Closed-loop Implementation of a Non-isolated High Step-up Integrated SEPIC-CUK DC-DC Converter Structure with Single Switch

Duraisamy, Murali

doi:10.1590/1678-4324-2024230787

Abstract

Recently, the renewable energy applications require the development of highly efficient DC-DC converters with higher voltage transfer gain capability to meet out the increased global power demand. The non-isolated DC-DC converters are preferred due to certain drawbacks of isolated structures. The traditional boost, SEPIC (single-ended primary-inductor converter), and CUK based DC-DC converter structures are modified with additional power switches, diodes, and passive components in order to achieve high voltage gain. However, the modified structures with large number of active and passive elements suffer from the drawbacks of increased complexity of control algorithm, reduced power conversion efficiency and higher converter cost. Hence, the researchers started to explore more on single power switch configured non-isolated high step-up DC-DC converter topologies using hybrid concept. The research work presented in this paper explores such a high gain single-switch hybrid DC-DC converter structure that combines the conventional SEPIC and CUK topologies to achieve enhanced voltage gain. In the proposed hybrid topology, the input current is continuous during all modes of converter operation. Moreover, the power switch experiences only low voltage-current stress. The closed-loop configuration of the proposed hybrid converter is implemented using classic PID (Proportional+Integral+Derivative) and FOPID (Fractional Order PID) controllers, and simulated in MATLAB / SIMULINK environment with duty ratio D = 0.7 for the power switch. The results demonstrate that the dynamic performance of the converter with FOPID controller is much improved in terms of reduced settling time, overshoot, and ripples for the output voltage, as compared to that with classic PID controller.

Keywords:
closed-loop configuration; CUK converter; duty ratio; FOPID controller; hybrid DC-DC converter topology; MATLAB / SIMULINK; PID controller; SEPIC topology; voltage gain

HIGHLIGHTS

The proposed converter topology employs single control switch.

Improved voltage gain is obtained due to hybridization of SEPIC and CUK topologies.

The input current is continuous during all modes of converter operation.

The dynamic performance of the converter is improved with FOPID controller.

INTRODUCTION

Over recent decades, renewable energy system based electrical energy generation is widely employed to meet out the rapidly growing energy demand worldwide as the non-renewable fossil fuels such as coal, natural gas, and petroleum are rapidly depleting and contribute mainly to the global warming, immense environment pollution, and increased cost of the system [¹1 Blaabjerg F, Yang Y, Ma K, Wang X. Power electronics - The key technology for renewable energy system. Proceedings of the 4th International Conference on Renewable Energy Research and Applications (ICRERA’15), Palermo (Italy), 2015; 1618-26. doi.org/10.1109/ICRERA.2015.7418680.
https://doi.org/10.1109/ICRERA.2015.7418... ], [²2 Das D, Esmaili R, Xu L, Nichols D. An optimal design of a grid connected hybrid wind/photovoltaic/fuel cell system for distributed energy production. Proceedings of the 31st Annual Conference of IEEE Industrial Electronics Society (IECON 2005), Raleigh (NC), 2005; 2499-2504. doi.org/10.1109/IECON.2005.1569298.
https://doi.org/10.1109/IECON.2005.15692... ]. The renewable energy sources like photo-voltaic (PV) panels and fuel cells (FC) deliver the electrical power at low DC output voltage level [³3 Li W, He X. Review of nonisolated high- step-up DC-DC converters in photovoltaic grid-connected applications. IEEE Trans Ind Electron. 2011 Apr; 58(4):1239-50.], [⁴4 Jemei S, Hissel D, Pera MC, Kauffmann JM. A new modeling approach of embedded fuel-cell power generators based on artificial neural network. IEEE Trans Ind Electron. 2008 Jan; 51(1):437-47.]. High step-up DC-DC converters are employed to increase this low output voltage to high DC voltage level that can be fed as input to the grid-connected inverters [⁵5 Guilbert D, Mobarakeh BN, Pierfederici S, Bizon N, Mungporn P, Thounthong P. Comparative study of adaptive Hamiltonian control laws for DC microgrid stabilization: An Fuel cell boost converter. Appl Sci Eng Progress. 2022 Sep; 15(3):1-17.]-[¹⁰10 Premkumar M, Kumar C, Sowmya R. Analysis and implementation of high-performance DC-DC step-up converter for multilevel boost structure. Front Energy Res. 2019 Dec; 7:1-11.]. The performance of renewable energy system based power generation thus depends mainly on the appropriate selection of highly efficient and cost-effective DC-DC converters capable of achieving high voltage gain.

