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Hauptverfasser: Smets, Laura, Van Leekwijck, Werner, Tsang, Ing Jyh, Latré, Steven
Format: Preprint
Veröffentlicht: 2023
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2312.00454
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author Smets, Laura
Van Leekwijck, Werner
Tsang, Ing Jyh
Latré, Steven
author_facet Smets, Laura
Van Leekwijck, Werner
Tsang, Ing Jyh
Latré, Steven
contents Hyperdimensional Computing (HDC) is a brain-inspired and light-weight machine learning method. It has received significant attention in the literature as a candidate to be applied in the wearable internet of things, near-sensor artificial intelligence applications and on-device processing. HDC is computationally less complex than traditional deep learning algorithms and typically achieves moderate to good classification performance. A key aspect that determines the performance of HDC is the encoding of the input data to the hyperdimensional (HD) space. This article proposes a novel light-weight approach relying only on native HD arithmetic vector operations to encode binarized images that preserves similarity of patterns at nearby locations by using point of interest selection and local linear mapping. The method reaches an accuracy of 97.35% on the test set for the MNIST data set and 84.12% for the Fashion-MNIST data set. These results outperform other studies using baseline HDC with different encoding approaches and are on par with more complex hybrid HDC models. The proposed encoding approach also demonstrates a higher robustness to noise and blur compared to the baseline encoding.
format Preprint
id arxiv_https___arxiv_org_abs_2312_00454
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle An Encoding Framework for Binarized Images using HyperDimensional Computing
Smets, Laura
Van Leekwijck, Werner
Tsang, Ing Jyh
Latré, Steven
Computer Vision and Pattern Recognition
Machine Learning
Hyperdimensional Computing (HDC) is a brain-inspired and light-weight machine learning method. It has received significant attention in the literature as a candidate to be applied in the wearable internet of things, near-sensor artificial intelligence applications and on-device processing. HDC is computationally less complex than traditional deep learning algorithms and typically achieves moderate to good classification performance. A key aspect that determines the performance of HDC is the encoding of the input data to the hyperdimensional (HD) space. This article proposes a novel light-weight approach relying only on native HD arithmetic vector operations to encode binarized images that preserves similarity of patterns at nearby locations by using point of interest selection and local linear mapping. The method reaches an accuracy of 97.35% on the test set for the MNIST data set and 84.12% for the Fashion-MNIST data set. These results outperform other studies using baseline HDC with different encoding approaches and are on par with more complex hybrid HDC models. The proposed encoding approach also demonstrates a higher robustness to noise and blur compared to the baseline encoding.
title An Encoding Framework for Binarized Images using HyperDimensional Computing
topic Computer Vision and Pattern Recognition
Machine Learning
url https://arxiv.org/abs/2312.00454