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1.
C. V. Singh 《Meteorology and Atmospheric Physics》2001,78(3-4):205-214
Summary
The paper deals with the variability of summer-monsoon rainfall during normal, flood and drought years over India. During
flood years the monsoon rainfall increases mostly all over parts of the country and large area less than 100 cm isohytel covers
Orissa and adjoining Madhya Pradesh. During drought years the rainfall amount decreases over the entire country and isohytel
of 100 cm shrinks to almost a point. The variability of monsoon rainfall from flood to normal to drought years depends upon
the number of depression/low-pressure area which form over the North Bay and move inland. To understand the intraseasonal
and interannual variability of the monsoon rainfall, daily and seasonal anomalies has been performed by using the Empirical
Orthogonal Function analysis. Further Empirical Orthogonal Function (EOF) analysis is carried out on these data to find out
the nature of rainfall distribution in different monsoon categories namely normal, flood and drought years. This technique
thus serves to identify spatial and temporal patterns characteristics of possible physical significance.
Received July 25, 2000/Revised September 26, 2000 相似文献
2.
Daily modes of South Asian summer monsoon variability in the NCEP climate forecast system 总被引:1,自引:0,他引:1
The leading modes of daily variability of the Indian summer monsoon in the climate forecast system (CFS), a coupled general circulation model, of the National Centers for Environmental Predictions (NCEP) are examined. The space?Ctime structures of the daily modes are obtained by applying multi-channel singular spectrum analysis (MSSA) on the daily anomalies of rainfall. Relations of the daily modes to intraseasonal and interannual variability of the monsoon are investigated. The CFS has three intraseasonal oscillations with periods around 106, 57 and 30?days with a combined variance of 7%. The 106-day mode has spatial structure and propagation features similar to the northeastward propagating 45-day mode in the observations except for its longer period. The 57-day mode, despite being in the same time scale as of the observations has poor eastward propagation. The 30-day mode is northwestward propagating and is similar to its observational counterpart. The 106-day mode is specific to the model and should not be mistaken for a new scale of variability in observations. The dominant interannual signal is related to El Ni?o-Southern Oscillation (ENSO), and, unlike in the observations, has maximum variance in the eastern equatorial Indian Ocean. Although the Indian Ocean Dipole (IOD) mode was not obtained as a separate mode in the rainfall, the ENSO signal has good correlations with the dipole variability, which, therefore, indicates the dominance of ENSO in the model. The interannual variability is largely determined by the ENSO signal over the regions where it has maximum variance. The interannual variability of the intraseasonal oscillations is smaller in comparison. 相似文献
3.
Peculiar Temporal Structure of the South China Sea Summer Monsoon 总被引:11,自引:0,他引:11
Bin Wang Corresponding author's address: Dr. Bin Wang Department of Meteorology University of Hawaii Correa Road Honolulu Hawaii USA. bwang@soest.hawaii.edu. Renguang Wu Department of Meteorology University of Hawaii U 《大气科学进展》1997,(2)
PeculiarTemporalStructureoftheSouthChinaSeaSummerMonsoonBinWang①andRenguangWuDepartmentofMeteorology,UniversityofHawai,USARec... 相似文献
4.
Subodh K. Saha Subhadeep Halder K. Krishna Kumar B. N. Goswami 《Climate Dynamics》2011,36(11-12):2077-2089
It is proposed that, land?Catmosphere interaction around the time of monsoon onset could modulate the first episode of climatological intraseasonal oscillation (CISO) and may generate significant ??internal?? interannual variation in the Indian summer monsoon rainfall. The regional climate model RegCM3 is used over Indian monsoon domain for 27?years of control simulation. In order to prove the hypothesis, another two sets of experiment are performed using two different boundary conditions (El Ni?o year and non-ENSO year). In each of these experiments, a single year of boundary conditions are used repeatedly year after year to generate ??internal?? interannual monsoon variability. Simulation of monsoon climate in the control model run is found to be in reasonably good agreement with observation. However, large rainfall bias is seen over Arabian Sea and Bay of Bengal. The interannual monsoon rainfall variability are of the same order in two experiments, which suggest that the external influences may not be important on the generation of ??internal?? monsoon rainfall variability. It is shown that, a dry (wet) pre-onset land-surface condition increases (decreases) rainfall in June which in turn leads to an anomalous increase (decrease) in seasonal (JJAS) rainfall. The phase and amplitude of CISO are modulated during May?CJune and beyond that the modulation of CISO is quite negligible. Though the pre-onset rainfall is unpredictable, significant modulation of the post-onset monsoon rainfall by it can be exploited to improve predictive skill within the monsoon season. 相似文献
5.
