Develop fundamental mathematical and computational skills to use throughout the course.

Acquire a range of skills necessary for the role of the professional engineer.

Derive from first principles the mathematical descriptions of stress analysis, and understand the physical significance of stress and strain.

Learn to derive mathematical descriptions of mechanics applications using first principles.

Discover the important mechanical properties and learn about the concept and practice of materials selection.

Explore a range of fluid dynamics mechanisms and forces to gain a solid understanding of the fundamentals.

Study the inter-conversion of heat, work, and other forms of energy and distinguish between reversible and irreversible processes.

Understand mechatronics as a concept for modelling and designing machine systems.

Learn about the design process from brief to manufacture, including how to produce a product design specification.

Continue your development of key mathematical and computational skills, including partial differential equations and interpolation.

Demonstrate skills in data collection and recording and in writing a technical report.

Build on your existing knowledge to appreciate how stresses at a point vary and combine in different directions.

Master essential basic topics in vibrations and dynamics and understand the dynamical behaviour of various systems.

Acquire the tools needed to predict component failures and identify failure mechanisms in practice.

Further your knowledge of key aspects of engineering fluid mechanics, including dimensional analysis.

Explore a variety of industrially-significant processes concerned with energy conversion and use.

Develop an understanding of the physics of heat transfer and solve simple problems involving heat conduction, convection and radiation.

Demystify electronics and control through hands-on experience of building electronic systems and by using instrumentation to analyse their behaviour.

Carry out two major engineering projects and develop your knowledge of engineering design.

Better understand professional engineering roles, responsibilities and ethics.

Work in a realistic engineering project environment and develop your transferable skills.

Your I-Explore module offers you choices from a range of subjects hosted outside of the department.

You will be taught alongside students from other courses with options including business, management and many more.

Reinforce your knowledge of stress analysis and solve a wide range of axi-symmetric elastic problems.

Understand the foundations, principles, application and limitations of linear elastic fracture mechanics.

Study advanced concepts in thermodynamics including non-ideal behaviour, phase change and electro-chemistry.

Advance your appreciation of subsonic, transonic and supersonic flows.

Gain the expertise required to design and realise a full mechatronic system.

Evaluate the dynamic response requirements of a proposed machine design and produce workable proposals for its safe and effective operation.

Learn the principal components of, and terminology used in, embedded computer hardware and software.

Formulate an appropriate brief and process for a design project and turn a design opportunity into a concept.

Appreciate the concept of mathematical optimisation as applied to system design.

Analyse the mechanical properties, processing characteristics and failure modes of the principal classes of polymer.

Explore the fundamentals of continuum mechanics that underpin the theoretical understanding of many engineering disciplines.

Use finite element programs in a practical way to solve problems in linear elastic stress analysis.

Advance your knowledge and understanding of product machining and examine the evolution of modern product manufacturing industry since 1900.

Explore technical, social, economic and environmental issues related to nuclear energy.

Understand the main concepts and principles of tribology, with particular emphasis on lubricated systems.

Discover how mathematics can be used to characterise and model the qualitative behaviour of non-linear systems.

Build your confidence with statistical methods and procedures and perform predictive modelling tasks using regression and time series analysis.

Tackle real-life automotive design problems using the knowledge and skills gained during the course.

Apply fundamental engineering principles to complex engineering problems on a supervised individual project.

Projects can be experimental, computer-based or analytical (or a combination), with your research spread over the final year.

Design a jet engine for a civil airliner in a small group and improve your understanding of aerodynamic design choices.

Examine the metal forming technologies used for the manufacture of a range of metal components such as automotive and aircraft body panels.

Learn how to construct physical and computational models of processes occurring in IC engines, hybrid-electric powertrains and energy storage systems.

Explore the design and technology of mechanical transmission systems and design and analyse geared drive systems.

Build your working knowledge of modelling, analysis and design methods in relation to continuous and discrete control systems.

Investigate fundamental elasticity and plasticity theory, problems and solutions.

Use the theoretical principles of vibration and vibration analysis techniques to solve vibration problems.

Analyse the scientific foundations of combustion and assess trends relating to the global utilisation of fuels for energy consumption.

Engage with the mathematical formulation used for a range of heat and fluid flow problems.

Explore data processing methods used for industrial processes and understand their purpose.

Broaden your understanding of the reactor physics of nuclear reactors, including neutron conservation and neutron diffusion.

