Sage Journals: Discover world-class research

Abstract

The convergence speed, Chattering Phenomenon (CP), and tracking accuracy are among the most important challenges of the Sliding Mode Control (SMC) family controllers for Voltage Regulation (VR) in integrated Photovoltaic Systems (PVSs) and Voltage Control Systems (VCS). For this purpose, this paper presents a new and hybrid control method of the sliding family called Fast Integral Terminal Sliding Mode Control (FITSMC) based on the super twisting reaching law that can overcome these challenges. Also, an estimator for this family is designed to estimate the Equivalent Photovoltaic Resistance (EPR) and update the system model. As such, the control exactness is increased. A new terminal integral sliding surface, which increases convergence speed and accuracy, is featured by the controller described in this paper. Essentially, this sliding surface has dynamics that consist of an integral component that increases accuracy in convergence and a derivative component that increases speed in convergence. In addition, the controller has a new Super-Twisting Reaching Law (STRL) that increases convergence speed and decreases Chattering (Ch). A number of practical experiments were performed in a laboratory setting to demonstrate the performance of the new methodology. The experimental results demonstrate the capabilities of the new methodology to reduce Ch, Convergence Time (CT), and Tracking Error (TE).

Keywords

Photovoltaic system voltage control system fast integral terminal sliding mode equivalent photovoltaic resistance chattering phenomenon convergence time

Get full access to this article

View all access options for this article.

References

Trujillo

Velasco

Figueres

, et al. Modeling and control of a push–pull converter for photovoltaic microinverters operating in island mode. Appl Energy 2011; 88: 2824–2834.

Zenk

. Comparison of the performance of photovoltaic power generation-consumption system with push-pull converter under the effect of five different types of controllers. Int J Photoenergy 2019; 2019: 3810970.

Rajan

. Optimizing photovoltaic panel performance: a comparative study of meta-heuristic algorithms. Adv Eng Intell Syst 2024; 003: 83–105.

Czarkowski

Kazimierczuk

. Application of state feedback with integral control to pulse-width modulated push-pull DC-DC convertor. IEE Proc, Control Theory Appl 1994; 141: 99–103.

Qinglin

Haohui

Zibo

, et al. A push-pull forward resonant converter with wide input based on fixed frequency pulse width modulation. Power Syst Technol 2024; 48: 4317–4326.

Corradini

Orietti

Mattavelli

, et al. Digital hysteretic voltage-mode control for DC–DC converters based on asynchronous sampling. IEEE Trans Power Electron 2008; 24: 201–211.

Al-Baidhani

Salvatierra

Ordóñez

, et al. Simplified nonlinear voltage-mode control of PWM DC-DC buck converter. IEEE Trans Energy Convers 2020; 36: 431–440.

Zhang

Kimball

. DC–DC converter based photovoltaic simulator with a double current mode controller. IEEE Trans Power Electron 2017; 33: 5860–5868.

Urtasun

Samanes

Barrios

, et al. Control of a photovoltaic array interfacing current-mode-controlled boost converter based on virtual impedance emulation. IEEE Trans Ind Electron 2018; 66: 3496–3506.

10.

Tan

Green

Hernandez-Aramburo

. A current-mode controlled maximum power point tracking converter for building integrated photovoltaics. In 2007 European conference on power electronics and applications, IEEE, 2007, pp. 1–10.

11.

Abd Rahim

Selvaraj

. Hysteresis current control and sensorless MPPT for grid-connected photovoltaic systems. In 2007 IEEE international symposium on industrial electronics, IEEE, 2007, pp. 572–577.

12.

Denysiuk

Bielokha

Derevianko

, et al. Design and modeling PV converter with hysteresis control. In 2022 IEEE 8th international conference on energy smart systems (ESS), IEEE, 2022, pp. 165–168.

13.

