In modern agricultural societies, smart farm systems that allow for both autonomous and manual adjustment of farming environments are increasingly being adopted. These systems contribute to improved productivity by enabling real-time monitoring of crop conditions and reducing the labor burden on farmers through automated control. Consequently, many farmers from various socioeconomic backgrounds have begun implementing smart farming technologies. However, a growing number of these users find it difficult to fully experience the expected convenience and efficiency, and due to the high initial installation costs and disappointing outcomes, many farmers are withdrawing their facilities. For smart farm projects to succeed and be widely accepted, it is essential not only to provide the technology but also to enable farmers to understand and experience its efficiency firsthand. This study proposes a simulation system designed to allow users to manually adjust the types of smart farm facilities installed based on varying levels of investment budgets. The simulation offers a virtual environment in which users can indirectly experience the functions of a smart farm system, and it provides tools to analyze and compare the efficiency and impact of each component quantitatively. Through this experience, members of agricultural communities will gain a deeper understanding of the practical value and necessity of smart farming technologies. Ultimately, this approach aims to reduce the barriers to adoption, promote the sustainable implementation of smart farming solutions, and support the development of a more efficient and resilient agricultural infrastructure.In modern agricultural societies, smart farm systems that allow for both autonomous and manual adjustment of farming environments are increasingly being adopted. These systems contribute to improved productivity by enabling real-time monitoring of crop conditions and reducing the labor burden on farmers through automated control. Consequently, many farmers from various socioeconomic backgrounds have begun implementing smart farming technologies. However, a growing number of these users find it difficult to fully experience the expected convenience and efficiency, and due to the high initial installation costs and disappointing outcomes, many farmers are withdrawing their facilities. For smart farm projects to succeed and be widely accepted, it is essential not only to provide the technology but also to enable farmers to understand and experience its efficiency firsthand. This study proposes a simulation system designed to allow users to manually adjust the types of smart farm facilities installed based on varying levels of investment budgets. The simulation offers a virtual environment in which users can indirectly experience the functions of a smart farm system, and it provides tools to analyze and compare the efficiency and impact of each component quantitatively. Through this experience, members of agricultural communities will gain a deeper understanding of the practical value and necessity of smart farming technologies. Ultimately, this approach aims to reduce the barriers to adoption, promote the sustainable implementation of smart farming solutions, and support the development of a more efficient and resilient agricultural infrastructure.