Performance Analysis of Galvanically Coupled HBC Channels for Implantable Extravascular Sensors

Extravascular sensors can provide hemodynamic data to aid in diagnosis and management of cardiovascular diseases (CVD). This prompts research into methods for communicating data to and from these implanted sensors. This paper proposes five (5) in-body communication paths that use galvanically couple...

Full description

Saved in:
Bibliographic Details
Published inInternational Conference on Bio-engineering for Smart Technologies (Online) pp. 1 - 4
Main Authors Sooknanan, Justin, Rocke, Sean
Format Conference Proceeding
LanguageEnglish
Published IEEE 14.05.2025
Subjects
Biological system modeling
Bit error rate
Decoding
Finite element analysis
finite element method
galvanic coupling
human body communication (HBC)
implantable
Receivers
Sensor phenomena and characterization
Software
Transceivers
Transmitters
Online AccessGet full text
ISSN2831-4352
DOI10.1109/BioSMART66413.2025.11046102

Cover

Abstract Extravascular sensors can provide hemodynamic data to aid in diagnosis and management of cardiovascular diseases (CVD). This prompts research into methods for communicating data to and from these implanted sensors. This paper proposes five (5) in-body communication paths that use galvanically coupled human body communications (HBC). These channel models are designed for finite-element method (FEM) simulations in Comsol Multiphysics 6.1. The resulting magnitude and phase responses were used to create a human body communication chain in Matlab R2024a. The communication chain comprises of the HBC physical (PHY) layer at the transmitter, a filter replicating the human body channel, a correlation decoder as well as supporting analog front-end circuitry. Afterwards, Monte Carlo analysis was applied to the transmission of frequency shift coded (FSC) signals across the channels to obtain their error characteristics. Bit error rates (BER) obtained for these channels varied between 10^−4 and 10^−5, indicating promising performance.
AbstractList Extravascular sensors can provide hemodynamic data to aid in diagnosis and management of cardiovascular diseases (CVD). This prompts research into methods for communicating data to and from these implanted sensors. This paper proposes five (5) in-body communication paths that use galvanically coupled human body communications (HBC). These channel models are designed for finite-element method (FEM) simulations in Comsol Multiphysics 6.1. The resulting magnitude and phase responses were used to create a human body communication chain in Matlab R2024a. The communication chain comprises of the HBC physical (PHY) layer at the transmitter, a filter replicating the human body channel, a correlation decoder as well as supporting analog front-end circuitry. Afterwards, Monte Carlo analysis was applied to the transmission of frequency shift coded (FSC) signals across the channels to obtain their error characteristics. Bit error rates (BER) obtained for these channels varied between 10^−4 and 10^−5, indicating promising performance.
Author Sooknanan, Justin
Rocke, Sean
Author_xml – sequence: 1
  givenname: Justin
  surname: Sooknanan
  fullname: Sooknanan, Justin
  email: justin.sooknanan1@my.uwi.edu
  organization: The University of the West Indies,Department of Electrical & Computer Engineering,St. Augustine,Trinidad & Tobago
– sequence: 2
  givenname: Sean
  surname: Rocke
  fullname: Rocke, Sean
  email: sean.rocke@uwi.edu
  organization: The University of the West Indies,Department of Electrical & Computer Engineering,St. Augustine,Trinidad & Tobago
BookMark eNo1kMFOAjEURavRRED-wEUT14N9bae0S5ggkGA0wsIdeTPzJo4pHdICkb9Xo65ucpJzFrfPrkIXiLF7ECMA4R6mbbd-mrxujNGgRlLI_IdrA0JesD4Yk-uxBXi7ZD1pFWRa5fKGDVP6EEIoCWDsuMe2LxSbLu4wVMQnAf05tYl3DZ-jP2FoK_T-zIvuuPdU88W04MU7hkA-8W-NL3d7j-GApSc--zxEPGGqjh4jX1NIXUy37LpBn2j4twO2eZxtikW2ep4vi8kqa506ZEqWJdWKBEgBthalI-MInJO6hly6SokStVKlabRFK1FroNxhA1Y0Tkg1YHe_2ZaItvvY7jCet_9_qC9N7VjA
