基于饱和内存的动态核心进化聚类算法

Haibin Xie, Peng Li, Zhiyong Ding
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引用次数: 0

摘要

由于在实施 K-means 算法之前需要设定聚类核心的数量,因此在数据不断增加、分布特征不断变化的应用中,这种算法往往会失效。本文提出了一种进化算法 DCC,它可以随着数据的变化动态调整聚类核的数量。DCC 算法使用高斯函数作为每个聚类核的激活函数。每个聚类核都可以根据对输入数据的响应及其内存状态调整其中心向量和覆盖范围,以更好地拟合空间中的样本聚类。DCC 算法模型可以从 0 开始演化,每增加一个新样本后,可以通过竞争学习调整或拆分获胜的动态核心,从而使算法的聚类核心数量始终与现有数据保持较好的适应关系。此外,由于其聚类核心可以拆分,因此可以对密集分布的数据集群进行细分。最后,详细的实验结果表明,基于动态核心法的进化聚类算法 DCC 具有优异的聚类性能和较强的鲁棒性。
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A dynamic core evolutionary clustering algorithm based on saturated memory

Because the number of clustering cores needs to be set before implementing the K-means algorithm, this type of algorithm often fails in applications with increasing data and changing distribution characteristics. This paper proposes an evolutionary algorithm DCC, which can dynamically adjust the number of clustering cores with data change. DCC algorithm uses the Gaussian function as the activation function of each core. Each clustering core can adjust its center vector and coverage based on the response to the input data and its memory state to better fit the sample clusters in the space. The DCC algorithm model can evolve from 0. After each new sample is added, the winning dynamic core can be adjusted or split by competitive learning, so that the number of clustering cores of the algorithm always maintains a better adaptation relationship with the existing data. Furthermore, because its clustering core can split, it can subdivide the densely distributed data clusters. Finally, detailed experimental results show that the evolutionary clustering algorithm DCC based on the dynamic core method has excellent clustering performance and strong robustness.

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