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1.
Prediction skill of the Madden and Julian Oscillation in dynamical extended range forecasts 总被引:1,自引:0,他引:1
The Madden and Julian Oscillation (MJO) is the most prominent mode of intraseasonal variations in the tropical region. It
plays an important role in climate variability and has a significant influence on medium-to-extended ranges weather forecasting
in the tropics. This study examines the forecast skill of the oscillation in a set of recent dynamical extended range forecasts
(DERF) experiments performed by the National Centers for Environmental Prediction (NCEP). The present DERF experiments were
done with the reanalysis version of the medium range forecast (MRF) model and include 50-day forecasts, initialized once-a-day
(0Z) with reanalyses fields, for the period between 1 January, 1985, and 31 December, 1989. The MRF model shows large mean
errors in representing intraseasonal variations of the large-scale circulation, especially over the equatorial eastern Pacific
Ocean. A diagnostic analysis has considered the different phases of the MJO and the associated forecast skill of the MRF model.
Anomaly correlations on the order of 0.3 to 0.4 indicate that skillful forecasts extend out to 5 to 7 days lead-time. Furthermore,
the results show a slight increase in the forecast skill for periods when convective anomalies associated with the MJO are
intense. By removing the mean errors, the analysis shows systematic errors in the representation of the MJO with weaker than
observed upper level zonal circulations. The examination of the climate run of the MRF model shows the existence of an intraseasonal
oscillation, although less intense (50–70%) and with faster (nearly twice as fast) eastward propagation than the observed
MJO. The results indicate that the MRF model likely has difficulty maintaining the MJO, which impacts its forecast. A discussion
of future work to improve the representation of the MJO in dynamical models and assess its prediction is presented.
Received: 28 December 1998 / Accepted: 27 September 1999 相似文献
2.
MJO prediction in the NCEP Climate Forecast System version 2 总被引:3,自引:0,他引:3
Wanqiu Wang Meng-Pai Hung Scott J. Weaver Arun Kumar Xiouhua Fu 《Climate Dynamics》2014,42(9-10):2509-2520
The Madden–Julian Oscillation (MJO) is the primary mode of tropical intraseasonal climate variability and has significant modulation of global climate variations and attendant societal impacts. Advancing prediction of the MJO using state of the art observational data and modeling systems is thus a necessary goal for improving global intraseasonal climate prediction. MJO prediction is assessed in the NOAA Climate Forecast System version 2 (CFSv2) based on its hindcasts initialized daily for 1999–2010. The analysis focuses on MJO indices taken as the principal components of the two leading EOFs of combined 15°S–15°N average of 200-hPa zonal wind, 850-hPa zonal wind and outgoing longwave radiation at the top of the atmosphere. The CFSv2 has useful MJO prediction skill out to 20 days at which the bivariate anomaly correlation coefficient (ACC) drops to 0.5 and root-mean-square error (RMSE) increases to the level of the prediction with climatology. The prediction skill also shows a seasonal variation with the lowest ACC during the boreal summer and highest ACC during boreal winter. The prediction skills are evaluated according to the target as well as initial phases. Within the lead time of 10 days the ACC is generally greater than 0.8 and RMSE is less than 1 for all initial and target phases. At longer lead time, the model shows lower skills for predicting enhanced convection over the Maritime Continent and from the eastern Pacific to western Indian Ocean. The prediction skills are relatively higher for target phases when enhanced convection is in the central Indian Ocean and the central Pacific. While the MJO prediction skills are improved in CFSv2 compared to its previous version, systematic errors still exist in the CFSv2 in the maintenance and propagation of the MJO including (1) the MJO amplitude in the CFSv2 drops dramatically at the beginning of the prediction and remains weaker than the observed during the target period and (2) the propagation in the CFSv2 is too slow. Reducing these errors will be necessary for further improvement of the MJO prediction. 相似文献
3.
