AUTHOR INDEX
Aguilar, E. (Tarragona, Spain) ..................... 47 Auer, I. (Wien, Austria) ................................ 47 Betz, H.D. (Garching,Germany) ................. 295 Bihari, Z. (Budapest, Hungary) .................. 143 Blanka, V. (Szeged, Hungary) .................... 219 Bobvos, J. (Budapest, Hungary) ................. 175 Böhm, R. (Wien, Austria) ............................ 47 Caramelo, L. (Vila Real, Portugal) ............... 69 Diebel, S. (Munich, Germany) ................... 295 Dimitrova, T. (Sofia, Bulgaria) .................. 295 Domonkos, P. (Tortosa, Spain) ..................... 47, 91 Dubuisson, B. (Toulouse, France) ................ 47 Faragó, I. (Budapest, Hungary) .................. 201 Farda, A. (Brno, Czech Republic) .............. 123 Ferenczi, Z. (Budapest, Hungary) .............. 359 Freitas, L. (Vila Real, Portugal) ................... 69 Führer, E. (Sopron, Hungary) ..................... 159 Geresdi, I. (Pécs, Hungary) ........................ 377 Guijarro, J.A. (Palma di Mallorca, Spain) .... 35, 47 Horváth, L. (Budapest, Hungary) ............... 159 Izsák, F. (Budapest, Hungary) .................... 201 Jagodics, A. (Budapest, Hungary) .............. 159 Juhász, I. (Budapest, Hungary) .................. 159 Klancar, M. (Ljubljana, Slovenia) ................ 47 Kohlmann, M. (Budapest, Hungary) ........... 4.4 Kristóf, G. (Budapest, Hungary) ................ 239 Krisztalovics, K. (Budapest, Hungary) ....... 175 Lábó, E. (Budapest, Hungary) .................... 377 Lagzi, I. (Budapest, Hungary) ..................... 4.4 Lakatos, M. (Budapest, Hungary) .............. 143 Lebarbier, E. (Paris, France) ......................... 47
Leelőssy, Á. (Budapest, Hungary) ............... 4.4 Ludányi, E.L. (Budapest, Hungary) ............. 4.4 Lindau, R. (Bonn, Germany) .......................... 1 Marosi, Gy. (Sopron, Hungary) .................. 159 Matyasovszky, I. (Budapest, Hungary) ....... 187 Mendes, M. (Lisboa, Portugal) ..................... 69 Mestre, O. (Toulouse, France) ...................... 47 Mészáros, R. (Budapest, Hungary) .............. 4.4 Meyer, B. (Leipzig, Germany) .................... 219 Mezősi, G. (Szeged, Hungary) .................... 219 Mihailovic, D.T. (Novi Sad, Serbia) ........... 277 Mitzeva, R. (Sofia, Bulgaria) ...................... 295 Nunes, L.F. (Lisboa, Portugal) ..................... 69 Páldy, A. (Budapest, Hungary) ................... 175 Pereira, M.G. (Lisboa, Portugal) ................... 69 Picard, F. (Villeurbanne, France) .................. 47 Podrascanin, Z. (Novi Sad, Serbia) ............. 277 Rácz, N. (Budapest, Hungary) .................... 239 Robin, S. (Paris, France) ............................... 47 Štěpánek, P. (Brno, Czech Republic) ............... 47, 123 Szabó, T. (Basque Country, Spain) ............. 201 Szalai, S. (Gödöllő, Hungary) ..................... 143 Szász, G. (Debrecen, Hungary) .................. 315 Szentimrey, T. (Budapest, Hungary) .......... 113, 143 Trájer, A. (Budapest, Hungary) .................. 175 Tóth, Z. (Budapest, Hungary) ...................... 4.3 Venema, V. (Bonn, Germany) ........................ 1 Vertachnik, G. (Ljubljana, Slovenia) ............ 47 Weidinger, T. (Budapest, Hungary) ............ 239 Zahradníček, P. (Brno, Czech Republic) .... 123 Zhelev, H. (Sofia, Bulgaria) ........................ 295
TABLE OF CONTENTS I. Papers
Blanka, V., Mezősi, G., and Meyer, B.: Projected changes in the drought hazard in Hungary due to climate change ................................................... 219 Dimitrova, T., Mitzeva, R., Betz, H.D., Zhelev, H., and Diebel, S.: Lightning behavior during the lifetime of severe hail-producing thunderstorms ............... 295
ii
Domonkos, P.: Measuring performances of homogenization methods .................. 91 Faragó, I., Izsák, F., and Szabó, T.: An IMEX scheme combined with Richardson extrapolation methods for some reaction-diffusion equations ........ 201
