• DocumentCode
    1446226
  • Title

    Integrated High-Voltage Inductive Power and Data-Recovery Front End Dedicated to Implantable Devices

  • Author

    Mounaim, F. ; Sawan, M.

  • Author_Institution
    Dept. of Electr. Eng., Ecole Polytech. de Montreal, Montreal, QC, Canada
  • Volume
    5
  • Issue
    3
  • fYear
    2011
  • fDate
    6/1/2011 12:00:00 AM
  • Firstpage
    283
  • Lastpage
    291
  • Abstract
    In near-field electromagnetic links, the inductive voltage is usually much larger than the compliance of low-voltage integrated-circuit (IC) technologies used for the implementation of implantable devices. Thus most integrated power-recovery approaches limit the induced signal to low voltages with inefficient shunt regulation or voltage clipping. In this paper, we propose using high-voltage (HV) complementary metal-oxide semiconductor technology to fully integrate the inductive power and data-recovery front end while adopting a step-down approach where the inductive voltage is left free up to 20 or 50 V. The advantage is that excessive inductive power will translate to an additional charge that can be stored in a capacitor, instead of shunting to ground excessive current with voltage limiters. We report the design of two consecutive HV custom ICs-IC1 and IC2-fabricated in DALSA semiconductor C08G and C08E technologies, respectively, with a total silicon area (including pads) of 4 and 9 mm2, respectively. Both ICs include HV rectification and regulation; however, IC2 includes two enhanced rectifier designs, a voltage-doubler, and a bridge rectifier, as well as data recovery. Postlayout simulations show that both IC2 rectifiers achieve more than 90% power efficiency at a 1-mA load and provide enough room for 12-V regulation at a 3-mA load and a maximum-available inductive power of 50 mW only. Successful measurement results show that HV regulators provide a stable 3.3- to 12-V supply from an unregulated input up to 50 or 20 V for IC1 and IC2, respectively, with performance that matches simulation results.
  • Keywords
    CMOS integrated circuits; biomedical telemetry; data communication equipment; energy harvesting; inductive power transmission; power integrated circuits; prosthetic power supplies; rectification; rectifiers; voltage control; DALSA semiconductor C08E technology; DALSA semiconductor C08G technology; bridge rectifier; current 1 mA; current 3 mA; data recovery front end; high voltage CMOS technology; high voltage integrated circuits; high voltage rectification; high voltage regulation; implantable devices; inductive power front end; inductive voltage; integrated high voltage inductive power; integrated power recovery; near field electromagnetic links; post layout simulations; power 50 mW; size 4 mm; size 9 mm; step down approach; voltage 3.3 V to 12 V; voltage doubler; Bridge circuits; Capacitors; Logic gates; MOS devices; Regulators; Transistors; Voltage control; Bridge circuits; complementary metal–oxide semiconductor (CMOS) integrated circuits; high-voltage techniques; implantable biomedical devices; inductive power transmission; rectifiers; regulators;
  • fLanguage
    English
  • Journal_Title
    Biomedical Circuits and Systems, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1932-4545
  • Type

    jour

  • DOI
    10.1109/TBCAS.2010.2103558
  • Filename
    5710602