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Fault-tolerant Quantum Chemical Calculations with Improved Machine-Learning Models

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arxiv 2401.09484 v3 pith:GQFUV4DC submitted 2024-01-16 physics.chem-ph

Fault-tolerant Quantum Chemical Calculations with Improved Machine-Learning Models

classification physics.chem-ph
keywords calculationschemicalcodedcomputationalexcitedfaultfurtherimprove
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Easy and effective usage of computational resources is crucial for scientific calculations. Following our recent work of machine-learning (ML) assisted scheduling optimization [Ref: J. Comput. Chem. 2023, 44, 1174], we further propose 1) the improve ML models for the better predictions of computational loads, and as such, more elaborate load-balancing calculations can be expected; 2) the idea of coded computation, i.e. the integration of gradient coding, in order to introduce fault tolerance during the distributed calculations; and 3) their applications together with re-normalized exciton model with time-dependent density functional theory (REM-TDDFT) for calculating the excited states. Illustrated benchmark calculations include P38 protein, and solvent model with one or several excitable centers. The results show that the improved ML-assisted coded calculations can further improve the load-balancing and cluster utilization, and owing primarily profit in fault tolerance that aiming at the automated quantum chemical calculations for both ground and excited states.

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