Cellular neural networks for image analysis using steep slope devices

Abstract

Traditional CMOS based von Neumann architectures face daunting challenges in performing complex computational tasks at high speed and with low power on spatio-temporal data, e.g., image processing, pattern recognition, etc. In this study, we discuss the utilities of various steep slope, beyond-CMOS emerging devices for image processing applications within the non-von Neumann computing paradigm of cellular neural networks (CNNs). In general, the steep subthreshold swing of the devices obviates the output transfer hardware used in a conventional CNN cell. For image processing with binary stable outputs, Tunnelling FETs (TFETs) can facilitate low power operation. For multi-valued problems, devices like graphene transistors, Symmetric tunnelling FETs (SymFETs) might be leveraged to solve a problem with fewer computational steps. The potential for additional hardware reduction when compared to functional equivalents via conventional CNNs is also possible. Emerging devices can also lead to lower power implementations of the voltage controlled current sources (VCCSs) that are an integral component of any CNN cell. Furthermore, non-linear implementations of the VCCSs via emerging devices could enable simpler computational paths for many image processing tasks.