Analyse turbulent flow and heat transfer in both single-phase and two-phase systems within nuclear reactors.

Learn how to brainstorm effectively and keep an open mind in relation to the design process.

Further develop your understanding of stress analysis theories and techniques.

Build on your existing knowledge of fracture mechanics and learn how to predict the residual strength of a flawed structure.

Deepen your appreciation of fluid mechanics and use numerical solutions to describe the fundamental features of fluid flow.

Develop your familiarity with the C programming language and write simple programs to manipulate data.

Increase your awareness of system design and optimisation and better understand modern optimisation theory and practice.

Consolidate your existing knowledge of continuum mechanics and build your appreciation of the finite element method.

Gain practical experience in analysis using an industry-standard, interactive, finite element program.

Build your knowledge of the basic theory of machine learning (ML) and explore the workings of neural networks (NN).

Learn how to define an energy system and identify its major components.

Apply the principles of fluid mechanics and thermodynamics to a range of engineering and environmental problems.

There are multiple modules available through Inter Departmental Exchange (IDX). 

These modules allow you to take a module from another discipline, preparing you for interdisciplinary work.

Develop fundamental mathematical and computational skills to use throughout the course.

Acquire a range of skills necessary for the role of the professional engineer.

Derive from first principles the mathematical descriptions of stress analysis, and understand the physical significance of stress and strain.

Learn to derive mathematical descriptions of mechanics applications using first principles.

Discover the important mechanical properties and learn about the concept and practice of materials selection.

Explore a range of fluid dynamics mechanisms and forces to gain a solid understanding of the fundamentals.

Study the inter-conversion of heat, work, and other forms of energy and distinguish between reversible and irreversible processes.

Understand mechatronics as a concept for modelling and designing machine systems.

Learn about the design process from brief to manufacture, including how to produce a product design specification.

Continue your development of key mathematical and computational skills, including partial differential equations and interpolation.

Demonstrate skills in data collection and recording and in writing a technical report.

Build on your existing knowledge to appreciate how stresses at a point vary and combine in different directions.

Master essential basic topics in vibrations and dynamics and understand the dynamical behaviour of various systems.

Acquire the tools needed to predict component failures and identify failure mechanisms in practice.

Further your knowledge of key aspects of engineering fluid mechanics, including dimensional analysis.

Explore a variety of industrially-significant processes concerned with energy conversion and use.

Develop an understanding of the physics of heat transfer and solve simple problems involving heat conduction, convection and radiation.

Demystify electronics and control through hands-on experience of building electronic systems and by using instrumentation to analyse their behaviour.

Carry out two major engineering projects and develop your knowledge of engineering design.

Better understand professional engineering roles, responsibilities and ethics.

Work in a realistic engineering project environment and develop your transferable skills.

Your I-Explore module offers you choices from a range of subjects hosted outside of the department.

You will be taught alongside students from other courses with options including business, management and many more.

Reinforce your knowledge of stress analysis and solve a wide range of axi-symmetric elastic problems.

Understand the foundations, principles, application and limitations of linear elastic fracture mechanics.

Study advanced concepts in thermodynamics including non-ideal behaviour, phase change and electro-chemistry.

Advance your appreciation of subsonic, transonic and supersonic flows.

Gain the expertise required to design and realise a full mechatronic system.

Evaluate the dynamic response requirements of a proposed machine design and produce workable proposals for its safe and effective operation.

Learn the principal components of, and terminology used in, embedded computer hardware and software.

Formulate an appropriate brief and process for a design project and turn a design opportunity into a concept.

Appreciate the concept of mathematical optimisation as applied to system design.

Analyse the mechanical properties, processing characteristics and failure modes of the principal classes of polymer.

Explore the fundamentals of continuum mechanics that underpin the theoretical understanding of many engineering disciplines.

Use finite element programs in a practical way to solve problems in linear elastic stress analysis.

Advance your knowledge and understanding of product machining and examine the evolution of modern product manufacturing industry since 1900.

Explore technical, social, economic and environmental issues related to nuclear energy.

Understand the main concepts and principles of tribology, with particular emphasis on lubricated systems.

Discover how mathematics can be used to characterise and model the qualitative behaviour of non-linear systems.

Build your confidence with statistical methods and procedures and perform predictive modelling tasks using regression and time series analysis.

Tackle real-life automotive design problems using the knowledge and skills gained during the course.

Develop fundamental mathematical and computational skills to use throughout the course.

