# Entropy stability analysis of smoothed dissipative particle dynamics

**Authors:** Satori Tsuzuki

arXiv: 1905.06332 · 2026-02-26

## TL;DR

This paper analyzes the entropy stability of smoothed dissipative particle dynamics (SDPD), revealing how different kernel functions influence stability conditions and enhancing understanding of particle discretization.

## Contribution

It provides a theoretical entropy stability analysis of SDPD, identifying how kernel choices affect stability conditions in particle discretization.

## Key findings

- Eight types of entropy stability conditions depend on kernel functions.
- Lucy, poly6, and spiky kernels share the same stability conditions.
- Spline kernel exhibits different entropy stability conditions.

## Abstract

This article presents an entropy stability analysis of smoothed dissipative particle dynamics (SDPD) to review the validity of particle discretization of entropy equations. First, we consider the simplest SDPD system: a simulation of incompressible flows using an explicit time integration scheme, assuming a quasi-static scenario with constant volume, constant number of particles, and infinitesimal time shift. Next, we derive a form of entropy from the discretized entropy equation of SDPD by integrating it with respect to time. We then examine the properties of a two-particle system for a constant temperature gradient. Interestingly, our theoretical analysis suggests that there exist eight different types of entropy stability conditions, which depend on the types of kernel functions. It is found that the Lucy kernel, poly6 kernel, and spiky kernel produce the same types of entropy stability conditions, whereas the spline kernel produces different types of entropy stability conditions. Our results contribute to a deeper understanding of particle discretization.

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Source: https://tomesphere.com/paper/1905.06332