Supervised local and non-local structure preserving projections with application to just-in-time learning for adaptive soft sensor

doi:10.1016/j.cjche.2015.11.012

Chin.J.Chem.Eng. ›› 2015, Vol. 23 ›› Issue (12): 1925-1934.DOI: 10.1016/j.cjche.2015.11.012

Supervised local and non-local structure preserving projections with application to just-in-time learning for adaptive soft sensor

Weiming Shao, Xuemin Tian, PingWang

College of Information and Control Engineering, China University of Petroleum (Huadong), Qingdao 266580, China

Received:2015-05-19 Revised:2015-07-15 Online:2016-01-19 Published:2015-12-28
Contact: Xuemin Tian
Supported by:
Supported by the National Natural Science Foundation of China (61273160) and the Fundamental Research Funds for the Central Universities (14CX06067A, 13CX05021A).

Supervised local and non-local structure preserving projections with application to just-in-time learning for adaptive soft sensor

Weiming Shao, Xuemin Tian, PingWang

College of Information and Control Engineering, China University of Petroleum (Huadong), Qingdao 266580, China

通讯作者: Xuemin Tian
基金资助:
Supported by the National Natural Science Foundation of China (61273160) and the Fundamental Research Funds for the Central Universities (14CX06067A, 13CX05021A).

Abstract

Abstract: In soft sensor field, just-in-time learning (JITL) is an effective approach tomodel nonlinear and time varying processes. However,most similarity criterions in JITL are computed in the input space onlywhile ignoring important output information,whichmay lead to inaccurate construction of relevant sample set. To solve this problem, we propose a novel supervised feature extraction method suitable for the regression problemcalled supervised local and non-local structure preserving projections (SLNSPP), in which both input and output information can be easily and effectively incorporated through a newly defined similarity index. The SLNSPP can not only retain the virtue of locality preserving projections but also prevent faraway points from nearing after projection, which endues SLNSPP with powerful discriminating ability. Such two good properties of SLNSPP are desirable for JITL as they are expected to enhance the accuracy of similar sample selection. Consequently, we present a SLNSPP-JITL framework for developing adaptive soft sensor, including a sparse learning strategy to limit the scale and update the frequency of database. Finally, two case studies are conducted with benchmark datasets to evaluate the performance of the proposed schemes. The results demonstrate the effectiveness of LNSPP and SLNSPP.

Key words: Adaptive soft sensor, Just-in-time learning, Supervised local and non-local structure, preserving projections, Locality preserving projections, Database monitoring

摘要： In soft sensor field, just-in-time learning (JITL) is an effective approach tomodel nonlinear and time varying processes. However,most similarity criterions in JITL are computed in the input space onlywhile ignoring important output information,whichmay lead to inaccurate construction of relevant sample set. To solve this problem, we propose a novel supervised feature extraction method suitable for the regression problemcalled supervised local and non-local structure preserving projections (SLNSPP), in which both input and output information can be easily and effectively incorporated through a newly defined similarity index. The SLNSPP can not only retain the virtue of locality preserving projections but also prevent faraway points from nearing after projection, which endues SLNSPP with powerful discriminating ability. Such two good properties of SLNSPP are desirable for JITL as they are expected to enhance the accuracy of similar sample selection. Consequently, we present a SLNSPP-JITL framework for developing adaptive soft sensor, including a sparse learning strategy to limit the scale and update the frequency of database. Finally, two case studies are conducted with benchmark datasets to evaluate the performance of the proposed schemes. The results demonstrate the effectiveness of LNSPP and SLNSPP.

关键词: Adaptive soft sensor, Just-in-time learning, Supervised local and non-local structure, preserving projections, Locality preserving projections, Database monitoring

Weiming Shao, Xuemin Tian, PingWang. Supervised local and non-local structure preserving projections with application to just-in-time learning for adaptive soft sensor[J]. Chin.J.Chem.Eng., 2015, 23(12): 1925-1934.

References

[1] P. Kadlec, B. Gabrys Bogdan, S. Strandt, Data-driven soft sensors in the process industry, Comput. Chem. Eng. 33 (4) (2009) 795-814.

[2] L. Fortuna, S. Graziani, A. Rizzo, G.M. Xibilia, Soft sensors for monitoring and control of industrial processes, Springer-Verlag, London, 2007.

[3] Y. Liu, Z.L. Gao, P. Li, H.Q. Wang, Just-in-time kernel learning with adaptive parameter selection for soft sensor modeling of batch processes, Ind. Eng. Chem. Res. 51 (11) (2012) 4313-4327.

[4] H.G. Tian, X.M. Tian, X.G. Deng, Soft sensor for polypropylene melt index based on improved orthogonal least squares,World Congress on Intelligent Control and Automation (WCICA), July 6-9, 2010, Jinan, China, 2010.

[5] Z.Q. Ge, Z.H. Song, Semisupervised Bayesian method for soft sensor modeling with unlabeled data samples, AIChE J 57 (8) (2011) 2109-2118.

[6] W.M. Shao, X.M. Tian, P.Wang, Online learning soft sensor method based on recursive kernel algorithm for PLS, CIESC J. 63 (9) (2012) 2887-2891.

[7] A.K. Pani, V.K. Vadlamudi, H.K. Mohanta, Development and comparison of neural network based soft sensors for online estimation of cement clinker quality, ISA Trans. 52 (1) (2013) 19-29.

[8] H. Kaneko, K. Funatsu, Application of online support vector regression for soft sensors, AIChE J 60 (2) (2014) 600-612.

[9] S.N. Zhang, F.L. Wang, D.K. He, R.D. Jia, Real-time product quality control for batch processes based on stacked least-squares support vector regressionmodels, Comput. Chem. Eng. 36 (10) (2012) 217-226.