The categories of high step-up DC-DC converters include transformer-based (isolated) and transformerless (non-isolated) structures. The transformer-based DC-DC converter topologies, suitable for high power applications, employ high-frequency transformers to provide electrical barrier between input and output ports of the converter. This electrical barrier helps to provide protection of the sensitive loads [¹¹11 Liu D, Deng F, Wang Y, Chen Z. Improved control strategy for T-type isolated DC/DC converters. J Power Electron. 2017 Jul; 17(4):874-83.]. Another advantage of galvanically isolated DC-DC converter topologies is that they are capable to provide high voltage gain suitable for electric vehicles and renewable energy applications [¹²12 Yilmaz M, Krein PT. Review of the impact of vehicle-to-grid technologies on distribution systems and utility interfaces. IEEE Trans Power Electron. 2013 Dec; 28(12):5673-89.]-[¹⁶16 Babaei E, Abbasi F, Tarzamni H, Kolahian P. Isolated high step-up switched-boost DC/DC converter with modified control method. IET Power Electronics, 2019 Nov; 12(14):3635-45.]. The important demerits of such isolated topologies are that the control switches are subjected to high frequency voltage transients due to isolation transformer’s leakage inductance; two-stage power conversion process such as DC-AC-DC is involved; and complexity of control circuitry is increased. Hence, the non-isolated DC-DC converter configurations find more applications in electric vehicles and renewable energy system based power generation [¹⁷17 Mounica V, Obulesu YP. A comprehensive review on non-isolated bidirectional DC-DC converter topologies for electric vehicle application. Advances in Automation, Signal Processing, Instrumentation, and Control, Lecture Notes in Electrical Engineering, 2021 Mar; 700:2097-108.]-[¹⁸18 Blaabjerg F, Bhaskar MS, Padmanaban S. Non-isolated DC-DC converters for renewable energy applications. CRC Press, 2021 Apr; 1st Edition.].

A non-isolated highly efficient hybrid topology of single-switch configured boost and Cuk converters is presented in [¹⁹19 Karthikeyan M, Elavarasu R, Ramesh P, Bharatiraja C, Sanjeevikumar P, Mihet-Popa L, et al. A hybridization of Cuk and Boost converter using single switch with higher voltage gain capability. Energies, 2020 May; 13(2312):1-24.]. The proposed lower component-count configuration under continuous current mode operation in [¹⁹19 Karthikeyan M, Elavarasu R, Ramesh P, Bharatiraja C, Sanjeevikumar P, Mihet-Popa L, et al. A hybridization of Cuk and Boost converter using single switch with higher voltage gain capability. Energies, 2020 May; 13(2312):1-24.] has high voltage gain capability than that of traditional boost and Cuk converters. A non-isolated integrated boost and modified Cuk converters with enhanced voltage gain is presented in [²⁰20 Murali D. A transformerless boost-modified Cuk combined single-switch DC-DC converter topology with enhanced voltage gain. Braz Arch Biol Technol, 2023 Apr; 66:1-20.]. The steady state behavior and state space modeling of the hybrid topology are better explained in [²⁰20 Murali D. A transformerless boost-modified Cuk combined single-switch DC-DC converter topology with enhanced voltage gain. Braz Arch Biol Technol, 2023 Apr; 66:1-20.]. The hybrid converter configuration proposed in [²⁰20 Murali D. A transformerless boost-modified Cuk combined single-switch DC-DC converter topology with enhanced voltage gain. Braz Arch Biol Technol, 2023 Apr; 66:1-20.] can provide higher voltage gain than that of the configuration proposed in [¹⁹19 Karthikeyan M, Elavarasu R, Ramesh P, Bharatiraja C, Sanjeevikumar P, Mihet-Popa L, et al. A hybridization of Cuk and Boost converter using single switch with higher voltage gain capability. Energies, 2020 May; 13(2312):1-24.].