Sensitivity of MJO simulations to diabatic heating profiles 总被引:2,自引:0,他引:2
The difficulty for global atmospheric models to reproduce the Madden–Julian oscillation (MJO) is a long-lasting problem. In an attempt to understand this difficulty, simple numerical experiments are conducted using a global climate model. This model, in its full paramterization package (control run), is capable of producing the gross features of the MJO, namely, its planetary-scale, intraseasonal, eastward slow propagation. When latent heating profiles in the model are artificially modified, the characteristics of the simulated MJO changed drastically. Intraseasonal perturbations are dominated by stationary component over the Indian and western Pacific Oceans when heating profiles are top heavy (maximum in the upper troposphere). In contrast, when diabatic heating is bottom heavy (maximum in the lower troposphere), planetary-scale, intraseasonal, eastward propagating perturbations are reproduced with a phase speed similar to that of the MJO. The difference appears to come from surface and low-level moisture convergence, which is much stronger and more coherent in space when the heating profile is bottom heavy than when it is top heavy. These sensitivity experiments, along with other theoretical, numerical, and observational results, have led to a hypothesis that the difficulty for global models to produce the MJO partially is rooted in a lack of sufficient diabatic heating in the lower troposphere, presumably from shallow convection. 相似文献
4.
Even though multi-model prediction systems may have better skill in predicting the interannual variability (IAV) of Indian
summer monsoon (ISM), the overall performance of the system is limited by the skill of individual models (single model ensembles).
The DEMETER project aimed at seasonal-to-interannual prediction is not an exception to this case. The reasons for the poor
skill of the DEMETER individual models in predicting the IAV of monsoon is examined in the context of the influence of external
and internal components and the interaction between intraseasonal variability (ISV) and IAV. Recently it has been shown that
the ISV influences the IAV through very long breaks (VLBs; breaks with duration of more than 10 days) by generating droughts.
Further, all VLBs are associated with an eastward propagating Madden–Julian Oscillation (MJO) in the equatorial region, facilitated
by air–sea interaction on intraseasonal timescales. This VLB-drought–MJO relationship is analyzed here in detail in the DEMETER
models. Analyses indicate that the VLB-drought relationship is poorly captured by almost all the models. VLBs in observations
are generated through air–sea interaction on intraseasonal time scale and the models’ inability to simulate VLB-drought relationship
is shown to be linked to the models’ inability to represent the air–sea interaction on intraseasonal time scale. Identification
of this particular deficiency of the models provides a direction for improvement of the model for monsoon prediction. 相似文献
5.
Real-time multivariate indices for the boreal summer intraseasonal oscillation over the Asian summer monsoon region 总被引:3,自引:0,他引:3
June-Yi Lee Bin Wang Matthew C. Wheeler Xiouhua Fu Duane E. Waliser In-Sik Kang 《Climate Dynamics》2013,40(1-2):493-509
The boreal summer intraseasonal oscillation (BSISO) of the Asian summer monsoon (ASM) is one of the most prominent sources of short-term climate variability in the global monsoon system. Compared with the related Madden-Julian Oscillation (MJO) it is more complex in nature, with prominent northward propagation and variability extending much further from the equator. In order to facilitate detection, monitoring and prediction of the BSISO we suggest two real-time indices: BSISO1 and BSISO2, based on multivariate empirical orthogonal function (MV-EOF) analysis of daily anomalies of outgoing longwave radiation (OLR) and zonal wind at 850 hPa (U850) in the region 10°S–40°N, 40°–160°E, for the extended boreal summer (May–October) season over the 30-year period 1981–2010. BSISO1 is defined by the first two principal components (PCs) of the MV-EOF analysis, which together represent the canonical northward propagating variability that often occurs in conjunction with the eastward MJO with quasi-oscillating periods of 30–60 days. BSISO2 is defined by the third and fourth PCs, which together mainly capture the northward/northwestward propagating variability with periods of 10–30 days during primarily the pre-monsoon and monsoon-onset season. The BSISO1 circulation cells are more Rossby wave like with a northwest to southeast slope, whereas the circulation associated with BSISO2 is more elongated and front-like with a southwest to northeast slope. BSISO2 is shown to modulate the timing of the onset of Indian and South China Sea monsoons. Together, the two BSISO indices are capable of describing a large fraction of the total intraseasonal variability in the ASM region, and better represent the northward and northwestward propagation than the real-time multivariate MJO (RMM) index of Wheeler and Hendon. 相似文献
6.
