Future Power Networks

This module provides an overview of five important topics - flexible AC transmission, power electronics in distribution, state estimation, impact of low system inertia and multi-vector integrated energy system.

Understand the challenges of developing digitalised power systems from a techno-economic-socio perspective.

Improve your lab skills and improve your understanding of the steady-state and dynamic behaviour of a microgrid.

Understand the principles for designing linear multivariable control systems to meet a range of practical applications.

Gain an overview of the technologies involved in making an electric vehicle (EV), as well as those required to enable wider adoption of EVs.

This module covers two broad HVDC technologies and their system-level impact. The focus is on HVDC converter operation and control, operation of HVDC links and HVDC grids and interaction between HVDC and host AC systems.

Learn to build and use engineering-economic models that optimisation expansion plans for future power systems.

Learn how to design computer algorithms for finding minima and maxima and discover how to interpret and modify algorithms found in standard computer packages.

This module covers the analysis of market participants' strategies, the impact of demand elasticity on the market outcomes and prices, operational reliability and ancillary services, network congestion and related locational marginal pricing including transmission access rights, coordination of trading between energy and balancing services, investment in generation and transmission assets.

This module covers modelling of synchronous, asynchronous generation technologies (wind turbine generators), their control for system voltage, and frequency support and interaction with the system.

Gain the analytical skills required to study random phenomena in engineering systems and learn how to set up probabilistic models for engineering problems.

This module covers stability and control challenges encountered in a low (or zero) carbon electric power system including mitigation measures to facilitate deep decarbonisation. The scope is power systems with 100% inverter-based resources using a combination of grid-following and grid-forming converters.

Understand the concepts and theoretical techniques needed to study the stability and stabilisation of nonlinear control systems.

This module covers the enabling technologies and system-level considerations for transforming the electricity system into a more sustainable form. Apart from operation of the low carbon energy technologies (such as wind, solar, hydro, heat networks etc.) the planning and operational challenges posed by decarbonisation are described.

Broaden your knowledge of advanced modern control methodologies and explore topics including Kalman filtering and tracking, fault detection and isolation, and linear matrix inequalities.