Scattering through a flexural trifurcated waveguide by varying the material properties

Afsar, Haleem; Nawaz, Rab; Yaseen, Aqsa

doi:10.1088/1402-4896/ac0561

Cited by 19 publications

(6 citation statements)

References 27 publications

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“…In the context of structural difficulties, the phrases "clamped," "pivoted," and "pin-jointed" are frequently used to characterise various sorts of boundary conditions. These conditions explain how a specific structure is either supported or constrained at the edge and can be viewed in many related studies [21,22,[24][25][26]. Moreover in order to ensure matching of pressure and velocity at the junction, we impose the following conditions…”

Section: Mathematical Formulationmentioning

confidence: 99%

“…In the context of structural difficulties, the phrases “clamped,” “pivoted,” and “pin‐jointed” are frequently used to characterise various sorts of boundary conditions. These conditions explain how a specific structure is either supported or constrained at the edge and can be viewed in many related studies [21, 22, 24–26]. Moreover in order to ensure matching of pressure and velocity at the junction, we impose the following conditions

$$\begin{equation} {\left.

…”

Section: Mathematical Formulationmentioning

confidence: 99%

“…Tiwana et al [20] also studied sound radiation effects due to bifurcated waveguide structures with multiple bounding properties of non-dynamics type. Nevertheless, there is a literature gap in addressing multiple multifurcated problems with flexible boundaries except very few studies are established in recent times [21][22][23]. The consideration of such structures becomes imperative as rectangular waveguides have a much larger bandwidth over which only a single mode can propagate.…”

Section: Introductionmentioning

confidence: 99%

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Modeling and analysis of scattering in trifurcated guided waves with hard and flexible outer surfaces: A mathematical study

Alahmadi

2023

Z Angew Math Mech

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This article discusses the scattering in a trifurcated guided wave featuring the combination of hard and flexible exterior surfaces. Through the formulation of the relevant boundary value problem and modes matching of orthogonal and non‐orthogonal functions, a comprehensive solution is obtained through infinite linear algebraic equations. The structural complexity of these structures introduces challenges related to non‐linearities in dispersive relations, and uncommon orthogonal characteristics of eigenfunctions. Therefore, by reorganizing the differential system into an algebraic one, a solution is obtained by truncating the system numerically. Further, analytical and numerical tests validate the solution, including graphical representations of relative powers versus frequency. The results reveal that transmission dominates reflection for frequencies above 900Hz in the symmetrical setting, with nearly equal power propagating through regions 2, 3, and 4. In the non‐symmetrical setting, power primarily transmits through region 4 for frequencies above 600Hz whereas most of the power being reflected at cut‐on frequencies when region 3 as rigid‐soft instead of rigid‐rigid. The obtained solution also confirms the properties of eigenfunctions, and the power distribution among different regions validates the accuracy of the solution. This work holds significance as it provides a standard procedure for modeling and solving a broad range of multifurcated problems with multiple dynamic boundary properties. The findings aid the understanding and development of waveguide systems, offering vision to practical applications in various fields involving complex wave propagation.

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Section: Mathematical Formulationmentioning

confidence: 99%

$$\begin{equation} {\left.

…”

Section: Mathematical Formulationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Modeling and analysis of scattering in trifurcated guided waves with hard and flexible outer surfaces: A mathematical study

Alahmadi

2023

Z Angew Math Mech

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“…The waveguides, elastic plates, beams, laminates, panels, rods, as well as cylindrical shells, are some of the structures that may be found in multiply-bond layers, to highlight a few, see Refs. [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25] In terms of layered structure design and structural analysis, which frequently has contrasting material and geometrical parameters, such as size, volume density, and stiffness. Layered structures offer advantages such as high resistance, lightweight, and strength; additionally, they have static and dynamic excitations.…”

Section: Introductionmentioning

confidence: 99%

Dispersion of elastic waves in the three-layered inhomogeneous sandwich plate embedded in the Winkler foundations

Asif

Nawaz

Nuruddeen³

2023

Science Progress

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This research article investigates the behavior of elastic waves in an inhomogeneous isotropic three-layered sandwich plate with soft-core and stiff-skin layers embedded in Winkler foundations, using anti-plane shear motion. The study establishes the exact antisymmetric dispersion relation, low-frequency spectrum, and overall cut-off frequency of the wave propagation. A shortened polynomial dispersion relation is developed for the long-wave low-frequency regime by considering the contrasting material setup and compared with the exact dispersion relation. This article also provides exact and asymptotic formulas for stresses and displacements in each layer of the plate, as well as approximate one-dimensional equations of motion. The results suggest that the approximate equations of motion for the three-layered sandwich plate are valid throughout the entire low-frequency range, despite the presence of Winkler foundations on both sides of the plate. This research is significant as it provides insights into the behavior of waves in composite materials and can be used to improve the design of sandwich structures used in various engineering applications. Additionally, the findings that the approximate equations of motion for the three-layered sandwich plate are valid throughout the low-frequency range, despite the presence of Winkler foundations, can help simplify calculations and make the design process more efficient.

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“…In the absence of phase discontinuities, the MM technique was used to address the acoustic dispersion in planar trifurcated and pentafurcated waveguides structures carrying compressible fluid. Current research in this field is noticeable using specified references [16][17][18][19][20][21][22][23][24][25].…”

Section: Introductionmentioning

confidence: 99%

Energy distribution of bifurcated waveguide structure with planar and non-planar surfaces

Afsar

Akbar

2022

Mathematics and Mechanics of Solids

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The present communication addresses the reflection and transmission analysis of a two-dimensional waveguide structure with planar and non-planar surfaces. In the fields of physics, engineering and applied mathematics, research is being carried out to control or reduce unwanted and harmful noise to an acceptable level. Our aim is to solve the boundary value problem developed to simulate the transmission and reflection of a bifurcated waveguide structure in the channels or ducts that have abrupt changes in the height together with planar and non-planar surfaces. Furthermore, the eigenfunctions are linearly independent and non-orthogonal. To solve non-orthogonal eigenfunctions, a generalized orthogonality relation has been developed. Solution is obtained using mode matching technique (MMT) along with generalized orthogonal relations. In the last section, solution is viewed graphically in the inner and outer ducts or channels for different frequencies and height. The expressions for energy distribution in different duct regions are obtained and sketched subject to the various properties of the waveguide material. The results are well supported for a number of mathematical and physical reasons.

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Scattering through a flexural trifurcated waveguide by varying the material properties

Cited by 19 publications

References 27 publications

Modeling and analysis of scattering in trifurcated guided waves with hard and flexible outer surfaces: A mathematical study

Modeling and analysis of scattering in trifurcated guided waves with hard and flexible outer surfaces: A mathematical study

Dispersion of elastic waves in the three-layered inhomogeneous sandwich plate embedded in the Winkler foundations

Energy distribution of bifurcated waveguide structure with planar and non-planar surfaces

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