Scientific Error-bounded Lossy Compression with Super-resolution Neural Networks

Jinyang Liu; Sheng Di; Sian Jin; Kai Zhao; Xin Liang; Zizhong Chen; Franck Cappello

doi:10.1109/BigData59044.2023.10386682

Scientific Error-bounded Lossy Compression with Super-resolution Neural Networks

Jinyang Liu
, Sheng Di
, Sian Jin
, Kai Zhao
, Xin Liang
, Zizhong Chen
, Franck Cappello

Producción científica: Conference contribution › revisión exhaustiva

10 Citas (Scopus)

Resumen

The fast growth of computational power and scales of modern super-computing systems have raised great challenges for the management of exascale scientific data. To maintain the usability of scientific data, error-bound lossy compression is proposed and developed as an essential technique for the size reduction of scientific data with constrained data distortion. Among the diverse datasets generated by various scientific simulations, certain datasets cannot be effectively compressed by existing error-bounded lossy compressors with traditional techniques. The recent success of Artificial Intelligence has inspired several researchers to integrate neural networks into error-bounded lossy compressors. However, those works still suffer from limited compression ratios and/or extremely low efficiencies. To address those issues and improve the compression on the hard-to-compress datasets, in this paper, we propose SRNNSZ, which is a deep learning-based scientific error-bounded lossy compressor leveraging the hierarchical data grid expansion paradigm implemented by super-resolution neural networks. SRNN-SZ applies the most advanced super-resolution network HAT for its compression, which is free of time-costing per-data training. In experiments compared with various state-of-the-art compressors, SRNN-SZ achieves up to 75% compression ratio improvements under the same error bound and up to 80% compression ratio improvements under the same PSNR than the second-best compressor.

Idioma original	English
Título de la publicación alojada	Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023
Editores	Jingrui He, Themis Palpanas, Xiaohua Hu, Alfredo Cuzzocrea, Dejing Dou, Dominik Slezak, Wei Wang, Aleksandra Gruca, Jerry Chun-Wei Lin, Rakesh Agrawal
Páginas	229-236
Número de páginas	8
ISBN (versión digital)	9798350324457
DOI	https://doi.org/10.1109/BigData59044.2023.10386682
Estado	Published - 2023
Evento	2023 IEEE International Conference on Big Data, BigData 2023 - Sorrento, Italy Duración: dic 15 2023 → dic 18 2023

Serie de la publicación

Nombre	Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023

Conference

Conference	2023 IEEE International Conference on Big Data, BigData 2023
País/Territorio	Italy
Ciudad	Sorrento
Período	12/15/23 → 12/18/23

Nota bibliográfica

Publisher Copyright:
© 2023 IEEE.

Financiación

ACKNOWLEDGMENTS This research was supported by the Exascale Computing Project (ECP), Project Number: 17-SC-20-SC, a collaborative effort of two DOE organizations – the Office of Science and the National Nuclear Security Administration, responsible for the planning and preparation of a capable exascale ecosystem, including software, applications, hardware, advanced system engineering and early testbed platforms, to support the nation’s exascale computing imperative. The material was supported by the U.S. Department of Energy, Office of Science, Advanced Scientific Computing Research (ASCR), under contract DE-AC02-06CH11357, and supported by the National Science Foundation under Grant OAC-2003709, OAC-2104023, OAC-2311875, OAC-2311877, and OAC-2153451. We acknowledge the computing resources provided on Bebop (operated by Laboratory Computing Resource Center at Argonne) and on Theta and JLSE (operated by Argonne Leadership Computing Facility).

Financiadores	Número del financiador
National Science Foundation Arctic Social Science Program	OAC-2003709, OAC-2311877, OAC-2311875, OAC-2153451, OAC-2104023
National Science Foundation Arctic Social Science Program
U.S. Department of Energy EPSCoR
Office of Science Programs
National Nuclear Security Administration
Advanced Scientific Computing Research	DE-AC02-06CH11357
Advanced Scientific Computing Research

ASJC Scopus subject areas

Artificial Intelligence
Computer Networks and Communications
Computer Science Applications
Information Systems
Information Systems and Management
Safety, Risk, Reliability and Quality

Acceder al documento

10.1109/BigData59044.2023.10386682

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Liu, J., Di, S., Jin, S., Zhao, K., Liang, X., Chen, Z., & Cappello, F. (2023). Scientific Error-bounded Lossy Compression with Super-resolution Neural Networks. En J. He, T. Palpanas, X. Hu, A. Cuzzocrea, D. Dou, D. Slezak, W. Wang, A. Gruca, J. C.-W. Lin, & R. Agrawal (Eds.), Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023 (pp. 229-236). (Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023). https://doi.org/10.1109/BigData59044.2023.10386682

Liu, Jinyang ; Di, Sheng ; Jin, Sian et al. / Scientific Error-bounded Lossy Compression with Super-resolution Neural Networks. Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023. editor / Jingrui He ; Themis Palpanas ; Xiaohua Hu ; Alfredo Cuzzocrea ; Dejing Dou ; Dominik Slezak ; Wei Wang ; Aleksandra Gruca ; Jerry Chun-Wei Lin ; Rakesh Agrawal. 2023. pp. 229-236 (Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023).

