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Cellular Automata Model with Game Theory for Power Management of Hybrid Renewable Energy Smart Grids

  • Prodromos Chatziagorakis
  • Constantinos Elmasides
  • Georgios Ch. Sirakoulis
  • Ioannis Karafyllidis
  • Ioannis Andreadis
  • Nikolaos Georgoulas
  • Damianos Giaouris
  • Athanasios I. Papadopoulos
  • Chrysovalantou Ziogou
  • Dimitris Ipsakis
  • Simira Papadopoulou
  • Panos Seferlis
  • Fotis Stergiopoulos
  • Paris Voutetakis
Part of the Lecture Notes in Computer Science book series (LNCS, volume 8751)

Abstract

In recent years, control of smart grids that match electricity demand in different sites and forms with supply has been considered as one of the most difficult aspect of smart energy grids design. In this paper we present a Cellular Automata (CA) based approach combined with Game Theory for the enhancement of Power Management Strategies (PMSs) of multiple Hybrid Renewable Energy Systems (HYRES) that form a smart grid for the exchange of energy. More specifically, taking advantage of the local interactions of HYRES we coupled CA principles with Public Goods Game (PGG) for modeling. The presented CA model focuses on providing valuable feedback for PMSs of the understudy HYRES connected in a grid. In this manner, a flexible network based HYRES design is considered and applied to specific HYRESs located in Olvio, near Xanthi, Greece, part of SYSTEMS SUNLIGHT facilities. The proposed model can be applied to the understudy HYRESs grid management to enhance and optimize its PMS based on the provided energy prediction scenarios.

Keywords

Cellular Automata Game Theory Modeling Power Management Strategy Hybrid Renewable Energy System Smart Energy Grids 

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Copyright information

© Springer International Publishing Switzerland 2014

Authors and Affiliations

  • Prodromos Chatziagorakis
    • 1
  • Constantinos Elmasides
    • 2
  • Georgios Ch. Sirakoulis
    • 1
  • Ioannis Karafyllidis
    • 1
  • Ioannis Andreadis
    • 1
  • Nikolaos Georgoulas
    • 1
  • Damianos Giaouris
    • 3
  • Athanasios I. Papadopoulos
    • 3
  • Chrysovalantou Ziogou
    • 3
  • Dimitris Ipsakis
    • 3
  • Simira Papadopoulou
    • 3
  • Panos Seferlis
    • 3
  • Fotis Stergiopoulos
    • 3
  • Paris Voutetakis
    • 3
  1. 1.Department of Electrical and Computer EngineeringDemocritus University of ThraceXanthiGreece
  2. 2.Systems Sunlight S.A.XanthiGreece
  3. 3.Chemical Process Engineering Research InstituteCentre for Research and Technology HellasThermi-ThessalonikiGreece

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