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Based on daily precipitation records at 75 meteorological stations in Hunan Province, central south China, the spatial and temporal variability of precipitation indices is analyzed during 1961–2010. For precipitation extremes, most of precipitation indices suggest that both the amount and the intensity of extreme precipitation are increasing, especially the mean precipitation amount on a wet day, showing a significant positive trend. Meanwhile, both of the monthly rainfall heterogeneity and the contribution of the days with the greatest rainfall show an upward trend. When it comes to rainfall erosivity, most of this province is characterized by high values of annual rainfall erosivity. Although the directions of trends in annual rainfall erosivity at most stations are upward, only 6 of the 75 stations have significant trends. Furthermore, the spatial and temporal variation of dryness/wetness has been assessed by the standardized precipitation index (SPI). The principal component analysis (PCA) was applied to the SPI series computed on 24-month time scales. The results demonstrated a noticeable spatial variability with three subregions characterized by different trends: a remarkable wet tendency prevails in the central and southern areas, while the northern areas are dominated by a remarkable dry tendency. 相似文献
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初始场中尺度信息对暴雨预报的影响 总被引:3,自引:1,他引:2
由于观测资料分辨率与模式分辨率的不同,利用高分辨率模式对暴雨进行预报时,常规观测资料形成的初始场不能直接分辨出中尺度系统,这种中尺度系统特征的缺少可以认为是初始场的一种信息误差。利用中尺度天气分析的尺度分离方法可以提取这种中尺度信息。通过分析初始场中尺度信息的结构、演变特征及其对暴雨预报影响的机理,发现初始场中尺度信息的结构在主要雨带的对流敏感区具有明确的天气学意义,包含了有利暴雨产生的信息;其能量随时间也是增长的,特别是在积分12小时以后,能量迅速增长然后趋于稳定,超过了初始随机扰动的能量增长。利用减弱和增强初始场中中尺度信息的两种初始场作暴雨预报,其结果反映了初始场中尺度信息对暴雨预报的重要性,特别是对雨团位置和强度的预报,这些信息会直接影响暴雨的精细预报。 相似文献
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Laurent Pfister Gilles Drogue Abdelkhalak El Idrissi Jean-François Iffly Christelle Poirier Lucien Hoffmann 《Climatic change》2004,66(1-2):67-87
The spatial variability of observed trends in rainfall structure over the last 5 decades and its effects on the spatial variability of maximum daily water levels in the Grand-Duchy of Luxembourg (Europe) were investigated in 9 sub-basins of the Mosel river. Over the past 25 years, an increase in westerly atmospheric circulation types during winter months has caused an increase in winter rainfall totals, duration and intensity. More specifically, the spatial variability of trends having affected winter rainfall totals, duration and intensity have led to spatially varying positive trends in maximum daily water levels. Observed trends in rainfall characteristics and maximum daily water levels during winter show closely linked spatial patterns that are strongly related to the topography of the study area. 相似文献
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S. Dutta 《Meteorology and Atmospheric Physics》2007,95(1-2):1-14
Summary A mesoscale three-dimensional (3-D) dynamical model is presented to diagnose orographic rainfall, with particular reference
to the Western Ghats (WG) in India. This model has two parts, namely, a dynamical part and a thermodynamical part. In the
dynamical part the vertical velocity induced by a mesoscale elliptical orographic barrier has been computed using the perturbation
technique. In the thermodynamical part rainfall intensity (RFI) has been computed using the computed vertical velocities,
with the help of continuity of moisture and mass. The computed RFI has been compared with observed RFI as well as with that
computed by 2-D model.
The present study shows that during the southwest monsoon season (SWMS), orographic rainfall enhancement in the WG area appears
to be solely due to the vertical shear of the basic flow and its variation with height. Stability appears to have very little
influence on it.
