Acceleration of structural topology optimization using symmetric element-by-element strategy for unstructured meshes on GPU

Ratnakar, Shashi Kant; Kiran, Utpal; Sharma, Deepak

doi:10.1108/ec-01-2022-0022

Cited by 3 publications

(1 citation statement)

References 42 publications

(94 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In a recent work, 52 matrix‐free FEM is used to solve up to 500 million DOFs numerical homogenization problem with preconditioned CG solver based on

EbE

and

NbN

strategies. Apart from the aforementioned works, there are numerous other research works that show significant computational performance by matrix‐free solvers with GPUs in wide range of areas like elasticity, 48,49 topology optimization, 53,54 earthquake simulation, 55 fluid mechanics 56 and so forth.…”

Section: Literature Surveymentioning

confidence: 99%

Development of GPU‐based matrix‐free strategies for large‐scale elastoplasticity analysis using conjugate gradient solver

Kiran,

Sharma,

Gautam

2024

Numerical Meth Engineering

View full text Add to dashboard Cite

In recent years, matrix‐free conjugate gradient (CG) solvers with graphics processing unit (GPU) acceleration have been effectively used to reduce the execution timings of finite element method (FEM)‐based engineering simulations. However, there is not much in the literature that discusses the application of matrix‐free CG solvers for elastoplasticity. The primary challenge is the presence of both elastic and plastic states, which introduce branching issues in the parallel computation of sparse matrix‐vector multiplication (SpMV). The current work proposes an efficient split kernel strategy for elastoplasticity that segregates elements in elastic and plastic zones and allows the application of standard GPU‐based matrix‐free SpMV strategies in the literature to elastoplastic simulation. The proposed strategy avoids branching issues, facilitates coalesced memory access, allows efficient usage of on‐chip memory, and uses minimum storage to realize large‐scale simulation on a GPU with limited memory. We also propose matrix‐free SpMV strategies for GPU implementation based on an element‐by‐element technique that makes efficient use of memory hierarchy available in a GPU. The computational efficiency of the proposed strategies is demonstrated over three large‐scale benchmark examples from elastoplasticity, and the performance results are compared with GPU optimized node‐based and degrees of freedom (DOF)‐based matrix‐free strategies. The results show that the splitting of computation is most suitable for low plasticity problems, where most of the matrix‐free strategies show significant speedups with respect to single kernel strategy for elastoplasticity. The proposed element‐by‐element strategy using node‐wise thread allocation is found to have the best performance, achieving up to 7.16 and 3.35 speedup over node‐based and DOF‐based strategy, respectively. For problems with higher amounts of plasticity, the proposed strategies perform slightly better and achieve modest speedups due to advantages in the initial stages of Newton iterations. In terms of wall‐clock timings, the proposed matrix‐free solver is found to be up to 2 faster than GPU optimized assembly‐based elastoplasticity solver.

show abstract

“…In a recent work, 52 matrix‐free FEM is used to solve up to 500 million DOFs numerical homogenization problem with preconditioned CG solver based on

EbE

and

NbN

Section: Literature Surveymentioning

confidence: 99%

Development of GPU‐based matrix‐free strategies for large‐scale elastoplasticity analysis using conjugate gradient solver

Kiran,

Sharma,

Gautam

2024

Numerical Meth Engineering

View full text Add to dashboard Cite

show abstract

An efficient framework for matrix-free SpMV computation on GPU for elastoplastic problems

Kiran,

Sharma,

Gautam

2024

Mathematics and Computers in Simulation

View full text Add to dashboard Cite

GPU parallel computation strategy for electrothermal coupling problems using improved assembly-free FEM

Wu,

Wang,

Hou

et al. 2024

Journal of Computational Design and Engineering

View full text Add to dashboard Cite

The analysis of electrothermal coupling problems finds extensive application in engineering. However, for large-scale electrothermal coupling problems, the time cost and storage requirements for solving them using the Finite Element Method (FEM) are substantial. We optimise the finite element electrothermal coupling computation from two aspects: computational speed and storage usage. Based on the assembly-free FEM, we explore the symmetry of element matrices to reduce storage for second-order tetrahedral elements and propose a GPU parallel algorithm to improve computational speed. At the same time, we allocate the parallel parts of an electrothermal coupling problem to two GPUs to improve the speed further. In addition, for the three types of boundary conditions in electrothermal coupling problems, we design parallel application methods suitable for assembly-free FEM. Finally, we compare our strategy with methods from other literature through the numerical experiment. Our method reduces the element matrices’ storage by 45%. Compared with the solution process using the element level method and degree of freedom(DoF) level method, our strategy achieves average acceleration ratios of 5.83 and 1.38, respectively.

show abstract

Acceleration of structural topology optimization using symmetric element-by-element strategy for unstructured meshes on GPU

Cited by 3 publications

References 42 publications

Development of GPU‐based matrix‐free strategies for large‐scale elastoplasticity analysis using conjugate gradient solver

Development of GPU‐based matrix‐free strategies for large‐scale elastoplasticity analysis using conjugate gradient solver

An efficient framework for matrix-free SpMV computation on GPU for elastoplastic problems

GPU parallel computation strategy for electrothermal coupling problems using improved assembly-free FEM

Contact Info

Product

Resources

About