1. Fully Integrated Biopotential Acquisition Analog Front-End IC
- Author
-
Hyungseup Kim, Haryong Song, Yunjong Park, and Hyoungho Ko
- Subjects
Materials science ,DC servo loop (DSL) ,capacitive input boosting loop (CIBL) ,lcsh:Chemical technology ,Biochemistry ,Article ,Analytical Chemistry ,law.invention ,Chopper ,User-Computer Interface ,Analog front-end ,Common-mode rejection ratio ,law ,Humans ,lcsh:TP1-1185 ,Electrical and Electronic Engineering ,biopotential ,capacitively-coupled chopper instrumentation amplifier(CCIA) ,ripple reduction loop (RRL) ,capacitiveinput boosting loop (CIBL) ,Electrodes ,Instrumentation ,Capacitive coupling ,Amplifiers, Electronic ,Input offset voltage ,business.industry ,Electrical engineering ,Signal Processing, Computer-Assisted ,Equipment Design ,capacitively-coupled chopper instrumentation amplifier (CCIA) ,Atomic and Molecular Physics, and Optics ,Capacitor ,Semiconductors ,CMOS ,Instrumentation amplifier ,business - Abstract
A biopotential acquisition analog front-end (AFE) integrated circuit (IC) is presented. The biopotential AFE includes a capacitively coupled chopper instrumentation amplifier (CCIA) to achieve low input referred noise (IRN) and to block unwanted DC potential signals. A DC servo loop (DSL) is designed to minimize the offset voltage in the chopper amplifier and low frequency respiration artifacts. An AC coupled ripple rejection loop (RRL) is employed to reduce ripple due to chopper stabilization. A capacitive impedance boosting loop (CIBL) is designed to enhance the input impedance and common mode rejection ratio (CMRR) without additional power consumption, even under an external electrode mismatch. The AFE IC consists of two-stage CCIA that include three compensation loops (DSL, RRL, and CIBL) at each CCIA stage. The biopotential AFE is fabricated using a 0.18 mu m one polysilicon and six metal layers (1P6M) complementary metal oxide semiconductor (CMOS) process. The core chip size of the AFE without input/output (I/O) pads is 10.5 mm(2). A fourth-order band-pass filter (BPF) with a pass-band in the band-width from 1 Hz to 100 Hz was integrated to attenuate unwanted signal and noise. The overall gain and band-width are reconfigurable by using programmable capacitors. The IRN is measured to be 0.94 mu V-RMS in the pass band. The maximum amplifying gain of the pass-band was measured as 71.9 dB. The CIBL enhances the CMRR from 57.9 dB to 67 dB at 60 Hz under electrode mismatch conditions.
- Published
- 2015