Sensitivity of the Simulated Tropical Intraseasonal Oscillation to Cumulus Parameterizations 
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下载免费PDF全文 The sensitivity of the simulated tropical intraseasonal oscillation or MJO (Madden and Julian oscillation) to different cumulus parameterizations is studied by using an atmospheric general circulation model (GCM)--SAMIL (Spectral Atmospheric Model of IAP LASG). Results show that performance of the model in simulating the MJO alters widely when using two different cumulus parameterization schemes-the moist convective adjustment scheme (MCA) and the Zhang-McFarlane (ZM) scheme. MJO simulated by the MCA scheme was found to be more realistic than that simulated by the ZM scheme. MJO produced by the ZM scheme is too weak and shows little propagation characteristics. Weak moisture convergence at low levels simulated by the ZM scheme is not enough to maintain the structure and the eastward propagation of the oscillation. These two cumulus schemes produced different vertical structures of the heating profile. The heating profile produced by the ZM scheme is nearly uniform with height and the heating is too weak compared to that produced by the MCA, which maybe contributes greatly to the failure of simulating a reasonable MJO. Comparing the simulated MJO by these two schemes indicate that the MJO simulated by the GCM is highly sensitive to cumulus parameterizations implanted in. The diabatic heating profile plays an important role in the performance of the GCM. Three sensitivity experiments with different heating profiles are designed in which modified heating profiles peak respectively in the upper troposphere (UH), middle troposphere (MH), and lower troposphere (LH). Both the LH run and the MH run produce eastward propagating signals on the intraseasonal timescale, while it is interesting that the intraseasonal timescale signals produced by the UH run propagate westward. It indicates that a realistic intraseasonal oscillation is more prone to be excited when the maximum heating concentrates in the middle-low levels, especially in the middle levels, while westward propagating disturbances 相似文献
7.
利用1979—2018年夏季逐日观测和再分析数据,对北半球夏季热带季节内振荡影响我国夏季降水的规律和预测方法开展了研究。首先,利用非传统滤波即异常相对倾向(Anomalous Relative Tendency,ART)方法获取了气象要素的次季节变化分量,并采用EOF分析方法提取了北半球夏季热带主要季节内振荡信号,结果表明向外长波辐射(Outgoing Longwave Radiation,OLR)异常相对倾向EOF前两个模态共同反映了北半球夏季起源于印度洋并向东和向北传播的、具有30~60 d周期的季节内振荡(Boreal Summer Intraseasonal Oscillation,BSISO)信号。回归分析表明,该季节内振荡信号能够导致当地及其北面地区低层风场和位势高度场异常,影响该地区及其北面地区的水汽辐合辐散,从而能引起我国尤其是我国南方地区季节内旱涝变化,并一定程度上反映了我国异常雨带的向北推进过程。而后,将提取的热带主要季节内振荡信号作为预测因子,将降水异常相对倾向作为先行预板对象,利用多元线性回归方法构建了我国夏季旬降水异常相对倾向的预报模型,将预报的旬降水异常相对倾向加上观测已知的降水近期背景距平,从而得到旬降水距平的预报结果。通过历史回报和交叉检验,评估了该模型对梅雨期我国江淮流域降水(包括2020年梅汛期异常降水)的次季节预测能力。 相似文献
8.
The daily outgoing longwave radiation (OLR) field in boreal summer shows significant power spectrum peaks on quasi-biweekly (10–20-day) and intraseasonal (20-80-day) timescales over the Indo-western Pacific warm pool, especially over the South China Sea and Bay of Bengal. The quasi-biweekly oscillation (QBWO) originates from off-equatorial western North Pacific, and is characterized by a northwest-southeast oriented wave train pattern, propagating northwestward. The intraseasonal oscillation (ISO), on the other hand, originates from the equatorial Indian Ocean and propagates eastward and northward. Why the equatorial mode possesses a 20–80-day periodicity while the off-equatorial mode favors a 10–20-day periodicity is investigated through idealized numerical experiments with a 2.5-layer atmospheric model. In the off-equatorial region, the model simulates, under a realistic three-dimensional summer mean flow, the most unstable mode that has a wave train pattern with a typical zonal wavelength of 6000 km and a period of 10–20 days, propagating northwestward. This is in contrast to the equatorial region, where a Madden-Julian oscillation (MJO) like mode with a planetary (wavenumber-1) zonal scale and a period ranging from 20 to 80 days is simulated. Sensitivity experiments with different initial conditions indicate that the QBWO is an intrinsic mode of the atmosphere in boreal summer in the off-equatorial Indo-western Pacific region under the summer mean state, while the MJO is the most unstable mode in the equatorial region. 相似文献
9.
