Channel quality predictions assisted by new algorithms for high throughput satellite and 5G systems

Ali M. Al-Saegh; Esraa Mousa Ali; Mariam Qutaiba Abdalrazak; Nouf Abd Elmunim; Mohammad Alibakhshikenari; Bal S. Virdee; Nisar Ahmad Abbasi; Muhammad Akmal Chaudhary; Lida Kouhalvandi; Taha A. Elwi; Patrizia Livreri; Takfarinas Saber

doi:10.1038/s41598-025-20199-z

Channel quality predictions assisted by new algorithms for high throughput satellite and 5G systems

Ali M. Al-Saegh
, Esraa Mousa Ali
, Mariam Qutaiba Abdalrazak
, Nouf Abd Elmunim
, Mohammad Alibakhshikenari
, Bal S. Virdee
, Nisar Ahmad Abbasi
, Muhammad Akmal Chaudhary
, Lida Kouhalvandi
, Taha A. Elwi
, Patrizia Livreri
, Takfarinas Saber

Middle Technical University
Al Ahliyya Amman University
Al-Bayan University
Princess Nourah Bint Abdulrahman University
University of Galway
Dogus University
London Metropolitan University
Bahrain Polytechnic
Al-Nahrain University
University of Palermo

Research output: Contribution to journal › Article › peer-review

5 Scopus citations

Abstract

Variations in rainfall patterns across different regions reduce the accuracy of existing satellite channel models. As satellite services and 5G applications continue to advance, the development of accurate rain-impairment-aware channel models has become essential. This paper presents a prediction model for rain-induced impairments in High Throughput Satellite (HTS) and 5G satellite-to-land communication channels. The proposed model integrates three novel algorithms designed to characterize and analyze rain-induced attenuation and channel quality. Specifically, these algorithms calculate rain-specific attenuation, effective slant path lengths through rainfall, overall rain-induced attenuation, signal carrier-to-noise ratios, and symbol error rates across three conventional modulation schemes. Additionally, the study introduces a new database detailing rain-induced attenuation on HTS channels, considering various frequencies and rainfall intensities. Results indicate substantial fluctuations in HTS-to-land fade levels and signal quality during rainfall events, which could lead to communication link outages, particularly at higher-order modulation schemes. This study provides practical methods to analyze channel characteristics using actual rainfall measurements, thereby facilitating the effective design and deployment of future HTS and 5G system.

Original language	English
Article number	34649
Journal	Scientific Reports
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41598-025-20199-z
State	Published - Dec 2025

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 9 Industry, Innovation, and Infrastructure

Keywords

Broadband wireless access, rain attenuation
Energy sustainable development
High throughput satellite (HTS)
Innovation systems
Satellite communications
Symbol error rate

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10.1038/s41598-025-20199-z

Cite this

Al-Saegh, A. M., Ali, E. M., Abdalrazak, M. Q., Elmunim, N. A., Alibakhshikenari, M., Virdee, B. S., Abbasi, N. A., Chaudhary, M. A., Kouhalvandi, L., Elwi, T. A., Livreri, P., & Saber, T. (2025). Channel quality predictions assisted by new algorithms for high throughput satellite and 5G systems. Scientific Reports, 15(1), Article 34649. https://doi.org/10.1038/s41598-025-20199-z

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title = "Channel quality predictions assisted by new algorithms for high throughput satellite and 5G systems",

abstract = "Variations in rainfall patterns across different regions reduce the accuracy of existing satellite channel models. As satellite services and 5G applications continue to advance, the development of accurate rain-impairment-aware channel models has become essential. This paper presents a prediction model for rain-induced impairments in High Throughput Satellite (HTS) and 5G satellite-to-land communication channels. The proposed model integrates three novel algorithms designed to characterize and analyze rain-induced attenuation and channel quality. Specifically, these algorithms calculate rain-specific attenuation, effective slant path lengths through rainfall, overall rain-induced attenuation, signal carrier-to-noise ratios, and symbol error rates across three conventional modulation schemes. Additionally, the study introduces a new database detailing rain-induced attenuation on HTS channels, considering various frequencies and rainfall intensities. Results indicate substantial fluctuations in HTS-to-land fade levels and signal quality during rainfall events, which could lead to communication link outages, particularly at higher-order modulation schemes. This study provides practical methods to analyze channel characteristics using actual rainfall measurements, thereby facilitating the effective design and deployment of future HTS and 5G system.",

