Kavli Affiliate: Feng Wang
| First 5 Authors: Feng Wang, Hong Qiu, Yingying Huang, Xiaozhe Gu, Renfang Wang
| Summary:
Magnetotelluric (MT) forward modeling is fundamental for improving the
accuracy and efficiency of MT inversion. Neural operators (NOs) have been
effectively used for rapid MT forward modeling, demonstrating their promising
performance in solving the MT forward modeling-related partial differential
equations (PDEs). Particularly, they can obtain the electromagnetic field at
arbitrary locations and frequencies. In these NOs, the projection layers have
been dominated by multi-layer perceptrons (MLPs), which may potentially reduce
the accuracy of solution due to they usually suffer from the disadvantages of
MLPs, such as lack of interpretability, overfitting, and so on. Therefore, to
improve the accuracy of MT forward modeling with NOs and explore the potential
alternatives to MLPs, we propose a novel neural operator by extending the
Fourier neural operator (FNO) with Kolmogorov-Arnold network (EFKAN). Within
the EFKAN framework, the FNO serves as the branch network to calculate the
apparent resistivity and phase from the resistivity model in the frequency
domain. Meanwhile, the KAN acts as the trunk network to project the resistivity
and phase, determined by the FNO, to the desired locations and frequencies.
Experimental results demonstrate that the proposed method not only achieves
higher accuracy in obtaining apparent resistivity and phase compared to the NO
equipped with MLPs at the desired frequencies and locations but also
outperforms traditional numerical methods in terms of computational speed.
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