The Madden-Julian oscillation (MJO) skeleton model is a low-order model for intraseasonal oscillations that, in an extended form, includes off-equatorial and antisymmetric components. Previous studies of this extended model have used an idealized background state and forcing terms. In the current study, observation-based estimates of these forcing terms and background state are used. Linear solutions to the extended model with this observation-based forcing consist of both equatorially-symmetric convective events and events with a meridional tilt reminiscent of composites of the boreal summer intraseasonal oscillation (BSISO) in observational studies. Solutions to a nonlinear stochastic form of the model exhibit realistic precipitation mean and variance and intraseasonal variability throughout much of the tropics. These solutions contain several types of events, including meridionally-tilted convective activity that moves both northward and eastward. Solutions to both forms of the model also indicate that this BSISO-like convective activity is coupled to activity over the eastern Pacific. A discussion of these features and their agreement with previous observational studies of the BSISO is given. 相似文献
10.
Sensitivity of the Simulated Tropical Intraseasonal Oscillation to Cumulus Parameterizations 下载免费PDF全文
下载免费PDF全文 The sensitivity of the simulated tropical intraseasonal oscillation or MJO (Madden and Julian oscilla tion)to different cumulus parameterizations is studied by using an atmospheric general circulation model (GCM)-SAMIL(Spectral Atmospheric Model of IAP LASG).Results show that performance of the model in simulating the MJO alters widely when using two different cumulus parameterization schemes-the moist convective adjustment scheme(MCA)and the Zhang-McFarlane(ZM)scheme.MJO simulated by the MCA scheme was found to be more realistic than that simulated by the ZM scheme.MJO produced by the ZM scheme is too weak and shows little propagation characteristics.Weak moisture convergence at low levels simulated by the ZM scheme is not enough to maintain the structure and the eastward propagation of the oscillation.These two cumulus schemes produced different vertical structures of the heating profile.The heating profile produced by the ZM scheme is nearly uniform with height and the heating is too weak compared to that produced by the MCA,which maybe contributes greatly to the failure of simulating a reasonable MJO.Comparing the simulated MJO by these two schemes indicate that the MJO simulated by the GCM is highly sensitive to cumulus parameterizations implanted in.The diabatic heating profile plays an important role in the performance of the GCM.Three sensitivity experiments with different heating profiles are designed in which modified heating profiles peak respectively in the upper troposphere(UH), middle troposphere(MH),and lower troposphere(LH).Both the LH run and the MH run produce eastward propagating signals on the intraseasonal timescale,while it is interesting that the intraseasonal timescale signals produced by the UH run propagate westward.It indicates that a realistic intraseasonal oscillation is more prone to be excited when the maximum heating concentrates in the middle-low levels,especially in the middle levels,while westward propagating disturbances axe more prone to be produced when the maximum heating appears very high. 相似文献
11.
