Statistical Study of Rainfall Inversion Using the Earth-Space Link at the Ku Band: Optimization and Validation for 1 Year of Data

Zhao, Yingcheng; Liu, Xichuan; Xian, Minghao; Gao, Taichang

doi:10.1109/jstars.2021.3111336

Cited by 5 publications

(3 citation statements)

References 39 publications

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“…The communication link between two such directional antennas is called a microwave backhaul link, or microwave link for short. As shown in Figure 1, when the microwave propagates through the rain area, the transmitting power will be attenuated due to the scattering and absorption by raindrops [21,22]. This type of microwave attenuation is called rain-induced attenuation, and the relative loss of power per unit path length is called specific attenuation, denoted as k (dB/km).…”

Section: Basic Principlementioning

confidence: 99%

A Review on Rainfall Measurement Based on Commercial Microwave Links in Wireless Cellular Networks

Lian

Wei

Sun

et al. 2022

Sensors

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As one of the most critical elements in the hydrological cycle, real-time and accurate rainfall measurement is of great significance to flood and drought disaster risk assessment and early warning. Using commercial microwave links (CMLs) to conduct rainfall measure is a promising solution due to the advantages of high spatial resolution, low implementation cost, near-surface measurement, and so on. However, because of the temporal and spatial dynamics of rainfall and the atmospheric influence, it is necessary to go through complicated signal processing steps from signal attenuation analysis of a CML to rainfall map. This article first introduces the basic principle and the revolution of CML-based rainfall measurement. Then, the article illustrates different steps of signal process in CML-based rainfall measurement, reviewing the state of the art solutions in each step. In addition, uncertainties and errors involved in each step of signal process as well as their impacts on the accuracy of rainfall measurement are analyzed. Moreover, the article also discusses how machine learning technologies facilitate CML-based rainfall measurement. Additionally, the applications of CML in monitoring phenomena other than rain and the hydrological simulation are summarized. Finally, the challenges and future directions are discussed.

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Section: Basic Principlementioning

confidence: 99%

A Review on Rainfall Measurement Based on Commercial Microwave Links in Wireless Cellular Networks

Lian

Wei

Sun

et al. 2022

Sensors

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“…Zhao dkk [39] melakukan estimasi curah hujan dari data penerimaan SNR satelit Ku-band selama 1 tahun dengan resolusi temporal 1 menit di Nanjing, China. Metode yang digunakan yaitu kombinasi Kalman filter untuk penentuan baseline dan model ITU-R dengan data statistik tinggi hujan 10 tahun untuk konversi ke curah hujan.…”

Section: Gambar 7 Path-averaged Stratiform Rain-induced (Wet Path)unclassified

Optimalisasi Saluran Komunikasi Berbasis Gelombang Mikro Sebagai Alternatif Sistem Pemantauan Curah Hujan

Mardyansyah

Kurniawan

Santoso

et al. 2022

EJI

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As a vast archipelagic country with diverse topographic conditions and has an annual average rainfall of more than 2000 mm, Indonesia is prone to hydrometeorological disasters. Based on Indonesia's disaster data, throughout 2021 there were 3,658 incidents of floods and landslides distributed throughout Indonesia. This makes real-time rainfall monitoring with high density indispensable. Indonesia currently has a rainfall monitoring system about 1000 automatic rain gauges, so an increase in the spatial resolution of network is necessary. The increasing density of monitoring equipment using rain gauges and weather radar poses the problem of high procurement and operational costs. Therefore, several alternative rainfall monitoring systems are needed. In this article, we review several studies that focus on the utilization of terrestrial and satellite communication link operating in high frequency bands as an alternative for measuring rainfall. Optimization of the satellite communication system network is more suitable than terrestrial networks to be applied in Indonesia with archipelagic areas because it has a large number of point distributions with wider coverage. The use of artificial intelligence with deep learning techniques such as one dimensional convolutional neural network (1D-CNN) is also very promising to estimate rainfall intensity because it has a high accuracy of 93%..

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“…The enhancements offered by the updated system include a data-driven rain event detector, able to automatically identify the presence of rain events along the Earth-satellite link, and an improved procedure to estimate rain attenuation from the received satellite signal, which makes the rain rate prediction fully automated and thus applicable in real-time using any equipment receiving signals transmitted from a satellite operating at Ku band or above. The methods currently available in the literature [12,13,14,15,16] offer elaborate solutions either for the identification of rain events or for the estimation of the rainfall intensity from the received power, while the proposed model covers effectively both aspects: the identification of rain events is achieved by an accurate machine learning technique, and the rain rate prediction relies on a model underpinned by sound physical concepts (e.g. path reduction factors -accounting for the spatial inhomogeneity of precipitation along the link, the dependence of the rain height on the season, and the different impact of stratiform and convective events [8]).…”

Section: Introductionmentioning

confidence: 99%

Real-Time Rainfall Estimation Using Satellite Signals: Development and Assessment of a New Procedure

Giro

Luini

Riva

et al. 2022

IEEE Trans. Instrum. Meas.

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This contribution presents a comprehensive methodology for the real-time estimation of the rain intensity from downlink satellite signals. The enhanced system leverages on Extremely Randomized Trees Classifiers to automatically perform rainfall detection along Earth-satellite links and successively employs an improved procedure to determine the corresponding slant-path rain attenuation. The latter quantity is then exploited to yield realtime rainfall rate estimates with 1-minute time resolution. The accuracy of the proposed methodology is tested using Ka and Q band propagation data, collected in two different sites (Milan and Madrid) and in the framework of the propagation experiments. The results demonstrate the reliability of the automated rain event detector, as well as a satisfactory accuracy in estimating the slant-path rain attenuation and the point rainfall rate. The accuracy is assessed both on a statistical and on an instantaneous basis through the evaluation of different error figures and by inspection of individual time series.

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Statistical Study of Rainfall Inversion Using the Earth-Space Link at the Ku Band: Optimization and Validation for 1 Year of Data

Cited by 5 publications

References 39 publications

A Review on Rainfall Measurement Based on Commercial Microwave Links in Wireless Cellular Networks

A Review on Rainfall Measurement Based on Commercial Microwave Links in Wireless Cellular Networks

Optimalisasi Saluran Komunikasi Berbasis Gelombang Mikro Sebagai Alternatif Sistem Pemantauan Curah Hujan

Real-Time Rainfall Estimation Using Satellite Signals: Development and Assessment of a New Procedure

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