Your search keyword '"Shang, Huazhe"' showing total 27 results

1. Cloud Top Pressure Retrieval Using Polarized and Oxygen A-band Measurements from GF5 and PARASOL Satellites

Author

Wei, Lesi, Shang, Huazhe, Xu, Jian, Shi, Chong, Tana, Gegen, Chao, Kefu, Bao, Shanhu, Chen, Liangfu, and Letu, Husi

Published

2024

2. A novel physics-based cloud retrieval algorithm based on neural networks (CRANN) from hyperspectral measurements in the O2-O2 band

Author

Wang, Wenwu, Letu, Husi, Shang, Huazhe, Xu, Jian, Yan, Huanhuan, Gao, Lianru, Yu, Chao, Gu, Jianbin, Tao, Jinhua, Xu, Na, Chen, Lin, and Chen, Liangfu

Published

2024

3. A hybrid cloud detection and cloud phase classification algorithm using classic threshold-based tests and extra randomized tree model

Author

Shang, Huazhe, Letu, Husi, Xu, Ri, Wei, Lesi, Wu, Laixiong, Shao, Jiangqi, Nagao, Takashi M., Nakajima, Takashi Y., Riedi, Jérôme, He, Jie, and Chen, Liangfu

Published

2024

4. Advancing Cloud Classification Over the Tibetan Plateau: A New Algorithm Reveals Seasonal and Diurnal Variations.

Author

Bao, Fangling, Letu, Husi, Shang, Huazhe, Ri, Xu, Chen, Deliang, Yao, Tandong, Wei, Lesi, Tang, Chenqian, Yin, Shuai, Ji, Dabin, Lei, Yonghui, Shi, Chong, Peng, Yiran, and Shi, Jiancheng

Subjects

DIURNAL cloud variations, CLASSIFICATION algorithms, GEOSTATIONARY satellites, SPRING, SEASONS

Abstract

The cloud classification algorithm widely used in the International Satellite Cloud Climatology Project (ISCCP) tends to underestimate low clouds over the Tibetan Plateau (TP), often mistaking water clouds for high‐level clouds. To address this issue, we propose a new algorithm based on cloud‐top temperature and optical thickness, which we apply to TP using Advanced Himawari Imager (AHI) geostationary satellite data. Compared with Clouds and the Earth's Radiant Energy System cloud‐type products and ISCCP results obtained from AHI data, this new algorithm markedly improved low‐cloud detection accuracy and better aligned with cloud phase results. Validation with lidar cloud‐type products further confirmed the superiority of this new algorithm. Diurnal cloud variations over the TP show morning dominance shifting to afternoon high clouds and evening mid‐level clouds. Winter is dominated by high clouds, summer by mid‐level clouds, spring by daytime low clouds and nighttime high clouds, and autumn by low and mid‐level clouds. Plain Language Summary: The accurate identification of low clouds over the Tibetan Plateau (TP) is crucial for climate regulation, ecosystems, aviation safety, research, and modeling. However, satellite‐based methods often miss these clouds, misclassifying them as high‐level clouds. To remedy this, we developed a new algorithm using cloud‐top temperature and optical thickness, applied to Advanced Himawari Imager data. This significantly improves low‐cloud detection, better aligning with actual cloud phases. Simultaneously, we analyzed diurnal cloud variations over the TP with the new algorithm. Cloud types at different altitudes in the TP exhibit strong seasonality. The dominant cloud types in winter and summer are high and mid‐level, respectively. In spring, low clouds dominate during the day (2:00–10:00 UTC), transitioning to high clouds at night (10:00–18:00 UTC), with mid‐level clouds prevailing at other times. In autumn, low clouds dominate during the day, transitioning to mid‐level clouds at other times, with fewer occurrences of high clouds. Key Points: Employing cloud‐top temperature instead of pressure resolves classification‐phase inconsistencies for clouds in the Tibetan Plateau (TP)Lidar validation shows new algorithm's low cloud detection outperforms the conventional International Satellite Cloud Climatology Project algorithm for both TP and plainsThe study reveals significant diurnal and seasonal variations in low clouds over the TP [ABSTRACT FROM AUTHOR]

Published

2024

5. Technical note: Retrieval of the supercooled liquid fraction in mixed-phase clouds from Himawari-8 observations.

Author

Wang, Ziming, Letu, Husi, Shang, Huazhe, and Bugliaro, Luca

Subjects

SUPERCOOLED liquids, CLIMATE sensitivity, TRACKING algorithms, REMOTE sensing, ICE clouds, RAIN-making, STRATOCUMULUS clouds, ICE

