(Integrated Master in Science:) Integrated Master in Science
Computer Science
Current
University of Essex
University of Essex
Computer Science and Electronic Engineering (School of)
Colchester Campus
Masters
Full-time
Computing
MSCIG402
10/05/2023
Details
Professional accreditation
Accredited by BCS, the Chartered Institute for IT for the purposes of fully meeting the academic requirement for registration as a Chartered IT Professional.
Accredited by BCS, the Chartered Institute for IT on behalf of the Engineering Council for the purposes of fully meeting the academic requirement for registration as a Chartered Engineer.
Admission criteria
GCSE: Mathematics C/4
A-levels: AAB
BTEC: D*DD, depending on subject studied - advice on acceptability can be provided.
IB: 33 points or three Higher Level certificates with 665. Either must include Standard Level Mathematics grade 4, or a minimum of 3 in Higher Level Mathematics. We will accept grade 4 in either Standard Level Mathematics: Analysis and Approaches or Standard Level Mathematics: Applications and Interpretation.
Maths in the IB is not required if you have already achieved GCSE Maths at grade C/4 or above or 4 in IB Middle Years Maths.
We are also happy to consider a combination of separate IB Diploma Programme Programme Courses (formerly certificates) at both Higher and Standard Level. Exact offer levels will vary depending on the range of subjects being taken at higher and standard level, and the course applied for.
We can also consider combinations with BTECs or other qualifications in the Career-related programme – the acceptability of BTECs and other qualifications depends on the subject studied, advice on acceptability can be provided. Please contact the Undergraduate Admissions Office for more information.
T-levels: Distinction* - Entry requirements for students studying T-level qualifications are dependent on subjects studied. Advice can be provided on an individual basis.
IELTS (International English Language Testing System) code
English language requirements for applicants whose first language is not English: IELTS 6.0 overall. Different requirements apply for second year entry, and specified component grades are also required for applicants who require a visa to study in the UK.
Other English language qualifications may be acceptable so please contact us for further details. If we accept the English component of an international qualification then it will be included in the information given about the academic levels listed above. Please note that date restrictions may apply to some English language qualifications
If you are an international student requiring a visa to study in the UK please see our immigration webpages for the latest Home Office guidance on English language qualifications.
If you do not meet our IELTS requirements then you may be able to complete a pre-sessional English pathway that enables you to start your course without retaking IELTS.
Additional Notes
If you’re an international student, but do not meet the English language or academic requirements for direct admission to this degree, you could prepare and gain entry through a pathway course. Find out more about opportunities available to you at the University of Essex International College here.
Course qualifiers
A course qualifier is a bracketed addition to your course title to denote a specialisation or pathway that you have achieved via the completion of specific modules during your course. The
specific module requirements for each qualifier title are noted below. Eligibility for any selected qualifier will be determined by the department and confirmed by the final year Board of
Examiners. If the required modules are not successfully completed, your course title will remain as described above without any bracketed addition. Selection of a course qualifier is
optional and student can register preferences or opt-out via Online Module Enrolment (eNROL).
None
Rules of assessment
Rules of assessment are the rules, principles and frameworks which the University uses to calculate your course progression and final results.
Additional notes
None
External examiners
Prof Pietro Oliveto
Professor
Southern University of Science and Technology (SUSTech)
External Examiners provide an independent overview of our courses, offering their expertise and help towards our continual improvement of course content, teaching, learning, and assessment.
External Examiners are normally academics from other higher education institutions, but may be from the industry, business or the profession as appropriate for the course.
They comment on how well courses align with national standards, and on how well the teaching, learning and assessment methods allow students to develop and demonstrate the relevant knowledge and skills needed to achieve their awards.
External Examiners who are responsible for awards are key members of Boards of Examiners. These boards make decisions about student progression within their course and about whether students can receive their final award.
Programme aims
- to equip students with the knowledge and skills that are currently in high demand in the computing industry and in the wider economy
- to enable students to acquire a broad understanding of computer science, whilst providing opportunities for them to develop expertise within particular areas of specialisation
- to develop the students' ability to make an effective contribution to team-based activity
- to encourage students to adopt an investigative approach and develop autonomous study skills in order to ensure their continuing professional development
- to provide students with an understanding of the industrial context and an appreciation of a range of external factors that affect the work of the computer professional.
- to prepare students for careers in advanced research and/or development environments by acquiring knowledge and skills in specialised areas of computer science
- to develop the students' ability to make a critical evaluation of the theories, techniques, tools and systems used in their chosen areas of specialisation
- to enable students to contribute to future developments in their field by providing them with an understanding of recent advances and current research activity
- to develop the students' ability to undertake research by providing appropriate resources and guidance in their use
Learning outcomes and learning, teaching and assessment methods
On successful completion of the programme a graduate should demonstrate knowledge and skills as follows:
A: Knowledge and understanding
A1: Apply knowledge of mathematics, statistics, natural science and engineering principles to the solution of complex problems. Some of the knowledge will be at the forefront of the particular subject of study.
