research-article

TONARI: Reactive Detection of Close Physical Contact Using Unlicensed LPWAN Signals

Authors:

Chenglong Shao,

Osamu MutaAuthors Info & Claims

ACM Transactions on Internet of Things, Volume 5, Issue 2

Article No.: 13, Pages 1 - 30

https://doi.org/10.1145/3648572

Published: 23 April 2024 Publication History

Abstract

Recognizing if two objects are in close physical contact (CPC) is the basis of various Internet-of-Things services such as vehicle proximity alert and radiation exposure reduction. This is achieved traditionally through tailor-made proximity sensors that proactively transmit wireless signals and analyze the reflection from an object. Despite its feasibility, the past few years have witnessed the prosperity of reactive CPC detection techniques that do not need spontaneous signal transmission and merely exploit received wireless signals from a target. Unlike existing approaches entailing additional effort of multiple antennas, dedicated signal emitters, human intervention, or a back-end server, this article presents TONARI, an effortless CPC detection framework that performs in a reactive manner. TONARI is developed for the first time with LoRa, the representative of unlicensed low-power wide area network (LPWAN) technologies, as the wireless signal for CPC detection. At the heart of TONARI lies a novel feature arbitrator that decides whether two devices are in CPC or not by distinguishing different types of LoRa chirp-based additive sample magnitude sequences. Software-defined radio-based experiments are conducted to show that the achievable CPC detection accuracy via TONARI can reach 100% in most practical cases.

References

[1]

Actility. 2021. Olympus Adopts Proximity Detection and Contact Tracing in its Japanese Factories to Fight Against COVID-19 using LoRaWAN. Retrieved from https://www.actility.com/olympus-adopts-proximity-detection-and-contact-tracing-in-its-japanese-factories-to-fight-against-covid-19-using-lorawan/

[2]

Amazon Sidewalk. 2023. Retrieved from https://docs.aws.amazon.com/iot/latest/developerguide/amazon-sidewalk-overview.html

[3]

Apple and Google. 2023. Privacy-preserving contact tracing. Retrieved from https://covid19.apple.com/contacttracing

[4]

Arduino Uno Rev3 microcontroller board. 2023. Retrieved from https://store.arduino.cc/products/arduino-uno-rev3/

[5]

Constantine A. Balanis. 2016. Antenna Theory: Analysis and Design (4th ed.). Wiley.

[6]

Liang Cai, Kai Zeng, Hao Chen, and Prasant Mohapatra. 2011. Good neighbor: Ad hoc pairing of nearby wireless devices by multiple antennas. In Proceedings of NDSS.

[7]

Daniele Croce, Michele Gucciardo, Stefano Mangione, Giuseppe Santaromita, and Ilenia Tinnirello. 2018. Impact of LoRa imperfect orthogonality: Analysis of link-level performance. IEEE Commun. Lett. 22, 4 (Apr.2018), 796–799.

[8]

Dragino Arduino Shield featuring LoRa technology. 2023. Retrieved from https://www.dragino.com/products/lora/item/102-lora-shield.html

[9]

Ettus Research UBX 10-6000 MHz Rx/Tx (40 MHz, N Series and X Series). 2023. Retrieved from https://www.ettus.com/all-products/ubx40/

[10]

Ettus Research USRP N210 software defined radio. 2023. Retrieved from https://www.ettus.com/all-products/un210-kit/

[11]

Ettus Research VERT900 antenna. 2023. Retrieved from https://www.ettus.com/all-products/vert900/

[12]

Avik Ghose, Chirabrata Bhaumik, and Tapas Chakravarty. 2013. BlueEye: A system for proximity detection using Bluetooth on mobile phones. In Proceedings of ACM UbiComp Adjunct.

Digital Library

[13]

Great Scott Gadgets HackRF One. 2023. https://greatscottgadgets.com/hackrf/one/

[14]

Andreas Hoglund, Johan Bergman, Xingqin Lin, Olof Liberg, Antti Ratilainen, Hazhir Shokri Razaghi, Tuomas Tirronen, and Emre A. Yavuz. 2018. Overview of 3GPP release 14 further enhanced MTC. IEEE Commun. Stand. Mag. 2, 2 (June2018), 84–89.

[15]

HopeRF RFM95/96/97/98(W) datasheet. 2023. Retrieved from https://cdn.sparkfun.com/assets/learn_tutorials/8/0/4/RFM95\_96_97_98W.pdf

[16]

Chitra Javali, Girish Revadigar, Lavy Libman, and Sanjay Jha. 2014. SeAK: Secure authentication and key generation protocol based on dual antennas for wireless body area networks. In Proceedings of RFIDSec.

[17]

Rong Jin, Liu Shi, Kai Zeng, Amit Pande, and Prasant Mohapatra. 2016. MagPairing: Pairing smartphones in close proximity using magnetometers. IEEE Trans. Info. Forens. Secur. 11, 6 (June2016), 1306–1320.

