Incremental Model Order Reduction of Smoothed-Particle Hydrodynamic Simulations

TL;DR

This paper introduces an incremental SVD-based compression method for time-dependent particle simulation data, significantly reducing memory use while maintaining accuracy, applicable to complex 2D and 3D simulations.

Contribution

It extends an existing grid-based SVD compression approach to irregular particle data, incorporating adaptive rank truncation and imputation strategies for efficient, accurate simulation data compression.

Findings

Reduces memory requirements by about 90%.

Increases computational effort by about 10%.

Maintains high accuracy in 2D and 3D test cases.

Abstract

Engineering simulations are usually based on complex, grid-based, or mesh-free methods for solving partial differential equations. The results of these methods cover large fields of physical quantities at very many discrete spatial locations and temporal points. Efficient compression methods can be helpful for processing and reusing such large amounts of data. A compression technique is attractive if it causes only a small additional effort and the loss of information with strong compression is low. The paper presents the development of an incremental Singular Value Decomposition (SVD) strategy for compressing time-dependent particle simulation results. The approach is based on an algorithm that was previously developed for grid-based, regular snapshot data matrices. It is further developed here to process highly irregular data matrices generated by particle simulation methods during simulation. Various aspects important for information loss, computational effort and storage requirements are discussed, and corresponding solution techniques are investigated. These include the development of an adaptive rank truncation approach, the assessment of imputation strategies to close snapshot matrix gaps caused by temporarily inactive particles, a suggestion for sequencing the data history into temporal windows as well as bundling the SVD updates. The simulation-accompanying method is embedded in a parallel, industrialized Smoothed-Particle Hydrodynamics software and applied to several 2D and 3D test cases. The proposed approach reduces the memory requirement by about 90% and increases the computational effort by about 10%, while preserving the required accuracy. For the final application of a water turbine, the temporal evolution of the force and torque values for the compressed and simulated data is in excellent agreement.