2020
2.
Yeom, Jeong Seon; Noh, Gosan; Chung, Heesang; Kim, Ilgyu; Jung, Bang Chul
Performance analysis of satellite and terrestrial spectrum-shared networks with directional antenna Journal Article
In: ETRI Journal, vol. 42, no. 5, pp. 712–720, 2020.
Abstract | Links | BibTeX | Tags: cognitive satellite-terrestrial network, poisson point process, spectrum sharing, stochastic geometry, success probability
@article{Yeom2020,
title = {Performance analysis of satellite and terrestrial spectrum-shared networks with directional antenna},
author = {Jeong Seon Yeom and Gosan Noh and Heesang Chung and Ilgyu Kim and Bang Chul Jung
},
doi = {10.4218/etrij.2020-0185},
year = {2020},
date = {2020-11-16},
urldate = {2020-11-16},
journal = {ETRI Journal},
volume = {42},
number = {5},
pages = {712--720},
abstract = {Abstract Recently, to make the best use of limited and precious spectrum resources, spectrum sharing between satellite and cellular networks has received much interest. In this study, we mathematically analyze the success probability of a fixed (satellite) earth station (FES) based on a stochastic geometry framework. Both the FES and base stations (BSs) are assumed to be equipped with a directional antenna, and the location and the number of BSs are modeled based on the Poisson point process. Furthermore, an exclusion zone is considered, in which the BSs are prohibited from locating in a circular zone with a certain radius around the FES to protect it from severe interference from the cellular BSs. We validate the analytical results on the success probability of the cognitive satellite-terrestrial network with directional antennas by comparing it using extensive computer simulations and show the effect of the exclusion zone on the success probability at the FES. It is shown that the exclusion zone-based interference mitigation technique significantly improves the success probability as the exclusion zone increases.},
keywords = {cognitive satellite-terrestrial network, poisson point process, spectrum sharing, stochastic geometry, success probability},
pubstate = {published},
tppubtype = {article}
}
Abstract Recently, to make the best use of limited and precious spectrum resources, spectrum sharing between satellite and cellular networks has received much interest. In this study, we mathematically analyze the success probability of a fixed (satellite) earth station (FES) based on a stochastic geometry framework. Both the FES and base stations (BSs) are assumed to be equipped with a directional antenna, and the location and the number of BSs are modeled based on the Poisson point process. Furthermore, an exclusion zone is considered, in which the BSs are prohibited from locating in a circular zone with a certain radius around the FES to protect it from severe interference from the cellular BSs. We validate the analytical results on the success probability of the cognitive satellite-terrestrial network with directional antennas by comparing it using extensive computer simulations and show the effect of the exclusion zone on the success probability at the FES. It is shown that the exclusion zone-based interference mitigation technique significantly improves the success probability as the exclusion zone increases.
1.
Cassiau, Nicolas; Noh, Gosan; Jaeckel, Stephan; Raschkowski, Leszek; Houssin, Jean-Michel; Combelles, Laurent; Thary, Marjorie; Kim, Junhyeong; Doré, Jean-Baptiste; Laugeois, Marc
Satellite and terrestrial multi-connectivity for 5G: making spectrum sharing possible Proceedings Article
In: IEEE Wireless Communications and Networking Conference (WCNC 2020), Seoul, South Korea, 2020.
Abstract | Links | BibTeX | Tags: 5G, multi-connectivity, satellite, spectrum sharing
@inproceedings{cassiau:hal-02864733,
title = {Satellite and terrestrial multi-connectivity for 5G: making spectrum sharing possible},
author = {Nicolas Cassiau and Gosan Noh and Stephan Jaeckel and Leszek Raschkowski and Jean-Michel Houssin and Laurent Combelles and Marjorie Thary and Junhyeong Kim and Jean-Baptiste Dor\'{e} and Marc Laugeois},
url = {https://hal.archives-ouvertes.fr/hal-02864733},
year = {2020},
date = {2020-01-01},
urldate = {2020-01-01},
booktitle = {IEEE Wireless Communications and Networking Conference (WCNC 2020)},
address = {Seoul, South Korea},
abstract = {This paper reports the first results of the 5G-ALLSTAR project [1] aiming at providing solutions and enablers for spectrum sharing in a 5G cellular and satellite multi-connectivity context. First, we present an exhaustive study of the frequency bands eligible for these systems in the short and medium term. A ray-tracing based and a geometry-based stochastic channel models developed in the project are then described. These models can be used to simulate systems involving terrestrial and non-terrestrial networks. We then describe three different ways investigated in the project for managing interference: signal processing (hardware implementation of a 5G New Radio compatible physical layer), beamforming (steering and switching beams in order to avoid the interference while preserving the spectral efficiency) and radio resource management (tool designed for joint optimization of satellite and terrestrial resource sharing).},
keywords = {5G, multi-connectivity, satellite, spectrum sharing},
pubstate = {published},
tppubtype = {inproceedings}
}
This paper reports the first results of the 5G-ALLSTAR project [1] aiming at providing solutions and enablers for spectrum sharing in a 5G cellular and satellite multi-connectivity context. First, we present an exhaustive study of the frequency bands eligible for these systems in the short and medium term. A ray-tracing based and a geometry-based stochastic channel models developed in the project are then described. These models can be used to simulate systems involving terrestrial and non-terrestrial networks. We then describe three different ways investigated in the project for managing interference: signal processing (hardware implementation of a 5G New Radio compatible physical layer), beamforming (steering and switching beams in order to avoid the interference while preserving the spectral efficiency) and radio resource management (tool designed for joint optimization of satellite and terrestrial resource sharing).