TY - GEN
T1 - Enhancing Seismic Post-stack Reconstruction with Diffusion Models
T2 - 2025 IEEE Statistical Signal Processing Workshop, SSP 2025
AU - Goyes-Penafiel, Paul
AU - Arguello, Henry
AU - Kamilov, Ulugbek S.
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - Seismic post-stack data often contains missing traces, affecting processing and interpretation. Deep learning methods, both supervised and unsupervised, have advanced reconstruction but face challenges in generalization and computational cost. We propose a reconstruction method that integrates a pre-trained generative diffusion model with Deep Image Prior (DIP) to ensure data consistency. The diffusion model captures the prior distribution of seismic images, generating realistic reconstructions, while DIP enforces structural consistency using the inherent properties of seismic data. Additionally, diffusion models enable uncertainty quantification by generating multiple samples, providing insights into reliability. Our approach demonstrates strong reconstruction performance on both field and synthetic seismic images, even in structurally complex and previously unseen scenarios. Compared to existing diffusion-based methods, our technique reduces neural function evaluations by up to 4x, significantly improving efficiency. This highlights its ability to handle high geological variability across different exploration targets while maintaining computational feasibility. Our implementation is available at https://github.com/PAULGOYES/CDDIP.git
AB - Seismic post-stack data often contains missing traces, affecting processing and interpretation. Deep learning methods, both supervised and unsupervised, have advanced reconstruction but face challenges in generalization and computational cost. We propose a reconstruction method that integrates a pre-trained generative diffusion model with Deep Image Prior (DIP) to ensure data consistency. The diffusion model captures the prior distribution of seismic images, generating realistic reconstructions, while DIP enforces structural consistency using the inherent properties of seismic data. Additionally, diffusion models enable uncertainty quantification by generating multiple samples, providing insights into reliability. Our approach demonstrates strong reconstruction performance on both field and synthetic seismic images, even in structurally complex and previously unseen scenarios. Compared to existing diffusion-based methods, our technique reduces neural function evaluations by up to 4x, significantly improving efficiency. This highlights its ability to handle high geological variability across different exploration targets while maintaining computational feasibility. Our implementation is available at https://github.com/PAULGOYES/CDDIP.git
KW - deep image prior
KW - diffusion models
KW - inverse problem
KW - seismic reconstruction
KW - uncertainty
UR - https://www.scopus.com/pages/publications/105012190594
U2 - 10.1109/SSP64130.2025.11073374
DO - 10.1109/SSP64130.2025.11073374
M3 - Conference contribution
AN - SCOPUS:105012190594
T3 - IEEE Workshop on Statistical Signal Processing Proceedings
SP - 86
EP - 90
BT - 2025 IEEE Statistical Signal Processing Workshop, SSP 2025
PB - IEEE Computer Society
Y2 - 8 June 2025 through 11 June 2025
ER -