A 4096 channel event-based multielectrode array with asynchronous outputs compatible with neuromorphic processors
Matteo Cartiglia, Filippo Costa, Shyam Narayanan, Cat-Vu H. Bui, Hasan Uluşan, Nicoletta Risi, Germain Haessig, Andreas Hierlemann, Fernando Cardes, Giacomo Indiveri
Abstract
Bio-signal sensing is pivotal in medical bioelectronics. Traditional methods focus on high sampling rates, leading to large amounts of irrelevant data and high energy consumption. We introduce a self-clocked microelectrode array (MEA) that digitizes bio-signals at the pixel level by encoding changes as asynchronous digital address-events only when they exceed a threshold, significantly reducing off-chip data transmission. This novel MEA comprises a 64 × 64 electrode array, an asynchronous 2D-arbiter, and an Address-Event Representation (AER) communication block. Each pixel operates autonomously, monitoring voltage fluctuations from cellular activity and producing digital pulses for significant changes. Positive and negative signal changes are encoded as “up” and “down” events and are routed off-chip via the asynchronous arbiter. We present results from chip characterization and experimental measurements using electrogenic cells. Additionally, we interface the MEA to a mixed-signal neuromorphic processor, demonstrating a prototype for end-to-end event-based bio-signal sensing and processing. Developing efficient real-time closed-loop interfacing with neuromorphic processors is a challenge. The authors report a GAIA sensor, which is a 4096-channel event-based MEA that encodes biopotentials in event-based pulses reducing data transmission and power consumption.