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1.
《气象与环境学报》2016,(6)
利用国家气象信息中心基于最优插值法(Optimal Interpolation,OI)、ANUSPLIN插值法(AV 2.0)、普通克里格法(Ordinary Kriging,OK)的1.0°×1.0°与0.5°×0.5°格点化的1961—2004年中国区域月温度和月降水资料及1961—2004年美国NCDC的GHCN 5.0°×5.0°月降水资料,对中国大陆地区温度和降水不同插值方法空间插值数据的精度及时间序列进行了对比研究。结果表明:在1961—2004年平均气候态下,中国区域不同插值法插值后的降水和温度空间分布型较一致,年循环变化也较一致。在中国区域、东部区域和西部区域,OI与AV 2.0方法插值的降水场绝对误差分别为2.15 mm、1.28 mm和0.00 mm,OK与AV 2.0方法插值的温度场绝对误差分别为0.20℃、0.05℃和0.45℃。对于中国区域降水场时间序列,AV 2.0和OI方法插值的降水与GHCN不同季节的降水变化趋势较一致,且不同插值方法插值的夏季降水量差异较大,冬季降水量差异较小。1961—2004年AV 2.0与OI方法插值的降水场相关系数在0.22—0.98之间变化,冬季和春季降水场相关性较高,夏季和秋季降水场相关性较低;个别年份秋季和冬季插值后降水量的偏差稍大,最大偏差达3.08 mm,1961—2004年平均降水量偏差为0.64 mm。AV 2.0与OK方法插值的年平均温度差值小于0.54℃,且多年时间序列变化趋势较一致。 相似文献
2.
中国地面均一化相对湿度月值格点数据集的建立 总被引:3,自引:3,他引:0
基于1951—2014年2400余个中国国家级地面气象站均一化相对湿度资料,采用薄盘样条法,进行空间内插,得到了中国地面均一化相对湿度月值0.5°×0.5°格点数据集(CR数据集)。数据集的质量评估结果表明:冬季插值误差相对夏季偏高。冬、春、夏、秋季分析值与站点实测值的插值偏差空间区域特征不显著,平均偏差分别为0.002%/月、0.013%/月、0.008%/月和0.007%/月。冬、春、夏、秋季平均相对误差分别为0.431%/月、0.439%/月、0.286%/月和0.382%/月。分析值与站点实测值间的平均相关系数达0.89。整体来看,插值后的格点化相对湿度资料能够比较准确、细致地描述我国年平均相对湿度场的东南湿、西北干的主要空间特征。能够较好地展现长江以南地区、黄河以南长江以北地区、西北地区、天山南北麓、塔里木盆地等大地形的相对湿度变化特征。由于青藏高原台站稀少,格点数据集对该地区空气相对湿度特征的刻画是否合理很难给出定性、定量的判断。通过对CR数据集进行长时间序列气候变化趋势分析,表明60年来全国平均相对湿度呈减小趋势。 相似文献
3.
用Kriging方法对中国历史气温数据插值可行性讨论 总被引:11,自引:0,他引:11
使用 Kriging 插值方法对已经过质量控制和均一化的1951年1月-2004年12月中国全部基本、基准站气温资料逐月进行空间插值.通过站点的实际序列与插值后格点序列进行比较,针对相关系数和线性趋势等多个量来检验 Kriging 方法对气候资料插值的效果.结果表明:插值前、后的气温空间分布、气温变化趋势都非常一致,从年际变化来看,插值序列与实际站点序列的相关性也非常高.对比分析还发现用距平序列的插值效果要明显优于原始气温序列插值,但不同的球面模型半径插值在站点稀疏地区的插值结果差别较大,需要先对气候要素进行空间代表性进行分析,以合适的球面半径进行插值.对于气候变化比较特殊的地区,如中国西南部分地区,插值序列很难反映更小尺度的气候变化规律. 相似文献
4.