Abstract

The supercooled liquid fraction (SLF) in mixed-phase clouds (MPCs) is an essential variable of cloud microphysical processes and climate sensitivity. However, the SLF is currently calculated in spaceborne remote sensing only as the cloud phase–frequency ratio of adjacent pixels, which results in a loss of the original resolution in observations of cloud liquid or ice content within MPCs. Here, we present a novel method for retrieving the SLF in MPCs based on the differences in radiative properties of supercooled liquid droplets and ice particles at visible (VIS) and shortwave infrared (SWI) channels of the geostationary Himawari-8. Liquid and ice water paths are inferred by assuming that clouds are composed of only liquid or ice, with the real cloud water path (CWP) expressed as a combination of these two water paths (SLF and 1-SLF as coefficients), and the SLF is determined by referring to the CWP from Cloud-Aerosol Lidar and Infrared Pathfinder Satellite Observations (CALIPSO). The statistically relatively small cloud phase spatial inhomogeneity at a Himawari-8 pixel level indicates an optimal scene for cloud retrieval. The SLF results are comparable to global SLF distributions observed by active instruments, particularly for single-layered cloud systems. While accessing the method's feasibility, SLF averages are estimated between 74 % and 78 % in Southern Ocean (SO) stratocumulus across seasons, contrasting with a range of 29 % to 32 % in northeastern Asia. The former exhibits a minimum SLF around midday in summer and a maximum in winter, while the latter trend differs. This novel algorithm will be valuable for research to track the evolution of MPCs and constrain the related climate impact. [ABSTRACT FROM AUTHOR]

Published

2024

6. Cloud thermodynamic phase detection using a directional polarimetric camera (DPC)

Author

Shang, Huazhe, Letu, Husi, Chen, Liangfu, Riedi, Jérôme, Ma, Run, Wei, Lesi, Labonnote, Laurent C., Hioki, Souichiro, Liu, Chao, Wang, Zhongting, and Wang, Jianjie

Published

2020

7. High-resolution retrieval of cloud microphysical properties and surface solar radiation using Himawari-8/AHI next-generation geostationary satellite

Author

Letu, Husi, Yang, Kun, Nakajima, Takashi Y., Ishimoto, Hiroshi, Nagao, Takashi M., Riedi, Jérôme, Baran, Anthony J., Ma, Run, Wang, Tianxing, Shang, Huazhe, Khatri, Pradeep, Chen, Liangfu, Shi, Chunxiang, and Shi, Jiancheng

Published

2020

8. Estimation of shortwave solar radiation using the artificial neural network from Himawari-8 satellite imagery over China

Author

Peng, Zhong, Letu, Husi, Wang, Tianxing, Shi, Chong, Zhao, Chuanfeng, Tana, Gegen, Zhao, Naizhuo, Dai, Tie, Tang, Ronglin, Shang, Huazhe, Shi, Jiancheng, and Chen, Liangfu

Published

2020

9. A review of the estimation of downward surface shortwave radiation based on satellite data: Methods, progress and problems

Author

Letu, Husi, Shi, Jiancheng, Li, Ming, Wang, Tianxing, Shang, Huazhe, Lei, Yonghui, Ji, Dabin, Wen, Jianguang, Yang, Kun, and Chen, Liangfu

Published

2020

10. Cloud cover over the Tibetan Plateau and eastern China: a comparison of ERA5 and ERA-Interim with satellite observations

Author

Lei, Yonghui, Letu, Husi, Shang, Huazhe, and Shi, Jiancheng

Published

2020

11. Diurnal haze variations over the North China plain using measurements from Himawari-8/AHI

Author

Shang, Huazhe, Letu, Husi, Pan, Xiaole, Wang, Ziming, Ma, Run, Liu, Chao, Dai, Tie, Li, Shenshen, Chen, Liangfu, Chen, Cheng, and Hu, Qiaoyun

Published

2019

12. An improved algorithm of cloud droplet size distribution from POLDER polarized measurements

Author

Shang, Huazhe, Letu, Husi, Bréon, François-Marie, Riedi, Jérôme, Ma, Run, Wang, Ziming, Nakajima, Takashi Y., Wang, Zhongting, and Chen, Liangfu

Published

2019

13. Estimation of Top-of-Atmosphere Longwave Cloud Radiative Forcing Using FengYun-4A Geostationary Satellite Data.

Author

Xu, Ri, Zhao, Jun, Bao, Shanhu, Shang, Huazhe, Bao, Fangling, Tana, Gegen, and Wei, Lesi

Subjects

GEOSTATIONARY satellites, RADIATIVE forcing, RADIATION measurements, ENERGY budget (Geophysics), ELECTRONIC data processing, RADIATION

