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Castellanos Contreras, J.U.; Rodríguez Urrego, L. Smart Grid Control Systems. Encyclopedia. Available online: https://encyclopedia.pub/entry/43799 (accessed on 04 September 2024).
Castellanos Contreras JU, Rodríguez Urrego L. Smart Grid Control Systems. Encyclopedia. Available at: https://encyclopedia.pub/entry/43799. Accessed September 04, 2024.
Castellanos Contreras, Jose Ulises, Leonardo Rodríguez Urrego. "Smart Grid Control Systems" Encyclopedia, https://encyclopedia.pub/entry/43799 (accessed September 04, 2024).
Castellanos Contreras, J.U., & Rodríguez Urrego, L. (2023, May 04). Smart Grid Control Systems. In Encyclopedia. https://encyclopedia.pub/entry/43799
Castellanos Contreras, Jose Ulises and Leonardo Rodríguez Urrego. "Smart Grid Control Systems." Encyclopedia. Web. 04 May, 2023.
Smart Grid Control Systems
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This entry is adapted from the peer-reviewed paper 10.3390/en16083541

The development of control techniques in smart grids has its origins mainly in the need to mitigate network failures and changes in power quality. The foregoing is due to economic concerns and the environmental impacts of energy issues in terms of sustainable development. Smart Grids have also contributed to the development and integration of renewable energies into the distributed system since this type of generation source presents intermittent output. These intermittency characteristics of renewable sources and the stochastic behavior of demand make these networks complex systems with types of non-linear control that must be robustly modeled, analyzed, tested, and implemented when considering their operation, safety, reliability, and maintenance.

smart grids renewable energy control systems

1. Rule-Based Control (RBC)

Also known as autonomous control, based on static command control strategies RBCs are not capable of making any adaptive decisions, and, in most uses, algorithms are based on fuzzy logic. Their implementation is simple and flexible compared to other control strategies [1]. To improve decision-making in an adaptive way and in a stable state, a metaheuristic or homeostatic algorithm is implemented [2][3]. Figure 1 shows an example of the programmable temperature control systems (PTC) in North America, where their automatic adjustment is based on rules associated with high demand, intervening in the adjustments of these meters based on times when users do not make changes [4].
Figure 1. Rules-based control systems and wireless sensors [4].

2. Optimal Control (RBC)

The objective of this type of control is to solve an optimization problem and implement its result. Optimization problems are generally solved in the context of a complex systems control scheme, such as model-based predictive control (MPC) [5]. The principle of control is to optimize (minimize or maximize) one or more target variables, varying their decision values while satisfying a set of constraints. In the case of the Smart Grid in Figure 2, the conventional approach is to minimize the cost of the operation, which includes different components (fuel, storage, maintenance, policies, cycles, demand, and supply, among others) [6]. An application of this control has been developed at the Tamil Nadu Institute of Technology and Sciences, India, where a predictive control model called the trust was implemented in the wireless sensor nodes to observe them as energy supply and demand nodes and thus obtain more adequate metrics. The proposed trust model validates compensation failures and data loss failures in smart meters [7].
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Figure 2. MPC controller in a micro-network [3].

3. Agent-Based Modeling (ABM) Control

Agent-based modeling control systems are intelligent systems consisting of a collection of agents that interact with each other in such a way that the entire system learns and evolves. The term “agent” refers to a computer system capable of performing autonomous actions, which can be divided into different agents, including: controller, central coordination, load, network entry and exit, planner, management, market, regulation, and others [8][9]. These agents communicate with each other to perform coordinated actions, perform complex calculations, and make decisions. These models are more focused on energy management.
They can be used in situations where a fully formulated optimization problem would be impractically complex or where a model of the complete system cannot be known. They are tolerant of errors due to their decentralized control scheme [10][11].
Research carried out at Beihang University in Beijing, China, presents agent-based control as a solution to failures when they are associated with the dynamic load balancing of the smart grid. The agent-based algorithm optimizes groups of nodes called herds based on load compensation using communication architectures [12]. A similar system for distribution network restoration in future smart grids can be seen in [13], where the self-repair capacity of future networks will be a must.