Beijing located at the junction of four major components of the Asian-Australia monsoon system (the Indian, the western North Pacific, the East Asian subtropical, and the Indonesian-Australian monsoons), the monsoon cli-mate over the South China Sea (SCS) exhibits some unique features. Evidences are presented in this paper to reveal and document the following distinctive features in the temporal structure of the SCS summer monsoon:(1) pronounced monsoon singularities in the lower tropospheric monsoon flows which include the pre-onset and withdrawal easterly surges and the southwesterly monsoon bursts at Julian pentad 34-35 (June 15-24) and pentad 46-47 (August 14-23);(2) four prominent subseasonal cycles (alternative occurrences of climatological active and break monsoons);(3) considerably larger year-to-year variations in convective activity on intraseasonal time scale compared to those over the Bay of Bengal and the Philippine Sea;(4) the redness of the climatological mean spectrum of precipitation / deep convection on synoptic to intraseasona] time scales in the central SCS;(5) a remarkable asymmetry in the seasonal transitions between summer and winter monsoons and an extremely abrupt mid-May transition (the outburst of monsoon rain and the sudden switch in tie lower troposphere winds from an easterly to a westerly regime);(6) the bi-modal interannual variation of summer monsoon onset (normal and delayed modes).In addition, the monsoon rainfall displays enormous east-west gradient over the central SCS. Possible causes for these features are discussed. A number of specific science questions concerning some of the peculiar features are raised for the forthcoming SCS monsoon experiment to address 相似文献
6.
本文基于1979~2015年中国台站观测的格点化高分辨率降水和NCEP II大气再分析逐日资料,探讨了亚洲季风区夏季30~60天大气季节内振荡(ISO)与长江中下游地区持续性降水异常的关系,重点揭示了南亚和东亚子季风区ISO的相互作用及二者协同引起长江中下游持续性极端降水的物理机制。合成分析表明,南亚和东亚ISO是通过高层辐散环流发生相互作用。在ISO位相1~3(5~7),异常活跃(抑制)对流从赤道印度洋北传至孟加拉湾—印度次大陆区域,其伴随的高层异常辐散(辐合)环流通过补偿效应,引起南海—热带西北太平洋的异常高层辐合(辐散),加强了局地的异常下沉(上升)运动,有利于南海—西北太平洋的异常抑制(活跃)对流发展并维持。南海—西北太平洋的异常抑制(活跃)对流伴随着显著的斜压散度,并进一步激发出一个连接南海和长江中下游的经向垂直环流圈,引起长江中下游强烈的异常上升(下沉)运动和低层水汽辐合(辐散),使得降水持续性偏多(少),极端降水的发生概率持续地偏高(低),有利于(不利于)形成持续性极端降水事件。研究还表明,亚洲季风区ISO的强度存在显著的年际变化,并对长江中下游持续性极端降水的发生频次和持续时间具有调制作用。在ISO偏强(弱)年,长江中下游持续性极端降水的发生频次较高(低),且持续时间较长(短)。 相似文献
7.
8.
The Asian summer monsoon: an intercomparison of CMIP5 vs. CMIP3 simulations of the late 20th century 总被引:4,自引:0,他引:4
K. R. Sperber H. Annamalai I.-S. Kang A. Kitoh A. Moise A. Turner B. Wang T. Zhou 《Climate Dynamics》2013,41(9-10):2711-2744
The boreal summer Asian monsoon has been evaluated in 25 Coupled Model Intercomparison Project-5 (CMIP5) and 22 CMIP3 GCM simulations of the late twentieth Century. Diagnostics and skill metrics have been calculated to assess the time-mean, climatological annual cycle, interannual variability, and intraseasonal variability. Progress has been made in modeling these aspects of the monsoon, though there is no single model that best represents all of these aspects of the monsoon. The CMIP5 multi-model mean (MMM) is more skillful than the CMIP3 MMM for all diagnostics in terms of the skill of simulating pattern correlations with respect to observations. Additionally, for rainfall/convection the MMM outperforms the individual models for the time mean, the interannual variability of the East Asian monsoon, and intraseasonal variability. The pattern correlation of the time (pentad) of monsoon peak and withdrawal is better simulated than that of monsoon onset. The onset of the monsoon over India is typically too late in the models. The extension of the monsoon over eastern China, Korea, and Japan is underestimated, while it is overestimated over the subtropical western/central Pacific Ocean. The anti-correlation between anomalies of all-India rainfall and Niño3.4 sea surface temperature is overly strong in CMIP3 and typically too weak in CMIP5. For both the ENSO-monsoon teleconnection and the East Asian zonal wind-rainfall teleconnection, the MMM interannual rainfall anomalies are weak compared to observations. Though simulation of intraseasonal variability remains problematic, several models show improved skill at representing the northward propagation of convection and the development of the tilted band of convection that extends from India to the equatorial west Pacific. The MMM also well represents the space–time evolution of intraseasonal outgoing longwave radiation anomalies. Caution is necessary when using GPCP and CMAP rainfall to validate (1) the time-mean rainfall, as there are systematic differences over ocean and land between these two data sets, and (2) the timing of monsoon withdrawal over India, where the smooth southward progression seen in India Meteorological Department data is better realized in CMAP data compared to GPCP data. 相似文献
9.