Abstract

The distribution and variation of top-of-atmosphere longwave cloud radiative forcing (LCRFTOA) has drawn a significant amount of attention due to its importance in understanding the energy budget. Advancements in sensor and data processing technology, as well as a new generation of geostationary satellites, such as the FengYun-4A (FY-4A), allow for high spatiotemporal resolutions that are crucial for real-time radiation monitoring. Nevertheless, there is a distinct lack of official top-of-atmosphere outgoing longwave radiation products under clear-sky conditions (OLRclear). Consequently, this study addresses the challenge of constructing LCRFTOA data with high spatiotemporal resolution over the full disk region of FY-4A. After simulating the influence of atmospheric parameters on OLRclear based on the SBDART radiation transfer model (RTM), we developed a model for estimating OLRclear using infrared channels from the advanced geosynchronous radiation imager (AGRI) onboard the FY-4A satellite. The OLRclear results showed an RMSE of 5.05 W/m2 and MBE of 1.59 W/m2 compared to ERA5. The corresponding RMSE and MBE value compared to CERES was 6.52 W/m2 and 2.39 W/m2. Additionally, the calculated LCRFTOA results were validated against instantaneous, daily average, and monthly average ERA5 and CERES LCRFTOA products, supporting the validity of the algorithm proposed in this paper. Finally, the changes in LCRFTOA due to varied cloud heights (high, medium, and low cloud) were analyzed. This study provides the basis for comprehensive studies on the characteristics of top-of atmosphere radiation. The results suggest that high-height clouds exert a greater degree of radiative forcing more frequently, while low-height clouds are more frequently found in the lower forcing range. [ABSTRACT FROM AUTHOR]

Published

2024

14. Rainfall Area Identification Algorithm Based on Himawari-8 Satellite Data and Analysis of its Spatiotemporal Characteristics.

Author

Chen, Xingru, Letu, Husi, Shang, Huazhe, Ri, Xu, Tang, Chenqian, Ji, Dabin, Shi, Chong, and Teng, Yupeng

Subjects

METEOROLOGICAL research, GEOSTATIONARY satellites, DATA analysis, WATER vapor, ALGORITHMS, RAINFALL

Abstract

Real-time monitoring of rainfall areas based on satellite remote sensing is of vital importance for extreme rainfall research and disaster prediction. In this study, a new rainfall area identification algorithm was developed for the new generation of geostationary satellites with high spatial and temporal resolution and rich bands. As the main drivers of the rainfall process, the macro and micro physical properties of clouds play an important role in the formation and development of rainfall. We considered differences in the absorption capacity of the water vapor absorption channels in the infrared band and introduced a sensitivity difference of rainfall area in water vapor channels to construct a sensitive detection of the water vapor region. The results of this algorithm were evaluated using Global Precipitation Measurement (GPM) satellite products and CloudSat measurements in various scenarios, with hit rates of 70.03% and 81.39% and false alarm rates of 2.05% and 21.34%, respectively. Spatiotemporal analysis revealed that the types of upper clouds in the rainfall areas mainly consisted of deep convection, cirrostratus, and nimbostratus clouds. Our study provides supporting data for weather research and disaster prediction, as well as an efficient and reliable method for capturing temporal and spatial features. [ABSTRACT FROM AUTHOR]

Published

2024

15. Surface Solar Radiation Compositions Observed from Himawari-8 / 9 and Fengyun-4 Series.

Author

Letu, Husi, Ma, Run, Nakajima, Takashi Y., Shi, Chong, Hashimoto, Makiko, Nagao, Takashi M., Baran, Anthony J., Nakajima, Teruyuki, Xu, Jian, Wang, Tianxing, Tana, Gegen, Bilige, Sude, Shang, Huazhe, Chen, Liangfu, Ji, Dabin, Lei, Yonghui, Wei, Lesi, Zhang, Peng, Li, Jun, and Li, Lei

Subjects

SOLAR radiation, SOLAR surface, MACHINE learning, RADIATIVE transfer, ENVIRONMENTAL health, SOLAR energy

Abstract

Surface downward solar radiation compositions (SSRC), including photosynthetically active radiation (PAR), ultraviolet-A (UVA), ultraviolet-B (UVB), and shortwave radiation (SWR), with high spatial–temporal resolutions and precision are essential for applications including solar power, vegetation photosynthesis, and environmental health. In this study, an optimal algorithm was developed to calculate SSRC, including their direct and diffuse components. Key features of the algorithm include combining the radiative transfer model with machine learning techniques, including full consideration of the effects of aerosol types, cloud phases, and gas components. A near-real-time monitoring system was developed based on this algorithm, with SSRC products generated from Himawari-8/9 and Fengyun-4 series data. Validation with ground-based data shows that the accuracy of the SWR and PAR compositions (daily mean RMSEs of 19.7 and 9.2 W m−2, respectively) are significantly better than those of state-of-the-art products from CERES, ERA5, and GLASS. The accuracy of UVA and UVB measurements is comparable with CERES. Characteristics of aerosols, clouds, gases, and their impacts on SSRC are investigated before, during, and post COVID-19; in particular, significant SSRC variations due to the reduction of aerosols and increase of ozone are identified in the Chinese central and eastern areas during that period. The spatial–temporal resolution of data products [up to 0.05° (10 min)−1 for the full-disk region] is one of the most important advantages. Data for the East Asia–Pacific region during 2016–20 is available from the CARE home page (www.slrss.cn/care/sp/pc/). [ABSTRACT FROM AUTHOR]

