Neural Data Compression for Physics Plasma Simulation
Abstract
We present a VAE-based data compression method, called VAe Physics Optimized Reduction (VAPOR), to compress scientific data while preserving physics constraints. VAPOR is based on Vector Quantized Variational Auto Encoder (VQ-VAE) and extended with physics-informed optimization functions and refinement layers, focusing on compressing and reconstructing scientific data with minimum loss of information under physics constraints. We demonstrate VAPOR by using outputs from XGC, a massively parallel fusion simulation code running on the largest supercomputers. Key features of VAPOR are three-fold; i) find a reduced representation of physics data, ii) reconstruct the data with a minimum loss, iii) preserve physics information (e.g., mass, energy, moment conservation). We discuss challenges in XGC 5D data reconstruction and present our initial experiences and results on how we construct Deep Neural Network (DNN) of VAPOR to optimize the reconstruction quality of XGC data and integrate XGC’s physics constraints.
Cite
Text
Choi et al. "Neural Data Compression for Physics Plasma Simulation." ICLR 2021 Workshops: Neural_Compression, 2021.Markdown
[Choi et al. "Neural Data Compression for Physics Plasma Simulation." ICLR 2021 Workshops: Neural_Compression, 2021.](https://mlanthology.org/iclrw/2021/choi2021iclrw-neural/)BibTeX
@inproceedings{choi2021iclrw-neural,
title = {{Neural Data Compression for Physics Plasma Simulation}},
author = {Choi, Jong and Churchill, Michael and Gong, Qian and Ku, Seung-Hoe and Lee, Jaemoon and Rangarajan, Anand and Ranka, Sanjay and Pugmire, Dave and Chang, Cs and Klasky, Scott},
booktitle = {ICLR 2021 Workshops: Neural_Compression},
year = {2021},
url = {https://mlanthology.org/iclrw/2021/choi2021iclrw-neural/}
}