Aims and Fit of Module

This project provides students with the opportunity to combine their extensive knowledge of research methods and techniques with their technical and analytical skills in order to plan, execute, and critically evaluate outcomes of a substantial and complex research project at the forefront of Advanced Technology. Through guided independent inquiry, students will deepen their mastery of domain-specific methodologies while developing crucial professional competencies such as project management, risk analysis, problem-solving, and evaluative judgement, with emphasis on ethical, sustainable, and user-centered approaches to innovation. Students will also develop and enhance their ability to articulate complex ideas through structured academic writing and technical presentations.

This module aligns with programme learning outcomes by bridging theoretical concepts and frameworks with complex practical applications in computing and engineering, fostering novel and impactful solutions that balance technical rigour with societal and environmental considerations to extend the boundaries of knowledge. It consolidates students’ readiness for doctoral study, research and development roles, or careers in industry, equipping them to address real-world challenges through strategically informed, ethically grounded innovation. 

Learning outcomes

A. Synthesise and critically evaluate advanced scholarly and industrial literature to identify unresolved challenges and position original research contributions within the field of Advanced Technology.
B. Formulate novel and impactful research questions that address complex technical challenges aligned with emerging trends in industry or academia.
C. Design and manage a research project across its full lifecycle, integrating legal, social, ethical and professional frameworks, risk mitigation strategies, and adaptive planning to address evolving technical or contextual challenges.
D. Create an innovative technical artefact (e.g., software, system, prototype) that advances computing and engineering knowledge or practice, employing cutting-edge research methodologies to justify originality and feasibility.
E. Critically evaluate the artefact’s performance, scalability, social and environmental impact, and ethical implications of its deployment,  employing rigorous validation techniques to assess its contribution against defined research goals and broader field-specific benchmarks.
F. Communicate complex original findings to technical and non-technical audiences through high-impact presentations, contextualising project outcomes within current research trends in Advanced Technology.
G. Structure and write an academic dissertation that systematically documents the research lifecycle, synthesizing methodological choices, iterative refinements, and critical reflections.
H. Reflect on personal and project evolution through the research process, articulating how challenges, feedback, and self-directed learning have shaped professional identity and readiness for advanced roles.

Method of teaching and learning

This module fosters independent learning and a spirit of academic inquiry through sustained personalised supervision. Students select a project and supervisor by mutual agreement based on their interests. Students’ learning is supported through regular meetings with their allocated academic and, for JITRI projects, industrial supervisor(s). Supervisors guide students through iterative cycles of planning, development, and critical evaluation, offering formative feedback tailored to the student’s specific research project. This mentorship ensures students balance creativity with methodological rigour. Supervisors also provide targeted advice and guidance on synthesising research findings, structuring arguments, and presenting technical and research outcomes with clarity, ensuring students develop the skills necessary to communicate effectively on complex technical matters across written, visual, and oral formats with a variety of audiences.