Chuang.The development of snowcover mapping from AVHRR to MODIS［J］.Geography and GeoInformation Science,2005，21(5):15-19.］
［9］蒋友严,杜文涛,韩涛,等.基于HJ-1B数据的积雪制图NDSI阈值分析——以祁连山积雪为例［J］.冰川冻土,2013,35(3):648-655.［Jiang Youyan,Du Wentao,Han Tao,et al.Analysis on NDSI threshold in mapping snow cover based on HJ-1B dataa case study of snow in the Qilian Mountains［J］.Journal of Glaciology and Geocryology,2013,35(3):648-655.］
［10］夏坤,罗勇,李伟平.BATSSAST模式对积雪深度的模拟试验与改进［J］.冰川冻土,2009,31(5):871-879.［Xia Kun,Luo Yong,Li Weiping.Snow depths simulated by BATSSAST model and its improvement［J］.Journal of Glaciology and Geocryology,2009,31(5):871-879.］
［11］辛颖.阿什河上游天然次生林与人工林小流域水文生态效益〖JP2〗对比研究［D］.哈尔滨：东北林业大学,2011.［Xin Ying.Comparison〖JP〗 of Hydrological Ecology between Secondary Forest and Artificial Forest Small Watershed in the Upper Reaches of Ashihe River［D］.Harbin:Northeast Forestry University,2011.］
［12］汪凌霄,肖鹏峰,冯学智.天山典型林带积雪的多角度遥感识〖JP2〗别［J］.遥感学报,2012,16(5):1035-1042,1044-1053.［Wang〖JP〗 Lingxiao,Xiao Pengfeng,Feng Xuezhi.Retrieving snow information in typical forest zone of Tianshan mountains from multiangle imaging spetroradiometer data［J］.Journal of Remote Sensing,2012,16(5):1035-1042,1044-1053.］
［13］Gary H L.Airflow patterns and snow accumulation in a forest clearing (Pinus contorta latifolia,pines,Colorado,Wyoming)［C］//ProceedingsWestern Snow Conference (USA).1978.
［14］Pomeroy J W,Granter R J,Pietroniro A,et al.Hydrological Pathways in the Prince Albert Model Forest,NHRI Contribution Series No.CS-97004［J］.National Hydrology Research Institute,Environment Canada:Saskatoon,1997.
［15］Musselman K N,Molotch N P,Brooks P D.Effects of vegetation on snow accumulation and ablation in a midlatitude subalpine forest［J］.Hydrological Processes:An International Journal,2008,22(15):2767-2776.
［16］Woods S W,Ahl R,Sappington J,et al.Snow accumulation in thinned lodgepole pine stands,Montana,USA［J］.Forest Ecology and Management,2006,235(1-3):202-211.
［17］车涛,李新,高峰.青藏高原积雪深度和雪水当量的被动微波遥感反演［J］.冰川冻土,2004,26(3):363-368.［Che Tao,Li Xin,Gao Feng.Estimation of snow water equivalent in the Tibetan Plateau using passive microwave remote sensing data(SSM/I)［J］.Journal of Glaciology and Geocryology,2004,26(3):363-368.］
［18］孙之文,施建成,蒋玲梅,等.被动微波遥感反演中国西部地区雪深、雪水当量算法初步研究［J］.地球科学进展,2006,21(12):1363-1369.［Sun Zhiwen,Shi Jiancheng,Jiang Lingmei,et al.Development of snow depth and snow water equivalent algorithm in western China using passive microwave remote sensing data［J］.Advances in Earth Science,2006,21(12):1363-1369.］
［19］李新,车涛.积雪被动微波遥感研究进展［J］.冰川冻土,2007,29(3):487-496.［Li Xin,Che Tao.A review on passive microwave remote sensing of snow cover［J］.Journal of Glaciology and Geocryology,2007,29(3):487-496.］
［20］黄慰军,黄镇,崔彩霞,等.新疆雪密度分布研究［J］.中国农业气象,2007,28(4):383-385.［Huang Weijun,Huang Zhen,Cui Caixia,et al.Study on snow density distribution in Xinjiang［J］.Chinese Journal of Agrometeorology,2007,28(4):383-385］
［21］汪左,冯学智,肖鹏峰,等.基于合成孔径雷达图像的山区雪水当量反演［J］.南京大学学报（自然科学版）,2015,51(5):996-1004.［Wang Zuo,Feng Xuezhi,Xiao Pengfeng,et al.Retrieval of snow water equivalence using SAR data for mountains area［J］.Journal of Nanjing University(Natural Science Edition),2015,51(5):996-1004.］
［22］施建成,熊川,蒋玲梅.雪水当量主被动微波遥感研究进展［J］.中国科学:地球科学,2016,46(4):529.［Shi Jiancheng,Xiong Chuan,Jiang Lingmei.Review of snow water equivalent microwave remote sensing［J］.Science China Earth Sciences,2016,46(4):529.］
［23］郑明国,蔡强国.一种新的土地覆盖类别面积估计方法及其在最大似然分类法中的应用［J］.资源科学,2007,29(3):214-220.［Zheng Mingguo,Cai Qiangguo.A new approach to area estimation by land cover category and its application in Maximum Likelihood classification［J］.Resources Science,2007,29(3):214-220］
［24］Strahler A H.The use of prior probabilities in maximum likelihood classification of remotely sensed data［J］.Remote Sensing of Environment,1980,10(2):135-163.
