Schools Archives - Engineering Professors Council

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The following provides links to a range of resources and information to help university admissions tutors and those working in recruitment and admissions roles.

And each year, in November, the Engineering Professors’ Council organises a Recruitment and Admissions Forum so that all of those involved in the recruitment and admission of students to engineering programmes in UK higher education have the opportunity to get together and share experiences and best practice, as well as hear the latest from policy makers, the funding agencies and Government. We also provide feedback to members from the annual early enrolments survey, which provides an indication of student numbers compared with the prior year for both undergraduate and postgraduate (taught) students.

Don’t forget to check out the Tomorrow’s Engineers programme website which offers a wide range of resources to assist schools, prospective students and their advisers. The latest range, including a leaflet entitled ‘Make a Difference to the World: Engineering at University’ may be found here.

And do take a look at this set of films, produced by the 2014 winner of the EPC’s Engaging in Engineering awards, Dr Emma Carter of the University of Sheffield – aimed at 8 to 15 year olds, their particularly useful for schools outreach activity.

If you can’t find what you’re looking for on this page, why not ask a colleague by starting a discussion? Or feel free to drop us a line directly.

Contents:

Any views, thoughts, and opinions expressed herein are solely that of the author(s) and do not necessarily reflect the views, opinions, policies, or position of the Engineering Professors’ Council or the Toolkit sponsors and supporters.

The Recruitment and Admissions Toolkit has not been updated as yet but has been left here for archive purposes.

Engineering Council website: ‘Information for Students’.

In addition, the following are available on request from marketing@engc.org.uk, putting IEng/CEng in the subject line.

1. A ‘Student guide to professional registration with the Engineering Council’

2. An introductory email aimed at new undergraduates.

The Recruitment and Admissions Toolkit has not been updated as yet but has been left here for archive purposes.

The EPC routinely tracks applications trends at both undergraduate and postgraduate level across all of the engineering disciplines. We report and comment on these at our Recruitment and Admissions Forum, held in November annually. The latest may be accessed in our Data explorer.

UCAS scheduled statistical releases.

The Department for Business, Innovation and Skills published a report in December 2013 on the trends in applications and demand from students for postgraduate study.

The Recruitment and Admissions Toolkit has not been updated as yet but has been left here for archive purposes.

The EPC reviews and reports on graduate engineers’ ability to gain employment on leaving university. The latest information may be accessed by members in our Data explorer.

The Recruitment and Admissions Toolkit has not been updated as yet but has been left here for archive purposes.

A brief guide to the Scottish educational system: for admissions tutors elsewhere.

Pupils in Scotland move from primary to secondary school one year later than in England and (traditionally) from school to university one year earlier, around age 17. The state school system is almost entirely homogeneous and comprehensive. University degrees are a year longer to compensate for the earlier entry. Thus a BEng typically takes 4 years and MEng takes 5 years. Engineering programmes are usually specialised from the start but most Scottish bachelors degrees provide a broad programme in the first two years followed by specialised honours courses in the final two years; in general Scottish education places a higher emphasis on breadth than in England.

National qualifications are administered by a single Scottish Qualifications Authority (SQA). For many years pupils have taken the following set of examinations.

Standard grades around age 16 (S4/Y11). Pupils typically study around 8 standard grades; the number of courses has not proliferated as in England.
Highers after a further year (S5/Y12). The typical load is 5 Highers including English and Mathematics. These are the traditional exit qualifications, accepted for entry to the first year of Scottish degree courses. Many pupils leave school at this level.
Advanced Highers after another year (S6/Y13). Three Advanced Highers is regarded as a full load but many pupils take a mixture of Advanced Highers and further Highers for increased breadth, which is a deeply rooted feature of Scottish education.
Good grades in Advanced Highers are accepted for direct entry into the second year of Scottish degrees and for entry to universities elsewhere in the UK.
Advanced Highers except Mathematics include an extended practical investigation.
The Scottish Baccalaureate comprises two Advanced Highers, a further Higher and an interdisciplinary project, again encouraging breadth.