江淮夏季降水季节内振荡和海气背景场的关系 总被引:6,自引:1,他引:5
本文利用1954~2005年中国740站逐日降水资料和NCEP/NCAR再分析资料,分析江淮夏季降水季节内振荡(ISO)的年际变化,并讨论了异常年的海气背景特征.诊断分析的结果表明:(1)当江淮夏季降水ISO活跃时,江淮流域、孟加拉湾、南海及其以东海域和日本南部海区上空大气都表现出显著的季节内振荡特征.在江淮夏季降水不... 相似文献
10.
The space–time structure of the daily atmospheric variability in the South American monsoon system has been studied using multichannel singular spectrum analysis of daily outgoing longwave radiation. The three leading eigenmodes are found to have low-frequency variability while four other modes form higher frequency oscillations. The first mode has the same time variability as that of El Nino-Southern Oscillation (ENSO) and exhibits strong correlation with the Pacific sea surface temperature (SST). The second mode varies on a decadal time scale with significant correlation with the Atlantic SST suggesting an association with the Atlantic multidecadal oscillation (AMO). The third mode also has decadal variability but shows an association with the SST of the Pacific decadal oscillation (PDO). The fourth and fifth modes describe an oscillation that has a period of about 165 days and is associated with the North Atlantic oscillation (NAO). The sixth and seventh modes describe an intraseasonal oscillation with a period of 52 days which shows strong relation with the Madden-Julian oscillation. There exists an important difference in the variability of convection between Amazon River Basin (ARB) and central-east South America (CESA). Both regions have similar variations due to ENSO though with higher magnitude in ARB. The AMO-related mode has almost identical variations in the two regions, whereas the PDO-related mode has opposite variations. The interseasonal NAO-related mode also has variations of opposite sign with comparable magnitudes in the two regions. The intraseasonal variability over the CESA is robust while it is very weak over the ARB region. The relative contributions from the low-frequency modes mainly determine the interannual variability of the seasonal mean monsoon although the interseasonal oscillation may contribute in a subtle way during certain years. The intraseasonal variability does not seem to influence the interannual variability in either region. 相似文献
11.
THE RELATIONSHIP BETWEEN INDIAN MONSOON SYSTEMS IN SUMMER AND THE CONTINUOUS HEAVY RAIN OVER THE UPPER REACHES OF CHANGJIANG RIVER 
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下载免费PDF全文 In this paper,the continuous heavy rains over the upper reaches of Changjiang River during June—Augustare analyzed.They are closely related to the Indian monsoon systems.The average synoptic situationsand the average distributions of some meteorological elements over the Bay of Bengal during the period ofheavy rains are presented.The correlation coefficients between meteorological elements and rainfall arecalculated and the main monsoon influence systems and the key regions are denoted.Results can be usedas a reference in the 24 h forecast of rainfall. 相似文献
12.
