SAQA

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SOUTH AFRICAN QUALIFICATIONS AUTHORITY

REGISTERED QUALIFICATION:

Bachelor of Engineering in Computer and Electronic Engineering

SAQA QUAL ID	QUALIFICATION TITLE
112991	Bachelor of Engineering in Computer and Electronic Engineering
ORIGINATOR
North West University
PRIMARY OR DELEGATED QUALITY ASSURANCE FUNCTIONARY			NQF SUB-FRAMEWORK
CHE - Council on Higher Education			HEQSF - Higher Education Qualifications Sub-framework
QUALIFICATION TYPE	FIELD		SUBFIELD
National First Degree(Min 480)	Field 06 - Manufacturing, Engineering and Technology		Engineering and Related Design
ABET BAND	MINIMUM CREDITS	PRE-2009 NQF LEVEL	NQF LEVEL	QUAL CLASS
Undefined	480	Not Applicable	NQF Level 08	Regular-Provider-ELOAC
REGISTRATION STATUS		SAQA DECISION NUMBER	REGISTRATION START DATE	REGISTRATION END DATE
Reregistered		EXCO 0821/24	2021-07-01	2027-06-30
LAST DATE FOR ENROLMENT		LAST DATE FOR ACHIEVEMENT
2028-06-30		2034-06-30

In all of the tables in this document, both the pre-2009 NQF Level and the NQF Level is shown. In the text (purpose statements, qualification rules, etc), any references to NQF Levels are to the pre-2009 levels unless specifically stated otherwise.

This qualification does not replace any other qualification and is not replaced by any other qualification.

PURPOSE AND RATIONALE OF THE QUALIFICATION

Purpose:
The primary purpose of the qualification is to provide a well-rounded, broad education that equips qualifying learners with the knowledge base, theory and methodology of Computer and Electronic Engineering. Also, it is to enable them to demonstrate initiative and responsibility in an academic or professional context. This qualification prepares learners for professional training, Postgraduate studies or professional practice in the field of Engineering. The Bachelor of Engineering in Computer and Electronic Engineering provides learners with a foundation in the knowledge, philosophy, principles and skills in the Mechanical Engineering profession. The qualification provides learners with the ability to apply these to professional or career contexts.

Rationale:
Engineering is a discipline and profession that serves the needs of society and the economy. The qualification is designed to contribute to meeting this need by developing engineering competence. The qualification, with its broad fundamental base, is the starting point of a career path in one of many areas of engineering specialisation through structured development and lifelong learning. The broad base allows maximum flexibility and mobility for the holder to adjust to changing needs. Skills, knowledge, values and attitudes reflected in the qualification are building blocks for the development of learner engineers towards becoming competent engineers. To ultimately lead complex engineering activities and solve complex engineering problems, thus contributing to economic activity and national development.

LEARNING ASSUMED TO BE IN PLACE AND RECOGNITION OF PRIOR LEARNING

Recognition of Prior Learning (RPL):
Where learners do not meet the minimum admission requirements, RPL may be used to grant access to the qualification. The application of RPL is according to the Recognition of Prior Learning, Credit Accumulation and Transfer, and assessment (CHE 2016) and the institution's RPL policy.

The Faculty of Health Sciences ensures the implementation of quality assurance processes in the RPL process (including applications, assessment, and reporting and management systems). It also ensures that administrative and support systems, both before and after RPL assessment, are in place.

Entry Requirements:
The minimum entry requirement for this qualification is:

A National Senior Certificate, NQF Level 4, granting access to Bachelor studies.

RECOGNISE PREVIOUS LEARNING?

QUALIFICATION RULES

This qualification consists of the following compulsory modules at National Qualifications Framework Levels 5, 6, 7 and 8 totalling 624 Credits.

Compulsory Modules Level 5, 164 Credits.

Academic Literacy Development, 12 Credits.

Programming for Engineers, 12 Credits.

Engineering Graphics I, 12 Credits.

Introductory Algebra and Calculus I, 12 Credits.

Basic Physics I, 12 Credits.

Introduction to Digital Systems, 12 Credits.

Statics and Mathematical Modelling, 12 Credits.

Electrotechnique I, 8 Credits.

Materials Science I, 16 Credits.

Introductory Algebra and Calculus II, 12 Credits.

Basic Physics II, 12 Credits.

Introduction to Microcontrollers, 12 Credits.

Practical Engineering Practice, 8 Credits.

Compulsory Modules Level 6, 172 Credits.

Electrotechnique II, 8 Credits.

Electricity and Magnetism, 8 Credits.

Dynamics I, 8 Credits.

Differential Equations, 8 Credits.

