English

A scalable and efficient convolutional neural network accelerator using HLS for a System on Chip design

Computer Vision and Pattern Recognition 2020-10-08 v2 Hardware Architecture

Abstract

This paper presents a configurable Convolutional Neural Network Accelerator (CNNA) for a System on Chip design (SoC). The goal was to accelerate inference of different deep learning networks on an embedded SoC platform. The presented CNNA has a scalable architecture which uses High Level Synthesis (HLS) and SystemC for the hardware accelerator. It is able to accelerate any Convolutional Neural Network (CNN) exported from Python and supports a combination of convolutional, max-pooling, and fully connected layers. A training method with fixed-point quantized weights is proposed and presented in the paper. The CNNA is template-based, enabling it to scale for different targets of the Xilinx Zynq platform. This approach enables design space exploration, which makes it possible to explore several configurations of the CNNA during C- and RTL-simulation, fitting it to the desired platform and model. The CNN VGG16 was used to test the solution on a Xilinx Ultra96 board using PYNQ. The result gave a high level of accuracy in training with an auto-scaled fixed-point Q2.14 format compared to a similar floating-point model. It was able to perform inference in 2.0 seconds, while having an average power consumption of 2.63 W, which corresponds to a power efficiency of 6.0 GOPS/W.

Keywords

Cite

@article{arxiv.2004.13075,
  title  = {A scalable and efficient convolutional neural network accelerator using HLS for a System on Chip design},
  author = {Kim Bjerge and Jonathan Horsted Schougaard and Daniel Ejnar Larsen},
  journal= {arXiv preprint arXiv:2004.13075},
  year   = {2020}
}

Comments

18 pages, 12 figures

R2 v1 2026-06-23T15:08:02.968Z