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基于RUL和SVs-GFF的云服务器老化预测方法

孟海宁 童新宇 谢国 张贝贝 黑新宏

孟海宁, 童新宇, 谢国, 张贝贝, 黑新宏. 基于RUL和SVs-GFF的云服务器老化预测方法. 自动化学报, 2024, 50(10): 2036−2048 doi: 10.16383/j.aas.c211112
引用本文: 孟海宁, 童新宇, 谢国, 张贝贝, 黑新宏. 基于RUL和SVs-GFF的云服务器老化预测方法. 自动化学报, 2024, 50(10): 2036−2048 doi: 10.16383/j.aas.c211112
Meng Hai-Ning, Tong Xin-Yu, Xie Guo, Zhang Bei-Bei, Hei Xin-Hong. Cloud server aging prediction method based on RUL and SVs-GFF. Acta Automatica Sinica, 2024, 50(10): 2036−2048 doi: 10.16383/j.aas.c211112
Citation: Meng Hai-Ning, Tong Xin-Yu, Xie Guo, Zhang Bei-Bei, Hei Xin-Hong. Cloud server aging prediction method based on RUL and SVs-GFF. Acta Automatica Sinica, 2024, 50(10): 2036−2048 doi: 10.16383/j.aas.c211112

基于RUL和SVs-GFF的云服务器老化预测方法

doi: 10.16383/j.aas.c211112
基金项目: 国家自然科学基金(61602375, 61773313), 陕西省自然科学基础研究计划基金(2019JQ-749)资助
详细信息
    作者简介:

    孟海宁:西安理工大学计算机科学与工程学院副教授. 主要研究方向为机器学习, 故障诊断与预测. 本文通信作者. E-mail: hnmeng@xaut.edu.cn

    童新宇:西安理工大学计算机科学与工程学院博士研究生. 主要研究方向为机器学习, 时间序列预测. E-mail: tongxinyu@stu.xaut.edu.cn

    谢国:西安理工大学教授. 主要研究方向为数据分析, 故障诊断. E-mail: guoxie@xaut.edu.cn

    张贝贝:西安理工大学计算机科学与工程学院讲师. 主要研究方向为数据挖掘, 大数据技术. E-mail: bbzhang115@hotmail.com

    黑新宏:西安理工大学计算机科学与工程学院教授. 主要研究方向为机器学习, 系统安全. E-mail: heixinhong@xaut.edu.cn

Cloud Server Aging Prediction Method Based on RUL and SVs-GFF

Funds: Supported by National Natural Science Foundation of China (61602375, 61773313) and Natural Science Basic Research Plan of Shaanxi Province (2019JQ-749)
More Information
    Author Bio:

    MENG Hai-Ning Associate professor at the School of Computer Science and Engineering, Xi'an University of Technology. Her research interest covers machine learning and fault prognosis & prediction. Corresponding author of this paper

    TONG Xin-Yu Ph.D. candidate at the School of Computer Science and Engineering, Xi'an University of Technology. His research interest covers machine learning and time series prediction

    XIE Guo Professor at Xi'an University of Technology. His research interest covers data analysis and fault diagnosis

    ZHANG Bei-Bei Lecturer at the School of Computer Science and Engineering, Xi'an University of Technology. His research interest covers data mining and big data technology

    HEI Xin-Hong Professor at the School of Computer Science and Engineering, Xi'an University of Technology. His research interest covers machine learning and system security

  • 摘要: 针对云服务器中存在软件老化现象, 将造成系统性能衰退与可靠性下降问题, 借鉴剩余使用寿命(Remaining useful life, RUL)概念, 提出基于支持向量和高斯函数拟合(Support vectors and Gaussian function fitting, SVs-GFF)的老化预测方法. 首先, 提取云服务器老化数据的统计特征指标, 并采用支持向量回归(Support vector regression, SVR)对统计特征指标进行数据稀疏化处理, 得到支持向量(Support vectors, SVs)序列数据; 然后, 建立基于密度聚类的高斯函数拟合(Gaussian function fitting, GFF)模型, 对不同核函数下的支持向量序列数据进行老化曲线拟合, 并采用Fréchet距离优化算法选取最优老化曲线; 最后, 基于最优老化曲线, 评估系统到达老化阈值前的RUL, 以预测系统何时发生老化. 在OpenStack云服务器4个老化数据集上的实验结果表明, 基于RUL和SVs-GFF的云服务器老化预测方法与传统预测方法相比, 具有更高的预测精度和更快的收敛速度.
  • 图  1  云服务器老化现象

