An Efficient Design of Adaptive Model Predictive Controller for Load Frequency Control in Hybrid Power System

Gulzar, Muhammad Majid; Sibtain, Daud; Arslan, Ahmad; Javed, Imran; Murawwat, Sadia; Rasool, Imran; Hayat, Aamir

doi:10.1155/2022/7894264

Cited by 20 publications

(12 citation statements)

References 39 publications

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“…The wind farm includes number of wind turbines where the total capacity of the wind farm is 33 MW. The modelling of the wind farm sys-tem representing pitch control, pitch actuator, and induction generator transfer functions is mentioned in [40] under unbalanced loading [36]. The modelling of the thermal system units is formulated as follows: the power generating capacity of the thermal power plant is 4000 MW operational at 2200 MW at 50 Hz.…”

Section: Wind System Schemingmentioning

confidence: 99%

“…Likewise, variable structure gain scheduling model predictive controller (GSMPC-PI) was introduced to cope up the LFC problem under renewable-based power system in [35]. The adaptive design for MPC was also proposed in [36], for multiarea power system. Similarly, AMPC controller was formulated to counter frequency oscillations that are perturbed due to load disturbance in a hybrid power system [37].…”

Section: Introductionmentioning

confidence: 99%

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Cascaded Fractional Model Predictive Controller for Load Frequency Control in Multiarea Hybrid Renewable Energy System with Uncertainties

Gulzar

Sibtain

Khalid

2023

International Journal of Energy Research

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The rapid utilization of electricity has forced the stability of the power system for continuous operation. Due to difference in demand and generation, the frequency reference point changes that needs to be restored to its locus point for the stable operation of the power system. Therefore, a novel efficient control design is propounded to counter the phenomena of load frequency control. The designing of cascaded fractional model predictive controller coupled with fractional-order PID controller (CFMPC-FOPID) is designed for an efficient response of the power system under load disruption and system parameter variations. The controller is optimized by sooty tern optimization algorithm to identify the optimal parameters of the controller. The controller is tested under power mixing of renewable energy sources (i.e., PV and wind) and under varying load scenarios in multiarea hybrid power system. The proposed controller has effectively handled the frequency disruption under distinct load change by stabilizing it in 1.34 sec, 0.60 sec, and 0.41 sec for area-1 with an average time of 0.78 sec, and for area-2, the stabilizing time is 1.40 sec, 0.89 sec, and 0.56 sec with an average time of 0.95 sec, whereas the average time for MPC/PI, DSA-FOPID, GWO: PI-PD, and SCA: FOPI-FOPID is 7.67 sec, 4.68 sec, 1.77 sec, and 4.72 sec, respectively, for area-1 and 6.47 sec, 5.13 sec, 3.45 sec, and 5.02 sec, respectively, for area-2. The outcome result justifies the superiority of the studied technique.

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Section: Wind System Schemingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Cascaded Fractional Model Predictive Controller for Load Frequency Control in Multiarea Hybrid Renewable Energy System with Uncertainties

Gulzar

Sibtain

Khalid

2023

International Journal of Energy Research

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“…A cascaded fractional MPC controller design has been proposed to counter the frequency oscillations under rapid changes in load [31]. The efficient design of an adaptive MPC has been designed to mitigate frequency fluctuations [32]. Examining the literature overview, this paper presents the following originalities:…”

Section: Literature Reviewmentioning

confidence: 99%

Frequency stabilization for interconnected renewable based power system using cascaded model predictive controller with fractional order PID controller

