More insights into stability analysis of shear-damped laminates: The role of active boundary and lower-order passive distributed dampers under various boundary conditions | ESAIM: Control, Optimisation and Calculus of Variations (ESAIM: COCV)

Open Access

Issue		ESAIM: COCV Volume 31, 2025


Article Number		52
Number of page(s)		29
DOI		https://doi.org/10.1051/cocv/2025039
Published online		24 June 2025

R. DiTaranto, Theory of vibratory bending for elastic and viscoelastic layered finite length beams. J. Appl. Mech. 32 (1956) 881–886. [Google Scholar]
D.J. Mead and S. Markus, The forced vibration of a three-layer, damped sandwich beam with arbitrary boundary conditions. J. Sound Vibr. 10 (1969) 163–175. [Google Scholar]
R. Mindlin, Influence of rotary inertia and shear on flexural motions of isotropic elastic plates. J. Appl. Mech. 18 (1951) 31–38. [Google Scholar]
A. Nosier and J. Reddy, On vibration and buckling of symmetric laminated plates according to shear deformation theory. Acta Mechanica 94 (1992) 123–151. [CrossRef] [MathSciNet] [Google Scholar]
Y. Rao and B. Nakra, Vibrations of unsymmetrical sandwich beams and plates with viscoelastic cores. J. Sound Vibr. 34 (1974) 309–326. [Google Scholar]
J. Reddy, A generalization of two-dimensional theories of laminated composite plates. Commun. Appl. Numer. Methods 3 (1987) 173–180. [CrossRef] [Google Scholar]
E. Reissner, On the bending of elastic plates. Q. Appl. Math. 4 (1947) 55–68. [Google Scholar]
C. Sun and Y. Lu, Vibration Damping of Structural Elements. Prentice Hall (1995). [Google Scholar]
M.-J. Yan and E. Dowell, Governing equations for vibrating constrained-layer damping sandwich plates and beams. J. Appl. Mech. 39 (1972) 1041–1046. [Google Scholar]
S. Hansen, Several related models for multilayer sandwich plates. Math. Models Methods Appl. Sci. 14 (2004) 1103–1132. [Google Scholar]
A.O. Ozer, Modeling and well-posedness results for active constrained layered (ACL) beams with/without magnetic effects, in Proc. SPIE 9799, Active and Passive Smart Structures and Integrated Systems (2016) 97991F. [Google Scholar]
A.O. Ozer, Modeling and controlling an active constrained layered (ACL) beam actuated by two voltage sources with/without magnetic effects. IEEE Trans. Automatic Control 62 (2017) 6445–6450. [Google Scholar]
A.O. Ozer, Potential formulation for charge or current-controlled piezoelectric smart composites and stabilization results: electrostatic versus quasi-static versus fully-dynamic approaches. IEEE Trans. Automatic Control 64 (2018) 989–1002. [Google Scholar]
R. Rajaram, Exact boundary controllability results for a Rao-Nakra sandwich beam. Syst. Control Lett. 56 (2007) 558–567. [Google Scholar]
A.O. Ozer and S.W. Hansen, Exact boundary controllability results for a multilayer Rao-Nakra sandwich beam. SIAM J. Cont. Optim. 52 (2014) 1314–1337. [Google Scholar]
A.O. Ozer and S.W. Hansen, Uniform stabilization of a multi-layer Rao-Nakra sandwich beam. Math. Control Signals Syst. 23 (2013) 199–222. [Google Scholar]
S. Hansen and O. Imanuvilov, Exact controllability of a multilayer Rao-Nakra plate with clamped boundary conditions. ESAIM Control Optim. Calc. Var. 17 (2011) 1101–1132. [CrossRef] [EDP Sciences] [MathSciNet] [Google Scholar]
S. Hansen and O. Imanuvilov, Exact controllability of a multilayer Rao-Nakra plate with free boundary conditions. Math. Control Relat. Fields 1 (2011) 189–230. [Google Scholar]
Y. Li, Z. Liu and Y. Wang, Weak stability of a laminated beam. Math. Control Related Fields 8 (2018) 789–808. [Google Scholar]
