Thesis Abstract

Abstract
This thesis investigates the application of Ground-Penetrating Radar (GPR) for subsurface imaging and characterization. The study aims to explore the effectiveness of GPR technology in providing detailed insights into the subsurface layers of various materials and environments. The research involves conducting field experiments using GPR equipment to collect data and analyze the results to assess the capabilities and limitations of this geophysical method. The introduction section provides an overview of the significance of subsurface imaging and characterization in various fields such as civil engineering, environmental science, and archaeology. The background of the study delves into the principles of GPR technology, highlighting its working mechanism and key components. The problem statement emphasizes the existing challenges in subsurface imaging and the need for advanced techniques like GPR to address these challenges. The objectives of the study include evaluating the accuracy and resolution of GPR in imaging subsurface structures, determining the depth penetration capabilities of GPR, and assessing the impact of different soil types and moisture levels on GPR results. The limitations of the study are acknowledged, including factors that may affect the quality of GPR data and interpretations. The scope of the study outlines the specific areas and materials targeted for investigation using GPR technology. The significance of the study lies in its potential to enhance subsurface imaging capabilities, leading to improved decision-making in various applications. The structure of the thesis is outlined to provide a roadmap for the reader, guiding them through the chapters and sections that present the research findings and analysis. Definitions of key terms related to GPR and subsurface imaging are provided to ensure clarity and understanding throughout the thesis. The literature review chapter explores existing research and studies on GPR technology, its applications, and advancements in subsurface imaging techniques. Various case studies and experiments are analyzed to understand the strengths and limitations of GPR in different scenarios. The research methodology chapter details the experimental setup, data collection procedures, and data analysis techniques employed in the study. The findings chapter presents a comprehensive discussion of the results obtained from the field experiments using GPR. The analysis includes the interpretation of GPR data, visualization of subsurface structures, and comparisons with ground truth information where available. The implications of the findings are discussed in relation to the research objectives and the broader context of subsurface imaging and characterization. In conclusion, this thesis demonstrates the potential of GPR technology for subsurface imaging and characterization, highlighting its capabilities in providing detailed and accurate insights into subsurface structures. The study contributes to the advancement of geophysical methods for non-destructive testing and evaluation of subsurface materials. Recommendations for future research and applications of GPR technology are provided based on the findings and analysis presented in this study.

Thesis Overview