RADMEP+ Learning Outcomes

  1. Graduates demonstrate a comprehensive understanding and advanced knowledge in the field of radiation effects on microelectronics and photonics. 2) They are able to apply their knowledge to solve complex problems in related areas
  2. RADMEP+ underscores the development of critical thinking, problem-solving, and research capabilities, particularly within the context of radiation effects on microelectronics and photonics. 2) Graduates are able to independently identify, formulate, and solve complex problems using advanced analytical tools and techniques
  3. Graduates cultivate a global perspective on the development and application of photonics or microelectronics, equipping them to address challenges and contribute to their respective fields of expertise. 2) They are able to understand the social, economic, and ethical implications of their work, and actively seek opportunities to collaborate with relevant partners.
  4. The RADMEP+ programme aspires to produce highly skilled and adaptable professionals capable of making significant contributions to the global community. 2) They demonstrate initiative, continuous learning, flexibility and adaptability in their professional endeavors.
  5. Through collaborative and multicultural experiences, students gain strong intercultural communication, teamwork, and project management skills, preparing them for international professional environments. 2) Graduates are able to effectively communicate technical concepts, build reports, and navigate cultural differences within diverse teams.

Specific Learning Outcomes

  1. Graduates demonstrate broad experience and understanding of microelectronics, photonics and their applications. They will possess detailed knowledge and understanding of radiation effects on those technologies can apply this knowledge to estimate the vulnerability or improve their radiation hardness
  2. Graduates adeptly analyze and critically evaluate technical solutions in microelectronics, photonics or radiation effects. They will independently undertake R&D projects, applying knowledge and problem solving skills in novel or unfamiliar situations related to those domains. They will work effectively within teams, integrating knowledge from different disciplines and developing skills in experimental, theoretical, and numerical design for R&D.
  3. Graduates proficiently analyze and interpret data using data processing or artificial intelligence methods. They will identify, formulate, and solve photonics and microelectronics problems, evaluating diverse points of view within different frameworks. They will apply disciplinary or interdisciplinary learning across multiple contexts, integrating knowledge and practice.
  4. Graduates communicate effectively in presenting ideas orally and in writing (oral communication; written communication) and other media forms.