Abstract
The objective of the present paper is to examine the capability of the regional climate model version 3 (RegCM3) to simulate the annual as well as seasonal precipitation variability over the Indian subcontinent. RegCM3 has been run at 40 km horizontal resolution for the period of 1982–2006 continuously and model results were compared to the observed precipitation datasets of India Meteorological Department (IMD) and CPC Merged Analysis of Precipitation (CMAP). Model evaluation has been done using different statistical methods like mean bias error (MBE), root mean square error, mean percentage error (MPE) and studied the spatial pattern of annual and seasonal variability and trend. Daily precipitation data at 1° × 1° grids of IMD have been used to study observed climatological means (both annual and seasonal), regression trends, interannual and intraseasonal variability over India from 1951 to 2007. The spatial distribution of annual precipitation shows a decreasing trend over west coast of India, central India, hilly region of India and an increasing trend is found over the northwest India, peninsular India and northeast India. The temporal distribution of daily precipitation shows highest rainfall of 18 mm/day in mid July (in composite flood cases only) and 12 mm/day during August (in composite drought cases only). The RegCM3 simulated annual and seasonal precipitation variability is close to the observed IMD and CMAP over all India (AI). During winter and pre-monsoon season, the model has overestimated the mean precipitation while underestimated in summer and post-monsoon season. Overall, annual precipitation showed the deficiency of −22.44 % compared to IMD and −1.41 % compared to CMAP over India. To understand the possible cause of annual and seasonal precipitation biases over India and its six homogeneous regions, the vertical difference (model mines National Centre for Environmental Prediction; NCEP) fields of water vapor mixing ratio (WVMR) and air temperature from surface to top level (1σ–18σ level) have been studied in detail. The model produced more moisture at the lower level during winter (JF) and pre-monsoon (MAM) season and reduced WVMR at the same levels during summer (JJAS) and post (OND) monsoon over India. High moisture content at the lower level simulated in the model can explain the increased precipitation during JF and MAM season and vice versa during JJAS and OND. Similar results were found over the homogeneous regions of India. This analysis indicates that the RegCM3 has more transport of vertical WVMR from surface to mid layer of the troposphere compared to NCEP.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Ahn JB, Lee J, Im ES (2012) The reproducibility of surface air temperature over South Korea using dynamical downscaling and statistical correction. J Meteorol Soc Jpn 90(4):493–507
Chang EC, Hong SY (2011) Projected climate change scenario over East Asia by a regional spectral model. J Korean Earth Sci Soc 32:770–783
Crétat J, Pohl B, Richard Y, Drobinski P (2012) Uncertainties in simulating regional climate of Southern Africa: sensitivity to physical parameterizations using WRF. Clim Dyn 38:613–634
Dash SK, Shekhar MS, Singh GP, Vernekar AD (2002) Relationship between surface fields over Indian Ocean and monsoon precipitation over homogeneous zones of India. Mausam 53:133–144
Dash SK, Shekhar MS, Singh GP (2006) Simulation of Indian summer monsoon circulation and Rainfall using RegCM3. Theor Appl Climatol 86:161–172
Dimri AP, Mohanty UC (2009) Simulation of mesoscale features associated with intense western disturbances over western Himalayas. Meteorol Appl 16:289–308
Dobler A, Ahrens B (2010) Analysis of the Indian summer monsoon system in the regional climate model COSMOCLM. J Geophys Res 115:D16101. doi:10.1029/2009JD013497
Duffy PB, Arritt RW, Coquard J, Gutowski W et al (2006) Simulations of present and future climates in the western United States with four nested regional climate models. J Clim 19:873–895
