Thesis Abstract

Abstract
This thesis explores the application of artificial intelligence (AI) in automated image processing for radiographic diagnosis. The field of radiography plays a crucial role in modern healthcare by providing vital diagnostic imaging for medical conditions. However, the interpretation of radiographic images can be complex and time-consuming for radiologists. The integration of AI technology has the potential to revolutionize radiographic diagnosis by enhancing the accuracy and efficiency of image analysis. This research project aims to investigate the development and implementation of AI algorithms for automated image processing in radiography. The study begins with an introduction to the background of the research, highlighting the importance of radiographic diagnosis in medical practice. The problem statement identifies the challenges faced in traditional image processing methods and emphasizes the need for AI solutions. The objectives of the study are outlined to guide the research process towards achieving specific goals, such as improving diagnostic accuracy and reducing interpretation time. The limitations and scope of the study are also discussed to provide a clear understanding of the research boundaries. A comprehensive literature review is conducted in Chapter Two, which examines existing research on AI applications in radiography and automated image processing. The review covers various aspects of AI technology, including machine learning algorithms, deep learning models, and computer vision techniques. By analyzing previous studies, this chapter aims to build a theoretical foundation for the development of AI solutions in radiographic diagnosis. Chapter Three details the research methodology employed in this study, outlining the process of data collection, image preprocessing, algorithm development, and evaluation metrics. The methodology includes the selection of radiographic datasets, the training of AI models, and the validation of results to ensure the effectiveness of the proposed algorithms. Various components of the research methodology, such as data augmentation techniques and model optimization strategies, are discussed to provide insights into the experimental process. In Chapter Four, the findings of the research are presented and discussed in detail. The results of the AI algorithms for automated image processing are evaluated based on performance metrics, such as accuracy, sensitivity, and specificity. The discussion focuses on the strengths and limitations of the developed models, highlighting areas for improvement and future research directions. The implications of the findings for clinical practice and the potential impact on radiographic diagnosis are also examined. Finally, Chapter Five concludes the thesis by summarizing the key findings and contributions of the research. The significance of the study is highlighted, emphasizing the benefits of AI-driven automated image processing in radiography. Recommendations for future research and practical implications for healthcare professionals are provided to guide further advancements in the field. Overall, this thesis contributes to the ongoing efforts to enhance radiographic diagnosis through the integration of AI technology in automated image processing. Keywords Artificial Intelligence, Radiography, Automated Image Processing, Machine Learning, Deep Learning, Medical Imaging.

Thesis Overview