Discover the fundamentals of aerodynamics, such as the basic laws of motion for incompressible fluid flow, mass conservation, and viscosity.

Learn the key constructs and thought processes that will help you to solve engineering problems and become a MATLAB and Python scripting expert.

Engage in engineering practice, and know the practical, legal, ethical, and manufacturing constraints, so you can come up with creative solutions.

Formulate equations to predict key performance metrics like cruise range, operating envelope, and take-off and landing for different types of vehicles operating.

Determine the relationship between microstructure and mechanical response of engineering materials and natural materials. Stress analysis, solid mechanics, and material selection are introduced.

Become knowledgeable and skilled in mathematics in order to prepare for the first-year aeronautical programme and for the more advanced techniques required in later years.

Develop your understanding of Newtonian physics, particle dynamics, and momentum, as well as structural mechanics, dynamics, and flight mechanics.

Understand equilibrium, compatibility, stress/strain law, and other fundamentals of structural analysis.

Study thermodynamics, gas dynamics, and heat transfer before moving on to more advanced modules, like propulsion and aerodynamics.

Explore incompressible and compressible aerodynamics and basic prediction methods for designing aerofoils.

Develop your programming skills with the help of a compiled language (C++), and learn further numerical analysis techniques that you will need in both the Aeronautics course and, thereafter, in industry.

Understand your customers and their needs, plan and cost the project, identify and mitigate risks, and create a project proposal. During subsequent projects, you will use the skills you learn in this module.

Know the practical, legal, ethical, and manufacturing constraints engineers must contend with when solving problems or planning projects.

Develop a working knowledge of flight vehicle dynamics, stability, and control. We review both the theoretical background and its practical application of predicting and controlling aircraft dynamics using the Department's Flight Simulation facility.

Learn how to predict failures under multiaxial loading that occur due to yielding, fractures, fatigue, and creep, and identify these failure mechanisms in practice.

Become familiar with probability and statistics, plus vector calculus and numerical analysis.

Using 'system' concepts and Mechatronics, learn how to model electrical systems with mechanical systems.

Learn about ramjets, turbojets, and turbofans' theory, starting with the thermodynamic cycle before diving into individual components' aero-thermal properties.

Get an overview of matrix methods in overall structural analysis (hardness and flexibility), and structural dynamics (force equilibrium, Hamilton's principle, and Lagrange's equation).

Use compressible and incompressible aerodynamics, boundary layers, and finite aspect ratio wings to design aerospace vehicles.

Develop a conventional aircraft using a basic set of operational requirements and integrating your prior knowledge and analytical skills and learn how vehicles are designed using multi-stage approaches.

Discover how automatic control systems are used in a wide range of technologies (not just Aeronautics, but Mechanical Engineering, Electrical Engineering, Chemical Engineering, Finance, Biology).

Take part in one of our five challenging research projects each year to learn about industrial engineering design in a large multidisciplinary team.

Apply structural principles to thin-walled structures representing aeroplane parts. Since modern aircraft are usually composites, learn homogeneous plate theory.

Through I-Explore, you'll have the chance to deepen your knowledge in a brand new subject area, chosen from a huge range of for-credit modules.

All undergraduate courses include one module from I-Explore's wide selection. The module you choose will be fully integrated into your course's curriculum and count as credit towards your degree.

Develop your understanding of the Finite Element Method, which uses a powerful mathematical abstraction based on function spaces, inner products, norms, and operators.

Find out about orbital mechanics, rigid body dynamics, and path planning problems, like time or fuel optimisation. Analysis of spacecraft motion, stability, and control is also included.

Deploy advanced mathematical tools to analyse the broad scope of phenome related to fluid flows and their interaction with structures.

Learn about variational calculus and its applications, plus complex variables and techniques based on them. This approach is useful for designing hypersonic nosecones and deriving potential flow solutions.

Develop the background knowledge and physical understanding you need to evaluate turbulent models critically.

Develop a solid understanding of the theory and implementation of primarily 1D numerical methods for computational fluid dynamics.

Learn how to solve two-dimensional potential, electrostatic and acoustic problems using the finite element method and Boundary Element method.

