LS-DYNA is the world-leading explicit simulation code for modeling highly non-linear, short-duration dynamic events. Qarnot provides the massive parallel computing power required to handle these intensive calculations without infrastructure limits.
LS-DYNA simulations, especially for crashworthiness or ballistics, require hundreds of cores to run efficiently. Qarnot’s MPP (Massively Parallel Processing) optimized environment allows you to scale your models instantly, significantly reducing simulation time.
From fluid-structure interaction (FSI) to advanced material failure, LS-DYNA handles the most complex physics. Qarnot’s high-performance nodes ensure that your most detailed meshes are processed with maximum stability and speed.
Simulation needs often peak during design validation phases. Qarnot’s pay-as-you-go model allows you to access thousands of cores for your LS-DYNA workloads only when you need them, avoiding the overhead of maintaining an underutilized on-premise cluster.
LS-DYNA simulations, especially for crashworthiness or ballistics, require hundreds of cores to run efficiently. Qarnot’s MPP (Massively Parallel Processing) optimized environment allows you to scale your models instantly, significantly reducing simulation time.
From fluid-structure interaction (FSI) to advanced material failure, LS-DYNA handles the most complex physics. Qarnot’s high-performance nodes ensure that your most detailed meshes are processed with maximum stability and speed.
Simulation needs often peak during design validation phases. Qarnot’s pay-as-you-go model allows you to access thousands of cores for your LS-DYNA workloads only when you need them, avoiding the overhead of maintaining an underutilized on-premise cluster.
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