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All qualifications and part qualifications registered on the National Qualifications Framework are public property. Thus the only payment that can be made for them is for service and reproduction. It is illegal to sell this material for profit. If the material is reproduced or quoted, the South African Qualifications Authority (SAQA) should be acknowledged as the source. |
| SOUTH AFRICAN QUALIFICATIONS AUTHORITY |
| REGISTERED QUALIFICATION: |
| Master of Engineering in Satellite Systems and Applications |
| SAQA QUAL ID | QUALIFICATION TITLE | |||
| 111149 | Master of Engineering in Satellite Systems and Applications | |||
| ORIGINATOR | ||||
| Cape Peninsula University of Technology | ||||
| PRIMARY OR DELEGATED QUALITY ASSURANCE FUNCTIONARY | NQF SUB-FRAMEWORK | |||
| CHE - Council on Higher Education | HEQSF - Higher Education Qualifications Sub-framework | |||
| QUALIFICATION TYPE | FIELD | SUBFIELD | ||
| Master's Degree | Field 06 - Manufacturing, Engineering and Technology | Engineering and Related Design | ||
| ABET BAND | MINIMUM CREDITS | PRE-2009 NQF LEVEL | NQF LEVEL | QUAL CLASS |
| Undefined | 180 | Not Applicable | NQF Level 09 | Regular-Provider-ELOAC |
| REGISTRATION STATUS | SAQA DECISION NUMBER | REGISTRATION START DATE | REGISTRATION END DATE | |
| Reregistered | EXCO 0821/24 | 2019-08-19 | 2027-06-30 | |
| LAST DATE FOR ENROLMENT | LAST DATE FOR ACHIEVEMENT | |||
| 2028-06-30 | 2031-06-30 | |||
| 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 Master of Engineering in Satellite Systems and Applications is to educate and train engineers, technologists and researchers who can effectively contribute to the development of knowledge at an advanced level, as required for the space industry. This qualification is intended to enable learners to apply integrated technical knowledge, advanced skills, analysis and problem-solving techniques to particular specialisations in the field of Space Engineering and Applications. Learners are immersed in a state-of-the-art environment and provided with advanced nanosatellite technology platforms that facilitate cutting-edge research in a number of niche areas in the broader discipline of satellite systems and applications, including, technology development at the subsystem and fully integrated satellite levels, space-based services and applications. Furthermore, the participation of leading space experts will ensure that students benefit from global exposure and will provide an inter-disciplinary qualification that exposes participants to all key aspects of space engineering, technology and applications. The research and innovation emanating from the qualification will contribute to the development of satellite engineering, technology and applications to support the National and African Space Programmes. The qualification will furthermore provide access to a pool of highly developed knowledge, maintain databases and promote knowledge sharing and transfer in support of the National Space Landscape. The collective purpose of the qualification is to produce learners that have a deep theoretical understanding of engineering and applications in the space environment, with the ability to apply this knowledge in a vibrant research and innovation ecosystem with actual satellite hardware, and to synthesise space-based engineering solutions in a multi-disciplinary environment to support the national and regional space industries. Qualifying learners would have developed a high level of intellectual independence through their engagement with theoretical coursework and project-based applied research in the areas of Satellite Systems and Applications. These attributes are developed through a range of modules dealing with complex issues in the satellite systems space, where solutions are driven by both systematic and creative design. The module outcomes are driven by carefully selected overarching material. A successful dissertation further emphasises the learner's ability to critically appraise information from a range of sources, make judgements through the application of sound theory and communicate their conclusions to specialist and non-specialist audiences. Learners can be employed in a number of satellite engineering phases, including design and development of subsystems; systems and full satellite missions; assembly, integration and environmental testing of satellites; operating satellite missions, development of applications and services based on satellite data; project management of satellite mission's development, and management of the respective phases. Rationale: Research activities are alligned strategically with the national needs and the continuing imperative for social and economic transformation to remain responsive to the economic and societal needs of the country and the continent. From a national perspective, South Africa has become increasingly dependent on space-based applications to manage its national resources and to support its safety and security objectives. It is therefore not difficult to grasp why the DST has identified Space Science (and its supporting technologies) as one of the five 'Grand Challenges' to be addressed in its Ten-Year Innovation Plan of 2008. The establishment of the South African National Space Agency (SANSA) in 2010 signalled a coherent approach to the development of space-based research, engineering and technology innovation in South Africa. The National Space Strategy states three key priority areas that a