Abstract
Seismic inversion is a process to obtain the spatial structure and physical properties of underground rock formations using surface acquired seismic data, constrained by known geological laws and drilling and logging data. The principle of seismic inversion based on deep learning is to learn the mapping between seismic data and rock properties by training a neural network using logging data as labels. However, due to high cost, the number of logging curves is often limited, leading to a trained model with poor generalization. Multi-task learning (MTL) provides an effective way to mitigate this problem. Learning multiple related tasks at the same time can improve the generalization ability of the model, thereby improving the performance of the main task on the same amount of labeled data. However, the performance of multi-task learning is highly dependent on the relative weights for the loss of each task, and manual tuning of the weights is often time-consuming and laborious. In this paper, a Fully Convolutional Residual Network (FCRN) is proposed to achieve seismic impedance inversion and seismic data reconstruction simultaneously, and a method based on the homoscedastic uncertainty of the Bayesian model is used to balance the weights of the loss function for the two tasks. The test results on the synthetic datasets of Marmousi2, Overthrust, and Volve field data show that the proposed method can automatically determine the optimal weight of the two tasks, and predicts impedance with higher accuracy than single-task FCRN model.
Highlights
Received: 20 December 2021Reflection seismic exploration is used to detect changes in impedance in the subsurface through an active seismic source
We believe seismic recona task that is not limited to impedance inversion, and other deep learning tasks such as seisstruction is a task that is not limited to impedance inversion, and other deep learning struction is a task that is not limited to impedance inversion, and other deep learning faultsuch interpretation can benefit inbenefit similar way
We propose a multi-task network for both impedance inversion and aseismic
Summary
Received: 20 December 2021Reflection seismic exploration is used to detect changes in impedance in the subsurface through an active seismic source. Seismic inversion refers to the process of estimating the properties of underground rocks using surface acquired seismic data. Classical seismic inversion methods usually start with a smooth model of underground properties, and perform forward simulation to generate synthetic seismic data. Due to the increased complexity of the subsurface structures, and the difficulty in obtaining a good initial model to converge to the high-resolution target model for conventional methods, advanced techniques are required for effective and efficient seismic inversion. With the successes of deep learning in the computer vision community, time series forecasting [2], and natural language processing, researchers have developed various data-driven seismic inversion techniques. The amount of available seismic data is growing exponentially and the deep learning methods are becoming integral components of geophysical exploration workflows [3], such as P-wave detection [4], seismic fault detection [5,6,7,8], seismic data noise attenuation [9,10], seismic data interpolation [11,12,13,14,15], and seismic slope estimation [16]
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