Published

2023

16. The Fusion of ERA5 and MERRA-2 Atmospheric Temperature Profiles with Enhanced Spatial Resolution and Accuracy.

Author

Qiao, Yale, Ji, Dabin, Shang, Huazhe, Xu, Jian, Xu, Ri, and Shi, Chong

Subjects

SPATIAL resolution, METEOROLOGICAL research, ATMOSPHERIC temperature, INTERPOLATION

Abstract

Accurate high-resolution atmospheric temperature profiles are essential for precisely characterizing the evolution of the atmosphere and developing numerical forecasts. Atmospheric datasets, such as ERA5 (the fifth-generation ECMWF Reanalysis) and MERRA-2 (the Modern-Era Retrospective Analysis for Research and Applications, Version 2), provide global and continuous temperature profiles, with fine vertical distribution and horizontal resolution. RAOB (Radiosonde Observation) sounding data have high confidence and representativeness and are usually used for data accuracy verification. Due to the difficulty of updating existing products, and the scarcity of research on mesospheric temperature profiles, this work maximizes the high observation accuracy of RAOB data, combines the benefits of ERA5's horizontal resolution and MERRA-2's vertical distribution, and employs the optimal interpolation method to combine the data, in order to produce a fused result with high spatial resolution. After converting all of the data to the same spatial distribution, the optimal interpolation method was used to combine the two datasets from separate places and different pressure layers in order to produce the fused results, which had a vertical distribution of 45 layers and a spatial resolution of 0.25°. The fused data's RMSE and MAE were 6.0 K and 5.0 K lower than those of the MERRA-2 temperature profile data, respectively, and 0.3 K and 0.4 K lower than those of the ERA5 temperature profile data, respectively. The validation, using data from 2019, showed that the fused data exhibits better correlation and data accuracy than the other two datasets, which demonstrated that the fused algorithm can potentially be used to generate reliable datasets for future meteorological research. [ABSTRACT FROM AUTHOR]

Published

2023

17. Estimation of Surface Downward Longwave Radiation and Cloud Base Height Based on Infrared Multichannel Data of Himawari-8.

Author

Shao, Jiangqi, Letu, Husi, Ri, Xu, Tana, Gegen, Wang, Tianxing, and Shang, Huazhe

Subjects

CLIMATE research, RADIATION, RANDOM forest algorithms, REMOTE sensing

Abstract

Surface downward longwave radiation (SDLR) is significant with regard to surface energy budgets and climate research. The uncertainty of cloud base height (CBH) retrieval by remote sensing induces the vast majority of SDLR estimation errors under cloudy conditions; reliable CBH observation and estimation are crucial for determining the cloud radiative effect. This study presents a CBH retrieval methodology built from 10 thermal spectral data from Himawari-8 (H-8) observations, utilizing the random forest (RF) algorithm to fully account for each band's contribution to CBH. The algorithm utilizes only infrared band data, making it possible to obtain CBH 24 h a day. Considering some factors that can significantly affect the CBH estimation, RF models are trained for different clouds using inputs from multiple H-8 channels together with geolocation information to target CBH derived from CloudSat/CALIPSO combined measurements. The validation results reveal that the new methodology performs well, with a root-mean-square error (RMSE) of only 1.17 km for all clouds. To evaluate the effect of CBH on SDLR estimation, an all-sky SDLR estimation algorithm based on previous CBH predictions is proposed. The new SDLR product not only has a resolution that is noticeably higher than that of benchmark products of the SDLR, such as the Clouds and the Earth's Radiant Energy System (CERES) and the next-generation reanalysis (ERA5) of the European Centre for Medium-Range Weather Forecasts (ECMWF), but it also has greater accuracy, with an RMSE of 21.8 W m−2 for hourly surface downward longwave irradiance (SDLI). [ABSTRACT FROM AUTHOR]

Published

2023

18. Establishment of an analytical model for remote sensing of typical stratocumulus cloud profiles under various precipitation and entrainment conditions.

