Welcome to the School of Automation of Wuhan University of Technology!

Welcome to the School of Automation of Wuhan University of Technology!

Welcome to the School of Automation of Wuhan University of Technology!

Undergraduate programs
HomeUndergraduate programs

Automation Program

2025-05-29 15:42

The Automation Program at Wuhan University of Technology aims to cultivate high-quality technical and management professionals with:

  • Sound character, strong social responsibility, and professional ethics,

  • Solid professional knowledge and comprehensive literacy,

  • Proficiency in fundamental theories, technologies, and research methods of automation,

  • Capability to engage in scientific research, technological development, engineering design, technical services, and project management in automation and related fields,

  • Adaptability to national new economic development and industry needs, coupled with strong adaptability, innovative awareness, practical spirit, and international competitiveness.

  • Program Objectives for Graduates (5 Years After Graduation):

    1. Possess humanistic literacy and social responsibility, adhering to professional ethics and norms.

    2. Demonstrate competence in system/engineering design, equipment R&D, technological transformation, production organization, and technical management in automation and related industries, with competitive advantages.

    3. Exhibit project management capabilities and serve effectively as a key member or leader in multidisciplinary teams.

    4. Continuously expand and enhance knowledge and skills through lifelong learning.

    5. Embrace sustainable development concepts and global vision, with the willingness and ability to innovate, start businesses, and serve society.

    Graduation Requirements:

    1. Engineering Knowledge: Apply mathematical, natural scientific, engineering foundational, and professional knowledge of automation to solve complex engineering problems in automation and related fields.

    2. Problem Analysis: Use fundamental principles of mathematics, natural sciences, and engineering sciences related to automation to identify, formulate, and analyze complex engineering problems in the discipline through literature research, accurately grasp requirements and object characteristics, and derive valid conclusions.

    3. Design/Development of Solutions: Propose solutions for complex engineering problems in automation, designing/developing control algorithms, strategies, automation devices, systems, information processing schemes, or technologies that meet specific needs. Reflect innovative awareness in design while considering social, health, safety, legal, cultural, and environmental factors.

    4. Research: Conduct research on complex engineering problems in automation based on scientific principles and methods, including experimental design, modeling analysis, data processing, and result discussion, to obtain reasonable and effective solutions or conclusions.

    5. Modern Tool Usage: Develop, select, and apply appropriate technologies, resources, modern engineering tools, and IT tools for complex engineering problems in automation, while understanding their limitations.

    6. Engineering and Society: Analyze and evaluate the impacts of automation engineering research and practices on society, health, safety, law, and culture based on engineering context knowledge, and understand professional responsibilities.

    7. Environment and Sustainable Development: Understand and assess the impacts of automation engineering practices on environmental and social sustainability.

    8. Professional Ethics: Uphold humanistic and social scientific literacy and social responsibility, adhering to engineering ethics and norms in professional practice.

    9. Individual and Teamwork: Assume roles as an individual, team member, or leader in multidisciplinary teams.

    10. Communication: Effectively communicate complex engineering problems in automation with industry peers and the public through reports, design documents, presentations, and clear verbal communication, including cross-cultural contexts.

    11. Project Management: Understand and apply engineering management principles and economic decision-making methods in multidisciplinary environments.

    12. Lifelong Learning: Maintain awareness of autonomous and lifelong learning, with the ability to continuously adapt to technological advancements.