A 64-channel back-gate adapted ultra-low-voltage spike-aware neural recording front-end with on-chip lossless/near-lossless compression engine and 3.3V stimulator in 22nm FDSOI
A 64-channel back-gate adapted ultra-low-voltage spike-aware neural recording front-end with on-chip lossless/near-lossless compression engine and 3.3V stimulator in 22nm FDSOI
In neural implants and biohybrid research systems, the integration of electrode recording and stimulation front-ends with pre-processing circuitry promises a drastic increase in real-time capabilities [1,6]. In our proposed neural recording system, constant sampling with a bandwidth of 9.8kHz yields 6.73μV input-referred noise (IRN) at a power-per-channel of 0.34μW for the time-continuous ΔΣ−modulator, and 0.52μW for the digital filters and spike detectors. We introduce dynamic current/bandwidth selection at the ΔΣ and digital filter to reduce recording bandwidth at the absence of spikes (i.e. local field potentials). This is controlled by a two-level spike detection and adjusted by adaptive threshold estimation (ATE). Dynamic bandwidth selection reduces power by 53.7%, increasing the available channel count at a low heat dissipation. Adaptive back-gate voltage tuning (ABGVT) compensates for PVT variation in subthreshold circuits. This allows 1.8V input/output (IO) devices to operate at 0.4V supply voltage robustly. The proposed 64-channel neural recording system moreover includes a 16-channel adaptive compression engine (ACE) and an 8-channel on-chip current stimulator at 3.3V. The stimulator supports field-shaping approaches, promising increased selectivity in future research.
- TU Dresden Germany
22nm FDSOI, Kompressions-Engine, Elektrode, Tiefpass, Stromquelle, Hochpassfilter, Digitalfilter, Überspannung, Vorhandensein von Modi, Echtzeitfähigkeit, dynamische Auswahl, Spike-Erkennung, Steigerung der Leistungsfähigkeit, neuronale Implantate, Kanalanzahl, eingangsbezogenes Rauschen, Rückkopplungselemente, arithmetische Kodierung, adaptive Abstimmung, ddc:530, 22nm FDSOI, Compression Engine, Electrode, Low-pass, Current Source, High-pass Filter, Digital Filter, Overvoltage, Presence Of Modes, Real-time Capability, Dynamic Selection, Spike Detection, Increase In Capability, Neural Implants, Channel Count, Input-referred Noise, Feedback Elements, Arithmetic Coding, Adaptive Tuning, info:eu-repo/classification/ddc/530
22nm FDSOI, Kompressions-Engine, Elektrode, Tiefpass, Stromquelle, Hochpassfilter, Digitalfilter, Überspannung, Vorhandensein von Modi, Echtzeitfähigkeit, dynamische Auswahl, Spike-Erkennung, Steigerung der Leistungsfähigkeit, neuronale Implantate, Kanalanzahl, eingangsbezogenes Rauschen, Rückkopplungselemente, arithmetische Kodierung, adaptive Abstimmung, ddc:530, 22nm FDSOI, Compression Engine, Electrode, Low-pass, Current Source, High-pass Filter, Digital Filter, Overvoltage, Presence Of Modes, Real-time Capability, Dynamic Selection, Spike Detection, Increase In Capability, Neural Implants, Channel Count, Input-referred Noise, Feedback Elements, Arithmetic Coding, Adaptive Tuning, info:eu-repo/classification/ddc/530
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