［25］彭望.遥感数据的计算机处理与地理信息系统［M］.北京：北京师范大学出版社，1991.［Peng Wang.The Computer Data Processing of Remote Sensing Data and Geographical Information System［M］.Beijing:Beijing Normal University Press,1991.］
［26］张庆费,周晓峰.黑龙江省中部地区森林对融雪径流的影响［J］.植物资源与环境学报,1994,3(3):36-40.［Zhang Qingfei,Zhou Xiaofeng.Influence of forest on snowflow in the middle region of Heilongjiang Province［J］.Journal of Plant Resources and Environment,1994,3(3):36-40.］
［27］Varhola A,Coops N C,Weiler M,et al.Forest canopy effects on snow accumulation and ablation:An integrative review of empirical results［J］.Journal of Hydrology,2010,392(3-4):219-233.
［28］Moeser D,Morsdorf F,Jonas T.Novel forest structure metrics from airborne LiDAR data for improved snow interception estimation［J］.Agricultural and Forest Meteorology,2015,208:40-49.
［29］俞正祥,韩广忠,蔡体久,等.基于GF-1遥感数据的大兴安岭林区雪水当量反演［J］.南京林业大学学报(自然科学版),2017,41(3):105-111.［Yu Zhengxiang,Han Guangzhong,Cai Tijiu,et al.Comparison between GF-1 data and Landsat-8 data in inversing SWE of the forest in the northern of Greater Khingan Mountain［J］.Journal of Nanjing Forestry University(Natural Sciences Edition),2017,41(3):105-111.］
［30］彭焕华,赵传燕,沈卫华,等.祁连山北坡青海云杉林冠对降雨截留空间模拟——以排露沟流域为例［J］.干旱区地理,2010,〖JP2〗33(4):600-606.［Peng Huanhua,Zhao Chuanyan,Shen Weihua,〖JP〗et al.Modeling rainfall canopy interception of 〖WTBX〗Picea crassifolia〖WTBZ〗 forest in Northern Slope of Qilian Mountains:a case of Pailugou catchment［J］.Arid Land Geography,2010,33(4):600-606.］
［31］陈曦,姜逢清,王亚俊,等.亚洲中部干旱区生态地理格局研究［J］.干旱区研究,2013,30(3):385-390.［Chen Xi，Jiang Fengqing,Wang Yajun,et al.Characteristics of the ecogeographical pattern in arid land of central Asia［J］.Arid Zone Research,2013,30(3):385-390.］
［32］王涛，霍彦峰，罗艳.近300 a来天山中西部降水与太阳活动的小波分析［J］.干旱区研究,2016,33(4):708-717.［Wang Tao,Huo Yanfeng,Luo Yan.Precipitation and sunspots in the central west Tianshan Mountains in recent 300 years［J］.Arid Zone Research,2016,33(4):708-717.］
［33］Andreadis K M,Storck P,Lettenmaier D P.Modeling snow accumulation and ablation processes in forested environments［J］.Water Resources Research,2009,45(5):1-13.
［34］[JP2]翟明娟,刘亚东,崔日鲜.基于冬小麦冠层数码图像的叶面积指数和叶片SPAD值的估算［J］.青岛农业大学学报(自然科学版),2016,33(2):91-96.［Zhai Mingjuan,Liu Yadong,Cui Rixian.Estimation of winter wheat leaf area index and leaf SPAD value based on digital canopy Image［J］.Journal of Qingdao Agricultural University(Natural Science Edition),2016,33(2):91-96.］[JP]
［35］蒋丽伟,张家琦,赵一臣,等.北京山区典型林分生长季叶面积指数动态变化［J］.林业资源管理,2019(2):132-136.［Jiang Liwei,Zhang Jiaqi,Zhao Yichen,et al.Dynamic change of leaf area index in the growing season of typical forests in Beijing mountainous area ［J］.Forest Resources Management,2019(2):132-136.］
［36］赵传燕,沈卫华,彭焕华.祁连山区青海云杉林冠层叶面积指数的反演方法［J］.植物生态学报,2009,33(5):860-869.［Zhao Chuanyan,Shen Weihua,Peng Huanhua.Methods for determining canopy leaf area index of picea crassifolia forest in Qilian Mountains,China［J］.Chinese Journal of Plant Ecology,2009,33(5):860-869.］
［37］Turner D P,Cohen W B,Kennedy R E,et al.Relationships between leaf area index and Landsat TM spectral vegetation indices across three temperate zone sites［J］.Remote Sensing of Environment,1999,70(1):52-68.