Gridded Hourly Precipitation Analysis from High-Density Rain Gauge Network over the Yangtze–Huai Rivers Basin during the 2007 Mei-Yu Season and Comparison with CMORPH

Abstract Heavy rainfall hit the Yangtze–Huai Rivers basin (YHRB) of east China several times during the prolonged 2007 mei-yu season, causing the worst flood since 1954. There has been an urgent need for attaining and processing high-quality, kilometer-scale, hourly rainfall data in order to understand the mei-yu precipitation processes, especially at the mesoβ and smaller scales. In this paper, the authors describe the construction of the 0.07°-resolution gridded hourly rainfall analysis over the YHRB region during the 2007 mei-yu season that is based on surface reports at 555 national and 6572 regional automated weather stations with an average resolution of about 7 km. The gridded hourly analysis is obtained using a modified Cressman-type objective analysis after applying strict quality control, including not only the commonly used internal temporal and spatial consistency and extreme value checks, but also verifications against mosaic radar reflectivity data. This analysis reveals many convectively generated finescale precipitation structures that could not be seen from the national station reports. A comprehensive quantitative assessment ensures the quality of the gridded hourly precipitation data. A comparison of this dataset with the U.S. Climate Prediction Center morphing technique (CMORPH) dataset on the same resolution suggests the dependence of the latter's performance on different rainfall intensity categories, with substantial underestimation of the magnitude and width of the mei-yu rainband as well as the nocturnal and morning peak rainfall amounts, due mainly to its underestimating the occurrences of heavy rainfall (i.e., >10 mm h−1).

Download Full-text

Mesoscale and Local Scale Evaluations of Quantitative Precipitation Estimates by Weather Radar Products during a Heavy Rainfall Event

Advances in Meteorology ◽

10.1155/2016/6089319 ◽

2016 ◽

Vol 2016 ◽

pp. 1-9 ◽

Cited By ~ 6

Author(s):

Basile Pauthier ◽

Benjamin Bois ◽

Thierry Castel ◽

D. Thévenin ◽

Carmela Chateau Smith ◽

...

Keyword(s):

High Resolution ◽

Heavy Rainfall ◽

Rain Gauge ◽

Local Scale ◽

Rainfall Event ◽

Heavy Rainfall Event ◽

Preliminary Evaluation ◽

Rainfall Variation ◽

Hourly Rainfall ◽

Rain Gauge Network

A 24-hour heavy rainfall event occurred in northeastern France from November 3 to 4, 2014. The accuracy of the quantitative precipitation estimation (QPE) by PANTHERE and ANTILOPE radar-based gridded products during this particular event, is examined at both mesoscale and local scale, in comparison with two reference rain-gauge networks. Mesoscale accuracy was assessed for the total rainfall accumulated during the 24-hour event, using the Météo France operational rain-gauge network. Local scale accuracy was assessed for both total event rainfall and hourly rainfall accumulations, using the recently developed HydraVitis high-resolution rain gauge network Evaluation shows that (1) PANTHERE radar-based QPE underestimates rainfall fields at mesoscale and local scale; (2) both PANTHERE and ANTILOPE successfully reproduced the spatial variability of rainfall at local scale; (3) PANTHERE underestimates can be significantly improved at local scale by merging these data with rain gauge data interpolation (i.e., ANTILOPE). This study provides a preliminary evaluation of radar-based QPE at local scale, suggesting that merged products are invaluable for applications at very high resolution. The results obtained underline the importance of using high-density rain-gauge networks to obtain information at high spatial and temporal resolution, for better understanding of local rainfall variation, to calibrate remotely sensed rainfall products.