The spatial distribution of RFI across the barrier shows that there are four regions of maximum rainfall, one primary on the
windward side behind the peak of the barrier and three secondary on the leeward side. The symmetry in the locations of these
secondary rainfall maxima appears to be critically dependent on the component of basic flow parallel to the major ridge axis
of the barrier. 相似文献
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Improving the accuracy of tipping-bucket rain records using disaggregation techniques 总被引:1,自引:0,他引:1
We present a methodology able to infer the influence of rainfall measurement errors on the reliability of extreme rainfall statistics. We especially focus on systematic mechanical errors affecting the most popular rain intensity measurement instrument, namely the tipping-bucket rain-gauge (TBR). Such uncertainty strongly depends on the measured rainfall intensity (RI) with systematic underestimation of high RIs, leading to a biased estimation of extreme rain rates statistics. Furthermore, since intense rain-rates are usually recorded over short intervals in time, any possible correction strongly depends on the time resolution of the recorded data sets. We propose a simple procedure for the correction of low resolution data series after disaggregation at a suitable scale, so that the assessment of the influence of systematic errors on rainfall statistics become possible. The disaggregation procedure is applied to a 40-year long rain-depth dataset recorded at hourly resolution by using the IRP (Iterated Random Pulse) algorithm. A set of extreme statistics, commonly used in urban hydrology practice, have been extracted from simulated data and compared with the ones obtained after direct correction of a 12-year high resolution (1 min) RI series. In particular, the depth–duration–frequency curves derived from the original and corrected data sets have been compared in order to quantify the impact of non-corrected rain intensity measurements on design rainfall and the related statistical parameters. Preliminary results suggest that the IRP model, due to its skill in reproducing extreme rainfall intensities at fine resolution in time, is well suited in supporting rainfall intensity correction techniques. 相似文献
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采用安徽省15站近60年来的降水资料,研究了季节和年雨日、降水量及雨强的气候变化特征.结果表明:1)空间分布上,雨日、降水量"南多北少",雨强中北部地区相当,皆小于南部地区;雨日数南北在冬春季相差较大,降水量夏季最多、冬季最少,雨强上南北在春季相差较大;雨日、降水量及雨强在年和季节上基本呈现显著正相关关系.2)时间演变上,雨日在减少,降水量、雨强在增多(大),且表现为两阶段的变化特征;小波分析显示约10 a的年代际周期变化,雨日上存在、降水量上在衰减、雨强上则不明显,约5 a、3 a的周期变化存在较多;雨日在春秋季减少明显,降水量春秋季减少,夏冬季增加但不明显,雨强尤以夏冬季增大明显;无论是年还是各季节的时间演变上,降水量与雨日、雨强均呈显著正相关,但雨日与雨强之间相关性则差些. 相似文献
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利用中国地面台站逐日和逐时降水资料,对中国东南沿海地区近40年(1967-2006年)盛夏(7-8月)降水强度变化特征进行了分析.逐日降水资料的分析结果表明我国东南沿海盛夏的降水量呈显著增加趋势,且主要是由日降水强度增强所致,日降水频次的贡献不显著.结合逐时降水资料的分析结果发现,东南沿海地区虽然降水日的平均降水时数显著增加,平均逐时降水强度也显著增强.通过按降水持续时数确定的降水事件分类分析发现,短持续降水(≤4h)平均小时强度显著增强,具体表现为弱小时强度降水减少和强降水增多.长持续性降水(≥15h)平均小时强度减弱,但降水频次增加.由于长持续性降水的平均小时降水强度远大于短时降水平均小时强度,对整体小时强度增强是正贡献.总之,我国东南沿海盛夏平均降水强度增强主要来自长持续性降水频次的增多、短时强降水频次的增多和短时弱降水频次的减少. 相似文献
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近50年广东省分级降水的时空分布特征及其变化趋势的研究 总被引:6,自引:2,他引:6
利用广东省86个常规气象观测站1961—2010年的逐日降水资料,分析近50年广东省降水气候特征,探讨不同等级降水空间分布及随时间变化特征。结果表明:广东省降水丰沛,年均降水量多为1 500~2 000 mm;降水气候特征的区域差异较大,不同区域降水量与降水日数分布差异显著;各月的降水日数差异没有降水量月分布的差异明显,非汛期的日降水量较小,而汛期降水日数多且日降水量大;小雨日和中雨日的区域差异小,大雨日、暴雨日、大暴雨日的大值中心主要集中在广东省的三大暴雨中心地区 (清远中心、阳江中心、海陆丰中心),雨日量级分布大致由北向南逐渐增强,且随着降水等级的增加降雨日数迅速减少;小雨、中雨和大雨的降水贡献率均由粤北地区向沿海地区递减,暴雨和大暴雨的贡献率由粤北向沿海递增;小雨日数显著减少、大雨以上日数略有增多,总降水日数也呈减少趋势;小雨和中雨的贡献率呈减少趋势,大雨以上贡献率增多,使年均降水量呈增多趋势。 相似文献
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1961—2015年中国暴雨变化诊断及其与多种气候因子的关联性研究 总被引:5,自引:4,他引:5
