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This paper presents a new wireless power link fabricated by using a conductive non-woven fabric on a leather substrate, thus resulting in a prototype that can be easily embedded in wearable accessories such as fashion bags. More in detail, in the fabricated prototype (which was designed to work in the ISM band 433.05 – 434.79 MHz), the power transfer was implemented by exploiting a magnetic coupling...
This paper proposes a novel wireless link for energizing pulse generators for deep brain stimulation. The proposed link consists of two magnetically coupled planar resonators. Experimental results referring to a prototype working in the MedRadio band and using minced pork in order to take into account the presence of human tissues are reported and discussed. Results obtained this way demonstrate a...
This paper presents a wireless energy link for wearable applications. The proposed link exploits a magnetic coupling between two resonators fabricated by using a conductive non-woven fabric for the conductive parts and leather as substrate, thus resulting in a prototype that can be easily embedded in wearable accessories such as fashion bags. Experimental data referring to a prototype working in the...
This paper presents a wireless energy link for rechargeable implantable pulse generators for deep brain stimulation. The proposed link exploits a magnetic coupling between two compact planar resonators. From experimental results referring to a prototype working in the MedRadio band a transfer efficiency of about 10.62% is demonstrated.
In this paper a wireless power transfer resonant link using inductive coupling is considered and analyzed on the basis of an artificial transmission line approach. More specifically, a periodic network consisting of inductively coupled LC resonators is studied. It is demonstrated that the analyzed system exhibits a pass-band characterized by negative effective parameters (i.e., a double negative pass-band)...
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