Harun A. Rashid Harry H. Hendon Matthew C. Wheeler Oscar Alves 《Climate Dynamics》2011,36(3-4):649-661
Predictions of the Madden?CJulian oscillation (MJO) are assessed using a 10-member ensemble of hindcasts from POAMA, the Australian Bureau of Meteorology coupled ocean?Catmosphere seasonal prediction system. The ensemble of hindcasts was initialised from observed atmosphere and ocean initial conditions on the first of each month during 1980?C2006. The MJO is diagnosed using the Wheeler-Hendon Real-time Multivariate MJO (RMM) index, which involves projection of daily data onto the leading pair of eigenmodes from an analysis of zonal winds at 200 and 850?hPa and outgoing longwave radiation (OLR) averaged about the equator. Forecasts of the two component (RMM1 and RMM2) index are quantitatively compared with observed behaviour derived from NCEP reanalyses and satellite OLR using the bivariate correlation skill, root-mean-square error (RMSE), and measures of the MJO amplitude and phase error. Comparison is also made with a simple vector autoregressive (VAR) prediction model of RMM as a benchmark. Using the full hindcast set, we find that the MJO can be predicted with the POAMA ensemble out to about 21?days as measured by the bivariate correlation exceeding 0.5 and the bivariate RMSE remaining below ~1.4 (which is the value for a climatological forecast). The VAR model, by comparison, drops to a correlation of 0.5 by about 12?days. The prediction limit from POAMA increases by less than 2?days for times when the MJO has large initial amplitude, and has little sensitivity to the initial phase of the MJO. The VAR model, on the other hand, shows a somewhat larger increase in skill for times of strong MJO variability and has greater sensitivity to initial phase, with lower skill for times when MJO convection is developing in the Indian Ocean. The sensitivity to season is, however, greater for POAMA, with maximum skill occurring in the December?CJanuary?CFebruary season and minimum skill in June?CJuly?CAugust. Examination of the MJO amplitudes shows that individual POAMA members have slightly above observed amplitude after a spin-up of about 10?days, whereas examination of the MJO phase error reveals that the model has a consistent tendency to propagate the MJO slightly slower than observed. Finally, an estimate of potential predictability of the MJO in POAMA hindcasts suggests that actual MJO prediction skill may be further improved through continued development of the dynamical prediction system. 相似文献
12.
Study on multi-scale blending initial condition perturbations for a regional ensemble prediction system 总被引:9,自引:0,他引:9
An initial conditions (ICs) perturbation method was developed with the aim to improve an operational regional ensemble prediction system (REPS). Three issues were identified and investigated: (2) the impacts of perturbation scale on the ensemble spread and forecast skill of the REPS; (3) the scale characteristic of the IC perturbations of the REPS; and (4) whether the REPS's skill could be improved by adding large-scale information to the IC perturbations. Numerical experiments were conducted to reveal the impact of perturbation scale on the ensemble spread and forecast skill. The scales of IC perturbations from the REPS and an operational global ensemble prediction system (GEPS) were analyzed. A "multi-scale blending" (MSB) IC perturbation scheme was developed, and the main findings can be summarized as follows: The growth rates of the ensemble spread of the REPS are sensitive to the scale of the IC perturbations; the ensemble forecast skills can benefit from large-scale perturbations; the global ensemble IC perturbations exhibit more power at larger scales, while the regional ensemble IC perturbations contain more power at smaller scales; the MSB method can generate IC perturbations by combining the small-scale component from the REPS and the large-scale component from the GEPS; the energy norm growth of the MSB-generated perturbations can be appropriate at all forecast lead times; and the MSB-based REPS shows higher skill than the original system, as determined by ensemble forecast verification. 相似文献
13.
Qian ZOU Quanjia ZHONG Jiangyu MAO Ruiqiang DING Deyu LU Jianping LI Xuan LI 《大气科学进展》2023,40(3):501-513
Based on a simple coupled Lorenz model, we investigate how to assess a suitable initial perturbation scheme for ensemble forecasting in a multiscale system involving slow dynamics and fast dynamics. Four initial perturbation approaches are used in the ensemble forecasting experiments: the random perturbation(RP), the bred vector(BV), the ensemble transform Kalman filter(ETKF), and the nonlinear local Lyapunov vector(NLLV) methods. Results show that,regardless of the method used, the ensemble ave... 相似文献
14.
This study examines the forecast performance of tropical intraseasonal oscillation (ISO) in recent dynamical extended range
forecast (DERF) experiments conducted with the National Centers for Environmental Prediction (NCEP) Global Forecasting System
(GFS) model. The present study extends earlier work by comparing prediction skill of the northern winter ISO (Madden-Julian
Oscillation) between the current and earlier experiments. Prediction skill for the northern summer ISO is also investigated.
