Data validation and missing data reconstruction using self-organizing map for water treatment

Lamrini, B, Lakhal, E K; Wehenkel, Louis

doi:10.1007/s00521-011-0526-5

Download

Article (Scientific journals)

Data validation and missing data reconstruction using self-organizing map for water treatment

Lamrini, B, Lakhal, E K; Wehenkel, Louis

2011 • In Neural Computing and Applications, 20 (4), p. 575-588

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/135925

DOI
10.1007/s00521-011-0526-5

Files (1)Send to Details Statistics Bibliography Similar publications

Files

Full Text

Data validation and missing data reconstruction using.pdf

Publisher postprint (776.99 kB)

Download

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Keywords :

Neural networks; Water treatment

Abstract :

[en] Applications in the water treatment domain generally rely on complex sensors located at remote sites. The processing of the corresponding measurements for generating higher-level information such as optimization of coagulation dosing must therefore account for possible sensor failures and imperfect input data. In this paper, selforganizing map (SOM)-based methods are applied to multiparameter data validation and missing data reconstruction in a drinking water treatment. The SOM is a special kind of artificial neural networks that can be used for analysis and visualization of large high-dimensional data sets. It performs both in a nonlinear mapping from a high-dimensional data space to a low-dimensional space aiming to preserve the most important topological and metric relationships of the original data elements and, thus, inherently clusters the data. Combining the SOM results with those obtained by a fuzzy technique that uses marginal adequacy concept to identify the functional states (normal or abnormal), the SOM performances of validation and reconstruction process are tested successfully on the experimental data stemming from a coagulation process involved in drinking water treatment.

Disciplines :

Computer science

Author, co-author :

Lamrini, B, Lakhal, E K

Wehenkel, Louis ; Université de Liège - ULiège > Dép. d'électric., électron. et informat. (Inst.Montefiore) > Systèmes et modélisation

Language :

English

Title :

Data validation and missing data reconstruction using self-organizing map for water treatment

Publication date :

2011

Journal title :

Neural Computing and Applications

ISSN :

0941-0643

eISSN :

1433-3058

Publisher :

Springer Science & Business Media B.V.

Volume :

Issue :

Pages :

575-588

Peer reviewed :

Peer Reviewed verified by ORBi

Available on ORBi :

since 08 December 2012

Statistics

Number of views

117 (2 by ULiège)

