In this module you will strengthen your mathematical skills and apply them to important engineering problems. Theory is presented in the context of real engineering scenarios so that both the mathematical technique itself and the engineering concept are both better understood. This includes extending integration into higher dimensions, and introducing linear algebra, including vectors and matrices, which are applied to solving problems on structural mechanics and electronic networks, for example. Methods of approximating and solving non-linear functions are discussed in order to show how hard problems can be simplified. Laplace transforms are introduced which reduce the complexity of differential equations allowing you to solve complex dynamic problems with relative ease. The theoretical development is supported by demonstration and implementation in MATLAB, a numerical analysis tool. By combining analytical techniques with computational tools, you’ll develop clear strategies for solving a wide range of engineering problems with confidence.
This module explores the core principles of engineering science, connecting key concepts to chemical, mechanical, nuclear, and electrical/electronic systems. You will discover how physical principles associated with energy transfer, forces, kinetics, and atomic behaviour shape the function of structures, processes, and components, laying the foundation for all engineering disciplines.
Topics include atomic and molecular behaviour in materials, charge movement, compound formation, and reaction kinetics. You will also examine forces from electrostatic, electromagnetic, and mechanical interactions, along with their effects on displacement, stress, current flow, and the behaviour of solids and fluids. You will also explore the operation of mechanical and electronic components in circuits, structures, and moving devices. Hands-on lab sessions will reinforce these concepts, providing practical experience and bringing theory to life.
This module explores the core principles of engineering science, connecting key concepts to chemical, mechanical, nuclear, and electrical/electronic systems. You will discover how physical principles associated with energy transfer, forces, kinetics, and atomic behaviour shape the function of structures, processes, and components laying the foundation for all engineering disciplines.
Topics include atomic and molecular behaviour in materials, charge movement, compound formation, and reaction kinetics. You will also examine forces from electrostatic, electromagnetic, and mechanical interactions, along with their effects on displacement, stress, current flow, and the behaviour of solids and fluids. You will also explore the operation of mechanical and electronic components in circuits, structures, and moving devices. Hands-on lab sessions will reinforce these concepts, providing practical experience and bringing theory to life.
This module covers key analytical techniques providing a foundation for all engineering programmes. Whether you are already familiar with these concepts or not, this module will bring everyone to the same level and make sure you have the mathematical tools to succeed. Techniques of primary importance to engineering such as complex numbers, differentiation and integration are covered to ensure you can understand and apply all the different methods available and solve real engineering problems during the supported sessions and beyond. This analysis is supported by practical lessons in the use of numerical techniques using tools such as MATLAB. These tools are used not only to show how techniques such as numerical integration are implemented in a way that enables you to generate solutions to any problem you may encounter as an engineer, but they also help you visualise and appreciate the meaning and implications to the analytical techniques used.