Master of Engineering in Aeronautics and Astronautics

University of Southampton Malaysia

Iskandar Puteri, Johor, Malaysia

Quick Facts

Duration

2+2 years

Mode

Full-time, On-campus

Intake

Sep

Tuition Fees

RM357,408

Optional Modules:

Accounting and Finance for Engineers
Advanced Computational Methods I
Advanced Finite Element Analysis
Advanced Partial Differential Equations
Advanced Photovoltaics, Fuel Cells and Batteries
Aeroacoustics
Aeroelasticity
Aerospace Control Design
Aerothermodynamics
Aircraft Propulsion
Aircraft Structures
Applications of CFD
Automobile Systems
Automotive Propulsion
Biological Flow
Biomaterials
Composites Engineering Design and Mechanics
Computational Methods in Biomedical Engineering Design
Concurrent Spacecraft Design
Control and Instrumentation
Design Search and Optimisation (DSO) - Principles, Methods, Parameterizations and Case Studies
Experimental Methods for Aerodynamics
Failure of Materials and Components
Finite Element Analysis in Solid Mechanics
Flow Control
Heat Transfer and Applications
Human Factors in Engineering
Hypersonic & High Temperature Gas Dynamics
Manufacturing and Materials
Materials for Transport Applications
Operational Research
Optimisation
Orthopaedic Biomechanics
Principles of Photovoltaics, Fuel Cells and Batteries
Race Car Aerodynamics
Renewable Energy from Environmental Flows: Wind, Wave and Tide
Space Environment
Spacecraft Instrumentation
Spacecraft Orbital Mechanics
Spacecraft Propulsion
Spacecraft Structural Design
Sustainable energy systems, resources and usage
Turbulence
Wing Aerodynamics

Group Design Project:

Optional modules:

Accounting and Finance for Engineers
Advanced Computational Methods I
Advanced Finite Element Analysis
Advanced Partial Differential Equations
Advanced Photovoltaics, Fuel Cells and Batteries
Aeroacoustics
Aeroelasticity
Aerospace Control Design
Aerothermodynamics
Aircraft Propulsion
Aircraft Structures
Applications of CFD
Automobile Systems
Automotive Propulsion
Biological Flow
Biomaterials
Composites Engineering Design and Mechanics
Computational Methods in Biomedical Engineering Design
Concurrent Spacecraft Design
Control and Instrumentation
Design Search and Optimisation (DSO) - Principles, Methods, Parameterizations and Case Studies
Experimental Methods for Aerodynamics
Failure of Materials and Components
Finite Element Analysis in Solid Mechanics
Flow Control
Heat Transfer and Applications
Human Factors in Engineering
Hypersonic & High Temperature Gas Dynamics
Manufacturing and Materials
Materials for Transport Applications
Operational Research
Optimisation
Orthopaedic Biomechanics
Principles of Photovoltaics, Fuel Cells and Batteries
Race Car Aerodynamics
Renewable Energy from Environmental Flows: Wind, Wave and Tide Space Environment Spacecraft Instrumentation Spacecraft Orbital Mechanics Spacecraft Propulsion Spacecraft Structural Design Sustainable energy systems, resources and usage Turbulence Wing Aerodynamics

Students get to choose from 7 specialisation:

A Level: A*AA including Mathematics and Physics, with a pass in the Physics Practical (where it is separately endorsed)
IB Diploma: Pass with 38 points overall, 19 points required at Higher Level, including 6 at Higher Level in Physics and 6 at Higher Level in Mathematics (Analysis and Approaches) or 7 at Higher Level in Mathematics (Applications and Interpretation). IB English: 5 at Standard/Higher Level in IB English Language Syllabus A or 6 at Standard Level/5 at Higher Level in IB English Language Syllabus B.
STPM: AA-A-, including Mathematics and Physics
UEC: AAAAAA, with A in Advanced Mathematics I & II, Physics and two other STEM subjects (Computing accepted)*

IELTS 6.5 overall, minimum 6.0 in all components or Grade C in SPM 1119 English (cohort before 2021), SPM CEFR Level B2 or above (cohort from 2021 onwards), Grade C in GCSE English, Grade A in IGCSE English as a Second Language, B3 in UEC English or equivalent