Modeling and performance analysis of IoT-over-LEO satellite systems under realistic operational constraints: a stochastic geometry approach
Modeling and performance analysis of IoT-over-LEO satellite systems under realistic operational constraints: a stochastic geometry approach
The growing demand for reliable and extensive connectivity has made low Earth orbit (LEO) satellites aided Internet of Things (IoT) systems a critical area of research. However, current theoretical studies on IoT-over-LEO satellite systems often rely on unrealistic assumptions, such as infinite terrestrial areas and omnidirectional satellite coverage, leaving significant gaps in theoretical analysis for more realistic operational constraints. These constraints involve finite terrestrial area, limited satellite coverage, Earth curvature effect, integral uplink and downlink analysis, and link-dependent interference. To address these gaps, this paper proposes a novel stochastic geometry based model to rigorously analyze the performance of IoT-over-LEO satellite systems. By adopting a binomial point process (BPP) instead of the conventional Poisson point process (PPP), our model accurately characterizes the geographical distribution of a fixed number of IoT devices in a finite terrestrial region. This modeling framework enables the derivation of distance distribution functions for both the links from the terrestrial IoT devices to the satellites (T-S) and from the satellites to the Earth station (S-ES), while also accounting for limited satellite coverage and Earth curvature effects. To realistically represent channel
conditions, the Nakagami fading model is employed for the TS links to characterize diverse small-scale fading environments, while the shadowed-Rician fading model is used for the S-ES links to capture the combined effects of shadowing and dominant
line-of-sight paths. Furthermore, the analysis incorporates uplink and downlink interference, ensuring a comprehensive evaluation of system performance. The accuracy and effectiveness of our theoretical framework are validated through extensive Monte Carlo simulations. These results provide insights into key
performance metrics, such as coverage probability and average ergodic rate, for both individual links and the overall system. Our study also offers an important analytical tool for optimizing the design and performance of IoT-over-LEO satellite systems with the operational constraints that are more realistic.
30576-30593
Dong, Wen-Yu
c0247ccb-4b0b-4ccb-8ec6-b01aaed6cb70
Yang, Shaoshi
23650ec4-bcc8-4a2c-b1e7-a30893f52e52
Zhang, Ping
2def4374-679d-41d1-bf3a-483028a73275
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
1 August 2025
Dong, Wen-Yu
c0247ccb-4b0b-4ccb-8ec6-b01aaed6cb70
Yang, Shaoshi
23650ec4-bcc8-4a2c-b1e7-a30893f52e52
Zhang, Ping
2def4374-679d-41d1-bf3a-483028a73275
Chen, Sheng
9310a111-f79a-48b8-98c7-383ca93cbb80
Dong, Wen-Yu, Yang, Shaoshi, Zhang, Ping and Chen, Sheng
(2025)
Modeling and performance analysis of IoT-over-LEO satellite systems under realistic operational constraints: a stochastic geometry approach.
IEEE Internet of Things Journal, 12 (15), .
(doi:10.1109/JIOT.2025.3570843).
Abstract
The growing demand for reliable and extensive connectivity has made low Earth orbit (LEO) satellites aided Internet of Things (IoT) systems a critical area of research. However, current theoretical studies on IoT-over-LEO satellite systems often rely on unrealistic assumptions, such as infinite terrestrial areas and omnidirectional satellite coverage, leaving significant gaps in theoretical analysis for more realistic operational constraints. These constraints involve finite terrestrial area, limited satellite coverage, Earth curvature effect, integral uplink and downlink analysis, and link-dependent interference. To address these gaps, this paper proposes a novel stochastic geometry based model to rigorously analyze the performance of IoT-over-LEO satellite systems. By adopting a binomial point process (BPP) instead of the conventional Poisson point process (PPP), our model accurately characterizes the geographical distribution of a fixed number of IoT devices in a finite terrestrial region. This modeling framework enables the derivation of distance distribution functions for both the links from the terrestrial IoT devices to the satellites (T-S) and from the satellites to the Earth station (S-ES), while also accounting for limited satellite coverage and Earth curvature effects. To realistically represent channel
conditions, the Nakagami fading model is employed for the TS links to characterize diverse small-scale fading environments, while the shadowed-Rician fading model is used for the S-ES links to capture the combined effects of shadowing and dominant
line-of-sight paths. Furthermore, the analysis incorporates uplink and downlink interference, ensuring a comprehensive evaluation of system performance. The accuracy and effectiveness of our theoretical framework are validated through extensive Monte Carlo simulations. These results provide insights into key
performance metrics, such as coverage probability and average ergodic rate, for both individual links and the overall system. Our study also offers an important analytical tool for optimizing the design and performance of IoT-over-LEO satellite systems with the operational constraints that are more realistic.
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Accepted/In Press date: 13 May 2025
e-pub ahead of print date: 16 May 2025
Published date: 1 August 2025
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Local EPrints ID: 504690
URI: http://eprints.soton.ac.uk/id/eprint/504690
ISSN: 2327-4662
PURE UUID: cda8ddac-5dea-4aba-a481-e7c62fdb58d7
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Date deposited: 17 Sep 2025 17:06
Last modified: 17 Sep 2025 17:06
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Author:
Wen-Yu Dong
Author:
Shaoshi Yang
Author:
Ping Zhang
Author:
Sheng Chen
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