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1.
利用1979~2015年JTWC(Joint Typhoon Warning Center)最佳路径资料(2001~2015年资料用于台风风圈结构分析)及ERA-interim(0.5°×0.5°)再分析数据,统计分析我国海南岛附近区域(15.5°N~23.5°N,106°E~116°E)热带气旋(Tropical Cyclone,简称TC)低层风场的变化特征。结果表明:(1)年均5.5个TC于4~12月主要以西偏北路径进入该区域,其中海南岛东南侧海域TC出现频率最高且强TC比例最多,而岛西北区域出现频率最低,强TC比例最少。(2)TC中心位于海南岛不同方位时,其外围低层风场分布具有不同的非对称特征,且大风出现比率也各有差异;TC中心位于海南岛上时出现大风比率最高,位于岛南侧时次之,位于岛北侧时最小。(3)该区域TC平均最大风速半径(RMW)为58.3 km;TC位于岛上时RMW最大,而位于岛西南侧最小。(4)TC近中心最大风速由海上向陆地急剧减小,其高值中心主要位于雷州半岛东侧及西侧海域。(5)研究区域内TC的34节风圈半径在TC环流的东侧大而西侧小,强TC大而弱TC小。(6)不同区域TC变形程度有所差异。平均而言,位于岛西南侧TC变形最大而位于岛东南侧时变形最小。 相似文献
2.
利用2010~2016年中国地面站重要天气报文、中国气象局(CMA)热带气旋最佳路径数据集以及地面站逐小时降水资料,对热带气旋(TC)影响下我国东南地区地面大风及其伴随天气特征进行统计分析,结果表明:(1)该区域TC大风主要沿海岸线分布,至内陆频次递减;TC大风多以东北风向为主,登陆前大风站点居多,12级以上的强风速基本分布在距TC中心300 km范围内。(2)强热带风暴(STS)和台风(TY)强度TC引起的站点大风最多,但16级以上大风主要出现在强台风(STY)和超强台风(Super TY)强度等级。慢速TC引起的站点大风主要出现其移向右前侧,快速主要出现在其右后侧。TC大风中向岸风均值略大于离岸风,其中12级以上风速向岸风站点多于离岸风,但16级以上大风则是离岸风站点明显多于向岸风。(3)约89.8%的TC大风伴随降水,分布于TC中心附近,东北风为主,峰值出现在8月。约10.2%的TC大风无降水,主要分布在TC外围,北风和东南风为主,风速较弱,多出现于5月和12月。12级以上TC大风几乎均伴随着降水,而无降水TC大风风速达12级以上样本很少。(4)约23.8%的TC大风伴随强对流天... 相似文献
3.
利用2000—2014年热带气旋(TC)最佳路径、最终分析资料和静止卫星红外云顶亮温(TBB)资料,对比分析了西北太平洋(WNP),以及南海(SCS)的迅速加强(RI),与非迅速加强(non-RI)TC样本的环境背景和TBB统计特征,其中non-RI样本细分为不同的强度变化率即:缓慢加强(SI),强度稳定、缓慢减弱和迅速减弱等。结果表明,相对于SI,WNP海域的RI样本处于海表温度较高、海洋上层热容量较大、最大可能强度较大、高层辐散较强、风垂直切变(VWS)较弱和高层纬向风(U200)偏东分量较大等环境背景条件下;SCS海域的RI样本较易发生在VWS较弱的环境背景条件下。此外,相对于non-RI,支持RI发展的有利条件还包括中低层相对湿度较大、高层环境温度较低等。RI样本通常具备的TBB特征为TC内核的对流云覆盖率较大、TBB平均值相对较小。采用K最近邻分类算法进行RI预报试验,交叉检验结果表明,该方法对RI样本有一定的识别预报能力,RI样本概括率达到74.2%,技巧评分达到0.717。 相似文献
4.