keywords = "Broadband wireless access, rain attenuation, Energy sustainable development, High throughput satellite (HTS), Innovation systems, Satellite communications, Symbol error rate",

author = "Al-Saegh, \{Ali M.\} and Ali, \{Esraa Mousa\} and Abdalrazak, \{Mariam Qutaiba\} and Elmunim, \{Nouf Abd\} and Mohammad Alibakhshikenari and Virdee, \{Bal S.\} and Abbasi, \{Nisar Ahmad\} and Chaudhary, \{Muhammad Akmal\} and Lida Kouhalvandi and Elwi, \{Taha A.\} and Patrizia Livreri and Takfarinas Saber",

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doi = "10.1038/s41598-025-20199-z",

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AU - Al-Saegh, Ali M.

AU - Ali, Esraa Mousa

AU - Abdalrazak, Mariam Qutaiba

AU - Elmunim, Nouf Abd

AU - Alibakhshikenari, Mohammad

AU - Virdee, Bal S.

AU - Abbasi, Nisar Ahmad

AU - Chaudhary, Muhammad Akmal

AU - Kouhalvandi, Lida

AU - Elwi, Taha A.

AU - Livreri, Patrizia

AU - Saber, Takfarinas

N1 - Publisher Copyright: © The Author(s) 2025.

PY - 2025/12

Y1 - 2025/12

N2 - Variations in rainfall patterns across different regions reduce the accuracy of existing satellite channel models. As satellite services and 5G applications continue to advance, the development of accurate rain-impairment-aware channel models has become essential. This paper presents a prediction model for rain-induced impairments in High Throughput Satellite (HTS) and 5G satellite-to-land communication channels. The proposed model integrates three novel algorithms designed to characterize and analyze rain-induced attenuation and channel quality. Specifically, these algorithms calculate rain-specific attenuation, effective slant path lengths through rainfall, overall rain-induced attenuation, signal carrier-to-noise ratios, and symbol error rates across three conventional modulation schemes. Additionally, the study introduces a new database detailing rain-induced attenuation on HTS channels, considering various frequencies and rainfall intensities. Results indicate substantial fluctuations in HTS-to-land fade levels and signal quality during rainfall events, which could lead to communication link outages, particularly at higher-order modulation schemes. This study provides practical methods to analyze channel characteristics using actual rainfall measurements, thereby facilitating the effective design and deployment of future HTS and 5G system.

AB - Variations in rainfall patterns across different regions reduce the accuracy of existing satellite channel models. As satellite services and 5G applications continue to advance, the development of accurate rain-impairment-aware channel models has become essential. This paper presents a prediction model for rain-induced impairments in High Throughput Satellite (HTS) and 5G satellite-to-land communication channels. The proposed model integrates three novel algorithms designed to characterize and analyze rain-induced attenuation and channel quality. Specifically, these algorithms calculate rain-specific attenuation, effective slant path lengths through rainfall, overall rain-induced attenuation, signal carrier-to-noise ratios, and symbol error rates across three conventional modulation schemes. Additionally, the study introduces a new database detailing rain-induced attenuation on HTS channels, considering various frequencies and rainfall intensities. Results indicate substantial fluctuations in HTS-to-land fade levels and signal quality during rainfall events, which could lead to communication link outages, particularly at higher-order modulation schemes. This study provides practical methods to analyze channel characteristics using actual rainfall measurements, thereby facilitating the effective design and deployment of future HTS and 5G system.

KW - Broadband wireless access, rain attenuation

KW - Energy sustainable development

KW - High throughput satellite (HTS)

KW - Innovation systems

KW - Satellite communications

KW - Symbol error rate

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DO - 10.1038/s41598-025-20199-z

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SN - 2045-2322

VL - 15

JO - Scientific Reports

JF - Scientific Reports

IS - 1

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ER -

Channel quality predictions assisted by new algorithms for high throughput satellite and 5G systems

Abstract

UN SDGs

Keywords

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