Since the boreal summer ISO exhibits northward propagation as well as eastward propagation along the equator, forecast skill
for both components is computed. For the 5-year period from 1 January, 1998 through 31 December, 2002, 30-day forecasts were
made once a day. Compared to the previous DERF experiment, the current model has shown some improvements in forecasting the
ISO during winter season so that the skillful forecasts (anomaly correlation>0.6) for upper-level zonal wind anomaly extend
from the previous shorter-than 5 days out to 7 days lead-time. A similar level of skill is seen for both northward and eastward
propagation components during the summer season as in the winter case. Results also show that forecasts from extreme initial
states are more skillful than those from null phases for both seasons, extending the skillful range by 3–6 days. For strong
ISO convection phases, the GFS model performs better during the summer season than during the winter season. In summer forecasts,
large-scale circulation and convection anomalies exhibit northward propagation during the peak phase. In contrast, the GFS
model still has difficulties in sustaining ISO variability during the northern winter as in the previous DERF run. That is,
the forecast does not maintain the observed eastward propagating signals associated with large-scale circulation; rather the
forecast anomalies appear to be stationary at their initial location and decay with time. The NCEP Coupled Forecast System
produces daily operational forecasts and its predication skill of the MJO will be reported in the future. 相似文献
15.
基于LAF思想的一种初始扰动生成方法及集合预报试验 总被引:4,自引:3,他引:1
在时间滞后平均法(LAF)思想的基础上,提出了一种改进的LAF方法,这种方法的思路是将不同的初始扰动叠加到模式初始场上进行不同的扰动预报,形成集合预报的成员;而不同的扰动场是通过在滞后不同时次上求取不同资料分析场之差获得。这种扰动不仅体现了不同分析场的差异,而且不同的滞后时间也体现了LAF方法的思路。然后利用经典的LAF方法及改进的LAF方法和AREM模式,分别对2004年6月14~15日安徽入梅首场暴雨过程进行了集合预报试验。结果表明,无论是雨带还是雨团位置和强度的预报,改进的LAF方法都优于经典的LAF方法。进一步研究发现,对于同一个扰动,加扰预报结果比减扰结果要好,若只选择加扰预报作集合平均,其预报结果更接近实况。 相似文献
16.
Bimodal representation of the tropical intraseasonal oscillation 总被引:2,自引:1,他引:1
The tropical intraseasonal oscillation (ISO) shows distinct variability centers and propagation patterns between boreal winter and summer. To accurately represent the state of the ISO at any particular time of a year, a bimodal ISO index was developed. It consists of Madden-Julian Oscillation (MJO) mode with predominant eastward propagation along the equator and Boreal Summer ISO (BSISO) mode with prominent northward propagation and large variability in off-equatorial monsoon trough regions. The spatial–temporal patterns of the MJO and BSISO modes are identified with the extended empirical orthogonal function analysis of 31?years (1979–2009) OLR data for the December–February and June–August period, respectively. The dominant mode of the ISO at any given time can be judged by the proportions of the OLR anomalies projected onto the two modes. The bimodal ISO index provides objective and quantitative measures on the annual and interannual variations of the predominant ISO modes. It is shown that from December to April the MJO mode dominates while from June to October the BSISO mode dominates. May and November are transitional months when the predominant mode changes from one to the other. It is also shown that the fractional variance reconstructed based on the bimodal index is significantly higher than the counterpart reconstructed based on the Wheeler and Hendon’s index. The bimodal ISO index provides a reliable real time monitoring skill, too. The method and results provide critical information in assessing models’ performance to reproduce the ISO and developing further research on predictability of the ISO and are also useful for a variety of scientific and practical purposes. 相似文献
17.
POSSIBLE INFLUENCES OF THE TROPICAL INDIAN OCEAN DIPOLE ON THE EASTWARD PROPAGATION OF MJO 总被引:1,自引:0,他引:1
Based on multiple datasets, correlation and composite analyses, and case studies, this paper investigated possible influences of the Indian Ocean dipole (IOD) mode on the eastward propagation of intraseasonal oscillation in the tropical atmosphere. The results showed that (1) the 30-60 day outgoing longwave radiation anomalies in the southeastern Indian Ocean and the 30-60 day 850-hPa zonal wind anomalies over the equatorial central Indian Ocean were significantly correlated with the IOD index; (2) during positive IOD years, the anomalously cold water in the southeastern Indian Ocean and the 850-hPa anomalous easterlies over the equatorial central Indian Ocean might act as barriers to the continuously eastward propagation of the intraseasonal convection, which interrupts the Madden-Julian oscillation (MJO) propagation in the eastern equatorial Indian Ocean and western Pacific; and (3) during negative IOD years, the anomalously warm water in the southeastern Indian Ocean and the low-level westerly anomalies over the equatorial central Indian Ocean favor the eastward movement of MJO. 相似文献
18.
