For many years, transcutaneous energy transfer (TET) systems have been developed for energizing total artificial heart systems. Although such a basic system can be developed without too much design effort, optimization toward high power transfer efficiency forces the introduction of novel system topologies and design strategies. In addition, for medical applications, the thermal impact of a TET system on the biological tissue should be taken into account, resulting in limitations on usable coil geometries. This article presents a TET system that has been developed for a power transfer of 25 W over a distance of 1 cm with minimal dimensions of 1 x 6 x 4 cm for the external driver and 5 x 3 x 1 cm for the internal electronics. The coil geometries have a thickness of 2 mm and a diameter of 6 cm. An overall system efficiency of 80% was achieved for an internal load of 25 W.
A microsystem for wireless long-term measurement of the intraocular
pressure is presented. The sensing element is a novel distributed
parallel-resonant inductive-capacative circuit, with a pressure-dependent
resonance frequency. This circuit is based upon a twofold on-chip deposited
inductor. The high Q inductor is deposited by electrodeposition of copper on
a micromachined chip incorporating a pressure-sensitive diaphragm. Test
structures were fabricated and characterized. Q factors of 30 at 45 MHz and
inductance values of 0.4 µH are obtained for 3×3 mm2
structures.
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