利用自适应非结构化四面体网格联合反演势场数据

GEOPHYSICS Pub Date : 2024-02-06 DOI:10.1190/geo2023-0280.1
Hongzhu Cai, Ruijin Kong, Ziang He, Xinyu Wang, Shuang Liu, Sining Huang, M. A. Kass, Xiangyun Hu
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引用次数: 0

摘要

电位场数据的反演是一项重大挑战,因为它具有难以确定的性质,往往会导致非唯一的模型解。为了解决这个问题,我们的工作重点是为势场数据开发一种稳健的联合反演方法,旨在获得更精确的密度和磁感应强度分布。与之前大多数使用常规网格的工作不同,我们的方法采用了自适应非结构化四面体网格,增强了处理电位场方法反演问题的能力。在反演过程中,四面体网格会根据模型更新率进行细化。我们在目标函数中集成了格拉米安约束,允许在非结构化网格上以模型参数或其空间梯度来执行模型相似性。此外,我们采用移动最小二乘法计算梯度算子,这对模型正则化至关重要。我们的模型研究表明,这种方法能有效反演势场数据,得到可靠的地下密度和磁感应强度分布。与单个数据集反演相比,联合反演方法产生的地球物理模型连贯一致,相关性更强。值得注意的是,它大大缓解了非唯一性问题,恢复的异常点位置与实际地面情况更加接近。将我们的方法和算法应用于加拿大火环地区的实地数据,联合反演过程生成了具有强大相关性的综合地球物理模型,为该地区的矿产勘探提供了潜在的益处。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Joint Inversion of Potential Field Data with Adaptive Unstructured Tetrahedral Mesh
Inverting potential field data presents a significant challenge due to its ill-posed nature, often leading to non-unique model solutions. Addressing this, our work focuses on developing a robust joint inversion method for potential field data, aiming to achieve more accurate density and magnetic susceptibility distributions. Unlike most previous work that utilizes regular meshes, our approach adopts an adaptive unstructured tetrahedral mesh, offering enhanced capabilities in handling the inverse problem of potential field methods. During inversion, the tetrahedral mesh is refined in response to the model update rate. We integrate a Gramian constraint into the objective function, allowing enforcement of model similarity in terms of either model parameters or their spatial gradients on an unstructured mesh. Additionally, we employ the moving least-squares method for gradient operator computation, essential for model regularization. Our model studies indicate that this method effectively inverts potential field data, yielding reliable subsurface density and magnetic susceptibility distributions. The joint inversion approach, compared to individual dataset inversion, produces coherent geophysical models with enhanced correlations. Notably, it significantly mitigates the non-uniqueness problem, with the recovered anomaly locations aligning more closely with actual ground truths. Applying our methodology and algorithm to field data from the Ring of Fire area in Canada, the joint inversion process has generated comprehensive geophysical models with robust correlations, offering potential benefits for mineral exploration in the region.
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