Advanced Calculus I, 8 Credits.

Linear Algebra I, 8 Credits.

Algorithms and Optimisation, 8 Credits.

Understanding the Technological World, 12 Credits.

Signal Theory I, 16 Credits.

Electronics I, 16 Credits.

Linear Systems, 12 Credits.

Numerical Methods, 8 Credits.

Engineering Analysis, 8 Credits.

Applied Linear Algebra, 8 Credits.

Embedded Systems, 12 Credits.

Fundamental Engineering Application Programme II, 24 Credits.

Compulsory Modules Level 7, 168 Credits.

Electromagnetics, 16 Credits.

Electronics II, 16 Credits.

Network Fundamentals, 16 Credits.

Object-oriented Software Development, 16 Credits.

Engineering Statistics, 16 Credits.

Control Theory I, 16 Credits.

Embedded Operating Systems, 16 Credits.

Computer Engineering Design, 16 Credits.

Signal Theory II, 16 Credits.

Principles of Measurement, 12 Credits.

Science, Technology and Society, 12 Credits.

Compulsory Modules Level 8, 120 Credits.

Signal Theory III, 16 Credits.

Telecommunication Systems, 16 Credits.

Control Theory II, 16 Credits.

Databases and Web-programming, 16 Credits.

Data Analysis, 12 Credits.

Engineering Management, 12 Credits.

Vacation Training Seniors, 8 Credits.

Project (year module), 24 Credits.

EXIT LEVEL OUTCOMES

1. Demonstrate competence to identify, assess, formulate and solve convergent and divergent engineering problems creatively and innovatively.
2. Demonstrate competence to apply knowledge of mathematics, basic science and engineering sciences from first principles to solve engineering problems.
3. Demonstrate competence to perform creative, procedural and non-procedural design and synthesis of components, systems, engineering works, products or processes.
4. Demonstrate competence to design and conduct investigations and experiments.
5. Demonstrate competence to use appropriate engineering methods, skills and tools, including those based on information technology.
6. Demonstrate competence to communicate effectively, both orally and in writing, with engineering audiences and the community at large.
7. Demonstrate critical awareness of the impact of engineering activity on the social, industrial and physical environment.
8. Demonstrate competence to work effectively as an individual, in teams and multidisciplinary environments.
9. Demonstrate competence to engage in independent learning through well-developed learning skills.
10. Demonstrate critical awareness of the need to act professionally and ethically and to exercise judgment and take responsibility within own limits of competence.

ASSOCIATED ASSESSMENT CRITERIA

Associated Assessment Criteria for Exit Level Outcome 1:

Analyse and define the problem, identifies the criteria for an acceptable solution.

Identify necessary information and applicable engineering and other knowledge and skills.

Generate and formulate possible approaches to the solution of a problem.

Models and analyses possible solution(s).
Evaluate possible solutions and selects the best solution.
Formulate and present the solution in an appropriate form.

Associated Assessment Criteria for Exit Level Outcome 2:
The learner:

Brings mathematical, numerical analysis and statistical knowledge and methods to bear on engineering problems by using an appropriate mix of:
> Formal analysis and modelling of engineering components, systems or processes.
> Communicating concepts, ideas and theories with the aid of mathematics.
> Reasoning about and conceptualising engineering components, systems or processes using mathematical concepts.
> Deal with uncertainty and risk through the use of probability and statistics.

Use physical laws and knowledge of the physical world as a foundation for the engineering sciences and the solution of engineering problems by an appropriate mix of:
> Formal analysis and modelling of engineering components, systems or processes using principles and knowledge of the basic sciences.
> Reasoning about and conceptualising engineering problems, components, systems or processes using principles of the basic sciences.

Use the techniques, policies and laws of engineering science at a fundamental level and in at least one specialist area to:
> Identify and solve open-ended engineering problems.
> Identify and pursue engineering applications.
> Work across engineering disciplinary boundaries through cross-disciplinary literacy and shared fundamental knowledge.

Associated Assessment Criteria for Exit Level Outcome 3:

Identify and formulate the design problem to satisfy user needs, applicable standards, codes of practice and legislation.

Plan and manage the design process: focus on essential issues, recognises and deals with constraints.

Acquire and evaluate the requisite knowledge, information and resources: applies correct principles, evaluate and use design tools.

Perform design tasks including analysis, quantitative modelling and optimisation.

Evaluate alternatives and preferred solution: exercises judgment, tests implementation and performs techno-economic analyses.

Assess the impacts and benefits of the design: social, legal, health, safety, and environmental.

Communicate the design logic and information.

Associated Assessment Criteria for Exit Level Outcome 4:

Plan and conduct investigations and experiments.

