Thesis Abstract

Abstract
This thesis presents a comprehensive investigation into the utilization of Ground Penetrating Radar (GPR) data for mapping subsurface features. The study focuses on the application of GPR technology in geophysics to enhance the understanding of the subsurface environment. The research aims to explore the efficacy of GPR as a non-invasive geophysical method for mapping underground structures and features. Chapter One provides an introduction to the research topic, detailing the background of the study, the problem statement, objectives, limitations, scope, significance, structure of the thesis, and definitions of key terms. The chapter sets the foundation for the subsequent chapters by establishing the context and rationale for the research. Chapter Two comprises a comprehensive literature review that examines existing studies, methodologies, and applications of GPR technology in geophysics. The chapter delves into various aspects of GPR data acquisition, processing, and interpretation techniques used for subsurface mapping. It also explores the benefits and limitations of GPR technology in different geological settings. Chapter Three presents the research methodology employed in this study, detailing the data collection process, equipment used, data processing techniques, and analytical methods. The chapter outlines the steps taken to acquire and analyze GPR data for mapping subsurface features and provides insights into the decision-making processes involved in the research. Chapter Four is dedicated to a detailed discussion of the findings obtained from the analysis of GPR data for mapping subsurface features. The chapter presents the results of the study, including the identification and characterization of underground structures, anomalies, and geological features using GPR technology. It also discusses the challenges encountered during data interpretation and the implications of the findings on geophysical exploration. Chapter Five offers a conclusion and summary of the thesis, highlighting the key findings, implications, and recommendations for future research. The chapter reflects on the significance of the study in advancing the understanding of subsurface mapping using GPR technology and offers insights into potential areas for further investigation and development. In conclusion, this thesis contributes to the field of geophysics by demonstrating the effectiveness of Ground Penetrating Radar (GPR) data for mapping subsurface features. The research findings highlight the potential of GPR technology as a valuable tool for non-invasive subsurface exploration and provide valuable insights for geoscientists, researchers, and practitioners in the field.

Thesis Overview

The project titled "Analysis of Ground Penetrating Radar (GPR) data for mapping subsurface features" aims to explore the potential of Ground Penetrating Radar (GPR) as a geophysical tool for mapping subsurface features in various environments. This research overview provides a comprehensive explanation of the project, its significance, objectives, methodology, and expected outcomes. **Significance of the Project:** Ground Penetrating Radar (GPR) is a non-destructive geophysical technique that has gained significant attention in recent years for its ability to provide high-resolution subsurface imaging. By analyzing GPR data, researchers and professionals can detect and map various subsurface features such as utilities, archaeological artifacts, geological structures, and soil properties. This project seeks to leverage the capabilities of GPR to enhance subsurface mapping accuracy and efficiency in different applications. **Objectives of the Project:** The primary objective of this project is to investigate the effectiveness of GPR data analysis for mapping subsurface features. Specific objectives include: 1. To review existing literature on GPR technology and its applications in subsurface feature mapping. 2. To collect GPR data in different field settings to represent a variety of subsurface conditions. 3. To develop data processing techniques for enhancing the interpretation of GPR data. 4. To analyze the processed GPR data to identify and map subsurface features accurately. 5. To compare the results of GPR data analysis with ground truth data to validate the mapping accuracy. **Methodology:** The research methodology for this project involves a multi-step approach to data collection, processing, analysis, and validation. Field surveys will be conducted using GPR equipment in diverse environments to capture subsurface data. The collected GPR data will then undergo preprocessing to remove noise and enhance signal quality. Data analysis techniques, including signal processing algorithms and imaging software, will be applied to interpret the subsurface features. **Expected Outcomes:** Through the systematic analysis of GPR data, this project aims to achieve the following outcomes: 1. Improved understanding of the capabilities and limitations of GPR technology for subsurface mapping. 2. Development of data processing techniques to enhance the interpretation of GPR data. 3. Accurate mapping of subsurface features in various field settings. 4. Validation of GPR data analysis results through comparison with ground truth data. 5. Contribution to the advancement of geophysical methods for subsurface feature mapping. In conclusion, the project "Analysis of Ground Penetrating Radar (GPR) data for mapping subsurface features" holds great potential to expand our knowledge of subsurface imaging techniques and their practical applications. By exploring the capabilities of GPR technology and developing innovative data analysis methods, this research aims to contribute to the field of geophysics and enhance the accuracy and efficiency of subsurface feature mapping.