H. Hutten, H. Scharfetter, W. Ninaus, Bernhard Puswald, G. I. Petrova, D. Kovachev
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Inductively coupled wideband transceiver for bioimpedance spectroscopy (IBIS)
Most measurement devices for bioimpedance spectroscopy are coupled to the measured object (tissue) via electrodes. At frequencies >500 kHz they suffer from artifacts due to stray capacitances between electrode leads as well as between ground and object. The non-invasive measurement of the brain conductivity is hardly possible with surface electrodes. These disadvantages can be obviated by inductive coupling. The aim of this work was the development of a wideband transceiver. In order to define its specifications a feasibility study has been carried out with a simulation model for two different coil systems above a homogeneous conducting plate. According to simulation results both systems render possible to resolve conductivity changes down to 10/sup -3/(/spl Omega/m)/sup -1/ at 50 kHz. The sensitivity increases with the square of the frequency. The receiver electronics must then resolve voltages >=1 /spl mu/V at an excitation current of 1 A. We have realized a transceiver which matches these specifications with a S/N-ratio of 22 dB at 1 /spl mu/V. The frequency range is 50 kHz-5 MHz.
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