Thesis Abstract

Abstract
The application of Ground Penetrating Radar (GPR) in Archaeological Site Mapping has emerged as a valuable tool in modern geophysics, offering non-invasive and high-resolution imaging capabilities for subsurface investigations. This thesis explores the effectiveness of GPR technology in mapping archaeological sites, with a focus on its potential to enhance the understanding of buried structures and artifacts. The research encompasses a comprehensive literature review, methodological approach, and discussion of findings to provide valuable insights into the practical application of GPR in archaeology. Chapter One Introduction 1.1 Introduction 1.2 Background of Study 1.3 Problem Statement 1.4 Objective of Study 1.5 Limitation of Study 1.6 Scope of Study 1.7 Significance of Study 1.8 Structure of the Thesis 1.9 Definition of Terms Chapter Two Literature Review 2.1 Overview of Ground Penetrating Radar Technology 2.2 Historical Context of Archaeological Site Mapping 2.3 Previous Applications of GPR in Archaeology 2.4 Challenges and Limitations in GPR Archaeological Surveys 2.5 Advances in GPR Data Processing and Interpretation 2.6 Comparative Analysis of GPR with Other Geophysical Techniques 2.7 Case Studies of Successful GPR Applications in Archaeology 2.8 Theoretical Framework for GPR Data Interpretation 2.9 Role of GPR in Preserving Cultural Heritage 2.10 Future Directions and Emerging Trends in GPR Archaeological Research Chapter Three Research Methodology 3.1 Selection of Study Area 3.2 Data Acquisition and Processing 3.3 Ground Truthing and Validation Techniques 3.4 Equipment Calibration and Field Procedures 3.5 Data Interpretation and Analysis 3.6 Integration of GPR Results with Other Survey Methods 3.7 Quality Control Measures 3.8 Ethical Considerations in Archaeological Surveys Chapter Four Discussion of Findings 4.1 Interpretation of GPR Data 4.2 Identification of Subsurface Features 4.3 Mapping of Archaeological Structures 4.4 Comparison with Ground Truthing Results 4.5 Evaluation of GPR Performance 4.6 Implications for Archaeological Site Management 4.7 Challenges and Recommendations for Future Research Chapter Five Conclusion and Summary In conclusion, this thesis demonstrates the potential of Ground Penetrating Radar as a valuable tool in Archaeological Site Mapping. The research findings highlight the effectiveness of GPR technology in enhancing the identification and mapping of buried structures and artifacts, thereby contributing to the preservation and understanding of cultural heritage. The study provides valuable insights for archaeologists, geophysicists, and heritage conservationists, paving the way for further advancements in non-invasive subsurface investigations. Keywords Ground Penetrating Radar, Archaeological Site Mapping, Geophysics, Cultural Heritage, Non-Invasive Survey, Subsurface Imaging, Data Interpretation

Thesis Overview

The project titled "Application of Ground Penetrating Radar in Archaeological Site Mapping" aims to explore the utilization of Ground Penetrating Radar (GPR) technology in the field of archaeological site mapping. Ground Penetrating Radar is a non-invasive geophysical method that uses radar pulses to image the subsurface features of the Earth. This technology has shown great potential in mapping archaeological sites by detecting buried structures, artifacts, and other archaeological remains without the need for excavation. The research will begin with an introduction that provides background information on the use of GPR in archaeology, highlighting its advantages and limitations. The problem statement will emphasize the challenges faced in traditional archaeological site mapping methods and how GPR can offer a more efficient and cost-effective solution. The objectives of the study will focus on evaluating the effectiveness of GPR in mapping archaeological sites, identifying best practices for data collection and analysis, and assessing the accuracy of GPR results compared to traditional excavation methods. The study will also address the limitations of using GPR in archaeological site mapping, such as depth restrictions, signal interference, and data interpretation challenges. The scope of the research will define the specific parameters and boundaries within which the study will be conducted, including the types of archaeological sites, geographical locations, and equipment used. Furthermore, the significance of the study lies in its potential to revolutionize archaeological site mapping practices by offering a non-destructive and efficient method for detecting and mapping buried features. The research findings will contribute valuable insights to the field of archaeology and geophysics, offering practical recommendations for the integration of GPR technology into archaeological research and conservation efforts. In conclusion, this project will provide a comprehensive overview of the application of Ground Penetrating Radar in archaeological site mapping, shedding light on the benefits, challenges, and future prospects of using this innovative technology in the field of archaeology.