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22.2 A 176-channel 0.5cm3 0.7g wireless implant for motor function recovery after spinal cord injury.

, , , , , , , , and . ISSCC, page 382-383. IEEE, (2016)

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A Novel Biomimetic Stimulator System for Neural Implant., , , , , , and . NER, page 843-846. IEEE, (2019)The design of integrated 3-GHz to 11-GHz CMOS transmitter for full-band ultra-wideband (UWB) applications., , , , , and . ISCAS, page 2709-2712. IEEE, (2008)A 37.6mm2 1024-channel high-compliance-voltage SoC for epiretinal prostheses., , and . ISSCC, page 294-295. IEEE, (2013)A 3.110.6 GHz CMOS Direct-Conversion Receiver for UWB Applications., , and . ICECS, page 1328-1331. IEEE, (2006)Bio-impedance characterization technique with implantable neural stimulator using biphasic current stimulus., , and . EMBC, page 474-477. IEEE, (2014)22.2 A 176-channel 0.5cm3 0.7g wireless implant for motor function recovery after spinal cord injury., , , , , , , , and . ISSCC, page 382-383. IEEE, (2016)A 64-channel neuron recording system., , , , and . EMBC, page 2862-2865. IEEE, (2011)Wireless Gigabit Data Telemetry for Large-Scale Neural Recording., , , , and . IEEE J. Biomed. Health Informatics, 19 (3): 949-957 (2015)A Wireless Platform to Support Pre-Clinical Trial of Neural Implant for Spinal Cord Injury., , , and . EMBC, page 5487-5490. IEEE, (2018)A hybrid hardware and software approach for cancelling stimulus artifacts during same-electrode neural stimulation and recording., , , and . EMBC, page 6190-6193. IEEE, (2016)