Download Full-text

Synoptic Situations of Extreme Hourly Precipitation over China

Journal of Climate ◽

10.1175/jcli-d-16-0057.1 ◽

2016 ◽

Vol 29 (24) ◽

pp. 8703-8719 ◽

Cited By ~ 34

Author(s):

Yali Luo ◽

Mengwen Wu ◽

Fumin Ren ◽

Jian Li ◽

Wai-Kin Wong

Keyword(s):

Regional Distribution ◽

Extreme Rainfall ◽

Northern China ◽

Rain Gauge ◽

Synoptic Type ◽

Shear Line ◽

Hourly Precipitation ◽

The North ◽

Hourly Rainfall ◽

Reflectivity Data

Abstract In this study, synoptic situations associated with extreme hourly precipitation over China are investigated using rain gauge data, weather maps, and composite radar reflectivity data. Seasonal variations of hourly precipitation (>0.1 mm h−1) suggest complicated regional features in the occurrence frequency and intensity of rainfall. The 99.9th percentile is thus used as the threshold to define the extreme hourly rainfall for each station. The extreme rainfall is the most intense over the south coastal areas and the North China Plain. About 77% of the extreme rainfall records occur in summer with a peak in July (30.4%) during 1981–2013. Nearly 5800 extreme hourly rainfall records in 2011–15 are classified into four types according to the synoptic situations under which they occur: the tropical cyclone (TC), surface front, vortex/shear line, and weak-synoptic forcing. They contribute 8.0%, 13.9%, 39.1%, and 39.0%, respectively, to the total occurrence and present distinctive characteristics in regional distribution and seasonal or diurnal variations. The TC type occurs most frequently along the coasts and decreases progressively toward inland China; the frontal type is distributed relatively evenly east of 104°E; the vortex/shear line type shows a prominent center over the Sichuan basin with two high-frequency bands extending from the center southeastward and northeastward, respectively; and the weak-synoptic type occurs more frequently in southeast, southwest, and northern China, and in the easternmost area of northeast China. Occurrences of the weak-synoptic type have comparable contributions from mesoscale convective systems and smaller-scale storms with notable differences in their preferred locations.

Download Full-text

A Comparison Between Global Satellite Mapping of Precipitation Data and High-Resolution Radar Data – A Case Study of Localized Torrential Rainfall over Japan

Journal of Disaster Research ◽

10.20965/jdr.2021.p0786 ◽

2021 ◽

Vol 16 (4) ◽

pp. 786-793

Author(s):

Yoshiaki Hayashi ◽

Taichi Tebakari ◽

Akihiro Hashimoto ◽

◽

Keyword(s):

High Resolution ◽

Heavy Rainfall ◽

Daily Rainfall ◽

Radar Data ◽

Rain Gauge ◽

Hourly Rainfall ◽

The Difference ◽

Microwave Imager ◽

Satellite Mapping

This paper presents a case study comparing the latest algorithm version of Global Satellite Mapping of Precipitation (GSMaP) data with C-band and X-band Multi-Parameter (MP) radar as high-resolution rainfall data in terms of localized heavy rainfall events. The study also obliged us to clarify the spatial and temporal resolution of GSMaP data using high-accuracy ground-based radar, and evaluate the performance and reporting frequency of GSMaP satellites. The GSMaP_Gauge_RNL data with less than 70 mm/day of daily rainfall was similar to the data of both radars, but the GSMaP_Gauge_RNL data with over 70 mm/day of daily rainfall was not, and the calibration by rain-gauge data was poor. Furthermore, both direct/indirect observations by the Global Precipitation Measurement/Microwave Imager (GPM/GMI) and the frequency thereof (once or twice) significantly affected the difference between GPM/GMI data and C-band radar data when the daily rainfall was less than 70 mm/day and the hourly rainfall was less than 20 mm/h. Therefore, it is difficult for GSMaP_Gauge to accurately estimate localized heavy rainfall with high-density particle precipitation.

Download Full-text

Evaluation of the High-Resolution CMORPH Satellite Rainfall Product Using Dense Rain Gauge Observations and Radar-Based Estimates

Journal of Hydrometeorology ◽

10.1175/jhm-d-12-017.1 ◽

2012 ◽

Vol 13 (6) ◽

pp. 1784-1798 ◽

Cited By ~ 65

Author(s):

Emad Habib ◽

Alemseged Tamiru Haile ◽

Yudong Tian ◽

Robert J. Joyce

Keyword(s):