Sibtain,

Rafiq,

Bhatti

et al. 2023

IET Renewable Power Gen

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In today's electrical grid, frequency cannot be ignored. The proliferation of renewable energy sources into a power system degrades its frequency; hence, the need for frequency regulation has been increased as a result. The second major factor is the perturbation in the load that originates the frequency fluctuation which needs to be suppressed in minimum time to avoid any system collapse. The designing of an optimal controller is indispensable because of increasing power system complexity. In order to maintain the stability of the power system, this paper presents the cascaded design of the model predictive controller with fractional order PID controller (MPC‐FOPIDN) to mitigate the frequency oscillations due to disruption in load. The combination of the predictive capabilities of model predictive control (MPC) and fractional order control enhances control abilities, making it an optimal control strategy for load frequency control (LFC). The grasshopper optimization algorithm (GOA) is applied to obtain optimal gains values for the FOPID controller. The efficacy of the controller has effectively mitigated frequency fluctuations caused by a change in demand or any uncertainty in the power system.

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“…However, because of their cost or capacity [10], many of these devices are not appropriate for wind-solar generation [11,12]. Some of the issues connected with deploying ESS in wind and solar energy systems include ramp rates [13], transmission losses, and limiting the power output of wind-solar farms [4]. The Battery Energy Storage System [11,12] is the energy storage system that works best with wind-solar power generation as it has many advantages, particularly its ease of implementation and modest needed installation space, the BESS is currently the most frequently utilized ESS to alleviate power fluctuation [14].…”

Section: Introductionmentioning

confidence: 99%

An Intelligent Model Predictive Control Strategy for Stable Solar-Wind Renewable Power Dispatch Coupled with Hydrogen Electrolyzer and Battery Energy Storage

Syed

Khalid

2023

International Journal of Energy Research

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Renewable energy sources such as photovoltaic (PV) and wind power are widely used; however, their intermittent nature impairs power supply quality by creating frequency distortions and irregularities in voltage. Battery energy storage systems (BESS) are utilized to flatten out and relieve fluctuation issues. To prevent the need for larger storage systems and to prolong their operational life through controlled charging and discharging, a method of control for BESS charging level regulation is necessary. This study presents a solar-wind power and battery state of charge (SoC) control technique using a hydrogen electrolyzer (HE) fuel cell unit. An Intelligent Model Predictive Controller (IMPC) has been developed that utilizes a neural network (NN) plant model for predictive minimization instead of using a mathematical plant model for dynamic management of the HE output, which allows for flattened PV-wind power supply with regulated BESS charging and discharging. The IMPC accepts as inputs the intermittent renewable power and different battery attributes and intelligently manages the HE production while staying within the imposed restrictions. The NN, as opposed to a mathematical plant model, captures the dynamics of the plant with exceptionally high accuracy. Moreover, the NN plant model performance increases as the data gathered from the actual system increases. The neural network model resolves concerns with the MPC model’s mathematical intricacy that occurs as the plant becomes more complicated. According to simulation results, the IMPC greatly reduces PV-wind power fluctuations, for solar power, the IMPC reduces the peak battery SoC by 26.7% and compared to FLC, the peak SoC is reduced by 11.2%. Similarly, for wind power, the peak SoC is reduced by 7.3% and is decreased 3.2% more than the FLC. To demonstrate the power smoothing effectiveness of the IMPC, the peak solar power ramp rate is reduced by 30.3% and the peak wind power ramp rate is reduced by 91.3%. The presented method encourages green hydrogen usage in the electrical sector for supplying firmed solar and wind power.

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An Efficient Design of Adaptive Model Predictive Controller for Load Frequency Control in Hybrid Power System

Cited by 20 publications

References 39 publications

Cascaded Fractional Model Predictive Controller for Load Frequency Control in Multiarea Hybrid Renewable Energy System with Uncertainties

Cascaded Fractional Model Predictive Controller for Load Frequency Control in Multiarea Hybrid Renewable Energy System with Uncertainties

Frequency stabilization for interconnected renewable based power system using cascaded model predictive controller with fractional order PID controller

An Intelligent Model Predictive Control Strategy for Stable Solar-Wind Renewable Power Dispatch Coupled with Hydrogen Electrolyzer and Battery Energy Storage

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