Prediction of laser beam spatial profiles in a high-energy laser facility by use of deep learning

Guardalben, M. J.; Goduguluri, L. N.; Mathur, A.; Wang, J.; Yadav, R.

doi:10.1364/OE.540193

Title: Prediction of laser beam spatial profiles in a high-energy laser facility by use of deep learning

Journal Article · 05 November 2024 · Optics Express

DOI: https://doi.org/10.1364/OE.540193 · OSTI ID:2476415

; Goduguluri, L. N.; Mathur, A.; Wang, J.; Yadav, R.

We adapt the significant advances achieved recently in the field of generative artificial intelligence/machine-learning to laser performance modeling in multipass, high-energy laser systems with application to high-shot-rate facilities relevant to inertial fusion energy. Advantages of neural-network architectures include rapid prediction capability, data-driven processing, and the possibility to implement such architectures within future low-latency, low-power consumption photonic networks. Four models were investigated that differed in their generator loss functions and utilized the U-Net encoder/decoder architecture with either a reconstruction loss alone or combined with an adversarial network loss. We achieved inference times of 1.3 ms for a 256 × 256 pixel near-field beam with errors in predicted energy of the order of 1% over most of the energy range. It is shown that prediction errors are significantly reduced by ensemble averaging the models with different weight initializations. These results suggest that including the temporal dimension in such models may provide accurate, real-time spatiotemporal predictions of laser performance in high-shot-rate laser systems.

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Sponsoring Organization:: USDOE National Nuclear Security Administration (NNSA)

Grant/Contract Number:: NA0004144

OSTI ID:: 2476415

Journal Information:: Optics Express, Journal Name: Optics Express Journal Issue: 24 Vol. 32; ISSN 1094-4087; ISSN OPEXFF

Publisher:: Optical Society of AmericaCopyright Statement

Country of Publication:: United States

Language:: English

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Title: Prediction of laser beam spatial profiles in a high-energy laser facility by use of deep learning

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