Advance your knowledge of aerodynamic and thermodynamic analysis of propulsion systems for high-speed flight.

Create an innovative culture, network, and creativity through open innovation practices.

Understand the manufacturing processes of composite materials and their corresponding underlying manufacturing principles..

Build proficiency in the use of the C++ programming language and the skills to be able to write efficient parallel programs.

Discover how to analyse and design spacecraft systems using an industry-standard methodology covering mission objectives, requirements analysis, political and regulatory constraints, and financial considerations.

Learn about current methods for designing spacecraft structures, including launchers, satellite platforms, and inflatable habitats.

Examine the concepts and techniques associated with modern optimisation theory and practice.

Analyse how additive manufacturing is helping solve future industry challenges and build your knowledge of advanced manufacturing methodologies.

Learn how modern mathematical techniques are used to predict conditions when laminar-turbulent transition takes place.

Explore the most popular Machine Learning and AI algorithms used in aerospace research and industry.

Discover the mechanics of composite materials and foams, sandwich construction, and how lightweight structures are analysed, including design optimisation.

Study the theory and practice of aeroelasticity in fixed-wing aircraft, including structural dynamics and turbulence dynamics, and how deformed air vehicles affect control.

Discover the key numerical methods used for solving the governing equations of fluid dynamics for aerodynamic design.

Identify a research topic and independently investigate it, then present the results in a professional setting.

Develop your understanding of the Finite Element Method, which uses a powerful mathematical abstraction based on function spaces, inner products, norms, and operators.

Find out about orbital mechanics, rigid body dynamics, and path planning problems, like time or fuel optimisation. Analysis of spacecraft motion, stability, and control is also included.

Deploy advanced mathematical tools to analyse the broad scope of phenome related to fluid flows and their interaction with structures.

Learn about variational calculus and its applications, plus complex variables and techniques based on them. This approach is useful for designing hypersonic nosecones and deriving potential flow solutions.

Develop the background knowledge and physical understanding you need to evaluate turbulent models critically.

Develop a solid understanding of the theory and implementation of primarily 1D numerical methods for computational fluid dynamics.

Learn how to solve two-dimensional potential, electrostatic and acoustic problems using the finite element method and Boundary Element method.

Advance your knowledge of aerodynamic and thermodynamic analysis of propulsion systems for high-speed flight.

Create an innovative culture, network, and creativity through open innovation practices.

Understand the manufacturing processes of composite materials and their corresponding underlying manufacturing principles..

Build proficiency in the use of the C++ programming language and the skills to be able to write efficient parallel programs.

Discover how to analyse and design spacecraft systems using an industry-standard methodology covering mission objectives, requirements analysis, political and regulatory constraints, and financial considerations.

Learn about current methods for designing spacecraft structures, including launchers, satellite platforms, and inflatable habitats.

Gain a better understanding of the physics and governing equations of fluid dynamics.

Discover the key numerical methods used for solving the governing equations of fluid dynamics for aerodynamic design.

Discover how hypersonic vehicles experience unique flow physics. Also defined are the equations of motion to describe an entry mission for past and current spacecraft.

Discover the mechanics of composite materials and foams, sandwich construction, and how lightweight structures are analysed, including design optimisation.

Study the theory and practice of aeroelasticity in fixed-wing aircraft, including structural dynamics and turbulence dynamics, and how deformed air vehicles affect control.

Examine the concepts and techniques associated with modern optimisation theory and practice.

Analyse how additive manufacturing is helping solve future industry challenges and build your knowledge of advanced manufacturing methodologies.

Learn how modern mathematical techniques are used to predict conditions when laminar-turbulent transition takes place.

Explore the most popular Machine Learning and AI algorithms used in aerospace research and industry.

Gain a greater understanding of the financial, strategic and operational context of your core discipline.

Discover the fundamentals of aerodynamics, such as the basic laws of motion for incompressible fluid flow, mass conservation, and viscosity.

Learn the key constructs and thought processes that will help you to solve engineering problems and become a MATLAB and Python scripting expert.

Engage in engineering practice, and know the practical, legal, ethical, and manufacturing constraints, so you can come up with creative solutions.

Formulate equations to predict key performance metrics like cruise range, operating envelope, and take-off and landing for different types of vehicles operating.

