Thesis Abstract

Abstract
This thesis explores the implementation of precision agriculture techniques to enhance crop yield in the face of a changing climate. With the increasing challenges posed by climate change on agriculture, there is a critical need to adopt innovative strategies to optimize crop production. Precision agriculture offers a promising approach by leveraging technology and data-driven solutions to improve efficiency and sustainability in farming practices. The primary objective of this study is to investigate the effectiveness of precision agriculture techniques in maximizing crop yield under changing climatic conditions. The introduction provides an overview of the background of the study, highlighting the growing concerns related to climate change impacts on agriculture and the need for sustainable solutions. The problem statement emphasizes the challenges faced by farmers in adapting to changing climate patterns and the limitations of traditional farming practices in achieving optimal crop yield. The objectives of the study are outlined to address the gap in research by evaluating the benefits of precision agriculture in mitigating climate risks and enhancing productivity. A comprehensive literature review in Chapter Two examines existing studies on precision agriculture and its applications in improving crop yield. The review encompasses ten key areas, including the principles of precision agriculture, technological tools and sensors, data analytics, decision support systems, and case studies demonstrating successful implementation of precision farming practices. Chapter Three delves into the research methodology employed to investigate the impact of precision agriculture techniques on crop yield. The methodology section includes detailed descriptions of the research design, data collection methods, sampling techniques, analysis procedures, and statistical tools utilized to evaluate the outcomes of the study. Additionally, the chapter discusses the variables considered in the research and the criteria for measuring crop yield improvements. Chapter Four presents a detailed discussion of the findings derived from the study, focusing on the effectiveness of precision agriculture techniques in optimizing crop yield under changing climatic conditions. The results highlight the benefits of adopting precision farming practices, such as improved resource management, enhanced crop monitoring, and increased yield potential. The discussion also addresses the challenges and limitations encountered during the implementation of precision agriculture solutions. Finally, Chapter Five provides a conclusion and summary of the thesis, emphasizing the significance of the research findings in the context of sustainable agriculture and climate resilience. The conclusion reflects on the implications of the study for farmers, policymakers, and stakeholders in the agriculture sector, emphasizing the importance of integrating precision agriculture techniques to enhance food security and environmental sustainability. Overall, this thesis contributes to the growing body of knowledge on precision agriculture and its role in achieving optimal crop yield in a changing climate. Keywords Precision agriculture, Crop yield, Climate change, Sustainable agriculture, Technology, Data analytics, Decision support systems.

Thesis Overview