4. Model-Based Predictive Control (MPC)

Model-based predictive control is a control strategy based entirely on the dynamic model of the system. In general, it is a linear model that takes as input the current state of the system and external disturbances and generates a future state [14]. The resulting state is optimized in a prediction horizon of N + 1, and the now-current state (N + 1) with the current and predicted disturbances is introduced into the model, as in Figure 3. The MPC has the advantage of having an account of the future state of the system and future disturbances when making control decisions for the current next step; thus, one can anticipate future events and act on that prior knowledge in the present. An advantage of the predictive control of the model is that it is only as good as the model that is placed in it [15][16].
This type of model is being applied in commercial buildings in Hong Kong for the management of the demand for air conditioners and its relationship with the supply of energy through the Smart Grid. The main objective is to maximize the power reduction based on a predictive profile of the electrical networks as well as maintain the air temperature inside the building. The MPC controller determines the demand control outputs based on the building’s thermal response model [17].
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Figure 3. Model of a predictive control [18].

5. Control Based on Discrete Event Models (CMEDS)

This type of control is based on asynchronous dynamic systems, which evolve according to the occurrence of events [19]. Its behavior can be described as sequences of events forming a language and thus establishing a process that can be coupled to a supervisor, and this can force the processes to be recurrent. It is present where the Petri nets are perfectly coupled by the supervised control manager, as seen in Figure 4. This type of control was applied in Detroit in the United States by the Department of Electrical and Computer Engineering at Wayne University. Its objective was to avoid overload tripping of circuit breakers through the distribution or output of the overload in the network with the maximum possible power transfer [20].
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Figure 4. Supervised control. (a) The extended process. (b) The supervisor’s scheme. (c) The supervised control scheme [21].
Supervised systems are managed via Petri nets since they establish programmable logic rules and define events restricted by actions. These Petri nets have penetrated control systems for failure analysis, financial systems, energy, storage systems, automation systems, and telecommunications through their different forms, such as timed, hybrid, and stochastic Petri nets, combined with other control methods or colored [22][23].
These models can be combined by different techniques, which can be from the same PN family but from different sources, such as Bayesian Petri nets and stochastic Petri nets. In this case, one of them can act as the supervisory PN, which controls the events, and the other PN can generate the model through an algorithm for process control. In addition, a combination of hybrid models can be presented. These can be PNs with a discrete or continuous control model. An applied example of the combination of PN techniques is the modeling of urban traffic systems in the city of Turin, Italy, which uses real-time control strategies. The hybrid model uses timed colored Petri nets (TCPNs; Figure 4, section (b) of reference [24]) as a system control of entrances and exits in the intersections; these TCPNs establish the possible stopping times, numbers of vehicles, and flow directions, while the vehicular flow on the road has been modeled through a stochastic discrete-time model (Figure 4). Hybrid model validation has shown that relevant traffic dynamics have been considered, but the real-time computational cost is of low latency and time-saving, making it suitable for real-case applications. The above, due to the simulation, can be performed in parallel for the hybrid model [24].