space technology platform must deliver on, namely: environmental resource management; health, safety and security; and innovation and economic growth. Within these priority areas, the Strategy identifies the following key objectives: The qualification will address all of these objectives through its multi-disciplined human capacity development for the national and regional space industries by developing research, improving postgraduate output and incubating industry-driven technology innovation to address the societal needs of Africa. The focus on nanosatellites enables the qualification to bridge the innovation chasm that implicitly exists due to the inhibitive high technology and resource threshold of bigger satellites. Internationally, there is an acknowledgement of this paradigm shift that nanosatellites have brought about in the space industry. From an industry stakeholder perspective, the South African National Space Agency (SANSA) supports the implementation of the qualification. SANSA recognises the gap in South African academic qualifications to develop the technical skills to support the space industry. In developing their long-term Space Industry Development Framework, SANSA sees institutions playing a significant role towards human capital development. The qualification addresses these current gaps within the space industry (Furthermore, the African Union is committed to the development of an indigenous space industrial capability. The qualification will consequently serve the skills and technological requirements of the national and regional space industries at a pivotal time of their development. In order to provide learners with a deeper theoretical foundation to prepare them for Postgraduate research, a professional Master's qualification with a focus on Satellite Systems and Applications is required. This is especially relevant to this field, where Undergraduate and graduate degrees do not prepare the learners sufficiently for postgraduate research in this highly specialised field. The discipline covers a range of related engineering fields, namely Electrical, Mechanical, Industrial, and Mechatronics Engineering. Learners with a NQF Level 8 qualification in any of these fields can enter the qualification. The qualification combines aspects of both technology and applications, which provide learners with a skills set of appreciating and understanding the interplay between user-responsive applications and the technology that supports it. This holistic approach is unique in South Africa and will provide learners with a competitive edge in the market, as well as benefit the industry through employing these individuals. Learners who enrol for this qualification will be able to articulate to the international Master of Science with appropriate augmentation of the coursework and research project. |
| LEARNING ASSUMED TO BE IN PLACE AND RECOGNITION OF PRIOR LEARNING |
| Recognition of Prior Learning (RPL):
The institutional Recognition of Prior Learning (RPL) policy will be applied to learners who seek to join the qualification via this route. The intent of the policy speaks to the institution's commitment to align with the principles of the National Qualifications Framework (NQF) and the National Plan for Higher Education in South Africa. Specific reference is given to broadening the social base of higher education, increasing access to higher education, increasing the mobility of learners across higher education institutions, accelerating progress through learning qualifications, increasing the number of graduates and developing staff. RPL considers formal, non-formal and informal learning in granting a status to learners based on their prior learning type, either for "access" or "advanced standing" or a combination of the two. If applicant learner has considerable work experience but does not meet the entry requirements of this qualification, the learner may apply for entry into this qualification through RPL. This is referred to as "access". Applicant learner might have gained knowledge and/or experience in specific areas when compared to the outcomes against this qualification that might cover some subjects. The learner may apply for recognition of these subjects and this is called "advanced standing". The learner indicates the reason for applying for recognition of previous learning that could be the entrance to the qualification or exemption from certain modules in the qualification. The institution will determine the criteria for the recognition of prior learning based on the request (could be admission requirements of the qualification, assessment of exit level outcomes of modules for which exemption are requested or approved guidelines required by the industry). The learner must submit a portfolio of evidence of learning in place (what the applicant knows). Entry Requirements: The minimum entry requirement for this qualification is: Or Or Or |
| RECOGNISE PREVIOUS LEARNING? |
| Y |
| QUALIFICATION RULES |
| This qualification consists of the following compulsory and elective modules at Level 9 totalling 180 Credits.
Compulsory Modules, 165 Credits: Elective Modules, 15 Credits: Or |
| EXIT LEVEL OUTCOMES |
| 1. Demonstrate specialist knowledge through the interrogation and evaluation of multiple sources in the design and application of satellite technology and apply and critique advanced techniques from a range of methods in the processing, analysis, and interpretation of complex problems in the field of satellite systems and applications.