A SEPIC converter capable of producing a stable and controlled output voltage using PID controller tuned by Bat Algorithm optimization method is proposed in [²¹21 Khather SI, Ibrahim MA. Modeling and simulation of SEPIC controlled converter using PID controller. Int J Power Electron Drive Syst. 2020 June; 11(2):833-43.]. The proposed PID controlled SEPIC converter in [²¹21 Khather SI, Ibrahim MA. Modeling and simulation of SEPIC controlled converter using PID controller. Int J Power Electron Drive Syst. 2020 June; 11(2):833-43.] has better dynamic performance in the presence of load and line disturbances. A combined SEPIC-Boost converter using several PID feedback tuning methods suitable for renewable energy applications is presented in [²²22 Mamat MN, Ishak D. Analysis of SEPIC-Boost converter using several PID feedback tuning methods for renewable energy applications. J Adv Res Appl Sci Eng Tech. 2022 Mar; 26(1):105-17.]. The authors of [²²22 Mamat MN, Ishak D. Analysis of SEPIC-Boost converter using several PID feedback tuning methods for renewable energy applications. J Adv Res Appl Sci Eng Tech. 2022 Mar; 26(1):105-17.] concluded that an extremely well-regulated output voltage is obtained using SEPIC-Boost converter with modified Ziegler-Nichols tuned PID controller. The performances of a linear PID controller and a nonlinear fuzzy controller are compared in terms of output voltage regulation in the presence of input voltage disturbances for a SEPIC converter proposed in [²³23 Mouslim S, Oubella M, Kourchi M, Ajaamoum M. Simulation and analyses of SEPIC converter using linear PID and fuzzy logic controller. Mater Today, 2020 May; 27(4):3199-208.]. A closed loop implementation with optimized FOPID controller for a conventional SEPIC topology can give the better voltage regulation [²⁴24 Senthilkumar R, Sunil Dhas GJ. Fractional order controller design for SEPIC converter using metaheuristic algorithm. J Intell Fuzzy Syst. 2018 Dec; 35(6):6269-76.].

A Cuk converter can well regulate the output voltage using PI/PID and fuzzy controllers [²⁵25 Yilmaz M, Corapsiz MF, Corapsiz MR. Voltage control of Cuk converter with PI and Fuzzy logic controller in continuous conduction mode. Balkan J Electri Comp Eng. 2020 Apr; 8(2):127-34., ²⁶26 Sevim D, Gider V. Designing a control interface and PID controller of CUK converter. Eur. J. Tech. 2021 May; 11(1):93-100.]. An application of Cuk converter for charging a lithium polymer battery of 12 V and 40 AH rating is presented in [²⁷27 Shoumi HN, Sudiharto I, Sunarno E. Design of the CUK converter with PI controller for battery charging. Proceedings of the International Seminar on Application for Technology of Information and Communication (iSemantic’20), Semarang (Indonesia), 2020 Sep; 1-5. doi.org/10.1109/iSemantic50169.2020.9234294.
https://doi.org/10.1109/iSemantic50169.2... ], where the converter output voltage is stabilized by PI control. A high performance PID controller, that can ensure a stabilized DC output voltage in the presence of small and large signal disturbances, is designed based on internal model control (IMC) principle for a reduced-order model of the Cuk converter proposed by the authors in [²⁸28 Gupta M, Gupta N, Garg MM. Performance analysis of IMC-PID controller designed for Cuk converter with model reduction. Proceedings of the 1st International Conference on Sustainable Technology for Power and Energy Systems (STPES’22). Srinagar (India). 2022 July; 1-6. doi.org/10.1109/STPES54845.2022.10006465.
https://doi.org/10.1109/STPES54845.2022.... ]. A PI control based voltage tracking of bridgeless power factor correction (BPFC) Cuk converter is proposed in [²⁹29 Utomo WM, Isa NAA, Baker AA, Gani AFHA, Prasetyo BE, Elmunsyah H, et al. Voltage tracking of bridgeless PFC Cuk converter using PI controller. Int J Power Electron Drive Syst. 2020 Mar; 11(1):367-73.], which has the advantages of faster steady state response and lower output voltage ripples. The output voltage of an Interleaved Cuk Converter (ICC) can be regulated using Genetic Algorithm (GA) tuned FOPID controller in the presence of input voltage variations [³⁰30 Rayeen Z, Tiwari S, Hanif O. Fractional order PID controller for tuning interleaved Cuk converter. Proceedings of the International Conference on Electrical, Electronics and Computer Electronics and Computer Engineering (UPCON 2019). Aligarh (India). 2019 Nov; 1-6. doi.org/10.1109/UPCON47278.2019.8980252.
https://doi.org/10.1109/UPCON47278.2019.... ]. The stabilization of output voltage of linearized model of a non-isolated DC-DC Cuk converter can be exercised in the presence of any disturbance, using GA tuned FOPID controller as suggested by the authors in [³¹31 Tiwari S, Rayeen Z, Hanif O. Design and analysis of fractional order PID controller tuning via Genetic Algorithm for CUK converter. Proceedings of the 13th IEEE International Conference on Industrial and Information Systems (ICIIS 2018). Robar (Punjab). 2018 Dec; 1-6. doi.org/10.1109/ICIINFS.2018.8721419.
https://doi.org/10.1109/ICIINFS.2018.872... ]. Some authors suggested a Cuk converter with well-regulated output voltage using PSO (Particle Swarm Optimization) tuned FOPID controller [³²32 Xiong B, Kong Q, Chen X. A fractional order PID controller tuning via PSO of Cuk converter. Int J Wirel Mob Comput. 2017 Jan; 12(2):147-53.].

