Evaluation of the ability of the Weather Research and Forecasting model to reproduce a sub-daily extreme rainfall event in Beijing, China using different domain configurations and spin-up times

Chu, Qing; Xu, Zongxue; Chen, Yiheng; Han, Dawei

doi:10.5194/hess-22-3391-2018

Cited by 22 publications

(19 citation statements)

References 54 publications

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“…Hal ini dikarenakan hujan merupakan parameter yang paling akhir diperhitungkan pada model setelah melewati proses panjang di atmosfer seperti pemanasan, penguapan, dan pembentukan awan. Selain itu pada perhitungan model terdapat hal-hal yang membatasi prediktabilitas hujan seperti penggunaan paremeterisasi kumulus dan mikrofisik awan (Stensrud et al, 2015) serta lama waktu spin-up time (Chu, Q. et. al., 2018).…”

Section: Evaluasi Kinerja Model Wrfunclassified

Investigasi Pengaruh Skenario Modifikasi Urbanisasi pada Perubahan Hujan di Kota Makassar

Sari

Atsidiqi²

2020

Prosiding SNFA

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Abstract: Urbanization affects the atmosphere through the urban heat island (UHI) process, resulting in the change of rain patterns over urban areas. Makassar as the one of big cities in Indonesia is assumed to be suffering from this effect, thus an investigation related to the issue needs to be done. This study contains a simulation of urbanization scenarios using a three-dimensional non-hydrostatic Weather Research and Forecasting (WRF) Model during the transition monsoon period: September-October-November (SON) 2014-2018. The study covers 5 selected heavy-rain-event during the SON period: 24 September 2016, 9 October 2016, 24 October 2016, 22 November 2016, and 23 September 2017. Result shows that the model is able to simulate some weather parameters with relatively small root-mean-square-error (RMSE) and high correlation on three rain event cases. Afterwards, scenarios of 25% and 50% increasing urban area towards Makassar coastal line (as reclamation plan) and existing urban areas have been done. The results show that urbanization increases daily average temperature over urban areas, so does UHI maximum reach number of 1.5°C for both scenarios on 24 September 2016 rain event. Also, it increases rain accumulation up to 50% over reclamation areas and relativeky decreases rainfall over existing urban areas. Abstrak: Peningkatan jumlah penduduk dan kegiatan urbanisasi dapat mengubah interaksi atmosfer melalui penambahan pelepasan panas yang menyebabkan terjadinya efek urban heat islands (UHI) serta perubahan hujan di wilayah perkotaan. Sebagai salah satu kota metropolitan di Indonesia, Makassar dimungkinkan terdampak oleh efek UHI tersebut. Sehingga penelitian ini dilakukan untuk mengetahui dampak urbanisasi terhadap perubahan akumulasi dan/atau pola hujan di wilayah Makassar sesuai skenario jumlah penduduk tahun 2045. Investigasi dilakukan dengan memanfaatkan model non-hidrostatik tiga dimensi Weather Research and Forecasting (WRF) pada musim transisi September-Oktober-November (SON) 2014-2018. Kejadian hujan lebat terpilih sebanyak 5 hari yakni tanggal 24 September 2016, 9 Oktober 2016, 24 Oktober 2016, 22 November 2016, dan 23 September 2017. Verifikasi model dilakukan dengan menggunakan metode statistik. Hasilnya, model mampu digunakan untuk mensimulasikan tiga dari lima kejadian hujan lebat dengan nilai RMSE relatif rendah dan korelasi tinggi. Selanjutnya, skenario modifikasi dilakukan dengan menambahkan wilayah urban sebesar 25% dan 50% untuk masing-masing area di bagian pantai (sesuai rencana reklamasi) dan taman kota. Dari hasil simulasi hujan lebat tanggal 24 September 2016 diketahui bahwa urbanisasi meningkatkan rataan suhu harian wilayah perkotaan yang menyebabakan UHI maksimum meningkat antara 0.1° hingga 1.5°C pada dua skenario modifikasi. Selain itu skenario modifikasi urbanisasi menyebabkan peningkatan hujan sebesar 50% di area reklamasi dan cenderung normal bahkan mengalami penurunan di wilayah taman kota sekitar Universitas Hasanuddin.

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Section: Evaluasi Kinerja Model Wrfunclassified

Investigasi Pengaruh Skenario Modifikasi Urbanisasi pada Perubahan Hujan di Kota Makassar

Sari

Atsidiqi²

2020

Prosiding SNFA

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“…All domains were comprised of 28 vertical pressure levels with the top level set at 50 hPa according to the WRF guidelines. The WRF model runs with longer spin-up times could lead to better rainfall simulation, given better initial weather conditions (Chu et al, 2018). Following the recommendations of previous studies (Chu et al, 2018;Kleczek et al, 2014), a spinup time of 12 h is adopted for each forecast in the present study to run the WRF model.…”

