ࡱ> 9 0:bjbj.. =.LhLhN:''''' ( ( (8D() ( g2*+(+++Y45Tc5,fffffff$?jlff'574"Y455f''++Sf>>>5'8+'+f>5f>>`D'c+09[6bb&xff0 gBb[m9n[mLcc8[m'dp55>55555ff};555 g5555[m555555555X n&:  1Programme TitleComputer Science with a Year in Industry2Programme CodeCOMU403JACS CodeI1004Level of StudyUndergraduate5aFinal QualificationMaster of Computing (MComp)5bQAA FHEQ LevelMasters6Intermediate QualificationBachelor of Science with Honours (BSc Hons)7Teaching Institution (if not ߲ݴý)Not applicable8FacultyEngineering9DepartmentComputer Science10Other Departments involved in teaching the programmeNone11Mode of AttendanceFull-time12Duration of the Programme5 years13Accrediting Professional or Statutory BodyBritish Computer Society14Date of production/revisionMarch 202315. Background to the programme and subject area Computer Science is the fundamental discipline of the information and communication age. Computing now permeates every aspect of life, ranging from business and medicine to science, engineering and the humanities; and skilled personnel are required to harness and exploit the growing power of computing devices. A degree in Computer Science with a Year in Industry covers a wide spectrum of knowledge, ranging from mathematics, algorithms and data structures, software engineering, hardware and networks to human and professional issues. It also develops a wide range of technical and interpersonal skills, including analysis and design, computer programming, team management, report writing, presentation skills and enterprise. Our Computer Science degree with a Year in Industry has a strong theoretical basis and a high practical content. Key features include project teamwork at all levels, building real business systems for external clients, a project dissertation and participation either in a group research project, or in a software house. At the higher levels, students may pursue advanced topics in computer speech and language processing, 3D graphics, robotics and machine learning, theoretical computer science and software engineering and distributed systems. Students on the Computer Science with a Year in Industry spend the penultimate year of their degree working in an engineering company of their choice. This provides them with wide-ranging experiences and opportunities to put their academic studies into context, and to improve their technical and professional skills. It also enhances their employment prospects, enabling them to gain direct experience of industry culture, make contacts and strengthen their CV. Students are responsible for finding their own industrial placements, but are assisted by staff in the department and the Careers Service. In addition to the year in industry, our curriculum reflects the latest research developments and professional standards in Computer Science. Teaching is informed by the research activity of staff, which has an international reputation for the quality of its research. In the 2021 Research Excellence Framework (REF), 99% of our research was rated in the top two categories, meaning it is classed as world-leading or internationally excellent. The Department is rated 8th nationally for the quality of our research environment. Close links are maintained with industry-leading companies through the departments Industrial Advisory Board. Our degrees are accredited by the British Computer Society (BCS), thus providing a route to the professional status of Chartered Engineer (CEng), Chartered Scientist (CSci) and Chartered Information Technology Professional (CITP). See the Department of Computer Science website:  HYPERLINK "http://www.shef.ac.uk/dcs" \h http://www.shef.ac.uk/dcs for more information.16. Programme aims The aims of the programme are: To provide a thorough academic grounding in the core subject matter of Computer Science, with advanced study paths informed by the Departments wide-ranging research interests; To develop technical, professional and managerial skills through exposure to practical, industrially-oriented projects, emphasising teamwork and communication as well as software design and development skills; To expose students to leading-edge world-class research in Computer Science, and engage students in advanced research areas and methods; To provide students with direct experience of working in industry, applying and developing their technical and professional skills; To produce immediately employable graduates with an industrially relevant mix of knowledge, practical skills and self-motivation, and with leadership and enterprise skills; To provide an international dimension with opportunities for study in universities in other countries.17. Programme learning outcomes Knowledge and understanding - On successful completion of the programme, students will have obtained:K1A full understanding of programming languages and styles, algorithms and data structures.K2A full understanding of discrete and continuous mathematical foundations for computing.K3A full understanding of software engineering, analysis and design methods and process management.K4A full understanding of artificial intelligence and biologically-inspired models of machine reasoning.K5An appreciation of computer hardware design and computer network architectures.K6An appreciation of human, social, legal and professional issues relating to the use of computers.K7An appreciation of the commercial and industrial dimension to computing, through interaction with clients.K8A deep understanding of aspects of theoretical and applied computer science and symbolic calculi (core topic for the degree).K9A deep understanding in a range of research-led topics taught in the final years of the degree.K10Work experience and appreciation of how subject-specific knowledge gained during the degree is applied