It is tempting to compare the qualifications with GCSE, AS and A levels but there are significant differences.

Highers and Advanced Highers are independent courses, not linked like AS and A2.
Most courses are taught as three units, which can be taken as standalone but ungraded qualifications. This is typically used to increase breadth; a unit of Higher Statistics is a common choice. Pupils must pass all units to complete a course but the results are not used in the overall assessment, which tests the course as a whole; it covers the units plus further ‘added value’ material that integrates the units. In other words, the courses are not modular in the ‘test and forget’ sense.
The smaller number of courses means that Scottish qualifications are generally regarded as being slightly stronger than their English equivalents. For example, Advanced Highers are about a grade above A levels: a B in Advanced Higher is roughly equivalent to an A in A level. This is recognised in the UCAS points tariff: AH A=130, B=110, C=90; A-level A*=140, A=120, B=100, C=80, although many Scots would argue that AH should receive somewhat higher scores.
The provision of Advanced Highers remains patchy; few schools offer a full range.
Further Mathematics is not available in Scotland although Advanced Higher Mathematics contains topics such as complex numbers that are no longer in Pure Mathematics A level (at least for some boards). Higher and Advanced Higher Mathematics of Mechanics are being introduced but their popularity is doubtful.

This picture is evolving as a result of the Curriculum for Excellence, currently progressing through secondary schools. Major changes have occurred in primary and the earlier years of secondary education but the impact on pre-university qualifications may be small.

Standard grades were examined for the last time in 2013, now replaced by National 5.
Highers and Advanced Highers are being revised (after another recent revision). My experience from review groups is that the sciences are using this as an opportunity to restore the academic level after some years of perceived decline. For example the description of Higher Physics says “Structurally, the question paper will be similar to Higher Physics and Revised Higher Physics. However, there will be less emphasis on recall questions and more emphasis on the application of knowledge and skills”. Unfortunately it is not clear how this aspiration can be applied to some of the newly introduced material, mostly astrophysical, which is largely descriptive.
Revised Higher Physics contains a new half-unit on Researching Physics but it is too early to gauge its value. It may prepare pupils better for the Advanced Higher Investigation. Other subjects except mathematics include a similar exercise.
Unfortunately there is less positive evidence about mathematics, where students suffer from the same problem of poor basic algebraic skills as in England. However, new courses in Lifeskills Mathematics are being introduced for pupils who need arithmetic more than algebra; this might relieve the pressure to teach traditional mathematics courses to weaker students and allow the curriculum to be strengthened.
Flexibility is a key feature of the Curriculum for Excellence. For example, it is suggested that pupils might omit National 5 and spend two years on Higher courses instead. They may spread their Higher exams over two years rather than one.
It is hard to know what opportunity will be taken with this flexibility. Most schools may retain National 5 to provide evidence on which future choices of subject can be based, for instance.
Engineering Science is a new suite of courses that replaces Technological Studies, whose popularity has declined. The main topics are electronics, control, mechanisms and structures. It is generally considered as an adjunct to physics rather than a replacement.

Helpful publications

Qualifications can cross boundaries: A rough guide to comparing qualifications in the UK and Ireland, produced jointly by QAA, Ofqual, the Scottish Credit and Qualifications Framework Partnership, CCEA Accreditation, the Credit and Qualifications Framework for Wales, and Quality and Qualifications Ireland, http://www.qaa.ac.uk/en/Publications/Documents/qualifications-can-cross-boundaries.pdf
Information for Universities on the New National Qualifications, SQA.
Scottish universities have issued statements on their approaches to the Curriculum for Excellence.
Information on Scottish Credit and Qualifications Framework Partnership for HEIs, SCQF.
Universities Scotland www.universities-scotland.ac.uk have published a guide Beyond the Senior Phase: University Engagement with Curriculum for Excellence They have also produced Implications of Curriculum for Excellence (CfE) in Scottish schools on admissions for universities in England, Wales & Northern Ireland https://www.universities-scotland.ac.uk/publications/cfe-for-the-rest-of-the-uk/

John Davies, revised 2014-12-06

The Recruitment and Admissions Toolkit has not been updated as yet but has been left here for archive purposes.

