Euclidean distance stratified random sampling based clustering model for big data mining

IF 0.9 Q3 MATHEMATICS, APPLIED Computational and Mathematical Methods Pub Date : 2021-10-15 DOI:10.1002/cmm4.1206
Kamlesh Kumar Pandey, Diwakar Shukla
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引用次数: 3

Abstract

Big data mining is related to large-scale data analysis and faces computational cost-related challenges due to the exponential growth of digital technologies. Classical data mining algorithms suffer from computational deficiency, memory utilization, resource optimization, scale-up, and speed-up related challenges in big data mining. Sampling is one of the most effective data reduction techniques that reduces the computational cost, improves scalability and computational speed with high efficiency for any data mining algorithm in single and multiple machine execution environments. This study suggested a Euclidean distance-based stratum method for stratum creation and a stratified random sampling-based big data mining model using the K-Means clustering (SSK-Means) algorithm in a single machine execution environment. The performance of the SSK-Means algorithm has achieved better cluster quality, speed-up, scale-up, and memory utilization against the random sampling-based K-Means and classical K-Means algorithms using silhouette coefficient, Davies Bouldin index, Calinski Harabasz index, execution time, and speedup ratio internal measures.

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基于欧氏距离分层随机抽样的大数据挖掘聚类模型
大数据挖掘涉及大规模数据分析,由于数字技术的指数级增长,大数据挖掘面临着与计算成本相关的挑战。在大数据挖掘中,传统的数据挖掘算法面临着计算量不足、内存占用、资源优化、规模化、提速等方面的挑战。采样是最有效的数据约简技术之一,对于任何数据挖掘算法在单机和多机执行环境下都能有效地降低计算成本,提高可扩展性和计算速度。本研究提出了一种基于欧几里得距离的地层创建方法和一种基于分层随机抽样的大数据挖掘模型,该模型在单机执行环境下使用K-Means聚类(SSK-Means)算法。采用轮廓系数、Davies Bouldin指数、Calinski Harabasz指数、执行时间和加速比等内部度量指标,与基于随机抽样的K-Means和经典K-Means算法相比,SSK-Means算法在聚类质量、加速、扩展和内存利用率方面取得了更好的性能。
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