[10] J. Tang, T.Y. Chai,W. Yu, L.J. Zhao, On-line KPLS algorithm with application to ensemble modeling parameters of mill load, 39 (5) (2013) 471-486.

[11] P. Kadlec, R. Grbi?, B. Gabrys, Review of adaptation mechanism for data-driven soft sensors, Comput. Chem. Eng. 35 (1) (2011) 1-24.

[12] H. Kaneko, K. Funatsu, Classification of the degradation of soft sensor models and discussion on adaptive models, AIChE J 59 (7) (2013) 2239-2347.

[13] W.M. Shao, X.M. Tian, H.L. Chen, Adaptive anti-over-fitting soft sensing method based on local learning, Preprints of the 10th IFAC International Symposium on Dynamics and Control of Process Systems, December 18-20, 2013. Mumbai, India, 2013.

[14] K. Chen, J. Ji, H.Q. Wang, Z.H. Song, Adaptive local kernel-based learning for soft sensormodeling of nonlinear processes, Chem. Eng. Res. Des. 89 (10) (2011) 2117-2124.

[15] Y. Liu, Z.L. Gao, J.H. Chen, Development of soft sensors for online quality prediction of sequential-reactor-multi-grade industrial processes, Chem. Eng. Sci. 102 (11) (2013) 602-612.

[16] J.P. Zhang, Y.S. Yim, J.M. Yang, Intelligent selection of instances for prediction functions in lazy learning algorithms, Artif. Intell. Rev. 11 (1-5) (1997) 175-191.

[17] Q.B. Zheng, H. Kimura, Just-in-timemodeling for function prediction and its applications, Asian J. Control 3 (1) (2001) 35-44.

[18] M.R. Gupta, E.K. Garcia, E. Chin, Adaptive local linear regression with application to printer color management, IEEE Trans. Image Process. 17 (6) (2008) 936-945.

[19] C. Cheng,M.S. Chiu, A newdata-basedmethodology for nonlinear processmodeling, Chem. Eng. Sci. 59 (13) (2004) 2801-2810.

[20] Y.Q. Liu, D.P. Huang, Y. Li, Development of interval soft sensors using enhanced justin- time learning and inductive confidence predictor, Ind. Eng. Chem. Res. 51 (8) (2012) 3356-3367.

[21] K. Fujiwara, M. Kano, S. Hasebe, Development of correlation-based pattern recognition algorithm and adaptive soft-sensor design, Control. Eng. Pract. 20 (4) (2012) 371-378.

[22] K. Fujiwara, M. Kano, S. Hasebe, A. Takinami, Soft-sensor development using correlation-based just-in-time modeling, AIChE J 55 (7) (2009) 1754-1764.

[23] J. Yang, D. Zhang, J.Y. Yang, B. Niu, Globally maximizing, locally minimizing: Unsupervised discriminant projection with applications to face and palm biometrics, IEEE Trans. Pattern Anal. Mach. Intell. 29 (4) (2007) 650-664.

[24] X.F. He, P. Niyogi, Locality preserving projections, Neural Inform. Process. Syst. 16 (2003) 153-160.

[25] J. Yang, D. Zhang, J.Y. Yang, ‘Non-locality’ preserving projection and its application to palm print recognition, 9th International Conference on Control, Automation, Robotics, and Vision, Dec. 5-8, 2006, Singapore, 2006.

[26] M.G. Zhang, Z.Q. Ge, Z.H. Song, R.W. Fu, Global-local structure analysismodel and its application for fault detection and identification, Ind. Eng. Chem. Res. 50 (2011) 6837-6848.

[27] Y. Kansha, M.S. Chiu, Adaptive generalized predictive control based on JITL technique, J. Process Control 19 (7) (2009) 1067-1072.

[28] G.C. Cawley, N.L.C. Talbot, Preventing over-fitting during model selection via Bayesian regularisation of the hyper-parameters, J. Mach. Learn. Res. 8 (2007) 841-861.

[29] H.J. Galicia, Q.P. He, J. Wang, Adaptive outlier detection and classification for online soft sensor update, Preprints of the 8th IFAC Symposium on Advanced Control of Chemical Processes The International Federation of Automatic Control, Furama Riverfront, Singapore, July 10-13 2012, pp. 402-407.

[30] H. Kaneko, K. Funatsu, Classification of the degradation of soft sensor models and discussion on adaptive models, AIChE J 59 (7) (2013) 2339-2347.

[31] T.H. Zhang, J. Yang, D.L. Zhao, X.L. Ge, Linear local tangent space alignment and application to face recognition, Neurocomputing 70 (7) (2007) 1547-1553.

[32] J.A.K. Suykens, T.V. Gestel, J.D. Brabanter, B.D. Moor, J. Vandewalle, Least squares support vector machines, World Scientific, Singapore, 2002.

[33] J.A.K. Suykens, J.D. Brabanter, L. Lukas, J. Vandewalle, Weighted least squares support vector machines: Robustness and sparse approximation, Neurocomputing 48 (1) (2002) 85-105.

[34] Y. Liu, H.Q. Wang, J. Yu, P. Li, Selective recursive kernel learning for online identification of nonlinear systems with NARX form, J. Process Control 20 (2) (2009) 181-194.

[35] H. Kaneko, K. Funatsu, Database monitoring index for adaptive soft sensors and the application to industrial process, AIChE J 60 (1) (2014) 160-169.

Supervised local and non-local structure preserving projections with application to just-in-time learning for adaptive soft sensor

Supervised local and non-local structure preserving projections with application to just-in-time learning for adaptive soft sensor

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 1

Recommended Articles

Metrics

Comments