In this work, a hybridized non-isolated single-switch DC-DC converter topology with high voltage gain suitable for renewable energy applications is suggested. The traditional SEPIC and Cuk topologies are connected in parallel to obtain the proposed hybrid topology operating in continuous conduction mode. The active and passive components experience low voltage stress. This hybrid structure produces the enhanced voltage gain by complementing the benefits of SEPIC and Cuk configurations. The voltages appearing across the two shunt capacitors at the load side are summed up to get the output voltage (V₀) in the proposed converter topology. The closed-loop implementation of the proposed integrated structure with suitably tuned FOPID controller ensures the output voltage stabilization. The voltage conversion ratio of the proposed integrated structure is found to be greater than that of the classical SEPIC and Cuk topologies.

The structure of the remaining part of the paper is as follows: The various modes of operation, the derivation of static voltage gain, the simulation results and discussion of the proposed hybrid converter are presented in detail in subsequent sections that follow. The proposed converter has been simulated in MATLAB / SIMULINK platform and the corresponding results and discussion are presented in Section 3. The features of the proposed work are summarized in Conclusion section.

WORKING OF THE PROPOSED HYBRID CONVERTER STRUCTURE

The structures of traditional non-isolated DC-DC SEPIC and the CUK converter are depicted in Figure 1(a) and 1(b). Figure 1(c) shows the suggested non-isolated hybrid DC-DC converter topology with single control switch developed by parallel integration of the classical topologies shown in Figure 1(a) and 1(b) with common elements on the input side as control switch (S) and the inductor (L₁). The summation of the voltages appearing across the capacitors C₃ and C₄ is taken as load voltage (V₀). The integrated structure with ideal active and passive elements provides enhanced voltage gain than that of the conventional configurations shown in Figure 1(a) and Figure 1(b). The SEPIC converter can produce positive output and the CUK converter can produce negative output. However, the positive aspects of the proposed integrated converter are that (i). The integrated topology can produce positive (non-inverted) output, (ii). The voltage conversion ratio of the proposed integrated structure is found to be greater than that of the classical SEPIC and CUK topologies, (iii). Continuous currents are obtained at the input and output of the converter, and (iv). Low ripple current at both input and output of the converter. Moreover, the active and passive elements of the structure experience low voltage stress. There are three continuous conduction modes of operation of the proposed integrated converter structure.

Figure 1
Topologies of DC-DC converter - (a). Conventional SEPIC converter, (b). CUK converter, (c). Proposed integrated converter.