本文利用美国联合台风预警中心(JTWC)、中国气象局上海台风研究所(CMA)及日本气象厅东京台风中心(JMA)3 套热带气旋(TC)数据集,分别选取TC 达到生命史极值强度时、达到台风等级时以及达到热带风暴等级时所在的位置作为研究指标,分析了1980—2013 年5—11 月西北太平洋TC 达到不同强度时所在位置的长期变化趋势。研究得出如下结论:西北太平洋TC 在达到生命史极值强度时所处的位置表现为显著向北移动的趋势,3 个不同数据集向北移动趋势值分别为90、93、113 km/10a。同时TC 在达到台风和热带风暴级别时还存在相对明显的向北和向西移动趋势。本文进一步从环境场出发,分析了垂直风切变、海表温度以及潜在生成指数等影响因子的变化特征,为TC达不同强度时所处位置的长期变化趋势给出可能的物理解释。 相似文献
5.
西北太平洋热带气旋尺度的气候特征研究 总被引:1,自引:0,他引:1
使用美国联合台风警报中心(Joint Typhoon Warning Center,简称JTWC)整编的2001-2006年的热带气旋(简称TC)资料,分析了TC尺度季节变化特征、区域分布情况,并讨论了TC尺度和强度的关系,初步探讨了西北太平洋热带气旋尺度的气候特征。研究结果表明:TC尺度有明显的季节变化特征,平均尺度在4月份最大,达到230.4km,2月份最小,为69.5km;TC尺度有明显的区域分布不均匀性,TC尺度出现最大值的区域位于28.6~29.5°N,131.1~133.0°E的海面上,而在123°E以东和12°N以南地区,TC尺度往往都在200km以下;对于不同强度的TC,其尺度与强度变幅有明显差异,热带风暴(TS)的24h尺度变幅最大,而台风(TY)的24h强度变幅最大;TC尺度和强度的相关性在不同路径下是有差异的,西北行、西行、北上型的TC尺度与强度呈显著的正相关,两者的相关系数达到了0.93以上,东北行和回旋型的TC尺度和强度的相关系数接近0.6,转向型TC的相关系数在0.85左右;此外,TC尺度和强度的相关性在其生命史的不同阶段也存在显著差异,在发展期,尺度和强度的相关性最好,其相关系数达到0.92,其他阶段相关性则减弱. 相似文献
6.
本文择优选取了国际耦合模式比较计划第五阶段(CMIP5)中19个气候模式的试验数据,预估了RCP4.5和RCP8.5典型浓度路径情景下21世纪末(2080~2099年)西北太平洋地区(0°~40°N,100°E~180°)台风环境场和台风生成潜力指数(IGP)变化。结果表明,相对于1986~2005年参考时段,21世纪末西北太平洋海洋表面温度(SST)增加,垂直风切变(VWS)和向外长波辐射(OLR)均在其与台风频数呈显著负相关的区域减少,有利于台风生成和发展;由大陆向南海延伸的低压系统减弱,不利于台风活动。总体上,在RCP8.5情景下台风环境场的变化较RCP4.5情景相对更大。利用信噪比进一步考察了模式间差异性,SST变化的信噪比在大部分地区大于3.0,在低压系统控制区海平面气压变化的信噪比大于1.0,模式间一致性较好;对于VWS和OLR,信噪比小于0.6,模式间差异较大;但在与台风频数显著负相关的地区,对OLR变化方向的模拟在模式间高度一致。与以上环境场变化相对应,未来西北太平洋IGP显著增加。 相似文献
7.