Digital Library

[18]

Mohammed Jouhari, El Mehdi Amhoud, Nasir Saeed, and Mohamed-Slim Alouini. 2022. A survey on scalable LoRaWAN for massive IoT: Recent advances, potentials, and challenges. Retrieved from https://arXiv:2202.11082

[19]

Andre Kalamandeen, Adin Scannell, Eyal de Lara, Anmol Sheth, and Anthony LaMarca. 2010. Ensemble: Cooperative proximity-based authentication. In Proceedings of ACM MobiSys.

Digital Library

[20]

Matthieu Kanj, Vincent Savaux, and Mathieu Le Guen. 2020. A tutorial on NB-IoT physical layer design. IEEE Commun. Surveys Tutor. 22, 4 (2020), 2408–2446.

[21]

Srinivasan Keshav. 2012. Mathematical Foundations of Computer Networking. Addison-Wesley.

Digital Library

[22]

Chenning Li and Zhichao Cao. 2022. LoRa networking techniques for large-scale and long-term IoT: A down-to-top survey. ACM Comput. Surveys 55, 3, Article 52 (Feb.2022), 36 pages.

[23]

LoRa Alliance. 2018. LoRaWAN 1.0.3 Specification. LoRa Alliance.

[24]

LoRa Alliance. 2019. RP002-1.0.0 LoRaWAN Regional Parameters. LoRa Alliance.

[25]

Nicolai Marquardt and Saul Greenberg. 2015. Proxemic Interactions: From Theory to Practice. Morgan & Claypool.

[26]

Suhas Mathur, Robert Miller, Alexander Varshavsky, Wade Trappe, and Narayan Mandayam. 2011. ProxiMate: Proximity-based secure pairing using ambient wireless signals. In Proceedings of ACM MobiSys.

Digital Library

[27]

Rene Mayrhofer and Hans Gellersen. 2009. Shake well before use: Intuitive and secure pairing of mobile devices. IEEE Trans. Mobile Comput. 8, 6 (June2009), 792–806.

Digital Library

[28]

NUCLEO-L152RE STM32 development board. 2023. Retrieved from https://www.st.com/en/evaluation-tools/nucleo-l152re.html

[29]

Timothy J. Pierson, Xiaohui Liang, Ronald Peterson, and David Kotz. 2016. Wanda: Securely introducing mobile devices. In Proceedings of IEEE INFOCOM.

Digital Library

[30]

Timothy J. Pierson, Travis Peters, Ronald Peterson, and David Kotz. 2019. CloseTalker: Secure, short-range ad hoc wireless communication. In Proceedings of ACM MobiSys.

Digital Library

[31]

Timothy J. Pierson, Travis Peters, Ronald Peterson, and David Kotz. 2019. Proximity detection with single-antenna IoT devices. In Proceedings of ACM MobiCom.

Digital Library

[32]

Timothy J. Pierson, Reza Rawassizadeh, Ronald Peterson, and David Kotz. 2017. Secure information transfer between nearby wireless devices. In Proceedings of ACM S3.

Digital Library

[33]

Charles Platt. 2016. Encyclopedia of Electronic Components Volume 3. Make: Community.

Digital Library

[34]

Adin Scannell, Alexander Varshavsky, Anthony LaMarca, and Eyal De Lara. 2009. Proximity-based authentication of mobile devices. Int. J. Secur. Netw. 4, 1/2 (Feb.2009), 4–16.

Digital Library

[35]

Semtech. 2015. AN1200.22 LoRa modulation basics. Retrieved from https://www.frugalprototype.com/wp-content/uploads/2016/08/an1200.22.pdf

[36]

Semtech. 2017. Smart Cities Transformed using Semtech’s LoRa technology. Retrieved from https://www.semtech.com/uploads/technology/LoRa/Semtech_SmartCitiesTransformed_WhitePaper_FINAL.pdf

[37]

Semtech. 2021. LoRa devices supply chain & logistics geolocation. Retrieved from https://info.semtech.com/lora-geolocation-ebook

[38]

Semtech. 2023. LoRa Technology Is Connecting Our Smart Planet. Retrieved from https://www.semtech.com/lora/lora-applications

[39]

Misbah Shafi, Rakesh Kumar Jha, and Manish Sabraj. 2021. A survey on security issues of 5G NR: Perspective of artificial dust and artificial rain. Retrieved from https://arXiv:2104.03504

[40]

Chenglong Shao, Youngki Kim, and Wonjun Lee. 2020. Zero-effort proximity detection with ZigBee. IEEE Commun. Lett. 24, 9 (Sep.2020), 2047–2050.

[41]

Chenglong Shao and Osamu Muta. 2021. Dude, are you approaching me? Detecting close physical contact via unlicensed LPWAN signals. In Proceedings of IEEE ICC Workshop—Internet of Mobile Things.

[42]

Chenglong Shao, Osamu Muta, Wenjie Wang, and Wonjun Lee. 2021. Toward ubiquitous connectivity via LoRaWAN: An overview of signal collision resolving solutions. IEEE Internet Things Mag. 4, 4 (Dec.2021), 114–119.

