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Book chapterBialek J, O’Malley M, 2025, , Handbook on Electricity Regulation, Pages: 269-283
The following features have characterised traditional grids: (i) they were powered by large thermal/hydro/nuclear power stations whose output was fully controllable and therefore predictable, (ii) their technical characteristics were determined by the physics of synchronous machines used to convert mechanical/thermal energy into AC electricity. However, the combined drivers of decarbonisation and reduced costs of variable renewable resources (VRE), such as wind and solar photovoltaics stations, led to increased penetration of VREs with the following consequences: (i) the output of VRE plants is no longer controllable or fully predictable due to vagaries of weather (ii) the system technical characteristics are determined by control algorithms of inverters which connect VRE plants to the grid. This chapter covers the challenges the inverter-based grids pose for power system operation and planning. In particular we cover the resources adequacy challenge and the services challenge (synchronisation, frequency control, voltage control, damping, protection, blackstart and restoration).
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Journal articleChu Z, Teng F, 2025, , IEEE TRANSACTIONS ON POWER SYSTEMS, Vol: 40, Pages: 449-462, ISSN: 0885-8950
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- Citations: 2
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Journal articleChu Z, Teng F, 2025, , IEEE TRANSACTIONS ON SUSTAINABLE ENERGY, Vol: 16, Pages: 700-715, ISSN: 1949-3029
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Journal articleSpyrou E, Hobbs B, Chattopadhyay D, et al., 2024, , IEEE Transactions on Energy Markets, Policy and Regulation, Vol: 2, Pages: 436-448, ISSN: 2771-9626
Computational advances along with the profound impact of uncertainty on power system investments have motivated the creation of power system planning frameworks that handle long-run uncertainty, large number of alternative plans, and multiple objectives. Planning agencies seek guidance to assess such frameworks. This article addresses this need in two ways. First, we augment previously proposed criteria for assessing planning frameworks by including new criteria such as stakeholder acceptance to make the assessments more comprehensive, while enhancing the practical applicability of assessment criteria by offering criterion-specific themes and questions. Second, using the proposed criteria, we compare two widely used but fundamentally distinct frameworks: an ‘agree-on-plans’ framework, Robust Decision Making (RDM), and an ‘agree-on-assumptions’ framework, centered around Stochastic Programming (SP). By comparing for the first time head-to-head the two distinct frameworks for an electricity supply planning problem under uncertainties in Bangladesh, we conclude that RDM relies on a large number of simulations to provide ample information to decision makers and stakeholders, and to facilitate updating of subjective inputs. In contrast, SP is a highly dimensional optimization problem that identifies plans with relatively good probability-weighted performance in a single step, but even with computational advances remains subject to the curse of dimensionality.
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Journal articleO'Malley M, Holttinen H, Cutululis N, et al., 2024, , Wind Energy Science, Vol: 9, Pages: 2087-2112, ISSN: 2366-7443
The share of wind power in power systems is increasing dramatically, and this is happening in parallel with increased penetration of solar photovoltaics, storage, other inverter-based technologies, and electrification of other sectors. Recognising the fundamental objective of power systems, maintaining supply–demand balance reliably at the lowest cost, and integrating all these technologies are significant research challenges that are driving radical changes to planning and operations of power systems globally. In this changing environment, wind power can maximise its long-term value to the power system by balancing the needs it imposes on the power system with its contribution to addressing these needs with services. A needs and services paradigm is adopted here to highlight these research challenges, which should also be guided by a balanced approach, concentrating on its advantages over competitors. The research challenges within the wind technology itself are many and varied, with control and coordination internally being a focal point in parallel with a strong recommendation for a holistic approach targeted at where wind has an advantage over its competitors and in coordination with research into other technologies such as storage, power electronics, and power systems.
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Conference paperThakar S, Ramasubramanian D, Matevosyan J, et al., 2024, , 2024 IEEE Power & Energy Society General Meeting (PESGM), Publisher: IEEE, Pages: 1-5
With the increasing penetration of inverter based resources (IBRs) in present and future power systems, it is important to consider the different grid services needed from/provided by IBRs. To ensure network stability after a contingency such as trip of a synchronous generator or a fault, a grid may require services (for example, fast voltage control) from various IBRs. New IBRs to be installed with future capabilities (inherent blackstart capability) are often seen as a potential source for such services. However, the capability of many existing IBRs today are underutilized and if the capability from existing IBRs is utilized efficiently, it could greatly improve the network performance and reduce services needed from the future IBRs. This paper provides few illustrative examples detailing some of the services that may be needed by an IBR-dominated grid and the impact of asking these services from future IBRs and/or supplementing with services from existing IBRs.
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Journal articleChu Z, Wu J, Teng F, 2024, , ELECTRIC POWER SYSTEMS RESEARCH, Vol: 235, ISSN: 0378-7796
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Journal articleDucoin E, Gu Y, Chaudhuri B, et al., 2024, , IEEE Transactions on Power Systems, Vol: 39, Pages: 6345-6358, ISSN: 0885-8950
Most of the new renewable generation in power systems is connected through Grid-Following inverters (GFL). The accompanying decline of fossil-fuelled synchronous generation reduces the grid inertia. As these two trends progress, instabilities become more likely. To allow more renewables onto the grid, the use of combinations of GFL and Grid-Forming inverters (GFM) has been proposed, however, it is unclear how to parametrise these inverters for system objectives. This paper tackles the issue of parametrizing each GFM and GFL to ensure frequency trajectories at all buses, expressed in terms of frequency deviation, Rate of Change of Frequency and settling time, are stable, recognising that local frequencies can deviate substantially from the Center of Inertia (COI). The procedure to achieve this comprises simple closed-form equations, and yields the required values of droop slopes, GFM filter bandwidth and GFL Phase-Locked Loop bandwidth. These equations are derived from an analytical formulation of swing equations for GFM and GFL which are combined to describe the behaviour of not only the COI but also each bus. The detailed EMT simulations of a modified IEEE 14-bus network demonstrate that the simplifying assumptions made in the analysis are justified by the close correspondence between simulation and analytical projections.
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Journal articleHawker G, Bell K, Bialek J, et al., 2024, , PROGRESS IN ENERGY, Vol: 6
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Journal articleChu Z, Cui G, Teng F, 2024, , IEEE TRANSACTIONS ON SUSTAINABLE ENERGY, Vol: 15, Pages: 1715-1728, ISSN: 1949-3029
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