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DeepCQ: General-Purpose Deep-Surrogate Framework for Lossy Compression Quality Prediction

Machine Learning 2025-12-29 v1 Distributed, Parallel, and Cluster Computing Performance

Abstract

Error-bounded lossy compression techniques have become vital for scientific data management and analytics, given the ever-increasing volume of data generated by modern scientific simulations and instruments. Nevertheless, assessing data quality post-compression remains computationally expensive due to the intensive nature of metric calculations. In this work, we present a general-purpose deep-surrogate framework for lossy compression quality prediction (DeepCQ), with the following key contributions: 1) We develop a surrogate model for compression quality prediction that is generalizable to different error-bounded lossy compressors, quality metrics, and input datasets; 2) We adopt a novel two-stage design that decouples the computationally expensive feature-extraction stage from the light-weight metrics prediction, enabling efficient training and modular inference; 3) We optimize the model performance on time-evolving data using a mixture-of-experts design. Such a design enhances the robustness when predicting across simulation timesteps, especially when the training and test data exhibit significant variation. We validate the effectiveness of DeepCQ on four real-world scientific applications. Our results highlight the framework's exceptional predictive accuracy, with prediction errors generally under 10\% across most settings, significantly outperforming existing methods. Our framework empowers scientific users to make informed decisions about data compression based on their preferred data quality, thereby significantly reducing I/O and computational overhead in scientific data analysis.

Keywords

Cite

@article{arxiv.2512.21433,
  title  = {DeepCQ: General-Purpose Deep-Surrogate Framework for Lossy Compression Quality Prediction},
  author = {Khondoker Mirazul Mumenin and Robert Underwood and Dong Dai and Jinzhen Wang and Sheng Di and Zarija Lukić and Franck Cappello},
  journal= {arXiv preprint arXiv:2512.21433},
  year   = {2025}
}
R2 v1 2026-07-01T08:40:28.887Z