Performance characterization of variable width square coils for inductive link wireless power transfer

Abstract: Supplying power to electronic medical implants (EMI) by inductive coupling has always been appreciated for its biocompatibility and its ability to transmit sufficient power to the implants. Although this method was introduced a long time ago, several challenges remain. The major challenge is the sensitivity of the link to coupling and quality factor variations which are strongly dependent on the separation distance and lateral displacements between receiving and issuing coils. In this context and in order to i… Show more

“…By designing inconstant conductor width distributions and spatial distributions, Q-factor enhancement is attained in double-layer printed spiral resonator [49], printed circular resonator [50], and stacked multilayer printed spiral resonator [51]. This is made possible as losses induced by eddy current are hindered with designs that involve gradual decrement of conductive trace widths from the outermost loop to the innermost loop [52] unlike conventional constant width for all loops.…”

Dual-Band Resonator Designs for Near-Field Wireless Energy Transfer Applications

“…By designing inconstant conductor width distributions and spatial distributions, Q-factor enhancement is attained in double-layer printed spiral resonator [49], printed circular resonator [50], and stacked multilayer printed spiral resonator [51]. This is made possible as losses induced by eddy current are hindered with designs that involve gradual decrement of conductive trace widths from the outermost loop to the innermost loop [52] unlike conventional constant width for all loops.…”

Dual-Band Resonator Designs for Near-Field Wireless Energy Transfer Applications

Design Optimization of Multiple-Layer PSCs With Minimal Losses for Efficient and Robust Inductive Wireless Power Transfer