NGFS rainfall forecast verification over India using the contiguous rain area (CRA) method

Abstract The contiguous rain area (CRA) method for spatial forecast verification is a features-based approach that evaluates the properties of forecast rain systems, namely, their location, size, intensity, and finescale pattern. It is one of many recently developed spatial verification approaches that are being evaluated as part of a Spatial Forecast Verification Methods Intercomparison Project. To better understand the strengths and weaknesses of the CRA method, it has been tested here on a set of idealized geometric and perturbed forecasts with known errors, as well as nine precipitation forecasts from three high-resolution numerical weather prediction models. The CRA method was able to identify the known errors for the geometric forecasts, but only after a modification was introduced to allow nonoverlapping forecast and observed features to be matched. For the perturbed cases in which a radar rain field was spatially translated and amplified to simulate forecast errors, the CRA method also reproduced the known errors except when a high-intensity threshold was used to define the CRA (≥10 mm h−1) and a large translation error was imposed (>200 km). The decomposition of total error into displacement, volume, and pattern components reflected the source of the error almost all of the time when a mean squared error formulation was used, but not necessarily when a correlation-based formulation was used. When applied to real forecasts, the CRA method gave similar results when either best-fit criteria, minimization of the mean squared error, or maximization of the correlation coefficient, was chosen for matching forecast and observed features. The diagnosed displacement error was somewhat sensitive to the choice of search distance. Of the many diagnostics produced by this method, the errors in the mean and peak rain rate between the forecast and observed features showed the best correspondence with subjective evaluations of the forecasts, while the spatial correlation coefficient (after matching) did not reflect the subjective judgments.

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ACCURACY EVALUATION OF PREDICTING TIMES OF ISSUES OF THE TRAIN OPERATION CONTROL USING RAINFALL FORECAST INFORMATION

Journal of Japan Society of Civil Engineers Ser B1 (Hydraulic Engineering) ◽

10.2208/jscejhe.75.2_i_121 ◽

2019 ◽

Vol 75 (2) ◽

pp. I_121-I_126

Author(s):

Yohei NAKABUCHI ◽

Hiroto SUZUKI ◽

Chiho KIMPARA ◽

Satoru ENDO ◽

Eiichi NAKAKITA

Keyword(s):

Accuracy Evaluation ◽

Rainfall Forecast ◽

Train Operation ◽

Operation Control

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The Development of a Quantitative Precipitation Forecast Correction Technique Based on Machine Learning for Hydrological Applications

Atmosphere ◽

10.3390/atmos11010111 ◽

2020 ◽

Vol 11 (1) ◽

pp. 111 ◽

Cited By ~ 2

Author(s):

Chul-Min Ko ◽

Yeong Yun Jeong ◽

Young-Mi Lee ◽

Byung-Sik Kim

Keyword(s):

Machine Learning ◽

Heavy Rainfall ◽

Extreme Rainfall ◽

Machine Learning Techniques ◽

Precipitation Forecast ◽

Machine Learning Technique ◽

Rainfall Forecast ◽

Quantitative Precipitation Forecast ◽

Correction Technique ◽

Learning Technique

This study aimed to enhance the accuracy of extreme rainfall forecast, using a machine learning technique for forecasting hydrological impact. In this study, machine learning with XGBoost technique was applied for correcting the quantitative precipitation forecast (QPF) provided by the Korea Meteorological Administration (KMA) to develop a hydrological quantitative precipitation forecast (HQPF) for flood inundation modeling. The performance of machine learning techniques for HQPF production was evaluated with a focus on two cases: one for heavy rainfall events in Seoul and the other for heavy rainfall accompanied by Typhoon Kong-rey (1825). This study calculated the well-known statistical metrics to compare the error derived from QPF-based rainfall and HQPF-based rainfall against the observational data from the four sites. For the heavy rainfall case in Seoul, the mean absolute errors (MAE) of the four sites, i.e., Nowon, Jungnang, Dobong, and Gangnam, were 18.6 mm/3 h, 19.4 mm/3 h, 48.7 mm/3 h, and 19.1 mm/3 h for QPF and 13.6 mm/3 h, 14.2 mm/3 h, 33.3 mm/3 h, and 12.0 mm/3 h for HQPF, respectively. These results clearly indicate that the machine learning technique is able to improve the forecasting performance for localized rainfall. In addition, the HQPF-based rainfall shows better performance in capturing the peak rainfall amount and spatial pattern. Therefore, it is considered that the HQPF can be helpful to improve the accuracy of intense rainfall forecast, which is subsequently beneficial for forecasting floods and their hydrological impacts.

