Title :
Scalable architecture for streaming neural information from implantable multichannel neuroprosthetic devices
Author :
Thomson, Kyle E. ; Suhail, Yasir ; Oweiss, Karim G.
Author_Institution :
ECE Dept., Michigan State Univ., East Lansing, MI, USA
Abstract :
Two hardware architectures for implementing lifting-based discrete wavelet transform (DWT) suitable for implantable, real-time operation of high-density sensor array neuroprosthetic devices. A core computational node (CN) is designed for use in both architectures to yield maximum processor usage. The first uses multiple pipelined replicas of the CN, requiring fewer clock cycles. The second architecture reuses a single CN, thus requires less chip area but longer time delay. By utilizing the difference between the data sampling rate and available computation bandwidth, the novelty of both designs lies in the scalability to an arbitrary number of channels by interleaving the DWT computation without affecting the real-time operability. Performance comparison and overall considerations of both designs are presented in details.
Keywords :
array signal processing; biosensors; brain; discrete wavelet transforms; medical signal processing; pipeline processing; prosthetics; real-time systems; signal sampling; DWT; computation bandwidth; computational node; data sampling rate; hardware architectures; high-density sensor array; implantable multichannel neuroprosthetic devices; lifting-based discrete wavelet transform; multiple pipelined replicas; neural information; processor usage; real-time operation; scalable architecture; streaming; Bandwidth; Clocks; Computer architecture; Delay effects; Discrete wavelet transforms; Hardware; Neural prosthesis; Sampling methods; Scalability; Sensor arrays;
Conference_Titel :
Circuits and Systems, 2005. ISCAS 2005. IEEE International Symposium on
Print_ISBN :
0-7803-8834-8
DOI :
10.1109/ISCAS.2005.1464844