西北太平洋热带气旋迅速增强特征及其影响因子 总被引:3,自引:1,他引:2
选取西北太平洋上热带气旋(TC)24小时风速变化累积频率达95%所对应的15.4 m/s作为迅速增强(RI)的标准,研究了RI个例的基本特征以及TC自身特征因子与环境因子对RI的作用。结果表明,TC迅速增强过程的持续时间平均为33小时,最长可达78小时,并且TC经过迅速增强过程几乎都达到了台风级别以上,其中,一半以上达到了强台风级别以上。对比迅速增强(RI)和非迅速增强(non-RI)个例得到,RI个例相对于non-RI个例发生区域偏南偏东,两者的移动速度没有明显差异,但RI个例有较大向西移动分量并且前12小时增强较大;相对于non-RI个例,RI个例离最大潜在强度较远并且发生在较暖水区和55%~75%的低层相对湿度的条件下;RI个例发生在较小的垂直风切变和较弱的对流层上层东风气流情况下,由上层槽或冷低压引起的强迫弱于平均状况时RI较易发生。TC前12小时强度变化(DVMX)、海表面温度(SST)和垂直风切变(SHR)是影响迅速增强的主要因子,当DVMX≥6.3 m/s时RI发生的可能性最大,达到17.2%。当有若干个影响因子共同起作用时发生RI可能性显著增加,其中以较大的前12小时强度变化(DVMX≥6.3 m/s)、较高的海表面温度(SST≥29.4℃)、较弱的垂直风切变(SHR≤5.9 m/s)、较小的相对涡旋角动量通量辐合(REFC≤-1.6 m/(s.d))、偏东经度(LON≥138.2°E)和低纬度(LAT≤16.7°N)共同作用时,RI发生的可能性达到最大,可达66.7%。 相似文献
8.
为探究西北太平洋台风尺度对台风强度变化的影响,从美国联合台风预警中心(JTWC)2006—2015年最优路径(best track)观测资料中筛选出快速增强和非快速增强两类台风样本,采用台风最大风速半径(RMW)、34 kn(1 kn=0.51 m/s)风速等值线半径(AR34)和最外围闭合等压线半径(ROCI)三个尺度参数,初步分析了台风尺度与强度变化之间的关系。结果表明:内核尺度(RMW和AR34)与台风强度变化之间存在显著负相关,而外核尺度(ROCI)与台风强度变化之间的相关性较弱。经历和未经历快速增强过程的两类台风的初始尺度,前者显著小于后者。可以使用RMW和AR34代表的尺度参数来辅助中小尺度台风的强度预报和快速增强过程的预测。 相似文献
9.
基于2005—2020年的中国气象局台风最佳路径数据集以及葵花(Himawari-8)和风云(FY-4)卫星云图数据,结合人工智能新技术,将深度学习模型应用于台风涡旋识别、台风定位定强、台风强度突变预测等方面,具体内容主要包括基于深度图像目标检测的台风涡旋识别模型、基于图像分类和检索的台风智能定强模型以及融合时空序列特征的台风快速增强判别模型,构建了一套台风智能监测和预报系统。通过对2020年全年样本进行了测试,结果显示:该系统对强热带风暴级及以上强度的台风涡旋正确识别率达90%以上,台风强度估测的MAE和RMSE分别为3.8 m/s和5.05 m/s,对全年独立样本强度快速加强预测的综合准确率达到65.3%,该系统实现了业务上利用高时空分辨率卫星图像实时对热带气旋进行自动识别、定位定强和智能追踪的功能,为进一步提高我国台风监测和预报预警的能力提供了有利支撑。 相似文献
10.
环境风速垂直切变对西北太平洋热带气旋强度变化的影响 总被引:2,自引:0,他引:2
利用2000—2006年中国气象局《热带气旋年鉴》和NCEP再分析日资料,对环境风垂直切变对西北太平洋热带气旋(TC)强度变化的影响进行统计分析。首先比较了不同高度层之间、不同水平区域平均的全风速垂直切变和纬向风速垂直切变对TC强度变化的影响,结果表明,全风速切变对TC强度变化的抑制作用显著大于纬向风速垂直切变;以200~800 km的圆环区域平均计算的风速垂直切变与TC强度变化的负相关最显著;中高层的风速垂直切变与TC强度变化的相关优于中低层。其次,全风速切变大于8 m/s后抑制TC增强,且这种抑制作用存在6~60 h的滞后。全风速垂直切变大时,滞后时间较短:当全风速切变为8~9 m/s(9~10 m/s)时,TC强度在未来60(48) h开始减弱;当全风速切变大于10 m/s时,TC在6 h内开始减弱。最后,利用偏最小二乘回归建立TC强度变化的预报模型PLS-STIPSV。结果表明,加入风速垂直切变因子后对TC强度预报有所改进,并通过分析标准化回归系数进一步证实了上述的统计结果。 相似文献
11.
