6533b828fe1ef96bd128900d
RESEARCH PRODUCT
Mean-field games and dynamic demand management in power grids
Fabio BagagioloDario BausoDario BausoDario Bausosubject
Statistics and ProbabilityEconomics and EconometricsMains electricityViscosity solutionDynamic demand managementPopulationDistributional solutionsInterval (mathematics)law.inventionSettore ING-INF/04 - AutomaticalawControl theoryEconomicseducationeducation.field_of_studyApplied MathematicsComputer Graphics and Computer-Aided DesignThermostatMean field gameComputer Science ApplicationsPower (physics)Computational MathematicsComputational Theory and MathematicsTerminal (electronics)Dynamic demandSettore MAT/09 - Ricerca OperativaGame theoryMathematical economicsdescription
This paper applies mean-field game theory to dynamic demand management. For a large population of electrical heating or cooling appliances (called agents), we provide a mean-field game that guarantees desynchronization of the agents thus improving the power network resilience. Second, for the game at hand, we exhibit a mean-field equilibrium, where each agent adopts a bang-bang switching control with threshold placed at a nominal temperature. At equilibrium, through an opportune design of the terminal penalty, the switching control regulates the mean temperature (computed over the population) and the mains frequency around the nominal value. To overcome Zeno phenomena we also adjust the bang-bang control by introducing a thermostat. Third, we show that the equilibrium is stable in the sense that all agents' states, initially at different values, converge to the equilibrium value or remain confined within a given interval for an opportune initial distribution. © 2013 Springer Science+Business Media New York.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2013-11-12 |