气候变化背景下,频发的暴雨事件造成城市内涝、人员伤亡和财产损失,已经成为全社会广泛关注的焦点问题之一。为了诊断中国暴雨的时空变化及其与不同自然因子的关联性,采用1961—2015年中国659个降水站点数据,采用线性趋势、EOF分析等多种统计方法诊断了中国暴雨时空变化特征,结果表明,中国暴雨雨量、雨日和雨强在1961—2015年以胡焕庸线为界呈现出东南高-西北低的气候态空间分布格局;线性趋势分析表明1961—2015年中国暴雨雨量和雨日从东南沿海向西北内陆呈明显“增-减-增”的空间分布格局,且呈增长趋势的站点占主导,分别高达80.88%和79.81%;从西北内陆到东南沿海的年代剖面分析表明中国暴雨雨量和雨日随着年代推移在迅速增长;对低通滤波后的中国暴雨进行EOF分析表明中国暴雨雨量和雨日的增长东南沿海快,内陆地区慢。根据IPCC等已有研究中筛选出对中国地区有影响的28个气候因子,并将其与659个站点的暴雨进行相关分析,结果表明不同气候因子与不同区域暴雨呈现出错综复杂的相关性特征,其中与暴雨雨量呈现以正相关和负相关为主的气候因子分别为15和13个,全局相关因子包含AAO(Antarctic Oscillation)、Pacific Warmpool,而其它气候因子在七大分区中与暴雨的关联性各有突出,表现出明显的空间异质性。 相似文献
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Natural variability of summer rainfall over China in HadCM3 总被引:1,自引:0,他引:1
Summer rainfall over China has shown decadal variability in the past half century, which has resulted in major north–south shifts in rainfall with important implications for flooding and water resource management. This study has demonstrated how multi-century climate model simulations can be used to explore interdecadal natural variability in the climate system in order to address important questions around recent changes in Chinese summer rainfall, and whether or not anthropogenic climate change is playing a role. Using a 1,000-year simulation of HadCM3 with constant pre-industrial external forcing, the dominant modes of total and interdecadal natural variability in Chinese summer rainfall have been analysed. It has been shown that these modes are comparable in magnitude and in temporal and spatial characteristics to those observed in the latter part of the twentieth century. However, despite 1,000 years of model simulation it has not been possible to demonstrate that these modes are related to similar variations in the global circulation and surface temperature forcing occurring during the latter half of the twentieth century. This may be in part due to model biases. Consequently, recent changes in the spatial distribution of Chinese summer rainfall cannot be attributed solely to natural variability, nor has it been possible to eliminate the likelihood that anthropogenic climate change has been the driving factor. It is more likely that both play a role. 相似文献
12.
新疆南部(简称南疆)是典型的干旱区,地形和下垫面复杂,生态环境脆弱,对气候变化异常敏感。在全球变暖背景下,近年来南疆暴雨发生频率和强度明显增加,引起社会广泛关注。本文主要回顾了南疆干旱区暴雨的科学认知、研究进程和最新研究进展,南疆暴雨具有降水集中度高、相对强度大、极端性强、空间分布不均匀等特点。南疆暴雨研究经过了从大降水个例到多尺度相互作用机理和数值模拟发展应用的阶段,目前在南疆暴雨的重要影响天气系统和水汽输送等方面取得新的科学认识。最后,对干旱区暴雨科学研究的未来发展方向进行了简要的讨论和展望,以期承上启下,为未来新时期南疆暴雨研究提供创新基础。 相似文献
13.
Summary The west coast of the Indian peninsula receives very heavy rainfall during the summer Monsoon (June–September) season with
average rainfall over some parts exceeding 250 cm. Heavy rainfall events with rainfall more than 15 cm day−1 at one or more stations along the west coast of India occur frequently and cause considerable damage. A special observational
programme, Arabian Sea Monsoon Experiment, was carried out during the monsoon season of 2002 to study these events. The spatial
and temporal distributions of intense rainfall events, presented here, were used for the planning of this observational campaign.
The present study using daily rainfall data for summer monsoon season of 37 years (1951–1987) shows that the probability of
getting intense rainfall is the maximum between 14° N–16° N and near 19° N. The probability of occurrence of these intense
rainfall events is high from mid June to mid August, with a dip in early July. It has been believed for a long time that offshore
troughs and vortices are responsible for these intense rainfall events. However, analysis of the characteristics of cloud
systems associated with the intense rainfall events during 1985–1988 using very high resolution brightness temperature data
from INSAT-IB satellite shows that the cloud systems during these events are characterized by large spatial scales and high cloud tops.