Operation of the converter during Mode-I (t₀<t<t₁):

During Mode-I operation, the power switch S is in ON condition. The diodes D₁ and D₂ are open circuited due to reverse bias. The inductor L₁ is charged to supply voltage V_in. The capacitor C₁ charges the inductor L₂. The inductor L₃ is magnetized by the capacitors C₂ and C₄. The load voltage V₀ is obtained by the discharge of the capacitor C₃. The equivalent circuit for Mode-I is shown in Figure 2(a). The voltages across the inductors L₁, L₂, and L₃ are shown by the following Equation (1).

V_{L 1} = V_{i n}; V_{L 2} = V_{C 1}; V_{L 3} = V_{C 2} - V_{C 4}

(1)

where, VL1, VL2, & VL3 are the voltages across the inductors L1, L2, & L3 respectively;

Vin is DC input voltage;

VC1, VC2, & VC4 represent respectively the voltages across the capacitors C1, C2, & C4.

Operation of the converter during Mode-II (t1<t<t2):

During Mode-II operation, the power switch S is in OFF condition. The diode D1 is open circuited due to reverse bias and the diode D2 acts as short circuit due to forward bias condition. The inductor L1 gets demagnetized and hence charges the capacitor C2 through the forward biased diode D2. There is no demagnetization path for the inductor L2 due to reverse biased diode D1 and OFF condition of the switch S. Hence, there is no current flow through the inductor L2. The inductor L3 discharges its stored energy through the forward biased diode D2 and hence charges the capacitor C4. The capacitor C3 supplies the load current (I0). The corresponding equivalent circuit for Mode-II is shown in Figure 2(b). The following Equation (2) illustrates the inductors’ voltages.

V_{L 1} = V_{i n} - V_{C 2}; V_{L 2} = 0; V_{L 3} = - V_{C 4}

(2)

Operation of the converter during Mode-III (t2<t<t3):

During Mode-III operation, the power switch S remains in the OFF condition. Both the diodes D1 and D2 start conducting. The inductor L1 charges the capacitor C2. The inductor L2 charges the capacitor C3 through the forward biased diode D1. The inductor L3 charges the capacitor C4 through the forward biased diode D2. The source Vin supplies the load R0. The corresponding equivalent circuit for Mode-III is shown in Figure 2(c). The following Equation (3) illustrates the inductors’ voltages.

V_{L 1} = V_{i n} - V_{C 2}; V_{L 2} = - V_{C 3}; V_{L 3} = - V_{C 4}

(3)

Figure 2
Equivalent circuits of the suggested DC-DC converter - (a). Mode-I (b). Mode-II (c). Mode-III

Derivation of voltage gain of the proposed converter:

For the traditional continuous conduction mode (CCM) operated SEPIC and Cuk converter configurations, with duty ratio ‘k’ for the power switch, shown in Figure 1(a) and 1(b), the voltage gain equations (4) & (5) are illustrated as shown below:

V o l t a g e g a i n (G_{C C M}) f o r t h e t r a d i t i o n a l S E P I C t o p o \log y = \frac{V_{0}}{V_{i n}} = \frac{k}{1 - k}

(4)

V o l t a g e g a i n (G_{C C M}) f o r t h e t r a d i t i o n a l C u k c o n v e r t e r = \frac{V_{0}}{V_{i n}} = - \frac{k}{1 - k}

(5)

The Equations (1), (2), & (3) are used to derive the voltage gain equation for the proposed integrated SEPIC-Cuk DC-DC converter topology based on the volt-second balance principle applied to the three inductors L₁, L₂, and L₃.

V_{i n} k T_{s} + (V_{i n} - V_{C 2}) (1 - k) T_{s} = 0

(6)

V_{i n} k T_{s} - V_{C 3} (1 - k) T_{s} = 0

(7)

(V_{C 2} + V_{C 4}) k T_{s} - V_{C 4} (1 - k) T_{s} = 0

(8)

From the Equation (6), the voltage V_C2 across the capacitor C₂ is obtained as Equation (9).

V_{C 2} = \frac{V_{i n}}{1 - k}

(9)

From the Equations (7) & (8), the voltages V_C3 & V_C4 across the capacitors C₃ & C₄ are obtained.

V_{C 3} = V_{C 4} = \frac{k V_{i n}}{(1 - k)}

(10)

The load voltage (V₀) of the proposed converter is obtained as the sum of the capacitor voltages V_C3 and V_C4.

