Future high-density and high channel count neural interfaces that enable simultaneous
recording of tens of thousands of neurons will provide a gateway to study, restore and …

This paper investigates the efficacy of a wired-OR compressive readout architecture for
neural recording, which enables simultaneous data compression of action potential signals …

Neural interfaces of the future will be used to help restore lost sensory, motor, and other
capabilities. However, realizing this futuristic promise requires a major leap forward in how …

Multi-Electrode Arrays (MEA) have been widely used in neuroscience experiments.
However, the reduction of their wireless transmission power consumption remains a major …

Next generation neural recording and brain-machine interface (BMI) devices call for high
density or distributed systems with more than 1000 recording sites. As the recording site …

Wireless transmission of the recorded neural data without exceeding the extremely-limited
available power is one of the most significant challenges in developing implantable brain …

Implantable microsystems that collect and transmit neural data are becoming very useful
entities in the field of neuroscience. Limited by high data rates, on-chip compression is often …

Neuroscience research into how complex brain functions are implemented at an extra-
cellular level requires in vivo neural recording interfaces, including microelectrodes and …

The massive amount of data recorded by dense electrode arrays which are routinely
connected to Nyquist-sampling signal conditioning blocks introduces new design …

We present a fully implantable neural recording IC with a spike-driven data compression
scheme to improve the power efficiency and preserve crucial data for monitoring brain …