Fake Base Station Detection and Localization in 5G Network: A Proof of Concept

Danmarl Butad; Steven Matthew Tao; Harlee Tudtud; Alvin Joseph Macapagal; Philip Virgil Astillo; Gaurav Choudhary; Nicola Dragoni

doi:10.1007/978-981-97-4465-7_1

Fake Base Station Detection and Localization in 5G Network: A Proof of Concept

Danmarl Butad, Steven Matthew Tao, Harlee Tudtud, Alvin Joseph Macapagal, Philip Virgil Astillo, Gaurav Choudhary^*, Nicola Dragoni

^*Kontaktforfatter

Publikation: Kapitel i bog/rapport/konference-proceeding › Konferencebidrag i proceedings › Forskning › peer review

Abstract

One of the key features adopted in 5G network to achieve the requirements is the new millimeter-wave radio signal, which has limited coverage and low power penetration in nature. Consequently, there will be relatively more number of base station that will be deployed, thus, makes the transfer of point of attachments more frequent that its predecessors in achieving continuous connectivity of a user equipment (UE). Unfortunately, this scenario opens new security challenge against Fake base station, in which UEs can be at risk when transferred to these base stations. The aim of this study is to mitigate UE attachments against fake base stations through threshold-based detection and localization. The detection results showed low errors in various test scenarios. The proposed detection method achieved 95.94% precision, 100% recall, and 96.40% accuracy. Also, the proposed localization technique effectively locates the Fake Base Stations with low percentage errors. In both method, the UE quantity affects the performance, i.e., the performances improved as the number of UE increases. The effective performance rates potentially fortify the securities of 5G Network.

Originalsprog	Engelsk
Titel	Mobile Internet Security : 7th International Conference, MobiSec 2023, Revised Selected Papers
Redaktører	Ilsun You, Michal Choras, Seonghan Shin, Hwankuk Kim, Philip Virgil Astillo
Forlag	Springer Science+Business Media
Publikationsdato	2024
Sider	3-17
ISBN (Trykt)	9789819744640
DOI	https://doi.org/10.1007/978-981-97-4465-7_1
Status	Udgivet - 2024
Begivenhed	7th International Conference on Mobile Internet Security, MobiSec 2023 - Okinawa, Japan Varighed: 19. dec. 2023 → 21. dec. 2023

Konference

Konference	7th International Conference on Mobile Internet Security, MobiSec 2023
Land/Område	Japan
By	Okinawa
Periode	19/12/2023 → 21/12/2023

Navn	Communications in Computer and Information Science
Vol/bind	2095 CCIS
ISSN	1865-0929

Bibliografisk note

Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.

Dokumenter og links

10.1007/978-981-97-4465-7_1

SDU link

Tjek adgangen til materialet i Syddansk Universitetsbiblioteks søgemaskine

Andre filer og links

False_based_Station_Detection_and_Localization_in_5G___CCIS_Format (1)

Citationsformater

Butad, D., Tao, S. M., Tudtud, H., Macapagal, A. J., Astillo, P. V., Choudhary, G., & Dragoni, N. (2024). Fake Base Station Detection and Localization in 5G Network: A Proof of Concept. I I. You, M. Choras, S. Shin, H. Kim, & P. V. Astillo (red.), Mobile Internet Security : 7th International Conference, MobiSec 2023, Revised Selected Papers (s. 3-17). Springer Science+Business Media. https://doi.org/10.1007/978-981-97-4465-7_1

Butad, Danmarl ; Tao, Steven Matthew ; Tudtud, Harlee et al. / Fake Base Station Detection and Localization in 5G Network : A Proof of Concept. Mobile Internet Security : 7th International Conference, MobiSec 2023, Revised Selected Papers. red. / Ilsun You ; Michal Choras ; Seonghan Shin ; Hwankuk Kim ; Philip Virgil Astillo. Springer Science+Business Media, 2024. s. 3-17 (Communications in Computer and Information Science, Bind 2095 CCIS).

@inproceedings{df70254770854ba7b129a9fe1c978c00,

title = "Fake Base Station Detection and Localization in 5G Network: A Proof of Concept",

abstract = "One of the key features adopted in 5G network to achieve the requirements is the new millimeter-wave radio signal, which has limited coverage and low power penetration in nature. Consequently, there will be relatively more number of base station that will be deployed, thus, makes the transfer of point of attachments more frequent that its predecessors in achieving continuous connectivity of a user equipment (UE). Unfortunately, this scenario opens new security challenge against Fake base station, in which UEs can be at risk when transferred to these base stations. The aim of this study is to mitigate UE attachments against fake base stations through threshold-based detection and localization. The detection results showed low errors in various test scenarios. The proposed detection method achieved 95.94\% precision, 100\% recall, and 96.40\% accuracy. Also, the proposed localization technique effectively locates the Fake Base Stations with low percentage errors. In both method, the UE quantity affects the performance, i.e., the performances improved as the number of UE increases. The effective performance rates potentially fortify the securities of 5G Network.",

keywords = "5G Networks, 5G-Lena, Fake Base Station, Handover, Intrusion Detection, Localization",

author = "Danmarl Butad and Tao, \{Steven Matthew\} and Harlee Tudtud and Macapagal, \{Alvin Joseph\} and Astillo, \{Philip Virgil\} and Gaurav Choudhary and Nicola Dragoni",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.; 7th International Conference on Mobile Internet Security, MobiSec 2023 ; Conference date: 19-12-2023 Through 21-12-2023",