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Impact of INSAT-3D radiance data assimilation using WRF 3DVAR on simulation of Indian summer monsoon and high-resolution rainfall forecast over hilly terrain

Natural Hazards ◽

10.1007/s11069-021-04833-3 ◽

2021 ◽

Author(s):

Rekha Bharali Gogoi ◽

S. S. Kundu ◽

P. L. N. Raju

Keyword(s):

High Resolution ◽

Data Assimilation ◽

Summer Monsoon ◽

Indian Summer Monsoon ◽

Hilly Terrain ◽

Rainfall Forecast ◽

Radiance Data

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Rainfall forecast errors in different landfall stages of Super Typhoon Lekima (2019)

Frontiers of Earth Science ◽

10.1007/s11707-021-0894-9 ◽

2021 ◽

Author(s):

Bin He ◽

Zifeng Yu ◽

Yan Tan ◽

Yan Shen ◽

Yingjun Chen

Keyword(s):

Forecast Errors ◽

Super Typhoon ◽

Rainfall Forecast

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Rainfall forecast and computer data algorithm optimization in coastal areas based on improved neural network

Arabian Journal of Geosciences ◽

10.1007/s12517-021-07579-1 ◽

2021 ◽

Vol 14 (15) ◽

Author(s):

Jingzhu Wu ◽

Xiuzhi Xing

Keyword(s):

Neural Network ◽

Coastal Areas ◽

Algorithm Optimization ◽

Computer Data ◽

Rainfall Forecast

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Analysis of scale dependence of quantitative precipitation forecast verification: A case-study over the Mackenzie river basin Olivier Bousquet, Charles A. Lin and Isztar Zawadzki.Quarterly Journal of the Royal Meteorological Society, 132: 2107–2125

Quarterly Journal of the Royal Meteorological Society ◽

10.1002/qj.180 ◽

2008 ◽

Vol 134 (630) ◽

Keyword(s):

River Basin ◽

Scale Dependence ◽

Precipitation Forecast ◽

Forecast Verification ◽

Quantitative Precipitation Forecast ◽

Mackenzie River Basin ◽

Mackenzie River

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A spatial–temporal projection model for 10–30 day rainfall forecast in South China

Climate Dynamics ◽

10.1007/s00382-014-2215-4 ◽

2014 ◽

Vol 44 (5-6) ◽

pp. 1227-1244 ◽

Cited By ~ 27

Author(s):

Pang-Chi Hsu ◽

Tim Li ◽

Lijun You ◽

Jianyun Gao ◽

Hong-Li Ren

Keyword(s):

South China ◽

Projection Model ◽

Rainfall Forecast

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Intercomparison of Spatial Forecast Verification Methods: Identifying Skillful Spatial Scales Using the Fractions Skill Score

Weather and Forecasting ◽

10.1175/2009waf2222260.1 ◽

2010 ◽

Vol 25 (1) ◽

pp. 343-354 ◽

Cited By ~ 100

Author(s):

Marion Mittermaier ◽

Nigel Roberts

Keyword(s):

Spatial Scales ◽

Wrf Model ◽

Skill Score ◽

Area Ratio ◽

Forecast Verification ◽

Care Needs ◽

Forecast Performance ◽

Verification Methods ◽

Upper Level ◽

Formed Part

Abstract The fractions skill score (FSS) was one of the measures that formed part of the Intercomparison of Spatial Forecast Verification Methods project. The FSS was used to assess a common dataset that consisted of real and perturbed Weather Research and Forecasting (WRF) model precipitation forecasts, as well as geometric cases. These datasets are all based on the NCEP 240 grid, which translates to approximately 4-km resolution over the contiguous United States. The geometric cases showed that the FSS can provide a truthful assessment of displacement errors and forecast skill. In addition, the FSS can be used to determine the scale at which an acceptable level of skill is reached and this usage is perhaps more helpful than interpreting the actual FSS value. This spatial-scale approach is becoming more popular for monitoring operational forecast performance. The study also shows how the FSS responds to forecast bias. A more biased forecast always gives lower FSS values at large scales and usually at smaller scales. It is possible, however, for a more biased forecast to give a higher score at smaller scales, when additional rain overlaps the observed rain. However, given a sufficiently large sample of forecasts, a more biased forecast system will score lower. The use of percentile thresholds can remove the impacts of the bias. When the proportion of the domain that is “wet” (the wet-area ratio) is small, subtle differences introduced through near-threshold misses can lead to large changes in FSS magnitude in individual cases (primarily because the bias is changed). Reliable statistics for small wet-area ratios require a larger sample of forecasts. Care needs to be taken in the choice of verification domain. For high-resolution models, the domain should be large enough to encompass the length scale of the typical mesoscale forcing (e.g., upper-level troughs or squall lines). If the domain is too large, the wet-area ratios will always be small. If the domain is too small, fluctuations in the wet-area ratio can be large and larger spatial errors may be missed. The FSS is a good measure of the spatial accuracy of precipitation forecasts. Different methods are needed to determine other patterns of behavior.

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