Rain Gauge ◽

Random Errors ◽

Event Scale ◽

Entire Study ◽

Rain Gauges ◽

Fine Resolution ◽

Rain Rates ◽

Climate Prediction Center ◽

Rain Gauge Network ◽

Insight Into

Abstract This study focuses on the evaluation of the NOAA–NCEP Climate Prediction Center (CPC) morphing technique (CMORPH) satellite-based rainfall product at fine space–time resolutions (1 h and 8 km). The evaluation was conducted during a 28-month period from 2004 to 2006 using a high-quality experimental rain gauge network in southern Louisiana, United States. The dense arrangement of rain gauges allowed for multiple gauges to be located within a single CMORPH pixel and provided a relatively reliable approximation of pixel-average surface rainfall. The results suggest that the CMORPH product has high detection skills: the probability of successful detection is ~80% for surface rain rates >2 mm h−1 and probability of false detection <3%. However, significant and alarming missed-rain and false-rain volumes of 21% and 22%, respectively, were reported. The CMORPH product has a negligible bias when assessed for the entire study period. On an event scale it has significant biases that exceed 100%. The fine-resolution CMORPH estimates have high levels of random errors; however, these errors get reduced rapidly when the estimates are aggregated in time or space. To provide insight into future improvements, the study examines the effect of temporal availability of passive microwave rainfall estimates on the product accuracy. The study also investigates the implications of using a radar-based rainfall product as an evaluation surface reference dataset instead of gauge observations. The findings reported in this study guide future enhancements of rainfall products and increase their informed usage in a variety of research and operational applications.

Download Full-text

On CMORPH Rainfall for Streamflow Simulation in a Small, Hortonian Watershed

Journal of Hydrometeorology ◽

10.1175/2010jhm1270.1 ◽

2011 ◽

Vol 12 (3) ◽

pp. 456-466 ◽

Cited By ~ 13

Author(s):

Dawit A. Zeweldi ◽

Mekonnen Gebremichael ◽

Charles W. Downer

Keyword(s):

Peak Flow ◽

Rain Gauge ◽

Rainfall Data ◽

Rain Gauge Data ◽

Small Watersheds ◽

Hydrologic Analysis ◽

Comparable Performance ◽

Climate Prediction Center ◽

Rain Gauge Network ◽

Streamflow Simulation

Abstract The objective is to assess the use of the Climate Prediction Center morphing method (CMORPH) (~0.073° latitude–longitude, 30 min resolution) rainfall product as input to the physics-based fully distributed Gridded Surface–Subsurface Hydrologic Analysis (GSSHA) model for streamflow simulation in the small (21.4 km2) Hortonian watershed of the Goodwin Creek experimental watershed located in northern Mississippi. Calibration is performed in two different ways: using rainfall data from a dense network of 30 gauges as input, and using CMORPH rainfall data as input. The study period covers 4 years, during which there were 24 events, each with peak flow rate higher than 0.5 m3 s−1. Streamflow simulations using CMORPH rainfall are compared against observed streamflows and streamflow simulations using rainfall from a dense rain gauge network. Results show that the CMORPH simulations captured all 24 events. The CMORPH simulations have comparable performance with gauge simulations, which is striking given the significant differences in the spatial scale between the rain gauge network and CMORPH. This study concludes that CMORPH rainfall products have potential value for streamflow simulation in such small watersheds. Overall, the performance of CMORPH-driven simulations increases when the model is calibrated with CMORPH data than when the model is calibrated with rain gauge data.

Download Full-text

Comprehensive evaluation of precipitation analyses using a very dense rain gauge network in southeast Austria

10.5194/egusphere-egu2020-16576 ◽

2020 ◽

Author(s):

Esmail Ghaemi ◽

Ulrich Foelsche ◽

Alexander Kann ◽

Gottfried Kirchengast ◽

Juergen Fuchsberger

Keyword(s):

