A decentralized model predictive control scheme for the automatic generation control problem in power systems

With the high degree of wind power penetration integrated into multi-area AC/DC interconnected power grids, the frequency regulation capacity of automatic generation control (AGC) units is not sufficient in the wind power-penetrated area, making it difficult to effectively suppress the frequency stability caused by the fluctuation of wind power. Therefore, a coordinated control strategy for AGC units across areas based on bi-level model predictive control is proposed in this paper to achieve resource sharing. The control scheme uses economic model predictive control to realize steady power optimal allocation of the AGC units across areas in the upper layer and distributed model predictive control to realize dynamic frequency optimization control of the multi-area AGC units in the lower layer. Taking a three-area AC/DC interconnected power grid with a wind farm as an example, the simulation results show that, compared with model predictive control using tie-line frequency bias control (TBC) mode, the proposed control strategy can not only effectively maintain tie-line safety and frequency stability, but can also reduce the regulation cost of multi-area AGC units.

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Decentralized estimation for the automatic generation control problem in power systems

[Proceedings 1992] The First IEEE Conference on Control Applications ◽

10.1109/cca.1992.269776 ◽

2003 ◽

Cited By ~ 2

Author(s):

N. Bekhouche ◽

A. Feliachi

Keyword(s):

Power Systems ◽

Control Problem ◽

Automatic Generation ◽

Automatic Generation Control ◽

Decentralized Estimation ◽

Generation Control

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A FO-PID Controlled Automatic Generation Control of Multi Area Power Systems Tuned by Harmony Search

Recent Advances in Electrical & Electronic Engineering (Formerly Recent Patents on Electrical & Electronic Engineering) ◽

10.2174/2352096511666180719105754 ◽

2020 ◽

Vol 13 (1) ◽

pp. 101-109

Author(s):

Aurobindo Behera ◽

Tapas K. Panigrahi ◽

Arun K. Sahoo

Keyword(s):

Power Systems ◽

Harmony Search ◽

Automatic Generation ◽

System Stability ◽

Automatic Generation Control ◽

Similar System ◽

Thermal Plant ◽

Clear Idea ◽

Generation Control ◽

Fractional Controller

Background: Power system stability demands minimum variation in frequency, so that loadgeneration balance is maintained throughout the operation period. An Automatic Generation Control (AGC) monitors the frequency and varies the generation to maintain the balance. A system with multiple energy sources and use of a fractional controller for efficient control of stability is presented in the paper. At the outset a 2-area thermal system with governor dead band, generation rate constraint and boiler dynamics have been applied. Methods: A variation of load is deliberated for the study of the considered system with Harmony Search (HS) algorithm, applied for providing optimization of controller parameters. Integral Square Time Square Error (ISTSE) is chosen as objective function for handling the process of tuning controller parameters. : A study of similar system with various lately available techniques such as TLBO, hFA-PS and BFOA applied to PID, IDD and PIDD being compared to HS tuned fractional controller is presented under step and dynamic load change. The effort extended to a single area system with reheat thermal plant, hydel plant and a unit of wind plant is tested with the fractional controller scheme. Results: The simulation results provide a clear idea of the superiority of the combination of HS algorithm and FO-PID controller, under dynamically changing load. The variation of load is taken from 1% to 5% of the connected load. Conclusion: Finally, system robustness is shown by modifying essential factors by ± 30%.

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Wind power integration into the automatic generation control of power systems with large-scale wind power

The Journal of Engineering ◽

10.1049/joe.2014.0222 ◽

2014 ◽

Vol 2014 (10) ◽

pp. 538-545 ◽

Cited By ~ 6

Author(s):

Abdul Basit ◽

Anca Daniela Hansen ◽

Mufit Altin ◽

Poul Sørensen ◽

Mette Gamst

Keyword(s):

Power Systems ◽

Wind Power ◽

Large Scale ◽

Automatic Generation ◽

Automatic Generation Control ◽

Wind Power Integration ◽

Generation Control

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Improved model predictive load frequency control of interconnected power system with synchronized automatic generation control loops

Beni-Suef University Journal of Basic and Applied Sciences ◽

10.1186/s43088-020-00072-w ◽

2020 ◽

Vol 9 (1) ◽

Author(s):

Abdullahi Bala Kunya ◽

Mehmet Argin ◽

Yusuf Jibril ◽

Yusuf Abubakar Shaaban

Keyword(s):

Frequency Control ◽

Cross Coupling ◽

Absolute Error ◽

Automatic Generation ◽

Load Frequency Control ◽

Automatic Generation Control ◽

Control Vector ◽

Interconnected Power System ◽

Control Scheme ◽

Generation Control

Abstract Background Automatic generation control (AGC) of multi-area interconnected power system (IPS) is often designed with negligible cross-coupling between the load frequency control (LFC) and automatic voltage regulation (AVR) loops. This is because the AVR loop is considerably faster than that of LFC. However, with the introduction of slow optimal control action on the AVR, positive damping effect can be achieved on the LFC loop thereby improving the frequency control. In this paper, LFC synchronized with AVR in three-area IPS is proposed. Model predictive controller (MPC) configured in a dense distributed pattern, due to its online set-point tacking is used as the supplementary controller. The dynamics of the IPS subjected to multi-area step and random load disturbances are studied. The efficacy of the developed scheme is ascertained by simulating the disturbed system in MATLAB/Simulink. Results Based on the comparative analysis on the system responses, it is established that by cross-coupling the LFC loop with AVR, reductions of 66.45% and 59.09% in the frequency and tie-line power maximum deviations respectively are observed, while the respective settling times are found to be reduced by 29.68% and 22.77% when compared with the uncoordinated control scheme. In addition, the standard deviation and variance of the integral time absolute error of the system’s responses have reduced by 23.21% and 20.83% respectively compared to those obtained in a similar study. Conclusions The reduction in the maximum deviations and settling times in the system states indicates that introducing the voltage control via AVR loop has improved the frequency control significantly. While the lower standard deviation and variance of the integral time absolute error signify improvement in the robustness of the developed algorithm. However, this improvement is at the detriment of the controller size and computational complexity. In the uncoordinated control scheme, the control vector is one-dimensional, while in the coordinated scheme, the control vector is two-dimensional for each CA.

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