Smart Energy Hub Frequency Control-Based Machine Learning

Burak  Yildirim; Meysam Gheisarnejad Chirani; Mohammad Hassan Khooban

doi:10.1109/TETCI.2025.3551991

Smart Energy Hub Frequency Control-Based Machine Learning

Burak Yildirim
, Meysam Gheisarnejad Chirani
, Mohammad Hassan Khooban

Institut for Elektro- og Computerteknologi - Electrical Energy Technology

Publikation: Bidrag til tidsskrift/Konferencebidrag i tidsskrift /Bidrag til avis › Tidsskriftartikel › Forskning › peer review

Abstract

The increasing variety of energy conversion units and storage equipment connected to the multi-energy system, along with the uncertain factors posed by distributed wind and photovoltaic power generation, have made the energy flow structure of the system more complex. This complexity has created significant challenges for the frequency regulation of traditional energy hub systems. One of the characteristics of a microgrid (MG) is the use of combined heat and power (CHP) systems to generate both electrical and thermal energy at the same time. This can boost the system's dependability, efficiency, and economic performance. As a CHP's ramping capability makes it a useful tool for monitoring and controlling the MG's frequency, it will be employed in this research to achieve this goal. The complexity of the system's dynamics and set tasks throughout the course of the performance period necessitates advanced control structures for the MG with CHP systems. To address the challenges of controlling in MG with CHP systems, this research introduces a novel control structure based on deep reinforcement learning and single input interval type-2 fuzzy fractional-order proportional integral (SIT2-FFOPI) for this system. The SIT2-FFOPI serves as the main controller, with its fundamental parameters established through the utilization of the Improved Salp Swarm Algorithm (ISSA) optimization technique. An adaptive deep deterministic policy gradient (DDPG)-based actor-critic system has been developed to enhance the main controller's learning potential, thereby enabling it to more effectively address control challenges in the isolated MG. The efficacy of the suggested approach in real-time was evaluated through simulations carried out utilizing an OPAL-RT-based Hardware-in-the-Loop (HiL) configuration. As a result of this study, it was determined that the proposed controller for load disturbance, renewable energy sources (RES) power changes, and contingency circumstances in MG outperforms other controllers in terms of performance.

Originalsprog	Engelsk
Tidsskrift	IEEE Transactions on Emerging Topics in Computational Intelligence
Vol/bind	9
Nummer	5
Sider (fra-til)	3638-3649
Antal sider	12
ISSN	2471-285X
DOI	https://doi.org/10.1109/TETCI.2025.3551991
Status	Udgivet - 2025

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10.1109/TETCI.2025.3551991

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abstract = "The increasing variety of energy conversion units and storage equipment connected to the multi-energy system, along with the uncertain factors posed by distributed wind and photovoltaic power generation, have made the energy flow structure of the system more complex. This complexity has created significant challenges for the frequency regulation of traditional energy hub systems. One of the characteristics of a microgrid (MG) is the use of combined heat and power (CHP) systems to generate both electrical and thermal energy at the same time. This can boost the system's dependability, efficiency, and economic performance. As a CHP's ramping capability makes it a useful tool for monitoring and controlling the MG's frequency, it will be employed in this research to achieve this goal. The complexity of the system's dynamics and set tasks throughout the course of the performance period necessitates advanced control structures for the MG with CHP systems. To address the challenges of controlling in MG with CHP systems, this research introduces a novel control structure based on deep reinforcement learning and single input interval type-2 fuzzy fractional-order proportional integral (SIT2-FFOPI) for this system. The SIT2-FFOPI serves as the main controller, with its fundamental parameters established through the utilization of the Improved Salp Swarm Algorithm (ISSA) optimization technique. An adaptive deep deterministic policy gradient (DDPG)-based actor-critic system has been developed to enhance the main controller's learning potential, thereby enabling it to more effectively address control challenges in the isolated MG. The efficacy of the suggested approach in real-time was evaluated through simulations carried out utilizing an OPAL-RT-based Hardware-in-the-Loop (HiL) configuration. As a result of this study, it was determined that the proposed controller for load disturbance, renewable energy sources (RES) power changes, and contingency circumstances in MG outperforms other controllers in terms of performance.",

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doi = "10.1109/TETCI.2025.3551991",

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Smart Energy Hub Frequency Control-Based Machine Learning. / Yildirim, Burak ; Gheisarnejad Chirani, Meysam; Khooban, Mohammad Hassan.
I: IEEE Transactions on Emerging Topics in Computational Intelligence, Bind 9, Nr. 5, 2025, s. 3638-3649.