Ferenczi, Z.: Predictability analysis of the PM2.5 and PM10 concentration in Budapest ................................................ 359 Freitas, L., Pereira, M.G., Caramelo, L., Mendes, M., and Nunes, L.F.: Homogeneity of monthly air temperature in Portugal with HOMER and MASH .............................................. 69 Führer, E., Jagodics, A., Juhász, I., Marosi, Gy., and Horváth, L.: Ecological and economical impacts of climate change on Hungarian forestry practice .................................................. 159 Guijarro, J. A.: Climatological series shift test comparison on running windows ................................................ 35 Lábó, E. and Geresdi, I.: Application of a Detailed Bin Scheme in Longwave Radiation Transfer Modeling ................ 377 Lakatos, M., Szentimrey, T., Bihari, Z.,and Szalai, S.: Creation of a homogenized climate database for the Carpathian region by applying the MASH procedure and the preliminary analysis of the data ................................ 143 Leelőssy, Á., Ludányi, E.L., Kohlmann, M., Lagzi, I., and Mészáros, R.,: Comparison of two Lagrangian dispersion models: a case study for the chemical accident in Rouen, 21– 22 January 2013 .................................... 4.4 Lindau, R. and Venema, V.: On the multiple breakpoint problem and the number of significant breaks in homogenization of climate records ................
1
Matyasovszky, I.: Estimating red noise spectra of climatological time series ..... 187
Mestre, O., Domonkos, P., Picard, F., Auer, I., Robin, S., Lebarbier, E., Böhm, R., Aguilar, E., Guijarro, J., Vertachnik, G., Klancar, M., Dubuisson, B., and Štěpánek, P.: HOMER: a homogenization software – methods and applications ................... 47 Podrascanin, Z. and Mihailovic, D.T.: Performance of the Asymmetric Convective Model Version 2, in the Unified EMEP Model ........................... 277 Rácz, N., Kristóf, G., and Weidinger, T.: Evaluation and validation of a CFD solver adapted to atmospheric flows: Simulation of topography-induced waves .................................................... 239 Štěpánek, P., Zahradníček, P., and Farda, A.: Experiences with data quality control and homogenization of daily records of various meteorological elements in the Czech Republic in the period 1961–2010 .................................. 123 Szász, G.: Agrometeorological research and its results in Hungary (1870– 2010) ..................................................... 315 Szentimrey, T.: Theoretical questions of daily data homogenization .................... 113 Trájer, A., Bobvos, J., Krisztalovics, K., and Páldy, A.: Regional differences between ambient temperature and incidence of Lyme disease in Hungary ............................................................... 175 Tóth, Z.: High resolution solar spectrophotometry and narrow spectral range solar radiation measurements at the Hungarian Meteorological Service .. 4.3
SUBJECT INDEX
A accidental release agriculture, history
435 315
agroclimatology agrometeorology air quality - forecast
315 315 359
iii
- of Budapest - of Hungary - monitoring air pollution modeling ALADIN regional climate model atmospheric dispersion Austria autoregressive model
359 359 359 359, 435 219 359, 435 47 187
B bin scheme break point detection Bulgaria bulk scheme
377 1 295 377
C calibration 403 Carpathian Region Project 143 climate - Carpathian Region Project 143 - change 159, 175, 219 - extremes 113 - indices 143 - regional change 219 - series 1, 35, 47, 69, 91, 113, 123, 143, 159, 187 - stations 1 - variations 35 climatological - regional differences 175 - series inhomogeneity 1, 35, 47, 69, 91, 113, 123, 143 - surface observations 91, 113, 123, 143 - upper air observations 91 climatology 315 cloud microphysics 377 cloud-radiation interaction 377 comparison, shift tests 35 complex terrain 239 computational fluid dynamics 239 convective mixing, non-local 277 cooling rate 377 COST Action ES0601 – HOME1, 35, 47, 91, 143 crop canopy 315 Czech Republic 123
iv
D data - quality control - processing daily data - processing - series diesase, vector-borne diffusion equations dispersion modeling distribution drought - hazard - indices dynamic programing