in the workplace. Skills and other attributes - On successful completion of the programme, students will be able:S1To function in an Information and Communication Technology (ICT) environment using appropriate technology such as email, the Internet, shared data and code repositories.S2To conceive, design and write correct working computer programs in several different programming styles, using a variety of compilers and development environments.S3To construct and manipulate formal and mathematical models.S4To apply a software engineering process and take a project through the stages of the software lifecycle, using design notations and software engineering tools selectively.S5To communicate effectively in writing, present a two-sided argument, expose technical information clearly, comprehend and summarise research-level material with proper citation of sources.S6To communicate effectively in speaking, interview and interact productively with a client, present and defend a substantial piece of work, engage with others and respond effectively to questions.S7To work effectively in a team, demonstrating personal responsibility and group management ability, interpersonal skills, leadership and delegation, and plan to meet deadlines.S8To design solutions for complex problems to meet a customer's needs within the context of a wider business practice.S9To research material from multiple published sources, comprehend and filter such material and from it synthesize theories, principles or designs pertinent to a practical, problem-solving project.S10To demonstrate personal initiative, self-motivation and problem-solving skills, through the selection and taking through to completion of a practical, problem-solving individual project with a research dimension.S11To demonstrate group initiative and enterprise within a group project.S12To work effectively in an industrial environment.18. Teaching, learning and assessment Development of the learning outcomes is promoted through the following teaching and learning methods: The Department fosters an environment with many opportunities for individual and group learning, but the responsibility for learning rests with the student, who must be personally organised and self-motivated to make the most of the programme. Teaching is offered through formal lectures, seminars, computer laboratories, problem-solving classes and project supervision. Lectures are formal presentations to a large class of students by a lecturer. The purpose of a lecture is to motivate interest in a subject, to convey the core concepts and information content succinctly and to point students towards further sources of information. Lectures are interactive and students are encouraged to ask questions at suitable points. Students are expected to take notes during lectures, adding detail to published course materials (which should be printed and brought to the lecture, when provided in advance on electronic media). The learning outcomes K1-K10 are supported mainly through this mode. Seminars are longer semi-formal presentations to a class of students by a lecturer, researcher, industrial partner or student, describing an area of their current research or business. There is typically more opportunity than in a lecture to structure the session internally with questions, problem solving and other kinds of interactive or shared learning experience, in which the students may also participate in the teaching and lead discussions. The learning outcomes K7 and S5-S9 are directly promoted through this mode, with indirect support for K1-K6, K8-K10. Computer laboratories are sessions supervised by teaching assistants (under the direction of the responsible lecturer) in which students work at a computer, to develop a specific practical skill, such as familiarisation, computer programming, or the use of a software engineering or mathematical modelling tool. The learning outcomes S1-S4 are promoted mainly through this mode, with indirect support for K1-K3. Problem-solving classes are sessions conducted by a lecturer with a class of students, in which exercises are completed interactively and solutions are provided within the period. The purpose of such a class is to help students engage with, and assimilate the material presented in lectures and start to apply this knowledge. The learning outcomes K2-K6 and K8 are supported through this mode. Project supervision involves regular meetings with a students individual or group project supervisor, who may also be their personal tutor. During each session, students report on their progress to the supervisor, who highlights further areas of investigation, helps with technical problems, advises about the content and structure of technical reports and generally encourages the students to organise their time effectively. The learning outcomes S5-S11 are directly promoted through this mode, with S1-S4 supported indirectly. The transition to self-motivated learning is encouraged through specialist teaching materials such as lecture handouts or copies of lecture slides, supplied via the Departments website. Set course texts and background materials are available through the University libraries, at bookshops and also via the Internet. Active learning is fostered and promoted through engagement in practical work, such as exercises, assignments and projects. Exercises are short tasks, either writing computer programs or working out solutions to other kinds of set problem, which are typically reviewed at the end of the session. Learning outcomes K1-K10 and S1-S4 may be supported this way. Assignments are typically offered in stages over a number of weeks, involving the design and implementation of a software system to perform a given task, or the researching of a body