Developments in Pre-University Education Classification of Vocational Qualifications and the Tech Bacc.

There have been some developments as far as the Government’s classification of qualifications into ‘Technical Level’ (which was originally called ‘Occupational’), ‘Applied General’ and ‘Academic’. It is understood that ‘Occupational’ was meant to mean specialist craft/technician qualifications and the Government envisioned them not to be a “normal” route to higher education.

The scene changed considerably during 2014. The larger BTEC engineering qualifications have moved from being classified as ‘Applied General’ to ‘Technical Level’. Only the smaller BTEC Engineering Certificate (equivalent to one AS qualification) is left in the ‘Applied General’ category.

There may be two reasons for this:

Following the consultation (in 2013) the Government agreed that ‘Technical Level’ qualifications could be used for entrance to university.
The new Technical Baccalaureate (Tech Bacc) performance measure only recognises ‘Technical Level’ qualifications, not ‘Applied General’.

Relevant documents can be found at:

The City and Guilds Technical Baccalaureate

City and Guilds officially launched their ‘TechBac’ qualification in, among other subjects, Engineering, Construction and IT. (This should not be confused with the Government’s Tech Bacc which, like the EBacc, is not a qualification, merely a performance measure.) The TechBac claims to be a blend of technical qualifications, a project qualification and a work placement. There appear to be two Level 2 TechBac qualifications (presumably of different sizes). Both involve a free-standing ‘Level 2 Higher Project’ and either a Technical Award or Technical Certificate in Engineering. A Level 3 TechBac is termed an ‘Advanced TechBac’ and it comes in three sizes: Certificate, Extended Certificate and Diploma. All have the free-standing ‘Level 3 Extended Project’ as a mandatory component.

The Pearson Edexcel BTEC Nationals

Most of the Level 3 BTEC National qualifications are now in the Tech Level category and therefore qualify to be included in the Government’s Tech Bacc. The BTEC Nationals are being revised and teaching to the new specification will start in 2016. This means that university admission tutors are unlikely to see the new qualifications before the 2018 entry. There is very little detail at the time of writing this paper as to the content of the new qualifications.

Edexcel are changing the names of their national qualifications and the following table is an interpretation of the changes:

GLH*	A Level Equivalent	2010 National	2016 National
180	0.5	Certificate	—
360	1.0	Subsidiary Diploma	Award
540	1.5	90-Credit Diploma	Subsidiary Certificate
720	2.0	Diploma	Certificate
1080	3.0	Extended Diploma	Diploma

* GLH = Guided Learning Hours

One thing to note is that the various sizes of BTEC qualifications do allow the mixture of BTEC and A Level qualifications.

Currently, the best information on the 2016 Nationals can be found at:

https://qualifications.pearson.com/content/dam/pdf/BTEC-Nationals/general/Your_Quick_Guide_to_BTEC_Nationals_2016_Nov14.pdf

Developments at Level 2

Awareness of the new school performance measures, Progress 8 and Attainment 8, is increasing and they will certainly be a great improvement on the best-5 GCSEs, which they replace from 2016. The English Baccalaureate stays but its importance may decline.

There is a range of GCSE-sized engineering qualifications that have been approved by the Government to be counted in Progress-8 and Attainment-8 metrics. In the areas of engineering and construction, these include:

The new Person BTEC First Awards, including those developed in collaboration with the Royal Academy of Engineering as a replacement for the Level 2 Engineering Diploma;
OCR Cambridge Level 1/2 National Certificates;
WJEC Level 1/2 Awards.

University Technical Colleges (UTCs) are now able to blend GCSEs with these Level 2 vocational qualifications without their league table position being compromised. Up to 3 vocational qualifications can be included. Further information can be found at:

https://www.gov.uk/government/uploads/system/uploads/attachment_data/file/285990/P8_factsheet.pdf

Teaching of the new versions of GCSE Science qualifications are due start in 2016. The new much tighter Key Stage 4 specifications for science mean that the old modular structure for science will no longer be practical. Schools will not be able to mix the teaching of combined and single science subjects as the additional material covered in the single sciences is spread throughout the topics. The Combined Science GCSE will be double-weighted. No single Combined Science will be available. The new specifications can be found at:

The tighter specifications mean that there will be less variation between awarding bodies and that would have made the design of A level sciences easier – had their revision been delayed until 2018.