Further study using daily satellite derived outgoing longwave radiation (OLR) data over a longer period (1975–1998) shows
that, most of these events (about 62%) are associated with systems organized on synoptic and larger scales. We find that most
of the offshore convective systems responsible for intense rainfall along the west coast of India are linked to the atmospheric
conditions over equatorial Indian Ocean. 相似文献
14.
城市地区强降水发生频次和强度的增加容易诱发内涝现象,年径流总量控制率作为海绵城市的重要设计参数,更是直接受到降水变化的影响。以江苏省为例,利用全省70个国家级气象观测站1961—2019年最新的日降水量资料评估了气候变化对城市年径流总量控制率分区的影响。研究发现,有效降水的年代际变化十分明显,1991—2019年降水日数、降水量、降水强度均比其他时间段上更多、更强;太湖流域的设计雨量较小,连云港地区的设计雨量较大,南北差异随着控制率的提高而扩大,当控制率为85%时,全省设计雨量平均值为38.1 mm,最大值是最小值的1.7倍;气候变化对年径流总量控制率分区影响明显,江苏的苏南、江淮南部大部分地区的分区变大,导致全省IV区所占面积明显增加。不同等级降水的变化趋势是影响年径流控制率分区的关键因素,大雨以上的雨日、雨量在有效降水中占比增加,则分区变大。 相似文献
15.
The ability of state-of-the-art climate models to capture the mean spatial and temporal characteristics of daily intense rainfall events over Africa is evaluated by analyzing regional climate model (RCM) simulations at 90- and 30-km along with output from four atmospheric general circulation models (AGCMs) and coupled atmosphere–ocean general circulation models (AOGCMs) of the Climate Model Intercomparison Project 5. Daily intense rainfall events are extracted at grid point scale using a 95th percentile threshold approach applied to all rainy days (i.e., daily rainfall ≥1 mm day?1) over the 1998–2008 period for which two satellite-derived precipitation products are available. Both RCM simulations provide similar results. They accurately capture the spatial and temporal characteristics of intense events, while they tend to overestimate their number and underestimate their intensity. The skill of AGCMs and AOGCMs is generally similar over the African continent and similar to previous global climate model generations. The majority of the AGCMs and AOGCMs greatly overestimate the frequency of intense events, particularly in the tropics, generally fail at simulating the observed intensity, and systematically overestimate their spatial coverage. The RCM performs at least as well as the most accurate global climate model, demonstrating a clear added value to general circulation model simulations and the usefulness of regional modeling for investigating the physics leading to intense events and their change under global warming. 相似文献
16.
Sukanta Kumar Das Sanjib Kumar Deb C. M. Kishtawal P. K. Pal 《Theoretical and Applied Climatology》2012,109(1-2):81-94
Seasonal prediction of Indian Summer Monsoon (ISM) has been attempted for the current year 2011 using Community Atmosphere Model (CAM) developed at the National Centre for Atmospheric Research (NCAR). First, 30?years of model climatology starting from 1981 to 2010 has been generated to capture the variability of ISM over the Indian region using 30 seasonal simulations. The simulated model climatology has been validated with different sets of observed climatology, and it was observed that the simulated climatological rainfall is affected by model bias. Subsequently, a bias correction procedure using the Tropical Rainfall Measuring Mission (TRMM) 3B43 rainfall has been proposed. The bias-corrected rainfall climatology shows both spatial and temporal variability of ISM satisfactorily. Further, four sets of 10-member ensemble simulations of ISM 2009 and 2010 have been performed in hindcast mode using observed sea surface temperature (SST) and persistence of April SST anomaly, and it has been found that the bias-corrected model rainfall captures the seasonal variability of ISM reasonably well with some discrepancies in these two contrasting monsoon years. With this positive background, the seasonal prediction of ISM 2011 has been carried out in forecast mode with the assumption of persistence of May SST anomaly from June through September 2011. The model assessment shows an 11% deficiency in All-India Rainfall (AIR) of ISM 2011. In particular, the monthly accumulated rains are predicted to be 101% (17.6?cm), 86% (24.3?cm), 83% (21.0?cm) and 95% (15.5?cm) of normal AIR for the months of June, July, August and September, respectively. 相似文献
17.
C. V. Singh 《大气科学进展》1998,15(3):424-432
There are limitations in using the seasonal rainfall total in studies of Monsoon rainfall climatology. A correlation analysis of the individual station seasonal rainfall with all India seasonal mean rainfall has been made. After taking the significance test (strictly up to 5% level) the stations which are significantly correlated have been considered in this study in normal, flood and drought years respectively. Analysis of seasonal rainfall data of 50 stations spread over a period of 41 years suggests that a linear relationship fits better than the logarithmic relationship when seasonal rain-fall versus number of rainy days is studied. The linear relationship is also found to be better in the case of seasonal rainfall versus mean daily intensity. 相似文献
18.
