Title :
An Analytical Model for Inductively Coupled Implantable Biomedical Devices With Ferrite Rods
Author :
Theilmann, P.T. ; Asbeck, P.M.
Author_Institution :
Dept. of Electr. & Comput. Eng., Univ. of California at San Diego, La Jolla, CA
Abstract :
Using approximations applicable to near field coupled implants simplified expressions for the complex mutual inductance of coaxial aligned coils with and without a cylindrical ferrite rod are derived. Experimental results for ferrite rods of various sizes and permeabilities are presented to verify the accuracy of this expression. An equivalent circuit model for the inductive link between an implant and power coil is then presented and used to investigate how ferrite size, permeability and loss affect the power available to the implant device. Enhancements in coupling provided by high frequency, low permeability nickel zinc rods are compared with low frequency high permeability manganese zinc rods.
Keywords :
biomedical electronics; coils; eddy current losses; equivalent circuits; ferrite devices; inductive power transmission; iron compounds; magnetic circuits; magnetic leakage; magnetic permeability; power supplies to apparatus; prosthetics; soft magnetic materials; FeMnZnO; FeNiZnO; biomedical devices; coaxial aligned coils; complex mutual inductance; cylindrical ferrite rod; equivalent circuit model; ferrite rod magnetic loss; ferrite rod permeability; implant device power supply; implant-power coil inductive link; inductively coupled implants; manganese zinc rods; near field coupled implants; nickel zinc rods; Analytical models; Coils; Coupling circuits; Ferrites; Frequency; Implantable biomedical devices; Implants; Mutual coupling; Permeability; Zinc; Biomedical power supplies; biomedical telemetry; ferrites; implantable biomedical devices; mutual coupling;
Journal_Title :
Biomedical Circuits and Systems, IEEE Transactions on
DOI :
10.1109/TBCAS.2008.2004776