Engelbrecht FA, Mcgregor JL, Engelbrecht CJ (2009) Dynamics of the conformal-cubic atmospheric model projected climate-change signal over southern Africa. Int J Climatol 29:1013–1033
Giorgi F, Bi X, Pal JS (2004) Mean, interannual variability and trends in a regional climate change experiment over Europe: present-day climate (1961–1990). Clim Dyn 22:733–756
Grell GA (1993) Prognostic evaluation of assumptions used by cumulus parameterizations. Mon Weather Rev 121:764–787
Holtslag AAM, de Bruijn EIF, Pan HL (1990) A high resolution air mass transformation model for short-range weather forecasting. Mon Weather Rev 118:1561–1575
Hong S-Y, Kanamitsu M (2014) Dynamical downscaling: fundamental issues from an NWP point of view and recommendations. Asia-Pac J Atmos Sci 50(1):83–104
Hong SY, Moon NK, Lim KSS, Kim JW (2010) Future climate change scenarios over Korea using a multi-nested downscaling system: a pilot study. Asia-Pac J Atmos Sci 46:425–435
Im ES, Park EH, Kwon WT, Giorgi F (2006) Present climate simulations over Korea with a regional climate model using a one-way double-nested system. Theor Appl Climatol 86:187–200
Im ES, Ahn JB, Remedio AR, Kwon WT (2008) Sensitivity of the regional climate of East/Southeast Asia to convective parameterizations in the RegCM3 modelling system. Part 1: focus on the Korean peninsula. Int J Climatol 28:1861–1877
Im ES, Ahn JB, Kim DW (2012a) An assessment of future dryness over Korea based on the ECHAM5-RegCM3 model chain under A1B emission scenario. Asia-Pac J Atmos Sci 48(4):325–337
Im ES, Lee BJ, Kwon JH, In SR, Han SO (2012b) Potential increase of flood hazards in Korea due to global warming from a highresolution regional climate simulation. Asia-Pac J Atmos Sci 48(1):107–113
Kiehl JT, Hack JJ, Bonan GB, Boville BA, Briegleb BP, Williamson DL, and Rasch PJ (1996) Description of the NCAR community climate model (CCM3). NCAR Tech Note/TN-420 + STR. National Centre for Atmospheric Research, Boulder, p 152
Krishnamurti TN, Sanjay J (2003) A new approach to the cumulus parameterization issue. Tellus 55A:275–300
Kumar P, Wiltshire A, Mathison C, Asharaf S, Ahrens B, Lucas-Picher P, Christensen JH, Gobiet A, Saeed F, Hagemann S, Jacob D (2013) Downscaled climate change projections with uncertainty assessment over India using a high resolution multi-model approach. Sci Total Environ 468–469:S18–S30. doi:10.1016/j.scitotenv.2013.01.051
Lee J-W, Hong S-Y (2014) Potential for added value to downscaled climate extremes over Korea by increased resolution of a regional climate model. Theor Appl Climatol 117:667–677. doi:10.1007/s00704-013-1034-6
Lee E, Sacks WJ, Chase TN, Foley JA (2011) Simulated impacts of irrigation on the atmospheric circulation over Asia. J Geophys Res 116:D08114. doi:10.1029/2010JD014740
Lee DK, Cha DH, Jin CS, Choi SJ (2013) A regional climate change simulation over East Asia. Asia-Pac J Atmos Sci 49:655–664
Lucas-Picher P, Christensen JH, Saeed F, Kumar P, Asharaf S, Ahrens B, Wiltshire A, Jacob D, Hagemann S (2011) Can regional climate models represent the Indian monsoon? J Hydrometeor 12:849–868
MacKellar NC, Tadross MA, Hewitson BC (2009) Effects of vegetation map change in MM5 simulations of southern Africa’s summer climate. Int J Climatol 29:885–898
Maharana P, Dimri AP (2014) Study of seasonal climatology and interannual variability over India and its subregions using a regional climate model (RegCM3). J Earth Syst Sci 123(5):1147–1169
Mariotti L, Coppola E, Sylla MB, Giorgi F, Piani C (2011) Regional climate model simulation of projected 21st century climate change over an all Africa domain: comparison analysis of nested and driving model results. J Geophys Res 116:D15111. doi:10.1029/2010JD015068
Noguer M, Jones RG, Murphy JM (1998) Sources of systematic errors in the climatology of a nested regional climate model (RCM) over Europe. Clim Dyn 14:691–712
Oh S-G, Suh M-S, Cha D-H (2013) Impact of lateral boundary conditions on precipitation and temperature extremes over South Korea in the CORDEX regional climate simulation using RegCM4. Asia-Pac J Atmos Sci 49(4):497–509
Paeth H, Born K, Girmes R, Podzun R, Jacob D (2009) Regional climate change in tropical and Northern Africa due to greenhouse forcing and land use changes. J Clim 22:114–132