References

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  2. Parejo, A.; Sanchez-Squella, A.; Barraza, R.; Yanine, F.; Barrueto-Guzman, A.; Leon, C. Design and Simulation of an Energy Homeostaticity System for Electric and Thermal Power Management in a Building with Smart Microgrid. Energies 2019, 12, 1806.
  3. Yanine, F.; Sanchez-Squella, A.; Barrueto, A.; Cordova, F.; Sahoo, S.K. Engineering Sustainable Energy Systems: How Reactive and Predictive Homeostatic Control Can Prepare Electric Power Systems for Environmental Challenges. Procedia Comput. Sci. 2017, 122, 439–446.
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  7. Gilbert, E.P.K.; Lydia, M.; Baskaran, K.; Rajsingh, E.B. Trust aware fault tolerant prediction model for wireless sensor network-based measurements in Smart Grid environment. Sustain. Comput. Inform. Syst. 2019, 23, 29–37.
  8. Khan, M.W.; Wang, J. The research on multi-agent system for microgrid control and optimization. Renew. Sustain. Energy Rev. 2017, 80, 1399–1411.
  9. Coelho, P.; Silva, L.; Faria, I.; Vieria, M.; Monteiro, A.; Pinto, G.; Prudêncio, C.; Fernandes, R.; Soares, R. Adipocyte Secretome Increases Radioresistance of Malignant Melanocytes by Improving Cell Survival and Decreasing Oxidative Status. Radiat Res 2017, 187, 581–588.
  10. Basir Khan, M.R.; Jidin, R.; Pasupuleti, J. Multi-agent based distributed control architecture for microgrid energy management and optimization. Energy Convers. Manag. 2016, 112, 288–307.
  11. Kulasekera, A.L.; Gopura, R.A.R.C.; Hemapala, K.T.M.U.; Perera, N. A review on multi-agent systems in microgrid applications. In Proceedings of the 2011 IEEE PES International Conference on Innovative Smart Grid Technologies, Kollam, India, 1–3 December 2011; pp. 173–177.
  12. Ren, Y.; Fan, D.; Feng, Q.; Wang, Z.; Sun, B.; Yang, D. Agent-based restoration approach for reliability with load balancing on smart grids. Appl. Energy 2019, 249, 46–57.
  13. Al-Hinai, A.; Haes Alhelou, H. A multi-agent system for distribution network restoration in future smart grids. Energy Rep. 2021, 7, 8083–8090.
  14. Parisio, A.; Rikos, E.; Glielmo, L. A Model Predictive Control Approach to Microgrid Operation Optimization. IEEE Trans. Control Syst. Technol. 2014, 22, 1813–1827.
  15. Gong, C.; Wang, X.; Xu, W.; Tajer, A. Distributed real-time energy scheduling in smart grid: Stochastic model and fast optimization. IEEE Trans. Smart Grid 2013, 4, 1476–1489.
  16. Parisio, A.; Rikos, E.; Tzamalis, G.; Glielmo, L. Use of model predictive control for experimental microgrid optimization. Appl. Energy 2014, 115, 37–46.
  17. Tang, R.; Wang, S.; Xu, L. An MPC-based optimal control strategy of active thermal storage in commercial buildings during fast demand response events in smart grids. Energy Procedia 2019, 158, 2506–2511.
  18. Serna, Á.; Tadeo Rico, F.J.; Normey-Rico, J.E. Advanced control based on predictive control ideas for hydrogen production by electrolysis. In Proceedings of the Actas de las XXXVIII Jornadas de Automática, Gijón, Spain, 6–8 September 2017; pp. 167–173.
  19. Li, X.; Yu, W.; Perez, S. Adaptive fuzzy petri nets for supervisory hybrid systems modeling. IFAC Proc. Vol. 2002, 35, 277–282.
  20. Zhao, J.; Chen, Y.L.; Chen, Z.; Lin, F.; Wang, C.; Zhang, H. Modeling and control of discrete event systems using finite state machines with variables and their applications in power grids. Syst. Control Lett. 2012, 61, 212–222.
  21. Pérez Moo, S.A. Modeling and Control of Hybrid Systems with Fuzzy Petri Nets and Neural Networks; Instituto Politécnico Nacional: Mexico City, Mexico, 2002.
  22. Luo, J.; Liu, Z.; Zhou, M.; Xing, K.; Wang, X.; Li, X.; Liu, H. Robust deadlock control of automated manufacturing systems with multiple unreliable resources. Inf. Sci. 2019, 479, 401–415.
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  24. Basile, F.; Chiacchio, P.; Teta, D. A hybrid model for real time simulation of urban traffic. Control Eng. Pract. 2012, 20, 123–137.
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Subjects: Engineering, Electrical & Electronic
Contributors MDPI registered users' name will be linked to their SciProfiles pages. To register with us, please refer to https://encyclopedia.pub/register :
Jose Ulises Castellanos Contreras
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Leonardo Rodríguez Urrego
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Update Date: 09 May 2023
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