利用1961—2015年中国地面降水日值05°×05°格点数据集(V20)(下称V20格点资料)及同期陕西省内55站逐日降水资料,评估了V20格点资料在陕西地区的适用性,并分析了近年来不同等级降水事件在陕西地区的时空变化特征。结果表明:V20格点降水资料在陕北地区的误差较小,在关中大部较实况降水偏大,在陕南地区较实况偏小;各等级降水在全省呈现出南多北少的分布特征,V20中雨和大雨等级降水空间分布与实况较为一致,V20小雨雨量及雨日大于实况,V20暴雨事件较实况显著偏少;观察不同等级降水的时空变化特征发现,小雨在全省大部呈下降趋势,中雨在陕北北部、关中大部及陕南东部呈增加趋势,在陕北南部及陕南西部等地减少,大雨和暴雨在全省大部增加,V20各等级降水变化幅度小于实况变幅,暴雨事件变化趋势差异最大。 相似文献
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近50a中国降水格点数据集的建立及质量评估 总被引:11,自引:2,他引:9
基于2012年6月更新的高质量2 400个台站降水资料,采用薄盘样条法,制定了采用3个自变量(经度、纬度、海拔高度)、降水量开平方预处理、3次样条的插值方案,并引入数字高程资料,以减弱中国独特地形条件下高程对降水空间插值精度的影响,并对1961—2010年中国区域地面降水站点资料进行了空间内插,得到了中国地面降水0.5°×0.5°格点数据集。经数据集的质量评估结果表明:分析值与站点观测值均方根误差平均为0.49 mm,相关系数平均达0.93(通过0.01的显著性检验),夏季插值误差高于冬季,东南地区误差普遍高于其他地区。冬、春、夏、秋季绝大多数台站绝对误差在±10 mm/月以内。冬、春、夏、秋季分别有60%、82%、54%、77%的台站相对误差在±10%之间。插值后的格点化降水资料能够比较细致、准确地描述中国大陆年平均降水场的东南多、西北少的主要空间特征,但也平滑掉了范围很小的降水极值中心。台站分布越密集的地方,插值效果越好,并且最近距离小于40 km的台站插值精度较高,大于40 km插值精度衰减较快。 相似文献
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利用2019年1—12月国家气象信息中心实况格点资料、贵州地面观测站资料以及ECMWF 2 m气温起报场资料,讨论了相同插值方案下站点数对空间分布的反演效果以及相同测站数下不同插值方案的表现,同时对国家气象信息中心实况格点场进行检验,并对本地建立的气温格点分析场进行初步评估。结果表明:相同的插值方案下,站数越多越能反映要素场的实际分布状态;基于贵州特殊地形,在相同站数下双线性插值法优于邻域法;通过对国家气象信息中心实况格点分析场评估,日最高、最低气温在贵州区域均存在明显误差,其平均绝对误差分别为1.6℃与1.1℃左右,平均RMSE分别达2.2℃与1.6℃。采用Cressman方案对离散观测资料重建的本地化气温格点分析场进行评估,其最高、最低气温平均绝对误差降至0.2℃与0.1℃左右,大幅度降低了与测站观测值的差异,基本可以代替国家气象信息中心下发的气温格点分析场,并将为今后贵州省业务或研究工作中格点预报的客观订正提供新的更符合实际的参考。 相似文献
7.
使用2012~2014年每年3~5月CUACE(China Meteorological Administration Unified Atmospheric Chemistry Environment)模式地面沙尘浓度格点预报产品,预报员预报等级产品、实况地面观测沙尘等级和特征站观测PM10(空气动力学当量直径小于等于10 μm的颗粒物,即可吸入颗粒物)资料,并针对CUACE模式格点产品,选取不同半径对格点产品进行圆插值,从而对2012~2014年共25次沙尘过程值,采取3年总样本计算TS(Threat Score)评分,对格点产品适合的圆插值半径和预报产品适合的检验实况资料进行研究,结论如下:(1)如实况采用沙尘等级,模式插值半径与TS评分在浮尘或扬沙等级成近似线性下降关系,而在沙尘暴以上等级TS评分与插值半径关系几乎不大,最优插值半径可选为最小插值半径0.5°(经度/纬度);如实况采用PM10资料,TS评分在浮尘或扬沙等级根据半径不同变化较为剧烈,沙尘暴以上等级TS评分与插值半径关系不大,可以采用浮尘或扬沙平均线3.5°为平均最优插值半径。如果沙尘过程较弱,插值半径可适当减小,以1°最合适;(2)对CUACE模式预报产品,沙尘等级观测TS评分可用性要优于PM10资料,但两者在沙尘暴以上等级评分差别不大,总体上CUACE模式最优检验实况资料可选为沙尘等级观测资料。对预报员沙尘预报产品,观测沙尘等级TS评分要远高于PM10,预报员沙尘预报产品最优检验实况资料为观测沙尘等级资料。 相似文献
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西藏地区旱涝等级划分及时空分布特征 总被引:7,自引:3,他引:7
利用西藏22个站点1969-1998年逐日降水资料,采用d指数旱涝等级方法。按夏季(5-9月),初夏(5-6月),盛夏(7-8月)时段进行了旱涝等级划分。采用EOF分析方法对全区22个站点旱涝等级展开分解,得出西藏地区的旱涝时空分布特征,主要类型和周期,而且对西藏地区夏季(5-9月)的旱涝做了预测。 相似文献
9.