ContentType Conference Proceeding
DBID 6IE
6IL
CBEJK
RIE
RIL
DOI 10.1109/BioSMART66413.2025.11046102
DatabaseName IEEE Electronic Library (IEL) Conference Proceedings
IEEE Proceedings Order Plan All Online (POP All Online) 1998-present by volume
IEEE Xplore All Conference Proceedings
IEEE Electronic Library (IEL)
IEEE Proceedings Order Plans (POP All) 1998-Present
DatabaseTitleList
Database_xml – sequence: 1
  dbid: RIE
  name: IEEE Electronic Library (IEL)
  url: https://proxy.k.utb.cz/login?url=https://ieeexplore.ieee.org/
  sourceTypes: Publisher
DeliveryMethod fulltext_linktorsrc
EISBN 166547811X
9781665478113
EISSN 2831-4352
EndPage 4
ExternalDocumentID 11046102
Genre orig-research
GroupedDBID 6IE
6IL
6IN
AAWTH
ABLEC
ADZIZ
ALMA_UNASSIGNED_HOLDINGS
BEFXN
BFFAM
BGNUA
BKEBE
BPEOZ
CBEJK
CHZPO
IEGSK
OCL
RIE
RIL
ID FETCH-LOGICAL-i93t-32bbed3e012018d0b9e69e19924d1529c30ba433b6f48a82a441e59af180f9023
IEDL.DBID RIE
IngestDate Thu Jul 10 06:35:40 EDT 2025
IsPeerReviewed false
IsScholarly false
Language English
LinkModel DirectLink
MergedId FETCHMERGED-LOGICAL-i93t-32bbed3e012018d0b9e69e19924d1529c30ba433b6f48a82a441e59af180f9023
PageCount 4
ParticipantIDs ieee_primary_11046102
PublicationCentury 2000
PublicationDate 2025-May-14
PublicationDateYYYYMMDD 2025-05-14
PublicationDate_xml – month: 05
  year: 2025
  text: 2025-May-14
  day: 14
PublicationDecade 2020
PublicationTitle International Conference on Bio-engineering for Smart Technologies (Online)
PublicationTitleAbbrev BIOSMART
PublicationYear 2025
Publisher IEEE
Publisher_xml – name: IEEE
SSID ssj0003211687
Score 1.9112294
Snippet Extravascular sensors can provide hemodynamic data to aid in diagnosis and management of cardiovascular diseases (CVD). This prompts research into methods for...
SourceID ieee
SourceType Publisher
StartPage 1
SubjectTerms Biological system modeling
Bit error rate
Decoding
Finite element analysis
finite element method
galvanic coupling
human body communication (HBC)
implantable
Receivers
Sensor phenomena and characterization
Software
Transceivers
Transmitters
Title Performance Analysis of Galvanically Coupled HBC Channels for Implantable Extravascular Sensors
URI https://ieeexplore.ieee.org/document/11046102
hasFullText 1
inHoldings 1
isFullTextHit
isPrint
link http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwjV3fS8MwEA66B_FJxYm_Cehruqbpj-R1Y3MIjsEm7G0k7QWGox2zBfWv99KtGwqCb6GQEu7CfXfJfV8IeRRWcx3YkAFXhoVY1TKVacvSAJTMTGKFrtU-R_HwNXyeRbMtWb3mwgBA3XwGnhvWd_lZkVbuqKzDeS0PjhH3EPfZhqy1O1ARWMrEMjkiD1sdzU53UUxeMC2MY4zUWAoGkdf84cdbKjWUDE7IqFnEpoPkzatK46Vfv_QZ_73KU9Les_boeIdHZ-QA8nMyH--ZAbRRIKGFpU96iUm0c9Hyk_aKarWEjA67Per4BjkiJsVp1IkHo-0dv4r2P8q1bjpX6QTr32L93ibTQX_aG7LtowpsoUTJRGAMZAIcZ5bLzDcKYgWuBzXMEMpVKnyjQyFMbEOpZaAxXYJIaculbxUC_AVp5UUOl4QmifQRzFIsSADDLTo2UlylkYDIuZhfkbYzzny1kc2YN3a5_uP7DTl2PnJX8zy8Ja1yXcEdIn5p7mtPfwPjBqrK
linkProvider IEEE
linkToHtml http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwjV1dS8MwFA2ioD6pOPHbgL62a5r0I68bm1O3MdiEvZWkvYXhaMdsQf313nTrhoLgWym0hHvgnnuTe04IeeCpYspNhQVMaktgV2vJRKVW7IIMEx2kXFVun0O_9yqep950LVavtDAAUA2fgW0eq7P8JI9Ls1XWZKyyB8eMu4fEL7yVXGuzpcKxmfHDYJ_cr500m61ZPh5gYej7mKuxGXQ9u_7Hj9tUKjLpHpFhvYzVDMmbXRbajr9-OTT-e53HpLHV7dHRhpFOyA5kpyQabbUBtPYgoXlKH9Ucy2gD0vyTtvNyMYeE9lptahQHGXImxc-osQ_G6BuFFe18FEtVz67SMXbA-fK9QSbdzqTds9bXKlgzyQuLu1pDwsGoZlmYOFqCL8FMoYoEyVzG3NFKcK79VIQqdBUWTOBJlbLQSSVS_BnZzfIMzgkNgtBBOouxJQFMuAitJ5mMPQ6eAZldkIYJTrRYGWdEdVwu_3h_Rw56k0E_6j8NX67IocHLHNQzcU12i2UJN8j_hb6tUP8GBXuuFw
openUrl ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=proceeding&rft.title=International+Conference+on+Bio-engineering+for+Smart+Technologies+%28Online%29&rft.atitle=Performance+Analysis+of+Galvanically+Coupled+HBC+Channels+for+Implantable+Extravascular+Sensors&rft.au=Sooknanan%2C+Justin&rft.au=Rocke%2C+Sean&rft.date=2025-05-14&rft.pub=IEEE&rft.eissn=2831-4352&rft.spage=1&rft.epage=4&rft_id=info:doi/10.1109%2FBioSMART66413.2025.11046102&rft.externalDocID=11046102