Research output: Contribution to journal › Article › peer-review
Unique recovery of unknown spatial load in damped Euler-Bernoulli beam equation from final time measured output. / Hasanov, Alemdar; Romanov, Vladimir; Baysal, Onur.
In: Inverse Problems, Vol. 37, No. 7, 075005, 07.2021.Research output: Contribution to journal › Article › peer-review
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TY - JOUR
T1 - Unique recovery of unknown spatial load in damped Euler-Bernoulli beam equation from final time measured output
AU - Hasanov, Alemdar
AU - Romanov, Vladimir
AU - Baysal, Onur
N1 - Publisher Copyright: © 2021 IOP Publishing Ltd. Copyright: Copyright 2021 Elsevier B.V., All rights reserved.
PY - 2021/7
Y1 - 2021/7
N2 - In this paper we discuss the unique determination of unknown spatial load F(x) in the damped Euler-Bernoulli beam equation ρ (x)utt + μ ut + (r (x) uxx)xx = F (x)G (t) from final time measured output (displacement, u T (x) ≔ u(x, T) or velocity, ν t,T (x) ≔ u t (x, T)). It is shown in [Hasanov Hasanoglu and Romanov 2017 Introduction to Inverse Problems for Differential Equations (New York: Springer)] that the unique determination of F(x) in the undamped wave equation utt-(k (x)ux)x = F (x)G (t) from final time output is not possible. This result is also valid for the undamped beam equation ρ (x) utt+ (r (x) uxx)xx = F (x)G (t). We prove that in the presence of damping term μu t , the spatial load can be uniquely determined by the final time output, in terms of the convergent singular value expansion (SVE), as, F(x) = ςn = 1∞ uT,n ψn (x)/ σn under some acceptable conditions with respect to the final time T > 0, the damping coefficient μ > 0 and the temporal load G(t) > 0. As an alternative method we propose the adjoint problem approach (APA) and derive an explicit gradient formula for the Fréchet derivative of the Tikhonov functional J(F) = ∥u (˙ ,T;F)- uT∥L2 (0,l)2. Comparative analysis of numerical algorithms based on SVE and APA methods are provided for the harmonic loading G(t) = cos(ωt), ω > 0, as a most common dynamic loading case. The results presented in this paper not only clearly demonstrate the key role of the damping term μu t in the inverse problems arising in vibration and wave phenomena, but also allows us, firstly, to find admissible values of the final time T > 0, at which a final time measured output can be extracted, and secondly, to reconstruct the unknown spatial load F(x) in the damped Euler-Bernoulli beam equation from this measured output.
AB - In this paper we discuss the unique determination of unknown spatial load F(x) in the damped Euler-Bernoulli beam equation ρ (x)utt + μ ut + (r (x) uxx)xx = F (x)G (t) from final time measured output (displacement, u T (x) ≔ u(x, T) or velocity, ν t,T (x) ≔ u t (x, T)). It is shown in [Hasanov Hasanoglu and Romanov 2017 Introduction to Inverse Problems for Differential Equations (New York: Springer)] that the unique determination of F(x) in the undamped wave equation utt-(k (x)ux)x = F (x)G (t) from final time output is not possible. This result is also valid for the undamped beam equation ρ (x) utt+ (r (x) uxx)xx = F (x)G (t). We prove that in the presence of damping term μu t , the spatial load can be uniquely determined by the final time output, in terms of the convergent singular value expansion (SVE), as, F(x) = ςn = 1∞ uT,n ψn (x)/ σn under some acceptable conditions with respect to the final time T > 0, the damping coefficient μ > 0 and the temporal load G(t) > 0. As an alternative method we propose the adjoint problem approach (APA) and derive an explicit gradient formula for the Fréchet derivative of the Tikhonov functional J(F) = ∥u (˙ ,T;F)- uT∥L2 (0,l)2. Comparative analysis of numerical algorithms based on SVE and APA methods are provided for the harmonic loading G(t) = cos(ωt), ω > 0, as a most common dynamic loading case. The results presented in this paper not only clearly demonstrate the key role of the damping term μu t in the inverse problems arising in vibration and wave phenomena, but also allows us, firstly, to find admissible values of the final time T > 0, at which a final time measured output can be extracted, and secondly, to reconstruct the unknown spatial load F(x) in the damped Euler-Bernoulli beam equation from this measured output.
KW - damped Euler-Bernoulli and wave equations
KW - inverse source problem
KW - singular values
KW - uniqueness
UR - http://www.scopus.com/inward/record.url?scp=85109096129&partnerID=8YFLogxK
U2 - 10.1088/1361-6420/ac01fb
DO - 10.1088/1361-6420/ac01fb
M3 - Article
AN - SCOPUS:85109096129
VL - 37
JO - Inverse Problems
JF - Inverse Problems
SN - 0266-5611
IS - 7
M1 - 075005
ER -
ID: 29136735