In this paper, we develop a
comprehensive real-time interactive framework for the Utility and customers in
a smart grid while ensuring grid-stability and Quality-of-Service (QoS). First,
we propose a hierarchical architecture for the Utility-customer interaction
consisting of sub-components of customer load prediction, renewable generation
integration, power-load balancing and demand response (DR). Within this
hierarchical architecture, we focus on the problem of real-time scheduling in
an abstract grid model consisting of one controller and multiple customer
units. A scalable solution to the real-time scheduling problem is proposed by
combining solutions to two sub-problems (1) centralized sequential decision
making at the controller to maximize an accumulated reward for the whole
micro-grid and (2) distributed auctioning among all customers based on the
optimal load profile obtained by solving the first problem to coordinate their
interactions. We formulate the centralized sequential decision making at the controller
as a hidden mode Markov decision process (HM-MDP). Next, a Vikrey auctioning
game is designed to coordinate the actions of the individual smart-homes to
actually achieve the optimal solution derived by the controller under realistic
gird interaction assumptions. We show that though truthful bidding is a weakly
dominant strategy for all smart-homes in the auctioning game, collusive
equilibria do exist and can jeopardize the effectiveness and efficiency of the
trading opportunity allocation. Analysis on the structure of the Bayesian Nash
equilibrium solution set shows that the Vickrey auctioning game can be made
more robust against collusion by customers (anticipating distributed
smart-homes) by introducing a positive reserve price. The corresponding
auctioning game is then shown to converge to the unique incentive compatible
truthful bidding Bayesian Nash equilibrium, without jeopardizing the
auctioneer’s (microgrid controller’s) prof- t. The paper also explicitly
discusses how this two- step solution approach can be scaled to be suitable for
more complicated smart grid architectures beyond the assumed abstract model.
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