TY - JOUR
T1 - Analysis of strategic renewable energy, grid and storage capacity investments via Stackelberg-cournot modelling
AU - Andoni, Merlinda
AU - Robu, Valentin
AU - Couraud, Benoit
AU - Früh, Wolf Gerrit
AU - Norbu, Sonam
AU - Flynn, David
PY - 2021
Y1 - 2021
N2 - With increasing decarbonisation and accessibility to our energy systems and markets, there is a need to understand and optimise the value proposition for different stakeholders. Game-theoretic models represent a promising approach to study strategic interactions between self-interested private energy system investors. In this work, we design and evaluate a game-theoretic framework to study strategic interactions between profit-maximising players that invest in network, renewable generation and storage capacity. Specifically, we study the case where grid capacity is developed by a private renewable investor, but line access is shared with competing renewable and storage investors, thus enabling them to export energy and access electricity demand. We model the problem of deducing how much capacity each player should build as a non-cooperative Stackelberg-Cournot game between a dominant player (leader) who builds the power line and renewable generation capacity, and local renewable and storage investors (multiple followers), who react to the installation of the line by increasing their own capacity. Using data-driven analysis and simulations, we developed an empirical search method for estimating the game equilibrium, where the payoffs capture the realistic operation and control of the energy system under study. A practical demonstration of the underlying methodology is shown for a real-world grid reinforcement project in the UK. The methodology provides a realistic mechanism to analyse investor decision-making and investigate feasible tariffs that encourage distributed renewable investment, with sharing of grid access.
AB - With increasing decarbonisation and accessibility to our energy systems and markets, there is a need to understand and optimise the value proposition for different stakeholders. Game-theoretic models represent a promising approach to study strategic interactions between self-interested private energy system investors. In this work, we design and evaluate a game-theoretic framework to study strategic interactions between profit-maximising players that invest in network, renewable generation and storage capacity. Specifically, we study the case where grid capacity is developed by a private renewable investor, but line access is shared with competing renewable and storage investors, thus enabling them to export energy and access electricity demand. We model the problem of deducing how much capacity each player should build as a non-cooperative Stackelberg-Cournot game between a dominant player (leader) who builds the power line and renewable generation capacity, and local renewable and storage investors (multiple followers), who react to the installation of the line by increasing their own capacity. Using data-driven analysis and simulations, we developed an empirical search method for estimating the game equilibrium, where the payoffs capture the realistic operation and control of the energy system under study. A practical demonstration of the underlying methodology is shown for a real-world grid reinforcement project in the UK. The methodology provides a realistic mechanism to analyse investor decision-making and investigate feasible tariffs that encourage distributed renewable investment, with sharing of grid access.
KW - Data analysis
KW - Energy storage
KW - Game theory
KW - Leader-follower game
KW - Network upgrade
KW - Optimisation
KW - Renewable generation
KW - Stackelberg-Cournot game
UR - http://www.scopus.com/inward/record.url?scp=85102314279&partnerID=8YFLogxK
U2 - 10.1109/ACCESS.2021.3062981
DO - 10.1109/ACCESS.2021.3062981
M3 - Article
AN - SCOPUS:85102314279
SN - 2169-3536
VL - 9
SP - 37752
EP - 37771
JO - IEEE Access
JF - IEEE Access
M1 - 9366750
ER -