2017年6月18日北京门头沟地区突发泥石流,造成6人伤亡。短时强降水是这起事件的主要诱发因素,但常规气象观测并没有很好地观测到此次降水过程,可见降水数据的准确性对于滑坡泥石流的实时预警及预报至关重要。近年来,卫星遥感估算降水发展迅速,WRF(Weather Research and Forecasting Model)模式关于降水的预报技巧也逐渐提高。本文以自动站降水资料为参考,首先利用定性方法和泰勒图、TS(Threat Score)评分等定量的方法比较了CMORPH(CPC MORPHing technique)、GPM(Global Precipitation Measurement)和PERSIANN-CCS(Precipitation Estimation from Remotely Sensed Information using Artificial Neural Networks-Cloud Classification System)三种卫星降水资料以及不同起报时间的WRF预报降水对此次降水过程的表现能力,然后利用降水数据驱动滑坡泥石流统计预报模型,对此次事件进行了回报,分析不同降水数据在模型中的实际应用效果,最终为滑坡泥石流实时预警和预报系统的构建提供参考。结果表明,三种卫星降水资料基本上能反映出此次降水过程东北—西南向的带状空间分布形态,其中,CMORPH与自动站资料的空间相关性最好,命中率也最高,但对降水量有一定的高估,GPM对平均降水量的时间变化有较好的反映,体现了卫星降水在观测较少地区的良好利用价值,PERSIANN-CCS的表现则相对差些。WRF模式能预报出此次降水的带状空间分布特征,但降水中心的位置与实际有所偏差;此外,预报的最大降水量的峰值出现时间比实际上晚。由于此次降水的强局地性,只有空间分辨率均匀且质量相对较好的CMORPH卫星降水驱动模型可以回报出此次事件,而自动站点资料由于空间分布不均,则没有回报出此次事件,这表明了卫星降水在滑坡泥石流实时预警系统的构建中具有一定的优势。WRF模式降水驱动模型可以提前做出预警,虽然预报的事件发生时间与实际相比偏晚3~5 h,但WRF可以较好地预报72 h内的降水,因而可以延长灾害的可预见期。WRF模式预报降水的时间和空间精度都需要进一步提高,但是仍具有很好的参考意义。 相似文献
19.
利用高分辨率区域气候模式Reg CM3对华北地区1991—2002年夏季气候进行了数值模拟,对照中国台站的实测资料,对模拟的华北地区夏季降水、温度进行了较为全面的比较,以检验模式的模拟性能。对平均场的模拟结果检验认为,该区域气候模式对华北地区夏季降水的空间分布模拟存在一定的误差,河套地区及黄河以南地区降水量接近实况,沿着太行山脉及东部沿海地区降水量明显偏多。模式对温度的模拟误差较小,较好地再现了气温的空间分布特征,但山西及以北地区模拟的温度略偏低。模式能够较好地模拟出华北地区夏季降水和气温的年际变化,成功再现了该区域降水和气温的异常变化。模式能够成功模拟出该区域降水和气温日变化特征,特别是对于逐年夏季的降水日变化过程的峰值和谷值均有成功表现,对于典型年份华北地区较强降水过程中降水发生的时间、落区、强度等也有再现能力,不足的是模拟的降水量比观测偏大。对于模式误差是否与地形或模式积云对流参数化方案等有关,需要进一步探讨。 相似文献
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利用1971-2007年东亚地区夏季(6-8月)逐日格点降水资料,借助事件同步法建立格点之间的非线性相关,构建了极端降水复杂网络,从复杂网络的角度研究了东亚地区极端降水的区域性特征,并利用复杂网络中的关联强度和关联方向信息,从极端降水时、空记忆性的角度构建了预测模型。复杂网络结构特征量表明:北部陆地地区的夏季极端降水空间同步性好,而沿海地区的夏季极端降水空间同步性差。不同地区的格点与周围格点的关联空间范围不一样,沿海地区格点之间远距离连接少,关联空间范围小,北部陆地地区格点之间远距离连接多,关联空间范围较大。极端降水预测模拟结果显示沿海地区的预测准确率一般高于北部陆地地区,其原因是该地区极端降水强度大、降水密集度高且空间格点的平均连接距离小、直接关联性强。研究表明,从时、空记忆的角度构建的预测模型对东亚地区的极端降水具有一定的预测能力,在极端降水研究中存在一定的潜在应用价值。 相似文献