论文信息 - 27.1 A 2.8µW 80mVpp-linear-input-range 1.6GΩ-input impedance bio-signal chopper amplifier tolerant to common-mode interference up to 650mVpp

27.1 A 2.8µW 80mVpp-linear-input-range 1.6GΩ-input impedance bio-signal chopper amplifier tolerant to common-mode interference up to 650mVpp

Closed-loop neuromodulation with simultaneous stimulation and sensing is desired to administer therapy in patients suffering from drug-resistant neurological ailments. However, stimulation generates large artifacts at the recording sites, which saturate traditional front-ends. The common-mode (CM) artifact can be ∼500mV, and the differential-mode (DM) artifact is 50 to 100mV. This work presents a neural recording chopper amplifier that can tolerate 80mV<inf>pp</inf> DM and 650mV<inf>pp</inf> CM artifacts in a signal band of 1Hz to 5kHz. To digitize a 2mV<inf>pp</inf> neural signal to 8b accompanied by an 80mV<inf>pp</inf> DM artifact requires a linearity of 80dB. Neural recording front-ends also need to function within a power budget of 3 to 5µW/ch, input-referred noise of 4 to 8µV<inf>rms</inf>, DC input impedance Z<inf>in</inf>>1GΩ and high-pass cutoff of 1Hz [1,2]. Prior work has addressed power and noise [2–6], but has low Z<inf>in</inf> and limited input signal range, making them incapable of performing true closed-loop operation.

Hariprasad Chandrakumar | Dejan Markovic

[1] A.-T. Avestruz,et al. A 2 $\mu\hbox{W}$ 100 nV/rtHz Chopper-Stabilized Instrumentation Amplifier for Chronic Measurement of Neural Field Potentials , 2007, IEEE Journal of Solid-State Circuits.

[2] Hariprasad Chandrakumar,et al. 5.5 A 2µW 40mVpp linear-input-range chopper- stabilized bio-signal amplifier with boosted input impedance of 300MΩ and electrode-offset filtering , 2016, 2016 IEEE International Solid-State Circuits Conference (ISSCC).

[3] Jan M. Rabaey,et al. A 0.013mm2 5μW DC-coupled neural signal acquisition IC with 0.5V supply , 2011, 2011 IEEE International Solid-State Circuits Conference.