Thesis Abstract

Abstract
This thesis presents the design and implementation of a Smart Energy Management System (SEMS) for residential buildings. The increasing demand for energy efficiency and sustainability has led to the development of smart technologies aimed at optimizing energy consumption. The SEMS proposed in this study integrates advanced sensor technologies, data analytics, and control strategies to monitor, analyze, and manage energy usage in residential buildings. The introduction provides an overview of the motivation behind the research, highlighting the importance of energy management in reducing carbon emissions and promoting sustainable living. The background of the study explores existing literature on smart energy management systems and identifies gaps in current research that this study aims to address. The problem statement identifies the challenges faced in traditional energy management practices and sets the context for the proposed SEMS. The objectives of the study are outlined to guide the research process, focusing on the development of a cost-effective and user-friendly SEMS that can adapt to the dynamic energy needs of residential buildings. The limitations and scope of the study are discussed to provide clarity on the boundaries and constraints of the research. The significance of the study is highlighted, emphasizing the potential impact of the SEMS on reducing energy consumption, lowering utility costs, and enhancing overall comfort and convenience for residents. The structure of the thesis is outlined to provide a roadmap for the reader, detailing the organization of chapters and key sections within each chapter. Definitions of key terms are provided to clarify terminology used throughout the thesis. Chapter Two presents a comprehensive literature review on smart energy management systems, covering topics such as sensor technologies, data analytics, optimization algorithms, and control strategies. The review synthesizes current research findings and identifies best practices and emerging trends in the field of energy management for residential buildings. Chapter Three describes the research methodology adopted in the design and implementation of the SEMS. The chapter covers aspects such as system architecture, sensor selection, data collection methods, algorithm development, and system testing procedures. The methodology is structured to ensure the reliability and validity of the research findings. Chapter Four presents a detailed discussion of the findings from the implementation of the SEMS in a residential building pilot study. The chapter includes analysis of energy consumption patterns, performance evaluation of the SEMS, user feedback, and recommendations for future improvements. Chapter Five concludes the thesis by summarizing the key findings, highlighting the contributions of the study, and discussing implications for future research and practical applications. The conclusion reflects on the achievements and challenges encountered in the design and implementation of the SEMS and offers insights into the potential for scaling up the system for broader deployment in residential buildings. In conclusion, this thesis contributes to the field of smart energy management by presenting a novel SEMS designed specifically for residential buildings. The research findings demonstrate the feasibility and effectiveness of the SEMS in optimizing energy usage, reducing environmental impact, and enhancing user comfort and convenience. The study sets the stage for further research and innovation in smart energy management systems for sustainable living.

Thesis Overview