On the Finite Time Stabilization Via Robust Control for Uncertain Disturbed Systems

Amato, F., Ambrosino, R., Ariola, M., Cosentino, C., De Tommasi, G. (2014). Finite-Time Stability and Control, Springer, London. Search in Google Scholar

Amato, F., Ariola, M., Cosentino, C., Abdallah, C. and Dorato, P. (2003). Necessary and sufficient conditions for finite-time stability of linear systems, Proceedings of the 2003 American Control Conference, Denver, USA, Vol. 5, pp. 4452–4456. Search in Google Scholar

Amato, F., Ariola, M. and Dorato, P. (2001). Finite-time control of linear systems subject to parametric uncertainties and disturbances, Automatica 37(9): 1459–1463. Search in Google Scholar

Bhat, S.P. and Bernstein, D.S. (2000). Finite-time stability of continuous autonomous systems, SIAM Journal on Control and Optimization 38(3): 751–766. Search in Google Scholar

Edwards, C. and Spurgeon, S. (1998). Sliding Mode Control: Theory and Applications, CRC Press, Boca Raton. Search in Google Scholar

Haddad, W.M. and Chellaboina, V. (2011). Nonlinear Dynamical Systems and Control: A Lyapunov-based Approach, Princeton University Press, Princeton. Search in Google Scholar

Khalil, H.K. and Grizzle, J.W. (2002). Nonlinear Systems, Vol. 3, Prentice Hall, Upper Saddle River. Search in Google Scholar

Kokotović, P.V., Nicosia, T., Menini, L., Zaccarian, L. and Abdallah, C.T. (2006). Current Trends in Nonlinear Systems and Control: In Honor of Petar Kokotovic and Turi Nicosia, Springer, Boston. Search in Google Scholar

Kukurowski, N., Mrugalski, M., Pazera, M. and Witczak, M. (2022). Fault-tolerant tracking control for a non-linear twin-rotor system under ellipsoidal bounding, International Journal of Applied Mathematics and Computer Science 32(2): 171–183, DOI: 10.34768/amcs-2022-0013. Open DOISearch in Google Scholar

Li, X., Ho, D.W. and Cao, J. (2019). Finite-time stability and settling-time estimation of nonlinear impulsive systems, Automatica 99: 361–368. Search in Google Scholar

Liu, H., Zhong, M. and Yang, R. (2018). Simultaneous disturbance compensation and H_i/H^∞ optimization in fault detection of UAVs, International Journal of Applied Mathematics and Computer Science 28(2): 349–362, DOI: 10.2478/amcs-2018-0026. Open DOISearch in Google Scholar

Orlov, Y., Aoustin, Y. and Chevallereau, C. (2010). Finite time stabilization of a perturbed double integrator. Part I: Continuous sliding mode-based output feedback synthesis, IEEE Transactions on Automatic Control 56(3): 614–618. Search in Google Scholar

Polyakov, A., Efimov, D. and Perruquetti, W. (2015). Finite-time and fixed-time stabilization: Implicit Lyapunov function approach, Automatica 51: 332–340. Search in Google Scholar

Poznyak, A., Polyakov, A. and Azhmyakov, V. (2014). Attractive Ellipsoids in Robust Control, Springer, Cham. Search in Google Scholar

Puangmalai, J., Tongkum, J. and Rojsiraphisal, T. (2020). Finite-time stability criteria of linear system with non-differentiable time-varying delay via new integral inequality, Mathematics and Computers in Simulation 171: 170–186. Search in Google Scholar

Utkin, V.I. and Poznyak, A.S. (2013). Adaptive sliding mode control with application to super-twist algorithm: Equivalent control method, Automatica 49(1): 39–47. Search in Google Scholar

Wang, H., Liu, P.X., Zhao, X. and Liu, X. (2019). Adaptive fuzzy finite-time control of nonlinear systems with actuator faults, IEEE Transactions on Cybernetics 50(5): 1786–1797. Search in Google Scholar

Weiss, L. and Infante, E. (1967). Finite time stability under perturbing forces and on product spaces, IEEE Transactions on Automatic Control 12(1): 54–59. Search in Google Scholar

Yu, S., Yu, X., Shirinzadeh, B. and Man, Z. (2005). Continuous finite-time control for robotic manipulators with terminal sliding mode, Automatica 41(11): 1957–1964. Search in Google Scholar