A2: Analyse complex problems to reach substantiated conclusions using first principles of mathematics, statistics, natural science and engineering principles.
A3: Select and apply appropriate computational and analytical techniques to modelcomplex problems, recognising the limitations of the techniques employed.
A4: Select and evaluate technical literature and other sources of information to address complex problems
A5: Knowledge and understanding of computer science and software based design. (If studying on the MSci award this knowledge and understanding will be expected to be achieved at advanced level)
A101: Apply a comprehensive knowledge of mathematics, statistics, natural science and engineering principles to the solution of complex problems. Much of the knowledge will be at the forefront of the particular subject of study and informed by a critical awareness of new developments and the wider context of engineering.
A102: Formulate and analyse complex problems to reach substantiated conclusions. This will involve evaluating available data using first principles of mathematics, statistics, natural science and engineering principles, and using engineering judgment to work with information that may be uncertain or incomplete, discussing the limitations of the techniques employed.
A103: Select and apply appropriate computational and analytical techniques to model complex problems, discussing the limitations of the techniques employed.
A104: Select and critically evaluate technical literature and other sources of information to solve complex problems.
Learning methods
Lectures are the principal method of delivery for the concepts and principles involved in achieving the learning outcomes.
Students are also directed to reading from textbooks, academic papers and material available on-line.
Understanding is reinforced by means of exercise classes, discussion groups, laboratories, assignments and project work.
Specialist knowledge is further developed during supervision of the final year individual project.
Assessment methods
Achievement of knowledge outcomes is assessed primarily through unseen examinations, and also through marked coursework.
An assessment of the understanding of underlying concepts and principles forms part of the overall assessment of the final year individual project report and oral presentation.
The assessment of the CE902 essay includes specific allocation of marks for the breadth and depth of the knowledge gained during the study of the chosen topic.
B: Intellectual and cognitive skills
B1: Design solutions for complex problems that meet a combination of societal, user, business and customer needs as appropriate. This will involve consideration of applicable health & safety, diversity, inclusion, cultural, societal, environmental and commercial matters, codes of practice and industry standards.
B2: Apply an integrated or systems approach to the solution of complex problems.
B3: Evaluate the environmental and societal impact of solutions to complex problems and minimise adverse impacts.
B4: Identify and analyse ethical concerns and make reasoned ethical choices informed by professional codes of conduct.
B5: Use a risk management process to identify, evaluate and mitigate risks (the effects of uncertainty) associated with a particular project or activity.
B6: Apply software engineering principles to the design of computer systems and software.
Learning methods
The basis for intellectual skills is provided in lectures, and they are developed by means of recommended reading, guided and self directed study, assignments and project work.
Assessment methods
Achievement of intellectual skills is assessed primarily through unseen examinations, and also through marked assignments and project work.
C: Practical skills
C1: Adopt a holistic and proportionate approach to the mitigation of security risks.
C2: Adopt an inclusive approach to engineering practice and recognise the responsibilities, benefits and importance of supporting equality, diversity and inclusion.
C3: Use practical laboratory and workshop skills to investigate complex problems.
C4: Select and apply appropriate materials, equipment, engineering technologies and processes, recognising their limitations.
C5: Ability to design, construct and analyse computer systems and software.
Learning methods
Practical skills are developed in exercise classes, laboratory classes, assignments and project work.
Assessment methods
Achievement of practical skills is assessed through marked coursework, project reports, oral presentations and demonstrations of completed systems.
D: Key skills
D1: Discuss the role of quality management systems and continuous improvement in the context of complex problems.
D2: Apply knowledge of engineering management principles, commercial context, project and change management, and relevant legal matters including intellectual property rights.
D3: Function effectively as an individual, and as a member or leader of a team.
D4: Communicate effectively on complex engineering matters with technical and non-technical audiences.
D5: Plan and record self-learning and development as the foundation for lifelong learning/CPD.
Learning methods
Students learn key skills in research, problem solving, communication and team project work in the first year project module, and thereafter the development of key skills forms an integral part of their overall learning activity.
Assessment methods
Assessment of the key skills is intrinsic to subject based assessment.
The assessment of project work includes specific allocations of credit for project management and the quality of presentations.
An individual's contribution to team projects is determined by means of a submission containing reflective and self-assessment components.
The assessment of the final year individual project report includes specific allocation of credit for the quality, extent and relevance of a bibliography, including internet sources.