Conduct a literature search and critically evaluates material.

Perform necessary analyses.

Select and use appropriate equipment or software.

Analyse, interpret and derive information from data.

Draw conclusions based on evidence.

Communicate the purpose, process and outcomes in a technical report.

Associated Assessment Criteria for Exit Level Outcome 5:

Use method, skill or tool effectively.

Select and assess the applicability and limitations of the method, skill or tool.

Apply the method, skill or too correctly.

Test and assess the end-results produced by the method, skill or tool critically.

Create computer applications as required by the discipline.

Associated Assessment Criteria for Exit Level Outcome 6:

Use appropriate structure, style and language for purpose and audience.

Use effective graphical support.

Apply methods of providing information for use by others involved in engineering activity.

Meet the requirements of the target audience.

Use appropriate structure, style and language.

Use relevant visual materials.

Associated Assessment Criteria for Exit Level Outcome 7:
The learner identifies and deals with an appropriate combination of issues in:

The impact of technology on society.

Occupational and public health and safety.

Impact on the physical environment.

The personal, social, cultural values and requirements of those affected by engineering activity.

Associated Assessment Criteria for Exit Level Outcome 8:

Identify and focus on objectives.

Work strategically.

Execute tasks effectively.

Deliver completed work on time.

Make individual contribution to team activity.

Perform critical functions.

Enhance the work of fellow team members.

Benefit from the support of team members.

Communicate effectively with team members.

Deliver completed work on time.

Acquire a working knowledge of co-workers' discipline.

Use a systems approach.

Communicate across disciplinary boundaries.

Associated Assessment Criteria for Exit Level Outcome 9:

Reflect on your learning and determines learning requirements and strategies.

Source and evaluate information.

Access comprehend and apply knowledge acquired outside formal instruction.

Challenges assumptions and embraces new thinking.

Associated Assessment Criteria for Exit Level Outcome 10:

Be aware of requirements to maintain competence and to keep abreast of up-to-date tools and techniques.

Display an understanding of the system of professional development.

Accept responsibility for own actions.

Display judgment in decision making during problem solving and design.

Limit decision making to area of current competence.

Reason about and make judgment on ethical aspects in case study context.

Discern boundaries of proficiency in problem solving and design.

Integrated Assessment:
Formative assessment:

Homework, class tests, semester tests, practical reports, assignments.

Summative assessment:

Examination.

INTERNATIONAL COMPARABILITY

Country: United Kingdom.

Institution: University of Manchester.

Qualification Title: Bachelor of Engineering in Computer Systems Engineering.

The Bachelor of Engineering in Computer Systems Engineering is similar to the qualification at the University of Manchester. The main focus is on knowledge and skills to develop computer-based systems with real-time response. The qualifications have a focus on sophisticated electronic systems that permeate all aspects of life such as microprocessors, memory, a communications capability, application-specific hardware and software.

Country: New Zealand.

Institution: University of Auckland.

Qualification Title: Bachelor of Engineering (Honours) in Computer Systems Engineering.

The University of Auckland offers a Bachelor of Engineering (Honours) in Computer Systems Engineering qualification, which is similar to the qualification at the institution, in terms of the purpose of the qualification and duration of study. Both these qualifications focus on the discipline's foundations so that learners can adapt to its rapid pace of change and fulfil the need for professionals in an increasingly broad range of industries. Qualifying learners in both qualifications get essential skills to consider practical engineering problems with computer-based solutions. Often by embedding a computer system into a complex operation that can sense, problem-solve and act in the real world.

ARTICULATION OPTIONS

This qualification allows possibilities for both vertical and horizontal articulation:

Horizontal Articulation:

Postgraduate Diploma in Engineering, NQF Level 8.

Vertical Articulation:

Master of Engineering in Computer and Electronic Engineering, NQF Level 9.

MODERATION OPTIONS

N/A

CRITERIA FOR THE REGISTRATION OF ASSESSORS

N/A

NOTES

N/A

LEARNING PROGRAMMES RECORDED AGAINST THIS QUALIFICATION:

NONE

PROVIDERS CURRENTLY ACCREDITED TO OFFER THIS QUALIFICATION:

This information shows the current accreditations (i.e. those not past their accreditation end dates), and is the most complete record available to SAQA as of today. Some Primary or Delegated Quality Assurance Functionaries have a lag in their recording systems for provider accreditation, in turn leading to a lag in notifying SAQA of all the providers that they have accredited to offer qualifications and unit standards, as well as any extensions to accreditation end dates. The relevant Primary or Delegated Quality Assurance Functionary should be notified if a record appears to be missing from here.

1.	North West University