Temporal Resolution ◽

Comprehensive Evaluation ◽

Analysis Data ◽

Radar Data ◽

Rain Gauge ◽

Accurate Estimation ◽

Wet Season ◽

Rainfall Events ◽

Rainfall Analysis ◽

Rain Gauge Network

Precipitation is one of the most important inputs of meteorological and hydrological models and also flood warning systems. Thus, accurate estimation of rainfall is essential for improving the reliability of the models and systems. Although remote sensing (RS) techniques for rainfall estimation (e.g., weather radars and satellite microwave imagers) have improved significantly over the last decades, rain gauges are still more reliable and widely used for this purpose and also for the evaluation of RS estimates. Since the characteristics of a rainfall event can change rapidly in space and time, the accuracy of rain gauge estimation is highly dependent on the spatial and temporal resolution of the gauge network.The main aim of this study is to evaluate the ability of the Integrated Nowcasting through Comprehensive Analysis (INCA) of the Central Institute for Meteorology and Geodynamics (ZAMG) to detect and estimate rainfall events. This is done by using 12 years of data from a very dense rain gauge network, the WegenerNet Feldbach region, as a reference, and comparing its data to the INCA analyses. INCA rainfall analysis data are based on a combination of ZAMG ground station data, weather radar data, and high-resolution topographic data. The system provides precipitation rate data with a 1 km spatial grid resolution and 15 minutes temporal resolution. The WegenerNet includes 155 ground stations, almost uniformly spread over a moderate hilly orography area of about 22 km &#215; 16 km.After removing outliers and scale WegenerNet data to 1 km, the accuracy of INCA to detect and estimate rainfall events was investigated using 12 years of the dataset. The results show that INCA can detect rainfall events relatively well. It was found that INCA overestimates the rainfall amount between 2012 and 2014, and generally overestimates precipitation for light rainfall events. For heavy rainfall events, however, an underestimation of INCA is prominent in most events. Based on the results, the difference between INCA and WegenerNet estimates is relatively higher during the wet season in the summer half-year (May-September). It is worth pointing out that INCA performs better in detecting and estimating rainfall around the two ZAMG stations located within the study area.

Download Full-text

Wavelet Filter Approach andZ-RRelationship in Meteorological Forecasting

Advances in Meteorology ◽

10.1155/2015/858717 ◽

2015 ◽

Vol 2015 ◽

pp. 1-12

Author(s):

Wallop Jiwlong ◽

Anongrit Kangrang

Keyword(s):

Rain Gauge ◽

Wavelet Filter ◽

Filtration Process ◽

Wavelet Filters ◽

Calibration And Validation ◽

Filter Technique ◽

Proposed Model ◽

Hourly Rainfall ◽

Filter Approach ◽

Reflectivity Data

The purpose of this study is to investigate theZ-Rrelationship for computing rainfall using conventional and wavelet filters technique. Wavelet filter technique was applied to data filtration process. The proposed model was applied to determine the rainfall of five rain gauge meteorological stations in Thailand. The three-hourly rainfall and radar reflectivity data were used in this study. The results indicated that the accumulative rainfall of wavelet filters technique was close to the observed rainfall data more than the results of conventional practice for both calibration and validation processes. Consequently, we are confident that a wavelet filters technique is a useful tool for estimating the rainfall.

Download Full-text

Evaluation of CMPA precipitation estimate in the evolution of typhoon-related storm rainfall in Guangdong, China

Journal of Hydroinformatics ◽

10.2166/hydro.2016.241 ◽

2016 ◽

Vol 18 (6) ◽

pp. 1055-1068 ◽

Cited By ~ 12

Author(s):

Dashan Wang ◽

Xianwei Wang ◽

Lin Liu ◽

Dagang Wang ◽

Huabing Huang ◽

...

Keyword(s):

