Impact of Environmental Factors on LoRa 2.4 GHz Time of Flight Ranging Outdoors

Yiqing Zhou; Xule Zhou; Zecan Cheng; Chenao Lu; Junhan Chen; Jiahong Pan; Yizhuo Liu; Sihao Li; Kyeong Soo Kim

Impact of Environmental Factors on LoRa 2.4 GHz Time of Flight Ranging Outdoors

Yiqing Zhou, Xule Zhou, Zecan Cheng, Chenao Lu, Junhan Chen, Jiahong Pan, Yizhuo Liu, Sihao Li^*, Kyeong Soo Kim^*

^*Corresponding author for this work

Department of Communications and Networking

Research output: Contribution to conference › Paper › peer-review

Abstract

In WSN/IoT, node localization is essential to long-running applications for accurate environment monitoring and event detection, often covering a large area in the field. Due to the lower time resolution of typical WSN/IoT platforms (e.g., 1 µs on ESP32 platforms) and the jitters in timestamping, packet-level localization techniques cannot provide meter-level resolution. For high-precision localization as well as world-wide interoperability via 2.4-GHz ISM band, a new variant of LoRa, called LoRa 2.4 GHz, was proposed by Semtech, which provides a radio frequency (RF) time of flight (ToF) ranging method for meter-level localization. However, the existing datasets reported in the literature are limited in their coverages and do not take into account varying environmental factors such as temperature and humidity. To address these issues, LoRa 2.4 GHz RF ToF ranging data was collected on a sports field at the XJTLU south campus, where three LoRa nodes logged samples of ranging with a LoRa base station, together with temperature and humidity, at reference points arranged as a 3×3 grid covering 400 squaremeter over three weeks and uploaded all measurement records to the base station equipped with an ESP32-based transceiver for machine and user communications. The results of a preliminary investigation based on a simple deep neural network (DNN) model demonstrate that the environmental factors, including the temperature and humidity, significantly affect the accuracy of ranging, which calls for advanced methods of compensating for the effects of environmental factors on LoRa RF ToF ranging
outdoors.

Original language	English
Pages	1--5
Number of pages	5
Publication status	Accepted/In press - 27 Sept 2025
Event	The 10th International Workshop on GPU Computing and AI (held in conjunction with 13th International Symposium on Computing and Networking) - Yamagata Terrsa, Yamagata, Japan Duration: 25 Nov 2025 → 28 Nov 2025 https://is-candar.org/gca25

Conference

Conference	The 10th International Workshop on GPU Computing and AI (held in conjunction with 13th International Symposium on Computing and Networking)
Abbreviated title	GCA'25
Country/Territory	Japan
City	Yamagata
Period	25/11/25 → 28/11/25
Internet address	https://is-candar.org/gca25

Keywords

LoRa
Wireless sensor network (WSN)
internet of things (IoT)
Localization
Environmental factors
Ranging
Time of Flight (ToF)
Deep neural network (DNN)

Cite this

Zhou, Y., Zhou, X., Cheng, Z., Lu, C., Chen, J., Pan, J., Liu, Y., Li, S., & Kim, K. S. (Accepted/In press). Impact of Environmental Factors on LoRa 2.4 GHz Time of Flight Ranging Outdoors. 1--5. Paper presented at The 10th International Workshop on GPU Computing and AI (held in conjunction with 13th International Symposium on Computing and Networking), Yamagata, Japan.

@conference{4c4733c5a8ef4cbeb9f0fb21c7b300fb,

title = "Impact of Environmental Factors on LoRa 2.4 GHz Time of Flight Ranging Outdoors",

abstract = "In WSN/IoT, node localization is essential to long-running applications for accurate environment monitoring and event detection, often covering a large area in the field. Due to the lower time resolution of typical WSN/IoT platforms (e.g., 1 µs on ESP32 platforms) and the jitters in timestamping, packet-level localization techniques cannot provide meter-level resolution. For high-precision localization as well as world-wide interoperability via 2.4-GHz ISM band, a new variant of LoRa, called LoRa 2.4 GHz, was proposed by Semtech, which provides a radio frequency (RF) time of flight (ToF) ranging method for meter-level localization. However, the existing datasets reported in the literature are limited in their coverages and do not take into account varying environmental factors such as temperature and humidity. To address these issues, LoRa 2.4 GHz RF ToF ranging data was collected on a sports field at the XJTLU south campus, where three LoRa nodes logged samples of ranging with a LoRa base station, together with temperature and humidity, at reference points arranged as a 3×3 grid covering 400 squaremeter over three weeks and uploaded all measurement records to the base station equipped with an ESP32-based transceiver for machine and user communications. The results of a preliminary investigation based on a simple deep neural network (DNN) model demonstrate that the environmental factors, including the temperature and humidity, significantly affect the accuracy of ranging, which calls for advanced methods of compensating for the effects of environmental factors on LoRa RF ToF ranging outdoors.",

keywords = "LoRa, Wireless sensor network (WSN), internet of things (IoT), Localization, Environmental factors, Ranging, Time of Flight (ToF), Deep neural network (DNN)",