The Recruitment and Admissions Toolkit has not been updated as yet but has been left here for archive purposes.

UCAS provides a useful set of links to information about student finance in each of the devolved administrations:

The Recruitment and Admissions Toolkit has not been updated as yet but has been left here for archive purposes.

There is considerable anecdotal evidence that students who have studied Further Mathematics find the transition to the mathematics taught and used in an undergraduate engineering programme much easier. A report published by the Institute of Physics in 2011¹ found:

“Those students who had studied further mathematics to A- or AS-level standard reported coping better with the mathematical content of the degree, and as such perceived that they required less additional support throughout their studies. Many students and academics felt that studying further mathematics should therefore be made a requirement of studying physics or engineering at university.”

It seems then, that is in the interests of engineering departments that more students study Further Mathematics, at least to AS level, which introduces them to complex numbers and matrices and extends their algebraic abilities.

But one of the main obstacles to future growth in the number of students taking Further Mathematics is the cost to many schools and colleges of running courses for relatively few students. Universities can play a key role in further increasing the number of students taking Further Mathematics by providing clear encouragement to students to do so through their admissions policies and in course planning.

Admissions statements and entry requirements which emphasise the importance of Further Mathematics have a strong influence on students’ subject choices and have helped to create the demand from students for Further Mathematics. The Russell Group report “Informed Choices”, which lists Further Mathematics as a facilitating subject has helped many school and college mathematics departments make the case for more Further Mathematics provision.

Engineering departments can help to promote the study of Further Mathematics and improve the prior knowledge of their students. Some examples which have been used successfully by HE mathematics departments are:

Including encouraging statements in admissions literature about the benefits of studying full A Level or AS Level Further Mathematics;
Indicating the proportion of undergraduates currently studying a particular course with A or AS Level Further Mathematics qualifications;
Offering bursaries/scholarships to students with Further Mathematics qualifications;
Differentiating the grades in the offer for students with Further Mathematics;
Making A or AS Level Further Mathematics a requirement for the course.

Working to promote engineering applications

The Advanced Mathematics Support Programme (AMSP) is a government-funded initiative, supported by the Department for Education and is managed by Mathematics in Education and Industry (MEI). The MEI website contains a range of resources for both teachers and students of Maths and Advanced Maths.

The Advanced Mathematics Support Programme is able to provide information for teachers and students about STEM degree courses, including the Advanced Mathematics requirements, via its network of Area Coordinators, through newsletters and at AMSP events.

These information sheets are of particular interest:

Further Maths [now Advanced Maths] Briefing for Higher Education (2013)

The current content of AS and A2 Further Mathematics (2013)

..and a network of regional university-based representatives is available for local support.

See also details and resources available from the Sigma organisation which has received HEFCE funding to enable any higher education institution in England to tap into a wealth of expertise and resources which it has developed. Sigma, established in 2005, has been a driving force in the creation of university-wide centres dedicated to helping students to develop and improve mathematical and statistical skills. It is led by Professors Tony Croft from Loughborough University and Duncan Lawson from Newman University.

The Recruitment and Admissions Toolkit has not been updated as yet but has been left here for archive purposes.

The Engineering for Growth website acts as a central hub for partner news and Engineering for Growth activities and events and also offers resources such as images and industry statistics which members may find helpful in developing student recruitment materials.
Big Bang Fair
IET – routes to engineering
IMechE scholarships
Institution of Civil Engineers – education & resources
The Student Room – engineering
Tomorrow’s Engineers
Why not Chem Eng?
Women in Science and Engineering (WISE)
Primary Engineer
Emma Carter’s EPC-funded Engenius Films Vimeo Channel
Engineering Development Trust