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Study information

Electronic Engineering (2023)

1. Programme Title:

Electronic Engineering

NQF Level:

6

2. Description of the Programme (as in the Business Approval Form)

The Electronic Engineering programmes at Exeter are part of a wider family of Engineering programmes that have been developed around a number of core principles that distinguish them as innovative, forward looking and student centred. Exeter’s approach to engineering education emphasis collaborative project based learning (PBL), contextualised teaching and an emphasis on skills development and practical application of knowledge. Starting with a core first year and building on commonalities with other engineering disciplines we deliver a unique teaching style based on the pillars of analysis, design and sustainability. Our engineering programmes also equip students with an awareness of entrepreneurship and the skills and confidence to apply their engineering knowledge in entrepreneurial endeavours.. In a fast-changing world we introduce advanced methodologies in analogue and digital electronics, digital signal processing, telecommunication systems, electrical systems, and microprocessor and microcontroller technologies. Professional practice–led and project- based learning, delivered through industry-focused modules and individual and team projects, spans the entire programme and ensures that our graduates are industry–ready with awareness of engineering ethics in their development as professional engineers.

3. Educational Aims of the Programme

The BEng degree programme is designed to deliver all of the required learning outcomes as set out in UK-SPEC for a bachelors degree. Higher level modules (including projects) are based on research-led teaching methods building upon the expertise of the electronic engineering academic staff.
 
The programme aims to enable students to become:
 
(a) flexible engineering graduates equipped to work effectively within engineering design and practice and contributing specialist skills , demonstrating an awareness of the context within which they work, and taking responsibility for their own personal and professional development;
 
(b) graduates who need only to complete an appropriate period of further study or matching section to be educationally qualified to become chartered engineers within the appropriate sector of industry;
 
(c) aware of the environmental, economic, social and sustainability issues that are an integral part of the professional engineer's role in society;
 
(d) able to work well in multi-disciplinary groups with experience of communication, organization, planning and logistics.
 
Through this programme, the College will provide students with: learning opportunities to match their abilities and aspirations, personal academic and pastoral support throughout their university career, appropriate methods of teaching and assessment and a programme of study that they find demanding, interesting and intellectually stimulating, while allowing them to enjoy other aspects of university life. The College will also seek to promote the role of industry and engineering institutions and the benefits that they can provide to undergraduates e.g. through links with the industrial club and student membership of the engineering institutions.
 

4. Programme Structure

The BEng Electronic Engineering programme is a (3) year programme of study at National Qualification Framework (NQF) level (6) (as confirmed against the FHEQ). This programme is divided into (3) ‘Stages’. Each Stage is normally equivalent to an academic year. The programme is also divided into units of study called ‘modules’ which are assigned a number of ‘credits’. The credit rating of a module is proportional to the total workload, with 1 credit being nominally equivalent to 10 hours of work.

5. Programme Modules

Stage 1

Code Title Credits Compulsory NonCondonable
ENG1002Engineering Mathematics and Scientific Computing 30YesYes
ENG1005Multi-Disciplinary Group Challenge Project 30YesYes
ENG1006Entrepreneurship 115YesNo
ENG1007Fundamentals of Mechanics15YesYes
ENG1008Fundamentals of Materials15YesYes
ENG1009Fundamentals of Electronics15YesYes

The first year of the Electronic Engineering programme is shared with all engineering disciplines and strikes a balance between providing core engineering and mathematical knowledge and making the learning experience engaging and exciting. A year-long multi-disciplinary group project provides an over-arching vehicle for PBL and a means of putting core knowledge into practice in a collaborative group setting. Project briefs are developed in response to the core module content. To support the students’ project work they undertake workshops in sketching, report / technical writing and study / research skills. Students develop essential knowledge in Engineering Mathematics and Scientific Computing through a year-long module. By combining Mathematics and Programming, students develop both the mathematical knowledge that underpins engineering science and also the skills to put this knowledge to use by harnessing the power of programming. The first also includes three 15-credit modules, Fundamentals of Mechanics, Fundamentals of Materials, and Fundamentals of Electronics. All modules are delivered using a PBL framework that encourages students to become independent learners.  
 

