[1]刘小雍,叶振环.l 1-l 1双范数的最优下边界回归模型辨识[J].智能系统学报,2020,15(5):934-942.[doi:10.11992/tis.201902006]
 LIU Xiaoyong,YE Zhenhuan.Optimal lower boundary regression model based on double norms l 1-l 1 optimization[J].CAAI Transactions on Intelligent Systems,2020,15(5):934-942.[doi:10.11992/tis.201902006]
点击复制

l 1-l 1双范数的最优下边界回归模型辨识

《智能系统学报》[ISSN 1673-4785/CN 23-1538/TP] 卷: 15 期数: 2020年第5期 页码: 934-942 栏目: 学术论文—机器感知与模式识别 出版日期: 2020-09-05
Title:
Optimal lower boundary regression model based on double norms l 1-l 1 optimization
作者:
刘小雍, 叶振环
遵义师范学院 工学院,贵州 遵义 563006
Author(s):
LIU Xiaoyong, YE Zhenhuan
College of Engineering, Zunyi Normal University, Zunyi 563006, China
关键词:
${\ell _1}$范数的结构风险最小化逼近误差的${\ell _1}$范数下边界回归模型泛化性能建模精度最优性线性规划
Keywords:
${\ell _1}$-norm-based structural risk minimization${\ell _1}$-norm on approximation errorlower boundary regression modelgeneralization performancemodeling accuracyoptimalitylinear programming
分类号:
TP391.1
DOI:
10.11992/tis.201902006
文献标志码:
A
摘要:
考虑到来自传感器测量数据、模型结构以及参数的不确定性等因素,建模由这些因素导致的下边界模型尤为重要。通过将结构风险最小化理论与逼近误差最小化思想相结合,提出了${\ell _1} - {\ell _1}$ 双范数的最优下边界回归模型建模方法。首先,确定满足下边界回归模型的约束条件。其次,将结构风险的${\ell _2}$范数转化为简单的${\ell _1}$范数优化问题,并将回归模型与实际测量数据之间的逼近误差的${\ell _1}$范数融合到结构风险的${\ell _1}$范数优化问题,再应用较简单的线性规划对双范数的优化问题进行求解获取模型参数。最后,通过来自测量数据以及模型参数不确定性的实验分析,论证了提出方法的最优性,体现在:下边界模型的建模精度通过逼近误差的${\ell _1}$范数得到保证;模型结构复杂性在结构风险的${\ell _1}$范数优化条件下得到有效控制,进而提高其泛化性能。
Abstract:
In statistical modeling, regression analysis is a set of statistical processes for estimating the relationships between a dependent variable and one or more independent variables. Considering the uncertainties in the structure and parameters of the model derived from sensor measurement data, a new model called optimal lower boundary model is proposed to remove the uncertainties in parameters and characteristics. The proposed method is a combination of structural risk minimization theory (SRM) and some ideas from approximation error minimization. An optimal lower boundary regression model (LBRM) is presented using ${\ell _1} - {\ell _1}$ double norms optimization. First, constraint conditions subjected to LBRM are defined. Then, ${\ell _2}$-norm optimization based on structural risk is converted into simple ${\ell _1}$-norm optimization so that approximation error between the measurements based on ${\ell _1}$-norm is computed and minimized. Next, LBRM is integrated into ${\ell _1}$-norm optimization (based on structural risk). Thus, simpler linear programming can be applied to the constructed double-norms optimization problem to solve parameters of LBRM. Finally, the proposed method is demonstrated by experiments regarding uncertain measurements and parameters of nonlinear system. It has the following prominent features: modeling accuracy of LBRM can be guaranteed by introducing the ${\ell _1}$-norm minimization on approximation error; model’s structural complexity is under control by ${\ell _1}$-norm optimization based on structural risk, thus the performance of the model can be improved further.
参考文献/References:
[1] HAN Honggui, GUO Yanan, QIAO Junfei. Nonlinear system modeling using a self-organizing recurrent radial basis function neural network[J]. Applied soft computing, 2018, 71: 1105-1116.
[2] FRAVOLINI M L, NAPOLITANO M R, DEL CORE G, et al. Experimental interval models for the robust fault detection of aircraft air data sensors[J]. Control engineering practice, 2018, 78: 196-212.
[3] FANG Shengen, ZHANG Qiuhu, REN Weixin. An interval model updating strategy using interval response surface models[J]. Mechanical systems and signal processing, 2015, 60-61: 909-927.
[4] LEUNG F H F, LAM H K, LING S H, et al. Tuning of the structure and parameters of a neural network using an improved genetic algorithm[J]. IEEE transactions on neural networks, 2003, 14(1): 79-88.
[5] 赵文清, 严海, 王晓辉. BP神经网络和支持向量机相结合的电容器介损角辨识[J]. 智能系统学报, 2019, 14(1): 134-140
ZHAO Wenqing, YAN Hai, WANG Xiaohui. Capacitor dielectric loss angle identification based on a BP neural network and SVM[J]. CAAI transactions on intelligent systems, 2019, 14(1): 134-140
