Yechan Park, Seok-Tae Koh, Jeongeun Lee, Hong-Gyeom Kim, Jaesuk Choi, S. Ha, Chul-Woong Kim, M. Je
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A Frequency-Splitting-Based Wireless Power and Data Transfer IC for Neural Prostheses with Simultaneous 115mWPower and 2.5Mb/s Forward Data Delivery
The electrical cochlear implants (Cls) have given > 500,000 patients worldwide a better life to date. However, the electrical neural stimulation has limited spatial resolution due to the spread of stimulation current, which reduces the number of effective channels to < 10 and results in a restricted perception of sound. Recently developed CIs such as optogenetic Cls have overcome this limitation, enabling much higher effective channel count [1]. However, such CIs require much larger power consumption (>100mW) and a higher data transmission rate (>lMb/s) than conventional Cls. As a result, designing a simultaneous wireless power and data transfer (SWPDT) system becomes challenging. AIso, due to the short distance between transmitter (TX) and receiver (RX) coils separated only by a scalp, frequency splitting may occur, and it should be carefully considered.
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