Project Abstract

Abstract
Ground-Penetrating Radar (GPR) is a non-invasive geophysical method that has been widely used in various fields, including environmental studies, archaeology, and civil engineering. This research focuses on the application of GPR in mapping subsurface features, with a particular emphasis on its effectiveness, limitations, and significance in the field of geophysics. The introduction provides an overview of GPR technology, its principles, and its applications. The background of the study outlines the historical development of GPR and its evolution as a valuable tool for subsurface imaging. The problem statement highlights the challenges and limitations associated with traditional subsurface mapping techniques and the need for more advanced and efficient methods. The objectives of the study aim to investigate the capabilities of GPR in mapping subsurface features, evaluate its accuracy and resolution, and compare its results with other geophysical methods. The limitations of the study acknowledge the constraints and potential sources of error that may affect the GPR data interpretation. The scope of the study defines the boundaries and extent of the research, focusing on specific subsurface features and study areas. The significance of the study emphasizes the practical implications of using GPR in subsurface mapping, such as its potential for detecting buried utilities, archaeological artifacts, and geological structures. The structure of the research outlines the organization of the study, including the chapters and sections that will be covered. The literature review chapter provides a comprehensive overview of previous research and studies related to GPR applications in subsurface mapping. It examines the methodologies, findings, and limitations of existing studies to build a foundation for the current research. The research methodology chapter details the experimental design, data collection procedures, data processing techniques, and data analysis methods used in the study. It outlines the steps taken to conduct field surveys, acquire GPR data, and interpret the results accurately. The discussion of findings chapter presents the results of the GPR surveys, including the identification of subsurface features, the interpretation of data anomalies, and the comparison with ground truth data. It analyzes the strengths and weaknesses of GPR in mapping subsurface features and discusses the implications of the findings. In conclusion, this research project demonstrates the effectiveness of GPR as a valuable tool for mapping subsurface features. It highlights the advantages of using GPR technology, such as its non-invasiveness, high resolution, and rapid data acquisition capabilities. The study contributes to the growing body of knowledge on GPR applications in geophysics and provides insights for future research and practical applications in various fields.

Project Overview