English

Speck: A Smart event-based Vision Sensor with a low latency 327K Neuron Convolutional Neuronal Network Processing Pipeline

Neural and Evolutionary Computing 2024-05-28 v2 Machine Learning Image and Video Processing

Abstract

Edge computing solutions that enable the extraction of high-level information from a variety of sensors is in increasingly high demand. This is due to the increasing number of smart devices that require sensory processing for their application on the edge. To tackle this problem, we present a smart vision sensor System on Chip (SoC), featuring an event-based camera and a low-power asynchronous spiking Convolutional Neural Network (sCNN) computing architecture embedded on a single chip. By combining both sensor and processing on a single die, we can lower unit production costs significantly. Moreover, the simple end-to-end nature of the SoC facilitates small stand-alone applications as well as functioning as an edge node in larger systems. The event-driven nature of the vision sensor delivers high-speed signals in a sparse data stream. This is reflected in the processing pipeline, which focuses on optimising highly sparse computation and minimising latency for 9 sCNN layers to 3.36{\mu}s for an incoming event. Overall, this results in an extremely low-latency visual processing pipeline deployed on a small form factor with a low energy budget and sensor cost. We present the asynchronous architecture, the individual blocks, and the sCNN processing principle and benchmark against other sCNN capable processors.

Keywords

Cite

@article{arxiv.2304.06793,
  title  = {Speck: A Smart event-based Vision Sensor with a low latency 327K Neuron Convolutional Neuronal Network Processing Pipeline},
  author = {Ole Richter and Yannan Xing and Michele De Marchi and Carsten Nielsen and Merkourios Katsimpris and Roberto Cattaneo and Yudi Ren and Yalun Hu and Qian Liu and Sadique Sheik and Tugba Demirci and Ning Qiao},
  journal= {arXiv preprint arXiv:2304.06793},
  year   = {2024}
}

Comments

accepted and presented at 28th IEEE International Symposium On Asynchronous Circuits and Systems (ASYNC) 2023

R2 v1 2026-06-28T10:05:23.128Z