Author

Shang, Huazhe, Hioki, Souichiro, Penide, Guillaume, Cornet, Céline, Letu, Husi, and Riedi, Jérôme

Subjects

STRATOCUMULUS clouds, REMOTE sensing, METEOROLOGICAL satellites, ORTHOGONAL functions, ATMOSPHERIC models, PARAMETERIZATION

Abstract

Structural patterns of cloud effective radius (ER) and liquid water content (LWC) profiles are essential variables of cloud lifecycle and precipitation processes, while observing cloud profiles from passive remote-sensing sensors remains highly challenging. Understanding whether there are typical structural patterns of ER and LWC profiles in liquid clouds and how they are linked to cloud entrainment or precipitating status is critical in developing algorithms to derive cloud profiles from passive satellite sensors. This study aims to address these questions and provide a preliminary foundation for the development of liquid cloud profile retrievals for the Multi-viewing, Multi-channel and Multi-polarization Imaging (3MI) sensor aboard the European Organization for the Exploitation of Meteorological Satellites (EUMETSAT) Polar System-Second Generation (EPS-SG) satellite, which is scheduled to be launched in 2025. Firstly, we simulate a large ensemble of stratocumulus cloud profiles using the Colorado State University (CSU) Regional Atmospheric Modeling System (RAMS). The empirical orthogonal function (EOF) analysis is adopted to describe the shape of simulated profiles with a limited number of elemental profile variations. Our results indicate that the first three EOFs of LWC and ER profiles can explain >90 % of LWC and ER profiles. The profiles are divided into four prominent patterns and all of these patterns can be simplified as triangle-shaped polylines. The frequency of these four patterns is found to relate to intensities of the cloud-top entrainment and precipitation. Based on these analyses, we propose a simplified triangle-shaped cloud profile parameterization scheme allowing us to represent these main patterns of LWC and ER. This simple yet physically realistic analytical model of cloud profiles is expected to facilitate the representation of cloud properties in advanced retrieval algorithms such as those developed for the 3MI/EPS-SG. [ABSTRACT FROM AUTHOR]

Published

2023

19. Retrieval of terahertz ice cloud properties from airborne measurements based on the irregularly shaped Voronoi ice scattering models.

Author

Li, Ming, Letu, Husi, Ishimoto, Hiroshi, Li, Shulei, Liu, Lei, Nakajima, Takashi Y., Ji, Dabin, Shang, Huazhe, and Shi, Chong

Subjects

ICE clouds, SUBMILLIMETER waves, ICE crystals, PARTICLE size distribution, REMOTE sensing, BRIGHTNESS temperature

Abstract

Currently, terahertz remote sensing technology is one of the best ways to detect the microphysical properties of ice clouds. Influenced by the representativeness of the ice crystal scattering (ICS) model, the existing terahertz ice cloud remote sensing inversion algorithms still have significant uncertainties. In this study, based on the Voronoi ICS model, we developed a terahertz remote sensing inversion algorithm of the ice water path (IWP) and median mass diameter (Dme) of ice clouds. This study utilized the single-scattering properties (extinction efficiency, single-scattering albedo, and asymmetry factor) of the Voronoi, sphere, and hexagonal column ICS models in the terahertz region. Combined with 14 408 groups of particle size distributions obtained from aircraft-based measurements, we developed the Voronoi, sphere, and column ICS schemes based on the Voronoi, sphere, and column ICS models. The three schemes were applied to the radiative transfer model to carry out the sensitivity analysis of the top-of-cloud (TOC) terahertz brightness temperature differences between cloudy and clear skies (BTDs) on the IWP and Dme. The sensitivity results showed that the TOC BTDs between 640 and 874 GHz are functions of the IWP, and the TOC BTDs of 380, 640, and 874 GHz are functions of the Dme. The Voronoi ICS scheme possesses stronger sensitivity to the Dme than the sphere and column ICS schemes. Based on the sensitivity results, we built a multi-channel look-up table for BTDs. The IWP and Dme were searched from the look-up table using an optimal estimation algorithm. We used 2000 BTD test data randomly generated by the RSTAR model to assess the algorithm's accuracy. Test results showed that the correlation coefficients of the retrieved IWP and Dme reached 0.99 and 0.98, respectively. As an application, we used the inversion algorithm to retrieve the ice cloud IWP and Dme based on the Compact Scanning Submillimeter-wave Imaging Radiometer (CoSSIR) airborne terahertz radiation measurements. Validation against the retrievals of the Bayesian algorithm reveals that the Voronoi ICS model performs better than the sphere and hexagonal column ICS models, with enhancement of the mean absolute errors of 5.0 % and 12.8 % for IWP and Dme , respectively. In summary, the results of this study confirmed the practicality and effectiveness of the Voronoi ICS model in the terahertz remote sensing inversion of ice cloud microphysical properties. [ABSTRACT FROM AUTHOR]

Published

2023

20. Shortwave Infrared Multi-Angle Polarization Imager (MAPI) Onboard Fengyun-3 Precipitation Satellite for Enhanced Cloud Characterization.

