Channel Modeling and Performance Analysis of Airplane-Satellite Terahertz Band Communications

Joonas Kokkoniemi; Josep M. Jornet; Vitaly Petrov; Yevgeni Koucheryavy; Markku Juntti

doi:10.1109/TVT.2021.3058581

Channel Modeling and Performance Analysis of Airplane-Satellite Terahertz Band Communications

Joonas Kokkoniemi^*
, Josep M. Jornet
, Vitaly Petrov
, Yevgeni Koucheryavy
, Markku Juntti

^*Corresponding author for this work

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

79 Citations (Scopus)

13 Downloads (Pure)

Abstract

Wireless connectivity in airplanes is becoming more important, demanded, and common. One of the largest bottlenecks with the in-flight Internet is that the airplane is far away from both the satellites and the ground base stations during most of the flight time. Maintaining a reliable and high-rate wireless connection with the airplane over such a long-range link thus becomes a challenge. Microwave frequencies allow for long link distances but lack the data rate to serve up to several hundreds of potential onboard customers. Higher bands in the millimeter-wave spectrum (30 GHz-300 GHz) have, therefore, been utilized to overcome the bandwidth limitations. Still, the per-user throughput with state-of-the-art millimeter-wave systems is an order of magnitude lower than the one available with terrestrial wireless networks. In this paper, we take a step further and study the channel characteristics for the terahertz band (THz, 0.3 THz-10 THz) in order to map the feasibility of this band for aviation. We first propose a detailed channel model for aerial THz communications taking into account both the non-flat Earth geometry and the main features of the frequency-selective THz channel. We then apply this model to estimate the characteristics of aerial THz links in different conditions. We finally determine the altitudes where the use of airplane-to-satellite THz connection becomes preferable over the airplane-to-ground THz link. Our results reveal that the capacity of the airborne THz link may reach speeds ranging from 50-150 Gbps, thus enabling cellular-equivalent data rates to the passengers and staff during the entire flight.

Original language	English
Pages (from-to)	2047-2061
Number of pages	15
Journal	IEEE Transactions on Vehicular Technology
Volume	70
Issue number	3
DOIs	https://doi.org/10.1109/TVT.2021.3058581
Publication status	Published - Mar 2021
Publication type	A1 Journal article-refereed

Funding

Manuscript received September 13, 2020; revised January 2, 2021; accepted January 28, 2021. Date of publication February 10, 2021; date of current version April 2, 2021. This work was supported in part by the Horizon 2020, European Union’s Framework Programme for Research and Innovation, under Grant Agreement Nos. 761794 (TERRANOVA) and 871464 (ARIADNE), in part by the Academy of Finland 6Genesis Flagship under Grant 318927, and in part by the US Air Force Research Laboratory Grant FA8750-20-1-0200. The review of this article was coordinated by Prof. J. Joung. (Corresponding author: Joonas Kokkoniemi.) Joonas Kokkoniemi and Markku Juntti are with the Centre for Wireless Communications, University of Oulu, Oulu 90014, Finland (e-mail: [email protected]; [email protected]).

Keywords

Airplane communications
satellite communications
THz channel modeling
THz communications

Publication forum classification

Publication forum level 3

ASJC Scopus subject areas

Automotive Engineering
Aerospace Engineering
Electrical and Electronic Engineering
Applied Mathematics

Access to Document

10.1109/TVT.2021.3058581Licence: CC BY

Channel Modeling and Performance Analysis 2021
CC BY
Final published version, 4.29 MBLicence: CC BY

http://urn.fi/URN:NBN:fi:tuni-202105285531Licence: CC BY

Cite this

@article{d945bacd604843e5be1590be48067832,

title = "Channel Modeling and Performance Analysis of Airplane-Satellite Terahertz Band Communications",

abstract = "Wireless connectivity in airplanes is becoming more important, demanded, and common. One of the largest bottlenecks with the in-flight Internet is that the airplane is far away from both the satellites and the ground base stations during most of the flight time. Maintaining a reliable and high-rate wireless connection with the airplane over such a long-range link thus becomes a challenge. Microwave frequencies allow for long link distances but lack the data rate to serve up to several hundreds of potential onboard customers. Higher bands in the millimeter-wave spectrum (30 GHz-300 GHz) have, therefore, been utilized to overcome the bandwidth limitations. Still, the per-user throughput with state-of-the-art millimeter-wave systems is an order of magnitude lower than the one available with terrestrial wireless networks. In this paper, we take a step further and study the channel characteristics for the terahertz band (THz, 0.3 THz-10 THz) in order to map the feasibility of this band for aviation. We first propose a detailed channel model for aerial THz communications taking into account both the non-flat Earth geometry and the main features of the frequency-selective THz channel. We then apply this model to estimate the characteristics of aerial THz links in different conditions. We finally determine the altitudes where the use of airplane-to-satellite THz connection becomes preferable over the airplane-to-ground THz link. Our results reveal that the capacity of the airborne THz link may reach speeds ranging from 50-150 Gbps, thus enabling cellular-equivalent data rates to the passengers and staff during the entire flight.",

keywords = "Airplane communications, satellite communications, THz channel modeling, THz communications",

author = "Joonas Kokkoniemi and Jornet, \{Josep M.\} and Vitaly Petrov and Yevgeni Koucheryavy and Markku Juntti",