year = "2024",

doi = "10.1007/978-981-97-4465-7\_1",

language = "English",

isbn = "9789819744640",

series = "Communications in Computer and Information Science",

publisher = "Springer Science+Business Media",

pages = "3--17",

editor = "Ilsun You and Michal Choras and Seonghan Shin and Hwankuk Kim and Astillo, \{Philip Virgil\}",

booktitle = "Mobile Internet Security",

address = "United States",

}

Butad, D, Tao, SM, Tudtud, H, Macapagal, AJ, Astillo, PV, Choudhary, G & Dragoni, N 2024, Fake Base Station Detection and Localization in 5G Network: A Proof of Concept. i I You, M Choras, S Shin, H Kim & PV Astillo (red), Mobile Internet Security : 7th International Conference, MobiSec 2023, Revised Selected Papers. Springer Science+Business Media, Communications in Computer and Information Science, bind 2095 CCIS, s. 3-17, 7th International Conference on Mobile Internet Security, MobiSec 2023, Okinawa, Japan, 19/12/2023. https://doi.org/10.1007/978-981-97-4465-7_1

Fake Base Station Detection and Localization in 5G Network: A Proof of Concept. / Butad, Danmarl; Tao, Steven Matthew; Tudtud, Harlee et al.
Mobile Internet Security : 7th International Conference, MobiSec 2023, Revised Selected Papers. red. / Ilsun You; Michal Choras; Seonghan Shin; Hwankuk Kim; Philip Virgil Astillo. Springer Science+Business Media, 2024. s. 3-17 (Communications in Computer and Information Science, Bind 2095 CCIS).

Publikation: Kapitel i bog/rapport/konference-proceeding › Konferencebidrag i proceedings › Forskning › peer review

TY - GEN

T1 - Fake Base Station Detection and Localization in 5G Network

T2 - 7th International Conference on Mobile Internet Security, MobiSec 2023

AU - Butad, Danmarl

AU - Tao, Steven Matthew

AU - Tudtud, Harlee

AU - Macapagal, Alvin Joseph

AU - Astillo, Philip Virgil

AU - Choudhary, Gaurav

AU - Dragoni, Nicola

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.

PY - 2024

Y1 - 2024

N2 - One of the key features adopted in 5G network to achieve the requirements is the new millimeter-wave radio signal, which has limited coverage and low power penetration in nature. Consequently, there will be relatively more number of base station that will be deployed, thus, makes the transfer of point of attachments more frequent that its predecessors in achieving continuous connectivity of a user equipment (UE). Unfortunately, this scenario opens new security challenge against Fake base station, in which UEs can be at risk when transferred to these base stations. The aim of this study is to mitigate UE attachments against fake base stations through threshold-based detection and localization. The detection results showed low errors in various test scenarios. The proposed detection method achieved 95.94% precision, 100% recall, and 96.40% accuracy. Also, the proposed localization technique effectively locates the Fake Base Stations with low percentage errors. In both method, the UE quantity affects the performance, i.e., the performances improved as the number of UE increases. The effective performance rates potentially fortify the securities of 5G Network.

AB - One of the key features adopted in 5G network to achieve the requirements is the new millimeter-wave radio signal, which has limited coverage and low power penetration in nature. Consequently, there will be relatively more number of base station that will be deployed, thus, makes the transfer of point of attachments more frequent that its predecessors in achieving continuous connectivity of a user equipment (UE). Unfortunately, this scenario opens new security challenge against Fake base station, in which UEs can be at risk when transferred to these base stations. The aim of this study is to mitigate UE attachments against fake base stations through threshold-based detection and localization. The detection results showed low errors in various test scenarios. The proposed detection method achieved 95.94% precision, 100% recall, and 96.40% accuracy. Also, the proposed localization technique effectively locates the Fake Base Stations with low percentage errors. In both method, the UE quantity affects the performance, i.e., the performances improved as the number of UE increases. The effective performance rates potentially fortify the securities of 5G Network.

KW - 5G Networks

KW - 5G-Lena

KW - Fake Base Station

KW - Handover

KW - Intrusion Detection

KW - Localization

U2 - 10.1007/978-981-97-4465-7_1

DO - 10.1007/978-981-97-4465-7_1

M3 - Article in proceedings

AN - SCOPUS:85200759858

SN - 9789819744640

T3 - Communications in Computer and Information Science

SP - 3

EP - 17

BT - Mobile Internet Security

A2 - You, Ilsun

A2 - Choras, Michal

A2 - Shin, Seonghan

A2 - Kim, Hwankuk

A2 - Astillo, Philip Virgil

PB - Springer Science+Business Media

Y2 - 19 December 2023 through 21 December 2023

ER -

Butad D, Tao SM, Tudtud H, Macapagal AJ, Astillo PV, Choudhary G et al. Fake Base Station Detection and Localization in 5G Network: A Proof of Concept. I You I, Choras M, Shin S, Kim H, Astillo PV, red., Mobile Internet Security : 7th International Conference, MobiSec 2023, Revised Selected Papers. Springer Science+Business Media. 2024. s. 3-17. (Communications in Computer and Information Science, Bind 2095 CCIS). doi: 10.1007/978-981-97-4465-7_1