将Hulme的全球陆地格点化降水资料在中国陆地区域内同测站值进行了对比分析。结果表明,格点化资料能较好地描述降水场的大尺度特征,40多个格点值序列代表了全国近200个测站记录,并具有较高的时空覆盖率。当仅对中国区域内的降水进行分析时,为使资料的代表性更好,需对位于国界附近和沿海地区格点的序列值进行必要的修正。 相似文献
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利用葵花8号卫星资料和地面降水观测资料,采用Spark GBT(Gradient Boosted Trees Regression)学习算法对中国西部地区进行定量降水估计(QPE),采用三维Barnes插值方法得到逐时降水格点场。试验结果表明,引入卫星资料估计降水,可以有效地改进站点密度小的区域的降水格点场的客观分析精度。 相似文献
11.
Using the International Comprehensive Ocean-Atmosphere Data Set(ICOADS) and ERA-Interim data, spatial distributions of air-sea temperature difference(ASTD) in the South China Sea(SCS) for the past 35 years are compared,and variations of spatial and temporal distributions of ASTD in this region are addressed using empirical orthogonal function decomposition and wavelet analysis methods. The results indicate that both ICOADS and ERA-Interim data can reflect actual distribution characteristics of ASTD in the SCS, but values of ASTD from the ERA-Interim data are smaller than those of the ICOADS data in the same region. In addition, the ASTD characteristics from the ERA-Interim data are not obvious inshore. A seesaw-type, north-south distribution of ASTD is dominant in the SCS; i.e., a positive peak in the south is associated with a negative peak in the north in November, and a negative peak in the south is accompanied by a positive peak in the north during April and May. Interannual ASTD variations in summer or autumn are decreasing. There is a seesaw-type distribution of ASTD between Beibu Bay and most of the SCS in summer, and the center of large values is in the Nansha Islands area in autumn. The ASTD in the SCS has a strong quasi-3a oscillation period in all seasons, and a quasi-11 a period in winter and spring. The ASTD is positively correlated with the Nio3.4 index in summer and autumn but negatively correlated in spring and winter. 相似文献
12.
Fei LIU Chen XING Jinbao LI Bin WANG Jing CHAI Chaochao GAO Gang HUANG Jian LIU Deliang CHEN 《大气科学进展》2020,37(7):663-670
正The Taal Volcano in Luzon is one of the most active and dangerous volcanoes of the Philippines. A recent eruption occurred on 12 January 2020(Fig. 1a), and this volcano is still active with the occurrence of volcanic earthquakes. The eruption has become a deep concern worldwide, not only for its damage on local society, but also for potential hazardous consequences on the Earth's climate and environment. 相似文献
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The moving-window correlation analysis was applied to investigate the relationship between autumn Indian Ocean Dipole (IOD) events and the synchronous autumn precipitation in Huaxi region, based on the daily precipitation, sea surface temperature (SST) and atmospheric circulation data from 1960 to 2012. The correlation curves of IOD and the early modulation of Huaxi region’s autumn precipitation indicated a mutational site appeared in the 1970s. During 1960 to 1979, when the IOD was in positive phase in autumn, the circulations changed from a “W” shape to an ”M” shape at 500 hPa in Asia middle-high latitude region. Cold flux got into the Sichuan province with Northwest flow, the positive anomaly of the water vapor flux transported from Western Pacific to Huaxi region strengthened, caused precipitation increase in east Huaxi region. During 1980 to 1999, when the IOD in autumn was positive phase, the atmospheric circulation presented a “W” shape at 500 hPa, the positive anomaly of the water vapor flux transported from Bay of Bengal to Huaxi region strengthened, caused precipitation ascend in west Huaxi region. In summary, the Indian Ocean changed from cold phase to warm phase since the 1970s, caused the instability of the inter-annual relationship between the IOD and the autumn rainfall in Huaxi region. 相似文献
14.
