期刊
NANOPHOTONICS
卷 9, 期 13, 页码 4097-4108出版社
WALTER DE GRUYTER GMBH
DOI: 10.1515/nanoph-2020-0055
关键词
integrated photonic; metasurface; neural networks; optical convolutions
资金
- Research and Development Office (RDO) at the Ministry of Education, Kingdom of Saudi Arabia [HIQI-36-201]
The technologically-relevant task of feature extraction from data performed in deep-learning systems is routinely accomplished as repeated fast Fourier transforms (FFT) electronically in prevalent domain-specific architectures such as in graphics processing units (GPU). However, electronics systems are limited with respect to power dissipation and delay, due to wire-charging challenges related to interconnect capacitance. Here we present a silicon photonics-based architecture for convolutional neural networks that harnesses the phase property of light to perform FFTs efficiently by executing the convolution as a multiplication in the Fourier-domain. The algorithmic executing time is determined by the time-of-flight of the signal through this photonic reconfigurable passive FFT 'filter' circuit and is on the order of 10's of picosecond short. A sensitivity analysis shows that this optical processor must be thermally phase stabilized conesponding to a few degrees. Furthermore, we find that for a small sample number, the obtainable number of convolutions per {time, power, and chip area) outperforms GPUs by about two orders of magnitude. Lastly, we show that, conceptually, the optical FFT and convolution-processing performance is indeed directly linked to optoelectronic device-level, and improvements in plasmonics, metamaterials or nanophotonics are fueling next generation densely interconnected intelligent photonic circuits with relevance for edge-computing 5G networks by processing tensor operations optically.
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