[6] 刘道华, 张礼涛, 曾召霞, 等. 基于正交最小二乘法的径向基神经网络模型[J]. 信阳师范学院学报(自然科学版), 2013, 26(3): 428-431
LIU Daohua, ZHANG Litao, ZENG Zhaoxia, et al. Radial basis function neural network model based on orthogonal least squares[J]. Journal of Xinyang Normal University (natural science edition), 2013, 26(3): 428-431
[7] 刘道华, 张飞, 张言言. 一种改进的RBF神经网络对县级政府编制预测[J]. 信阳师范学院学报(自然科学版), 2016, 29(2): 265-269
LIU Daohua, ZHANG Fei, ZHANG Yanyan. A prediction for the preparation of county government based on improved RBF neural networks[J]. Journal of Xinyang Normal University (natural science edition), 2016, 29(2): 265-269
[8] HAN Honggui, GE Luming, QIAO Junfei. An adaptive second order fuzzy neural network for nonlinear system modeling[J]. Neurocomputing, 2016, 2014: 837-847.
[9] LI Fanjun, QIAO Junfei, HAN Honggui, et al. A self-organizing cascade neural network with random weights for nonlinear system modeling[J]. Applied soft computing, 2016, 42: 184-193.
[10] HAN Honggui, QIAO Junfei. Hierarchical neural network modeling approach to predict sludge volume index of wastewater treatment process[J]. IEEE transactions on control systems technology, 2013, 21(6): 2423-2431.
[11] VAPNIK V N. An overview of statistical learning theory[J]. IEEE transactions on neural networks, 1999, 10(5): 988-999.
[12] 唐波, 彭友仙, 陈彬, 等. 基于BP神经网络的交流输电线路可听噪声预测模型[J]. 信阳师范学院学报(自然科学版), 2015, 28(1): 136-140
TANG Bo, PENG Youxian, CHEN Bin, et al. Audible noise prediction model of ac power lines based on BP neural network[J]. Journal of Xinyang Normal University (natural science edition), 2015, 28(1): 136-140
[13] HAO Peiyi. Interval regression analysis using support vector networks[J]. Fuzzy sets and systems, 2009, 160(17): 2466-2485.
[14] HAO Peiyi. Possibilistic regression analysis by support vector machine[C]//Proceedings of 2011 IEEE International Conference on Fuzzy Systems. Taipei, China, 2011: 889-894.
[15] 石磊, 侯丽萍. 基于改进PSO算法参数优化的模糊支持向量分类机[J]. 信阳师范学院学报(自然科学版), 2013, 26(2): 288-291
SHI Lei, HOU Liping. Parameter optimization of fuzzy support vector classifiers based on the improved PSO[J]. Journal of Xinyang Normal University (natural science edition), 2013, 26(2): 288-291
[16] SOUZA L C, SOUZA R M C R, AMARAL G J A, et al. A parametrized approach for linear regression of interval data[J]. Knowledge-based systems, 2017, 131: 149-159.
[17] DE A LIMA NETO E, DE A T DE CARVALHO F. An exponential-type kernel robust regression model for interval-valued variables[J]. Information sciences, 2018, 454-455: 419-442.
[18] BASAK D, PAL S, PATRANABIS D C. Support vector regression[J]. Neural information processing-letters and reviews, 2007, 11(10): 203-224.
[19] SMOLA A J, SCH?LKOPF B. A tutorial on support vector regression[J]. Statistics and computing, 2004, 14(3): 199-222.
[20] SOARES Y M G, FAGUNDES R A A. Interval quantile regression models based on swarm intelligence[J]. Applied soft computing, 2018, 72: 474-485.
[21] LU Zhao, SUN Jing, BUTTS K. Linear programming SVM-ARMA2K with application in engine system identification[J]. IEEE transactions on automation science and engineering, 2011, 8(4): 846-854.
[22] RIVAS-PEREA P, COTA-RUIZ J. An algorithm for training a large scale support vector machine for regression based on linear programming and decomposition methods[J]. Pattern recognition letters, 2013, 34(4): 439-451.
[23] HSU C W, CHANG C C, LIN C J. A practical guide to support vector classification. Technical report. Department of Computer Science, National Taiwan University (2003)[EB/OL](2010-4-15). http://www.csie.ntu.edu.tw/~cjlin/papers/guide/guide.pdf.

备注/Memo

收稿日期:2019-02-08。
基金项目:贵州省科技计划基金项目(黔科合基础[2018]1179);遵义师范学院博士项目(遵师BS[2015]04号).
作者简介:刘小雍,副教授,博士,主要研究方向为机器学习与人工智能。发表学术论文10余篇;叶振环,教授,博士,主要研究方向为动态系统故障诊断与容错控制、状态估计。发表学术论文20余篇
通讯作者:刘小雍.E-mail:liuxy204@163.com

更新日期/Last Update: 2021-01-15
Copyright © 《 智能系统学报》 编辑部
地址:(150001)黑龙江省哈尔滨市南岗区南通大街145-1号楼 电话:0451- 82534001、82518134 邮箱:tis@vip.sina.com