Stage 2

Code Title Credits Compulsory NonCondonable
ENG2003Electronic Engineering Challenge Project30YesYes
ENG2009Modelling of Engineering Systems 15YesYes
ENG2017Communication and Networking Technologies15YesYes
ENG2118Analogue and Digital Electronics Design15YesYes
ENG2004 Entrepreneurship 215YesNo
ENG2008Microcontroller Engineering15YesYes
ENG2006Industry 4.015YesNo

The second year continues in the same vein as the first with a combination of project work and core modules. A group project again provides context and motivation for the theory taught in the second year. This design and build project is electronic engineering specific with project briefs that allow students to experience the engineering design process and develop solutions drawing on the skills and knowledge gained in their first two years and adopting a heuristic approach to problem solving. The practice of developing mathematical knowledge and programming skill in tandem continues in the second year with two modules; Modelling of Engineering Systems in term 1 and Industry 4.0 in term 2. These modules develop traditional core mathematical knowledge but also introduce students to exciting and topical areas of engineering mathematics such as Data Science and Artificial Intelligence. The theme of entrepreneurship is continued with Entrepreneurship 2 which further develops students’ skillset and awareness of topics such as rapid prototype development, company formation and professional networking. Core electronic engineering modules in Communication and Networking Technologies, Analogue and Digital Electronics Design and Microcontroller Engineering introduce fundamental electronic engineering concepts. 
 

Stage 3

Code Title Credits Compulsory NonCondonable
ECM3175Individual Project30YesYes
ENG3018Control Engineering15YesYes
ECM3166Communications Engineering 15YesYes
ENG3012Mechatronics15YesYes
ECM3165Digital Signal Processing 15YesYes
ENG3004Engineering Electromagnetics15YesYes
Option Group A: Select 1:
ECM3153Management of Product Development 15NoNo
ENG3010Industrial Awareness & Problem Solving15NoNo
ENG3011Management and Leadership15NoNo
PHY3222Energy, Materials and Sustainability15NoNo

The focus in year 3 is on acquiring core Electronic engineering knowledge. Students will take modules in Control Engineering, Mechatronics, Communications Engineering, Digital Signal Processing and Engineering Electromagnetics. All students select one of four optional modules; Energy and the Environment, , Industrial Awareness and Problem Solving or Management & Leadership. Graduating BEng Students complete a 30 credit Individual Investigate Project guided by a specialist academic supervisor. MEng students complete a hands-on design and build project that challenges them to develop, prototype and explore the market for a solution to an Electronic engineering challenge. This project emphasis the combination of commercial awareness and the application of sound engineering knowledge.    

6. Programme Outcomes Linked to Teaching, Learning & Assessment Methods

On successfully completing the programme you will be able to: Intended Learning Outcomes (ILOs) will be accommodated & facilitated by the following learning & teaching and evidenced by the following assessment methods:

A Specialised Subject Skills & Knowledge

Programme ILO #1
demonstrate understanding of mathematical methods and their use, together with computational methods, for modelling, analysis, design and communication in engineering
 
ENG1002 Engineering Mathematics and Scientific Computing (Year 1), ENG2009 Modelling of Engineering Systems (Year 2), ENG2006 Industry 4.0 (Year 2), ECM3165 Digital Signal Processing (Year 3), ENG3004 Engineering Electromagnetics (Year 3), ENG3018 Control Engineering (Year 3)
 
Programme ILO #2
demonstrate understanding of a broad base of scientific principles underpinning electronic, material, mechanical and civil engineering
 
ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG1001 Fundamentals of Mechanics, Materials and Electronics (Year 1), ENG3012 Mechatronics (Year 3)
 
Programme ILO #3
demonstrate understanding of the characteristics and uses of engineering materials and components
 
ENG1001 Fundamentals of Mechanics, Materials and Electronics (Year 1), ECM2118 Analogue and Digital Electronics Design (Year 2), ENG2008 Microcontroller Engineering (Year 2), ECM3165 Digital Signal Processing (Year 3), ENG3004 Engineering Electromagnetics (Year 3), ENG3012 Mechatronics (Year 3)
 
Programme ILO #4
demonstrate understanding of a range of principles and design methods relating to the chosen engineering discipline in general, with in-depth knowledge and understanding in some specialist areas
 
ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2003 Electronic Engineering Challenge Project (Year 2), ECM2117 Communication & Networking Technologies (Year 2), ECM2118 Analogue and Digital Electronics Design (Year 2), ENG2008 Microcontroller Engineering (Year 2), ECM3175 BEng Individual Project (Year 3), ECM3165 Digital Signal Processing (Year 3), ECM3166 Communications Engineering (Year 3), ENG3004 Engineering Electromagnetics (Year 3), ENG3012 Mechatronics (Year 3)
 
