A diffusion model framework with iterative refinement, adapter conditioning, and DPS-projection guidance generates elastic parameters consistent with multi-source conditions and improves seismic inversion predictions over baselines.
GeoVolDiff: Taming 3D Geological Volumes with Latent Diffusion
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abstract
Deep learning has become a prevailing paradigm across a wide range of geophysical applications. Yet most existing studies concentrate on methodological refinements -- novel network architectures, physics-informed constraints, or taskspecific loss functions -- while paying comparatively little attention to a more fundamental challenge of any data-driven approach: the availability and representativeness of high-quality training data. This limitation is especially pronounced in geophysics. Unlike computer vision, which benefits from large-scale, well-curated benchmarks such as ImageNet, comparably abundant and reliably labelled geophysical data are prohibitively expensive to acquire and, in most field settings, lack accessible ground-truth supervision. To alleviate this data deficiency, we propose GeoVolDiff, a generative framework for three-dimensional geological volumes. It comprises three coupled stages: (i) constructing a foundational training corpus through physics-based forward simulation; (ii) training a Latent Diffusion Model (LDM) to capture the statistical distribution of 3D geological structures; and (iii) synthesizing diverse, structurally plausible volumes at scale for downstream geophysical tasks. We examine the utility of the synthesized data on a representative downstream task, seismic impedance inversion. Without incorporating any additional physical or geological prior, inversion networks pre-trained exclusively on synthesized data attain competitive performance on both synthetic and field datasets, indicating that data synthesised by the generative model can serve as an effective surrogate for costly field-acquired labels.
fields
physics.geo-ph 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Multi-Condition Guided Diffusion Model for Controllable Elastic Parameter Synthesis
A diffusion model framework with iterative refinement, adapter conditioning, and DPS-projection guidance generates elastic parameters consistent with multi-source conditions and improves seismic inversion predictions over baselines.