V_{0} = V_{C 3} + V_{C 4} = \frac{2 k}{(1 - k)} V_{i n}

(11)

The voltage gain (G_CCM) of the proposed integrated SEPIC-Cuk DC-DC converter is obtained as:

G_{C C M} = \frac{V_{0}}{V_{i n}} = \frac{2 k}{1 - k}

(12)

CONTROLLERS FOR THE PROPOSED INTEGRATED CONVERTER STRUCTURE

Suitable controllers are employed to obtain the stabilized output from the converter in the presence of any disturbances. In this work, classical PID (Proportional+Integral+Derivative) controller and FOPID (Fractional Order PID) controllers are used.

Classical PID controller:

The general form of classical PID controller is PID. The transfer function of the controller is given by Equation (13). In this work, the PID controller parameters such as K_p, K_i, & K_d are tuned by trial and error approach. Accordingly, suitable parameters are chosen and are shown in Table 2.

C (s) = \frac{Y (s)}{E (s)} = K_{p} + \frac{K_{i}}{s} + K_{d} s

(13)

Fractional Order PID (FOPID) controller:

The general form of Fractional Order PID (FOPID) controller is PI^λD^µ. The transfer function of the controller is given by Equation (14). The FOPID controller constants such as K_p, K_i, K_d, λ, and µ are also selected based on trial and error approach and are tabulated in Table 3.

C (s) = \frac{Y (s)}{E (s)} = K_{p} + \frac{K_{i}}{s^{λ}} + K_{d} s^{μ}

(14)

where, λ is integral order; µ is differential order. By suitable selection of these two parameters, the FOPID controller is made to have better control effect [³³33 Meng F, Liu S, Liu AK. Design of an optimal fractional order PID for constant tension control system. IEEE Access. 2020 Mar; 8:58933-39., ³⁴34 Aleksei T, Eduard P, Juri B. A flexible MATLAB tool for optimal fractional-order PID controller design subject to specifications. Proceedings of 31st Chinese Control Conference, Heifi (China), 2012 Jul; 4698-703.].

DESIGN OF THE PROPOSED INTEGRATED CONVERTER CIRCUIT COMPONENTS

The power switch ‘S’, and the diodes D₁ and D₂ are assumed to be ideal semiconductor devices. The inductors (L₁, L₂, and L₃) and capacitors (C₁, C₂, C_3, and C₄) of the proposed converter are designed so that the power switch ‘S’ has to support for both the converter voltage and current.

Design of inductors and capacitors:

The proposed converter has an input voltage (V_in) of 24 V and output voltage (V₀) of 112 V supplying a 85 W load. The duty ratio (k) of the power switch is selected as 0.7. Hence, the output voltage of SEPIC converter portion (V_So) and the Cuk converter portion (V_Co) in the integrated structure is 56 V each. The switching frequency (f_s) is 15 kHz. The values of all inductors and capacitors used in the proposed converter are so designed that the change in inductor and capacitor currents ) is no more than 4%, the output ripple voltage is no more than 1%, and the ripple voltage across the capacitors is no more than 5% [³⁵35 Priyadarshi N, Bhaskar MS, Padmanaban S, Blaabjerg F, Azam F. New CUK-SEPIC converter based photovoltaic power system with hybrid GSA-PSO algorithm employing MPPT for water pumping applications. IET Power Electronics, 2020 Mar; 13(13):2824-30.].

L_{1} \geq \frac{V_{i n}^{2} V_{S o}}{f_{s} (V_{i n} + V_{S o}) P_{o} (% Δ I_{L 1}^{\min})} \geq \frac{{(24)}^{2} \times 56}{15000 \times (24 + 56) \times 85 \times 4} \geq 79 µ H

The value of L₁ is taken as 100 µH for optimum performance of the converter.