Programme ILO #5
demonstrate understanding of management and business practices, including finance, law, marketing, personnel and quality
 
ENG2003 Electronic Engineering Challenge Project (Year 2), ECM2117 Communication & Networking Technologies (Year 2)
 
Programme ILO #6
demonstrate understanding of ethical and social issues related to engineering and professional responsibilities
 
ENG2003 Electronic Engineering Challenge Project (Year 2), ECM2117 Communication & Networking Technologies (Year 2), PHY3067 Energy and the Environment (Physics) (Year 3)
 

Learning & Teaching Activities

Assessment Methods

B Academic Discipline Core Skills & Knowledge

Programme ILO #7
demonstrate a systematic and creative approach to problem solving
 
ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2003 Electronic Engineering Challenge Project (Year 2), ECM2118 Analogue and Digital Electronics Design (Year 2), ENG2008 Microcontroller Engineering (Year 2), ECM3175 BEng Individual Project (Year 3), ENG3012 Mechatronics (Year 3)
 
Programme ILO #8
apply appropriate mathematical methods, scientific principles and computer based methods to the modelling, analysis and solution of practical engineering problems
 
ENG2009 Modelling of Engineering Systems (Year 2), ENG2006 Industry 4.0 (Year 2), ECM3175 BEng Individual Project (Year 3), ENG3004 Engineering Electromagnetics (Year 3), ENG3018 Control Engineering (Year 3)
 
Programme ILO #9
create a complete design, product or service to meet a customer need, starting from negotiation of specifications, showing creativity and justifying all decisions
 
ENG1006 Entrepreneurship 1 (Year 1), ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2003 Electronic Engineering Challenge Project (Year 2), ENG2004 Entrepreneurship 2 (Year 2), ECM2117 Communication & Networking Technologies (Year 2)
 
Programme ILO #10
take a holistic approach to design and problem solving
 
ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2003 Electronic Engineering Challenge Project (Year 2), ECM3175 BEng Individual Project (Year 3), ENG3012 Mechatronics (Year 3), ENG1006 Entrepreneurship 1 (Year 1), ENG1005 Multi-Disciplinary Challenge Project (Year 1)
 
Programme ILO #11
assess and manage risks (e.g.: commercial, safety, environmental etc.)
 
ENG1006 Entrepreneurship 1 (Year 1), ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2004 Entrepreneurship 2 (Year 2), ECM2117 Communication & Networking Technologies (Year 2), ECM3175 BEng Individual Project (Year 3)
 
Programme ILO #12
take personal responsibility for acting in a professional and ethical manner
 
ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2003 Electronic Engineering Challenge Project (Year 2), ECM3175 BEng Individual Project (Year 3), PHY3067 Energy and the Environment (Physics) (Year 3)
 
Programme ILO #13
select and use appropriate ICT based tools for analysis, design and communication of designs
 
ENG2003 Electronic Engineering Challenge Project (Year 2), ECM2118 Analogue and Digital Electronics Design (Year 2), ENG2008 Microcontroller Engineering (Year 2), ECM3175 BEng Individual Project (Year 3), ECM3165 Digital Signal Processing (Year 3), ENG3004 Engineering Electromagnetics (Year 3), ENG3012 Mechatronics (Year 3)
 
Programme ILO #14
select and use laboratory instrumentation appropriately and correctly
 
ENG1001 Fundamentals of Mechanics, Materials and Electronics (Year 1), ECM2118 Analogue and Digital Electronics Design (Year 2), ENG2008 Microcontroller Engineering (Year 2), ECM3165 Digital Signal Processing (Year 3), ECM3166 Communications Engineering (Year 3), ENG3012 Mechatronics (Year 3)
 
Programme ILO #15
construct prototype products, systems, experimental apparatus etc.
 
ENG1006 Entrepreneurship 1 (Year 1), ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2004 Entrepreneurship 2 (Year 2), ECM2118 Analogue and Digital Electronics Design (Year 2), ECM3175 BEng Individual Project (Year 3), ENG3012 Mechatronics (Year 3)
 
Programme ILO #16
work safely in laboratory, workshop environments etc., and promote safe practice
 
ENG1001 Fundamentals of Mechanics, Materials and Electronics (Year 1), ECM2118 Analogue and Digital Electronics Design (Year 2), ENG2008 Microcontroller Engineering (Year 2), ECM3165 Digital Signal Processing (Year 3), ECM3166 Communications Engineering (Year 3), ENG3012 Mechatronics (Year 3)
 
