Master of Science in Maritime Engineering Science - Advanced Computational Engineering

at University of Southampton - Boldrewood Innovation Campus United Kingdom

Help the world adapt to urbanisation, climate change and natural disasters with a master’s degree in civil engineering.

This 2-year integrated course is ideal if you didn't graduate in civil engineering, but have maths and physics skills. You'll spend a year learning the basics of civil engineering before progressing to the main MSc course for your second year.

If you're an EU or UK student you'll have the chance to carry out your research project on an industrial placement.

You’ll spend your first year studying key topics and improving your knowledge to prepare for your second year, when you’ll join the full-time MSc Civil Engineering course.

Throughout the course you’ll study:

• Fundamental principles, methods, analysis and synthesis in civil engineering design and applications
• Specialist modules in engineering fields such as: coastal, environmental, infrastructure, transport and engineering management
• Information and communication technology relevant to civil engineering, as well as management practices, health and safety issues, risk assessment and regulatory frameworks
• The role and professional responsibilities of engineers in society

You’ll complete a research project to apply the knowledge and transferable skills you have developed on the degree. If you live in the UK or EU, you have the option to take the MSc with an 11-month industrial placement. This is an opportunity to carry out applied research on real projects, while working with major civil engineering companies and research centres.

This civil engineering master's is accredited as meeting the requirements for Further Learning for a Chartered Engineer (CEng), for candidates who have already acquired a partial CEng accredited undergraduate first degree. See www.jbm.org.uk for further information.

Explore the relationships between transport systems, the people who use and operate them, and the wider world, with our MSc Transportation Planning and Engineering: Behaviour. This course offers modules in human factors in transport engineering, and the interactions between transport, energy systems, and the environment. You can study this course on a full-time, part-time or distance-learning basis.

If you want a career in the transport industry or you're an experienced transport professional interested in enhancing your skills, this degree is ideal.

This master’s degree in transportation planning and engineering: behaviour covers everything from the fundamentals of modelling and economics, through to the application of software and planning tools using real life examples from around the world. It’s the perfect way to improve your capabilities and career prospects in the transport sector.

Your course highlights include field trips and a mock public inquiry, where you'll learn about  public engagement and the role of public opinion in the transport planning process.

Your taught learning includes modules on:

• Transport economics
• Transport data analysis and techniques
• Transport planning: policy and governance
• Transport modelling
• Human factors in engineering
• Transport, energy and the environment

You’ll also have the chance to choose from a range of modules including:

• Highway and traffic engineering
• Railway engineering and operations
• Transport management and safety
• Logistics systems operations

You’ll gain experience using a range of transport-related software and you’ll be able to hear directly from a range of industry guest speakers. You’ll also carry out an individual research project on a topic of your choice.

Sustainable energy supply is one of the greatest challenges we face today. At Southampton, you'll learn to focus your engineering skills into cutting-edge technologies, such as wind turbines, solar cells and batteries. You'll study core mechanical engineering topics and explore how we store, use and distribute energy. You'll graduate with vital skills for environmental engineering and beyond.

Sustainable energy is a fascinating and growing area. This 4-year integrated master's in mechanical engineering focuses on the latest in energy technology, systems and processes, such as:

• Fuel cells
• Photovoltaics
• Biomass systems
• Tidal energy
• Wind turbines

This degree provides the core topics you'll need to master mechanical engineering. It then gives you the advanced skills to design and test sustainable-energy technologies.

As part of this course you can:

• Examine the economics behind energy technology investments
• Develop your management skills
• Take a work placement to boost your academic performance and prepare for your career
• Use our design workshops and studios
• Showcase your work in our annual Engineering Design Show
• Go on site visits to experience engineering in practice

You can take this course with an additional, year-long, paid placement. Apply with UCAS code H3J7 for the Industrial Placement Year option.

We're a designated university for the Defence Technical Undergraduate Scheme (DTUS).

