Feature relevance estimation for vibration-based condition monitoring of an internal combustion engine

TecnoLogicas Pub Date : 2017-05-15 DOI:10.22430/22565337.698
J. A. Hernández-Muriel, A. Álvarez-Meza, J. Echeverry-Correa, A. Orozco-Gutierrez, M. Álvarez-López
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引用次数: 3

Abstract

Condition monitoring of Internal Combustion Engines (ICE) benefits cost-effective operations in the modern industrial sector. Because of this, vibration signals are commonly monitored as part of a non-invasive approach to ICE analysis. However, vibration-based ICE monitoring poses a challenge due to the properties of this kind of signals. They are highly dynamic and non-stationary, let alone the diverse sources involved in the combustion process. In this paper, we propose a feature relevance estimation strategy for vibration-based ICE analysis. Our approach is divided into three main stages: signal decomposition using an Ensemble Empirical Mode Decomposition algorithm, multi-domain parameter estimation from time and frequency representations, and a supervised feature selection based on the Relief-F technique. Accordingly, we decomposed the vibration signals by using self-adaptive analysis to represent nonlinear and non-stationary time series. Afterwards, time and frequency-based parameters were calculated to code complex and/or non-stationary dynamics. Subsequently, we computed a relevance vector index to measure the contribution of each multi-domain feature to the discrimination of different fuel blend estimation/diagnosis categories for ICE. In particular, we worked with an ICE dataset collected from fuel blends under normal and fault scenarios at different engine speeds to test our approach. Our classification results presented nearly 98% of accuracy after using a k-Nearest Neighbors machine. They reveal the way our approach identifies a relevant subset of features for ICE condition monitoring. One of the benefits is the reduced number of parameters.
基于振动的内燃机状态监测特征相关性估计
内燃机(ICE)的状态监测有利于现代工业部门的成本效益操作。因此,振动信号通常作为ICE分析的非侵入性方法的一部分进行监测。然而,由于这类信号的特性,基于振动的ICE监测带来了挑战。它们是高度动态和非平稳的,更不用说燃烧过程中涉及的各种来源了。在本文中,我们提出了一种用于基于振动的ICE分析的特征相关性估计策略。我们的方法分为三个主要阶段:使用集成经验模式分解算法的信号分解,根据时间和频率表示的多域参数估计,以及基于Relief-F技术的监督特征选择。因此,我们通过自适应分析对振动信号进行分解,以表示非线性和非平稳的时间序列。然后,计算基于时间和频率的参数,以对复杂和/或非平稳动力学进行编码。随后,我们计算了一个相关向量指数,以衡量每个多域特征对ICE不同燃料混合估计/诊断类别的区分的贡献。特别是,我们使用了从不同发动机转速下的正常和故障情况下的燃料混合物中收集的ICE数据集来测试我们的方法。在使用k近邻机器后,我们的分类结果显示了近98%的准确率。它们揭示了我们的方法识别ICE状况监测相关特征子集的方式。其中一个好处是减少了参数的数量。
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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30
审稿时长
28 weeks
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