Author

Wang, Haofei, Zhang, Peng, Yin, Dekui, Li, Zhengqiang, Shang, Huazhe, Xu, Hanlie, Shang, Jian, Gu, Songyan, and Hu, Xiuqing

Subjects

WEATHER & climate change, NUMERICAL weather forecasting, CLIMATE change, CLOUD droplets, ICE clouds, ORBITS (Astronomy)

Abstract

Accurate measurement of the radiative properties of clouds and aerosols is of great significance to global climate change and numerical weather prediction. The multi-angle polarization imager (MAPI) onboard the Fengyun-3 precipitation satellite, planned to be launched in 2023, will provide the multi-angle, multi-shortwave infrared (SWIR) channels and multi-polarization satellite observation of clouds and aerosols. MAPI operates in a non-sun-synchronized inclined orbit and provides images with a spatial resolution of 3 km (sub-satellite) and a swath of 700 km. The observation channels of the MAPI include 1030 nm, 1370 nm, and 1640 nm polarization channels and corresponding non-polarization channels, which provide observation information from 14 angles. In-flight radiometric and polarimetric calibration strategies are introduced, aiming to achieve radiometric accuracy of 5% and polarimetric accuracy of 2%. Simulation experiments show that the MAPI has some unique advantages of characterizing clouds and aerosols. For cloud observation, the polarization phase functions of the 1030 nm and 1640 nm around the scattering angle of a cloudbow show strong sensitivity to cloud droplet radius and effective variance. In addition, the polarized observation of the 1030 nm and 1640 nm has a higher content of information for aerosol than VIS-NIR. Additionally, the unique observation geometry of non-sun-synchronous orbits can provide more radiometric and polarization information with expanded scattering angles. Thus, the multi-angle polarization measurement of the new SWIR channel onboard Fengyun-3 can optimize cloud phase state identification and cloud microphysical parameter inversion, as well as the retrieval of aerosols. The results obtained from the simulations will provide support for the design of the next generation of polarized imagers of China. [ABSTRACT FROM AUTHOR]

Published

2022

21. A New Benchmark for Surface Radiation Products over the East Asia–Pacific Region Retrieved from the Himawari-8 /AHI Next-Generation Geostationary Satellite.

Author

Letu, Husi, Nakajima, Takashi Y., Wang, Tianxing, Shang, Huazhe, Ma, Run, Yang, Kun, Baran, Anthony J., Riedi, Jerome, Ishimoto, Hiroshi, Yoshida, Mayumi, Shi, Chong, Khatri, Pradeep, Du, Yihan, Chen, Liangfu, and Shi, Jiancheng

Subjects

GEOSTATIONARY satellites, RADIATION

Abstract

Surface downward radiation (SDR), including shortwave downward radiation (SWDR) and longwave downward radiation (LWDR), is of great importance to energy and climate studies. Considering the lack of reliable SDR data with a high spatiotemporal resolution in the East Asia–Pacific (EAP) region, we derived SWDR and LWDR at 10-min and 0.05° resolutions for this region from 2016 to 2020 based on the next-generation geostationary satellite Himawari-8 (H-8). The SDR product is unique in terms of its all-sky features, high accuracy, and high-resolution levels. The cloud effect is fully considered in the SDR product, and the influence of high aerosol loadings and topography on the SWDR are considered. Compared to benchmark products of the radiation, such as Clouds and the Earth's Radiant Energy System (CERES) and the European Centre for Medium-Range Weather Forecasts (ECMWF) next-generation reanalysis (ERA5), and the Global Land Surface Satellite (GLASS), not only is the resolution of the new SDR product notably much higher, but the product accuracy is also higher than that of those products. In particular, hourly and daily root-mean-square errors of the new SWDR are 104.9 and 31.5 W m−2, respectively, which are much smaller than those of CERES (at 121.6 and 38.6 W m−2, respectively), ERA5 (at 176.6 and 39.5 W m−2, respectively), and GLASS (daily of 36.5 W m−2). Meanwhile, RMSEs of hourly and daily values of the new LWDR are 19.6 and 14.4 W m−2, respectively, which are comparable to that of CERES and ERA5, and even better over high-altitude regions. [ABSTRACT FROM AUTHOR]

Published

2022

22. First assessment of surface solar irradiance derived from Himawari-8 across China

Author

Shi, Hongrong, Li, Weiwei, Fan, Xuehua, Zhang, Jinqiang, Hu, Bo, Husi, Letu, Shang, Huazhe, Han, Xinlei, Song, Zijue, Zhang, Yingjie, Wang, Shu, Chen, Hongbin, and Xia, Xiang'ao

Published

2018

23. Ice Cloud Properties From Himawari-8/AHI Next-Generation Geostationary Satellite: Capability of the AHI to Monitor the DC Cloud Generation Process.

