基于SEBAL模型的土默特右旗腾发量研究
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摘要
【目的】评价SEBAL模型在估算内蒙古包头市土默特右旗腾发量时的适用性。【方法】基于2015年作物生育期内的Landsat8遥感影像,建立SEBAL模型,估算腾发量,利用FAO Penman-Monteith公式与水量平衡法估算得到腾发量进行了验证及评价,并采用多元逐步回归方法对其影响因素进行了分析。【结果】日腾发量的分布具有明显的空间差异性,呈现出"山峰型"变化趋势。SEBAL模型腾发量估算值与水量平衡法估算值相比,相对误差的平均值为6.053%;Penman-Monteith公式计算得到的日腾发量与水量平衡法估算值相差7.682%,都在10%以内,达到了精度要求,且SEBAL模型估算腾发量的精度高于Penman-Monteith公式。日腾发量与NDVI和地表温度相关性显著,由二者建立了最优的多元逐步回归方程。【结论】在缺乏数据的情况下,利用SEBAL模型可以较为准确地估算出土右旗的腾发量,且NDVI和地表温度对其的影响较大。
【Objective】Evapotranspiration is one of the most important processes in hydrological cycle and this paper evaluates the feasibility and accuracy of the SEBAL model to estimate it in Tumoteyouqi of Baotou, Inner Mongolia.【Method】Using the Landsat8 remote sensing images taken during the crop growth season in 2015, the SEBAL model was established to estimate the evapotranspiration. The result was validated against that estimated using the FAO-recommended Penman-Monteith formula and water balance method respectively, based on the multivariate stepwise regression of the factors believed to affect evapotranspiration.【Result】The daily evapotranspiration varied spatially, peaking in the mountainous areas. Compared with that calculated from the water balance, the average relative errors of the estimated evapotranspiration from the SEBAL model and the PenmanMonteith formula was 6.053% and 7.682% respectively. Daily evapotranspiration was significantly correlated to NDVI and surface temperature, and we derived an optimal multivariate stepwise regression model to estimate the evapotranspiration.【Conclusion】In the absence of ground-truth data, the SEBAL model can provide an accurate estimation of the evapotranspiration which was affected greatly by NDVI and surface temperature.
【Objective】Evapotranspiration is one of the most important processes in hydrological cycle and this paper evaluates the feasibility and accuracy of the SEBAL model to estimate it in Tumoteyouqi of Baotou, Inner Mongolia.【Method】Using the Landsat8 remote sensing images taken during the crop growth season in 2015, the SEBAL model was established to estimate the evapotranspiration. The result was validated against that estimated using the FAO-recommended Penman-Monteith formula and water balance method respectively, based on the multivariate stepwise regression of the factors believed to affect evapotranspiration.【Result】The daily evapotranspiration varied spatially, peaking in the mountainous areas. Compared with that calculated from the water balance, the average relative errors of the estimated evapotranspiration from the SEBAL model and the PenmanMonteith formula was 6.053% and 7.682% respectively. Daily evapotranspiration was significantly correlated to NDVI and surface temperature, and we derived an optimal multivariate stepwise regression model to estimate the evapotranspiration.【Conclusion】In the absence of ground-truth data, the SEBAL model can provide an accurate estimation of the evapotranspiration which was affected greatly by NDVI and surface temperature.
引文
[1]周彦昭,周剑,李妍,等.利用SEBAL和改进的SEBAL模型估算黑河中游戈壁、绿洲的蒸散发[J].冰川冻土,2014,36(6):1 526-1 537.
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[9]周玲,张丽,许君一,等.基于SEBAL模型的漓江流域蒸散量变化分析[J].水土保持研究,2015,22(4):332-337.
[10]郭玉川,董新光.SEBAL模型在干旱区区域蒸散发估算中的应用[J].遥感信息,2007(3):75-78.
