A non-local method in peridynamic theory for simulating elastic wave propagation in solids

“…An increase (or decrease) in the angle 𝜙 k causes a rotation of the half-space around the point x i , as illustrated in Figure 4. For the construction of the ABCs, we adopt a symmetric interval in (34) to specify the angle 𝜙 k in order to transmit incoming waves from the near-field at different incident angles into their respective half-space. In addition, the value of Δ𝜙 must not be selected arbitrarily high, such that incident waves propagate out and the energy is absorbed.…”

“…Another important note, alluded to in Section 3.1, is the selection of the parameters Δ𝜙 and Δ𝜅 as well as the associated ranges in (34). The application of EBFs is comprehensively studied in Reference 40, and possible ranges are provided in References 35-37.…”

“…The application of EBFs is comprehensively studied in Reference 40, and possible ranges are provided in References 35-37. In the present study, following (34), an interval of Δ𝜙[−1, 1] with ten equidistant subdivisions is employed. Empirically, it has been found that a value of Δ𝜙 = 𝜋∕4 generally achieves satisfactory results.…”

“…The influence of this parameter is presented by means of a sensitivity analysis in Reference 35. The second influential parameter Δ𝜅 in (34) affects the spatial fluctuation of the modes and determines the range of the interval Δ𝜅[−1, 1]. To find an upper limit to the value of Δ𝜅, we adopt the Nyquist-Shannon sampling theorem (see Reference 35).…”

Dirichlet‐type absorbing boundary conditions for peridynamic scalar waves in two‐dimensional viscous media

“…An increase (or decrease) in the angle 𝜙 k causes a rotation of the half-space around the point x i , as illustrated in Figure 4. For the construction of the ABCs, we adopt a symmetric interval in (34) to specify the angle 𝜙 k in order to transmit incoming waves from the near-field at different incident angles into their respective half-space. In addition, the value of Δ𝜙 must not be selected arbitrarily high, such that incident waves propagate out and the energy is absorbed.…”

“…Another important note, alluded to in Section 3.1, is the selection of the parameters Δ𝜙 and Δ𝜅 as well as the associated ranges in (34). The application of EBFs is comprehensively studied in Reference 40, and possible ranges are provided in References 35-37.…”

“…The application of EBFs is comprehensively studied in Reference 40, and possible ranges are provided in References 35-37. In the present study, following (34), an interval of Δ𝜙[−1, 1] with ten equidistant subdivisions is employed. Empirically, it has been found that a value of Δ𝜙 = 𝜋∕4 generally achieves satisfactory results.…”

“…The influence of this parameter is presented by means of a sensitivity analysis in Reference 35. The second influential parameter Δ𝜅 in (34) affects the spatial fluctuation of the modes and determines the range of the interval Δ𝜅[−1, 1]. To find an upper limit to the value of Δ𝜅, we adopt the Nyquist-Shannon sampling theorem (see Reference 35).…”

Dirichlet‐type absorbing boundary conditions for peridynamic scalar waves in two‐dimensional viscous media

“…In peridynamic theory, an integral model is used in place of the classic partial differential model, thus avoiding the invalidation problem, which usually appears under the classic mathematical framework due to discontinuity. After more than twenty years of development, peridynamic theory is now widely used in the study of elastic wave propagation [26], composite material fracture [27], rock failure [28] and corrosion damage [29], etc. Recently, with the advantages of dealing with fracture problems such as crack propagation, peridynamic theory has been preliminarily applied to the analysis of railway fatigue.…”

A two-dimensional ordinary state-based peridynamic model for surface fatigue crack propagation in railheads

Perfectly matched layers for peridynamic scalar waves and the numerical discretization on real coordinate space