An explicit dynamics GPU structural solver for thin shell finite elements

Bartezzaghi, Andrea; Cremonesi, Massimiliano; Parolini, Nicola; Perego, U.

doi:10.1016/j.compstruc.2015.03.005

Cited by 20 publications

(16 citation statements)

References 23 publications

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“…With the release of Compute Capability 1.3 devices in late 2008, fp64 computation is supported, but is still largely absent in literature. Bartezzaghi et al (2015) first addressed this issue, and with the exception of Strbac et al (2015) and Strbac et al (2016), the authors are unaware of reports using doubleprecision computation in our context. It is well-known that double-precision computation, particularly in atomic operations, is significantly slower but mandatory in accurate and general engineering application.…”

Section: Gpu-accelerated Explicit Fe Analysismentioning

confidence: 99%

“…Reports of large (up to two orders of magnitude) speed-ups can be found in the literature for the TLED method Taylor et al (2009), Strbac et al (2015), Strbac et al (2016), Bartezzaghi et al (2015). Such claims are often based on simplifications, some introduced in the following paragraphs.…”

Section: Gpu-accelerated Explicit Fe Analysismentioning

confidence: 99%

“…Further, benchmarking reports on GPU performance use simple or ideal (Bartezzaghi et al, 2015;Comas et al, 2008;Strbac et al, 2015) geometries. Meshing of complex geometries often requires misshaped elements (that limit usable step sizes in explicit analysis), also detailed further in Section 2.3.1.…”

Section: Gpu-accelerated Explicit Fe Analysismentioning

confidence: 99%

See 2 more Smart Citations

Rupture risk in abdominal aortic aneurysms: A realistic assessment of the explicit GPU approach

Štrbac

Pierce

Rodríguez-Vila

et al. 2017

Journal of Biomechanics

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Accurate estimation of peak wall stress (PWS) is the crux of biomechanically motivated rupture risk assessment for abdominal aortic aneurysms aimed to improve clinical outcomes. Such assessments often use the finite element (FE) method to obtain PWS, albeit at a high computational cost, motivating simplifications in material or element formulations. These simplifications, while useful, come at a cost of reliability and accuracy. We achieve research-standard accuracy and maintain clinically applicable speeds by using novel computational technologies. We present a solution using our custom finite element code based on graphics processing unit (GPU) technology that is able to account for added complexities involved with more physiologically relevant solutions, e.g. strong anisotropy and heterogeneity. We present solutions up to 17x faster relative to an established finite element code using state-of-the-art nonlinear, anisotropic and nearly-incompressible material descriptions. We show a realistic assessment of the explicit GPU FE approach by using complex problem geometry, biofidelic material law, doubleprecision floating point computation and full element integration. Due to the increased solution speed without loss of accuracy, shown on five clinical cases of abdominal aortic aneurysms, the method shows promise for clinical use in determining rupture risk of abdominal aortic aneurysms.

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Section: Gpu-accelerated Explicit Fe Analysismentioning

confidence: 99%

Section: Gpu-accelerated Explicit Fe Analysismentioning

confidence: 99%

See 1 more Smart Citation

Rupture risk in abdominal aortic aneurysms: A realistic assessment of the explicit GPU approach

Štrbac

Pierce

Rodríguez-Vila

et al. 2017

Journal of Biomechanics

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“…These graphics devices are also successfully used for real-time simulation and haptic feedback of soft tissue deformations [27,28], which are especially useful for the development of realistic simulators. Besides, relevant results are obtained for the structural solver of finite element explicit dynamics problems using GPU computing [29]. These graphics cards have also shown promising results in heterogeneous systems addressing large-scale problems in Finite Element Analysis (FEA) [30].…”

Section: Introductionmentioning

confidence: 99%

Efficient topology optimization using GPU computing with multilevel granularity

Martnez-Frutos

Martnez-Castejn

Herrero-Prez

2017

Advances in Engineering Software

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This paper proposes a well-suited strategy for High Performance Computing (HPC) of density-based topology optimization using Graphics Processing Units (GPUs). Such a strategy takes advantage of Massively Parallel Processing (MPP) architectures to overcome the computationally demanding procedures of density-based topology design, both in terms of memory consumption and processing time. This is done exploiting data locality and minimizing both memory consumption and data transfers. The proposed GPU instance makes use of different granularities for the topology optimization pipeline, which are selected to properly balance the workload between the threads exploiting the parallelization potential of massive parallel architectures. The performance of the fine-grained GPU instance of the solving stage is evaluated using two preconditioning techniques. The proposal is also compared with the classical CPU implementation for diverse topology optimization problems, including stiffness maximization, heat sink design and compliant mechanism design.

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“…Due to the limitation of computing power and memory space, the traditional computer cannot meet the requirements of large‐scale structural analyses . As a result, supercomputers with many processors and memories are employed …”

Section: Introductionmentioning

confidence: 99%

An approach to enhance the performance of large‐scale structural analysis on CPU‐MIC heterogeneous clusters

Miao

Jin

Ding

2016

Concurrency and Computation

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Summary Clusters with the CPU‐MIC heterogeneous architecture are becoming more popular in recent years. However, it is not easy to achieve good performance on such machines. The key challenge has been the asymmetry within clusters, arising from different kinds of execution units as well as different communication latencies. To improve the performance of large‐scale structural analysis on CPU‐MIC heterogeneous clusters, a multi‐layer and multi‐grain collaborative parallel computing approach is proposed in the paper. The proposed method combines the parallel algorithm and the hardware architecture of CPU‐MIC heterogeneous clusters together. Through mapping computing tasks to various hardware layers, it both resolves the load balance problem between CPU and MIC devices and significantly reduces the communication overheads of the system. Numerical experiments conducted on Tianhe‐2 supercomputer show that the proposed method obtained better performance compared with the traditional approach. Scalability investigation showed that the proposed method had good scalability with respect to problem sizes. The findings of this paper are of help to the parallel porting and performance optimization of other applications on CPU‐MIC heterogeneous clusters.

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An explicit dynamics GPU structural solver for thin shell finite elements

Cited by 20 publications

References 23 publications

Rupture risk in abdominal aortic aneurysms: A realistic assessment of the explicit GPU approach

Rupture risk in abdominal aortic aneurysms: A realistic assessment of the explicit GPU approach

Efficient topology optimization using GPU computing with multilevel granularity

An approach to enhance the performance of large‐scale structural analysis on CPU‐MIC heterogeneous clusters

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