Pursuing the EJUST ASE program shall result in the following outcomes on the graduates’ profile and capabilities:
General
Master a wide spectrum of engineering fundamental knowledge allowing the solution of engineering problems using the acquired mathematics and physics.
Perform experimental design, conduct experiments and interpret their results.
Design, simulate, validate functionality, and implement a system, component, and process to meet the requirements while respecting realistic constraints.
Integrate seamlessly in a heterogeneous team of professionals from different backgrounds. Assume responsibility for own and team performance.
Apply analytical, critical thinking and systemic approach to diagnose, model and solve fundamental engineering problems with variable ranges of complexity.
Behave professionally and adhere to professional ethics and codes of conduct.
Address various audiences and handle cultural challenges in a creative and productive manner depending on social competence and multi-lingual communicational abilities.
Be committed to saving the environment and mindful of the impacts of engineering practice on society. Direct efforts to foster sustainability principles.
Assume full responsibility for own learning and self-development. Engage in lifelong learning and demonstrate the capacity to engage in post-graduate research.
Maintain knowledge of contemporary engineering issues.
Strive to make use of the latest techniques, software and hardware tools useful for the engineering practice.
Acquire team leadership qualities, managerial skills and entrepreneurial spirit.
Specialization outcomes (Industrial and Manufacturing)
Perform aerodynamic analysis for low and high speeds aerospace vehicles using analytical, numerical, and experimental methods.
Study and analyze different types of propulsion systems and subsystems used in aerospace industry.
Perform static and dynamic structural analysis and design for different types of aerospace vehicles using analytical, numerical, and experimental methods.
Identify, formulate, and solve problems of flight mechanics, stability, and control for different types of aerospace vehicles and autonomous systems.
Acquire systems engineering capabilities for aerospace systems.
Select conventional aerospace equipment and instrumentations according to the required performance.
Design of aerospace systems that include integration of aeronautical or astronautical topics.
Adopt suitable national and international standards and codes to: design, build, operate, inspect and maintain aerospace equipment, systems and services.
Recognize his/her role in promoting the aerospace engineering field and contribute to the development of the profession and the community.
