FPGA Based Silicon Spiking Neural Array

Author

Cassidy, Andrew ; Denham, S. ; Kanold, P. ; Andreou, Andreas

Author_Institution

Johns Hopkins Univ., Baltimore

fYear

2007

fDate

27-30 Nov. 2007

Firstpage

75

Lastpage

78

Abstract

Rapid design time, low cost, flexibility, digital precision, and stability are characteristics that favor FPGAs as a promising alternative to analog VLSI based approaches for designing neuromorphic systems. High computational power as well as low size, weight, and power (SWAP) are advantages that FPGAs demonstrate over software based neuromorphic systems. We present an FPGA based array of Leaky-Integrate and Fire (LIF) artificial neurons. Using this array, we demonstrate three neural computational experiments: auditory Spatio-Temporal Receptive Fields (STRFs), a neural parameter optimizing algorithm, and an implementation of the Spike Time Dependant Plasticity (STDP) learning rule.

Keywords

elemental semiconductors; field programmable gate arrays; neural chips; silicon; FPGA; STDP; STRF; Si; auditory spatio-temporal receptive fields; leaky integrate-and-fire artificial neurons; neural parameter optimizing algorithm; neuromorphic systems; silicon spiking neural array; spike time dependant plasticity learning rule; Analog computers; Biological system modeling; Biology computing; Computer architecture; Costs; Field programmable gate arrays; Neuromorphics; Neurons; Silicon; Very large scale integration;

fLanguage

English

Publisher

ieee

Conference_Titel

Biomedical Circuits and Systems Conference, 2007. BIOCAS 2007. IEEE

Conference_Location

Montreal, Que.

Print_ISBN

978-1-4244-1524-3

Electronic_ISBN

978-1-4244-1525-0

Type

conf

DOI

10.1109/BIOCAS.2007.4463312

Filename

4463312