Abstract
Low earth orbit mobile satellite system (LEO-MSS) is the major system to provide communication support for mobile terminals beyond the coverage of terrestrial communication systems. However, the quick movement of LEO satellites and current single-layer system architecture impose restrictions on the capability to provide satisfactory service quality, especially for the remote and non-land regions with high traffic requirement. To tackle this problem, high-altitude platforms (HAPs) and terrestrial relays (TRs) are introduced to cover hot-spot regions, and the current single-layer system becomes an LEO-HAP multi-layer access network. Under this setup, we propose a hierarchical resource allocation approach to circumvent the complex management caused by the intricate relationships among different layers. Specifically, to maximize the throughputs, we propose a dynamic multi-beam joint resource optimization method in LEO-ground downlinks based on the predicted movement of LEO satellites. Afterwards, we propose the dynamic resource optimization method of HAP-ground downlinks when LEO satellites and HAPs share the same spectrum. To solve these problems, we use the Lagrange dual method and Karush-Kuhn-Tucker (KKT) conditions to find the optimal solutions. Numerical results show that the proposed architecture outperforms current LEO-MSS in terms of average capacity. In addition, the proposed optimization methods increase the throughputs of LEO-ground downlinks and HAP-ground downlinks with an acceptable complexity.
Highlights
We implement simulations to compare the average throughputs of the proposed forecast-based multi-beam joint dynamic radio resource optimization method with different parameters and services in low earth orbit (LEO) satellites and high-altitude platforms (HAPs)
DIRECTION In this paper, we focused on improving the network capacity of the regions beyond the coverage of terrestrial communication systems
As Low earth orbit mobile satellite system (LEO-MSS) can not provide enough capacity especially in hot-spot regions, we proposed an extended multi-layer network architecture based on multi-beam LEOMSS by introducing HAPs and terrestrial relays (TRs) to cover hot-spot regions, and analyzed the capacity improvement with different parameters
Summary
C. CONTRIBUTIONS In this paper, we focus on improving the network capacity of the regions beyond the coverage of terrestrial communications by proposing a multi-layer architecture based on LEO-MSS and optimizing its resource allocation. RADIO RESOURCE MANAGEMENT OPTIMIZATION METHOD Due to the benefits of HAPs and TRs explained in II-B.3, the presented extensible multilayer LEO-MSS architecture provides better performance on the average capacity of spaceair-ground links. LEO satellites send control signallings to inform HAPs and MTs the time of receiving data With this scheme, the interference of different beams in the actual system can be calculated accurately.
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