Mixed impedance transmission problems for vibrating layered elastic bodies |
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| Authors: | C. E. Athanasiadis D. Natroshvili V. Sevroglou I. G. Stratis |
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| Affiliation: | 1. Department of Mathematics, National and Kapodistrian University of Athens, Panepistimiopolis, GR 15784 Zographou, Athens, Greece;2. Department of Mathematics, Georgian Technical University, Tbilisi, Georgia;3. I. Vekua Institute of Applied Mathematics, I. Javakhishvili Tbilisi State University, University str., 2, Tbilisi 0186, Georgia;4. Department of Statistics and Insurance Science, University of Piraeus, GR 18534, Piraeus, Greece |
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| Abstract: | Direct scattering problems for partially coated piecewise homogenous and inhomogeneous layered obstacles in linear elasticity lead to mixed impedance transmission problems for the steady‐state elastic oscillation equations. For a piecewise homogenous isotropic composite body, we employ the potential method and reduce the mixed impedance transmission problem to an equivalent system of boundary pseudodifferential equations. We give a detailed analysis of the corresponding pseudodifferential operators, which live on the interface between the layers and on a proper submanifold of the boundary of the composite elastic body, and establish uniqueness and existence results for the original mixed impedance transmission problem for arbitrary values of the oscillation frequency parameter; this is crucial in the study of inverse elastic scattering problems for partially coated layered obstacles. We also investigate regularity properties of solutions near the collision curves, where the different boundary conditions collide, and establish almost best Hölder smoothness results. Further, we analyze the asymptotic behavior of the stress vector near the collision curve and derive explicit formulas for the stress singularity exponents. The case of Lipschitz surfaces is briefly treated separately. In the case of a composite body containing homogeneous or inhomogeneous finite anisotropic inclusions, we develop an alternative hybrid method based on the so‐called nonlocal approach and reduce the mixed transmission problem to an equivalent functional‐variational equation with a sesquilinear form that ‘lives’ on a bounded part of the layered composite body and its boundary. We show that this sesquilinear form is coercive and that the corresponding variational equation is uniquely solvable. Copyright © 2015 John Wiley & Sons, Ltd. |
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| Keywords: | elasticity elastic oscillations mixed boundary value problems impedance problems transmission problems potential method pseudodifferential equations elastic radiation conditions |
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