Research and application of FLANN neural network based on AHP

doi:10.11949/j.issn.0438-1157.20151911

CIESC Journal ›› 2016, Vol. 67 ›› Issue (3): 805-811.DOI: 10.11949/j.issn.0438-1157.20151911

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Research and application of FLANN neural network based on AHP

GENG Zhiqiang^1,2, WU Kaiying^1,2, HAN Yongming^1,2

1. College of Information Science and Technology, Beijing University of Chemical Technology, Beijing 100029, China;
2. Engineering Research Center of Intelligent PSE, Ministry of Education in China, Beijing 100029, China

Received:2015-12-15 Revised:2015-12-21 Online:2016-01-12 Published:2016-03-05
Contact: 67
Supported by:
supported by the National Natural Science Foundation of China (61374166, 61533003), the Specialized Research Fund for the Doctoral Program of Higher Education of China (20120010110010), and the Fundamental Research Funds for the Central Universities (YS1404, JD1502).

基于层次分析的FLANN神经网络研究及应用

耿志强^1,2, 武开英^1,2, 韩永明^1,2

1. 北京化工大学信息科学与技术学院, 北京 100029;
2. 智能过程系统工程教育部工程研究中心, 北京 100029

通讯作者: 韩永明
基金资助:
国家自然科学基金项目(61374166,61533003);高等学校博士学科点专项科研基金(20120010110010);中央高校基本科研业务费(YS1404,JD1502)。

Abstract

Abstract:

The traditional functional link artificial neural network (FLANN) is inefficient in the high-dimensional data modeling of the chemical process, where the data has characteristics of multi-dimensional, strongly coupled and noisy. In order to dealing with this problem, the FLANN based on analytical hierarchy process (AHP-FLANN) is proposed. The analytical hierarchy process (AHP) is constructed to filter redundant information and extract characteristic components. And then these characteristic components are trained by the FLANN. Meanwhile, the proposed AHP-FLANN method is applied to analyze the ethylene production data in the chemical industry. Compared with the BP network and the FLANN, the AHP-FLANN has the advantages of fast convergence speed with high modeling accuracy and strong network stability. The experimental result shows that the proposed method can guide the ethylene production conditions and improve the efficiency of energy utilization during ethylene production process. It has the practical value in practice.

Key words: ethylene plant, production capacity forecast, analytic hierarchy process, neural networks, model-predictive control, production

摘要：

针对传统函数链接型神经网络(functional link artificial neural networks,FLANN)不能有效处理化工过程中强耦合、带噪声的高维数据建模问题,提出了一种基于层次分析(analytic hierarchy process, AHP)的FLANN神经网络(AHP-FLANN)。通过层析分析模型过滤输入数据中的冗余信息,提取特征分量,并把提取的特征分量作为函数链接神经网络的输入进行建模。同时利用化工行业乙烯生产数据进行了验证,并和BP神经网络及FLANN神经网络进行了对比。结果表明,AHP-FLANN神经网络在处理复杂高维数据时具有收敛速度快、建模精度高、网络稳定性强等特点,同时能够指导乙烯生产,提高能效,具有良好的实用价值。

关键词: 乙烯装置, 生产能力预测, 层次分析法, 神经网络, 模型预测控制, 生产

CLC Number:

TP29

GENG Zhiqiang, WU Kaiying, HAN Yongming. Research and application of FLANN neural network based on AHP[J]. CIESC Journal, 2016, 67(3): 805-811.

耿志强, 武开英, 韩永明. 基于层次分析的FLANN神经网络研究及应用[J]. 化工学报, 2016, 67(3): 805-811.

