In-vivo Experimental Validation of the Attenuation Path Loss Model for Localization of Wireless Implanted Transmitters at 2.45 GHz

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

In-vivo Experimental Validation of the Attenuation Path Loss Model for Localization of Wireless Implanted Transmitters at 2.45 GHz. / Salchak, Yana A.; Albadri, Noor M.; Bjorkman, Tracey; Lau, Cora; Nadimi, Esmaeil S.; Bollen, Peter; Espinosa, Hugo G.; Thiel, David V.

In: IEEE Access, Vol. 10, 2022, p. 84894-84912.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Salchak, YA, Albadri, NM, Bjorkman, T, Lau, C, Nadimi, ES, Bollen, P, Espinosa, HG & Thiel, DV 2022, 'In-vivo Experimental Validation of the Attenuation Path Loss Model for Localization of Wireless Implanted Transmitters at 2.45 GHz', IEEE Access, vol. 10, pp. 84894-84912. https://doi.org/10.1109/ACCESS.2022.3196376

APA

Salchak, Y. A., Albadri, N. M., Bjorkman, T., Lau, C., Nadimi, E. S., Bollen, P., Espinosa, H. G., & Thiel, D. V. (2022). In-vivo Experimental Validation of the Attenuation Path Loss Model for Localization of Wireless Implanted Transmitters at 2.45 GHz. IEEE Access, 10, 84894-84912. https://doi.org/10.1109/ACCESS.2022.3196376

Vancouver

Salchak YA, Albadri NM, Bjorkman T, Lau C, Nadimi ES, Bollen P et al. In-vivo Experimental Validation of the Attenuation Path Loss Model for Localization of Wireless Implanted Transmitters at 2.45 GHz. IEEE Access. 2022;10:84894-84912. https://doi.org/10.1109/ACCESS.2022.3196376

Author

Salchak, Yana A. ; Albadri, Noor M. ; Bjorkman, Tracey ; Lau, Cora ; Nadimi, Esmaeil S. ; Bollen, Peter ; Espinosa, Hugo G. ; Thiel, David V. / In-vivo Experimental Validation of the Attenuation Path Loss Model for Localization of Wireless Implanted Transmitters at 2.45 GHz. In: IEEE Access. 2022 ; Vol. 10. pp. 84894-84912.

Bibtex

@article{abdc77018e9a4eba9d661d973db32cc1,
title = "In-vivo Experimental Validation of the Attenuation Path Loss Model for Localization of Wireless Implanted Transmitters at 2.45 GHz",
abstract = "Wireless capsule endoscopy (WCE) is a modern, non-invasive method of gastrointestinal examination that can significantly reduce mortality and morbidity. One of the current challenges in WCE is the precise localization of the capsule. An accurate path loss propagation model can be used to find the exact distance from the surface to the capsule inside the abdominal cavity. Unfortunately, there are no standardized In-to-On-Body channel models describing the signal propagation at ultra-high frequencies that are used in the most commercially available WCE systems. This study addresses the gap by conducting an experimental validation of a new propagation model for WCE applications at 2.45 GHz. The results were confirmed by conducting two separate in-vivo trials on porcine animals under general anesthesia. The performance of the model as well as the corresponding ranging errors were evaluated when it was used as an inverse solution for distance estimation to an ingested transmitter. The main advantage of the model is its theoretical basis, which can help further generalize the findings for similar communication scenarios. The obtained ranging error was smaller than one centimeter, suggesting that it can be used for accurate range-based positioning of implanted transmitters.",
keywords = "animals, body area networks, channel models, implantable biomedical devices, narrowband, UHF antennas, wireless capsule endoscopy, Wireless communication",
author = "Salchak, {Yana A.} and Albadri, {Noor M.} and Tracey Bjorkman and Cora Lau and Nadimi, {Esmaeil S.} and Peter Bollen and Espinosa, {Hugo G.} and Thiel, {David V.}",
note = "Publisher Copyright: {\textcopyright} 2013 IEEE.",
year = "2022",
doi = "10.1109/ACCESS.2022.3196376",
language = "English",
volume = "10",
pages = "84894--84912",
journal = "IEEE Access",
issn = "2169-3536",
publisher = "Institute of Electrical and Electronics Engineers Inc.",

}

RIS

TY - JOUR

T1 - In-vivo Experimental Validation of the Attenuation Path Loss Model for Localization of Wireless Implanted Transmitters at 2.45 GHz

AU - Salchak, Yana A.

AU - Albadri, Noor M.

AU - Bjorkman, Tracey

AU - Lau, Cora

AU - Nadimi, Esmaeil S.

AU - Bollen, Peter

AU - Espinosa, Hugo G.

AU - Thiel, David V.

N1 - Publisher Copyright: © 2013 IEEE.

PY - 2022

Y1 - 2022

N2 - Wireless capsule endoscopy (WCE) is a modern, non-invasive method of gastrointestinal examination that can significantly reduce mortality and morbidity. One of the current challenges in WCE is the precise localization of the capsule. An accurate path loss propagation model can be used to find the exact distance from the surface to the capsule inside the abdominal cavity. Unfortunately, there are no standardized In-to-On-Body channel models describing the signal propagation at ultra-high frequencies that are used in the most commercially available WCE systems. This study addresses the gap by conducting an experimental validation of a new propagation model for WCE applications at 2.45 GHz. The results were confirmed by conducting two separate in-vivo trials on porcine animals under general anesthesia. The performance of the model as well as the corresponding ranging errors were evaluated when it was used as an inverse solution for distance estimation to an ingested transmitter. The main advantage of the model is its theoretical basis, which can help further generalize the findings for similar communication scenarios. The obtained ranging error was smaller than one centimeter, suggesting that it can be used for accurate range-based positioning of implanted transmitters.

AB - Wireless capsule endoscopy (WCE) is a modern, non-invasive method of gastrointestinal examination that can significantly reduce mortality and morbidity. One of the current challenges in WCE is the precise localization of the capsule. An accurate path loss propagation model can be used to find the exact distance from the surface to the capsule inside the abdominal cavity. Unfortunately, there are no standardized In-to-On-Body channel models describing the signal propagation at ultra-high frequencies that are used in the most commercially available WCE systems. This study addresses the gap by conducting an experimental validation of a new propagation model for WCE applications at 2.45 GHz. The results were confirmed by conducting two separate in-vivo trials on porcine animals under general anesthesia. The performance of the model as well as the corresponding ranging errors were evaluated when it was used as an inverse solution for distance estimation to an ingested transmitter. The main advantage of the model is its theoretical basis, which can help further generalize the findings for similar communication scenarios. The obtained ranging error was smaller than one centimeter, suggesting that it can be used for accurate range-based positioning of implanted transmitters.

KW - animals

KW - body area networks

KW - channel models

KW - implantable biomedical devices

KW - narrowband

KW - UHF antennas

KW - wireless capsule endoscopy

KW - Wireless communication

U2 - 10.1109/ACCESS.2022.3196376

DO - 10.1109/ACCESS.2022.3196376

M3 - Journal article

AN - SCOPUS:85135740248

VL - 10

SP - 84894

EP - 84912

JO - IEEE Access

JF - IEEE Access

SN - 2169-3536

ER -

ID: 318706195