Author

Letu, Husi, Nagao, Takashi M., Nakajima, Takashi Y., Riedi, Jerome, Ishimoto, Hiroshi, Baran, Anthony J., Shang, Huazhe, Sekiguchi, Miho, and Kikuchi, Maki

Subjects

GEOSTATIONARY satellites, ICE clouds, METEOROLOGICAL satellites, OPTICAL measurements, LIGHT scattering, REPRODUCTION

Abstract

The Japan Meteorological Agency (JMA) successfully launched the Himawari-8 (H-8) new-generation geostationary meteorological satellite with the Advanced Himawari Imager (AHI) sensor on October 7, 2014. The H-8/AHI level-2 (L2) operational cloud property products were released by the Japan Aerospace Exploration Agency during September 2016. The Voronoi light scattering model, which is a fractal ice particle habit, was utilized to develop the retrieval algorithm called “Comprehensive Analysis Program for Cloud Optical Measurement” (CAPCOM-INV)-ice for the AHI ice cloud product. In this paper, we describe the CAPCOM-INV-ice algorithm for ice cloud products from AHI data. To investigate its retrieval performance, retrieval results were compared with 2000 samples of the ice cloud optical thickness and effective particle radius values. Furthermore, AHI ice cloud products are evaluated by comparing them with the MODIS collection-6 (C6) products. As an experiment, cloud property retrievals from AHI measurements, with an observation interval time of 2.5 min and ground-based rainfall observation radar data (the latter of which is supplied by the JMA, with a 1-km grid mesh), are used to investigate the generation processes of deep convective (DC) cloud in the vicinity of the Kyushu island, Japan. It revealed that AHI measurements have the capability of monitoring the growth processes, including variation of the cloud properties and the precipitation in the DC cloud. [ABSTRACT FROM AUTHOR]

Published

2019

24. A Supercooled Water Cloud Detection Algorithm Using Himawari‐8 Satellite Measurements.

Author

Wang, Ziming, Letu, Husi, Shang, Huazhe, Zhao, Chuanfeng, Li, Jiming, and Ma, Run

Subjects

RAIN-making, ICING (Meteorology), RADIATION, CLOUD droplets

Abstract

The detection of supercooled water clouds (SWCs) is essential for artificial rain enhancement, the prevention of aircraft ice accretion, and better understanding of radiative energy balance. However, it is challenging to identify SWCs using only passive satellite measurements. We adopt measurements from the Advanced Himawari Imager, which is onboard the new‐generation, high temporal, spatial, and spectral resolution geostationary Himawari‐8 satellite, to develop a time‐continuous Himawari‐8 SWC (HSWC) algorithm. The HSWC algorithm includes a group of tests using comprehensive cloud properties (e.g., cloud phase [CPH], cloud top temperature, cloud optical thickness, and cloud effective radius [CER]). Unlike previous SWC detection algorithms, which are based on cloud top temperature and cloud optical thickness properties, we introduce CER and CPH information into the HSWC algorithm because the distribution of SWCs is sensitive to CER values, and SWCs may appear in mixed‐phase clouds identified by satellites. Our analyses indicate that the additions of the CER and CPH tests could improve the performance of SWC detection by 15.07% and 4.75%, respectively. The full disk SWC detection results identified by the HSWC algorithm in January, May, August, and October of 2017 are validated using lidar measurements. The hit rate and false alarm rate are 93.52% and 25.27%, respectively. Our study provides potential SWC regions for the implementation of artificial rain enhancement. Key Points: We developed a supercooled water cloud detection algorithm using high‐resolution Himawari‐8 satellite measurementsCloud effective radius and cloud phase tests are effective for detecting supercooled water clouds (SWCs)The SWC results of our algorithm well agree with lidar measurements in different seasons [ABSTRACT FROM AUTHOR]

Published

2019

25. Spatiotemporal Distributions of Cloud Parameters and the Temperature Response Over the Mongolian Plateau During 2006–2015 Based on MODIS Data.