123 123 123 113 175 201, 359 359, 435 113 219 219 1
E EMEP - long-range transport model - unified model emissions environment, urban equation - reaction-diffusion evaporation extrapolation, Richardson
359 277 359 359 201 315 201
F fertility finite difference approximation flash rate forest - annual revenues - ecosystem - yield classes fluid dynamics fuel cell
315 201 295 159 159 159 239 201
G Germany gravity waves
1, 219, 295 239
H hail 295 hazard - drought 219, 315 - environmental 219 higher order moments 113 history of Hungarian agrometeorology 315 HOMER homogenization software 47, 69 homogenization 1, 35, 47, 69, 91, 143 homogenization methods 47, 69, 91, 113, 143 homogenized climate database 143 Hungary 113, 143, 159, 175, 187, 201, 219, 239, 315, 435, 377, 403
I IMEX – implicit-explicit method 201 indice - climate 143 - hazard 219 industrial accident 435 inhomogeneity - in climate series1, 35, 47, 69, 91. 113, 123 - in monthly mean temperature series 69 - statistical correction 1, 35, 47, 69, 91, 113, 123 indicator species 175 interaction between cloud and radiation 377 isotonic regression 187 Ixodes ricinus 175
J joint segmentation
47
- total longwave radiation transfer Lyme borreliosis
295 377 175
M MASH homogenization method 47, 69, 113 mathematical formulation 113 measurements - air pollution 359 - climate datasets 1, 47, 69, 91 - radiation 403 - technics 403 meteorological parameters 359 method - implicit-explicit 201 microphysics of clouds 377 mixing - non-local convective 277 - vertical turbulent 277 model - air quality forecast 359 - ALADIN regional climate 219 - autoregressive 187 - CFD (compuational fluid dynamics) 239 - chemical 277, 359 - dynamic programing 1 - dispersion 435 - EMEP long-range transport 359 - EMEP unified 277 - emission modul 359 - HYSPLIT Lagrangian dispersion 435 - PyTREX continental trajectory 435 - REMO regional climate 219 - RRTM RW radiation transfer 377 - validation 239 monitoring network 359 multiple break point detection 1 multiplicity 295
K kinetic energy, turbulent
277
L Lagrangian dispersion model lightning - density
435
N non-local convective mixing numerical - solution - weather prediction
277 201 239
295
v
O observations - surface climatic - upper air climatic optical depth optimal segmentation ozone - total - tropospheric
S
1, 47, 69, 91 91 403 47 403 359
P parameters, meteorological 359, 435 particulate matter 359 PEM – proton exchange membrane 201 penalty term 1 Portugal 69 precipitation - series 47, 113, 123, 159 prediction, numerical weather 239 production - actual 315 - capacity 159 - potential 315 productivity 315 programing, multiple 1 PyTREX trajectory model 435
R radar reflectivity radiation - longwave - modeling - solar - UV reaction-diffusion equations red noise spectra reflectivity, radar regional climate change regional climatic differences regression - isotonic - robust REMO regional climate model Richardson extrapolation robust regression
vi
295 377 377 403 403 201 187 295 219 175 187 187 219 201 187
search algorithm 1 segmentation - joint 47 - optimal 47 Serbia 277 shift tests comparison 35 solar radiation 403 Spain 35 species - indicator 175 - tree 159 spectra 187 spectrophotometry 403 statistical correction of inhomogeneities 123 stop criterion for search algorithms 1 surface climatic observations 91
T temperature - daily data series - Portugal monthly mean - series homogenization - urban series (UBRIS) terrain, complex time series, climatological 113, 123, 143, 159, 187 total lightning tree species trend bias turbulent - kinetic energy - vertical mixing
113, 159 69 47, 69, 91 47 239 1, 35, 47, 69, 91, 295 159 47 277 277
U upper air climatic observations urban - environment - trend bias UV radiation
V
91 359 47 403
validation, numerical model vector-borne disease vertical turbulent mixing
239 175 277
waves, gravity weather prediction, numerical
239 239
Y W water clouds water supply of crop canopy
377 315
yield - forest yield classes
159
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