Acquire a range of skills necessary for the role of the professional engineer.

Derive from first principles the mathematical descriptions of stress analysis, and understand the physical significance of stress and strain.

Learn to derive mathematical descriptions of mechanics applications using first principles.

Discover the important mechanical properties and learn about the concept and practice of materials selection.

Explore a range of fluid dynamics mechanisms and forces to gain a solid understanding of the fundamentals.

Study the inter-conversion of heat, work, and other forms of energy and distinguish between reversible and irreversible processes.

Understand mechatronics as a concept for modelling and designing machine systems.

Learn about the design process from brief to manufacture, including how to produce a product design specification.

Continue your development of key mathematical and computational skills, including partial differential equations and interpolation.

Demonstrate skills in data collection and recording and in writing a technical report.

Build on your existing knowledge to appreciate how stresses at a point vary and combine in different directions.

Master essential basic topics in vibrations and dynamics and understand the dynamical behaviour of various systems.

Acquire the tools needed to predict component failures and identify failure mechanisms in practice.

Further your knowledge of key aspects of engineering fluid mechanics, including dimensional analysis.

Explore a variety of industrially-significant processes concerned with energy conversion and use.

Develop an understanding of the physics of heat transfer and solve simple problems involving heat conduction, convection and radiation.

Demystify electronics and control through hands-on experience of building electronic systems and by using instrumentation to analyse their behaviour.

Carry out two major engineering projects and develop your knowledge of engineering design.

Better understand professional engineering roles, responsibilities and ethics.

Work in a realistic engineering project environment and develop your transferable skills.

Your I-Explore module offers you choices from a range of subjects hosted outside of the department.

You will be taught alongside students from other courses with options including business, management and many more.

Reinforce your knowledge of stress analysis and solve a wide range of axi-symmetric elastic problems.

Understand the foundations, principles, application and limitations of linear elastic fracture mechanics.

Study advanced concepts in thermodynamics including non-ideal behaviour, phase change and electro-chemistry.

Advance your appreciation of subsonic, transonic and supersonic flows.

Gain the expertise required to design and realise a full mechatronic system.

Evaluate the dynamic response requirements of a proposed machine design and produce workable proposals for its safe and effective operation.

Learn the principal components of, and terminology used in, embedded computer hardware and software.

Formulate an appropriate brief and process for a design project and turn a design opportunity into a concept.

Appreciate the concept of mathematical optimisation as applied to system design.

Analyse the mechanical properties, processing characteristics and failure modes of the principal classes of polymer.

Explore the fundamentals of continuum mechanics that underpin the theoretical understanding of many engineering disciplines.

Use finite element programs in a practical way to solve problems in linear elastic stress analysis.

Advance your knowledge and understanding of product machining and examine the evolution of modern product manufacturing industry since 1900.

Explore technical, social, economic and environmental issues related to nuclear energy.

Understand the main concepts and principles of tribology, with particular emphasis on lubricated systems.

Discover how mathematics can be used to characterise and model the qualitative behaviour of non-linear systems.

Build your confidence with statistical methods and procedures and perform predictive modelling tasks using regression and time series analysis.

Tackle real-life automotive design problems using the knowledge and skills gained during the course.

Apply fundamental engineering principles to complex engineering problems on a supervised individual project.

Projects can be experimental, computer-based or analytical (or a combination), with your research spread over the final year.

Design a jet engine for a civil airliner in a small group and improve your understanding of aerodynamic design choices.

Examine the metal forming technologies used for the manufacture of a range of metal components such as automotive and aircraft body panels.

Learn how to construct physical and computational models of processes occurring in IC engines, hybrid-electric powertrains and energy storage systems.

Explore the design and technology of mechanical transmission systems and design and analyse geared drive systems.

Build your working knowledge of modelling, analysis and design methods in relation to continuous and discrete control systems.

Investigate fundamental elasticity and plasticity theory, problems and solutions.

Use the theoretical principles of vibration and vibration analysis techniques to solve vibration problems.

Analyse the scientific foundations of combustion and assess trends relating to the global utilisation of fuels for energy consumption.

Engage with the mathematical formulation used for a range of heat and fluid flow problems.

Deepen your knowledge of composite materials, including the mechanics of fibre and particle reinforced composites and their methods of manufacture.

Explore data processing methods used for industrial processes and understand their purpose.

Broaden your understanding of the reactor physics of nuclear reactors, including neutron conservation and neutron diffusion.

