Multivariable predictive control considering time delay for load-frequency control in multi-area power systems

Daniar, Sabah; Shiroei, M.; Aazami, Rahmat

doi:10.1515/acsc-2016-0029

Cited by 6 publications

(4 citation statements)

References 14 publications

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“…Similar works on the topic of MPC for LFC of power system can be found in References 29‐31. In terms of communication delay, Reference 32 reconstructed the cost function of predictive controller to compensate the communication delay of LFC system, and the proposed control scheme can achieve smoother state response. In Reference 33, a coordination model predictive controller was designed based on LFC equivalent model of communication delay, and compared with PI controller, this controller has better control performance under various disturbances.…”

Section: Introductionmentioning

confidence: 86%

Load frequency predictive control for power systems concerning wind turbine and communication delay

Tang

Liu

et al. 2022

Optim Control Appl Methods

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This article addresses a model predictive control (MPC) technique for load frequency control (LFC) system in the presence of wind power, communication delay, and denial‐of‐service (DoS) attack. In this article, communication delay is incorporated into a single area control error transmission for simplicity, wind power and load disturbance are regarded as Lipschitz nonlinear terms, as for the randomly occurring DoS attack, it is modeled as Bernoulli processes with known conditional probability. Thinking all these adverse factors to stability and the limitation of input constraint synthetically, the stability of LFC system can be guaranteed by delay‐dependent Lyapunov function lemma and a state feedback MPC controller is designed to solve the LFC problems by minimizing the infinite‐horizon objective function. Although some scholars have studied the performance degradation and instability of LFC system caused by cyber attack and/or communication delay and some very nice results have been addressed, limited works have considered the MPC approach to deal with both the problems of cyber attack and communication delay which explicitly considers the physical constraints. In addition, the delay‐dependent Lyapunov function is adopted to deal with the problem of communication delay, which results in less conservatism of the presented method. Finally, the optimization problem with input constraint is solved and proven to be recursive feasibility, and the closed‐loop system turns out to be stable. The reasonability and validity of the provided strategy is verified through several groups of simulation experiments. It illustrates that the proposed control method can keep the system frequency steady in the standard range in spite of various attack conditions.

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Section: Introductionmentioning

confidence: 86%

Load frequency predictive control for power systems concerning wind turbine and communication delay

Tang

Liu

et al. 2022

Optim Control Appl Methods

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“…This time latency can be regarded on the area control error (ACE) signal. Furthermore, the time delay can be introduced during transmission of the LFC centre output to the individual GENCOs [8,13,[16][17][18]. The delaydependent stability analysis of the power system with a LFC scheme for constant, time-varying, and random time delays are is investigated in [8,11,12,14].…”

Section: Realistic Load Frequency Control (Lfc) In Competitive Enviromentioning

confidence: 99%

“…System damping responses obtained due to different time delays imposed to the power system in scenario 1 are gathered in Table 5. For the purpose of this research as a comprehensive study, the communication delays are considered on the both control input and control output of the LFC system, concurrently [16][17][18]. An exponential function e -τs is used to describe the communication delay where τ gives the communication delay time [17].…”

Section: Evaluation Of the Effect Of Communication Time Delaymentioning

confidence: 99%

Modified group search optimisation‐based comparative performance evaluation of thyristor controlled series capacitor‐based fractional order damping controllers to improve load frequency control performance in restructured environment

Morsali

Zare

Hagh

2017

IET Generation, Transmission & Distribution

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“…Load frequency control is of great importance in electric power system operation to damp frequency and voltage oscillations originating from load variations or sudden changes in load demands (B.Prakash Ayyappan and R.Kanimozhi 2021). In an interconnected power system that consists of several control areas, as if the system parameter varies then the grid tie-line power will change and the frequency deviations will occur (Sabah Daniar, Mojtaba Shiroei and Tahmat Aazami 2016). In a power system with huge interconnections, transient conflicts promote disturbances inside the system (S.Selvakumaran, V.Rajasekaran and R. Karthigaivel 2014).…”

Section: Introductionmentioning

confidence: 99%

Load frequency control of three area power system using optimal tuning of fractional order proportional integral derivative controller with multi objective grey wolf optimization

Ayyappan

R.²

2022

JER is an international, peer-reviewed journal that publishes f

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In an interconnected electrical power system, load frequency control is a most important ancillary service essential for maintaining the electrical system reliability at an adequate level. A Multi-Objective Grey Wolf Optimization (MOGWO) algorithm is introduced for maintaining a balance among exploitation and exploration stages and provides the best value of fitness. During the occurrence of the disturbance in the output of the system the optimization is implemented with Firefly Algorithm (FFA) and MOGWO which is tuned carefully and also the parameters are compared with three-area three-source model of the power system. A Fractional Order Proportional and Derivative (FOPID) controller is a PID controller whose derivative and integral orders are fractional rather than integer. The FOPID controller supports the better stability of the designed model with controlled deviation in frequency and grid tie line power deviations. In this proposed research work, optimal tuning of parameters of various controllers like PI, PID and FOPID in the power system is to regulate frequency in a multi-area multi-source model which is designed with the hydro-thermal-gas generation units. The output performance of the model designed is estimated from simulation results by means of MATLAB-SIMULINK tool. The dynamic performances of the system are studied with 1% or 2% step load perturbation in one Area. Sensitivity analysis reveals that the FFA and MOGWO optimized FOPID controller parameters obtained at nominal condition of loading, size and position of disturbance and system parameters are robust and need not be reset with wide changes in system.The simulation results show the effectiveness of FOPID controller in the presence and the absence of the FF and MOGWO algorithms considered and in that MOGWO algorithm is executed appropriately and it has improved the performance based on metrics such as overshoot, undershoot, and settling time.

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Multivariable predictive control considering time delay for load-frequency control in multi-area power systems

Cited by 6 publications

References 14 publications

Load frequency predictive control for power systems concerning wind turbine and communication delay

Load frequency predictive control for power systems concerning wind turbine and communication delay

Modified group search optimisation‐based comparative performance evaluation of thyristor controlled series capacitor‐based fractional order damping controllers to improve load frequency control performance in restructured environment

Load frequency control of three area power system using optimal tuning of fractional order proportional integral derivative controller with multi objective grey wolf optimization

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