 
 
 
 
 
 
 
 
 
 

Learning & Teaching Activities

Assessment Methods

C Personal / Transferable / Employment Skills & Knowledge

Programme ILO #17
communicate effectively and persuasively using the full range of currently available methods
 
ENG1006 Entrepreneurship 1 (Year 1), ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2003 Electronic Engineering Challenge Project (Year 2), ENG2004 Entrepreneurship 2 (Year 2), ECM2117 Communication & Networking Technologies (Year 2), ECM3175 BEng Individual Project (Year 3)
 
Programme ILO #18
manage resources and time
 
ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2003 Electronic Engineering Challenge Project (Year 2), ECM2117 Communication & Networking Technologies (Year 2), ECM2118 Analogue and Digital Electronics Design (Year 2), ENG2008 Microcontroller Engineering (Year 2), ECM3175 BEng Individual Project (Year 3), ECM3165 Digital Signal Processing (Year 3), ECM3166 Communications Engineering (Year 3), ENG3004 Engineering Electromagnetics (Year 3), ENG3012 Mechatronics (Year 3)
 
Programme ILO #19
work in a team, which may be multi-disciplinary
 
ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2003 Electronic Engineering Challenge Project (Year 2), ENG2004 Entrepreneurship 2 (Year 2), ECM2117 Communication & Networking Technologies (Year 2), ENG2008 Microcontroller Engineering (Year 2)
 
Programme ILO #20
learn independently, identifying own personal development needs and goals, reflecting on own performance and managing own personal development
 
ENG1006 Entrepreneurship 1 (Year 1), ENG2004 Entrepreneurship 2 (Year 2), ECM2117 Communication & Networking Technologies (Year 2), ECM2118 Analogue and Digital Electronics Design (Year 2), ENG2008 Microcontroller Engineering (Year 2), ECM3175 BEng Individual Project (Year 3), ECM3165 Digital Signal Processing (Year 3), ECM3166 Communications Engineering (Year 3), ENG3004 Engineering Electromagnetics (Year 3), ENG3012 Mechatronics (Year 3)
 
Programme ILO #21
obtain and process information from a wide range of sources, which may be conflicting, analyse it critically and apply this information in engineering applications
 
ENG1005 Multi-Disciplinary Challenge Project (Year 1), ENG2003 Electronic Engineering Challenge Project (Year 2), ECM2117 Communication & Networking Technologies (Year 2), ECM3175 BEng Individual Project (Year 3)
 
Programme ILO #22
sort, manipulate and present data in a way that facilitates effective analysis and decision making
 
ENG1002 Engineering Mathematics and Scientific Computing (Year 1), ENG2006 Industry 4.0 (Year 2), ECM3175 BEng Individual Project (Year 3)
 
 
 
 

 

 

Learning & Teaching Activities

Assessment Methods

7. Programme Regulations

Credit

The programme consists of 360 credits with 120 credits taken at each stage. Normally not more than 75 credits would be allowed in any one term. In total, students normally take no more than 150 credits at level 1, and must take at least 90 credits at level 3.

The pass mark for award of credit in an individual module is 40%.

Progression from 2nd to 3rd year
 
Students who gain an average of 60% or more in the first 2 years will be eligible to progress to Stage 3 of the MEng Electronic Engineering programme (weighting is 40% 1st year, 60% 2nd year).
 

Condonement

This programme is accredited by a PSRB under licence from the Engineering Council. Therefore, the latest Engineering Council regulations on condonement apply to this programme. Please find further details in the TQA Manual here: http://as.exeter.ac.uk/academic-policy-standards/tqa-manual/specialprovisionsforprogrammeswithaccreditationlicencedbytheengineeringcouncil/

 

Assessment and Awards

UG Programmes: Assessment at stage one does not contribute to the summative classification of the award. The award will normally be based on the degree mark formed from the credit weighted average marks for stages 2 and 3 combined in the ratio 1:2 respectively.

 

Classification

The marking of modules and the classification of awards broadly corresponds to the following percentage marks:

Class I    70% +                                                      

Class II   Division I 60-69%                                     

Class II   Division II 50-59%                                    

Class III  40-49%

Full details of assessment regulations for UG programmes can be found in the Teaching Quality Assurance Manual (TQA) on the University of Exeter website.  Generic marking criteria are also published here.

Please see the Teaching and Quality Assurance Manual for further guidance.

