C. T. Dyka scite author profile

SUMMARYIn this work, the stress-point approach, which was developed to address tension instability and improve accuracy in Smoothed Particle Hydrodynamics (SPH) methods, is further extended and applied for one-dimensional (1-D) problems. Details of the implementation of the stress-point method are also given. A stability analysis reveals a reduction in the critical time step by a factor of 1/(2 when the stress points are located at the extremes of the SPH particle. An elementary damage law is also introduced into the 1-D formulation. Application to a 1-D impact problem indicates far less oscillation in the pressure at the interface for coarse meshes than with the standard SPH formulation. Damage predictions and backface velocity histories for a bar appear to be quite reasonable as well. In general, applications to elastic and inelastic 1-D problems are very encouraging. The stress-point approach produces stable and accurate results.1997 by John Wiley & Sons, Ltd.

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Stability of DPD and SPH

Randles

Petschek

Libersky

et al. 2003

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On the Development of a Hybrid Particle Method Using the Differential Formulation

Dyka

Saigal

2005

International Journal for Computational Methods in Engineering

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An extension of the Dual Particle Dynamics (DPD) method is introduced for the differential (strong) formulation in solid mechanics. Similar to the DPD, the new approach, termed the Hybrid Particle Method, employs two different types of particles or interpolation points, namely the motion points (mps) and stress points (sps). Momentum is balanced at the mps, while stresses and other field variables are calculated and tracked at both the sps and mps. A new momentum mixture rule is introduced which allows the Hybrid Particle Method to span the entire range from pure co-locational (mps only) to the pure DPD as well as variations and combinations of the two approaches. In one dimension, the accuracies of both the momentum balance and stress calculations are examined in detail. Co-locational (mps only) approaches are shown to be extremely noisy for wave propagation problems. However, accurate stresses are obtained at both mps and sps. A series of one dimensional results are shown to demonstrate the validity of the formulation. A discussion on the Hybrid Particle Method for two-and three-dimensional analyses is given, including some preliminary two-dimensional results. Issues concerning the modeling of very large deformations using the Hybrid Particle Method are also outlined.

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A new approach to dynamic condensation for FEM

Dyka¹,

Ingel

Flippen

1996

Computers & Structures

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C. T. Dyka

An approach for tension instability in smoothed particle hydrodynamics (SPH)

Stress Points for Tension Instability in SPH

Stability of DPD and SPH

On the Development of a Hybrid Particle Method Using the Differential Formulation

A new approach to dynamic condensation for FEM

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