Ian A. Hiskens scite author profile

This paper discusses actively involving highly distributed loads in power system control actions; an overview of system control objectives is provided.By Duncan S. Callaway, Member IEEE, and Ian A. Hiskens, Fellow IEEE ABSTRACT | This paper discusses conceptual frameworks for actively involving highly distributed loads in power system control actions. The context for load control is established by providing an overview of system control objectives, including economic dispatch, automatic generation control, and spinning reserve. The paper then reviews existing initiatives that seek to develop load control programs for the provision of power system services. We then discuss some of the challenges to achieving a load control scheme that balances device-level objectives with power system-level objectives. One of the central premises of the paper is that, in order to achieve full responsiveness, direct load control (as opposed to price response) is required to enable fast time scale, predictable control opportunities, especially for the provision of ancillary services such as regulation and contingency reserves. Centralized, hierarchical, and distributed control architectures are discussed along with benefits and disadvantages, especially in relation to integration with the legacy power system control architecture. Implications for the supporting communications infrastructure are also considered. Fully responsive load control is illustrated in the context of thermostatically controlled loads and plug-in electric vehicles.

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Decentralized Charging Control of Large Populations of Plug-in Electric Vehicles

Callaway

Hiskens

2013

IEEE Trans. Contr. Syst. Technol.

854

491

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Decentralized charging control for large populations of plug-in electric vehicles

2010

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Distributed MPC Strategies With Application to Power System Automatic Generation Control

Venkat

Hiskens

Rawlings

et al. 2008

IEEE Trans. Contr. Syst. Technol.

712

437

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Trajectory sensitivity analysis of hybrid systems

Hiskens

Pai

2000

IEEE Trans. Circuits Syst. I

428

307

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Abstract-The development of trajectory sensitivity analysis for hybrid systems, such as power systems, is presented in the paper. A hybrid system model which has a differential-algebraic-discrete (DAD) structure is proposed. This model forms the basis for the subsequent sensitivity analysis. Crucial to the analysis is the development of jump conditions describing the behavior of sensitivities at discrete events, such as switching and state resetting. The efficient computation of sensitivities is discussed. A number of examples are presented to illustrate various aspects of the theory. It is shown that trajectory sensitivities provide insights into system behavior which cannot be obtained from traditional simulation.Index Terms-Dynamic response, hybrid dynamical systems, power systems, switched systems, trajectory sensitivity.

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Ian A. Hiskens

Achieving Controllability of Electric Loads

Decentralized Charging Control of Large Populations of Plug-in Electric Vehicles

Decentralized charging control for large populations of plug-in electric vehicles

Distributed MPC Strategies With Application to Power System Automatic Generation Control

Trajectory sensitivity analysis of hybrid systems

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