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Stability analysis of nonlinear stochastic flexibility function in smart energy systems (2405.15099v1)
Published 23 May 2024 in eess.SY and cs.SY
Abstract: Demand-side management provides a great potential for improving the efficiency and reliability of energy systems. This requires a mechanism to connect the market level and the demand side. The flexibility function is a novel approach that bridges the gap between the markets and the dynamics of physical assets at the lower levels of the energy systems and activates demand-side flexibility with the purpose of decision-making as well as for offering a new framework for balancing and grid services. Employing this function as a key for many decision-making and control algorithms reveals that a mathematically rigorous stability analysis is required for it. In this paper, we investigate the stability properties of two nonlinear flexibility functions, as a dynamic mapping between electricity price and power consumption. Specifically, we analyze the stability of a deterministic flexibility function and an It^{o} stochastic flexibility function. Simulation results are also provided to demonstrate the dynamics of the flexibility functions and to show that the analytical results hold.
- World Meteorological Organization (WMO). State of the climate in europe 2022. WMO: World Meteorological Organisation, 2023.
- Evolutionary game theoretic demand-side management and control for a class of networked smart grid. Automatica, 70:94–100, 2016.
- A real-time control framework for smart power networks: Design methodology and stability. Automatica, 58:43–50, 2015.
- Market implementation of multiple-arrival multiple-deadline differentiated energy services. Automatica, 116:108933, 2020.
- On the assessment and control optimisation of demand response programs in residential buildings. Renewable and Sustainable Energy Reviews, 127:109861, 2020.
- A survey of industrial applications of demand response. Electric Power Systems Research, 141:31–49, 2016.
- The potential of power-to-heat demand response to improve the flexibility of the energy system: An empirical review. Renewable and Sustainable Energy Reviews, 138:110489, 2021.
- A Rezaee Jordehi. Optimisation of demand response in electric power systems, a review. Renewable and sustainable energy reviews, 103:308–319, 2019.
- Model predictive control for demand side management in buildings: A survey. Sustainable Cities and Society, 75:103381, 2021.
- Reinforcement learning for demand response: A review of algorithms and modeling techniques. Applied energy, 235:1072–1089, 2019.
- Review of control strategies for improving the energy flexibility provided by heat pump systems in buildings. Journal of Process Control, 74:35–49, 2019.
- Experimental demonstration of frequency regulation by commercial buildings—part i: Modeling and hierarchical control design. IEEE Transactions on Smart Grid, 9(4):3213–3223, 2016.
- A unified framework for coordination of thermostatically controlled loads. Automatica, 152:111002, 2023.
- A review of hierarchical control for building microgrids. Renewable and Sustainable Energy Reviews, 118:109523, 2020.
- Ancillary services 4.0: A top-to-bottom control-based approach for solving ancillary services problems in smart grids. Ieee Access, 6:11694–11706, 2018.
- A control-based method to meet tso and dso ancillary services needs by flexible end-users. IEEE Transactions on Power Systems, 35(3):1868–1880, 2019.
- Market mechanisms for local electricity markets: A review of models, solution concepts and algorithmic techniques. Renewable and Sustainable Energy Reviews, 156:111890, 2022.
- A hierarchical price-based demand response framework in distribution network. IEEE Transactions on Smart Grid, 13(2):1151–1164, 2021.
- Demand response as a service: Clearing multiple distribution-level markets. IEEE Transactions on Cloud Computing, 10(1):82–96, 2021.
- Transactive control of commercial buildings for demand response. IEEE Transactions on Power Systems, 32(1):774–783, 2016.
- From white-box to grey-box modelling of the heat dynamics of buildings. In E3S Web of Conferences, volume 362, page 12002. EDP Sciences, 2022.
- Characterizing the energy flexibility of buildings and districts. Applied energy, 225:175–182, 2018.
- Stochastic nonlinear modelling and application of price-based energy flexibility. Applied Energy, 275:115096, 2020.
- Implementing flexibility into energy planning models: Soft-linking of a high-level energy planning model and a short-term operational model. Applied Energy, 260:114292, 2020.
- Model predictive control based on stochastic grey-box models. In Towards Energy Smart Homes: Algorithms, Technologies, and Applications, pages 329–380. Springer, 2012.
- A unifying energy-based approach to stability of power grids with market dynamics. IEEE Transactions on Automatic Control, 62(6):2612–2622, 2016.
- Uffe Høgsbro Thygesen. Stochastic Differential Equations for Science and Engineering. CRC Press, 2023.
- James O Ramsay. Monotone regression splines in action. Statistical science, pages 425–441, 1988.
- Frigg 2.0: Integrating price-based demand response into large-scale energy system analysis. Applied Energy, 364:122960, 2024.
- Hassan K Khalil. Nonlinear systems. Patience Hall, 2002.
- Héctor J Sussmann. On the gap between deterministic and stochastic ordinary differential equations. The Annals of Probability, pages 19–41, 1978.
- Harold Joseph Kushner and Kushner. Stochastic stability and control, volume 33. Academic press New York, 1967.
- Uffe Høgsbro Thygesen et al. A survey of lyapunov techniques for stochastic differential equations. Citeseer, 1997.
- Thomas C. Gard. Introduction to Stochastic Differential Equations. Dekker, 1988.
- EQUA Simulation AB. Ida indoor climate and energy. https://www.equa.se/en/ida-ice [Accessed: (October 2022)].
- Syn.ikia project: D4.2 characterization of the thermodynamic properties of the demonstration cases, 2022.