On this Marine Engineering and Autonomy MSc degree you'll learn about component and systems engineering for ships. You’ll also gain an understanding of the fixed and offshore structures that help them to function. Learn the skills you need to become a specialist in the marine sector.

On this UK master’s course you’ll gain an advanced understanding of the fundamental principles, methods and applications of maritime engineering science.

This pathway focuses on the analysis and specification of marine engineering and autonomous systems used on board ships and other marine structures. You’ll study topics like electrical theory, thermodynamics, and engine and machine tribology. 
 
You’ll explore the marine engineering systems found on board merchant and naval vessels and their importance to ship design. This includes performance characteristics of diesel engines, steam and gas turbines and electric propulsion. The course covers the dynamic response of the main shaft and associated components. 
 
An introduction to auxiliary systems includes: 

• Heating
• Ventilation and air-conditioning
• Refrigeration
• The main fuel system

You’ll also learn about propeller-engine matching and a selection of appropriate machinery configurations. 

Your optional study topics include a chance to study the principles of photovoltaics, fuel cells and batteries, where you’ll learn about: 

• Electrochemical routes to energy conversion
• The relative merits of batteries, fuel cells and redox flow cells
• Solar radiation as an energy source
• Solar cell operation and manufacture
• Design and operation of a photovoltaic system 

Throughout your studies, you’ll learn how to solve engineering problems by taking account of social, technical, economic and environmental constraints. 

Learn how to take a product from initial concept, to design and manufacture. Our 4-year master's in Mechanical Engineering with industry placement will put you on the path to becoming a chartered engineer. You'll learn about mechanical design, structures and materials, then select specialist topics to study. Project work throughout the degree provides the opportunity to apply your design skills to real-world problems.

This integrated master's lets you select a specialist theme pathway for years 3 and 4, or stay on in this generalised Mechanical Engineering theme. This general theme lets you take optional modules from the specialised courses in years 3 and 4.

You'll cover the essential principles of engineering, and learn about:

• Modelling and computing
• Systems design
• Law
• Management

In your third year you'll complete an individual research project and in year 4 you'll take part in a group design project. These projects are often linked to current research or topics that have practical relevance to industry.

As part of this course you can:

• Use our design workshops and studios
• Develop your design and computing skills
• Showcase your work in our annual Engineering Design Show
• Apply your knowledge to your choice of specialist areas, from automobiles to mechatronics
• Go on site visits to experience engineering in practice

You can take this course with an additional year-long, paid placement. Apply with UCAS code 30HH for the Industrial Placement Year option.

Choosing the correct materials is crucial to the success or failure of an engineering project. On this 4-year, integrated master's, you'll explore the properties and uses of common and new mechanical engineering materials. You'll develop the skills to design materials and surfaces, from the atomic level up to their application. This advanced course will help you find a rewarding career as a Chartered Engineer.

This course focuses on mechanics, structures and materials, and how they are managed. It will inspire you to use your knowledge and skills to address real mechanical and material engineering needs in society, in areas like:

• Transport
• Housing
• Recreation
• Food processing
• Medicine

You'll explore material use, including their design and manufacture, and you'll study how they behave throughout their service.

As part of this course you can:

• Showcase your work in our annual Engineering Design Show
• Choose from a range of optional modules, including microstructural and surface characterisation, and aircraft structures
• Put your skills into practice with an individual project and final year group design project
• Work with students from other engineering specialisms

The course draws on research from the Engineering Materials Research Group, which is actively involved in a broad range of activities in the advanced materials field.

You can take this course with an additional year-long, paid placement. Apply with UCAS code H3H1 for the Industrial Placement Year option.

We're a designated university for the Defence Technical Undergraduate Scheme (DTUS).

Train as a chemist for the industries of the future. This 4-year degree combines computational skills with traditional chemistry - an emerging specialism that is highly valued by employers in industry.

Advances in data science and machine learning have paved the way for the digitisation of chemistry, a process that allows us to find new products and commercialise technology faster, and at less cost.

This combined honours programme will put you at the forefront of research within this new, combined discipline, allowing you to develop the skills necessary to pursue careers across chemical industries and data science.