The atmospheric and oceanic conditions before the onset of EP El Ni?o and CP El Ni?o in nearly 30 years are compared and analyzed by using 850 hPa wind, 20℃ isotherm depth, sea surface temperature and the Wheeler and Hendon index. The results are as follows: In the western equatorial Pacific, the occurrence of the anomalously strong westerly winds of the EP El Ni?o is earlier than that of the CP El Ni?o. Its intensity is far stronger than that of the CP El Ni?o. Two months before the El Ni?o, the anomaly westerly winds of the EP El Ni?o have extended to the eastern Pacific region, while the westerly wind anomaly of the CP El Ni?o can only extend to the west of the dateline three months before the El Ni?o and later stay there. Unlike the EP El Ni?o, the CP El Ni?o is always associated with easterly wind anomaly in the eastern equatorial Pacific before its onset. The thermocline depth anomaly of the EP El Ni?o can significantly move eastward and deepen. In addition, we also find that the evolution of thermocline is ahead of the development of the sea surface temperature for the EP El Ni?o. The strong MJO activity of the EP El Ni?o in the western and central Pacific is earlier than that of the CP El Ni?o. Measured by the standard deviation of the zonal wind square, the intensity of MJO activity of the EP El Ni?o is significantly greater than that of the CP El Ni?o before the onset of El Ni?o. 相似文献
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Various features of the atmospheric environment affect the number of migratory insects, besides their initial population. However, little is known about the impact of atmospheric low-frequency oscillation(10 to 90 days) on insect migration. A case study was conducted to ascertain the influence of low-frequency atmospheric oscillation on the immigration of brown planthopper, Nilaparvata lugens(Stl), in Hunan and Jiangxi provinces. The results showed the following:(1) The number of immigrating N. lugens from April to June of 2007 through 2016 mainly exhibited a periodic oscillation of 10 to 20 days.(2) The 10-20 d low-frequency number of immigrating N. lugens was significantly correlated with a low-frequency wind field and a geopotential height field at 850 h Pa.(3) During the peak phase of immigration, southwest or south winds served as a driving force and carried N. lugens populations northward, and when in the back of the trough and the front of the ridge, the downward airflow created a favorable condition for N. lugens to land in the study area. In conclusion, the northward migration of N. lugens was influenced by a low-frequency atmospheric circulation based on the analysis of dynamics. This study was the first research connecting atmospheric low-frequency oscillation to insect migration. 相似文献
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基于最新的GTAP8 (Global Trade Analysis Project)数据库,使用投入产出法,分析了2004年到2007年全球贸易变化下南北集团贸易隐含碳变化及对全球碳排放的影响。结果显示,随着发展中国家进出口规模扩张,全球贸易隐含碳流向的重心逐渐向发展中国家转移。2004年到2007年,发达国家高端设备制造业和服务业出口以及发展中国家资源、能源密集型行业及中低端制造业出口的趋势加强,该过程的生产转移导致全球碳排放增长4.15亿t,占研究时段全球贸易隐含碳增量的63%。未来发展中国家的出口隐含碳比重还将进一步提高。贸易变化带来的南北集团隐含碳流动变化对全球应对气候变化行动的影响日益突出,发达国家对此负有重要责任。 相似文献
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Hourly outgoing longwave radiation(OLR) from the geostationary satellite Communication Oceanography Meteorological Satellite(COMS) has been retrieved since June 2010. The COMS OLR retrieval algorithms are based on regression analyses of radiative transfer simulations for spectral functions of COMS infrared channels. This study documents the accuracies of OLRs for future climate applications by making an intercomparison of four OLRs from one single-channel algorithm(OLR12.0using the 12.0 μm channel) and three multiple-channel algorithms(OLR10.8+12.0using the 10.8 and 12.0 μm channels; OLR6.7+10.8using the 6.7 and 10.8 μm channels; and OLR All using the 6.7, 10.8, and 12.0 μm channels). The COMS OLRs from these algorithms were validated with direct measurements of OLR from a broadband radiometer of the Clouds and Earth's Radiant Energy System(CERES) over the full COMS field of view [roughly(50°S–50°N, 70°–170°E)] during April 2011.Validation results show that the root-mean-square errors of COMS OLRs are 5–7 W m-2, which indicates good agreement with CERES OLR over the vast domain. OLR6.7+10.8and OLR All have much smaller errors(~ 6 W m-2) than OLR12.0and OLR10.8+12.0(~ 8 W m-2). Moreover, the small errors of OLR6.7+10.8and OLR All are systematic and can be readily reduced through additional mean bias correction and/or radiance calibration. These results indicate a noteworthy role of the6.7 μm water vapor absorption channel in improving the accuracy of the OLRs. The dependence of the accuracy of COMS OLRs on various surface, atmospheric, and observational conditions is also discussed. 相似文献
18.
Analysis of Atmospheric Boundary Layer Height Characteristics over the Arctic Ocean Using the Aircraft and GPS Soundings 
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下载免费PDF全文 正ERRATUM to: Atmospheric and Oceanic Science Letters, 4(2011), 124-130 On page 126 of the printed edition (Issue 2, Volume 4), Fig. 2 was a wrong figure because the contact author made mistake giving the wrong one. The corrected edition has been updated on our website. The editorial office is sincerely sorry for any 相似文献
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《大气科学进展》2014,(6)
正AN Junling;see LI Ying et al.;(5),1221—1232AN Junling;see QU Yu et al.;(4),787-800AN Junling;see WANG Feng et al.;(6),1331-1342Ania POLOMSKA-HARLICK;see Jieshun ZHU et al.;(4),743-754Baek-Min KIM;see Seong-Joong KIM et al.;(4),863-878BAI Tao;see LI Gang et al.;(1),66-84BAO Qing;see YANG Jing et al.;(5),1147—1156BEI Naifang; 相似文献