Determine the relationship between microstructure and mechanical response of engineering materials and natural materials. Stress analysis, solid mechanics, and material selection are introduced.

Become knowledgeable and skilled in mathematics in order to prepare for the first-year aeronautical programme and for the more advanced techniques required in later years.

Develop your understanding of Newtonian physics, particle dynamics, and momentum, as well as structural mechanics, dynamics, and flight mechanics.

Understand equilibrium, compatibility, stress/strain law, and other fundamentals of structural analysis.

Study thermodynamics, gas dynamics, and heat transfer before moving on to more advanced modules, like propulsion and aerodynamics.

Explore incompressible and compressible aerodynamics and basic prediction methods for designing aerofoils.

Develop your programming skills with the help of a compiled language (C++), and learn further numerical analysis techniques that you will need in both the Aeronautics course and, thereafter, in industry.

Understand your customers and their needs, plan and cost the project, identify and mitigate risks, and create a project proposal. During subsequent projects, you will use the skills you learn in this module.

Know the practical, legal, ethical, and manufacturing constraints engineers must contend with when solving problems or planning projects.

Develop a working knowledge of flight vehicle dynamics, stability, and control. We review both the theoretical background and its practical application of predicting and controlling aircraft dynamics using the Department's Flight Simulation facility.

Learn how to predict failures under multiaxial loading that occur due to yielding, fractures, fatigue, and creep, and identify these failure mechanisms in practice.

Become familiar with probability and statistics, plus vector calculus and numerical analysis.

Using 'system' concepts and Mechatronics, learn how to model electrical systems with mechanical systems.

Learn about ramjets, turbojets, and turbofans' theory, starting with the thermodynamic cycle before diving into individual components' aero-thermal properties.

Get an overview of matrix methods in overall structural analysis (hardness and flexibility), and structural dynamics (force equilibrium, Hamilton's principle, and Lagrange's equation).

Use compressible and incompressible aerodynamics, boundary layers, and finite aspect ratio wings to design aerospace vehicles.

Develop a conventional aircraft using a basic set of operational requirements and integrating your prior knowledge and analytical skills and learn how vehicles are designed using multi-stage approaches.

Discover how automatic control systems are used in a wide range of technologies (not just Aeronautics, but Mechanical Engineering, Electrical Engineering, Chemical Engineering, Finance, Biology).

Take part in one of our five challenging research projects each year to learn about industrial engineering design in a large multidisciplinary team.

Apply structural principles to thin-walled structures representing aeroplane parts. Since modern aircraft are usually composites, learn homogeneous plate theory.

Through I-Explore, you'll have the chance to deepen your knowledge in a brand new subject area, chosen from a huge range of for-credit modules.

All undergraduate courses include one module from I-Explore's wide selection. The module you choose will be fully integrated into your course's curriculum and count as credit towards your degree.

Develop your understanding of the Finite Element Method, which uses a powerful mathematical abstraction based on function spaces, inner products, norms, and operators.

Find out about orbital mechanics, rigid body dynamics, and path planning problems, like time or fuel optimisation. Analysis of spacecraft motion, stability, and control is also included.

Deploy advanced mathematical tools to analyse the broad scope of phenome related to fluid flows and their interaction with structures.

Learn about variational calculus and its applications, plus complex variables and techniques based on them. This approach is useful for designing hypersonic nosecones and deriving potential flow solutions.

Develop the background knowledge and physical understanding you need to evaluate turbulent models critically.

Develop a solid understanding of the theory and implementation of primarily 1D numerical methods for computational fluid dynamics.

Learn how to solve two-dimensional potential, electrostatic and acoustic problems using the finite element method and Boundary Element method.

Advance your knowledge of aerodynamic and thermodynamic analysis of propulsion systems for high-speed flight.

Create an innovative culture, network, and creativity through open innovation practices.

Understand the manufacturing processes of composite materials and their corresponding underlying manufacturing principles..

Build proficiency in the use of the C++ programming language and the skills to be able to write efficient parallel programs.

Discover how to analyse and design spacecraft systems using an industry-standard methodology covering mission objectives, requirements analysis, political and regulatory constraints, and financial considerations.