[43]

Sigfox. 2018. Sigfox technical overview. Retrieved from https://www.avnet.com/wps/wcm/connect/onesite/03aebfe2-98f7-4c28-be5f-90638c898009/sigfox-technical-overview.pdf?MOD=AJPERES&CVID=magVa.N&CVID=magVa.N&CVID=magVa.N

[44]

Zehua Sun, Huanqi Yang, Kai Liu, Zhimeng Yin, Zhenjiang Li, and Weitao Xu. 2022. Recent advances in LoRa: A comprehensive survey. ACM Trans. Sensor Netw. 18, 4, Article 67 (Nov.2022), 44 pages.

Digital Library

[45]

SX126xMB2xAS Mbed LoRa shield. 2023. Retrieved from https://os.mbed.com/components/SX126xMB2xAS/

[46]

SX1272MB2xAS/SX1272MB2DAS Mbed LoRa shield. 2023. Retrieved from https://os.mbed.com/components/SX1272MB2xAS/

[47]

Joachim Tapparel. 2019. Complete Reverse Engineering of LoRa PHY. Technical Report. EPFL, Lausanne, Switzerland.

[48]

Joachim Tapparel, Orion Afisiadis, Paul Mayoraz, Alexios Balatsoukas-Stimming, and Andreas Burg. 2020. An open-source LoRa physical layer prototype on GNU Radio. Retrieved from https://arXiv:2002.08208

[49]

Alex Varshavsky, Adin Scannell, Anthony LaMarca, and Eyal de Lara. 2007. Amigo: Proximity-based authentication of mobile devices. In Proceedings of UbiComp.

[50]

Fu Yu, Xiaolong Zheng, Liang Liu, and Huadong Ma. 2023. Enabling concurrency for non-orthogonal LoRa channels. In Proceedings of ACM MobiCom.

Digital Library

[51]

Jiansong Zhang, Zeyu Wang, Zhice Yang, and Qian Zhang. 2017. Proximity based IoT device authentication. In Proceedings of IEEE INFOCOM.

Cited By

Yu SXia XZhang ZHou NZheng YShu YLiu JTan RHe YChen J(2024)FDLoRa: Tackling Downlink-Uplink Asymmetry with Full-duplex LoRa GatewaysProceedings of the 22nd ACM Conference on Embedded Networked Sensor Systems10.1145/3666025.3699338(281-294)Online publication date: 4-Nov-2024
https://dl.acm.org/doi/10.1145/3666025.3699338

Index Terms

TONARI: Reactive Detection of Close Physical Contact Using Unlicensed LPWAN Signals
1. Human-centered computing
  1. Ubiquitous and mobile computing
    1. Ubiquitous and mobile computing systems and tools

Recommendations

RFC 9011: Static Context Header Compression and Fragmentation (SCHC) over LoRaWAN
Low-Power Wide Area Networks (LPWAN) for Communications of Mobile Sensor Data
SCC '19: Proceedings of the 2nd ACM/EIGSCC Symposium on Smart Cities and Communities

There are multiple options for communication of data to and from mobile sensors. For tracking systems, Global Navigation Satellite System (GNSS) is often used for localization and mobile-phone technologies are used for transmission of data. Low-power ...
A software-defined radio based cognitive radio demonstration over FM band
Recent Advances in Wireless Communications and Networks

In this paper, we present a software-defined radio (SDR) based cognitive radio (CR) implementation and demonstration over the frequency modulation (FM) band. Using GNU Radio as the software platform and USRP (Universal Software Radio Peripheral) SDR ...

Comments

Information & Contributors

Information

Published In

cover image ACM Transactions on Internet of Things

ACM Transactions on Internet of Things Volume 5, Issue 2

May 2024

214 pages

EISSN:2577-6207

DOI:10.1145/3613552

Editor:
Gian Pietro Picco
University of Trento, Italy

Issue’s Table of Contents

Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than the author(s) must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected].

Publisher

Association for Computing Machinery

New York, NY, United States

Journal Family

ACM Journals for the Design of Smart and Connected Systems

Publication History

Published: 23 April 2024

Online AM: 15 February 2024

Accepted: 06 February 2024

Revised: 23 January 2024

Received: 23 October 2023

Published in TIOT Volume 5, Issue 2

Check for updates

Author Tags

Qualifiers

Research-article

Funding Sources

The Telecommunications Advancement Foundation

Contributors

Other Metrics

View Article Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

1
Total Citations
View Citations
143
Total Downloads

Downloads (Last 12 months)123
Downloads (Last 6 weeks)7

Reflects downloads up to 03 Mar 2025

Other Metrics

View Author Metrics

Citations

Cited By

Yu SXia XZhang ZHou NZheng YShu YLiu JTan RHe YChen J(2024)FDLoRa: Tackling Downlink-Uplink Asymmetry with Full-duplex LoRa GatewaysProceedings of the 22nd ACM Conference on Embedded Networked Sensor Systems10.1145/3666025.3699338(281-294)Online publication date: 4-Nov-2024
https://dl.acm.org/doi/10.1145/3666025.3699338

View Options

Login options

Check if you have access through your login credentials or your institution to get full access on this article.

Full Access

Get this Article

View options

PDF

View or Download as a PDF file.

eReader

View online with eReader.

Full Text

View this article in Full Text.

Figures

Tables

Media

View full text|Download PDF

View Issue’s Table of Contents