Authors: O. Hassanein, Sreenatha G. Anavatti, Tapabrata Ray

Abstract:

The dynamics of the Autonomous Underwater Vehicles (AUVs) are highly nonlinear and time varying and the hydrodynamic coefficients of vehicles are difficult to estimate accurately because of the variations of these coefficients with different navigation conditions and external disturbances. This study presents the on-line system identification of AUV dynamics to obtain the coupled nonlinear dynamic model of AUV as a black box. This black box has an input-output relationship based upon on-line adaptive fuzzy model and adaptive neural fuzzy network (ANFN) model techniques to overcome the uncertain external disturbance and the difficulties of modelling the hydrodynamic forces of the AUVs instead of using the mathematical model with hydrodynamic parameters estimation. The models- parameters are adapted according to the back propagation algorithm based upon the error between the identified model and the actual output of the plant. The proposed ANFN model adopts a functional link neural network (FLNN) as the consequent part of the fuzzy rules. Thus, the consequent part of the ANFN model is a nonlinear combination of input variables. Fuzzy control system is applied to guide and control the AUV using both adaptive models and mathematical model. Simulation results show the superiority of the proposed adaptive neural fuzzy network (ANFN) model in tracking of the behavior of the AUV accurately even in the presence of noise and disturbance.

Keywords: AUV, AUV dynamic model, fuzzy control, fuzzy modelling, adaptive fuzzy control, back propagation, system identification, neural fuzzy model, FLNN.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1335080

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References:

[1] Wang, L.-X.; Mendel, J. M.: Back-Propagation Fuzzy System as Nonlinear Dynamic System Identifires. In: Fuzzy Systems, IEEE International Conference, pp.1409-1418 (1992)
[2] Bossley K. M.; Brown M.; Harris C. J.: Neurofuzzy identification of an autonomous underwater vehicle. In: J. International Journal of Systems Science, vol. 30, no. 9, pp. 901-913(1999)
[3] Naeem, W.: Model Predictive Control of an Autonomous Underwater Vehicle. In: UKACC Conference control. Sheffield, IFAC, 19-23 (2002)
[4] Citeseerx,http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.18.4 264&rep=rep1&type=pdf.
[5] Li-Xin Wang,: Stable adaptive fuzzy controllers with application to inverted pendulum tracking, In: Systems, Man, and Cybernetics, Part B: Cybernetics, IEEE Transactions on , vol.26, no.5, pp.677-691, (1996)
[6] Y. H. Pao, S. M. Phillips, and D. J. Sobajic, "Neural-net computing and intelligent control systems," Int. J. Control, vol. 56, no. 2, pp. 263-289,1992.
[7] C. H. Chen, C. J. Lin, and C. T. Lin, "A functional-link-based neurofuzzy network for nonlinear system control," IEEE Trans. Fuzzy Syst., vol. 16, no. 5, pp. 1362-1378, Oct. 2008.
[8] J.C. Patra, G. Panda, Adriaan van den Bos, Modeling of an intelligent pressure sensor using functional link artificial neural networks, ISA Transactions 39 (2000) 15-27.
[9] Fossen, Thor I.: Guidance and control of ocean vehicles. Wiley , New York (1994)
[10] Asokan T.: Mathematical Modelling and Simulation of Autonomous Underwater Vehicle. Technical Report, IIT Madras (2007)
[11] Wang, L. X.: Fuzzy System are Universal Approximators. In: IEEE Proceeding of International Conference on Fuzzy Systems, pp. 1163- 1170 (1992)
[12] Takagi, T., & Sugeno, M.: Fuzzy Ident of Sys & its Applic to Modelling & Control. In: IEEE Trans. on Systs, Man and Cyb, vol 15, pp. 116-1 32 (1985)
[13] Akkizidis, I.S.; Roberts, G.N.: Fuzzy modelling and fuzzy-neuro motion control of an autonomous underwater robot. In: Advanced Motion Control, AMC '98-Coimbra., 5th International Workshop, pp.641-646 (1998)
[14] Hassanein, O.; Anavatti, S.G.; Ray, T.; , "Fuzzy modeling and control for Autonomous Underwater Vehicle," Automation, Robotics and Applications (ICARA), 2011 5th International Conference on , vol., no., pp.169-174, 6-8 Dec. 2011
[15] Li-Xin Wang. Adaptive Fuzzy System and Control, Design and Stability Analysis. Prentic Hall, New Jersey (1994)
[16] Shaaban A. S, Sreenatha G. A., Jin Y. C.: Indirect Adaptive Fuzzy Control of Unmanned Aerial Vehicle. In: Proceedings of the 17th World Congress, The International Federation of Automatic Control, pp. 13229-13243, Seoul, Korea, ( 2008)
[17] Chen, Y.C. and C.C. Teng.: A Model Reference Control Structure Using a Fuzzy Neural Network. J. Fuzzy Sets and Systems, vol.73, pp. 291-312 (1995).