基于VSWI法的云南省土壤水分反演研究
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- 英文论文题名:Research of Soil Moisture Retrieval Based on VSWI in Yunnan Province
- 论文作者:曹言 ; 王杰 ; 李竹芬 ; 刘永宇 ; 张雷 ; 戚娜
- 英文论文作者:CAO Yan ; WANG Jie ; Li Zhufen ; LIU Yongyu ; ZHANG Lei ; QI Na ; Yunnan Institute of Water Resources and Hydropower Research ; Ho Hai University
- 年:2016
- 作者机构:云南省水利水电科学研究院;河海大学;
- 论文关键词:植被供水指数法 ; 云南省 ; 土壤含水量 ; 反演
- 英文论文关键词:VSWI ; Yunnan province ; soil moisture ; retrieval
- 会议召开时间:2016-11-01
- 会议录名称:云南省水利学会2016年度学术年会论文集
- 语种:中文
- 分类号:S152.7;S127
- 学会代码:YNKX
- 会议名称:云南省水利学会2016年度学术年会
- 会议地点:中国云南昆明
- 主办单位:云南省水利学会
- 学会名称:云南省科学技术协会
- 页数:14
- 文件大小:1135k
- 原文格式:D
- 会议级别:地方
摘要
基于2008年~2012年MODIS遥感数据和云南省23个土壤墒情站的土壤含水量数据,构建植被供水指数(VSWI)模型,开展云南省土壤水分反演研究。结果表明:(1)VSWI与土壤相对含水量呈负相关,VSWI与40cm处土壤相对含水量相关性最为显著,与20cm处土壤相对含水量显著性最差,且VSWI_N比VSWI_E更适合云南干旱监测。(2)VSWI_N能够准确的反映土壤水分的变化趋势,但其表现有一定的滞后性,大概滞后一个月左右,其中VSWI_N最大值出现在春季(3月~5月),VSWI_N最小值出现在降水最多的夏季(7月或8月)。(3)2008年~2012年云南省土壤墒情在时间上表现出波动降低的趋势,在季节上表现出夏秋两季高,冬春两季低的趋势,且夏季最高,春季最低的特征,在空间上表现出中部低,四周高的趋势。
Based on MODIS data from 2008 to 2012 and soil moisture data from 23 stations, Vegetation Supply Water Index(VSWI) has been calculated to study soil moisture retrieval in Yunnan province. The results show that negative correlation exists between VSWI and soil relative moisture, VSWI and soil relative moisture in the 40 cm has the significant correlation,Compared with 20 cm, the soil relative moisture has significantly poorer, furthermore, VSIW_N is better than VSIW_E for Yunnan drought monitoring. VSIW_N can accurately reflect the change trend of soil moisture, but its performance has a certain lag, it is may lag about a month or so. The maximum value of VSIW_N appeared in spring(March ~ May), The minimum value of VSIW_N appeared in summer(August or July) with the most precipitation. The soil relative moisture showed a decreasing trend in Yunnan province during 2008~2012 year, It has obvious seasonal variation that reaches a maximum in summer and a minimum in spring, Moreover, The relative soil moisture present a trend that lower in the center and higher around the center in Yunnan.
Based on MODIS data from 2008 to 2012 and soil moisture data from 23 stations, Vegetation Supply Water Index(VSWI) has been calculated to study soil moisture retrieval in Yunnan province. The results show that negative correlation exists between VSWI and soil relative moisture, VSWI and soil relative moisture in the 40 cm has the significant correlation,Compared with 20 cm, the soil relative moisture has significantly poorer, furthermore, VSIW_N is better than VSIW_E for Yunnan drought monitoring. VSIW_N can accurately reflect the change trend of soil moisture, but its performance has a certain lag, it is may lag about a month or so. The maximum value of VSIW_N appeared in spring(March ~ May), The minimum value of VSIW_N appeared in summer(August or July) with the most precipitation. The soil relative moisture showed a decreasing trend in Yunnan province during 2008~2012 year, It has obvious seasonal variation that reaches a maximum in summer and a minimum in spring, Moreover, The relative soil moisture present a trend that lower in the center and higher around the center in Yunnan.
引文
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[19]王正兴,刘闯.植被指数研究进展:从AVHRR-NDVI到MODIS-EVI[J].生态学报,2003,23(5):979~987.
[20]王密侠,马成军.农业干旱指标研究与进展[J].干旱地区农业研究,1998,16(3):119~124.
[21]王杰,曹言,张鹏,张雷.云南省土壤墒情时空变化特征分析[J].节水灌溉,2016(5):97~101.
[2]叶笃正,黄荣辉.长江黄河流域旱涝规律和成因研究[M].济南:山东科技出版社,1996.
[3]国家防汛抗旱总指挥部,中华人民共和国水利部.中国水旱灾害公报2010[M].北京:气象出版社,2010:34~48.
[4]陈云芬.全省干旱等级达80年以上一遇[N].云南日报,2010-3-17(1).
[5]全国12省区遭遇严重干旱[Z].新闻1+1.2014.1(8).
[6]解明恩,程建刚.云南气象灾害特征及成因分析[J].地理科学,2004,24(6):721~726.
[7]杜灵通,侯静,胡悦,王新云,王磊.基于遥感温度植被干旱指数的宁夏2000-201年旱情变化特征[J].农业工程学报,2015,31(14):209~216
[8]马建威,黄诗峰,胡健伟,等.基于MODIS数据的山东省土壤墒情遥感动态监测与分析[J].水文,2013,33(3):29~42.
[9]汝博文,缴锡云,王耀飞,郭维华.基于MODIS数据的土壤水分空间变异规律[J].中国农村水利水电.2016(4):38~42.
[10]李喆,谭德宝,张穗.遥感干旱监测在抗旱减灾应用中的若干思考[J].人民长江,2012,43(8):84~87.
[11]Rouse J W,Haas R H,Scheu J A,et al.Monitoring the vernal advancements and retrogradation(green wave effect)of nature vegetation[R].NASA/GSFC Final Report,NASA,1974:371~375.
[12]Shutko A M.Microwave radiometry of lands under natural and artificial moistening[J].IEEE Transactions on Geoscience and Remote Sensing,1982(20):18~26.
[13]鲍艳松,严婧,闵锦忠,王冬梅,李紫甜,李鑫川.基于温度植被干旱指数的江苏淮北地区农业干旱监测[J].农业工程学报,2014,30(7):163~172.
[14]赵福年,张虹,陈家宇,等.作物水分胁迫指数监测红壤农田短期干旱的分析[J].土壤通报,2013(2):314~320.
[15]王建傅,王蕾彬.基于植被供水指数的山东省2013年春季旱情监测[J].山东农业科学,2015,47(7):111-116
[16]肖国杰,李国春,赵丽华,等.植被供水指数法在辽西干旱监测中的应用[J].农业网络信息,2006(4):106~107.
[17]吴金亮,王玉成,杨国范.基于条件温度植被指数的土壤水分反演研究[J].节水灌溉,2014(7):16~18.
[18]杨丽萍,杨晓华,张存厚.植被供水指数发在内蒙古干旱监测中的应用[J].内蒙古农业科技,2008(1):58~59.
[19]王正兴,刘闯.植被指数研究进展:从AVHRR-NDVI到MODIS-EVI[J].生态学报,2003,23(5):979~987.
[20]王密侠,马成军.农业干旱指标研究与进展[J].干旱地区农业研究,1998,16(3):119~124.
[21]王杰,曹言,张鹏,张雷.云南省土壤墒情时空变化特征分析[J].节水灌溉,2016(5):97~101.