Isogeometric analysis of functionally graded sandwich plate
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Isogeometric analysis is used to analyze the behavior of functionally graded sandwich plates. Various theories have been developed to accurately model the bending behavior of these plates. One such theory is the hyperbolic quasi-3D shear deformation plate theory, which reduces the number of unknowns and eliminates the need for shear correction factors . Another theory called the spectral displacement formulation (SDF) uses a unique form of the Chebyshev series to express the displacement field, allowing for accurate bending analysis and satisfying traction-free boundary conditions . Stochastic isogeometric analysis (SIGA) is used to analyze functionally graded plates subjected to random distribution loads, modeling the spatial random variation as a homogeneous Gaussian random field . These theories and methods have been shown to be effective in analyzing the bending behavior, free vibration, and thermo-mechanical properties of functionally graded sandwich plates .
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7 Citations | The provided paper does not mention isogeometric analysis of functionally graded sandwich plates. |
| The paper presents a quasi-three-dimensional shear deformation theory for static bending and free vibration analyses of porous sandwich functionally graded plates reinforced with graphene nanoplatelets. However, it does not specifically mention isogeometric analysis of functionally graded sandwich plates. | |
1 Citations | The provided paper does not specifically mention the isogeometric analysis of functionally graded sandwich plates. |
| The provided paper does not specifically mention the analysis of functionally graded sandwich plates. |
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