note = "Funding Information: Manuscript received September 13, 2020; revised January 2, 2021; accepted January 28, 2021. Date of publication February 10, 2021; date of current version April 2, 2021. This work was supported in part by the Horizon 2020, European Union{\textquoteright}s Framework Programme for Research and Innovation, under Grant Agreement Nos. 761794 (TERRANOVA) and 871464 (ARIADNE), in part by the Academy of Finland 6Genesis Flagship under Grant 318927, and in part by the US Air Force Research Laboratory Grant FA8750-20-1-0200. The review of this article was coordinated by Prof. J. Joung. (Corresponding author: Joonas Kokkoniemi.) Joonas Kokkoniemi and Markku Juntti are with the Centre for Wireless Communications, University of Oulu, Oulu 90014, Finland (e-mail: [email protected]; [email protected]). Publisher Copyright: {\textcopyright} 1967-2012 IEEE.",

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volume = "70",

pages = "2047--2061",

journal = "IEEE Transactions on Vehicular Technology",

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publisher = "Institute of Electrical and Electronics Engineers Inc.",

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T1 - Channel Modeling and Performance Analysis of Airplane-Satellite Terahertz Band Communications

AU - Kokkoniemi, Joonas

AU - Jornet, Josep M.

AU - Petrov, Vitaly

AU - Koucheryavy, Yevgeni

AU - Juntti, Markku

N1 - Funding Information: Manuscript received September 13, 2020; revised January 2, 2021; accepted January 28, 2021. Date of publication February 10, 2021; date of current version April 2, 2021. This work was supported in part by the Horizon 2020, European Union’s Framework Programme for Research and Innovation, under Grant Agreement Nos. 761794 (TERRANOVA) and 871464 (ARIADNE), in part by the Academy of Finland 6Genesis Flagship under Grant 318927, and in part by the US Air Force Research Laboratory Grant FA8750-20-1-0200. The review of this article was coordinated by Prof. J. Joung. (Corresponding author: Joonas Kokkoniemi.) Joonas Kokkoniemi and Markku Juntti are with the Centre for Wireless Communications, University of Oulu, Oulu 90014, Finland (e-mail: [email protected]; [email protected]). Publisher Copyright: © 1967-2012 IEEE.

PY - 2021/3

Y1 - 2021/3

N2 - Wireless connectivity in airplanes is becoming more important, demanded, and common. One of the largest bottlenecks with the in-flight Internet is that the airplane is far away from both the satellites and the ground base stations during most of the flight time. Maintaining a reliable and high-rate wireless connection with the airplane over such a long-range link thus becomes a challenge. Microwave frequencies allow for long link distances but lack the data rate to serve up to several hundreds of potential onboard customers. Higher bands in the millimeter-wave spectrum (30 GHz-300 GHz) have, therefore, been utilized to overcome the bandwidth limitations. Still, the per-user throughput with state-of-the-art millimeter-wave systems is an order of magnitude lower than the one available with terrestrial wireless networks. In this paper, we take a step further and study the channel characteristics for the terahertz band (THz, 0.3 THz-10 THz) in order to map the feasibility of this band for aviation. We first propose a detailed channel model for aerial THz communications taking into account both the non-flat Earth geometry and the main features of the frequency-selective THz channel. We then apply this model to estimate the characteristics of aerial THz links in different conditions. We finally determine the altitudes where the use of airplane-to-satellite THz connection becomes preferable over the airplane-to-ground THz link. Our results reveal that the capacity of the airborne THz link may reach speeds ranging from 50-150 Gbps, thus enabling cellular-equivalent data rates to the passengers and staff during the entire flight.

AB - Wireless connectivity in airplanes is becoming more important, demanded, and common. One of the largest bottlenecks with the in-flight Internet is that the airplane is far away from both the satellites and the ground base stations during most of the flight time. Maintaining a reliable and high-rate wireless connection with the airplane over such a long-range link thus becomes a challenge. Microwave frequencies allow for long link distances but lack the data rate to serve up to several hundreds of potential onboard customers. Higher bands in the millimeter-wave spectrum (30 GHz-300 GHz) have, therefore, been utilized to overcome the bandwidth limitations. Still, the per-user throughput with state-of-the-art millimeter-wave systems is an order of magnitude lower than the one available with terrestrial wireless networks. In this paper, we take a step further and study the channel characteristics for the terahertz band (THz, 0.3 THz-10 THz) in order to map the feasibility of this band for aviation. We first propose a detailed channel model for aerial THz communications taking into account both the non-flat Earth geometry and the main features of the frequency-selective THz channel. We then apply this model to estimate the characteristics of aerial THz links in different conditions. We finally determine the altitudes where the use of airplane-to-satellite THz connection becomes preferable over the airplane-to-ground THz link. Our results reveal that the capacity of the airborne THz link may reach speeds ranging from 50-150 Gbps, thus enabling cellular-equivalent data rates to the passengers and staff during the entire flight.

KW - Airplane communications

KW - satellite communications

KW - THz channel modeling

KW - THz communications

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DO - 10.1109/TVT.2021.3058581

M3 - Article

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SN - 0018-9545

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JO - IEEE Transactions on Vehicular Technology

JF - IEEE Transactions on Vehicular Technology

IS - 3

ER -

Channel Modeling and Performance Analysis of Airplane-Satellite Terahertz Band Communications

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