Review of Active and Reactive Power Sharing Strategies in Hierarchical Controlled Microgrids

Han, Yi; Li, Hong; Shen, Pan; Coelho, E.A.A.; Guerrero, Josep M.

doi:10.1109/tpel.2016.2569597

Cited by 652 publications

(333 citation statements)

References 159 publications

(318 reference statements)

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“…The decentralized control does not rely on a MGCC and droop mechanism, so the error of a DG unit will not produce the failure of the entire system. Compared with the centralized control, these strategies have higher ability to tolerate the communication errors, and better plug-and-play performance, and can be easily extended to more DG units, which makes the system more scalable [144]. Nevertheless, there are still many problems that have not been effectively solved in the existing literatures.…”

Section: A the Classical Hierarchical Control Strategies Formentioning

confidence: 99%

MAS-Based Distributed Coordinated Control and Optimization in Microgrid and Microgrid Clusters: A Comprehensive Overview

Han

Zhang

et al. 2018

IEEE Trans. Power Electron.

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320

164

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Abstract-The increasing integration of the distributed renewable energy sources highlights the requirement to design various control strategies for microgrids (MGs) and microgrid clusters (MGCs). The multi-agent system (MAS)-based distributed coordinated control strategies shows the benefits to balance the power and energy, stabilize voltage and frequency, achieve economic and coordinated operation among the MGs and MGCs. However, the complex and diverse combinations of distributed generations in multi-agent system increase the complexity of system control and operation. In order to design the optimized configuration and control strategy using MAS, the topology models and mathematic models such as the graph topology model, non-cooperative game model, the genetic algorithm and particle swarm optimization algorithm are summarized. The merits and drawbacks of these control methods are compared. Moreover, since the consensus is a vital problem in the complex dynamical systems, the distributed MAS-based consensus protocols are systematically reviewed. NOMENCLATURE

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Section: A the Classical Hierarchical Control Strategies Formentioning

confidence: 99%

MAS-Based Distributed Coordinated Control and Optimization in Microgrid and Microgrid Clusters: A Comprehensive Overview

Han

Zhang

et al. 2018

IEEE Trans. Power Electron.

Self Cite

320

164

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“…The active load input current (i lALDQ ) is converted from the common reference frame "DQ" to the active load reference frame dq AL using PLL. (20) where δ i is the angle between the dq active load frame and common reference frame DQ.…”

Section: Active Load Modelmentioning

confidence: 99%

“…The details and characters of various control schemes were illustrated in [5]. Another updated revision for the power-sharing schemes was presented in [20]. It was stated that load demand and the controller power-sharing coefficients dominantly distress the low frequency modes; while filter parameters, load dynamics, and the controller parameters of the inner voltage and outer current controllers distress the medium and high frequency damped modes [5].…”

Section: Introductionmentioning

confidence: 99%

Optimal Design and Real Time Implementation of Autonomous Microgrid Including Active Load

2018

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Abstract:Controller gains and power-sharing parameters are the main parameters affect the dynamic performance of the microgrid. Considering an active load to the autonomous microgrid, the stability problem will be more involved. In this paper, the active load effect on microgrid dynamic stability is explored. An autonomous microgrid including three inverter-based distributed generations (DGs) with an active load is modeled and the associated controllers are designed. Controller gains of the inverters and active load as well as Phase Locked Loop (PLL) parameters are optimally tuned to guarantee overall system stability. A weighted objective function is proposed to minimize the error in both measured active power and DC voltage based on time-domain simulations. Different AC and DC disturbances are applied to verify and assess the effectiveness of the proposed control strategy. The results demonstrate the potential of the proposed controller to enhance the microgrid stability and to provide efficient damping characteristics. Additionally, the proposed controller is compared with the literature to demonstrate its superiority. Finally, the microgrid considered has been established and implemented on real time digital simulator (RTDS). The experimental results validate the simulation results and approve the effectiveness of the proposed controllers to enrich the stability of the considered microgrid.

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“…Hybrid control, a more practical scheme, combines centralized and distributed control, as shown in Figure 3 [80,81]. Distributed energy sources are grouped within an MG; a centralized control is used within each group, while distributed control is applied to a set of groups.…”

Section: Hybrid Centralized and Distributed Control Schemementioning

confidence: 99%

A Survey on Smart Agent-Based Microgrids for Resilient/Self-Healing Grids

2017

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This paper presents an overview of our body of work on the application of smart control techniques for the control and management of microgrids (MGs). The main focus here is on the application of distributed multi-agent system (MAS) theory in multi-objective (MO) power management of MGs to find the Pareto-front of the MO power management problem. In addition, the paper presents the application of Nash bargaining solution (NBS) and the MAS theory to directly obtain the NBS on the Pareto-front. The paper also discusses the progress reported on the above issues from the literature. We also present a MG-based power system architecture for enhancing the resilience and self-healing of the system.

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Review of Active and Reactive Power Sharing Strategies in Hierarchical Controlled Microgrids

Cited by 652 publications

References 159 publications

MAS-Based Distributed Coordinated Control and Optimization in Microgrid and Microgrid Clusters: A Comprehensive Overview

MAS-Based Distributed Coordinated Control and Optimization in Microgrid and Microgrid Clusters: A Comprehensive Overview

Optimal Design and Real Time Implementation of Autonomous Microgrid Including Active Load

A Survey on Smart Agent-Based Microgrids for Resilient/Self-Healing Grids

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