This paper reviews briefly advances in recent research on monsoon by Chinese scholars, including primarily: (1) the establishment of various monsoon indices. In particular, the standardized dynamic seasonal variability index of the monsoon can delimit the geographical distribution of global monsoon systems and determine quantitatively the date of abrupt change in circulation. (2) The provision of three driving forces for the generation of monsoon. (3) The revelation of the heating-pump action of the Tibetan Plateau, which strengthens southerlies in the southern and southeastern periphery of the Plateau and results in a strong rainfall center from the northern Bay of Bengal (BOB) to the Plateau itself. (4) Clarification of the initial onset of the Asian Summer Monsoon (ASM) in the BOB east of 90°E, Indochina Peninsula (ICP) and the South China Sea, of which the rapid northward progression of tropical convection in the Sumatra and the rapid westward movement of the South Asia High to the Indochina Peninsula are the earliest signs. (5) The provision of an integrated mechanism for the onset of the East Asian Summer Monsoon (EASM), which emphasizes the integrated impact of sensible heat over Indian Peninsula, the warm advection of the Tibetan Plateau and the sensible heat and latent heat over the Indochina Peninsula on the one hand, and the seasonal phase-lock effect of the northward propagation of low frequency oscillation on the other. (6) The revelation of the "planetary-scale moisture transport large-value band" from the Southern Hemisphere through to the Asian monsoon region and into the North Pacific, which is converged by several large-scale moisture transport belts in the Asian-Australian monsoon regions and whose variation influences directly the temporal and spatial distribution of summer rainfall in China. (7) Presenting the features of the seasonal advance of the EASM, the propagation of intraseasonal oscillation, and their relationship with rainfall in Ch 相似文献
13.
Monsoon precipitation in the AMIP runs 总被引:5,自引:1,他引:4
We present an analysis of the seasonal precipitation associated with the African, Indian and the Australian-Indonesian monsoon
and the interannual variation of the Indian monsoon simulated by 30 atmospheric general circulation models undertaken as a
special diagnostic subproject of the Atmospheric Model Intercomparison Project (AMIP). The seasonal migration of the major
rainbelt observed over the African region, is reasonably well simulated by almost all the models. The Asia West Pacific region
is more complex because of the presence of warm oceans equatorward of heated continents. Whereas some models simulate the
observed seasonal migration of the primary rainbelt, in several others this rainbelt remains over the equatorial oceans in
all seasons. Thus, the models fall into two distinct classes on the basis of the seasonal variation of the major rainbelt
over the Asia West Pacific sector, the first (class I) are models with a realistic simulation of the seasonal migration and
the major rainbelt over the continent in the boreal summer; and the second (class II) are models with a smaller amplitude
of seasonal migration than observed. The mean rainfall pattern over the Indian region for July-August (the peak monsoon months)
is even more complex because, in addition to the primary rainbelt over the Indian monsoon zone (the monsoon rainbelt) and
the secondary one over the equatorial Indian ocean, another zone with significant rainfall occurs over the foothills of Himalayas
just north of the monsoon zone. Eleven models simulate the monsoon rainbelt reasonably realistically. Of these, in the simulations
of five belonging to class I, the monsoon rainbelt over India in the summer is a manifestation of the seasonal migration of
the planetary scale system. However in those belonging to class II it is associated with a more localised system. In several
models, the oceanic rainbelt dominates the continental one. On the whole, the skill in simulation of excess/deficit summer
monsoon rainfall over the Indian region is found to be much larger for models of class I than II, particularly for the ENSO
associated seasons. Thus, the classification based on seasonal mean patterns is found to be useful for interpreting the simulation
of interannual variation. The mean rainfall pattern of models of class I is closer to the observed and has a higher pattern
correlation coefficient than that of class II. This supports Sperber and Palmer’s (1996) result of the association of better
simulation of interannual variability with better simulation of the mean rainfall pattern. The hypothesis, that the skill
of simulation of the interannual variation of the all-India monsoon rainfall in association with ENSO depends upon the skill
of simulation of the seasonal variation over the Asia West Pacific sector, is supported by a case in which we have two versions
of the model where NCEP1 is in class II and NCEP2 is in class I. The simulation of the interannual variation of the local
response over the central Pacific as well as the all-India monsoon rainfall are good for NCEP2 and poor for NCEP1. Our results
suggest that when the model climatology is reasonably close to observations, to achieve a realistic simulation of the interannual
variation of all-India monsoon rainfall associated with ENSO, the focus should be on improvement of the simulation of the
seasonal variation over the Asia West Pacific sector rather than further improvement of the simulation of the mean rainfall
pattern over the Indian region.
Received: 2 June 1997 / Accepted: 8 January 1998 相似文献
14.
东亚夏季风降水中30—60天低频振荡 总被引:16,自引:1,他引:16
通过对东亚夏季风区域30年候降水量的分析研究可以看到,降水中30—60天低频振荡的季节变化与总的季风降水的季节变化具有明显的锁相关系,对季风雨带位置的出现起着重要的调制作用;降水低频振荡的年际变化对梅雨的年际变化也起着重要的调制作用;降水低频振荡呈现明显的由南向北的经向传播。 相似文献
15.
