爆炸物
质点速度
地震波
地质学
瞬态(计算机编程)
衰减
信号(编程语言)
领域(数学)
非线性系统
振动
地震学
经验模型
地震计
能量(信号处理)
矢量场
岩土工程
色散体波
信号处理
预测建模
支持向量机
纵波
反射(计算机编程)
粒子(生态学)
机械
地震速度
岩石爆破
结构工程
消散
贝叶斯概率
工程类
波传播
应力场
人工神经网络
作者
Yanqi Song,Chuanpeng Liu,Zhixin Shao,Juntao Yang,Junjie Zheng,Zhibin Hao,Hang Fu
标识
DOI:10.1177/10775463261426227
摘要
To study the signal characteristics and vibration velocity attenuation mechanism of seismic wave in blasting roadway of deep stope, this study systematically analyzes the time-domain, frequency-domain, and instantaneous energy characteristics of seismic waves based on field monitoring data. The results indicate that blasting seismic waves exhibit multi-segmented time-domain characteristics, high-frequency components in the near field and low-frequency components in the far field in the frequency domain, as well as a dual-peak feature in instantaneous energy. By employing Butterworth signal processing techniques, the study successfully separates seismic waves induced by explosive loading and transient stress unloading, and develops a corresponding nonlinear fitting model. Based on dimensional analysis, a peak particle velocity (PPV) prediction model, BL-TU, was proposed, which comprehensively considers both explosive loading and transient unloading energy. Compared with the Sadov’s empirical formula, the BL-TU model offers a clearer physical interpretation and higher prediction accuracy. To further enhance predictive performance, a Bayesian optimization-based support vector regression model (BOA-SVR) was developed. The results demonstrate that the BL-TU and BOA-SVR models significantly outperform Sadov’s empirical formula in terms of prediction accuracy. These models provide an effective means for predicting peak particle velocity under complex deep geological conditions.
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