Seyedeh Atefeh Mohammadi scite author profile

Seyedeh Atefeh Mohammadi

4Publications

15Citation Statements Received

53Citation Statements Given

How they've been cited

How they cite others

127

Affiliations

Iran Meteorological Organization, Academic Center for Education, Culture and Research

Publications

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Comparison of the BMA and EMOS statistical methods for probabilistic quantitative precipitation forecasting

Javanshiri¹,

Fathi

Mohammadi

2021

Meteorological Applications

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The main approach to probabilistic weather forecasting has been the use of ensemble forecasting. In ensemble forecasting, the probability information is generally derived by using several numerical model runs, with perturbation of the initial conditions, physical schemes or dynamic core of the numerical weather prediction (NWP) models. However, ensemble forecasting usually tends to be under‐dispersive. Statistical post‐processing has, therefore, become an essential component of any ensemble prediction system aiming to improve the quality of numerical weather forecasts as they seek to generate calibrated and sharp predictive distributions of future weather quantities. Different versions of the ensemble model output statistics (EMOS) and the Bayesian model averaging (BMA) post‐processing methods are used in the present paper to calibrate 24, 48 and 72 hr forecasts of 24 hr accumulative precipitation. The ensemble employs the weather and research forecasting (WRF) model with eight different configurations which were run over Iran for six months (September 2015–February 2016). The results reveal that the BMA and EMOS‐censored, shifted gamma (CSG) techniques are substantially successful at improving the raw WRF ensemble forecasts; however, each approach improves different aspects of the forecast quality. The BMA method is more accurate, skilful and reliable than the EMOS‐CSG method, but has poorer discrimination. Moreover, it has better resolution in predicting the probability of high‐precipitation events than the EMOS‐CSG method.

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Comparison of spatial interpolation methods for gridded bias removal in surface temperature forecasts

Mohammadi¹,

Azadi

Rahmani

2017

J Meteorol Res

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Meta-heuristic CRPS minimization for the calibration of short-range probabilistic forecasts

Mohammadi

Rahmani

Azadi

2016

Meteorol Atmos Phys

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Optimization of continuous ranked probability score using PSO

Mohammadi¹,

Rahmani²,

Azadi³

2015

10.5267/j.dsl

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Weather forecast has been a major concern in various industries such as agriculture, aviation, maritime, tourism, transportation, etc. A good weather prediction may reduce natural disasters and unexpected events. This paper presents an empirical investigation to predict weather temperature using minimization of continuous ranked probability score (CRPS). The mean and standard deviation of normal density function are linear combination of the components of ensemble system. The resulted optimization model has been solved using particle swarm optimization (PSO) and the results are compared with Broyden-Fletcher-Goldfarb-Shanno (BFGS) method. The preliminary results indicate that the proposed PSO provides better results in terms of CRPS deviation criteria than the alternative BFGS method.

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