Correlation Coefficients ◽

Extreme Rainfall ◽

Heavy Rain ◽

Rain Gauge ◽

Probability Of Detection ◽

Spatiotemporal Evolution ◽

Light Rain ◽

Storm Rainfall ◽

Climate Prediction Center ◽

Rain Gauge Network

The merged precipitation data of Climate Prediction Center Morphing Technique and gauge observations (CMPA) generated for continental China has relatively high spatial and temporal resolution (hourly and 0.1°), while few studies have applied it to investigate the typhoon-related extreme rainfall. This study evaluates the CMPA estimate in quantifying the typhoon-related extreme rainfall using a dense rain gauge network in Guangdong Province, China. The results show that the event-total precipitation from CMPA is generally in agreement with gauges by relative bias (RB) of 2.62, 10.74 and 0.63% and correlation coefficients (CCs) of 0.76, 0.86 and 0.91 for typhoon Utor, Usagi and Linfa events, respectively. At the hourly scale, CMPA underestimates the occurrence of light rain (<1 mm/h) and heavy rain (>16 mm/h), while overestimates the occurrence of moderate rain. CMPA shows high probability of detection (POD = 0.93), relatively large false alarm ratio (FAR = 0.22) and small missing ratio (0.07). CMPA captures the spatial patterns of typhoon-related rain depth, and is in agreement with the spatiotemporal evolution of hourly gauge observations by CC from 0.93 to 0.99. In addition, cautiousness should be taken when applying it in hydrologic modeling for flooding forecasting since CMPA underestimates heavy rain (>16 mm/h).

Download Full-text

A case of severe flood over Albania: a rainfall analysis from a satellite perspective

Advances in Geosciences ◽

10.5194/adgeo-7-65-2006 ◽

2006 ◽

Vol 7 ◽

pp. 65-72 ◽

Cited By ~ 2

Author(s):

A. De Luque ◽

T. Porja ◽

A. Martín ◽

J. A. Guijarro ◽

S. Alonso

Keyword(s):

Rain Rate ◽

Daily Rainfall ◽

Rain Gauge ◽

Convective Rainfall ◽

Infrared Band ◽

Rainfall Analysis ◽

Convective Clouds ◽

Severe Flood ◽

Rain Gauge Network ◽

Cloud Top Temperature

Abstract. This paper presents results of daily rainfall estimates for the flood event in Albania occurred during the end of September 2002 (from the 21 until the 23). Estimated precipitations based on Meteosat-7 data and computed using various techniques, are compared with surface based observations. The two techniques, developed for convective clouds, were employed to screen the Albanian Flood. On one hand a single Infrared band technique known as Auto-estimator and on the other hand a three-channel Convective Rainfall Rate technique known as CRR. Secondly, for both methods, a number of corrections, such as, moisture, cloud growth rate, cloud top temperature gradient, parallax and orographic corrections were, also, performed and tested during the flood case. Preliminary results show that auto-estimator over-measure significantly daily rainfall with respect to the observed while CRR gives much closer rain quantities. The Auto-estimator power law curve was adjusted to the specific conditions using all the available rain rate gauge measurements. Satellite daily rainfall estimated by the two methods, corrected and calibrated were finally evaluated using the Albanian rain gauge network as ground true.

Download Full-text

Identification of the Optimum Rain Gauge Network Density for Hydrological Modelling Based on Radar Rainfall Analysis

Water ◽

10.3390/w12071906 ◽

2020 ◽

Vol 12 (7) ◽

pp. 1906

Author(s):

Yeboah Gyasi-Agyei

Keyword(s):

Scaling Laws ◽

Rain Gauge ◽

Hydrological Modelling ◽

Network Density ◽

Sampled Data ◽

Radar Rainfall ◽

Rainfall Analysis ◽

Rain Gauges ◽

Performance Statistics ◽

Rain Gauge Network

Rain gauges continue to be sources of rainfall data despite progress made in precipitation measurements using radar and satellite technology. There has been some work done on assessing the optimum rain gauge network density required for hydrological modelling, but without consensus. This paper contributes to the identification of the optimum rain gauge network density, using scaling laws and bias-corrected 1 km × 1 km grid radar rainfall records, covering an area of 28,371 km2 that hosts 315 rain gauges in south-east Queensland, Australia. Varying numbers of radar pixels (rain gauges) were repeatedly sampled using a unique stratified sampling technique. For each set of rainfall sampled data, a two-dimensional correlogram was developed from the normal scores obtained through quantile-quantile transformation for ordinary kriging which is a stochastic interpolation. Leave-one-out cross validation was carried out, and the simulated quantiles were evaluated using the performance statistics of root-mean-square-error and mean-absolute-bias, as well as their rates of change. A break in the scaling of the plots of these performance statistics against the number of rain gauges was used to infer the optimum rain gauge network density. The optimum rain gauge network density varied from 14 km2/gauge to 38 km2/gauge, with an average of 25 km2/gauge.

Download Full-text