Past Results, Present Trends, and Future Challenges in Intrabody Communication

Naranjo-Hernández, David; Callejón-Leblic, María A.; Vasić, Željka Lučev; Seyedi, MirHojjat; Gao, Yueming

doi:10.1155/2018/9026847

Cited by 51 publications

(62 citation statements)

References 212 publications

(382 reference statements)

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“…For instance, samples with low oil solution concentration can be utilized for mimicking tissue with high dielectric permittivity, while samples with high oil solution concentration can be used to mimic tissues with low conductivity like cortical bone, as shown in Figures As shown in Figures 6 and 7, the electrical properties of different tissues can be matched with samples of certain formulations and concentrations, depending on the electrical property of interest (whether conductivity or permittivity is more of concern), and the range of frequency in which the IBC application will operate within. It is important to note that most IBC applications utilize less than 1 MHz of bandwidth [22], due to the nature of medical applications, that typically require low bit rates. A summary of such results; best matching samples (samples that shows less than 10 % matching error) with respect to different tissues, regarding conductivity and permittivity, for different frequency ranges (Fmin is the minimum frequency and Fmax is the maximum frequency in MHz defining the band over which the matching error is below 10% ) within the IBC application band, is provided in Table 3.…”

Section: Resultsmentioning

confidence: 99%

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Physical Multi-Layer Phantoms for Intra-Body Communications

et al. 2018

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This paper presents approaches to creating tissue mimicking materials that can be used as phantoms for evaluating the performance of Body Area Networks (BAN). The main goal of the paper is to describe a methodology to create a repeatable experimental BAN platform that can be customized depending on the BAN scenario under test. Comparisons between different material compositions and percentages are shown, along with the resulting electrical properties of each mixture over the frequency range of interest for intra-body communications; 100 KHz to 100 MHz. Test results on a composite multi-layer sample are presented confirming the efficacy of the proposed methodology. To date, this is the first paper that provides guidance on how to decide on concentration levels of ingredients, depending on the exact frequency range of operation, and the desired matched electrical characteristics (conductivity vs. permittivity), to create multi-layer phantoms for intra-body communication applications.

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Section: Resultsmentioning

confidence: 99%

“…Several trials were reported in literature for the use of phantoms for IBC applications as a stable and easy to control, yet accurate experimental setup [22], [23]. Liquid phantoms were usually adopted in these trials, being the easiest to prepare.…”

Section: A Phantoms For Ibcmentioning

confidence: 99%

Physical Multi-Layer Phantoms for Intra-Body Communications

et al. 2018

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“…The pioneering work of Zimmerman on BCC was motivated by the dream and the imagination of a digital interconnected world where the center of communication is the human being [1], [2]. Driven by this idea, BCC can be established relying on two main coupling mechanisms [3]. The signal can be coupled in the body by direct current injection (galvanic coupling -GC) from a transmitter (TX) electrode to a receiver (RX).…”

Section: Introductionmentioning

confidence: 99%

“…The signal can be coupled in the body by direct current injection (galvanic coupling -GC) from a transmitter (TX) electrode to a receiver (RX). Alternatively, the near-field coupling of a quasi-electrostatic field between TX and RX electrodes can be used for (capacitive coupling -CC) [3]- [9]. However, the possibility of conveying information in the sub-cutaneous fat at frequencies around 2.45 GHz is currently under investigation [10]- [12].…”

Section: Introductionmentioning

confidence: 99%

A Periodic Transmission Line Model for Body Channel Communication

et al. 2020

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Body channel communication (BCC) is a technique for data transmission exploiting the human body as communication channel. Even though it was pioneered about 25 years ago, the identification of a good electrical model behind its functioning is still an open research question. The proposed distributed model can then serve as a supporting tool for the design, allowing to enhance the performances of any BCC system. A novel finite periodic transmission line model was developed to describe the human body as transmission medium. According to this model, for the first time, the parasitic capacitance between the transmitter and the receiver is assumed to depend on their distance. The parameters related to the body and electrodes are acquired experimentally by fitting the bioimpedentiometric measurements, in the range of frequencies from 1 kHz to 1 MHz, obtaining a mean absolute error lower than 4 • and 30 Ω for the phase angle and impedance modulus, respectively. The proposed mathematical framework has been successfully validated by describing a ground-referred and low-complexity system called Live Wire, suitable as supporting tool for visually impaired people, and finding good agreement between the measured and the calculated data, marking a ±3% error for communication distances ranging from 20 to 150 cm. In this work we introduced a new circuital approach, for capacitive-coupling systems, based on finite periodic transmission line, capable to describe and model BCC systems allowing to optimize the performances of similar systems. INDEX TERMS body area network, body channel communication, intra-body communication, propagation model, periodic transmission line

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“…Intra-body communications can be categorized into two main types; capacitive coupling (near-field coupling method) and galvanic coupling [13][14][15][16][17][18]. In capacitive coupling, only the signal electrodes of the transmitter and the receiver are attached to the body while the ground (GND) electrodes are left floating in the air.…”

Section: Introductionmentioning

confidence: 99%

Biometric Identity Based on Intra-Body Communication Channel Characteristics and Machine Learning

Khorshid

Alquaydheb

Kurdahi

et al. 2020

Sensors

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In this paper, we propose and validate using the Intra-body communications channel as a biometric identity. Combining experimental measurements collected from five subjects and two multi-layer tissue mimicking materials’ phantoms, different machine learning algorithms were used and compared to test and validate using the channel characteristics and features as a biometric identity for subject identification. An accuracy of 98.5% was achieved, together with a precision and recall of 0.984 and 0.984, respectively, when testing the models against subject identification over results collected from the total samples. Using a simple and portable setup, this work shows the feasibility, reliability, and accuracy of the proposed biometric identity, which allows for continuous identification and verification.

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Past Results, Present Trends, and Future Challenges in Intrabody Communication

Cited by 51 publications

References 212 publications

Physical Multi-Layer Phantoms for Intra-Body Communications

Physical Multi-Layer Phantoms for Intra-Body Communications

A Periodic Transmission Line Model for Body Channel Communication

Biometric Identity Based on Intra-Body Communication Channel Characteristics and Machine Learning

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