A biomimetic adaptive algorithm and low-power architecture for implantable neural decoders
Abstract
Algorithmically and energetically efficient computational architectures that operate in real time are essential for clinically useful neural prosthetic devices. Such devices decode raw neural data to obtain direct control signals for external devices. They can also perform data compression and vastly reduce the bandwidth and consequently power expended in wireless transmission of raw data from implantable brain-machine interfaces. We describe a biomimetic algorithm and micropower analog circuit architecture for decoding neural cell ensemble signals. The decoding algorithm implements a continuous-time artificial neural network, using a bank of adaptive linear filters with kernels that emulate synaptic dynamics. The filters transform neural signal inputs into control-parameter outputs, and can be tuned automatically in an on-line learning process. We provide experimental validation of our system using neural data from thalamic head-direction cells in an awake behaving rat.
Additional Information
© 2009 IEEE. Manuscript received April 2009. This work was funded in part by National Institutes of Health grants R01-NS056140 and R01-EY15545, the McGovern Institute Neurotechnology Program at MIT, and National Eye Institute grant R01-EY13337. Rapoport received support from a CIMIT–MIT Medical Engineering Fellowship.Attached Files
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Additional details
- Eprint ID
- 94131
- Resolver ID
- CaltechAUTHORS:20190325-154918574
- NIH
- R01-NS056140
- NIH
- R01-EY15545
- Massachusetts Institute of Technology (MIT)
- NIH
- R01-EY13337
- National Eye Institute
- Created
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2019-03-25Created from EPrint's datestamp field
- Updated
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2021-11-16Created from EPrint's last_modified field