Proxima

Abstract: Atomistic-scale simulations are prominent scientific applications that require the repetitive execution of a computationally expensive routine to calculate a system's potential energy. Prior work shows that these expensive routines can be replaced with a machinelearned surrogate approximation to accelerate the simulation at the expense of the overall accuracy. The exact balance of speed and accuracy depends on the specific configuration of the surrogatemodeling workflow and the science itself, and prior work l… Show more

“…The basic workflow sequences two steps: 1) surrogate training, 2) surrogate inference for addressing the target problem, potentially combined with some simulation runs when higher precision is needed. But some are pushing the logic one step further fusing these two steps into a single adaptive ensemble run where a steering logic, relying on shallow or deep learning, tries to improve the global workflow efficiency [9,83,88]. In this paper we focus on the deep surrogate training process (step 1), but our approach has all the necessary flexibility to be used in the fused workflow.…”

High Throughput Training of Deep Surrogates from Large Ensemble Runs

“…The basic workflow sequences two steps: 1) surrogate training, 2) surrogate inference for addressing the target problem, potentially combined with some simulation runs when higher precision is needed. But some are pushing the logic one step further fusing these two steps into a single adaptive ensemble run where a steering logic, relying on shallow or deep learning, tries to improve the global workflow efficiency [9,83,88]. In this paper we focus on the deep surrogate training process (step 1), but our approach has all the necessary flexibility to be used in the fused workflow.…”

High Throughput Training of Deep Surrogates from Large Ensemble Runs

Asynchronous Execution of Heterogeneous Tasks in ML-Driven HPC Workflows

Coupling streaming AI and HPC ensembles to achieve 100–1000× faster biomolecular simulations