Thesis Abstract

Abstract
This thesis explores the implementation of Artificial Intelligence (AI) in the field of radiography to enhance diagnostic accuracy and efficiency. The integration of AI technologies in radiography has the potential to revolutionize the way medical imaging is interpreted and analyzed, leading to improved patient outcomes and streamlined workflows in healthcare settings. This research investigates the current landscape of AI applications in radiography, identifies the challenges and opportunities associated with their implementation, and proposes strategies to optimize their use for enhancing diagnostic accuracy and efficiency. The study begins with a comprehensive introduction that outlines the background of the research, presents the problem statement, objectives, limitations, scope, significance, and structure of the thesis. The introduction also provides definitions of key terms relevant to the study to ensure clarity and understanding of the concepts discussed throughout the research. Chapter Two delves into a detailed literature review that explores ten key areas related to the implementation of AI in radiography. This section provides a thorough analysis of existing research, methodologies, technologies, and best practices in the field, offering insights into the current state of AI applications in radiography and their impact on diagnostic accuracy and efficiency. Chapter Three focuses on the research methodology employed in this study, outlining eight key components such as research design, data collection methods, sampling techniques, data analysis procedures, and ethical considerations. The chapter describes how the research was conducted to investigate the implementation of AI in radiography and evaluate its effects on diagnostic accuracy and efficiency. Chapter Four presents an elaborate discussion of the research findings, highlighting the key insights, trends, and implications derived from the analysis of the data collected. This section explores the impact of AI technologies on radiography practices, identifies the benefits and challenges associated with their implementation, and proposes recommendations for optimizing their use in healthcare settings. Finally, Chapter Five offers a comprehensive conclusion and summary of the project thesis, summarizing the key findings, discussing their significance, and outlining the implications for future research and practice in the field of radiography. The conclusion also highlights the contributions of this study to the existing body of knowledge and suggests areas for further exploration and development in the integration of AI technologies in radiography. In conclusion, this thesis provides a comprehensive examination of the implementation of Artificial Intelligence in radiography to enhance diagnostic accuracy and efficiency. By leveraging AI technologies effectively, healthcare professionals can improve the quality of patient care, optimize resource utilization, and advance the field of radiography towards a more data-driven and evidence-based practice.

Thesis Overview