Mine seismic source location via forward modeling of spherical waves in a multilayered horizontal or inclined medium

IF 3.9 2区 工程技术 Q3 ENERGY & FUELS
Shuai Wang, Zhaoxin Hu, Sha-sha Lu
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引用次数: 0

Abstract

Seismic source location is a classic inverse problem in seismology. In mathematical physics, inverse problems have multiple natural solutions. The objective of this study was to develop a generic theory and method of seeking the true solution from multiple solutions for the location of a coal mine seismic source in an idealized velocity structure model of a coal mine with a small scale and complex geological environment. Starting from the simplest velocity structure model, the complexity of the model gradually increased, until it approached the real velocity structure model, i.e., the multilayered horizontal and inclined velocity structure model, in order to find a generic method for solving the multi-solution inverse problem of coal mine seismic source location. Specifically, the wavefront distribution equation in a two-layer horizontal medium was derived and then expanded to any multi-layer horizontal medium. Based on this equation, a positive definite nonlinear equation system was established from the perspective of any observation system. The equation system contained four unknown variables of the spatiotemporal position of the seismic source. To determine the spatiotemporal parameters of the seismic source, nonlinear equations for four stations were required. To solve the nonlinear equation system, an initial iteration value was determined. In order to reduce the difficulty of determining the initial iteration value, the variable substitution method was used to reduce the number of location parameters. By rotating the original geodetic coordinate system of the station to be parallel and orthogonal to the medium interface, the wavefront method was extended to inclined medium. In conclusion, in this study, the problem of coal mine seismic source location in a multi-layer horizontal or inclined medium was effectively solved. The method proposed in this study provides a reference for solving the true solution from multiple solutions for the location of a coal mine seismic source in small-scale coal mines with complex geological environments.

Abstract Image

通过多层水平或倾斜介质中球面波的前向建模确定矿山震源位置
震源定位是地震学中一个典型的逆问题。在数学物理中,逆问题有多个自然解。本研究的目的是在规模较小、地质环境复杂的理想化煤矿速度结构模型中,建立一种从多解中寻求煤矿震源定位真解的通用理论和方法。从最简单的速度结构模型开始,逐渐增加模型的复杂度,直至接近真实的速度结构模型,即多层水平倾斜速度结构模型,从而找到解决煤矿震源定位多解逆问题的通用方法。具体而言,首先推导出两层水平介质中的波前分布方程,然后将其扩展到任何多层水平介质。在此方程的基础上,从任意观测系统的角度建立了一个正定非线性方程组。方程系统包含四个未知变量,即震源的时空位置。要确定震源的时空参数,需要四个台站的非线性方程。为了求解非线性方程组,需要确定初始迭代值。为了降低确定初始迭代值的难度,采用了变量替换法来减少位置参数的数量。通过旋转观测站的原始大地坐标系,使其与介质界面平行且正交,将波前法扩展到倾斜介质。总之,本研究有效地解决了多层水平或倾斜介质中的煤矿震源定位问题。本研究提出的方法为地质环境复杂的小型煤矿的煤矿震源定位提供了从多解中求解真解的参考。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Geomechanics and Geophysics for Geo-Energy and Geo-Resources
Geomechanics and Geophysics for Geo-Energy and Geo-Resources Earth and Planetary Sciences-Geophysics
CiteScore
6.40
自引率
16.00%
发文量
163
期刊介绍: This journal offers original research, new developments, and case studies in geomechanics and geophysics, focused on energy and resources in Earth’s subsurface. Covers theory, experimental results, numerical methods, modeling, engineering, technology and more.
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