Nam Ha‐Van scite author profile

Wireless power transfer (WPT) presents a safe and robust method for powering biomedical implants. The range and misalignment tolerance restrictions of the WPT system are the main factors, conducive to the transfer efficiency degradation. Especially, the implanted device is invisible and difficult to arrange in alignment with the transmitting coil. This paper proposes a butterfly-shaped transmitting (BS-Tx) coil of a magnetic resonance WPT system for biomedical implants. The BS-Tx coil prototypes with the changing driven current directions, parallel and anti-parallel current directions, are verified and analyzed. Besides, an equivalent circuit model of a coupling two-coil system with an optimal pair of capacitors method for the matching network is mathematically derived to obtain the maximized power transfer efficiency. The BS-Tx coil enhances the efficiency of the system in the distance, angle, and axial misalignment tolerances. A practical WPT system is fabricated and measured to verify the transfer efficiency through the real biological tissue and exhibits a significant efficiency improvement. Finally, a hypothetical context of retinal prosthesis application is demonstrated as a potential application to retinal implants. The proposed system shows a low specific absorption rate, that is satisfied the human safety regulations. INDEX TERMS Biomedical implants, butterfly-shape, magnetic resonant, misalignment tolerance, retinal prosthesis, wireless power transfer.

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Midfield Wireless Power Transfer for Deep-Tissue Biomedical Implants

Nguyen

Ha‐Van

Seo

2020

Antennas Wirel. Propag. Lett.

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Free-Positioning Wireless Power Transfer Using a 3D Transmitting Coil for Portable Devices

Ha‐Van

Le-Huu

et al. 2020

J Electromagn Eng Sci

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The free-positioning wireless power transfer (WPT) system has drawn attention in recent years. Traditionally, a WPT system can transfer energy in one or two directions on the same plane, but it leads the restrictions of angle and axis misalignment between a transmitter and a receiver coil. In this paper, we propose a free-positioning WPT system using a three-dimensional cubic-shaped transmitting coil for portable device charging. A small receiving coil is placed inside the transmitter to achieve the transferred energy through the magnetic resonant coupling. In addition, the equivalent circuit and the mutual inductance between the Tx and Rx coils are analyzed. Finally, a practical experiment is implemented to verify the transfer performance, which can reach up to about 50% power transfer efficiency. The proposed system can charge in spatial freedom.

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Nam Ha‐Van

Analytical and Experimental Investigations of Omnidirectional Wireless Power Transfer Using a Cubic Transmitter

Multiband Ambient RF Energy Harvesting for Autonomous IoT Devices

Modeling and Experimental Validation of a Butterfly-Shaped Wireless Power Transfer in Biomedical Implants

Midfield Wireless Power Transfer for Deep-Tissue Biomedical Implants

Free-Positioning Wireless Power Transfer Using a 3D Transmitting Coil for Portable Devices

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