55-year (1949 - 2003) data sets are used to study the statistical characteristics in intensity change of the tropical cyclones (TC) over the western North Pacific. According to the mathematical meaning of average value and standard deviation, the abruptly intensifying, gradually intensifying, stable intensity, gradually weakening and abruptly weakening of TC intensity are defined and the statistical characteristics, such as inter-decadal variation, inter-annual variation, inter-monthly variation, and regional distribution, etc. are analyzed. Main results are as follows: (1) From 1949 to 2003, there were 1886 TCs, averaging at 34.29 TCs per year. After 1995, the number of TCs dropped dramatically with less than 30 per year. 3.56% of the total were abruptly intensifying samples, and 3.31% were weakening samples. (2) For the annual mean, all but the stable group tend to decrease with the shift of decades as far as the overall change of the 6-h isallobaric process is concerned. (3) The abruptly intensifying TC seldom occurs over mid- and high-latitude area (north of 30°N) and low-latitude area and sometimes occurs around the islands and continent. Basically there is no gradually intensifying of TC over mid- and high- latitude area (north of 30°N and west of 125°E), in offshore Chinese waters. The gradually weakening and abruptly weakening TCs usually occur offshore China, west of 125 °E, but seldom over low-latitude area (0 - 5°N). 相似文献
12.
Two different initialization schemes for tropical cyclone(TC) prediction in numerical models are evaluated based on a case study of Typhoon Lekima(2019). The first is a dynamical initialization(DI) scheme where the axisymmetric TC vortex in the initial conditions is spun up through the 6-h cycle runs before the initial forecast time. The second scheme is a bogussing scheme where the analysis TC vortex is replaced by a synthetic Rankine vortex. Results show that although both initialization schemes can help improve the simulated rapid intensification(RI) of Lekima, the simulation employing the DI scheme(DIS) reproduces better the RI onset and intensification rate than that employing the bogussing scheme(BOG).Further analyses show the cycle runs of DI help establish a realistic TC structure with stronger secondary circulation than those in the control run and BOG, leading to fast vortex spinup and contraction of the radius of maximum wind(RMW).The resultant strong inner-core primary circulation favors precession of the midlevel vortex under the moderate vertical wind shear(VWS) and thus helps vortex alignment, contributing to an earlier RI onset. Afterwards, the decreased vertical shear and the stronger convection inside the RMW support the persistent RI of Lekima in DIS. In contrast, the reduced VWS is not well captured and the inner-core convection is weaker and resides farther away from the TC center in BOG,leading to slower intensification. The results imply that the DI effectively improves the prediction of the inner-core process,which is crucial to the RI forecast. 相似文献
13.
利用1949-2006年热带气旋(TC)年鉴资料,根据2006年新制定的TC等级标准,分析了登陆我国TC的气候特征。结果表明:登陆TC中强热带风暴(STS,38.5%)最多,其余依次为台风(TY)、热带风暴(TS)、强台风(STY)和超强台风(SuperTY)。59%的STY和66.7%的SuperTY在台湾省登陆,尽管登陆广东的TC最多,但登陆的STY和SuperTY却很少。7~9月是TC登陆活跃期,而8~9月登陆TC平均强度最强。登陆TC频数具有明显的年际和年代际变化特征,其中登陆TC频数呈弱的减少趋势,而TY及以上级别TC频数则有增加趋势。在全球气候变暖背景下,登陆TC的生成源地有向北移的趋势,然而近年来南落明显。登陆TC的平均强度出现减弱趋势,但进入21世纪以来,平均强度显著增强,尤其是TC逐年强度极值表现更为明显。登陆TC的平均登陆点无明显的南北偏移,但逐年登陆点最北纬度在20世纪70年代中期以后有南落现象,以35°N以南为主。 相似文献
14.