The precipitation over eastern China during January–March 2010 exhibited a marked intraseasonal oscillation (ISO) and a dominant period of 10-60 days. There were two active intraseasonal rainfall periods. The physical mechanisms responsible for the onset of the two rainfall events were investigated using ERA-interim data. In the first ISO event, anomalous ascending motion was triggered by vertically integrated (1000–300 hPa) warm temperature advection. In addition to southerly anomalies on the intraseasonal (10–60-day) timescale, synoptic-scale southeasterly winds helped advect warm air from the South China Sea and western Pacific into the rainfall region. In the second ISO event, anomalous convection was triggered by a convectively unstable stratification, which was caused primarily by anomalous moisture advection in the lower troposphere (1000–850 hPa) from the Bay of Bengal and the Indo-China Peninsula. Both the intraseasonal and the synoptic winds contributed to the anomalous moisture advection. Therefore, the winter intraseasonal rainfall events over East Asia in winter could be affected not only by intraseasonal activities but also by higher frequency disturbances. 相似文献
16.
The strength of the East Asian summer monsoon and associated rainfall has been linked to the western North Pacific subtropical high (WNPSH) and the lower-tropospheric low pressure system over continental East Asia (EA). In contrast to the large number of studies devoted to the WNPSH, little is known about the variability of the East Asian continental low. The present study delineates the East Asian continental low using 850-hPa geopotential height. Since the low is centered over northern EA (NEA), we refer to it as the NEA low (NEAL). We show that the intensity of the NEAL has large interannual variation, with a dominant period of 2–4 years. An enhanced NEAL exhibits a barotropic structure throughout the whole troposphere, which accelerates the summer-mean upper-tropospheric westerly jet and lower-tropospheric monsoon westerly to its south. We carefully identify the anomalous NEAL-induced rainfall anomalies by removal of the tropical heating effects. An enhanced NEAL not only increases rainfall locally in northern Northeast China, but also shifts the East Asian subtropical front northward, causing above-normal rainfall extending eastward from the Huai River valley across central-northern Japan and below-normal rainfall in South China. The northward shift of the East Asian subtropical front is attributed to the following processes without change in the WNPSH: an enhanced NEAL increases meridional pressure gradients and the monsoon westerly along the East Asian subtropical front, which in turn induces a cyclonic shear vorticity anomaly to its northern side. The associated Ekman pumping induces moisture flux convergence that shifts the East Asian subtropical front northward. In addition, the frequent occurrence of synoptic cut-off lows is found to be associated with an enhanced NEAL. Wave activity analysis indicates that the interannual intensity change of the NEAL is significantly associated with the extratropical Polar Eurasian teleconnection, in addition to the forcing of the tropical WNP heating. 相似文献
17.
Intraseasonal SST-precipitation relationship and its spatial variability over the tropical summer monsoon region 总被引:1,自引:1,他引:0
Mathew Roxy Youichi Tanimoto B. Preethi Pascal Terray R. Krishnan 《Climate Dynamics》2013,41(1):45-61
The SST-precipitation relationship in the intraseasonal variability (ISV) over the Asian monsoon region is examined using recent high quality satellite data and simulations from a state of the art coupled model, the climate forecast system version 2 (CFSv2). CFSv2 demonstrates high skill in reproducing the spatial distribution of the observed climatological mean summer monsoon precipitation along with its interannual variability, a task which has been a conundrum for many recent climate coupled models. The model also exhibits reasonable skill in simulating coherent northward propagating monsoon intraseasonal anomalies including SST and precipitation, which are generally consistent with observed ISV characteristics. Results from the observations and the model establish the existence of spatial variability in the atmospheric convective response to SST anomalies, over the Asian monsoon domain on intraseasonal timescales. The response is fast over the Arabian Sea, where precipitation lags SST by ~5 days; whereas it is slow over the Bay of Bengal and South China Sea, with a lag of ~12 days. The intraseasonal SST anomalies result in a similar atmospheric response across the basins, which consists of a destabilization of the bottom of the atmospheric column, as observed from the equivalent potential temperature anomalies near the surface. However, the presence of a relatively strong surface convergence over the Arabian Sea, due to the presence of a strong zonal gradient in SST, which accelerates the upward motion of the moist air, results in a relatively faster response in terms of the local precipitation anomalies over the Arabian Sea than over the Bay of Bengal and South China Sea. With respect to the observations, the ocean–atmosphere coupling is well simulated in the model, though with an overestimation of the intraseasonal SST anomalies, leading to an exaggerated SST-precipitation relationship. A detailed examination points to a systematic bias in the thickness of the mixed layer of the ocean model, which needs to be rectified. A too shallow (deep) mixed layer enhances (suppress) the amplitude of the intraseasonal SST anomalies, thereby amplifying (lessening) the ISV and the active-break phases of the monsoon in the model. 相似文献
18.