Learn about current methods for designing spacecraft structures, including launchers, satellite platforms, and inflatable habitats.

Examine the concepts and techniques associated with modern optimisation theory and practice.

Analyse how additive manufacturing is helping solve future industry challenges and build your knowledge of advanced manufacturing methodologies.

Learn how modern mathematical techniques are used to predict conditions when laminar-turbulent transition takes place.

Explore the most popular Machine Learning and AI algorithms used in aerospace research and industry.

Discover the mechanics of composite materials and foams, sandwich construction, and how lightweight structures are analysed, including design optimisation.

Study the theory and practice of aeroelasticity in fixed-wing aircraft, including structural dynamics and turbulence dynamics, and how deformed air vehicles affect control.

Discover the key numerical methods used for solving the governing equations of fluid dynamics for aerodynamic design.

Discover the fundamentals of aerodynamics, such as the basic laws of motion for incompressible fluid flow, mass conservation, and viscosity.

Learn the key constructs and thought processes that will help you to solve engineering problems and become a MATLAB and Python scripting expert.

Engage in engineering practice, and know the practical, legal, ethical, and manufacturing constraints, so you can come up with creative solutions.

Formulate equations to predict key performance metrics like cruise range, operating envelope, and take-off and landing for different types of vehicles operating.

Determine the relationship between microstructure and mechanical response of engineering materials and natural materials. Stress analysis, solid mechanics, and material selection are introduced.

Become knowledgeable and skilled in mathematics in order to prepare for the first-year aeronautical programme and for the more advanced techniques required in later years.

Develop your understanding of Newtonian physics, particle dynamics, and momentum, as well as structural mechanics, dynamics, and flight mechanics.

Understand equilibrium, compatibility, stress/strain law, and other fundamentals of structural analysis.

Study thermodynamics, gas dynamics, and heat transfer before moving on to more advanced modules, like propulsion and aerodynamics.

Explore incompressible and compressible aerodynamics and basic prediction methods for designing aerofoils.

Develop your programming skills with the help of a compiled language (C++), and learn further numerical analysis techniques that you will need in both the Aeronautics course and, thereafter, in industry.

Understand your customers and their needs, plan and cost the project, identify and mitigate risks, and create a project proposal. During subsequent projects, you will use the skills you learn in this module.

Know the practical, legal, ethical, and manufacturing constraints engineers must contend with when solving problems or planning projects.

Develop a working knowledge of flight vehicle dynamics, stability, and control. We review both the theoretical background and its practical application of predicting and controlling aircraft dynamics using the Department's Flight Simulation facility.

Learn how to predict failures under multiaxial loading that occur due to yielding, fractures, fatigue, and creep, and identify these failure mechanisms in practice.

Become familiar with probability and statistics, plus vector calculus and numerical analysis.

Using 'system' concepts and Mechatronics, learn how to model electrical systems with mechanical systems.

Learn about ramjets, turbojets, and turbofans' theory, starting with the thermodynamic cycle before diving into individual components' aero-thermal properties.

Get an overview of matrix methods in overall structural analysis (hardness and flexibility), and structural dynamics (force equilibrium, Hamilton's principle, and Lagrange's equation).

Use compressible and incompressible aerodynamics, boundary layers, and finite aspect ratio wings to design aerospace vehicles.

Develop a conventional aircraft using a basic set of operational requirements and integrating your prior knowledge and analytical skills and learn how vehicles are designed using multi-stage approaches.

Discover how automatic control systems are used in a wide range of technologies (not just Aeronautics, but Mechanical Engineering, Electrical Engineering, Chemical Engineering, Finance, Biology).

Take part in one of our five challenging research projects each year to learn about industrial engineering design in a large multidisciplinary team.

Apply structural principles to thin-walled structures representing aeroplane parts. Since modern aircraft are usually composites, learn homogeneous plate theory.

Through I-Explore, you'll have the chance to deepen your knowledge in a brand new subject area, chosen from a huge range of for-credit modules.

All undergraduate courses include one module from I-Explore's wide selection. The module you choose will be fully integrated into your course's curriculum and count as credit towards your degree.