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abstract = "The fast growth of computational power and scales of modern super-computing systems have raised great challenges for the management of exascale scientific data. To maintain the usability of scientific data, error-bound lossy compression is proposed and developed as an essential technique for the size reduction of scientific data with constrained data distortion. Among the diverse datasets generated by various scientific simulations, certain datasets cannot be effectively compressed by existing error-bounded lossy compressors with traditional techniques. The recent success of Artificial Intelligence has inspired several researchers to integrate neural networks into error-bounded lossy compressors. However, those works still suffer from limited compression ratios and/or extremely low efficiencies. To address those issues and improve the compression on the hard-to-compress datasets, in this paper, we propose SRNNSZ, which is a deep learning-based scientific error-bounded lossy compressor leveraging the hierarchical data grid expansion paradigm implemented by super-resolution neural networks. SRNN-SZ applies the most advanced super-resolution network HAT for its compression, which is free of time-costing per-data training. In experiments compared with various state-of-the-art compressors, SRNN-SZ achieves up to 75\% compression ratio improvements under the same error bound and up to 80\% compression ratio improvements under the same PSNR than the second-best compressor.",

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Liu, J, Di, S, Jin, S, Zhao, K, Liang, X, Chen, Z & Cappello, F 2023, Scientific Error-bounded Lossy Compression with Super-resolution Neural Networks. En J He, T Palpanas, X Hu, A Cuzzocrea, D Dou, D Slezak, W Wang, A Gruca, JC-W Lin & R Agrawal (eds.), Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023. Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023, pp. 229-236, 2023 IEEE International Conference on Big Data, BigData 2023, Sorrento, Italy, 12/15/23. https://doi.org/10.1109/BigData59044.2023.10386682

Scientific Error-bounded Lossy Compression with Super-resolution Neural Networks. / Liu, Jinyang; Di, Sheng; Jin, Sian et al.
Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023. ed. / Jingrui He; Themis Palpanas; Xiaohua Hu; Alfredo Cuzzocrea; Dejing Dou; Dominik Slezak; Wei Wang; Aleksandra Gruca; Jerry Chun-Wei Lin; Rakesh Agrawal. 2023. p. 229-236 (Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023).

Producción científica: Conference contribution › revisión exhaustiva

TY - GEN

T1 - Scientific Error-bounded Lossy Compression with Super-resolution Neural Networks

AU - Liu, Jinyang

AU - Di, Sheng

AU - Jin, Sian

AU - Zhao, Kai

AU - Liang, Xin

AU - Chen, Zizhong

AU - Cappello, Franck

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N2 - The fast growth of computational power and scales of modern super-computing systems have raised great challenges for the management of exascale scientific data. To maintain the usability of scientific data, error-bound lossy compression is proposed and developed as an essential technique for the size reduction of scientific data with constrained data distortion. Among the diverse datasets generated by various scientific simulations, certain datasets cannot be effectively compressed by existing error-bounded lossy compressors with traditional techniques. The recent success of Artificial Intelligence has inspired several researchers to integrate neural networks into error-bounded lossy compressors. However, those works still suffer from limited compression ratios and/or extremely low efficiencies. To address those issues and improve the compression on the hard-to-compress datasets, in this paper, we propose SRNNSZ, which is a deep learning-based scientific error-bounded lossy compressor leveraging the hierarchical data grid expansion paradigm implemented by super-resolution neural networks. SRNN-SZ applies the most advanced super-resolution network HAT for its compression, which is free of time-costing per-data training. In experiments compared with various state-of-the-art compressors, SRNN-SZ achieves up to 75% compression ratio improvements under the same error bound and up to 80% compression ratio improvements under the same PSNR than the second-best compressor.

AB - The fast growth of computational power and scales of modern super-computing systems have raised great challenges for the management of exascale scientific data. To maintain the usability of scientific data, error-bound lossy compression is proposed and developed as an essential technique for the size reduction of scientific data with constrained data distortion. Among the diverse datasets generated by various scientific simulations, certain datasets cannot be effectively compressed by existing error-bounded lossy compressors with traditional techniques. The recent success of Artificial Intelligence has inspired several researchers to integrate neural networks into error-bounded lossy compressors. However, those works still suffer from limited compression ratios and/or extremely low efficiencies. To address those issues and improve the compression on the hard-to-compress datasets, in this paper, we propose SRNNSZ, which is a deep learning-based scientific error-bounded lossy compressor leveraging the hierarchical data grid expansion paradigm implemented by super-resolution neural networks. SRNN-SZ applies the most advanced super-resolution network HAT for its compression, which is free of time-costing per-data training. In experiments compared with various state-of-the-art compressors, SRNN-SZ achieves up to 75% compression ratio improvements under the same error bound and up to 80% compression ratio improvements under the same PSNR than the second-best compressor.

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KW - error-bounded lossy compression

KW - super-resolution

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M3 - Conference contribution

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BT - Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023

A2 - He, Jingrui

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Liu J, Di S, Jin S, Zhao K, Liang X, Chen Z et al. Scientific Error-bounded Lossy Compression with Super-resolution Neural Networks. En He J, Palpanas T, Hu X, Cuzzocrea A, Dou D, Slezak D, Wang W, Gruca A, Lin JCW, Agrawal R, editores, Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023. 2023. p. 229-236. (Proceedings - 2023 IEEE International Conference on Big Data, BigData 2023). doi: 10.1109/BigData59044.2023.10386682

Scientific Error-bounded Lossy Compression with Super-resolution Neural Networks

Resumen

Serie de la publicación

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