Section: Wrf Model Configurationmentioning

confidence: 99%

“…The WRF model runs with longer spin-up times could lead to better rainfall simulation, given better initial weather conditions (Chu et al, 2018). Following the recommendations of previous studies (Chu et al, 2018;Kleczek et al, 2014), a spinup time of 12 h is adopted for each forecast in the present study to run the WRF model. By considering that high-resolution NWP forecasts are significantly sensitive to different microphysics parameterizations (Cintineo et al, 2014;Morrison et al, 2015), the current study implements three partially or completely double-moment cloud microphysics schemes to run the WRF model.…”

Section: Wrf Model Configurationmentioning

confidence: 99%

Sensitivity analysis of raindrop size distribution parameterizations in WRF rainfall simulation

Yang

Dai

Han

et al. 2019

Atmospheric Research

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Numerical weather models such as WRF (Weather Research and Forecasting) are increasingly used in studies on water resources. However, they have suffered from relatively poor performance in rainfall estimation. Among the various influential factors, a critical parameter in the WRF model rainfall retrieval is raindrop size distribution (DSD), which has not been fully explored. The analysis of sensitivity and uncertainty of the DSD model accuracy is significant for rainfall forecasts based on mesoscale numerical weather prediction (NWP) models. A WRF-disdrometer integrated error assessment framework is developed to analyze the accuracy and sensitivity of DSD parameterizations of gamma distribution in WRF rainfall simulation. This study adopts three different microphysics parameterizations (Morrison, WDM6, and Thompson aerosol-aware) to simulate the DSD of approximately one hundred rainfall events in Chilbolton, UK that are categorized into 12 scenarios based on the season, rainfall evenness, and rainfall rate. The Thompson aerosol-aware microphysics scheme shows the best performance among the three. In comparisons of WRF rainfall simulations across different scenarios of evenness and rainfall rate, a higher accuracy is obtained with more even rain and a higher rainfall rate. The sensitivity results of different DSD parameterizations indicate that the sensitivity to the intercept parameter 0 is pronouncedly higher than those to the shape parameter μ and slope parameter λ for all studied schemes. The overall WRF rainfall shows a trend of slight underestimation followed by overestimation as μ increases; further, the rainfall is overestimated when 10 0 or λ decreases and is underestimated when it increases and then remains constant. Comparisons of different scenarios reveal that variations of DSD parameters of even rain have a relatively high impact on rainfall recognizability, and the DSD parameterizations show a higher sensitivity for rainfall with a low rate. Moreover, the sensitivity discrimination is not clear among the rainfall of different seasons. The uncertainty assessment of the WRF rainfall retrieval caused by the shape parameter suggests that a gamma DSD model with a variable shape parameter should be developed according to the evenness, rainfall rate, and microphysics parameterizations by using the WRF model. Some modified algorithms of the WRF gamma DSD model for achieving better accuracy in WRF rainfall retrievals will be explored in future studies with various climatic regimes by adjusting the DSD parameterization based on the assimilation of measured data.

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“…After years of development, the current short-term and medium-term NWP models have become more and more accurate. However, for rainfall nowcasting, it is difficult to give accurate forecast results due to spin-up [ 5 ] and other problems in NWP models.…”

Section: Introductionmentioning

confidence: 99%

RN-Net: A Deep Learning Approach to 0–2 Hour Rainfall Nowcasting Based on Radar and Automatic Weather Station Data

Zhang

Wang

Guan

et al. 2021

Sensors

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Precipitation has an important impact on people’s daily life and disaster prevention and mitigation. However, it is difficult to provide more accurate results for rainfall nowcasting due to spin-up problems in numerical weather prediction models. Furthermore, existing rainfall nowcasting methods based on machine learning and deep learning cannot provide large-area rainfall nowcasting with high spatiotemporal resolution. This paper proposes a dual-input dual-encoder recurrent neural network, namely Rainfall Nowcasting Network (RN-Net), to solve this problem. It takes the past grid rainfall data interpolated by automatic weather stations and doppler radar mosaic data as input data, and then forecasts the grid rainfall data for the next 2 h. We conduct experiments on the Southeastern China dataset. With a threshold of 0.25 mm, the RN-Net’s rainfall nowcasting threat scores have reached 0.523, 0.503, and 0.435 within 0.5 h, 1 h, and 2 h. Compared with the Weather Research and Forecasting model rainfall nowcasting, the threat scores have been increased by nearly four times, three times, and three times, respectively.

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Evaluation of the ability of the Weather Research and Forecasting model to reproduce a sub-daily extreme rainfall event in Beijing, China using different domain configurations and spin-up times

Cited by 22 publications

References 54 publications

Investigasi Pengaruh Skenario Modifikasi Urbanisasi pada Perubahan Hujan di Kota Makassar

Investigasi Pengaruh Skenario Modifikasi Urbanisasi pada Perubahan Hujan di Kota Makassar

Sensitivity analysis of raindrop size distribution parameterizations in WRF rainfall simulation

RN-Net: A Deep Learning Approach to 0–2 Hour Rainfall Nowcasting Based on Radar and Automatic Weather Station Data

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