Number of downloads

668 (3 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

OpenAlex citations

Bibliography

Aguilar-Martin J, Balssa M, Lopez De Mantras R (1981) Recursive estimation of partitions: examples of learning and self teaching in RN and IN. Questiio: Quaderns d'Etadisticia, Siestems, Informatica i Investigacio Operativa, ISSN 0210-8054 5(3): 150-172.
Badran F, Thiria S, Main B (1992) Smoothing with topological map. In Proceedings of NeuroNimes92 (neural network & their applications), Nîmes, France, pp 107-115.
Barnett V, Lewis T (1994) Outliers in statistical data (Wiley series in probability & statistics), 3rd edn. Wiley, New York.
Biernacki C, Celeux G, Si Abdallah J-F, Govaert G, Langrognet F (2009) MIXMOD user's guide (MIXture MODelling software: high performance model-based cluster and discriminant analysis). Univ. of Franche-Comté, France. http://www-math. univ-fcomte. fr/mixmod/index. php.
Denning D (1987) An intrusion-detection model. IEEE Trans Softw Eng 13(2): 222-232.
Fuente MJ, Vega P (1999) Neural networks applied to fault detection of a biotechnological process. Eng Appl Artif Intell 12: 569-584.
Gagnon C, Grandjean BPA, Thibault J (1997) Modelling of coagulant dosage in a water treatment plant. Artif Intell Eng 11: 401-404.
Gonzalez F, Dasgupta D (2002) Neuro-immune and self-organizing map approaches to anomaly detection: a comparison. In: Proceedings of the 1st international conference on artificial immune systems, Canterbury, UK, pp 203-211.
Hernandez H, Le Lann M-V (2006) Development of a neural sensor for on-line prediction of coagulant dosage in a potable water treatment plant in the way of its diagnosis. In: Sichman JS et al (eds) IBERAMIA-SBIA 2006, LNAI 4140, pp 249-257.
Kasslin M, Kangas J, Simula O (1992). Process state monitoring using self organizing maps. In: Aleksander I, Taylor J (eds) Artificial neural networks II, vol 2, Amsterdam, Netherlands, North-Holland, pp 1531-1534.
Kempowsky T (2004). Surveillance des procédés à base de méthodes de classification: conception d'un outil d'aide pour la détection et le diagnostic des défaillances. PhD Thesis, LAAS-CNRS, Institut National des Sciences Appliquées (INSA), Toulouse, France.
Kohonen T (1995) Self-organizing maps. Volume 30 of Springer series in information sciences. Springer, Berlin.
Kohonen T, Oja E, Simula O, Visa A, Kangas J (1996) Engineering applications of the self-organizing map. Proc IEEE 84(10): 1358-1384.
Kramer MA (1991) Nonlinear principal component analysis using autoassociative neural networks. AIChE J 37(2): 233-243.
Lamrini B, Benhammou A, Le Lann M-V, Karama A (2005) A neural software sensor for on-line prediction of coagulant dosage: application to a drinking water treatment plant. Trans Inst Meas Control 27(3): 95-213.
Lamrini B, Benhammou A, Le Lann M-V, Lakhal El-K (2005) Detection of functional states by "LAMDA" classification technique: application to a coagulation process in drinking water treatment. Comptes Rendus Physique 6: 1161-1168.
Masschelein WJ (1997) Processus unitaires du traitement de l'eau potable. Tec & Doc Lavoisier (Ed), Paris.
Orantes A, Kempowsky T, Le Lann MV (2006) Classification as an aid tool for the selection of sensors used for fault detection and isolation. Trans Inst Meas Control 28(5): 457-480.
Piera-Carreté N, Desroches P, Aguilar-Martin J (1989). LAMDA: an incremental conceptual clustering system. Technical report No. 89420, LAAS-CNRS, Toulouse, France.
Planchon V (2005) Traitement des valeurs aberrantes: concepts actuels et tendances générales. Biotechnol Agron Soc Environ 9(1): 19-34.
Simula O, Alhoniemi E, Hollmen J, Vesanto J (1996). Monitoring and modelling of complex processes using hierarchical self-organizing maps. In: Proceeding of the IEEE international symposium on circuits and systems (ISCAS'96), vol supplement, pp 73-76.
Stanimirova I, Daszykowski M, Walczak B (2007) Dealing with missing values and outliers in principal component analysis. Talanta 72: 172-178.
Trautmann T (1995) Développement d'un modèle de cartes topologiques auto-organisatrices à architecture dynamique: Application au diagnostic. PhD thesis, Univ. of Compiègne, France.
Trautmann T, Denoeux T (1995) Comparison of dynamic feature map models for environmental monitorin. In: Proceedings of international conference on neural networks (ICNN'95), vol 1, Perth, Australia, pp 73-78.
Valentin N, Denoeux T, Fotoohi F (1999) An hybrid neural network based system for optimization of coagulant dosing in a water treatment plant. In: Proceedings of international joint conference on neural networks (IJCNN'99), Washington.
Vercauteren L, Sieben G, Praet M, Otte G, Vingerhoeds L, Boullart L, Lalliauw L, Roeds H (1990) The classification of brains tumours by a topological map. In: Proceedings of international conference on neural networks (ICNN'90), vol 1, Paris, pp 387-391.
Vesanto J (1999) SOM-based visualisation methods. Intell Data Anal 3: 111-126.
Vesanto J, Alhoniemi E, Himberg J, Kiviluoto K, Parviainen J (1999). Self-organizing map for data mining in MATLAB: the SOM toolbox. Simul News Eur 25-54.
Waissmann-Vilanova J (2000) Building a behavioural model for process supervision: application to a wastewater treatment plant. PhD thesis, LAAS-CNRS, Institut National Polytechnique (INP), Toulouse, France.
Zadeh LA (1978) Fuzzy sets as a basis for a theory of possibility. Fuzzy Sets Syst 1: 3-28.