Development, validation, and application of the 2.5D finite-length thin layer (FTL) element for computing dynamic response of the ground
Development, validation, and application of the 2.5D finite-length thin layer (FTL) element for computing dynamic response of the ground
The classic finite element (FE) method suffers from low computational efficiency when dealing with wave propagation in unbounded domains, as a sufficient number of elements are required per wavelength. This issue becomes particularly pronounced in soil dynamics problems involving semi-infinite ground. In this paper, we develop a 2.5D finite-length thin layer (FTL) method to efficiently calculate ground vibrations. Based on the well-established thin layer method, the ground is first discretized in the vertical direction, producing a series of thin layer elements. Through the quadratic eigenvalue analysis, the mode shapes of the thin layer elements are obtained. By superimposing the left- and right-propagating mode shapes, the stiffness matrix of the 2.5D FTL element is constructed. Since the mode shapes are derived analytically, the length of the 2.5D FTL element is not restricted by the analyzing frequency or corresponding ground wavelength, significantly reducing the degrees of freedom (DOFs) of the ground model. The ground responses computed by the 2.5D FTL method are compared with those obtained using the classic dynamic flexibility method and the 2.5D FE method, demonstrating the high accuracy of the 2.5D FTL method. The 2.5D FTL element is subsequently incorporated into the 2.5D finite element, with the perfectly matched layer (PML) serving as an absorbing boundary. Numerical results exhibit good compatibility between the 2.5D finite element and the 2.5D FTL element. Additionally, a case study of ground vibrations from an underground tunnel is conducted, illustrating the capability of the proposed method in analyzing dynamic interactions between complex engineering structures and soils.
2.5D finite-length thin layer (FTL) element, arbitrary element length, efficient computation, eigenvalue analysis, ground vibration
Peng, Yuhao
5f2f8af5-d6de-4448-b3cd-6106d47a1224
He, Chao
00c81b62-d2e8-4419-b651-ce7b635a295c
Li, Xiaoxin
f5d3ec53-96d2-4c30-b7d2-9533a204fad5
Qu, Xiangyu
98e0143d-b717-4388-a573-293e66c2f2dc
Sheng, Xiaozhen
c06ac8cc-eb10-4f8b-b3fb-9ec5b451a744
Zhou, Shunhua
997856ff-c254-44be-ac27-942586e54622
5 December 2025
Peng, Yuhao
5f2f8af5-d6de-4448-b3cd-6106d47a1224
He, Chao
00c81b62-d2e8-4419-b651-ce7b635a295c
Li, Xiaoxin
f5d3ec53-96d2-4c30-b7d2-9533a204fad5
Qu, Xiangyu
98e0143d-b717-4388-a573-293e66c2f2dc
Sheng, Xiaozhen
c06ac8cc-eb10-4f8b-b3fb-9ec5b451a744
Zhou, Shunhua
997856ff-c254-44be-ac27-942586e54622
Peng, Yuhao, He, Chao, Li, Xiaoxin, Qu, Xiangyu, Sheng, Xiaozhen and Zhou, Shunhua
(2025)
Development, validation, and application of the 2.5D finite-length thin layer (FTL) element for computing dynamic response of the ground.
International Journal for Numerical Methods in Engineering, 126 (23), [e70196].
(doi:10.1002/nme.70196).
Abstract
The classic finite element (FE) method suffers from low computational efficiency when dealing with wave propagation in unbounded domains, as a sufficient number of elements are required per wavelength. This issue becomes particularly pronounced in soil dynamics problems involving semi-infinite ground. In this paper, we develop a 2.5D finite-length thin layer (FTL) method to efficiently calculate ground vibrations. Based on the well-established thin layer method, the ground is first discretized in the vertical direction, producing a series of thin layer elements. Through the quadratic eigenvalue analysis, the mode shapes of the thin layer elements are obtained. By superimposing the left- and right-propagating mode shapes, the stiffness matrix of the 2.5D FTL element is constructed. Since the mode shapes are derived analytically, the length of the 2.5D FTL element is not restricted by the analyzing frequency or corresponding ground wavelength, significantly reducing the degrees of freedom (DOFs) of the ground model. The ground responses computed by the 2.5D FTL method are compared with those obtained using the classic dynamic flexibility method and the 2.5D FE method, demonstrating the high accuracy of the 2.5D FTL method. The 2.5D FTL element is subsequently incorporated into the 2.5D finite element, with the perfectly matched layer (PML) serving as an absorbing boundary. Numerical results exhibit good compatibility between the 2.5D finite element and the 2.5D FTL element. Additionally, a case study of ground vibrations from an underground tunnel is conducted, illustrating the capability of the proposed method in analyzing dynamic interactions between complex engineering structures and soils.
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Numerical_Meth_Engineering_-_2025_-_Peng_-_Development_Validation_and_Application_of_the_2_5D_Finite_Length_Thin_Layer_
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Numerical Meth Engineering - 2025 - Peng - Development Validation and Application of the 2 5D Finite‐Length Thin Layer
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Accepted/In Press date: 31 October 2025
e-pub ahead of print date: 5 December 2025
Published date: 5 December 2025
Keywords:
2.5D finite-length thin layer (FTL) element, arbitrary element length, efficient computation, eigenvalue analysis, ground vibration
Identifiers
Local EPrints ID: 510799
URI: http://eprints.soton.ac.uk/id/eprint/510799
ISSN: 0029-5981
PURE UUID: 67ff7d89-e813-4140-a46e-3257d968dbbc
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Date deposited: 22 Apr 2026 16:38
Last modified: 28 Apr 2026 17:07
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Contributors
Author:
Yuhao Peng
Author:
Chao He
Author:
Xiaoxin Li
Author:
Xiaozhen Sheng
Author:
Shunhua Zhou
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