The Indian subcontinent witnessed a severe monsoon drought in 2002, which largely resulted from a major rainfall deficiency
in the month of July. While moderate El Nino conditions prevailed during this period, the atmospheric convective activity
was anomalously enhanced over northwest and north-central Pacific in the 10–20°N latitude belt; and heavy rainfall occurred
over this region in association with a series of northward moving tropical cyclones. Similar out-of-phase rainfall variations
over the Indian region and the northwest (NW) Pacific have been observed during other instances of El Nino/Southern Oscillation
(ENSO). The dynamical linkage corresponding to this out-of-phase rainfall variability is explored in this study by conducting
a set of numerical experiments using an atmospheric general circulation model. The results from the model simulations lend
credence to the role of the tropical Pacific sea surface temperature anomalies in forcing the out-of-phase precipitation variability
over the NW Pacific and the Indian monsoon region. It is seen that the ENSO induced circulation response reveals an anomalous
pattern comprising of alternating highs and lows which extend meridionally from the equatorial region into the sub-tropic
and mid-latitude regions of west-central Pacific. This meridional pattern is associated with an anomalous cyclonic circulation
over NW Pacific, which is found to favor enhanced tropical cyclonic activity and intensified convection over the region. In
turn, the intensified convection over NW Pacific induces subsidence and rainfall deficiency over the Indian landmass through
anomalous east-west circulation in the 10–20°N latitude belt. Based on the present findings, it is suggested that the convective
activity over NW Pacific is an important component in mediating the ENSO-monsoon teleconnection dynamics. 相似文献
19.
Intraseasonal oscillation of the southwest monsoon over Sri Lanka and evaluation of its subseasonal forecast skill 下载免费PDF全文
下载免费PDF全文 斯里兰卡的雨季发生于5-9月间,主要受西南季风的控制.本文发现该地区的西南季风降水存在很强的次季节变率,主导周期为10-35天.降水的季节内变化与西传的异常气旋有关.进一步,利用S2S比较计划中欧洲中心的数值预报模式(ECMWF)提供的回报试验数据,评估了当今动力模式对斯里兰卡西南季风次季节变化的预报技巧.结果显示,对季风指数的预测技巧超过30天,而对降水指数的预测技巧大约两周,且模式的预报技巧具有明显的年际差异.分析表明,能否正确模拟出大尺度环流对热带对流的响应是影响斯里兰卡降水预测的重要因子. 相似文献
20.
C. V. Singh 《Meteorology and Atmospheric Physics》2004,85(4):227-234
Summary The present study involves the use of Empirical Orthogonal Function (EOF) analysis/Principal Component Analysis (PCA) to compare the dominant rainfall patterns from normal rainfall records over India, coupled with the major modes of the Outgoing Long-wave Radiation (OLR) data for the period (1979–1988) during the monsoon period (June–September). To understand the intraseasonal and interannual variability of the monsoon rainfall, daily and seasonal anomalies have been obtained by using the (EOF) analysis. Importantly, pattern characteristics of seasonal monsoon rainfall covering 68 stations in India are highlighted.The purpose is to ascertain the nature of rainfall distribution over the Indian continent. Based on this, the percentage of variance for both the rainfall and OLR data is examined. OLR has a higher spatial coherence than rainfall. The first principal component of rainfall data shows high positive values, which are concentrated over northeast as well as southeast, whereas for the OLR, the area of large positive values is concentrated over northwest and lower value over south India apart from the Indian ocean. The first five principal components explain 92.20% of the total variance for the rainfall and 99.50% of the total variance for the outgoing long-wave radiation. The relationship between monsoon rainfall and Southern Oscillations has also been examined and for the Southern Oscillations, it is 0.69 for the monsoon season. The El-Niño events mostly occurred during Southern Oscillations, i.e. Walker circulation. It has been found that the average number of low pressure system/low pressure system days play an important role during active (flood) or inactive (drought) monsoon year, but low pressure system days play more important role in comparison to low pressure systems and their ratio are (16:51) and (13:25) respectively. Significantly, the analysis identifies the spatial and temporal pattern characteristics of possible physical significance. 相似文献