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Derivation of dual-horizon state-based peridynamics formulation based on Euler–Lagrange equation

Bingquan Wang, Selda Oterkus, Erkan Oterkus

2020Continuum Mechanics and Thermodynamics21 citationsDOIOpen Access PDF

Abstract

Abstract The numerical solution of peridynamics equations is usually done by using uniform spatial discretisation. Although implementation of uniform discretisation is straightforward, it can increase computational time significantly for certain problems. Instead, non-uniform discretisation can be utilised and different discretisation sizes can be used at different parts of the solution domain. Moreover, the peridynamic length scale parameter, horizon, can also vary throughout the solution domain. Such a scenario requires extra attention since conservation laws must be satisfied. To deal with these issues, dual-horizon peridynamics was introduced so that both non-uniform discretisation and variable horizon sizes can be utilised. In this study, dual-horizon peridynamics formulation is derived by using Euler–Lagrange equation for state-based peridynamics. Moreover, application of boundary conditions and determination of surface correction factors are also explained. Finally, the current formulation is verified by considering two benchmark problems including plate under tension and vibration of a plate.

Topics & Concepts

PeridynamicsDiscretizationEuler's formulaDomain (mathematical analysis)MathematicsHorizonBoundary value problemApplied mathematicsBoundary (topology)Mathematical analysisMathematical optimizationComputer scienceMechanicsPhysicsContinuum mechanicsGeometryNumerical methods in engineeringElectromagnetic Simulation and Numerical MethodsGeotechnical Engineering and Underground Structures