of information leading to the writing of a discursive essay on a given topic. Learning outcomes S1-S5 are supported by this; indirectly K1-K10 are reinforced. Individual industrial placement: The penultimate year of the degree is spent in industry. This provides students with experience of working in a company relevant to the degree, consolidates knowledge gained during their academic studies, and enhances their understanding of how to apply this in practice. It also provides students with opportunities to develop professionally and plan for further development towards a professional qualification. Learning outcomes K11 and S12 are supported by this. Projects are undertaken individually or in groups over one or two semesters. Projects typically solve a larger problem, possibly for an industrial client, possibly with a research dimension. Individual projects require personal organisation and presentation skills; group projects also require group organisational and communication skills. Learning outcomes K6-K7 and S1-S11 are supported by this; indirectly, K1-K5, K8-K10 are reinforced. Private study makes up more than half of the time allocated to each module. Students are expected to read around the topics of each module and follow especially any directed reading from recommended course texts. Private study will include further investigations prior to exercises or projects and also consolidation of lecture notes. Opportunities to demonstrate achievement of the learning outcomes are provided through the following assessment methods: Modules may be assessed by formal examination, by practical assignments, by an individual or group project, or by some combination of these methods. Examinations are typically 2-hour question papers, in which students answer 3 from a choice of 4 questions. A typical question has 40% of the credit devoted to the recall of knowledge and information and 60% of the credit devoted to applying this knowledge actively to solve a short problem. Examinations test the knowledge learning outcomes K2-K10, but also provide evidence of practical skills S3 and S5, and, to a lesser extent, evidence of previous engagement in S2 and S4. Assignments are typically 10-20 hour pieces of continuously assessed coursework, which students complete individually or in groups as directed. An assignment may have multiple stages, each offered over a 2-3 week period, delivered to separate deadlines. Assignments both develop and assess the practical skills S2-S5 and they are the main means of assessing programming ability K1, S2. ICT skills S1 are assessed indirectly. Individual dissertation projects are completed at Level 3, typically over two semesters. Students select a topic, research the background literature, prepare a survey/analysis report at the interim assessment stage, and apply this knowledge in a practical, problem-solving project which typically involves the design, implementation and testing of a substantial piece of software. The final assessment stage is by dissertation and poster session, assessed independently by two examiners. A viva voce examination may be held to form a common view in cases of insufficient evidence or divergent opinions. The learning outcomes S5-S6, S9-S10 are directly assessed, together with specialist areas of knowledge from K8-K9. Practical skills in S1-S4 and knowledge in K1-K7 may be assessed indirectly. Industrial placement A variety of methods are used to assess the placement undertaken in the penultimate year. These include two written reports describing and reflecting on personal professional development through experience gained in the year in industry (from an online skills-based placement journal), and an oral presentation to their peers and staff on return from the year in industry. K11 and S12 are assessed via reports and a presentation. Group projects are completed at Levels 1, 2 and 4, over one or two semesters. Student teams are given topics (Level 1) or negotiate topics with their industrial clients or research sponsors (Levels 2, 4). Teams prepare analysis and design documents (Levels 1, 2), or draft research papers (Level 4), demonstrate a working software system (Levels 1, 2) or research solution involving software, designs or theories (Level 4), and provide a final report, together with timesheets, minutes and other evidence of their group management strategy. Credit is awarded to the team as a whole on the basis of the quality of the work, as evidenced in the final report, interim documentation (all Levels) and reported client satisfaction (Levels 2, 4). Credit is weighted towards individual team members based on their participation, as evidenced in the minutes, timesheets and other indicators of the division of workload and responsibility, which may include viva voce interviews. The learning outcomes S2, S4-S8 are directly assessed in software projects, together with K6-K7 in industrial projects. The learning outcomes S5-S7, S9 and S11 are directly assessed in research projects, which may also assess S2-S4 according to the type of project. Indirectly, K1-5, S1 may be assessed (all Levels) and K8-K10 (Level 4). Proportions of types of assessment by level can be found on the UniStats website:  HYPERLINK "http://unistats.direct.gov.uk/" \h http://unistats.direct.gov.uk/ 19. Reference points The learning outcomes have been developed to reflect the following points of reference: Subject Benchmark Statements  HYPERLINK "https://www.qaa.ac.uk/quality-code/subject-benchmark-statements" \t "_blank" https://www.qaa.ac.uk/quality-code/subject-benchmark-statements Framework for Higher Education Qualifications (2014)  HYPERLINK "https://www.qaa.ac.uk/docs/qaa/quality-code/qualifications-frameworks.pdf" \t "_blank" https://www.qaa.ac.uk/docs/qaa/quality-code/qualifications-frameworks.pdf