[11]倪猛,陈波,岳建华,等.洛河流域蒸散发遥感反演及其与各参数的相关性分析[J].地理与地理信息科学,2007,23(6):34-37,53.
[12]张楠楠,王文,王胤.基于HJ-1B数据和SEBAL模型的陆面蒸散发遥感估算[J].地理空间信息,2013,11(5):69-73,12.
[13]曾丽红,宋开山,张柏,等.应用Landsat数据和SEBAL模型反演区域蒸散发及其参数估算[J].遥感技术与应用,2008,23(3):255-263.
[14]柴玲,赵丽红,郑慧.土默特右旗农村城镇化的土地利用研究[J].内蒙古科技与经济,2016(8):6-7.
[15]贾琦.土默特右旗土地利用变化及其驱动力研究[J].陕西师范大学学报(自然科学版),2009,37(S1):101-102.
[16]吕海燕,李海旺,李武林.基于逐步回归分析的河南粮食产量因素研究[J].河南科学,2013,31(12):2 133-2 136.
[17]魏强,张吴平,吴亚楠,等.基于SEBAL模型的小麦水分生产率研究[J].灌溉排水学报,2017,36(7):38-46.
[2]李宝富,陈亚宁,李卫红,等.基于遥感和SEBAL模型的塔里木河干流区蒸散发估算[J].地理学报,2011,6(9):1 230-1 238.
[3]杨肖丽,任立良,袁飞,等.利用SEBAL模型对沙拉沐沦河流域蒸散发的分析[J].干旱区研究,2010,27(4):507-514.
[4]杨肖丽,任立良,雍斌.基于SEBAL模型的老哈河流域蒸散发研究[J].水电能源科学,2010,28(1):9-11.
[5]于文颖,纪瑞鹏,徐德增,等.基于SEBAL模型的盘锦湿地日蒸散估算及其分布特征[J].中国水土保持科学,2017,15(5):8-15.
[6] JOHN D. Simplified versions for the Penman evaporation equation using routine weather data[J]. Journal of Hydrology,2006,331(3):690-702.
[7] DI Suchuang, LI Zhaoliang, TANG Ronglin, et al,. Integrating two layers of soil moisture parameters into the MOD16 algorithm to improve evapotranspi ration estimations[J]. International Journal of Remote Sensing,2015,36(19/20):4 953-4 971.
[8]孙敏章,刘作新,吕谋超,等.基于陆面能量平衡方程的遥感模型[J].灌溉排水学报, 2005,24(3):74-76.
[9]周玲,张丽,许君一,等.基于SEBAL模型的漓江流域蒸散量变化分析[J].水土保持研究,2015,22(4):332-337.
[10]郭玉川,董新光.SEBAL模型在干旱区区域蒸散发估算中的应用[J].遥感信息,2007(3):75-78.
[11]倪猛,陈波,岳建华,等.洛河流域蒸散发遥感反演及其与各参数的相关性分析[J].地理与地理信息科学,2007,23(6):34-37,53.
[12]张楠楠,王文,王胤.基于HJ-1B数据和SEBAL模型的陆面蒸散发遥感估算[J].地理空间信息,2013,11(5):69-73,12.
[13]曾丽红,宋开山,张柏,等.应用Landsat数据和SEBAL模型反演区域蒸散发及其参数估算[J].遥感技术与应用,2008,23(3):255-263.
[14]柴玲,赵丽红,郑慧.土默特右旗农村城镇化的土地利用研究[J].内蒙古科技与经济,2016(8):6-7.
[15]贾琦.土默特右旗土地利用变化及其驱动力研究[J].陕西师范大学学报(自然科学版),2009,37(S1):101-102.
[16]吕海燕,李海旺,李武林.基于逐步回归分析的河南粮食产量因素研究[J].河南科学,2013,31(12):2 133-2 136.
[17]魏强,张吴平,吴亚楠,等.基于SEBAL模型的小麦水分生产率研究[J].灌溉排水学报,2017,36(7):38-46.
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