 

8. College Support for Students and Students' Learning

In accordance with University policy a system of personal tutors is in place for all students on this programme.  A University-wide statement on such provision is included in the University's TQA Manual.  As a student enrolled on this programme you will receive the personal and academic support of the Programme Coordinator and will have regular scheduled meetings with your Personal Tutor; you may request additional meetings as and when required. The role of personal tutors is to provide you with advice and support for the duration of the programme and extends to providing you with details of how to obtain support and guidance on personal difficulties such as accommodation, financial difficulties and sickness. You can also make an appointment to see individual teaching staff.

Information Technology (IT) Services provide a wide range of services throughout the Exeter campuses including open access computer rooms, some of which are available 24 hours, 7 days a week.  Help may be obtained through the Helpdesk, and most study bedrooms in halls and flats are linked to the University's campus network.

Additionally, the College has its own dedicated IT support staff, helpdesk and computer facilities which are linked to the wider network, but which also provide access to some specialised software packages.  Email is an important channel of communication between staff and students in the College and an extensive range of web-based information (see https://intranet.exeter.ac.uk/emps/) is maintained for the use of students, including a comprehensive and annually revised student handbook.

The Harrison Learning Resource Centre is generally open during building open hours. The Centre is available for quiet study, with four separate rooms that can be booked for meetings and group work. Amongst its facilities, the Learning Resource Centre has a number of desks, four meeting rooms with large LCD screens, and free use of a photocopier. Also available are core set texts from your module reading lists, and undergraduate and MSc projects from the past two years.

Online Module study resources provide materials for modules that you are registered for, in addition to some useful subject and IT resources. Generic study support resources, library and research skills, past exam papers, and the 'Academic Honesty and Plagiarism' module are also available through the student portal (http://vle.exeter.ac.uk)

Student/Staff Liaison Committee enables students & staff to jointly participate in the management and review of the teaching and learning provision.

 

10. Admission Criteria

All applications are considered individually on merit. The University is committed to an equal opportunities policy with respect to gender, age, race, sexual orientation and/or disability when dealing with applications. It is also committed to widening access to higher education to students from a diverse range of backgrounds and experience.

Candidates must satisfy the general admissions requirements of the University of Exeter.

 

For entry to the BEng Electronic Engineering programme, academic entry requirements are:

Normally completion of 12 years of education;

A/AS 200 points (local language A/AS Levels are accepted); IB 24 points; Country-specific entry qualifications can be obtained from INTO Admissions.

English: IELTS 5.5 with a minimum of 5.5 in all subskills (or equivalent)

Minimum grade C in GCSE Maths; IB Maths SL / HL 3 if not offered at O level / GCSE; or Minimum Year 12 Pass in Maths; 

 

Unless otherwise specified Subjects recognised must relate to 'academic’ subjects or modules only.

 

11. Regulation of Assessment and Academic Standards

Each academic programme in the University is subject to an agreed College assessment and marking strategy, underpinned by institution-wide assessment procedures.

The security of assessment and academic standards is further supported through the appointment of External Examiners for each programme. External Examiners have access to draft papers, course work and examination scripts. They are required to attend the Board of Examiners and to provide an annual report. Annual External Examiner reports are monitored at both College and University level. Their responsibilities are described in the University's code of practice.  See the University's TQA Manual for details.

 

12. Indicators of Quality and Standards

Certain programmes are subject to accreditation and/ or review by professional and statutory regulatory bodies (PSRBs).

The BEng Electronic Engineering is accredited by the Institution of Engineering and Technology (IET) as: 1. fully satisfying the educational base for an Incorporated Engineer (IEng). 2. partially satisfying the educational base for a Chartered Engineer (CEng). A programme of accredited further learning will be required to complete the educational base for CEng. See www.theiet.org for further information.

Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC).

Accreditation is awarded for a maximum of 5 years under each assessment exercise. The dates applicable to the current accreditation of this degree programme can be viewed on the Engineering Council list of accredited degrees: www.engc.org.uk/acad.

 

14 Awarding Institution University of Exeter
15 Lead College / Teaching Institution College of Engineering, Mathematics and Physical Sciences
16 Partner College / Institution
17 Programme accredited/validated by
18 Final Award(s) BEng (Hons)
19 UCAS Code (UG programmes) H610
20 NQF Level of Final Awards(s): 6
21 Credit (CATS and ECTS) 360 (180 ECTS)
22 QAA Subject Benchmarking Group (UG and PGT programmes) Engineering
23 Origin Date February 8th 2023 Last Date of Revision: June 20th 2023