Archive/A Substrate-Aware CMOS Micromagnetic Stimulation SoC with a Bent Micro-Coil and Programmable Triangular Current Driver
A Substrate-Aware CMOS Micromagnetic Stimulation SoC with a Bent Micro-Coil and Programmable Triangular Current Driver
Ji Won Kim, Dong Hun Cha, Seung Hwan Lee et al.
10. Juli 2026
en

Abstract

Microscopic magnetic stimulation (MSTI) induces electric fields without direct charge injection and can shape localized field gradients with asymmetric micro-coils. Most demonstrations still rely on external drivers, off-chip hardware, or separated coil validation, so the CMOS integration boundary remains poorly characterized. This work presents a fabricated 2×1mm20.18μm CMOS magnetic-stimulation SoC that co-integrates ASK-compatible command decoding, FSM and register-based parameter control, a programmable current–voltage–current triangular driver, and a bent top-metal micro-coil, and it characterizes the on-chip driver-to-coil path together with a substrate-aware field model. Sensing-load reconstruction confirms command-to-waveform programmability, including duration-window decoding, burst-count control, and polarity reversal, with measured slew targets that give a peak current of Ipk=3.72–21.6mA. A quantitative comparison contrasts the current-mode triangular driver with conventional electrode stimulators, a coil-impedance measurement shows the coil stays resistive across 1 to 10 MHz, and the measured total SoC power is about 41 mW. Substrate-aware simulation at a 15μm target plane shows that the grounded p-substrate retains 35.1–40.5% of the no-substrate peak x-directed field-gradient metric. The prototype establishes this electrical programmability and the substrate-aware gradient-transfer loss as a compact design-margin metric for CMOS-integrated magnetic stimulation. Direct biological activation is not claimed and is left to future in vitro validation.

IPC Classification

H01

Keywords

substrate-awarecmosmicromagneticstimulationbentmicro-coilprogrammabletriangularcurrentdriverelectronicsmicroscopicmagneticmstiinduceselectricfieldswithoutdirectchargeinjectionshapelocalizedfield
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