Analyse turbulent flow and heat transfer in both single-phase and two-phase systems within nuclear reactors.

Learn how to brainstorm effectively and keep an open mind in relation to the design process.

Further develop your understanding of stress analysis theories and techniques.

Build on your existing knowledge of fracture mechanics and learn how to predict the residual strength of a flawed structure.

Deepen your appreciation of fluid mechanics and use numerical solutions to describe the fundamental features of fluid flow.

Develop your familiarity with the C programming language and write simple programs to manipulate data.

Increase your awareness of system design and optimisation and better understand modern optimisation theory and practice.

Consolidate your existing knowledge of continuum mechanics and build your appreciation of the finite element method.

Gain practical experience in analysis using an industry-standard, interactive, finite element program.

Build your knowledge of the basic theory of machine learning (ML) and explore the workings of neural networks (NN).

Learn how to define an energy system and identify its major components.

Apply the principles of fluid mechanics and thermodynamics to a range of engineering and environmental problems.

There are multiple modules available through Inter Departmental Exchange (IDX). 

These modules allow you to take a module from another discipline, preparing you for interdisciplinary work.

Develop fundamental mathematical and computational skills to use throughout the course.

Acquire a range of skills necessary for the role of the professional engineer.

Derive from first principles the mathematical descriptions of stress analysis, and understand the physical significance of stress and strain.

Learn to derive mathematical descriptions of mechanics applications using first principles.

Discover the important mechanical properties and learn about the concept and practice of materials selection.

Explore a range of fluid dynamics mechanisms and forces to gain a solid understanding of the fundamentals.

Study the inter-conversion of heat, work, and other forms of energy and distinguish between reversible and irreversible processes.

Understand mechatronics as a concept for modelling and designing machine systems.

Learn about the design process from brief to manufacture, including how to produce a product design specification.

Continue your development of key mathematical and computational skills, including partial differential equations and interpolation.

Demonstrate skills in data collection and recording and in writing a technical report.

Build on your existing knowledge to appreciate how stresses at a point vary and combine in different directions.

Master essential basic topics in vibrations and dynamics and understand the dynamical behaviour of various systems.

Acquire the tools needed to predict component failures and identify failure mechanisms in practice.

Further your knowledge of key aspects of engineering fluid mechanics, including dimensional analysis.

Explore a variety of industrially-significant processes concerned with energy conversion and use.

Develop an understanding of the physics of heat transfer and solve simple problems involving heat conduction, convection and radiation.

Demystify electronics and control through hands-on experience of building electronic systems and by using instrumentation to analyse their behaviour.

Carry out two major engineering projects and develop your knowledge of engineering design.

Better understand professional engineering roles, responsibilities and ethics.

Work in a realistic engineering project environment and develop your transferable skills.

Your I-Explore module offers you choices from a range of subjects hosted outside of the department.

You will be taught alongside students from other courses with options including business, management and many more.

Reinforce your knowledge of stress analysis and solve a wide range of axi-symmetric elastic problems.

Understand the foundations, principles, application and limitations of linear elastic fracture mechanics.

Study advanced concepts in thermodynamics including non-ideal behaviour, phase change and electro-chemistry.

Advance your appreciation of subsonic, transonic and supersonic flows.

Gain the expertise required to design and realise a full mechatronic system.

Evaluate the dynamic response requirements of a proposed machine design and produce workable proposals for its safe and effective operation.

Learn the principal components of, and terminology used in, embedded computer hardware and software.

Formulate an appropriate brief and process for a design project and turn a design opportunity into a concept.

Appreciate the concept of mathematical optimisation as applied to system design.

Analyse the mechanical properties, processing characteristics and failure modes of the principal classes of polymer.

Explore the fundamentals of continuum mechanics that underpin the theoretical understanding of many engineering disciplines.

Use finite element programs in a practical way to solve problems in linear elastic stress analysis.

Advance your knowledge and understanding of product machining and examine the evolution of modern product manufacturing industry since 1900.

Explore technical, social, economic and environmental issues related to nuclear energy.

Understand the main concepts and principles of tribology, with particular emphasis on lubricated systems.

Discover how mathematics can be used to characterise and model the qualitative behaviour of non-linear systems.

Build your confidence with statistical methods and procedures and perform predictive modelling tasks using regression and time series analysis.

Tackle real-life automotive design problems using the knowledge and skills gained during the course.