In order to investigate the different thermodynamic mechanisms between rapid intensifying (RI) and rapid weakening (RW) tropical cyclones (TCs),the thermodynamic structures of two sets of composite TCs are analyzed based on the complete-form vertical vorticity tendency equation and the NCEP/NCAR reanalysis data.Each composite is composed of five TCs,whose intensities change rapidly over the coastal waters of China.The results show that the maximum apparent heating source Q1 exists in both the upper and lower troposphere near the RI TC center,and Q1 gets stronger at the lower level during the TC intensification period.But for the RW TC,the maximum Q1 exists at the middle level near the TC center,and Q1 gets weaker while the TC weakens.The maximum apparent moisture sink Q2 lies in the mid troposphere.Q2 becomes stronger and its peak-value height rises while TC intensifies,and vice versa.The increase of diabatic heating with height near the TC center in the mid-upper troposphere and the increase of vertical inhomogeneous heating near the TC center in the lower troposphere are both favorable to the TCs' rapid intensification; otherwise,the intensity of the TC decreases rapidly. 相似文献
15.
Combined with TRMM products and Tropical Cyclone (TC) best track data in Northwest Pacific from 1 January 2003 to 31 December 2009, a total of 118 TCs, including 336 instantaneous TC precipitation observations are established as the TRMM TC database, and the database is stratified into four intensity classes according to the standard of TC intensity adopted by China Meteorological Administration (CMA): Severe Tropical Storm (STS), Typhoon (TY), Severe Typhoon (STY) and Super Typhoon (SuperTY). For each TC snapshot, the mean rainfall distribution is computed using 10-km annuli from the TC center to a 300-km radius, then the axisymmetric component of TC rainfall is represented by the radial distribution of the azimuthal mean rain rate; the mean rain rates, rain types occurrence and contribution proportion are computed for each TC intensity class; and the mean quadrantal distribution of rain rates along TCs motion is analyzed. The result shows that: (1) TCs mean rain rates increase with their intensity classes, and their radial distributions show single-peak characteristic gradually, and furthermore, the characteristics of rain rates occurrence and contribution proportion change from dual-peak to single-peak distribution, with the peak rain rate at about 5.0 mm/h; (2) Stratiform rain dominate the rain type in the analysis zone, while convective rain mainly occurred in the eye-wall region; (3) The values of mean rain rate in each quadrant along TCs motion are close to each other, relatively, the value in the right-rear quadrant is the smallest one. 相似文献
16.
西北太平洋热带气旋快速增强阶段的风速分布特征 总被引:1,自引:2,他引:1
利用联合台风预警中心的最优路径(best-track)资料,筛选出西北太平洋地区快速增强和非快速增强两类热带气旋样本。利用美国国家海洋与大气管理局(NOAA)的多平台热带气旋表面风分析资料,对比分析了两类样本的风速和涡度的分布特征。结果显示,快速增强的热带气旋样本通常结构更紧凑,最大风速较大,最大风速半径较小,台风内区的风速较大。在涡度上表现为快速增强热带气旋样本内区的涡度和涡度梯度较大。对两类样本进行t检验,结果显示两类样本内区的切向风差异明显,说明热带气旋的内区风速分布与其发展之间存在密切联系。其物理机制可能是:当存在较大的内区涡度梯度时,涡度隔离机制有利于对流单体向涡旋中心汇聚,此外较大的涡度意味着较大的惯性稳定度,有利于非绝热加热向热带气旋动能的转换,二者共同作用有利于热带气旋的快速发展。 相似文献
17.