University Vision and Strategic Plan  HYPERLINK "http://www.sheffield.ac.uk/strategicplan" \t "_blank" http://www.sheffield.ac.uk/strategicplan  HYPERLINK "https://sites.google.com/sheffield.ac.uk/year-in-industry-eng/preparing-for-placement/checklist?authuser=0" Faculty of Engineering Placement Guidelines and Checklist The pathway structure through the degree programme was determined originally by SARTOR, 3rd Edition, 1997, and updated in the light of the UK Standard for Professional Engineering Competence, which is the primary point of reference for degrees offering professional accreditation in engineering and related areas, such as computing. The degree programme is formally accredited by the British Computer Society (BCS). The prominence given to practical, industrially related project work is supported by the BCS and our Industrial Advisory Board, which includes leading companies such as IBM, Nvidia and ARM. The content of the modules at Levels 3 and 4 is directly informed by the research interests of the Department and so conforms to the University Mission Statement to provide research-led teaching. The workload fits comfortably within the guidelines laid down by the University, and is monitored by external examiners, who also review the content and standards of the programme.20. Programme structure and regulations Our degree programmes are designed with a common curriculum at Levels 1-2, broadening out into many advanced study paths at Levels 3-4. The common core, which is used on our existing Computer Science degrees, satisfies the requirements for accreditation by the British Computer Society. It also permits direct transfers between the related degrees in Computer Science, Software Engineering and Artificial Intelligence and Computer Science and delayed transfers from related dual honours programmes. The Computer Science with a Year in Industry degree is the most general of our degrees and has the least restriction on module choice. Year 1 (Level 1) has a fixed core of 120 credits consisting of five modules running through the year: Java Programming, Foundations of Computer Science (the underlying mathematics), Devices and Networks, Machines and Intelligence, and Introduction to Software Engineering, which involves a group systems development exercise which forms the foundation for other group software development modules in later years, and two single-semester modules: Web and Internet Technology, Introduction to Algorithms and Data Structures. Students also participate in a compulsory week-long Global Engineering Challenge. Based on the Engineers without Borders Challenge (a national challenge for engineering undergraduates), students from across the Faculty of Engineering work together in multi-disciplinary teams to tackle a real-world problem with a global perspective. Year 2 (Level 2) contributes to the final degree classification and has a completely fixed structure. One subject is taught throughout the academic year: Automata, Logic and Computation. The remaining topics are taught in single semester blocks. In the first semester the topics taught are Data Driven Computing, Systems Design and Security, and Functional Programming. In the Spring semester students cover Robotics, Logic in Computer Science, and participate in The Software Hut. This is an industrial group project developing software systems for external clients and continues the theme of group software development from the previous year. Students also take part in the compulsory week-long project Engineering: Youre Hired. Again working with students from other engineering disciplines, this project requires them to apply their technical skills and engineering judgement to develop proposals for a technical, industrially-relevant problem. Neither this cross-faculty group project nor the Level 1 Global Engineering Challenge are credit bearing, but both are compulsory for progression to level 3. The projects enable students to develop a range of professional and technical competences, including awareness of the global context of their decisions, communication skills, cultural agility and enterprising problem solving. Students may transfer freely between this programme and the single honours degree programmes (in Computer Science, Software Engineering and Artificial Intelligence and Computer Science) at any time up until the end of Level 2. Dual honours students may transfer back into the single honours programme at the previous Level. Transfers between MComp and BSc are also freely permitted up until the end of Level 2, at which point students must maintain a higher standard to continue on the MComp, otherwise they must transfer to the BSc. Resit examinations are held in August for Levels 1 and 2, though project-based assessments and some coursework cannot be repeated within the same year. Year 3 (Level 3) contributes to the final degree classification and consists of the core 40-credit Dissertation Project, 10-credit Finance and Law for Engineers, approved units to the value of 70 credits from a variety of research led topics such as: Adaptive Intelligence, Advanced Algorithms, Software Re-engineering, Computer Security and Forensics, The Intelligent Web, Speech Processing, 3D Computer Graphics, Text Processing, Theory of Distributed Systems, Modelling & Simulation of Natural Systems and Undergraduate Ambassadors Scheme in Computer Science. In order to remain on the Year in Industry degree, students will normally be required to attain an average of 55 or above at the end of years 1, 2 and 3 in order to continue on the programme. Students not meeting this will transfer onto the MComp in Computer Science (without the Year in Industry). Students must maintain a standard no lower