author = "Yiqing Zhou and Xule Zhou and Zecan Cheng and Chenao Lu and Junhan Chen and Jiahong Pan and Yizhuo Liu and Sihao Li and Kim, \{Kyeong Soo\}",

year = "2025",

month = sep,

day = "27",

language = "English",

pages = "1----5",

note = "The 10th International Workshop on GPU Computing and AI (held in conjunction with 13th International Symposium on Computing and Networking), GCA'25 ; Conference date: 25-11-2025 Through 28-11-2025",

url = "https://is-candar.org/gca25",

}

Zhou, Y, Zhou, X, Cheng, Z, Lu, C, Chen, J, Pan, J, Liu, Y, Li, S & Kim, KS 2025, 'Impact of Environmental Factors on LoRa 2.4 GHz Time of Flight Ranging Outdoors', Paper presented at The 10th International Workshop on GPU Computing and AI (held in conjunction with 13th International Symposium on Computing and Networking), Yamagata, Japan, 25/11/25 - 28/11/25 pp. 1--5.

Impact of Environmental Factors on LoRa 2.4 GHz Time of Flight Ranging Outdoors. / Zhou, Yiqing; Zhou, Xule; Cheng, Zecan et al.
2025. 1--5 Paper presented at The 10th International Workshop on GPU Computing and AI (held in conjunction with 13th International Symposium on Computing and Networking), Yamagata, Japan.

Research output: Contribution to conference › Paper › peer-review

TY - CONF

T1 - Impact of Environmental Factors on LoRa 2.4 GHz Time of Flight Ranging Outdoors

AU - Zhou, Yiqing

AU - Zhou, Xule

AU - Cheng, Zecan

AU - Lu, Chenao

AU - Chen, Junhan

AU - Pan, Jiahong

AU - Liu, Yizhuo

AU - Li, Sihao

AU - Kim, Kyeong Soo

PY - 2025/9/27

Y1 - 2025/9/27

N2 - In WSN/IoT, node localization is essential to long-running applications for accurate environment monitoring and event detection, often covering a large area in the field. Due to the lower time resolution of typical WSN/IoT platforms (e.g., 1 µs on ESP32 platforms) and the jitters in timestamping, packet-level localization techniques cannot provide meter-level resolution. For high-precision localization as well as world-wide interoperability via 2.4-GHz ISM band, a new variant of LoRa, called LoRa 2.4 GHz, was proposed by Semtech, which provides a radio frequency (RF) time of flight (ToF) ranging method for meter-level localization. However, the existing datasets reported in the literature are limited in their coverages and do not take into account varying environmental factors such as temperature and humidity. To address these issues, LoRa 2.4 GHz RF ToF ranging data was collected on a sports field at the XJTLU south campus, where three LoRa nodes logged samples of ranging with a LoRa base station, together with temperature and humidity, at reference points arranged as a 3×3 grid covering 400 squaremeter over three weeks and uploaded all measurement records to the base station equipped with an ESP32-based transceiver for machine and user communications. The results of a preliminary investigation based on a simple deep neural network (DNN) model demonstrate that the environmental factors, including the temperature and humidity, significantly affect the accuracy of ranging, which calls for advanced methods of compensating for the effects of environmental factors on LoRa RF ToF ranging outdoors.

AB - In WSN/IoT, node localization is essential to long-running applications for accurate environment monitoring and event detection, often covering a large area in the field. Due to the lower time resolution of typical WSN/IoT platforms (e.g., 1 µs on ESP32 platforms) and the jitters in timestamping, packet-level localization techniques cannot provide meter-level resolution. For high-precision localization as well as world-wide interoperability via 2.4-GHz ISM band, a new variant of LoRa, called LoRa 2.4 GHz, was proposed by Semtech, which provides a radio frequency (RF) time of flight (ToF) ranging method for meter-level localization. However, the existing datasets reported in the literature are limited in their coverages and do not take into account varying environmental factors such as temperature and humidity. To address these issues, LoRa 2.4 GHz RF ToF ranging data was collected on a sports field at the XJTLU south campus, where three LoRa nodes logged samples of ranging with a LoRa base station, together with temperature and humidity, at reference points arranged as a 3×3 grid covering 400 squaremeter over three weeks and uploaded all measurement records to the base station equipped with an ESP32-based transceiver for machine and user communications. The results of a preliminary investigation based on a simple deep neural network (DNN) model demonstrate that the environmental factors, including the temperature and humidity, significantly affect the accuracy of ranging, which calls for advanced methods of compensating for the effects of environmental factors on LoRa RF ToF ranging outdoors.

KW - LoRa

KW - Wireless sensor network (WSN)

KW - internet of things (IoT)

KW - Localization

KW - Environmental factors

KW - Ranging

KW - Time of Flight (ToF)

KW - Deep neural network (DNN)

M3 - Paper

SP - 1

EP - 5

T2 - The 10th International Workshop on GPU Computing and AI (held in conjunction with 13th International Symposium on Computing and Networking)

Y2 - 25 November 2025 through 28 November 2025

ER -