Pal JS, Giorgi F, Bi XQ et al (2007) The ICTP RegCM3 and RegCNET: regional climate modeling for the developing world. B Am Math Soc 88:1395–1409
Pattnayak KC, Panda SK, Dash SK (2013) Comparative study of regional rainfall characteristics simulated by RegCM3 and recorded by IMD. Glob Planet Change 106:111–122
Rajeevan M, Bhate J, Kale JD, Lal B (2006) High resolution daily gridded rainfall data for the Indian region: analysis of break and active monsoon spells. Curr Sci 91:296–306
Ratnam JV, Kumar K (2005) Sensitivity of the simulated monsoons of 1987 and 1988 to convective parameterization schemes in MM5. J Clim 18:2724–2743
Rupa Kumar K, Sahai AK, Kumar KK, Patwardhan SK, Mishra PK, Revadekar JV, Kamala K, Pant GB (2006) High-resolution climate changes scenarios for India for the 21st century. Curr Sci 90:334–345
Singh GP, Oh JH (2007) Impact of Indian Ocean sea-surface temperature anomaly on Indian summer monsoon precipitation using a regional climate model. Inter J Climatol 27:1455–1465
Sinha P, Mohanty UC, Kar SC, Dash SK, Kumari S (2012) Sensitivity of the GCM driven summer monsoon simulations to cumulus parameterization schemes in nested RegCM3. Theoret Appl Climatol 112:285–306
Staniforth A (1997) Regional modeling: a theoretical discussion. Meteorol Atmos Phys 63:15–29
Suh MS, Oh SG, Lee DK, Cha DH, Choi SJ, Jin CS, Hong SY (2012) Development of new ensemble methods based on the performance skills of regional climate models over South Korea. J Clim 25:7067–7082
Sylla MB, Gaye AT, Pal JS, Jenkins GS, Bi XQ (2009) High resolution simulations of West Africa climate using regional climate model (RegCM3) with different lateral boundary conditions. Theor Appl Climatol 98:293–314
Sylla MB, Coppola E, Mariotti L, Giorgi F, Ruti PM, Dell’Aquila A, Bi X (2010) Multiyear simulation of the African climate using a regional climate model (RegCM3) with the high resolution ERA-interim reanalysis. Clim Dyn 35:231–247
Sylla MB, Gaye AT, Jenkins GS (2012) On the fine-scale topography regulating changes in atmospheric hydrological cycle and extreme rainfall over West Africa in a regional climate model projections. Int J Geophys 2012, Article ID 981649. doi:10.1155/2012/981649
Tadross MA, Gutowski WJ, Hewitson BC, Jack C, New M (2006) MM5 simulations of interannual change and the diurnal cycle of southern African regional climate. Theor Appl Climatol 86:63–80
Tummon F, Solmon F, Liousse C, Tadross M (2010) Simulation of the direct and semidirect aerosol effects on the southern Africa regional climate during the biomass burning season. J Geophys Res 115:D19206
Wang X, Zhong Z, Hu Y, Yuan H (2010) Effect of lateral boundary scheme on the simulation of tropical cyclone track in regional climate model RegCM3. Asia-Pac J Atmos Sci 46:221–230
Xie P, Arkin PA (1997) Global precipitation: a 17-year monthly analysis based on gauge observations, satellite estimates, and numerical model outputs. Bull Am Meteorol Soc 78:2539–2558
Xie SP, Xu H, Saji NH, Wang Y (2006) Role of narrow mountain in large-scale organization of Asian monsoon convection. J Climate 19:3420–3429
Zaroug MAH, Sylla MB, Giorgi F, Eltahir EAB, Aggarwal PK (2013) A sensitivity study on the role of the swamps of southern Sudan in the summer climate of North Africa using a regional climate model. Theor Appl Climatol 113(1–2):63–81
Acknowledgments
The authors acknowledge the International Centre for Theoretical Physics (ICTP), Trieste, Italy for providing model and RegCM3 data sets and Department of Science and Technology (DST), Government of India Do. No. DST/CCP/NMSKCC/10 for providing financial support.
Author information
Authors and Affiliations
Corresponding author
Additional information
Responsible Editor: S. Hong.
Rights and permissions
About this article
Cite this article
Maurya, R.K.S., Singh, G.P. Simulation of present-day precipitation over India using a regional climate model. Meteorol Atmos Phys 128, 211–228 (2016). https://doi.org/10.1007/s00703-015-0409-x
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00703-015-0409-x