aerospace engineering auckland university

Aerospace is a broad discipline which encompasses all aspects of aviation from the design and manufacture of aircraft to the study of their performance. Aerospace engineering is a discipline offered at Auckland University.A erospace engineering research at Auckland University is recognised as world class – rated 8th best in the world by QS World University Rankings 2018.

If you are seeking to learn about Aerospace Engineering Auckland University for the first time, the subject might seem overpowering for those who have not researched the subject before, but you are likely to be fascinated by the information you come across. 

Read more about Aeronautical engineering university nz, Aerospace engineering uoa , Masters in aerospace engineering in new zealand , Aerospace engineering salary nz You can also find articles related to Aerospace engineering nz on collegelearners.

Equip yourself for employment in the space and aeronautical sectors with Aotearoa’s first dedicated masters programme in aerospace engineering

Aerospace Engineering Auckland University

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Aotearoa’s space industry is growing, as is its capacity for innovation in industry and research. Get a head start in your career in this exciting field with the MAerospaceEng, designed to equip students with the skills, knowledge and expertise to be effective employees in a field with increasing national and global economic significance.

Our courses in Aerospace Engineering are supported by Te Pūnaha Ātea/Auckland Space Institute, which aims to enhance the growth of the New Zealand space sector. The institute is led by academics with deep expertise in the aerospace sector, making the University of Auckland ideally placed to deliver an excellent teaching and learning experience for our students. The MAerospaceEng programme has also received additional endorsements from the New Zealand Space Agency, Rocket Lab CEO Peter Beck and the Royal Aeronautical Society.

We also offer opportunities for practical projects with industry partners. This ensures that you’re prepared to fulfill your future workforce’s demands for complex problem solving, innovation and entrepreneurship.

.Apply nowfor Master of Aerospace EngineeringDurationFull-time: VariesNext start date2022 Semester One – 28 February2022 Semester Two – 18 JulyAvailable locationsCityPoints120 or 180Programme typePostgraduateTaught & research options available

Programme structure

There are four ways to complete a MAerospaceEng: Research (120 and 180 points) and Taught (120 and 180 points). Your selection will depend on your technical and educational background, and career goals.

Compulsory courses
In all cases, you will be required to complete the following:

  • AEROSPCE 730 Aerospace Systems Design (Semester One)
  • AEROSPCE 740 Aerospace Structures and Mechanisms (Semester Two)

Thesis or research project
A research component is necessary to the MAerospaceEng, regardless of your focus. This enables you to apply your technical knowledge to practical scenarios, and build your confidence in the field.

  • If you choose a research programme, you’ll need to complete the 90-point AEROSPACE 792 or 793 Thesis.
  • If you choose a taught programme, you’ll need to complete the 45-point AEROSPACE 791 Research Project.

Aerospace core courses
For the 180-point research and both taught options, you must complete at least two of the following courses:

  • AEROSPCE 720 Space Dynamics and Missions (Semester Two)
  • ENGGEN 769 Research Methods for Engineers (Semesters One and Two)
  • MECHENG 711 Computational Fluid Dynamics (Semester Two)
  • MECHENG 712 Aerohydrodynamics (Semester One)
  • MECHENG 743 Composite Materials (Semester One)

You will also need to complete additional electives depending on your study track. Refer to the Electives tab for more information.

If you’re not ready to commit to a masters programme, we also offer the following. 

Other options
These qualifications also serve as pathways towards the MAerospaceEng.

  • PGCert in Aerospace Engineering
  • PGDip in Aerospace Engineering

You’ll also need to meet other requirements, including time limits and total points limits. See Postgraduate enrolment. For all official programme information, including regulations about entry, enrolment, fees, examinations, and requirements for degrees, diplomas and certificates, see the University Calendar.

Where could this programme take you?

Aotearoa’s aerospace industry is making a significant, growing contribution to our economy, employing approximately 5,000 people in 2019. Pursuing a dedicated study option opens opportunities in aeronautics, astronautics, space systems and aerospace management, in technical or management roles, as well as pathways to employment in academia.

Jobs related to this programme

  • Aerospace Engineer
  • Launch Services Engineer
  • Payload Engineer
  • Project Manager
  • R&D Engineer
  • Space Mission Design & Operations
  • Space System Engineer
  • Technical Director, CTO

Further study options

  • Doctor of Philosophy

aerospace engineering uoa

There is increasing research activity related to the fields of aerospace and space engineering at our faculty, University, and in New Zealand. Our people are involved in many areas — from theoretical concepts to hardware implementation, academic study and computational models, to Assembly Integration and Testing, and industrial applications.