    Fig.  1  Software aging phenomenon in a cloud server

    图  2  基于SVs-GFF的云服务器老化预测方法框图

    Fig.  2  Block diagram of cloud server aging prediction method based on SVs-GFF

    图  3  支持向量的空间分布

    Fig.  3  Spatial distribution of support vectors

    图  4  实验平台

    Fig.  4  Test bed

    图  5  OpenStack云服务器原始数据

    Fig.  5  Original data of OpenStack cloud server

    图  6  原始数据的统计特征指标

    Fig.  6  Statistical characteristic index of origin data

    图  7  基于Fréchet距离选取最优老化曲线

    Fig.  7  Select the optimal aging curve via the Fréchet distance

    图  8  老化曲线拟合对比

    Fig.  8  Comparison of aging curve fitting

    图  9  云服务器老化预测结果

    Fig.  9  Cloud server aging prediction results

    图  10  云服务器RUL预测结果

    Fig.  10  Cloud server RUL prediction results

    图  11  云服务器RUL预测绝对误差

    Fig.  11  Absolute error of cloud server RUL prediction results

    图  12  云服务器老化预测结果

    Fig.  12  Cloud server aging prediction results

    图  13  云服务器RUL预测结果

    Fig.  13  Cloud server RUL prediction results

    图  14  云服务器RUL预测绝对误差

    Fig.  14  Absolute error of cloud server RUL prediction results

    表  1  老化曲线拟合RMSE对比 (%)

    Table  1  Comparison of aging curve fitting RMSE (%)

    拟合方法 响应时间集 页面传输速度集
    基于密度聚类的GFF 21.598 47.129
    SVR 57.334 114.239
    下载: 导出CSV

    表  2  不同预测方法的参数设置

    Table  2  Parameter setting of different prediction methods

    预测方法 参数设置
    SVs-GFF 高斯函数中$\alpha$、$\beta$、$\sigma$和$\gamma$的初始值: 0, 寻优方法: 最小二乘法, SVR中正则化参数: 1.0, 距离阈值$\varepsilon$: 0.5
    SVR 正则化参数: 1, 核函数: RBF
    GFF 高斯函数中$\alpha$、$\beta$、$\sigma$和$\gamma$的初始值: 0, 寻优方法: 最小二乘法
    PF 基于PF模型更新指数模型参数, 老化特征值$\alpha$: 1.979, 指数模型参数$b$: 0.00271, $c$: −0.1697, 白噪声标准差$d$: −0.06942
    ANN 神经元数: [输入层: 30, 隐藏层1: 64, 隐藏层2: 64, 隐藏层3: 32, 输出层: 1 ], 激活函数: ReLU, 迭代次数: 100
    LSTM 神经元数: [输入层: 10, 隐藏层1: 32, 隐藏层2: 32, 隐藏层3: 16, 输出层: 1 ], 激活函数: ReLU, 迭代次数: 100
    Markov 基于Markov模型更新指数模型参数, 指数模型参数的初始值: 0
    下载: 导出CSV

    表  3  预测性能比较

    Table  3  Comparison of prediction performances

    数据集名称 评价指标 SVs-GFF GFF SVR PF ANN LSTM Markov
    响应时间数据集 ${\rm{CRA}}$ 0.904 0.769 0.891 0.841 0.737 0.901 0.858
    $C_{PE}$ 15.117 15.896 16.035 15.369 18.353 19.360 15.371
    页面传输速度数据集 ${\rm{CRA}}$ 0.8790.6980.8610.8010.7210.7920.813
    $C_{PE}$16.48716.94516.98717.89719.54720.48717.881
    下载: 导出CSV
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  • 收稿日期:  2021-11-24
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