Design, realisation and evaluation of a liquid hollow torso phantom appropriate for wearable antenna assessment

Tsolis, Aris; Paraskevopoulos, Anastasios; Alexandridis, Antonis A.; Whittow, William G.; Chauraya, Alford; Vardaxoglou, J.C.

doi:10.1049/iet-map.2016.0235

Cited by 4 publications

(6 citation statements)

References 21 publications

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“…The physical and electrical properties of components that simulate biological organs were tabulated by Gabriel [30] through parametric modeling and can be obtained automatically thanks to the on-line application prepared by the Italian National Research Council [31]. These properties are achieved through a wide range of human tissue-equivalent mixtures, which are housed by enclosures that can be found in literature [32][33][34][35][36] and in market [5,6]. The mixtures [32][33][34] are usually classified according to the number of tissue-layers (homogeneous: 1 tissue layer, heterogeneous: multiple tissue layers), base ingredient, and low/high-water content (e.g., liquid, gel, semi-solid, solid), etc., whereas containers ([5, 6, 32, 35, 36]) are classified according to their resemblance to the external envelope of the human body shape (e.g., anthropomorphic or physical models, canonical models), etc.…”

Section: Human Tissue Equivalent Liquid: Phantommentioning

confidence: 99%

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Human Exposure to Emfs From Wearable Textile Patch Antennas: Experimental Evaluation of the Ground-Plane Effect

Seimeni¹,

Tsolis²,

Alexandridis³

et al. 2021

PIER B

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The aim of this paper is to prove that the power generated by a wearable textile patch antenna experiences reduced absorption in the phantom when the antenna ground-plane is increased. First, the dedicated human torso-equivalent phantom and two antennas were fabricated, which are multilayered, with orientation normal to the body and made of the same materials. One of the antennas has a double in size ground-plane with regards to the other antenna, while the rest of their dimensions are identical. According to the proposed measurement procedure, once the radiation efficiencies of both antennas are measured in free space and with the phantom, the total absorption coefficient and the phantom losses are evaluated. The comparison of the measurement results proves that the increased ground-plane reduces the absorption on the phantom body of the antenna EM power (by 30.5%). Simulations and measurements were found in good agreement, with maximum deviation between the two up to 6% in terms of radiated efficiency. Hence, the proposed experimental evaluation of the impact of the ground-plane size of a wearable textile patch antenna on the reduction of the power absorbed by the user's body can be considered as a simple, reliable and cost-effective measurement method.

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Section: Human Tissue Equivalent Liquid: Phantommentioning

confidence: 99%

“…The dimensions of the internal volume of the phantom enclosure have been decided to equal the average dimensions of an adult torso, that is to say: 33 cm × 14 cm × 49 cm [36]. The enclosure is made of Plexiglass (ε r = 2.36, tan δ = 1.62 * 10 −3 , thickness = 6 mm).…”

Section: Human Tissue Equivalent Liquid: Phantommentioning

confidence: 99%

Human Exposure to Emfs From Wearable Textile Patch Antennas: Experimental Evaluation of the Ground-Plane Effect

Seimeni¹,

Tsolis²,

Alexandridis³

et al. 2021

PIER B

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“…The characterization of BSN antennas is normally addressed without taking into account the effects of the transceiver itself and the consideration of a finite ground plane, which can greatly influence the antenna performance [28]. All of these, combined with the fact that the propagation mechanisms through the human body are not unknown in enough detail, underline the need for more exhaustive studies that analyze the influence of the human body on antennas and viceversa, to be undertaken [29].…”

Section: Introductionmentioning

confidence: 99%

“…The passive measurement inside an anechoic chamber is the standard method for the experimental characterization of antennas [8,21,27,29,30]. However, this method may be unsuitable if the characterization of the antenna integrated in a self-powered electronic device is required, given that the hardware components also influence the radiation characteristics [23,31].…”

Section: Introductionmentioning

confidence: 99%

“…Phantom to emulate on-body condition (separated): In this case, the space between the antenna and the metal support was occupied by a phantom of biological material to emulate the presence of the human body. Containers of liquids or gels that simulate the electrical properties of the body tissues have been used [29], but in this work a biological material of similar structure (skin, fat and muscle) is proposed. A chicken for food consumption was selected to implement the phantom (2.45 kg, clean inside, featherless at room temperature), which was fixed to the support.…”

mentioning

confidence: 99%

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Lessons Learned about the Design and Active Characterization of On-Body Antennas in the 2.4 GHz Frequency Band

Naranjo-Hernández

Reina‐Tosina

Roa

2019

Sensors

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This work addresses the design and experimental characterization of on-body antennas, which play an essential role within Body Sensor Networks. Four antenna designs were selected from a set of eighteen antenna choices and finally implemented for both passive and active measurements. The issues raised during the process of this work (requirements study, technology selection, development and optimization of antennas, impedance matching, unbalanced to balanced transformation, passive and active characterization, off-body and on-body configurations, etc.) were studied and solved, driving a methodology for the characterization of on-body antennas, including transceiver effects. Despite the influence of the body, the antennas showed appropriate results for an in-door environment. Another novelty is the proposal and validation of a phantom to emulate human experimentation. The differences between experimental and simulated results highlight a set of circumstances to be taken into account during the design process of an on-body antenna: more comprehensive simulation schemes to take into account the hardware effects and a custom design process that considers the application for which the device will be used, as well as the effects that can be caused by the human body.

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Next-Generation Healthcare: Enabling Technologies for Emerging Bioelectromagnetics Applications

Kiourti

Abbosh

Αθανασίου

et al. 2022

IEEE Open J. Antennas Propag.

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Rapid advances in antennas, propagation, electromagnetics, and materials are opening new and unexplored opportunities in body area sensing and stimulation. Next-generation wearables and implants are seamlessly providing round-the-clock monitoring. In turn, numerous applications are brought forward with the potential to ultimately transform healthcare, sports, consumer electronics, and beyond. This review paper provides a comprehensive overview, discusses challenges and opportunities, and indicates future directions for: (a) enabling technologies needed to make body area sensing and stimulation a reality, and (b) emerging bioelectromagnetics applications that may readily benefit from such technologies.

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Design, realisation and evaluation of a liquid hollow torso phantom appropriate for wearable antenna assessment

Cited by 4 publications

References 21 publications

Human Exposure to Emfs From Wearable Textile Patch Antennas: Experimental Evaluation of the Ground-Plane Effect

Human Exposure to Emfs From Wearable Textile Patch Antennas: Experimental Evaluation of the Ground-Plane Effect

Lessons Learned about the Design and Active Characterization of On-Body Antennas in the 2.4 GHz Frequency Band

Next-Generation Healthcare: Enabling Technologies for Emerging Bioelectromagnetics Applications

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