Develop your understanding of the Finite Element Method, which uses a powerful mathematical abstraction based on function spaces, inner products, norms, and operators.

Find out about orbital mechanics, rigid body dynamics, and path planning problems, like time or fuel optimisation. Analysis of spacecraft motion, stability, and control is also included.

Deploy advanced mathematical tools to analyse the broad scope of phenome related to fluid flows and their interaction with structures.

Learn about variational calculus and its applications, plus complex variables and techniques based on them. This approach is useful for designing hypersonic nosecones and deriving potential flow solutions.

Develop the background knowledge and physical understanding you need to evaluate turbulent models critically.

Develop a solid understanding of the theory and implementation of primarily 1D numerical methods for computational fluid dynamics.

Learn how to solve two-dimensional potential, electrostatic and acoustic problems using the finite element method and Boundary Element method.

Advance your knowledge of aerodynamic and thermodynamic analysis of propulsion systems for high-speed flight.

Create an innovative culture, network, and creativity through open innovation practices.

Understand the manufacturing processes of composite materials and their corresponding underlying manufacturing principles..

Build proficiency in the use of the C++ programming language and the skills to be able to write efficient parallel programs.

Discover how to analyse and design spacecraft systems using an industry-standard methodology covering mission objectives, requirements analysis, political and regulatory constraints, and financial considerations.

Learn about current methods for designing spacecraft structures, including launchers, satellite platforms, and inflatable habitats.

Examine the concepts and techniques associated with modern optimisation theory and practice.

Analyse how additive manufacturing is helping solve future industry challenges and build your knowledge of advanced manufacturing methodologies.

Learn how modern mathematical techniques are used to predict conditions when laminar-turbulent transition takes place.

Explore the most popular Machine Learning and AI algorithms used in aerospace research and industry.

Discover the mechanics of composite materials and foams, sandwich construction, and how lightweight structures are analysed, including design optimisation.

Study the theory and practice of aeroelasticity in fixed-wing aircraft, including structural dynamics and turbulence dynamics, and how deformed air vehicles affect control.

Discover the key numerical methods used for solving the governing equations of fluid dynamics for aerodynamic design.

Identify a research topic and independently investigate it, then present the results in a professional setting.

Develop your understanding of the Finite Element Method, which uses a powerful mathematical abstraction based on function spaces, inner products, norms, and operators.

Find out about orbital mechanics, rigid body dynamics, and path planning problems, like time or fuel optimisation. Analysis of spacecraft motion, stability, and control is also included.

Deploy advanced mathematical tools to analyse the broad scope of phenome related to fluid flows and their interaction with structures.

Learn about variational calculus and its applications, plus complex variables and techniques based on them. This approach is useful for designing hypersonic nosecones and deriving potential flow solutions.

Develop the background knowledge and physical understanding you need to evaluate turbulent models critically.

Develop a solid understanding of the theory and implementation of primarily 1D numerical methods for computational fluid dynamics.

Learn how to solve two-dimensional potential, electrostatic and acoustic problems using the finite element method and Boundary Element method.

Advance your knowledge of aerodynamic and thermodynamic analysis of propulsion systems for high-speed flight.

Create an innovative culture, network, and creativity through open innovation practices.

Understand the manufacturing processes of composite materials and their corresponding underlying manufacturing principles..

Build proficiency in the use of the C++ programming language and the skills to be able to write efficient parallel programs.

Discover how to analyse and design spacecraft systems using an industry-standard methodology covering mission objectives, requirements analysis, political and regulatory constraints, and financial considerations.

Learn about current methods for designing spacecraft structures, including launchers, satellite platforms, and inflatable habitats.

Gain a better understanding of the physics and governing equations of fluid dynamics.

Discover the key numerical methods used for solving the governing equations of fluid dynamics for aerodynamic design.

Discover how hypersonic vehicles experience unique flow physics. Also defined are the equations of motion to describe an entry mission for past and current spacecraft.

Discover the mechanics of composite materials and foams, sandwich construction, and how lightweight structures are analysed, including design optimisation.

Study the theory and practice of aeroelasticity in fixed-wing aircraft, including structural dynamics and turbulence dynamics, and how deformed air vehicles affect control.