Publikation: Bidrag til tidsskrift/Konferencebidrag i tidsskrift /Bidrag til avis › Tidsskriftartikel › Forskning › peer review

TY - JOUR

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AU - Gheisarnejad Chirani, Meysam

AU - Khooban, Mohammad Hassan

PY - 2025

Y1 - 2025

N2 - The increasing variety of energy conversion units and storage equipment connected to the multi-energy system, along with the uncertain factors posed by distributed wind and photovoltaic power generation, have made the energy flow structure of the system more complex. This complexity has created significant challenges for the frequency regulation of traditional energy hub systems. One of the characteristics of a microgrid (MG) is the use of combined heat and power (CHP) systems to generate both electrical and thermal energy at the same time. This can boost the system's dependability, efficiency, and economic performance. As a CHP's ramping capability makes it a useful tool for monitoring and controlling the MG's frequency, it will be employed in this research to achieve this goal. The complexity of the system's dynamics and set tasks throughout the course of the performance period necessitates advanced control structures for the MG with CHP systems. To address the challenges of controlling in MG with CHP systems, this research introduces a novel control structure based on deep reinforcement learning and single input interval type-2 fuzzy fractional-order proportional integral (SIT2-FFOPI) for this system. The SIT2-FFOPI serves as the main controller, with its fundamental parameters established through the utilization of the Improved Salp Swarm Algorithm (ISSA) optimization technique. An adaptive deep deterministic policy gradient (DDPG)-based actor-critic system has been developed to enhance the main controller's learning potential, thereby enabling it to more effectively address control challenges in the isolated MG. The efficacy of the suggested approach in real-time was evaluated through simulations carried out utilizing an OPAL-RT-based Hardware-in-the-Loop (HiL) configuration. As a result of this study, it was determined that the proposed controller for load disturbance, renewable energy sources (RES) power changes, and contingency circumstances in MG outperforms other controllers in terms of performance.

AB - The increasing variety of energy conversion units and storage equipment connected to the multi-energy system, along with the uncertain factors posed by distributed wind and photovoltaic power generation, have made the energy flow structure of the system more complex. This complexity has created significant challenges for the frequency regulation of traditional energy hub systems. One of the characteristics of a microgrid (MG) is the use of combined heat and power (CHP) systems to generate both electrical and thermal energy at the same time. This can boost the system's dependability, efficiency, and economic performance. As a CHP's ramping capability makes it a useful tool for monitoring and controlling the MG's frequency, it will be employed in this research to achieve this goal. The complexity of the system's dynamics and set tasks throughout the course of the performance period necessitates advanced control structures for the MG with CHP systems. To address the challenges of controlling in MG with CHP systems, this research introduces a novel control structure based on deep reinforcement learning and single input interval type-2 fuzzy fractional-order proportional integral (SIT2-FFOPI) for this system. The SIT2-FFOPI serves as the main controller, with its fundamental parameters established through the utilization of the Improved Salp Swarm Algorithm (ISSA) optimization technique. An adaptive deep deterministic policy gradient (DDPG)-based actor-critic system has been developed to enhance the main controller's learning potential, thereby enabling it to more effectively address control challenges in the isolated MG. The efficacy of the suggested approach in real-time was evaluated through simulations carried out utilizing an OPAL-RT-based Hardware-in-the-Loop (HiL) configuration. As a result of this study, it was determined that the proposed controller for load disturbance, renewable energy sources (RES) power changes, and contingency circumstances in MG outperforms other controllers in terms of performance.

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KW - DDPG

KW - SIT2-FFOPI

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DO - 10.1109/TETCI.2025.3551991

M3 - Journal article

SN - 2471-285X

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EP - 3649

JO - IEEE Transactions on Emerging Topics in Computational Intelligence

JF - IEEE Transactions on Emerging Topics in Computational Intelligence

IS - 5

ER -

Smart Energy Hub Frequency Control-Based Machine Learning

Abstract

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