| Literature DB >> 26609390 |
Anil Kumar RamRakhyani1, Gianluca Lazzi1.
Abstract
The need to correctly predict the voltage across terminals of mm-sized coils, with ferrite core, to be employed for magnetic stimulation of the peripheral neural system is the motivation for this work. In such applications, which rely on a capacitive discharge on the coil to realise a transient voltage curve of duration and strength suitable for neural stimulation, the correct modelling of the non-linearity of the ferrite core is critical. A demonstration of how a finite-difference model of the considered coils, which include a model of the current-controlled inductance in the coil, can be used to correctly predict the time-domain voltage waveforms across the terminals of a test coil is presented. Five coils of different dimensions, loaded with ferrite cores, have been fabricated and tested: the measured magnitude and width of the induced pulse are within 10% of simulated values.Entities:
Keywords: Fe3O4; bioelectric potentials; biomagnetism; capacitive discharge; coils; current-controlled inductance; ferrite core nonlinearity; ferrites; finite difference methods; finite-difference model; magnetic neurostimulation; neurophysiology; patient treatment; peripheral neural system; time-domain voltage waveforms; transient voltage curve
Year: 2014 PMID: 26609390 PMCID: PMC4614077 DOI: 10.1049/htl.2014.0087
Source DB: PubMed Journal: Healthc Technol Lett ISSN: 2053-3713