Examine the concepts and techniques associated with modern optimisation theory and practice.

Analyse how additive manufacturing is helping solve future industry challenges and build your knowledge of advanced manufacturing methodologies.

Learn how modern mathematical techniques are used to predict conditions when laminar-turbulent transition takes place.

Explore the most popular Machine Learning and AI algorithms used in aerospace research and industry.

Gain a greater understanding of the financial, strategic and operational context of your core discipline.

Discover the fundamentals of aerodynamics, such as the basic laws of motion for incompressible fluid flow, mass conservation, and viscosity.

Learn the key constructs and thought processes that will help you to solve engineering problems and become a MATLAB and Python scripting expert.

Engage in engineering practice, and know the practical, legal, ethical, and manufacturing constraints, so you can come up with creative solutions.

Formulate equations to predict key performance metrics like cruise range, operating envelope, and take-off and landing for different types of vehicles operating.

Determine the relationship between microstructure and mechanical response of engineering materials and natural materials. Stress analysis, solid mechanics, and material selection are introduced.

Become knowledgeable and skilled in mathematics in order to prepare for the first-year aeronautical programme and for the more advanced techniques required in later years.

Develop your understanding of Newtonian physics, particle dynamics, and momentum, as well as structural mechanics, dynamics, and flight mechanics.

Understand equilibrium, compatibility, stress/strain law, and other fundamentals of structural analysis.

Study thermodynamics, gas dynamics, and heat transfer before moving on to more advanced modules, like propulsion and aerodynamics.

Explore incompressible and compressible aerodynamics and basic prediction methods for designing aerofoils.

Develop your programming skills with the help of a compiled language (C++), and learn further numerical analysis techniques that you will need in both the Aeronautics course and, thereafter, in industry.

Understand your customers and their needs, plan and cost the project, identify and mitigate risks, and create a project proposal. During subsequent projects, you will use the skills you learn in this module.

Know the practical, legal, ethical, and manufacturing constraints engineers must contend with when solving problems or planning projects.

Develop a working knowledge of flight vehicle dynamics, stability, and control. We review both the theoretical background and its practical application of predicting and controlling aircraft dynamics using the Department's Flight Simulation facility.

Learn how to predict failures under multiaxial loading that occur due to yielding, fractures, fatigue, and creep, and identify these failure mechanisms in practice.

Become familiar with probability and statistics, plus vector calculus and numerical analysis.

Using 'system' concepts and Mechatronics, learn how to model electrical systems with mechanical systems.

Learn about ramjets, turbojets, and turbofans' theory, starting with the thermodynamic cycle before diving into individual components' aero-thermal properties.

Get an overview of matrix methods in overall structural analysis (hardness and flexibility), and structural dynamics (force equilibrium, Hamilton's principle, and Lagrange's equation).

Use compressible and incompressible aerodynamics, boundary layers, and finite aspect ratio wings to design aerospace vehicles.

Develop a conventional aircraft using a basic set of operational requirements and integrating your prior knowledge and analytical skills and learn how vehicles are designed using multi-stage approaches.

Discover how automatic control systems are used in a wide range of technologies (not just Aeronautics, but Mechanical Engineering, Electrical Engineering, Chemical Engineering, Finance, Biology).

Take part in one of our five challenging research projects each year to learn about industrial engineering design in a large multidisciplinary team.

Apply structural principles to thin-walled structures representing aeroplane parts. Since modern aircraft are usually composites, learn homogeneous plate theory.

Through I-Explore, you'll have the chance to deepen your knowledge in a brand new subject area, chosen from a huge range of for-credit modules.

All undergraduate courses include one module from I-Explore's wide selection. The module you choose will be fully integrated into your course's curriculum and count as credit towards your degree.

Develop your understanding of the Finite Element Method, which uses a powerful mathematical abstraction based on function spaces, inner products, norms, and operators.

Find out about orbital mechanics, rigid body dynamics, and path planning problems, like time or fuel optimisation. Analysis of spacecraft motion, stability, and control is also included.

Deploy advanced mathematical tools to analyse the broad scope of phenome related to fluid flows and their interaction with structures.

