2018
DOI: 10.1175/jamc-d-17-0132.1
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Detecting Severe Weather Trends Using an Additive Regressive Convective Hazard Model (AR-CHaMo)

Abstract: A statistical model for the occurrence of convective hazards was developed and applied to reanalysis data to detect multidecadal trends in hazard frequency. The modeling framework is based on an additive logistic regression for observed hazards that exploits predictors derived from numerical model data. The regression predicts the probability of a severe hazard, which is considered as a product of two components: the probability that a storm occurs and the probability of the severe hazard, given the presence o… Show more

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Cited by 62 publications
(83 citation statements)
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References 38 publications
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“…Overall, a positive gradient in WMILX frequency is identified both in north‐to‐west and west‐to‐east directions, that is, along the coastlines of the North Atlantic and the Baltic Sea. This general distribution of convective environments is confirmed by similar studies based on reanalysis (Mohr et al ., ; Prein and Holland, ; Rädler et al ., ; Taszarek et al ., ), lightning (PK17; Taszarek et al ., ), and satellite (Punge et al ., ) data. However, there are major differences in the area of the Alps and their surroundings, mainly because orographically induced circulations and resulting convergence zones, which are mainly relevant for the triggering of convection, are not sufficiently resolved by the coastDat‐2 reanalysis.…”
Section: Resultsmentioning
confidence: 97%
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“…Overall, a positive gradient in WMILX frequency is identified both in north‐to‐west and west‐to‐east directions, that is, along the coastlines of the North Atlantic and the Baltic Sea. This general distribution of convective environments is confirmed by similar studies based on reanalysis (Mohr et al ., ; Prein and Holland, ; Rädler et al ., ; Taszarek et al ., ), lightning (PK17; Taszarek et al ., ), and satellite (Punge et al ., ) data. However, there are major differences in the area of the Alps and their surroundings, mainly because orographically induced circulations and resulting convergence zones, which are mainly relevant for the triggering of convection, are not sufficiently resolved by the coastDat‐2 reanalysis.…”
Section: Resultsmentioning
confidence: 97%
“…Piper, ). This increase of convection‐favouring conditions for thunderstorm or hail development since the 1980s has been already observed by other studies (Kapsch et al ., ; Mohr and Kunz, ; Rädler et al ., ).…”
Section: Resultsmentioning
confidence: 97%
“…; Rädler et al . ). Due to its persistence, blocking might contribute to improved thunderstorm potential predictability on sub‐seasonal time scales beyond the classical weather forecast time scale of a few days, and complement current activities that investigate the connection of water vapour transport on the sub‐seasonal predictability of extremes (e.g., Lavers et al .…”
Section: Discussionmentioning
confidence: 99%
“…In contrast to teleconnection patterns, which capture the annual variability, atmospheric blocking affects the prevailing (stationary) environmental conditions, such as atmospheric stability and the moisture content of air masses. Nevertheless, blocking is not suitable as a single predictor for convection; other approaches should be pursued for this purpose (e.g., Doswell et al, 1996;Sánchez et al, 2009;Mohr et al, 2015b;Púčik et al, 2015;Rädler et al, 2018). Due to its persistence, blocking might contribute to improved thunderstorm potential predictability on sub-seasonal time scales beyond the classical weather forecast time scale of a few days, and complement current activities that investigate the connection of water vapour transport on the sub-seasonal predictability of extremes (e.g., Lavers et al, 2016aLavers et al, , 2016bPasquier et al, 2018).…”
Section: For Both Areas Approximately 22% Of the Days Betweenmentioning
confidence: 99%
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