Associative Memory based on clustered Neural Networks: Improved model and architecture for Oriented Edge Detection

2016 Conference on Design and Architectures for Signal and Image Processing (DASIP) Pub Date : 2016-10-10 DOI:10.1109/DASIP.2016.7853796

R. Danilo, Hugues Wouafo, C. Chavet, Vincent Gripon, L. Conde-Canencia, P. Coussy

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引用次数: 3

Abstract

Associative Memories (AM) are storage devices that allow addressing content from part of it, in opposition of classical index-based memories. This property makes them promising candidates for various search challenges including pattern detection in images. Clustered based Neural Networks (CbNN) allow efficient design of AM by providing fast pattern retrieval, especially when implemented in hardware. In particular, they can be used to store and next quickly identify oriented edges in images. However, current models of CbNN only provide good performances when facing erasures in the inputs. This paper introduces several improvements to the CbNN model in order to cope with intrusion and additive noises. Namely, we change the initialization of neurons to account for precise information depending on Euclidean distance. We also update the activation rules accordingly, resulting in an efficient handling of various types of input noise. To complete this paper, associated hardware architectures are presented along with the proposed computation models and those are compared with the existing CbNN implementation. Synthesis results show that among them, several divide the cost of that implementation by 3 while increasing the maximal frequency by 25%.

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基于聚类神经网络的联想记忆:面向边缘检测的改进模型和体系结构

联想存储器(AM)是一种存储设备，它允许从其中的一部分寻址内容，与传统的基于索引的存储器相反。这种特性使它们成为各种搜索挑战的有希望的候选者，包括图像中的模式检测。基于聚类的神经网络(CbNN)通过提供快速的模式检索，特别是在硬件实现时，允许有效的AM设计。特别是，它们可以用于存储和快速识别图像中的定向边缘。然而，目前的CbNN模型只有在面对输入中的擦除时才能提供良好的性能。本文对CbNN模型进行了改进，以应对入侵噪声和加性噪声。也就是说，我们改变神经元的初始化，根据欧几里得距离来解释精确的信息。我们还相应地更新了激活规则，从而有效地处理各种类型的输入噪声。为了完成本文，给出了相关的硬件架构以及所提出的计算模型，并与现有的CbNN实现进行了比较。综合结果表明，其中有几种方法将实现成本减半，而最大频率提高了25%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 Conference on Design and Architectures for Signal and Image Processing (DASIP)

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