Spacecraft Microvibrations and Stable Structures

Microvibration produced by the functioning of on board equipment — such as Reaction Wheel Assemblies, Cryocoolers, pointing mechanisms and more — and propagating through the spacecraft structure can seriously degrade the performance of accurately targeted payloads that include high resolution cameras or telescopes, and interferometers.

Our work is on the modelling and control of microvibrations. In particular we carry out theoretical modelling of transmission and control, supported by experimental verification activities and on-orbit validation.

Our expertise allows us to tackle the following issues:

  • Modelling and control of micro-vibrations which is theoretical modelling of the sources and transmission supported by experimental verification activities and on-orbit validation
  • Ultra-stable structures which are procedures to increase the stability of CFRP structures exposed to harsh environments

Deployable structures

Deployable structures are typically used in space application to enable the launch of equipment whose operational size in orbit exceeds the volume available in the launch vehicle. Solar arrays and antennas are typical examples of structures that are launched in a stowed configuration, and deployed once in orbit.

There are also classes of payloads — like optical instruments — where large structural elements are used to maintain optical components in place that could benefit from more compact, stowed launch configurations.

We are currently working on various projects that involve deployable structures for de-orbit devices, deployable antennas and optical instruments.

Correlation/Validation of FEM and Virtual Shaker testing

The correlation and validation of Finite Element Models (FEM) against physical test results are particularly important in the space industry because the loads experienced by a satellite during launch can only be accurately predicted by analysing the FEM of the satellite coupled with that of the Launch Vehicle. Our research focuses on: 

  • Representativeness of typical num-exp performance indicators, including MAC, Cross-orthogonality check and FRAC used for FEM correlation and validation in the space industry
  • FEM semi-automatic updates to improve correlations between FEM and physical test results
  • Improvement of testing procedures, with development of techniques aimed at avoiding over-testing for specific pieces of equipment mounted on satellites

Some related work has tackled the issue of modelling the test facility, as this can be coupled with the test item (satellite). This may produce discrepancies between numerical analysis and test results. Our researchers have been involved in developing a virtual testing methodology for vibration testing of spacecraft structures.

Synthetic Aperture Radar technology development

This project aims to develop the underlying science and technology needed to provide New Zealand with an overhead monitoring capability using space-based assets. This is research conducted through funding from the Science for Technological Innovation (SfTI) National Science Challenge to develop novel miniature Synthetic Aperture Radar (SAR) hardware and software for small satellites.

A growing research group involves collaborators from the Ministry of Business, Innovation and Employment (MBIE), Australian National University (ANU) and the German Aerospace Center (DLR).

Plasma micro-propulsion technology development

We are collaborating with the Space Physics, Plasma and Propulsion Laboratory at the Australian National Laboratory (ANU) and Stanford University to develop and test novel miniature satellite electric propulsion systems. Our work includes improving the Technology Readiness Level of ANU’s Pocket Rocket to enable the first space flight of the propulsion system in a CubeSat. In conjunction with this work, we are investigating optimal flight trajectories for low delta-v thrust systems to enable interplanetary exploration with small satellites.

Materials Science for sample return

We’re leveraging existing national expertise in light metals technology to develop new materials for ablation and thermal insulation to enable satellite sample return missions. We are also developing micro-fluidics devices for chemical and biological processing in low Earth orbit.

Our people

Professor Guglielmo Aglietti (primary contact)
Dr John Cater
Dr Andrew Austin
Associate Professor Mark Battley

aerospace engineering salary nz

Aerospace engineers design aircraft, spacecraft, missiles, and satellites. They receive proposals for projects and evaluate them for a variety of factors. Aerospace engineers can develop new technologies in these fields, designing new types of aerospace products. They must determine if the proposed project will be technically possible, financially possible, and safe. They will determine if the product meets the needs of the customer, can surpass environmental challenges, and can meet engineering principles. Once they have approved a project, they are in charge of coordinating the design and manufacturing of the product. They will also direct the final testing of the product and ensure that the project meets the proper quality standards. If there is a malfunction or damage in a product, they must identify the problem and any possible solutions.

A person working as an Aerospace Engineer in New Zealand typically earns around 118,000 NZD per year. Salaries range from 56,400 NZD (lowest) to 184,000 NZD (highest). An entry-level Aerospace Engineer with less than 1 year experience can expect to earn an average total compensation (includes tips, bonus, and overtime pay) of NZ$65,000 based on 6 salaries. An early career Aerospace Engineer with 1-4 years of experience earns an average total compensation of NZ$71,500 based on 11 salaries. In their late career (20 years and higher), employees earn an average total compensation of NZ$120,000

This is the average yearly salary including housing, transport, and other benefits. Aerospace Engineer salaries vary drastically based on experience, skills, gender, or location. Below you will find a detailed breakdown based on many different criteria.

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