Analysis and Optimization of Spiral Circular Inductive Coupling Link for Bio-Implanted Applications on Air and within Human Tissue

Mutashar, Saad; Hannan, M. A.; Samad, Salina Abdul; Hussain, Aini

doi:10.3390/s140711522

Cited by 65 publications

(62 citation statements)

References 23 publications

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“…In general WPT techniques are classified into three types [1] based on the transmission techniques: (1) the electromagnetic (EM) radiation technique, which transmits microwave energy over long distances and is used for space satellite applications [1]; (2) the inductive coupling technique, which allows the transfer of energy over very short distances and is used in wireless charging applications, such as laptops, mobile phones and biomedical implants [1][2][3][4][5]. For energy harvesting applications, the work presented in [6] depicted long-range energy transfer based on inductive coupling for a distance of 6 m, but the power received was confined to 10.9 mW for a 246-W DC power input.…”

Section: Introductionmentioning

confidence: 99%

An Efficiency Enhancement Technique for a Wireless Power Transmission System Based on a Multiple Coil Switching Technique

Nair

Choi

2016

Energies

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For magnetic-coupled resonator wireless power transmission (WPT) systems, higher power transfer efficiency can be achieved over a greater range in comparison to inductive-coupled WPT systems. However, as the distance between the two near-field resonators varies, the coupling between them changes. The change in coupling would in turn vary the power transfer efficiency. Generally, to maintain high efficiency for varying distances, either frequency tuning or impedance matching are employed. Frequency tuning may not limit the tunable frequency within the Industrial Scientific Medical (ISM) band, and the impedance matching network involves bulky systems. Therefore, to maintain higher transfer efficiency over a wide range of distances, we propose a multiple coil switching wireless power transmission system. The proposed system includes several loop coils with different sizes. Based on the variation of the distance between the transmitter and receiver side, the power is switched to one of the loop coils for transmission and reception. The system enables adjustment of the coupling coefficient with selective switching of the coil loops at the source and load end and, thus, aids achieving high power transfer efficiency over a wide range of distances. The proposed technique is analyzed with an equivalent circuit model, and simulations are performed to evaluate the performance. The system is validated through experimental results that indicate for a fixed frequency (13.56 MHz) that the switched loop technique achieves high efficiency over a wider range of distances.

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Section: Introductionmentioning

confidence: 99%

An Efficiency Enhancement Technique for a Wireless Power Transmission System Based on a Multiple Coil Switching Technique

Nair

Choi

2016

Energies

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“…C p and C s are the compensated capacitances of the primary and secondary units, respectively. In the secondary unit, the current I s can also be calculated as [16]:…”

Section: Discussionmentioning

confidence: 99%

“…Then, ω is the operating angular frequency, R L the equivalent resistance of the load, and M the mutual inductance between the track and pickup coil as given by [16]:…”

Section: Discussionmentioning

confidence: 99%

Dynamic Wireless Charging for Roadway-Powered Electric Vehicles: A Comprehensive Analysis and Design

Deng¹,

Jia²,

Zhang³

2016

PIER C

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Abstract-This paper presents a comprehensive analysis of the roadway powering system for electric vehicles (EVs) and proposes a design from the perspective of power track design, integration, and powering control strategy, aiming to ensure the charging power and persistence, enhance the control flexibility, and reduce the construction cost. 1) A novel design scheme is first proposed to determine the length and number of turns for power tracks by investigating the power supply-and-demand and the loss. 2) A novel evaluation index, namely the magnetic distribution variance, is proposed to determine the gap between adjacent tracks, which can effectively produce evenly-distributed energy field, thus improving the dynamic charging performance for EVs. 3) A sectional powering control strategy is proposed to implement a cost-saving and flexible roadway powering system. Lastly, the simulated and experimental results show that the exemplified prototype can achieve the transmission power 50 W over the distance of 200 mm, which verifies the proposed EV dynamic charging system with the salient advantages of the constant energization, flexible power control, and cost saving.

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“…The electric characteristics of the dual-layer planar coil can be determined by using well known models [56,57,58], where the electrical inductance for a circular multi-layer coil can be calculated as:

normalL ≅ L_{1} {+ normalL}_{2} \pm 2 normalM

where M = k(L 1 ∙L 2 ) 1/2 is the mutual inductance between the two levels of the planar coil [28], k = (R 2 out.T ∙R 2 out.R )/(R 2 out.T ∙R 2 out.R ) 1/2 (R 2 out.T + X 2 ) 3/2 is the coupling factor between the two coils, whereas L 1 and L 2 are the self-inductances for the lower and upper loops, which are determined from the following Equation [49,50,57,59]:

L_{1} {= normalL}_{2} ≅ \frac{μ_{0} n^{2} d_{avg} C_{1}}{2} [\ln (\frac{C_{2}}{F}) {+ normalC}_{3} {normalF + normalC}_{4} F^{2}]

where n = (Rout − Rin)(w + s) is the number of turns of the inductor, davg = (Dout + Din)/2 is the averaged diameter of the windings, F = (Dout − Din)/Dout + Din) is the fill factor of the windings and C1–C4 are constant coefficients determined by the winding geometry [57]. …”

Section: Integrated Wireless System Descriptionmentioning

confidence: 99%

Design and Simulation of an Integrated Wireless Capacitive Sensors Array for Measuring Ventricular Pressure

Hernández-Sebastián

Díaz-Alonso

Renero-Carrillo

et al. 2018

Sensors

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This paper reports the novel design of a touch mode capacitive pressure sensor (TMCPS) system with a wireless approach for a full-range continuous monitoring of ventricular pressure. The system consists of two modules: an implantable set and an external reading device. The implantable set, restricted to a 2 × 2 cm2 area, consists of a TMCPS array connected with a dual-layer coil, for making a reliable resonant circuit for communication with the external device. The capacitive array is modelled considering the small deflection regime for achieving a dynamic and full 5–300 mmHg pressure range. In this design, the two inductive-coupled modules are calculated considering proper electromagnetic alignment, based on two planar coils and considering the following: 13.56 MHz frequency to avoid tissue damage and three types of biological tissue as core (skin, fat and muscle). The system was validated with the Comsol Multiphysics and CoventorWare softwares; showing a 90% power transmission efficiency at a 3.5 cm distance between coils. The implantable module includes aluminum- and polyimide-based devices, which allows ergonomic, robust, reproducible, and technologically feasible integrated sensors. In addition, the module shows a simplified and low cost design approach based on PolyMEMS INAOE® technology, featured by low-temperature processing.

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Analysis and Optimization of Spiral Circular Inductive Coupling Link for Bio-Implanted Applications on Air and within Human Tissue

Cited by 65 publications

References 23 publications

An Efficiency Enhancement Technique for a Wireless Power Transmission System Based on a Multiple Coil Switching Technique

An Efficiency Enhancement Technique for a Wireless Power Transmission System Based on a Multiple Coil Switching Technique

Dynamic Wireless Charging for Roadway-Powered Electric Vehicles: A Comprehensive Analysis and Design

Design and Simulation of an Integrated Wireless Capacitive Sensors Array for Measuring Ventricular Pressure

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