The Effect of Intensity: Typhoon-Induced SST Cooling on Typhoon The Case of Typhoon Chanchu (2006) 总被引:4,自引:0,他引:4
In order to investigate air-sea interactions during the life cycle of typhoons and the quantificational effects of typhoon-induced SST cooling on typhoon intensity, a mesoscale coupled air-sea model is developed based on the non-hydrostatic mesoscale model MM5 and the regional ocean model POM, which is used to simulate the life cycle of Typhoon Chanchu (2006) from a tropical depression to a typhoon followed by a steady weakening. The results show that improved intensity prediction is achieved after considering typhoon-induced SST cooling; the trend of the typhoon intensity change simulated by the coupled model is consistent with observations. The weakening stage of Typhoon Chanchu from 1200 UTC 15 May to 1800 UTC 16 May can be well reproduced, and it is the typhoon-induced SST cooling that makes Chanchu weaken during this period. Analysis reveals that the typhoon-induced SST cooling reduces the sensible and latent heat fluxes from the ocean to the typhoon's vortex, especially in the inner-core region. In this study, the average total heat flux in the inner-core region of the typhoon decrease by 57.2%, whereas typhoon intensity weakens by 46%. It is shown that incorporation of the typhoon-induced cooling, with an average value of 2.17℃, causes a 46-hPa weakening of the typhoon, which is about 20 hPa per 1℃ change in SST. 相似文献
18.
Lightning activity and its relationship with typhoon intensity and vertical wind shear for Super Typhoon Haiyan (1330) 
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下载免费PDF全文 Super Typhoon Haiyan (1330), which occurred in 2013, is the most powerful typhoon during landfall in the meteorological record. In this study, the temporal and spatial distributions of lightning activity of Haiyan were analyzed by using the lightning data from the World Wide Lightning Location Network, typhoon intensity and position data from the China Meteorological Administration, and horizontal wind data from the ECMWF. Three distinct regions were identified in the spatial distribution of daily average lightning density, with the maxima in the inner core and the minima in the inner rainband. The lightning density in the intensifying stage of Haiyan was greater than that in its weakening stage. During the time when the typhoon intensity measured with maximum sustained wind speed was between 32.7 and 41.4 ms?1, the storm had the largest lightning density in the inner core, compared with other intensity stages. In contrast to earlier typhoon studies, the eyewall lightning burst out three times. The first two eyewall lightning outbreaks occurred during the period of rapid intensification and before the maximum intensity of the storm, suggesting that the eyewall lightning activity could be used to identify the change in tropical cyclone intensity. The flashes frequently occurred in the inner core, and in the outer rainbands with the black body temperature below 220 K. Combined with the ECMWF wind data, the influences of vertical wind shear (VWS) on the azimuthal distribution of flashes were also analyzed, showing that strong VWS produced downshear left asymmetry of lightning activity in the inner core and downshear right asymmetry in the rainbands. 相似文献
19.
Super Typhoon Haiyan(1330), which occurred in 2013, is the most powerful typhoon during landfall in the meteorological record. In this study, the temporal and spatial distributions of lightning activity of Haiyan were analyzed by using the lightning data from the World Wide Lightning Location Network,typhoon intensity and position data from the China Meteorological Administration, and horizontal wind data from the ECMWF. Three distinct regions were identified in the spatial distribution of daily average lightning density, with the maxima in the inner core and the minima in the inner rainband. The lightning density in the intensifying stage of Haiyan was greater than that in its weakening stage. During the time when the typhoon intensity measured with maximum sustained wind speed was between 32.7 and 41.4 m s-1, the storm had the largest lightning density in the inner core, compared with other intensity stages.In contrast to earlier typhoon studies, the eyewall lightning burst out three times. The first two eyewall lightning outbreaks occurred during the period of rapid intensification and before the maximum intensity of the storm, suggesting that the eyewall lightning activity could be used to identify the change in tropical cyclone intensity. The flashes frequently occurred in the inner core, and in the outer rainbands with the black body temperature below 220 K. Combined with the ECMWF wind data, the influences of vertical wind shear(VWS) on the azimuthal distribution of flashes were also analyzed, showing that strong VWS produced downshear left asymmetry of lightning activity in the inner core and downshear right asymmetry in the rainbands. 相似文献