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SparseTFNet: A Physically Informed Autoencoder for Sparse Time–Frequency Analysis of Seismic Data

Yang Yang, Youbo Lei, Naihao Liu, Zhiguo Wang, Jinghuai Gao, Jicai Ding

2022IEEE Transactions on Geoscience and Remote Sensing32 citationsDOI

Abstract

The time-frequency (TF) analysis is an effective tool in seismic signal processing. The sparsity-based TF transforms have been widely used to obtain high localized TF representations in recent past years. These TF transforms formulate a sparse TF representation as an inverse optimization problem using simple mathematical models, which are typically based on a hand-crafted prior knowledge. Unlike the traditional sparsity-based TF transforms, the supervised deep learning (DL)-based sparse TF representations don’t require this prior knowledge and instead use a large amount of labeled data set, which is difficult to label for seismic data. In this study, to bridge the gap between the traditional sparsity-based transforms and the supervised DL-based transforms, we propose a DL-based sparse TF analysis approach based on a physically informed autoencoder model, named the SparseTFNet. The proposed SparseTFNet includes two modules: a convolutional neural networks (CNN)-based encoder and a traditional inverse TF representation-based decoder. The CNN-based encoder is implemented by training the inverse optimization problem in the absence of the “ground-truth" TF representation, which can be trained with only seismic traces. The traditional inverse short time Fourier transform (STFT) is utilized as the decoder module in this study, which is used as a physical constraint to ensure the high accuracy of the calculated TF representation. Finally, after training and validating the proposed model using the noise-free and noisy synthetic seismic traces, the model is applied to three-dimensional (3D) offshore seismic data. The results show that the proposed SparseTFNet model has good performance in the delineation of the depositional fluvial channels.

Topics & Concepts

AutoencoderComputer scienceSparse approximationConvolutional neural networkArtificial intelligencePattern recognition (psychology)Inverse problemTime–frequency analysisDeep learningShort-time Fourier transformSynthetic dataAlgorithmFourier transformMathematicsComputer visionFourier analysisFilter (signal processing)Mathematical analysisSeismic Imaging and Inversion TechniquesSeismic Waves and AnalysisUnderwater Acoustics Research