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A 9-V-Tolerant Stacked-Switched-Capacitor Stimulation System With Level-Adaptive Switch Control and Rapid Stimulus-Synchronized Charge Balancing for Implantable Devices

Minju Park, Kyeongho Eom, Han-Sol Lee, Seung-Beom Ku, Hyung‐Min Lee

2023IEEE Journal of Solid-State Circuits11 citationsDOI

Abstract

This article proposes a stacked-switched-capacitor stimulation (SSCS) system that can provide up to 9-V stimulation without using an external high-voltage (HV) supply or HV conversion stages to supply the stimulator. With the level-adaptive switch control, SSCS can be HV tolerant using only low-voltage (LV) transistors. In addition, SSCS achieves high stimulation efficiency up to 71.4%, which includes charging and discharging efficiencies of 72.6% and 99.9%, respectively, to charge 1- <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"> <tex-math notation="LaTeX">$\mu \text{F}$ </tex-math></inline-formula> capacitor from 0 to 4 V by adopting the ac-to-capacitor charger and the stacked-capacitor stimulus discharger. Charge balancing (CB) can also be achieved in rapid time using the stimulus-synchronized CB (SS-CB) method which adaptively controls the pulsewidth of the recovery phase. The SSCS prototype verifies that the residual voltage up to 900 mV can be suppressed within four stimulation cycles and maintained within ±30 mV by utilizing SS-CB.

Topics & Concepts

CapacitorStimulationSwitched capacitorVoltageElectrical engineeringStimulus (psychology)NotationMaterials scienceComputer scienceMathematicsNeuroscienceEngineeringBiologyArithmeticPsychologyPsychotherapistNeuroscience and Neural EngineeringWireless Power Transfer SystemsAdvanced Memory and Neural Computing
A 9-V-Tolerant Stacked-Switched-Capacitor Stimulation System With Level-Adaptive Switch Control and Rapid Stimulus-Synchronized Charge Balancing for Implantable Devices | Litcius