Abstract
The accurate prediction of rainfall events, in terms of their timing, location and rainfall depth, is important to a wide range of social and economic applications. At many operational weather prediction centres, as is also the case at the South African Weather Service, forecasters use deterministic model outputs as guidance to produce subjective probabilistic rainfall forecasts. The aim of this research was to determine the skill of a new objective multi-model, multi-institute probabilistic ensemble forecast system for South Africa. Such forecasts are obtained by combining the rainfall forecasts of 2 operational high-resolution regional atmospheric models in South Africa. The first model is the Unified Model (UM), which is operational at the South African Weather Service. The UM contributes 3 ensemble members, each with a different physics scheme, data assimilation techniques and horizontal resolution. The second model is the Conformal-Cubic Atmospheric Model (CCAM) which is operational at the Council for Scientific and Industrial Research, which in turn contributed 2 members to the ensemble system based on different horizontal resolutions. A single-model ensemble forecast, with each of the ensemble members having equal weights, was constructed for the UM and CCAM models, respectively. These UM and CCAM single-model ensemble predictions are then combined into a multi-model ensemble prediction, using simple un-weighted averaging. The probabilistic forecasts produced by the single-model system as well as the multi-model system have been tested against observed rainfall data over 3 austral summer 6-month periods from 2006/07 to 2008/09, using the Brier skill score, relative operating characteristics, and the reliability diagram. The forecast system was found to be more skilful than the persistence forecast. Moreover, the system outscores the forecast skill of the individual models.
Highlights
Precipitation forecasts are of high relevance to users of meteor ological information in South Africa, but precipitation is highly variable in time and space, making it one of the most difficult meteorological variables to predict skilfully
The probabilistic forecasts produced by the single-model system as well as the multi-model system have been tested against observed rainfall data over 3 austral summer 6-month periods from 2006/07 to 2008/09, using the Brier skill score, relative operating characteristics, and the reliability diagram
Deterministic or best-guess forecasts are considered to be less reliable as the model integration-time increases, due to uncertainties that exist in the initial conditions as well as the internal error of the numerical model itself (Lorenz, 1963; Ebert, 2001; Stensrud et al, 2005; Theis et al, 2005)
Summary
Precipitation forecasts are of high relevance to users of meteor ological information in South Africa, but precipitation is highly variable in time and space, making it one of the most difficult meteorological variables to predict skilfully. Precipitation forecasts from NWP models are often provided in a deterministic manner. An accurate short-range numerical forecast is dependent on accurately describing the initial conditions (Kalnay, 2003). The reason for this dependency on accurate initial conditions stems from the chaotic and non-periodic characteristics of the atmosphere (Lorenz, 1963). Deterministic or best-guess forecasts are considered to be less reliable as the model integration-time increases, due to uncertainties that exist in the initial conditions as well as the internal error (physics and dynamics) of the numerical model itself (Lorenz, 1963; Ebert, 2001; Stensrud et al, 2005; Theis et al, 2005)
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