References 22

[1]	张绍兵, 季厌浮, 高志军. 基于神经网络专家系统的研究与实现[J]. 计算机工程与科学, 2008, (4): 156-158. Zhang S B, Ji Y F, Gao Z J. Research and implementation of an expert system based on neural networks[J]. Computer Engineering and Science, 2008, (4): 156-158.
[2]	杨国军, 崔平远, 李琳琳. 遗传算法在神经网络控制中的应用与实现[J]. 系统仿真学报, 2001, (5): 567-570. Yang G J, Cui P Y, Li L L. Applying and realizing of genetic algorithm in neural networks control[J]. Journal of System Simulation, 2001, (5): 567-570.
[3]	严宇, 刘天琪. 基于神经网络和模糊理论的电力系统动态安全评估[J]. 四川大学学报(工程科学版), 2004, (1): 106-110. Yan Y, Liu T Q. Dynamic security assessment of power system based on ann and fuzzy theory[J]. Journal of Sichuan University (Engineering Science Edition), 2004, (1): 106-110.
[4]	Ding S F, Su C Y, Yu J Z. An optimizing BP neural network algorithm based on genetic algorithm[J]. Artificial Intelligence Review, 2011, 36(2): 153-162.
[5]	Moallem P, Monadjemi S A. An efficient MLP-learning algorithm using parallel tangent gradient and improved adaptive learning rates[J]. Connection Science, 2010, 22(4): 373-392.
[6]	徐科军, 殷铭.基于FLANN的腕力传感器动态建模方法[J]. 仪器仪表学报, 2000, 21(1): 92-94. Xu K J, Yin M. A dynamic modeling method based on FLANN for wrist force sensor[J]. Chinese Journal of Scientific Instrument, 2000, 21(1): 92-94.
[7]	Mishra S K, Panda G, Meher S, et al. Exponential functional link artificial neural networks for denoising of image corrupted by Gaussian noise[C]//Proceedings of the 2009 International Conference on Advanced Computer Control. Washington, DC, USA: IEEE Computer Society, 2009: 355-359.
[8]	Majhi R, Panda G, Sahoo G. Development and performance evaluation of FLANN based model for forecasting of stock markets[J]. Expert Systems with Applications: An International Journal, 2009, 36(3): 6800-6808.
[9]	Huang S L, Hao K S, Zhao W. New improved FLANN approach for dynamic modelling of sensors[J]. International Journal of Computer Applications in Technology, 2011, 41(1/2): 4-10.
[10]	Lee J M, Yoo C K, Choi S W, et al. Nonlinear process monitoring using kernal principal component analysis[J]. Chem. Eng. Sci., 2004, 59(1): 223-234.
[11]	Geng Z Q, Zhu Q X. Multiscale nonlinear principal component analysis(NLPCA) and its application for chemical process monitoring[J]. Ind. Eng. Chem. Res., 2005, 44(10): 3585-3593.
[12]	Pascoe S, Bustamante R, Wilcox C, et al. Spatial fisheries management: a framework for multi-objective qualitative assessment[J]. Ocean & Coastal Management, 2009, 52(2): 130-138.
[13]	孙才志, 林学钰. 基于层次分析的模糊一致性判断矩阵及其应用[J]. 模糊系统与数学, 2002, 16(3): 59-63. Sun C Z, Lin X Y. Fuzzy consistent matrix based on AHP and its application[J]. Fuzzy Systems and Mathematics, 2002, 16(3): 59-63.
[14]	魏翠萍. 层次分析法中和积法的最优化理论基础及性质[J].系统工程理论与实践, 1999, 9: 113-115 WEI C P. The optimization basis and properties of the sum-product method in AHP[J]. Systems Engineering-Theory & Practice, 1999, 9: 113-115.
[15]	演克武,朱金福,何涛.层次分析法在多目标决策过程中的不足与改进[J]. 统计与决策, 2007, 5: 10-11. Yan K W, Zhu J F, He T. Inadequate and improved multi-objective decision-making process in AHP[J]. Statistics and Decision, 2007, 5: 10-11.
[16]	Pao Y H, Philips S M, Sobajic D J. Neural-net computing and intelligent control systems[J]. International Journal of Control, 1992, 56(2): 263-289.
[17]	叶世伟, 史忠植. 神经网络原理[M].北京: 机械工业出版社, 2004: 10-12. Ye S W, Shi Z Z. Neural Networks:A Comprehensive Foundation[M]. Beijing: China Machine Press, 2004: 10-12.
[18]	Han Y M, Geng Z Q, Liu Q Y. Energy efficiency evaluation based on data envelopment analysis integrated analytic hierarchy process in ethylene production[J]. Chinese Journal of Chemical Engineering, 2014, 22(12): 1279-1284.
[19]	耿志强, 朱群雄, 顾祥柏.基于关联层次模型的乙烯装置能效虚拟对标及应用[J].化工学报, 2011, 62(8): 2372-2377. Geng Z Q, Zhu Q X, Gu X B. Dependent function analytic hierarchy process model for energy efficiency virtual benchmark and its applications in ethylene equipments[J]. CIESC Journal, 2011, 62(8): 2372-2377.
[20]	Geng Z Q, Han Y M, Yu C P. Energy efficiency evaluation of ethylene product system based on density clustering data envelopment analysis model[J]. Advanced Science Letters, 2012, 5: 1-7.
[21]	王学雷. 面向乙烯生产流程的能源消耗动态定标方法[J].计算机与应用化学, 2010, 27(9): 1166-1170. Wang X L. A dynamic benchmarking method for energy consumption of ethylene production process[J]. Computers and Applied Chermistry, 2010, 27(9): 1166-1170.
[22]	Geng Z Q, Han Y M, Gu X B, et al. Energy efficiency estimation based on data fusion strategy: case study of ethylene product industry[J]. Industrial & Engineering Chemistry Research, 2012, 51: 8526-8534.

Research and application of FLANN neural network based on AHP

基于层次分析的FLANN神经网络研究及应用

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