Mohamed

Jeyanthy

Devaraj

. Hysteresis-based voltage and current control techniques for grid connected solar photovoltaic systems: comparative study. Int J Electric Comp Eng 2018; 8: 2671–2681.

14.

T-F

Chang

C-H

Chen

Y-H

. A fuzzy-logic-controlled single-stage converter for PV-powered lighting system applications. IEEE Trans Ind Electron 2000; 47: 287–296.

15.

Shangeetha

. Implementation of fuzzy logic controller in photovoltaic power generation using boost converter and boost inverter. Int J Power Electron Drive Syst 2012; 2: 249.

16.

Gursoy

Zhuo

Lozowski

, et al. Photovoltaic energy conversion systems with sliding mode control. Energies (Basel) 2021; 14: 6071.

17.

Inomoto

de Almeida Monteiro

JRB

Sguarezi Filho

. Boost converter control of PV system using sliding mode control with integrative sliding surface. IEEE J Emerg Sel Top Power Electron 2022; 10: 5522–5530.

18.

Sarvi

Soltani

NamazyPour

, et al. A new sliding mode controller for DC/DC converters in photovoltaic systems. J Energy 2013; 2013: 871025.

19.

Kalla

Kaushik

Singh

, et al. Adaptive control of voltage source converter based scheme for power quality improved grid-interactive solar PV–battery system. IEEE Trans Ind Appl 2019; 56: 787–799.

20.

Salleh

NAM

Hannoon

NMS

Baharom

. Design and analysis of an optimized proportional-integral-derivative (PID) controller for photovoltaic (PV) based microgrid in power system. In 2024 IEEE industrial electronics and applications conference (IEACon), IEEE, 2024, pp. 157–165.

21.

Abdel-Rahim

Wang

. A new high gain DC-DC converter with model-predictive-control based MPPT technique for photovoltaic systems. CPSS Trans Power Electron Appl 2020; 5: 191–200.

22.

Lashab

Sera

Guerrero

, et al. Discrete model-predictive-control-based maximum power point tracking for PV systems: overview and evaluation. IEEE Trans Power Electron 2017; 33: 7273–7287.

23.

López

Seleme Jr

Donoso

, et al. Digital control strategy for a buck converter operating as a battery charger for stand-alone photovoltaic systems. Sol Energy 2016; 140: 171–187.

24.

Tanouti

Setti

Aziz

, et al. Application of feedback-feedforward loop digital control to a PWM dc-dc boost converter used for solar photovoltaic systems. In 2014 International renewable and sustainable energy conference (IRSEC), IEEE, 2014, pp. 747–752.

25.

Fernandes

Vieira

Vitorino

, et al. Modeling and state-space feedback control of a DC-DC converter for photovoltaic systems. In 2014 IEEE energy conversion congress and exposition (ECCE), IEEE, 2014, pp. 1119–1128.

26.

Hartmann

Vitorino

de Rossiter Correa

, et al. Combining model-based and heuristic techniques for fast tracking the maximum-power point of photovoltaic systems. IEEE Trans Power Electron 2012; 28: 2875–2885.

27.

Bhat

Bernstein

. Finite-time stability of continuous autonomous systems. SIAM J Control Optim 2000; 38: 751–766.

28.

Liu

Deng

Liu

, et al. Fixed-time integral terminal sliding mode control with an adaptive RBF neural network for PMSM speed regulation. Control Eng Pract 2025; 156: 106236.

29.

Ullah

Zhang

, et al. Smooth super-twisting sliding mode control design with high order super-twisting observer for speed tracking control of permanent magnet synchronous motor drive system. ISA Trans 2025; 162: 227–242.

30.

Song

Zhou

. PMSM Disturbance resistant adaptive fast super-twisting algorithm speed control method. IEEE Access 2024; 12: 138155–138165.

A Novel Control Methodology for Photovoltaic Systems with Equivalent Photovoltaic Resistance Compensator

Abstract

Keywords

Get full access to this article

References