Thesis Abstract

Abstract
This thesis investigates the Implementation of LiDAR Technology for 3D Mapping in Urban Environments. LiDAR (Light Detection and Ranging) technology has emerged as a powerful tool for capturing detailed spatial data in various applications, including urban planning, infrastructure development, and environmental monitoring. The study focuses on the utilization of LiDAR technology to create high-resolution 3D maps of urban areas, enabling accurate visualization and analysis of the built environment. The introductory chapter provides an overview of the research topic, highlighting the significance of 3D mapping in urban environments and the role of LiDAR technology in this context. The background of the study discusses the evolution of LiDAR technology, its principles of operation, and its advantages over traditional surveying methods. The problem statement identifies the challenges and limitations faced in conventional mapping approaches and emphasizes the need for advanced technologies like LiDAR to overcome these constraints. The objectives of the study are to explore the capabilities of LiDAR technology for 3D mapping in urban environments, assess its accuracy and efficiency, and evaluate its potential for enhancing urban planning and development processes. The limitations of the study are also outlined, including technical constraints, data processing challenges, and cost implications. The scope of the study defines the geographical area and the specific aspects of urban mapping that will be addressed. The literature review chapter presents a comprehensive analysis of existing research and developments in LiDAR technology for urban mapping. Topics covered include LiDAR data acquisition methods, data processing techniques, applications in urban planning and infrastructure management, and case studies demonstrating the effectiveness of LiDAR in various urban contexts. The research methodology chapter describes the approach and procedures adopted in this study, including data collection methods, LiDAR data processing workflows, software tools utilized, and quality control measures implemented. The chapter also discusses the selection of study areas, data acquisition parameters, and validation techniques employed to assess the accuracy of the 3D maps generated using LiDAR technology. The findings chapter presents the results of the study, including the 3D maps created using LiDAR data, accuracy assessments, and comparisons with ground truth data. The discussion section analyzes the implications of the findings, highlights the strengths and limitations of LiDAR technology for urban mapping, and suggests potential areas for further research and development. The conclusion and summary chapter provide a summary of the key findings, conclusions drawn from the study, and recommendations for future research and practical applications of LiDAR technology in urban environments. The thesis contributes to the growing body of knowledge on the implementation of LiDAR technology for 3D mapping in urban areas, showcasing its potential to revolutionize urban planning and development processes.

Thesis Overview