Learn about variational calculus and its applications, plus complex variables and techniques based on them. This approach is useful for designing hypersonic nosecones and deriving potential flow solutions.

Develop the background knowledge and physical understanding you need to evaluate turbulent models critically.

Develop a solid understanding of the theory and implementation of primarily 1D numerical methods for computational fluid dynamics.

Learn how to solve two-dimensional potential, electrostatic and acoustic problems using the finite element method and Boundary Element method.

Advance your knowledge of aerodynamic and thermodynamic analysis of propulsion systems for high-speed flight.

Create an innovative culture, network, and creativity through open innovation practices.

Understand the manufacturing processes of composite materials and their corresponding underlying manufacturing principles..

Build proficiency in the use of the C++ programming language and the skills to be able to write efficient parallel programs.

Discover how to analyse and design spacecraft systems using an industry-standard methodology covering mission objectives, requirements analysis, political and regulatory constraints, and financial considerations.

Learn about current methods for designing spacecraft structures, including launchers, satellite platforms, and inflatable habitats.

Examine the concepts and techniques associated with modern optimisation theory and practice.

Analyse how additive manufacturing is helping solve future industry challenges and build your knowledge of advanced manufacturing methodologies.

Learn how modern mathematical techniques are used to predict conditions when laminar-turbulent transition takes place.

Explore the most popular Machine Learning and AI algorithms used in aerospace research and industry.

Discover the mechanics of composite materials and foams, sandwich construction, and how lightweight structures are analysed, including design optimisation.

Study the theory and practice of aeroelasticity in fixed-wing aircraft, including structural dynamics and turbulence dynamics, and how deformed air vehicles affect control.

Discover the key numerical methods used for solving the governing equations of fluid dynamics for aerodynamic design.

Identify a research topic and independently investigate it, then present the results in a professional setting.

Develop your understanding of the Finite Element Method, which uses a powerful mathematical abstraction based on function spaces, inner products, norms, and operators.

Find out about orbital mechanics, rigid body dynamics, and path planning problems, like time or fuel optimisation. Analysis of spacecraft motion, stability, and control is also included.

Deploy advanced mathematical tools to analyse the broad scope of phenome related to fluid flows and their interaction with structures.

Learn about variational calculus and its applications, plus complex variables and techniques based on them. This approach is useful for designing hypersonic nosecones and deriving potential flow solutions.

Develop the background knowledge and physical understanding you need to evaluate turbulent models critically.

Develop a solid understanding of the theory and implementation of primarily 1D numerical methods for computational fluid dynamics.

Learn how to solve two-dimensional potential, electrostatic and acoustic problems using the finite element method and Boundary Element method.

Advance your knowledge of aerodynamic and thermodynamic analysis of propulsion systems for high-speed flight.

Create an innovative culture, network, and creativity through open innovation practices.

Understand the manufacturing processes of composite materials and their corresponding underlying manufacturing principles..

Build proficiency in the use of the C++ programming language and the skills to be able to write efficient parallel programs.

Discover how to analyse and design spacecraft systems using an industry-standard methodology covering mission objectives, requirements analysis, political and regulatory constraints, and financial considerations.

Learn about current methods for designing spacecraft structures, including launchers, satellite platforms, and inflatable habitats.

Gain a better understanding of the physics and governing equations of fluid dynamics.

Discover the key numerical methods used for solving the governing equations of fluid dynamics for aerodynamic design.

Discover how hypersonic vehicles experience unique flow physics. Also defined are the equations of motion to describe an entry mission for past and current spacecraft.

Discover the mechanics of composite materials and foams, sandwich construction, and how lightweight structures are analysed, including design optimisation.

Study the theory and practice of aeroelasticity in fixed-wing aircraft, including structural dynamics and turbulence dynamics, and how deformed air vehicles affect control.

Examine the concepts and techniques associated with modern optimisation theory and practice.

Analyse how additive manufacturing is helping solve future industry challenges and build your knowledge of advanced manufacturing methodologies.

Learn how modern mathematical techniques are used to predict conditions when laminar-turbulent transition takes place.

Explore the most popular Machine Learning and AI algorithms used in aerospace research and industry.

Gain a greater understanding of the financial, strategic and operational context of your core discipline.