Oscillatory Neural Network as Hetero-Associative Memory for Image Edge Detection

Madeleine Abernot, Thierry Gil, Aida Todri-Sanial

Onderzoeksoutput: Hoofdstuk in Boek/Rapport/CongresprocedureConferentiebijdrageAcademicpeer review

6 Citaten (Scopus)

Samenvatting

The increasing amount of data to be processed on edge devices, such as cameras, has motivated Artificial Intelligence (AI) integration at the edge. Typical image processing methods performed at the edge, such as feature extraction or edge detection, use convolutional filters that are energy, computation, and memory hungry algorithms. But edge devices and cameras have scarce computational resources, bandwidth, and power and are limited due to privacy constraints to send data over to the cloud. Thus, there is a need to process image data at the edge. Over the years, this need has incited a lot of interest in implementing neuromorphic computing at the edge. Neuromorphic systems aim to emulate the biological neural functions to achieve energy-efficient computing. Recently, Oscillatory Neural Networks (ONNs) present a novel brain-inspired computing approach by emulating brain oscillations to perform auto-associative memory types of applications. To speed up image edge detection and reduce its power consumption, we perform an in-depth investigation with ONNs. We propose a novel image processing method by using ONNs as a Heterogeneous Associative Memory (HAM) for image edge detection. We simulate our ONN-HAM solution using first, a Matlab emulator, and then a fully digital ONN design. We show results on gray scale square evaluation maps, also on black and white and gray scale 28x28 MNIST images and finally on black and white 512x512 standard test images. We compare our solution with standard edge detection filters such as Sobel and Canny. Finally, using the fully digital design simulation results, we report on timing and resource characteristics, and evaluate its feasibility for real-time image processing applications. Our digital ONN-HAM solution can process images with up to 120x120 pixels (166 MHz system frequency) respecting real-time camera constraints. This work is the first to explore ONNs as hetero-associative memory for image processing applications.

Originele taal-2Engels
TitelProceedings of the 2022 Annual Neuro-Inspired Computational Elements Conference, NICE 2022
UitgeverijAssociation for Computing Machinery, Inc
Pagina's13-21
Aantal pagina's9
ISBN van elektronische versie978-1-4503-9559-5
DOI's
StatusGepubliceerd - 28 mrt. 2022
Extern gepubliceerdJa
Evenement2022 Annual Neuro-Inspired Computational Elements Conference, NICE 2022 - Virtual, Online, Verenigde Staten van Amerika
Duur: 28 mrt. 20221 apr. 2022

Publicatie series

NaamACM International Conference Proceeding Series

Congres

Congres2022 Annual Neuro-Inspired Computational Elements Conference, NICE 2022
Land/RegioVerenigde Staten van Amerika
StadVirtual, Online
Periode28/03/221/04/22

Bibliografische nota

Publisher Copyright:
© 2022 ACM.

Financiering

This work was supported by the European Union’s Horizon 2020 research and innovation program, EU H2020 NEURONN project under Grant 871501 (www.neuronn.eu). This work was supported by the European Union's Horizon 2020 research and innovation program, EU H2020 NEURONN project under Grant 871501 (www.neuronn.eu).

FinanciersFinanciernummer
European Union’s Horizon Europe research and innovation programme871501
European Commission

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