Thesis Abstract

Abstract
Unmanned Aerial Vehicles (UAVs) have revolutionized the field of surveying and geo-informatics by providing a cost-effective and efficient means of acquiring high-resolution spatial data. This thesis explores the integration of UAV technology for high-resolution mapping applications in surveying and geo-informatics. The study focuses on the use of UAVs to capture aerial imagery and generate accurate topographic maps and 3D models for various applications such as land surveying, urban planning, environmental monitoring, and disaster management. The research begins with an overview of the background of using UAVs in surveying and geo-informatics, highlighting the evolution of UAV technology, its benefits, and its applications in the field. The problem statement identifies the current challenges and limitations faced by traditional mapping methods and emphasizes the need for UAV integration to enhance data acquisition processes. The objectives of the study include assessing the accuracy and efficiency of UAV-based mapping, exploring the limitations of the technology, defining the scope of applications, and evaluating the significance of integrating UAVs in surveying and geo-informatics practices. In the literature review, ten key topics are discussed, covering the principles of UAV technology, photogrammetry, remote sensing, GIS integration, data processing techniques, accuracy assessment methods, regulatory considerations, and case studies demonstrating the successful implementation of UAVs in mapping projects. The research methodology section outlines the approach taken to collect and analyze data, including the selection of UAV equipment, flight planning procedures, data acquisition techniques, data processing software, and validation methods. The chapter also addresses ethical considerations, safety protocols, and compliance with aviation regulations. The discussion of findings chapter presents a detailed analysis of the data collected during UAV mapping missions, focusing on the accuracy of the generated maps and models, the efficiency of data processing workflows, and the challenges encountered during the project. The results highlight the advantages of using UAVs for high-resolution mapping, including increased spatial coverage, rapid data acquisition, and cost-effectiveness compared to traditional methods. The limitations of UAV technology, such as weather dependencies, flight restrictions, and data processing complexities, are also discussed. In the conclusion and summary chapter, the key findings of the study are summarized, emphasizing the importance of UAV integration for high-resolution mapping in surveying and geo-informatics. The significance of the research is highlighted in terms of its contributions to improving data acquisition processes, enhancing spatial data quality, and advancing mapping technologies in various fields. Recommendations for future research include exploring advanced UAV platforms, optimizing data processing algorithms, and addressing regulatory challenges to promote the widespread adoption of UAV technology in surveying and geo-informatics applications. Overall, this thesis provides valuable insights into the integration of UAVs for high-resolution mapping, showcasing the potential of UAV technology to transform traditional surveying and mapping practices and usher in a new era of spatial data acquisition and analysis in the field of surveying and geo-informatics.

Thesis Overview