than class 2/ii to proceed on the MComp degree, otherwise they may seek to graduate immediately under the BSc regulations. The Dissertation Project must be passed at the first attempt to gain honours and accreditation (see section 21). A student failing to graduate on the first attempt may repeat Level 3 once and hopefully graduate, but without honours. Year 4 (Year in Industry): In their penultimate year, students work in a company relevant to their degree for a minimum of 38 weeks. Throughout the placement year, students maintain an online skills-based journal. At the end of the placement, they use the journal to write a reflection report and give a presentation on the skills they have developed. The placement is assessed on a pass/fail basis and does not contribute to the degree classification: a pass in this placement year is required for the degree title to reflect the industry experience. Year 5 (Level 4) contributes to the final degree classification. Prior to 2018 entry, students must take one of or both of the 30-credit group Darwin Research Project and the 45 credit group project Genesys. From 2018 entry, students must undertake the Darwin Project, a year-long research-oriented group project, and may choose to undertake Genesys, an industry-focussed team project. Further topics are selected from the following research led modules: Testing and Verification in Safety Critical Systems, Machine Learning and Adaptive Intelligence, Software Development for Mobile Devices, Network Performance Analysis and Parallel Computing with Graphical Processing Units. There are also three follow-on courses from advanced modules in level 3: Natural Language Processing, Software and Hardware Verification, and Speech Technology. Finally, a variety of Level 4 versions of level three modules are offered in case a student regretted his/her module choice at Level 3. The extra modules are Text Processing, Speech Processing, 3D Computer Graphics, and Computer Security and Forensics. MComp students graduate on completing Level 4 successfully (see full regulations below). A student who, exceptionally, fails to meet the required standard (no lower than class 2/ii) may graduate with a BSc.Detailed information about the structure of programmes, regulations concerning assessment and progression and descriptions of individual modules are published in the University Calendar available on-line at  HYPERLINK "http://www.sheffield.ac.uk/calendar" \h http://www.sheffield.ac.uk/calendar.21. Student development over the course of study Level 1: Students learn the Java programming language, covering the basics of syntax, program construction and compiler tools. Later, they learn about object-oriented design, standard library packages, and how to use Javas self-documentation. Students learn about software lifecycles, the Unified Modelling Language (UML) design notation and the use of various Computer-Aided Software Engineering (CASE) tools. Through the Introduction to Software Engineering module, student teams learn how to pick up projects partway through the software lifecycle and progress them to the next stage. Students also acquire discrete mathematics for logic and formal specification, followed by matrix manipulation, and probability and statistics. Students learn about human and machine intelligence, and are trained in how to present a reasoned argument. Later, they learn how to program intelligent search algorithms in Java, and are introduced to data structures and algorithms in Computer Science. Students also learn about the software and protocols essential in todays Web based world. Level 2: Forms a foundation for the more advanced courses in Levels 3 and 4. Students learn the essential skills they will require as professional software engineers or computer scientists. The topics covered include the functional style of programming currently through the vehicle of Haskell. They learn about automata, formal languages and the theory of computation. The Systems Design and Security module extends their knowledge of program design techniques and includes an introduction to databases and security. They are introduced to machine learning and pattern processing in a module themed around the notion of data as a resource and to artificial intelligence and robotics. In the 2nd semester student teams compete in the Software Hut industrial project to deliver systems for external clients, applying the techniques and methods learned earlier. Level 3: The capstone achievement is the Dissertation Project, a major piece of research and development requiring initiative and problem-solving skills. The project starts with a review of relevant literature and technology followed by detailed analysis, design, implementation and testing, and a written dissertation. Students demonstrate their working systems at a poster session, run like a technology fair with industrial visitors. Students are also required to study Finance and Law for Engineers, which covers the legal and ethical framework in which software is developed and used. The COM third year taught modules are research led and the choice of module depends on the students interests and sometimes their choice of project. Year in Industry: Students will spend a year in a company relevant to their degree, working with an employer on graduate-level projects (or series of projects), applying and developing their knowledge and skills in the context of the employers area of work and within relevant time and funding constraints. In addition to an industry mentor, a university tutor will be in contact during the year, and where possible, will visit the student in their place of employment. The student will keep a skills-based journal of their professional development and will produce reports