Z. Liu, B. Rao and Q. Zhang, Polynomial stability of the Rao-Nakra beam with a single internal viscous damping. J. Differ. Equ. 269 (2020) 6125–6162. [Google Scholar]
T. Quispe Mendez, V. Cabanillas Zannini and B. Feng, Asymptotic behavior of the Rao-Nakra sandwich beam model with Kelvin-Voigt damping. Math. Mech. Solids 29 (2024) 22–38. [Google Scholar]
B. Feng and A. Ozkan Ozer, Long-time behavior of a nonlinearly damped Rao-Nakra sandwich beam. Appl. Math. Optim. 87 (2023) Article number 19. [CrossRef] [Google Scholar]
M. Aouadi, Regularity and upper semicontinuity of pullback attractors for non-autonomous Rao-Nakra beam. Nonlinearity 35 (2022) 1773. [Google Scholar]
M. Akil and Z. Liu, Stabilization of the generalized Rao-Nakra beam by partial viscous damping. Math. Methods Appl. Sci. 46 (2023) 1479–1510. [Google Scholar]
M.M. Al-Gharabli, S. Al-Omari and A.M. Al-Mahdi, Stabilization of a Rao-Nakra sandwich beam system by Coleman-Gurtin's thermal law and nonlinear damping of variable-exponent type. J. Math. 21 (2024) Article ID 1615178. [Google Scholar]
A.M. Al-Mahdi, M. Noor, M.M. Al-Gharabli, B. Feng and A. Soufyane, Stability analysis for a Rao-Nakra sandwich beam equation with time-varying weights and frictional dampings. AIMS Math. 9 (2024) 12570–12587. [CrossRef] [MathSciNet] [Google Scholar]
B. Feng, C.A. Raposo, C.A. Nonato and A. Soufyane, Analysis of exponential stabilization for Rao-Nakra sandwich beam with time-varying weight and time-varying delay: multiplier method versus observability. Math. Control Relat. Fields 13 (2023) 631–663. [Google Scholar]
A. Guesmia, On the stability of a linear Cauchy Rao-Nakra sandwich beam under frictional dampings. Taiwanese J. Math. 27 (2023) 799–811. [Google Scholar]
T.Q. Mendez, V. Cabanillas Zannini and B. Feng, Asymptotic behavior of the Rao-Nakra sandwich beam model with Kelvin-Voigt damping. Math. Mech. Solids 29 (2024) 22–38. [Google Scholar]
O.P.V. Villagran, C.A. Raposo, C.A. Nonato and A.J.A. Ramos, Stability of solution for Rao-Nakra sandwich beam with boundary dissipation of fractional derivative type. J. Fract. Calc. Appl. 13 (2022) 116–143. [Google Scholar]
S. Hansen and R. Rajaram, Riesz basis property and related results for a Rao-Nakra sandwich beam. Discrete Contin. Dyn. Syst. Suppl. Vol. (2005) 365–375. [Google Scholar]
S. Hansen and R. Rajaram, Simultaneous boundary control of a Rao-Nakra sandwich beam, in Proc. 44th IEEE Conference on Decision and Control and European Control Conference (2005) 3146–3151. [Google Scholar]
S.W. Hansen and R. Rajaram, Exact boundary controllability of a Rao-Nakra sandwich beam, in Smart Structures and Materials 2005: Modeling, Signal Processing, and Control. SPIE 5757 (2005) 97–107. [Google Scholar]
A. Allen, Stability Results for Damped Multilayer Composite Beams and Plates. PhD thesis, Iowa State University (2009). [Google Scholar]
M. Akil, Asymptotic behavior of serially connected piezoelectric-elastic smart design: enhanced polynomial and new exponential decay, Evol. Equ. Control Theory, in press (2025). [Google Scholar]
M. Akil, S. Nicaise, A.O. (Ozer and V. Regnier, Stability results for novel serially-connected magnetizable piezoelectric and elastic smart-system designs. Appl. Math. Optim. 89 (2024). [CrossRef] [Google Scholar]
M. Akil, S. Nicaise, A.O. Ozer, and H. Saleh, Advancing insights into the stabilization of novel serially connected magnetizable piezoelectric and elastic beams, SIAM J. Control Optim., in press (2025). [Google Scholar]

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