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A need for Restructuring of Engineering Education

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Title: A need for Restructuring of Engineering Education


1
A need for Restructuring ofEngineering Education
  • Saad M.A. Suliman and Hussain M.N. Al-Madani
  • College of Engineering, University of Bahrain

2
Contents
  • Introduction
  • Current Assessment of Engineering Education at
    UOB
  • Degree Structure
  • Pre-engineering component
  • Engineering component
  • Professional Engineering Component
  • Conclusion

3
1. Introduction
  • Accusations
  • Engineering education is accused for
  • poor teaching,
  • low productivity,
  • decaying infrastructure,
  • out dated curricula, and
  • lax management.

4
  • Challenges
  • Education is exposed to
  • Economical pressure
  • increased cost, and paradoxically increased
    competition
  • Technological pressure
  • rapidly evolving applications of
    information-related technologies, increasing pace
    of technological change
  • Social pressure
  • growing need for "professional" engineers
  • need for relevant and life-long learning programs

5
  • Other Challenges include
  • declining quality of high-school graduates
  • weak link between academia and industry.

6
2. Current Assessment of Engineering Education
  • For reassessment of its academic programs,
    curriculum, and teaching practices, College of
    Engineering of UOB carried out surveys to seek
    feedback from
  • enrolled students
  • graduates
  • faculty
  • industry
  • The data showed strengths and weaknesses of the
    current engineering education system.

7
  • Results are more disappointing with the students'
    background in mathematics, basic science and
    English language.
  • This is basically due to the low standard of
    intake to College of Engineering from secondary
    schools.

8
  • Feedback from both alumni and industry showed
    that students are short in
  • practical engineering knowledge and
    hands-on-experience,
  • information technology and computer usage,
  • management skills
  • environment and safety awareness.

9
  • Evaluation results of the engineering programs
    were presented and debated in the Symposium on
    Development and Enhancement of Engineering
    Education (24-25th February 2004)

10
  • The symposium concluded that there are pressing
    needs for revision of curriculum and other
    components of the engineering education system,
    i.e.
  • teaching methods and style, and
  • quality assurance.

11
3. Degree Structure
  • An integrated six-year program leading to M. Eng.
    Would be desirable to respond to the growing
    need for professional engineers.

12
  • The six-year program is to be partioned into
    three components
  • a two-year pre-engineering component taught by
    community colleges
  • a three-year engineering component Leading to B.
    Eng.,
  • one-year professional engineering component
    leading to M. Eng.

13
3.1 Pre-engineering component
  • Pre-engineering program is intended to provide
    better qualified and mature juniors to enter a
    professional engineering program.
  • To curb the growing costs challenge it is run by
    community colleges under the umbrella of the
    universities or independently.

14
  • It is devoted to fundamental courses in
    mathematics, science (Physics Chemistry),
    computing, English communication capabilities,
    and basic courses in design and analysis.
  • Introduction to humanitarian and social sciences
    that are related to engineering studies.

15
3.2 Engineering component
  • To overcome the weaknesses of the current
    engineering education system, its major
    constituents are revised
  • specialty structure,
  • curriculum structure,
  • course structure, and
  • learning methodology and style.

16
Specialty structure
  • Current system focuses on graduating and training
    of engineering personnel of general specialties
    within specific disciplines.
  • Current programs are less attractive because of
    their
  • overemphasis on disciplines,
  • too elaborate division of specialties with too
    narrow range of coverage, and
  • the lack of elasticity in the curriculum.

17
  • A growing need for renewing or reforming old
    specialties and programs to meet the new
    challenges.
  • Rather than current traditional engineering
    programs in mechanical, electrical, electronic,
    chemical, and civil engineering, programs that
    are directed to fulfill the needs of specific
    sectors in industry and society are needed.

18
  • Programs that qualify engineering graduates in
  • Power generation transmission
  • Water production
  • Aluminium and steel processing
  • Petroleum petrochemicals
  • Communications electronics
  • Roads and transportation
  • Buildings, construction and refrigeration
  • Sewage water treatment

19
  • Each of the above areas is a multi-disciplinary
    area requiring resources from different
    engineering departments.
  • Such structure resembles a cellular structure of
    a production system in engineering management
    terminology.
  • Other areas of interest to community can be added
    to the above list, or alternatively some of the
    traditional programs may run in parallel with the
    proposed programs.

20
Curriculum structure
  • The engineering component is divided into three
    phases
  • first year for engineering science and design
    phase
  • second year for industry exposure phase and
  • third year for professional skills phase.
  • A PBL modular structure is recommended for this
    three years sandwich program.

21
  • Modules of the first phase may be allocated along
    the following scheme
  • Statistics, differential mathematics numerical
    methods group 1 to 2 modules
  • Basic engineering group 4 to 5 modules
  • Design group 3 modules
  • Production and operation group 4 modules
  • maintenance group 2 modules.
  • Each module includes three problems with duration
    of one week per problem.

22
  • Inclusion of the industry exposure modules is
    needed to overcome the following difficulties
  • The classroom environment is organized and
    structured in different way from that of
    industry.
  • Engineering courses present information
    structured in terms of single disciplines while
    industry problems are solved with
    cross-disciplinary techniques.

23
  • In this phase of curriculum, students undergo
    supervised industrial training periods in related
    industries.
  • Industry exposure phase covers three groups of
    modules with an average of five modules each
  • design focused projects.
  • production focused projects.
  • operation and maintenance focused projects.

24
  • The success of the whole program depends on
    sponsorships provided by industry to accommodate
    engineering students during exposure to industry
    component.

25
  • Professional skills phase continuation of
    engineering science and design phase.
  • Nine modules are assigned to
  • specialized subjects
  • soft skills, environment and safety awareness
    subjects.
  • Six modules are allocated for graduation project.

26
Course structure
  • In view of the sharp paradox between ever
    increasing course content and the relatively
    fixed teaching time, the following measures
    should be taken.

27
  • Discarding or merging courses and adding new
    topics. Focal point of course construction
    should shift from reform of single courses to
    development and construction of a series of
    course modules.
  • Provision of multi-level modules for some core
    courses, i.e. basic modules, expansive modules,
    and improving modules.

28
  • Strengthening the internal links between courses.
  • Expanding module-based structure to include
    major-minor system, so that students can become
    of compound personnel.
  • Emphasis is laid on application of theories
    rather than deduction of theories.

29
3.3 Professional Engineering Component
  • The final stage of the integrated 2-3-1
    engineering education program is the professional
    engineering component in which 10 - to 12 modules
    are offered.
  • Each module is four weeks length.

30
  • Modules include
  • Selected advanced topics.
  • Training in scientific experimentation and
    engineering practice.
  • Soft skills and management courses of advanced
    contents.

31
4. Conclusion
  • Though the current curricula of engineering
    education conforms to international standards,
    nevertheless reform is needed.
  • Reform of current engineering education system
    call for revision of curriculum, teaching methods
    and styles, and quality assurance.

32
  • Other issues that to be considered, during the
    revision process, include
  • alternatives to traditional engineering programs,
  • education of engineers for international
    practice,
  • university-industry interaction, and
  • social status of engineers.

33
  • Thank you for listening.
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