Author

Bao, Shanhu, Letu, Husi, Zhao, Chuanfeng, Tana, Gegen, Shang, Huazhe, Wang, Tianxing, Lige, Bi, Bao, Yuhai, Purevjav, Gomboluudev, He, Jie, and Zhao, Jun

Abstract

The Mongolian Plateau (MP) has important influences on regional and global climate change. The spatiotemporal variations in the cloud cover and cloud optical thickness of total, high, middle, and low clouds over the MP during the daytime from 2006 to 2015 are analyzed using MODIS level 2 atmospheric data. Results show that the annual average total cloud cover over the MP decreases from the forest area in the northeast to the desert area in the southwest. The total cloud cover over the MP is obviously higher in summer than in other seasons, in which high clouds have a largest proportion, with the substantial total cloud cover changes. The spatial distributions of the high, middle, and low cloud covers over the MP are highly variable. The cooling effect of the cloud net radiative forcing is greater during the daytime in summer than in other seasons, which is likely associated with thick cloud optical thickness or large cloud cover in summer. Combined with the analyses of relationships among cloud cover, cloud optical thickness, cloud radiative forcing, and air temperature, the results show that significantly negative correlations exist between cloud optical thickness and cloud radiative forcing, and between total cloud cover and air temperature in the MP. The decrease in air temperature in summer over the MP during daytime confirm that the increase in the daytime total cloud cover strengthen the cooling effects of clouds and decrease the air temperature, especially in the high-value area with cloud cover distribution over the northeast MP. [ABSTRACT FROM AUTHOR]

Published

2019

26. Spatiotemporal distributions of cloud parameters and their response to meteorological factors over the Tibetan Plateau during 2003–2015 based on MODIS data.

Author

Bao, Shanhu, Letu, Husi, Zhao, Jun, Shang, Huazhe, Lei, Yonghui, Duan, Anmin, Chen, Bing, Bao, Yuhai, He, Jie, Wang, Tianxing, Ji, Dabin, Tana, Gegen, and Shi, Jiancheng

Subjects

CLOUD computing, ATMOSPHERIC temperature, CLOUDINESS, PARAMETER estimation

Abstract

The Tibetan Plateau (TP) has important influences on regional and global climate change. Here, we perform an in‐depth study of the relationship between cloud parameters and meteorological factors over the TP. The spatiotemporal variations in cloud cover and cloud optical thickness over the TP during the daytime from 2003 to 2015 are analysed using the Aqua‐MODIS level 2 atmospheric product data MYD06. Results show that the annual average cloud cover over the TP decreases from the southeast to the northwest. The cloud cover of the western TP is highest in spring and lowest in autumn, while the cloud cover of the eastern TP is higher in spring and summer. The cloud covers in most areas of the TP exceed 30% in spring and summer, and the cloud optical thickness in the southeastern TP exceeds 10 in summer, with substantial cloud cover and cloud optical thickness changes. Compared to other seasons, the cooling effect of the near surface cloud net radiative forcing is greater during daytime in summer, which is likely associated with thick cloud optical thickness or large cloud cover. The results of the analysis of relationships among cloud cover, water vapour and air temperature show that positive correlations exist between cloud cover and water vapour, and that significantly negative correlations exist between cloud cover and air temperature over the TP. Combined with the analysis of variation features in the cloud parameters and meteorological factors, we find that water vapour variations during the daytime over the TP lead to cloud cover changes, which affect the air temperature variations over the TP by the cooling effects of clouds, especially in summer. The cloud cover of the western Tibetan Plateau (TP) is highest in spring and lowest in autumn, while the cloud cover of the eastern TP is higher in spring and summer. Combined with the analysis of variation features in the cloud parameters and meteorological factors, we find that water vapour variations during the daytime over the TP lead to cloud cover changes, which affect the air temperature variations over the TP by the cooling effects of clouds, especially in summer. [ABSTRACT FROM AUTHOR]

Published

2019

27. Diurnal cycle and seasonal variation of cloud cover over the Tibetan Plateau as determined from Himawari-8 new-generation geostationary satellite data.

Author

Shang H, Letu H, Nakajima TY, Wang Z, Ma R, Wang T, Lei Y, Ji D, Li S, and Shi J

Abstract

Analysis of cloud cover and its diurnal variation over the Tibetan Plateau (TP) is highly reliant on satellite data; however, the accuracy of cloud detection from both polar-orbiting and geostationary satellites over this area remains unclear. The new-generation geostationary Himawari-8 satellites provide high-resolution spatial and temporal information about clouds over the Tibetan Plateau. In this study, the cloud detection of MODIS and AHI is investigated and validated against CALIPSO measurements. For AHI and MODIS, the false alarm rate of AHI and MODIS in cloud identification over the TP was 7.51% and 1.94%, respectively, and the cloud hit rate was 73.55% and 80.15%, respectively. Using hourly cloud-cover data from the Himawari-8 satellites, we found that at the monthly scale, the diurnal cycle in cloud cover over the TP tends to increase throughout the day, with the minimum and maximum cloud fractions occurring at 10:00 a.m. and 18:00 p.m. local time. Due to the limited time resolution of polar-orbiting satellites, the underestimation of MODIS daytime average cloud cover is approximately 4.00% at the annual scale, with larger biases during the spring (5.40%) and winter (5.90%).

Published

2018