Abstract

Multilayer feed-forward Artificial Neural Networks (ANNs) are universal function approximators capable of modeling measurable functions to any desired degree of accuracy. In practice, designing practical, efficient neural network architectures requires significant effort and expertise. Further, designing efficient neural network architectures that fit optimally on hardware for the benefit of acceleration adds yet another degree of complexity. In this paper, we use Evolutionary Cell Aided Design (ECAD), a framework capable of searching the design spaces for ANN structures and reconfigurable hardware to find solutions based on a set of constraints and fitness functions. Providing a modular and scalable 2D systolic array based machine learning accelerator design built for an Arria 10 GX 1150 FPGA device using OpenCL enables results to be tested and deployed in real hardware. Along with the hardware, a software model of the architecture was developed to speed up the evolutionary process. We present results from the ECAD framework showing the effect various optimizations including accuracy, images per second, effective giga-operations per second, and latency have on both ANN and hardware configurations. Through this work we show that unique solutions can exist for each optimization resulting in the best performance. This work lays the foundation for finding machine learning based solutions for a wide range of applications having different system constraints.

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