and a presentation covering their industry experience. Level 4: The capstone achievement is a group research project, the Darwin Project, which occupies a quarter (Darwin) of a students time during the year. Prior to 2018 entry, students may alternatively undertake Genesys, in which students work in a group to develop software for clients in industry and the public sector. In both of these modules, students learn to organise themselves professionally, holding structured meetings and producing action minutes. The groups act on their own initiative to determine strategy, make decisions, allocate resources and evaluate progress. In Darwin, the group works to solve a research problem, developing a research proposal initially and generating a publishable paper at the end, whilst in Genesys, the group develops software for clients in industry and the public sector. Students in both entry cohorts may optionally undertake both these modules, but for entry from 2018 the research-oriented Darwin Project is core. Other knowledge and skills acquired depend on the students personal interest (see above). Upon Graduation: Students successfully completing the programme graduate with Master of Computing (MComp) in Computer Science with a Year in Industry. Professional Development: Our degrees are accredited by the British Computer Society (BCS), the Chartered Institute for Computing and Information Systems. Accreditation recognises that a degree programme meets the requirement for the professional formation of a Chartered Information technology Professional, a Chartered Engineer or a Chartered Scientist, and so opens the way to these professional statuses. Students graduating with BSc Hons. in Computer Science automatically obtain Partial CITP, CEng and CSci Accreditation. Students graduating with MComp. in Computer Science automatically obtain Full CITP, CEng and CSci Accreditation. After gaining at least three years professional work experience in the computing and information systems field, MComp graduates may apply to the British Computer Society to obtain the status of Chartered Information Technology Professional and either Chartered Engineer or Chartered Scientist, as appropriate to their work.22. Criteria for admission to the programme Detailed information regarding admission to the programme is available at  HYPERLINK "http://www.shef.ac.uk/prospective/" \h http://www.shef.ac.uk/prospective/ The standard requirement is three A-levels, of which one must be in Mathematics. Other equivalent national and international qualifications are accepted; see  HYPERLINK "http://www.shef.ac.uk/dcs/undergrad" \h http://www.shef.ac.uk/dcs/undergrad for more details. Wider access is also offered to students lacking suitable A-level qualifications for science and engineering through the Foundation Year; see  HYPERLINK "/dcs/undergraduate/courses/foundationyear" \h /dcs/undergraduate/courses/foundationyear for more details. A general University of ߲ݴý admissions requirement is GCSE English. Non-native speakers of English must demonstrate suitable competence in the language. The preferred test is IELTS, though others are accepted. See the English Language Teaching Centre website  HYPERLINK "http://www.shef.ac.uk/eltc/" \h http://www.shef.ac.uk/eltc/ for more information.23. Additional information The Department of Computer Science is housed in the modern, purpose-built Regent Court building and has its own dedicated computing facilities. The Department is internationally recognised for its teaching and research (in the 2021 Research Excellence Framework (REF), 99% of our research was rated in the top two categories, meaning it is classed as world-leading or internationally excellent). Students are expected to find their own placement (either in the UK or abroad), although we are able to assist through the many contacts University staff have with industry. We regularly update students with details of companies with suitable placements. The University has a Student Placement Officer and Careers Officers, who brief students in Years 2 and 3 on CV writing, strategies for securing a placement and the practicalities of placement work. It is expected that students receive a salary for their work. The Year in Industry Tutor and the administrative staff maintain regular contact with the student and the placement provider throughout the year to check that the placement is going well. For all UK-based placements, a member of academic staff also visits the company. An international dimension is offered through the Study Abroad programme, in which students may spend part of their degree outside of the EU, or through the Erasmus+ programme, in which students may spend part of their degree in another EU/EEA country. See  HYPERLINK "http://www.sheffield.ac.uk/globalopps" http://www.sheffield.ac.uk/globalopps for more details. The Department offers course materials and information services to students via the departmental intranet. The Department of Computer Science Undergraduate Student Handbook governs all local aspects of academic student life, with regard to services offered, computer etiquette, and local regulations. See the Department of Computer Science website:  HYPERLINK "http://www.shef.ac.uk/dcs" http://www.shef.ac.uk/dcs for more information.This specification represents a concise statement about the main features of the programme and should be considered alongside other sources of information provided by the teaching department(s) and the University. In addition to programme specific information, further information about studying at ߲ݴý can be accessed via our Student Services web site at  HYPERLINK "http://www.shef.ac.uk/ssid/" \h http://www.shef.ac.uk/ssid/.     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