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Through project-based and practical, hands-on learning, you'll learn about the practical aspects of printed circuit board design, manufacture, assembly and testing. 
 

You'll learn about the software development life cycle and the tools used to build software programs, getting to grips with how to identify system requirements and convert a written specification to a procedural software design and quality metrics.

You'll also learn how to analyse a problem and formulate an algorithm for solving it.

You'll explore the static and dynamic analyses of the robots, and think about their mechanical components, including linkages, bearing, shaft and gear, as well as technical drawing (2D and 3D CAD).

You'll also cover the application of artificial intelligence in enhancing robotic systems' efficiency and capabilities, such as machine learning for autonomous decision-making and sensor data interpretation.

In this module, you'll learn mathematical techniques that you can use for intricate engineering problems.

Over a full year, you'll work through topics including algebra, calculus, matrices and complex numbers, learning to recognise when an engineering problem calls for a given method.

You'll also learn efficient strategies for breaking down and solving multifaceted problems, applicable in both mathematical and engineering activity.

You'll start by grasping the essential theory behind combinational and sequential logic, Boolean algebra, and other core concepts.

Then you'll directly apply this knowledge as you analyse, design and implement digital circuits and systems using microcontrollers.

Through hands-on practical sessions and projects, you'll reinforce your learning, while developing crucial real-world engineering skills.

By the end, you'll be able to confidently identify key digital components, understand microcontroller architecture, and describe assembly language commands - ready for advanced study and career opportunities across electronics and computer engineering.

You'll explore programmable logic controllers and process control systems, before designing a PLC based system for process control.

You'll work in the lab and attend lectures to learn all about the construction and characteristics of different types of electrical machines, and single and three phase power transformers. 

In this team-based module, you'll work through the full product design process, considering economic, social and sustainability aspects at each stage.

You'll learn how to adopt an inclusive approach, make group decisions, and report on your processes. You'll also identify and take up professional development opportunities to get yourself career-ready.

You'll analyse and develop complex, sequential systems to meet specified requirements, using microcontrollers, interfacing systems and programming skills.

Through a module-long project, you'll explore the uses and limitations of sequential systems, apply your understanding in a design-led solution, and prepare for careers across digital electronics and computer engineering

You'll explore the measurements of different physical quantities, such as temperature, liquid level and flow rates.

You'll also investigate the various sensors for the measurement of physical quantities, and analyse the characteristics of instruments and the uncertainty of measurements. 

You'll learn the fundamental knowledge and tools needed for modelling, design, planning, and control of robot systems, getting an introduction to applications including serial robots, parallel robots and mobile robots. 

You'll formulate a smart business plan in this career-driven module, covering viability, licensing, funding, launch, and growth.

Working in groups, you'll use risk management principles to protect your plans, identify ethical issues and relevant regulations, and develop your ability to sell your vision to investors.

With guidance from an expert supervisor, you'll identify a challenge that excites you and develop an approach to investigating it.

As you apply your analytical and creative skills to the project, you'll build self-confidence and resourcefulness alongside your new engineering capabilities.

You'll also learn to showcase your work professionally through reports and presentations that demonstrate your readiness for an engineering career after university.

You'll learn some of the important technical and problem solving skills sought after in the fields of signal processing and data analysis.

You'll be introduced to a range of topics that will include making use of concepts and knowledge from other subjects, including mathematics.

Additionally, you'll explore how artificial intelligence can be applied in signal processing and data analysis to enhance traditional methods.

You'll gain both a theoretical foundation and a practical insight into AI principles and their applications in robotics.

You'll cover the integration of AI algorithms into robotic control systems to enhance perception and decision-making capabilities, focusing on real-world applications and drawing on case studies of AI-driven robotic solutions in select industries.

You'll also consider the ethical considerations of AI in robotics.

You'll determine system requirements and design relevant controllers in this module, using industry-standard computer aided engineering packages.

You'll also explore the relative stability of systems, apply function identification to live data, and analyse the effects of changing parameters in a control system.

You'll review the static and the dynamic characteristics of sensors, as well as the measurement of physical quantities, such as flow, liquid-level, temperature and pressure, using different types of sensors.

You'll explore signal conditioning, signal processing, data acquisition, and signal transmission in a sensing system.

You'll also investigate the integration of Artificial Intelligence techniques with sensor technologies to enhance autonomous robotic perception and decision-making capabilities.