Performance Optimization Of 5G-Satellite Integrated Networks For IoT Applications: A Two-Ray Propagation Model Approach

Uko, Mfonobong, Ekpo, Sunday ORCID: https://orcid.org/0000-0001-9219-3759, Enahoro, Sunday and Fanuel, Elias (2024) Performance Optimization Of 5G-Satellite Integrated Networks For IoT Applications: A Two-Ray Propagation Model Approach. Smart Cities, 7 (6). pp. 3895-3913. ISSN 2624-6511

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Abstract

The convergence of 5G terrestrial networks with satellite systems offers a revolutionary approach to achieving global, seamless connectivity, particularly for Internet of Things (IoT) applications in urban and rural settings. This paper investigates the implications of this 5G-satellite integrated network architecture, specifically through the application of the two-ray propagation model and the Free-Space Path Loss (FSPL) model. By simulating signal characteristics over varying distances, altitudes, and environmental parameters, we explore how factors such as transmitter height, satellite altitude, and frequency impact received power, path loss, channel capacity, and outage probability. Key findings indicate that received power decreases significantly with increasing distance, with notable oscillations in the two-ray model due to interference from ground reflections, particularly evident within the first 100 km. For example, at 50 km, a 300 km satellite altitude yields approximately -115 dBm in received power, while at 1000 km altitude, this power drops to around -136 dBm. Higher frequencies (e.g., 32 GHz) exhibit greater path loss than lower frequencies (e.g., 24 GHz), with a 5 dB difference observed at 1000 km, reinforcing the need for frequency considerations in long-range communication design. In terms of channel capacity, increasing bandwidth enhances achievable data rates but declines with distance due to diminishing received power. At 100 km, a 50 MHz bandwidth supports up to 4500 Mbps, while at 3000 km, capacity drops to around 300 Mbps. The outage probability analysis shows that higher Signal-to-Noise Ratio (SNR) thresholds substantially increase the likelihood of communication failures, especially at distances exceeding 2000 km. For instance, at 3000 km, the outage probability for a 15 dB SNR threshold reaches approximately 25%, compared to less than 5% for a 5 dB threshold. These results underscore the critical trade-offs in designing 5G-satellite IoT networks, balancing bandwidth, frequency, SNR thresholds, and satellite altitudes for optimal performance across diverse IoT applications. The analysis provides valuable insights for enhancing connectivity and reliability in 5G-satellite integrated network, especially in remote and underserved regions.