A Survey of Machine Learning Applications in Microseismic Signal Recognition and Classification

EasyChair Preprint no. 11340

Abstract

Effective microseismic event identification and classification form the bedrock of data analysis in microseismic monitoring systems, facilitating real-time source location, rock-burst prediction, and mine safety. However, the complex mining environment necessitates preprocessing of sensor-collected microseismic signal data, plagued by noise. Traditional methods often yield inaccurate results when events exhibit similar traits. Machine learning's high precision separation proves promising, anticipating safety alerts by learning historical microseismic event patterns, and applying them to real-time data for predictive analysis. This approach mitigates inefficiencies and errors associated with manual recognition. Hence, machine learning has gained substantial traction in microseismic monitoring. This paper reviews recent machine learning applications in microseismic signal recognition and classification, addressing limitations of traditional methods, highlighting developmental disparities, presenting machine learning-based categorization, and summarizing advancements in signal recognition models. Lastly, the potential and challenges of machine learning in microseismic signal recognition are discussed.

Keyphrases: classification and recognition, event waveforms, image recognition, machine learning, microseismic signals

@Booklet{EasyChair:11340,
  author = {Hongmei Shu and Ahmad Yahya Dawod and Lei Mu and Worawit Tepsan},
  title = {A Survey of Machine Learning Applications in Microseismic Signal Recognition and Classification},
  howpublished = {EasyChair Preprint no. 11340},

  year = {EasyChair, 2023}}