On this computational chemistry degree, you'll:

• Study core principles of modern chemistry
• Gain practical training in programming, modelling and data analysis
• Use our modern equipment and laboratories
• Experience a range of modelling and computational approaches, including an extended project

Our digital chemistry course is designed by academics whose research supports industries ranging anywhere from pharmaceuticals and defence, to engineering and software development. You'll be able to apply the skills you learn to the industry of your chosen career.

This chemical engineering degree focuses on sustainability. On completion, you’ll have the skills to help the world transition to a more sustainable future. Demand is high for chemical engineering graduates. You’ll have excellent job prospects in sectors such as food, energy, pharmaceuticals and biochemicals.

Chemical engineering is a multi-disciplinary branch of engineering, focused on using chemicals and materials to design sustainable processes and giving them practical applications in the real world. This course focuses particularly on employability, sustainability and design.

The skills you’ll gain include:

• Computational methods
• Reaction engineering
• Thermofluids

On this Chemical Engineering BEng degree you’ll be able to:

• Take part in a challenging group design project
• Complete an optional extra year on a paid industrial placement
• Learn real-world skills with our dedicated computer suite and simulation software
• Use our virtual control room to gain experience working in a chemical plant
• Select from a range of specialist modules

You’ll work in our brand new, bespoke chemical engineering laboratories, which are part of our £12m chemistry building renovation. You’ll also have access to our engineering facilities, which consist of over 10,000m² of specialist workshops, laboratories and testing services.

Study the latest maritime techniques, methods and software on this MSc in Advanced Computational Engineering in Maritime Engineering at the University of Southampton. Learn the theory and practice behind maritime computational engineering science as you take on practical design tasks and prepare how to work effectively with industry.

You’ll gain an advanced understanding of the fundamental principles, methods and applications of maritime engineering science.
 
On this pathway you'll also learn advanced computational methods incorporating: 

• Complied versus interpreted language
• Combining c-code with python
• Version control and one version control tool
• Remote and local use of linux computers
• Shell commands
• Symbolic methods and code generation

Maritime computational engineering covers topics such as advanced sensors and signal processing techniques for machinery condition monitoring. You’ll look at condition-monitoring strategies, leading-edge sensing methods and advanced signal processing techniques. You’ll also gain an introduction to condition-monitoring procedures and system integration. 
 
Optional study topics include aeroelasticity, which covers aeroelastic stability and response. A combination of theoretical and practical teaching will give you a solid understanding of the subject and its application to various aeronautical systems. You’ll get the chance to work with professional software tools currently used by large aerospace industries. 

Throughout your studies, you’ll learn how to solve engineering problems by taking account of social, technical, economic and environmental constraints.

Take your engineering abilities to the final frontier of human endeavour. You’ll explore many aspects of aerospace engineering, including the design and manufacture of fast-moving air and space vehicles. You'll then specialise in spacecraft systems engineering, to prepare you for a career in the space industry and beyond.

Aeronautics and Astronautics looks at the science, engineering and manufacture of aircraft and spacecraft. You'll learn how they operate within our atmosphere and in space.

On this spacecraft engineering degree you’ll study the general principles of aerospace engineering, then take more advanced modules specialising in the design and operation of spacecraft, and their environmental impact.

In year 3 on MEng Aeronautics and Astronautics with Spacecraft Engineering you'll complete an individual research project and in year 4 you’ll participate in a group design project.

You’ll have access to our extensive facilities, which include:

• Dedicated student design studios and workshops
• The largest wind tunnel in any UK university
• State-of-the-art jet engine and space propulsion facilities
• Flight simulator
• Professional manufacturing centre

As part of this aeronautics and astronautics spacecraft engineering course you can:

• Showcase your work in our annual Engineering Design Show
• Attend site visits to experience engineering in practice
• Apply your engineering knowledge to solve a real-world problem

You can take this course with an additional year-long, paid placement. Apply with UCAS code H400 for the Industrial Placement Year option.