2. Understand the unique complexities of satellite systems and applications and are able to select and apply appropriate design procedures, processes, and techniques associated with the development of space mission planning strategies that are suitable for high-reliability environments. 3. Acquire advanced, specialist knowledge to identify, conceptualise, design and implement satellite technological solutions and use design concepts and application of appropriate methods in addressing user-responsive satellite applications. 4. Understand and commit to professional ethics, responsibilities, and norms in the peaceful and sustainable use of outer space. 5. Communicate effectively, both orally and in writing, within the context of satellite systems and applications, utilising advanced computer literacy skills to enhance communications. 6. Take interventions at an appropriate level within a system, based on an understanding of hierarchical relations within the system and the ability to address the intended and unintended consequences of intervention. 7. Develop his or her own life-long learning strategies, which sustain independent learning and academic or professional development and can interact effectively within the learning or professional groups as a means of enhancing learning. 8. Operate independently and take full responsibility for his or her own work and where appropriate, to account for leading and initiating processes and implementing systems, ensuring good resources management and governance practices. |
| ASSOCIATED ASSESSMENT CRITERIA |
| Associated Assessment Criteria for Exit Level Outcome 1:
Associated Assessment Criteria for Exit Level Outcome 2: Associated Assessment Criteria for Exit Level Outcome 3: Associated Assessment Criteria for Exit Level Outcome 4: Associated Assessment Criteria for Exit Level Outcome 5: Associated Assessment Criteria for Exit Level Outcome 6: Associated Assessment Criteria for Exit Level Outcome 7: Associated Assessment Criteria for Exit Level Outcome 7: Integrated Assessment: The institution's policy on assessments of learners governs the formulation of the assessment criteria. A variety of teaching and learning methods will be used. Different modalities of learning, such as theoretical learning, problem-based and project-based learning are staggered throughout the qualification. This approach ensures that learners engage actively with the material in different ways and at different cognitive levels. A blended assessment approach is used, including class tests, assignments, integrated projects, practical work, tutorials and presentations. The feedback provided after formative assessments enhance learner engagement with the subject and their own learning. There will be no grading for the formative evaluations. Summative Assessment will assess the extent to which the learner has achieved curricular objectives. The grade will form part of the overall grade at the end of the study unit. |
| INTERNATIONAL COMPARABILITY |
| This qualification is internationally and regionally recognised, as is evident from it hosting the International African CubeSat Workshop series, as well as its planned participation in the Pan-African University Space Science Institute. The qualification will further develop a highly-skilled workforce for their respective developing space industries.
The MSc in Space Science and Engineering: Space Technology/Space Science is offered at the University College London (UCL), Department of Space and Climate Physics, in association with the Department of Electronic and Electrical Engineering (London), in the United Kingdom. The MSc in Space Science and Engineering incorporates two pathways: 'Space Technology' (ST) and 'Space Science' (SS). The ST pathway is focused on the application of space technology in industrial settings. The SS pathway is focussed on scientific research applications of space technology. The compulsory and optional modules of the 180 Credits are similar to the MEng: Satellite Systems and Applications. The SS qualification has similar compulsory modules, but where it differs is in terms of the optional modules, where the SS modules focus strongly on physics. A MSc in Space Studies is offered at the American Public University (APU), School of Science, Technology, Engineering and Maths (Charles Town, WV) in the United States of America. APU offers a qualification that is devoted to the interdisciplinary study of space, including the historical, political, economic, legal, commercial, scientific and technical issues that make up this complex field of study. The MSc in Space Studies is offered entirely online and is offered in three streams, namely; Aerospace Science, Astronomy and Space Policy. Of the three streams, the streams that most relates to the MEng: Satellite Systems and Applications qualification is the Aerospace Science stream. However, the aerospace science stream has a strong focus on rocket theory and reliable space aircraft design. Overall the curriculum integrates the interdisciplinary study of space through multiple perspectives, such as space law, space policy, astronomy, propulsion and aerodynamics. The qualification prepares learners for humankind's exploration and usage of space and is useful for careers in aerospace operations engineering, planetarium astronomy, space journalism and military space systems. A Master of Space Studies is offered at the International Space University (ISU) (Strasbourg) in France. The ISU Master of Space Studies is a one- or two-year qualification. The first year is an on-campus taught year and learners who complete the year will graduate with the Master of Space Studies qualification. Learners who perform at an appropriate level in the first year will then be allowed to complete the second year of studies and will graduate with the Master of Space Studies and Thesis. The qualification offered in France consists of three modules, namely; core, practical and elective modules. The two core modules and elective modules are similar to what is offered in the MEng: Satellite Systems and Applications. Where the ISU qualification differs is the large practical component involving team projects, individual projects and an internship. The qualification is intended for individuals seeking professional development, further academic study, or both, through a one- or two-year graduate qualification. The modality of the offering is online. A MSc in Space Studies is offered at the University of North Dakota (Grand Forks) in the United States of America. The MSc qualification is offered as a 2-year qualification, with an online option extending the completion time to 4 years. The qualification is intended to give learners a broad view of space. The qualification is interdisciplinary in that it combines space physical science, space life science, space engineering, space policy and law, space business and economics and space history. This is different from the MEng: Satellite Systems and Applications where the primary focus is on satellite engineering, technology applications and space science. The modality of the offering is online. |
| ARTICULATION OPTIONS |
| This qualification allows possibilities for both vertical and horizontal articulation.
Horizontal Articulation: Vertical Articulation: |
| 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. |
| NONE |
| All qualifications and part qualifications registered on the National Qualifications Framework are public property. Thus the only payment that can be made for them is for service and reproduction. It is illegal to sell this material for profit. If the material is reproduced or quoted, the South African Qualifications Authority (SAQA) should be acknowledged as the source. |