This study evaluates performance of Madden–Julian oscillation (MJO) prediction in the Beijing Climate Center Atmospheric General Circulation Model (BCC_AGCM2.2). By using the real-time multivariate MJO (RMM) indices, it is shown that the MJO prediction skill of BCC_AGCM2.2 extends to about 16–17 days before the bivariate anomaly correlation coefficient drops to 0.5 and the root-mean-square error increases to the level of the climatological prediction. The prediction skill showed a seasonal dependence, with the highest skill occurring in boreal autumn, and a phase dependence with higher skill for predictions initiated from phases 2–4. The results of the MJO predictability analysis showed that the upper bounds of the prediction skill can be extended to 26 days by using a single-member estimate, and to 42 days by using the ensemble-mean estimate, which also exhibited an initial amplitude and phase dependence. The observed relationship between the MJO and the North Atlantic Oscillation was accurately reproduced by BCC_AGCM2.2 for most initial phases of the MJO, accompanied with the Rossby wave trains in the Northern Hemisphere extratropics driven by MJO convection forcing. Overall, BCC_AGCM2.2 displayed a significant ability to predict the MJO and its teleconnections without interacting with the ocean, which provided a useful tool for fully extracting the predictability source of subseasonal prediction. 相似文献
19.
基于季节内振荡的延伸预报试验 总被引:11,自引:2,他引:9
2~4周的延伸预报是近年来国际上天气和气候业务预报发展的一个重要方向。本文以江淮梅雨区降水为例, 在利用集合经验模态分解 (EEMD) 及多变量EOF方法获取梅雨区降水及其影响系统低频信号的基础上, 采用最优子集回归方法、 经验波传播 (EWP) 方法及全球海气耦合模式产品, 对梅雨季节内演变的延伸期预报方法进行了预报和试验, 以期为建立延伸期预报业务提供科学依据。试验结果表明: (1) 大气季节内振荡对梅雨区降水的延伸预报具有重要的应用价值, 可能是联系天气过程和异常的重要系统。(2) 通过EEMD方法提取前期降水演变及影响因子的季节内振荡信号, 采用最优子集回归统计学方法对梅雨区逐候降水量演变进行超前30天预报是有可能的。(3) EWP经验动力方法对热带ITCZ活跃异常的未来40天东传可能具有较好的预报效果, 还可能较好地预报出延伸期的梅雨区风场距平演变, 具有一定应用价值。(4) 全球海气耦合动力模式输出产品在延伸期环流形势趋势预报及20天左右的MJO指数预报方面有一定的参考价值。 相似文献
20.
热带大气低频振荡 (MJO) 和北半球夏季季节内振荡 (BSISO) 对全球范围天气气候事件有重要影响,是次季节-季节 (S2S) 预报最主要的可预报性来源之一。国家气候中心 (BCC) 基于我国完全自主的T639全球分析场数据、风云三号气象卫星射出长波辐射 (OLR) 资料以及BCC第2代大气环流模式系统的实时预报,发展了MJO实时监测预测一体化业务技术,建立了ISV/MJO监测预测业务系统 (IMPRESS1.0),已投入实时业务运行,在全国气象业务系统得到应用。该文着重介绍该系统提供的MJO和BSISO指数监测预测数据和图形产品,并描述了这些业务产品在2015年对MJO典型个例的实时监测预测应用情况。监测分析和预报检验表明,基于我国自主资料的监测结果能够较为准确地表征MJO和BSISO指数的振荡和演变过程,该系统对MJO和BSISO事件分别至少具备16 d和10 d左右的预报技巧。因此,基于IMPRESS1.0的MJO/BSISO监测预测一体化业务产品可为制作延伸期预报提供重要的参考依据。 相似文献