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KD-INR: Time-Varying Volumetric Data Compression via Knowledge Distillation-Based Implicit Neural Representation

Jun Han, Hao Zheng, Chongke Bi

2023IEEE Transactions on Visualization and Computer Graphics14 citationsDOI

Abstract

Traditional deep learning algorithms assume that all data is available during training, which presents challenges when handling large-scale time-varying data. To address this issue, we propose a data reduction pipeline called knowledge distillation-based implicit neural representation (KD-INR) for compressing large-scale time-varying data. The approach consists of two stages: spatial compression and model aggregation. In the first stage, each time step is compressed using an implicit neural representation with bottleneck layers and features of interest preservation-based sampling. In the second stage, we utilize an offline knowledge distillation algorithm to extract knowledge from the trained models and aggregate it into a single model. We evaluated our approach on a variety of time-varying volumetric data sets. Both quantitative and qualitative results, such as PSNR, LPIPS, and rendered images, demonstrate that KD-INR surpasses the state-of-the-art approaches, including learning-based (i.e., CoordNet, NeurComp, and SIREN) and lossy compression (i.e., SZ3, ZFP, and TTHRESH) methods, at various compression ratios ranging from hundreds to ten thousand.

Topics & Concepts

Computer scienceData compressionLossy compressionArtificial intelligenceBottleneckCompression (physics)Pipeline (software)Compression ratioArtificial neural networkRepresentation (politics)Pattern recognition (psychology)Machine learningData miningAutomotive engineeringLawMaterials scienceComposite materialProgramming languagePolitical sciencePoliticsEmbedded systemInternal combustion engineEngineeringGenerative Adversarial Networks and Image SynthesisAdvanced Image Processing TechniquesImage and Signal Denoising Methods
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