L_{2} \geq \frac{2 V_{i n} V_{S o}^{2}}{f_{s} (V_{i n} + V_{S o}) P_{o} (% Δ I_{L 2}^{\max})} \geq \frac{2 \times 24 \times {(56)}^{2}}{15000 \times (24 + 56) \times 85 \times 3} \geq 492 µ H

L_{3} \geq \frac{2 V_{i n} V_{S o}^{2}}{f_{s} (V_{i n} + V_{S o}) P_{o} (% Δ I_{L 3}^{\max})} \geq \frac{2 \times 24 \times {(56)}^{2}}{15000 \times (24 + 56) \times 85 \times 3} \geq 492 µ H

The values of L₂ and L₃ are taken as 700 µH each for optimum performance of the converter.

C_{1} \geq \frac{P_{0}}{f_{s} \times 2 {(V_{i n} + V_{S o})}^{2} (% Δ V_{C 1}^{\max})} \geq \frac{85}{15000 \times 2 \times {(24 + 56)}^{2} \times 3} \geq 0.15 µ F

C_{2} \geq \frac{P_{0}}{f_{s} \times 2 {(V_{i n} + V_{S o})}^{2} (% Δ V_{C 2}^{\max})} \geq \frac{85}{15000 \times 2 \times {(24 + 56)}^{2} \times 3} \geq 0.15 µ F

The values of C₁ and C₂ are taken as 3.3 µF each for optimum performance of the converter.

C_{3} \geq \frac{P_{0}}{f_{s} \times 2 (V_{i n} + V_{S o}) V_{S o} (% Δ I_{C 3}^{\max})} \geq \frac{85}{15000 \times 2 \times (24 + 56) \times 56 \times 3} \geq 0.211 µ F

C_{4} \geq \frac{P_{0}}{f_{s} \times 16 V_{C o}^{2} (% Δ V_{C 4}^{\max})} \geq \frac{85}{15000 \times 16 \times {(56)}^{2} \times 1} \geq 0.113 µ F

The values of C₃ and C₄ are taken as 0.5 µF each for optimum performance of the converter.

SIMULATION OF THE PROPOSED INTEGRATED CONVERTER: RESULTS AND DISCUSSION

The simulation models of the suggested integrated DC-DC converter configuration with PID and FOPID controllers are developed using MATLAB/SIMULINK software tool as shown in Figure 3 and Figure 4. The variable-step solver of type ‘ode 45’ is used for simulating the converter at 15 kHz switching frequency (f_s). Table 1, Table 2, and Table 3 respectively list the values of converter circuit parameters, PID controller parameters, and FOPID controller parameters used for simulation. A PWM (Pulse Width Modulation) pulse as shown in Figure 5 is generated using pulse generator for triggering the MOSFET switch S into conduction. The duty cycle ‘k’ for the power switch S is considered to be varying from 0.5 to 0.9. A resistive load of 150 Ω resistance with 85 W power capacity is used. In this work, the simulation results are shown for k = 0.7. A DC source (V_in) of 24 V, as shown in Figure 6, is given as input voltage to the proposed converter. Figure 7 shows the waveform of DC input current (I_in) with 3.874 A as steady state value. Figure 8 and Figure 9 show the DC output voltage (V₀) and DC output current (I₀) waveforms of the converter with PID and FOPID controllers, which indicate that the converter with FOPID controller performs better than that with classical PID controller in terms of reduced overshoot and reduced settling time. The three inductors’ voltages V_L1, V_L2, & V_L3 are illustrated in Figure 10, Figure 11, and Figure 12 respectively for the converter with FOPID controller. The waveforms of voltages V_C1, V_C2, V_C3, & V_C4 across the four capacitors C₁, C₂, C₃, & C₄ are respectively shown in Figure 13, Figure 14, Figure 15, and Figure 16 for the converter with FOPID controller. The sum of voltages V_C3 & V_C4 gives the output voltage (V₀) of the converter. Figure 17 and Figure 18 illustrate that the voltage stress across the diodes D₁ and D₂ is found to be low. The voltage stress and current stress of the power switch are indicated by the waveforms shown in Figure 19 and Figure 20 for the converter with PID and FOPID controllers. It is understood that the power switch is subjected to low voltage and current stress for the case of converter with FOPID controller. For k = 0.7, the proposed converter has the efficiency (η_c) of 90% as calculated below:

η_{c} = \frac{P_{0}}{P_{i n}} \times 100 = \frac{V_{0} I_{0}}{V_{i n} I_{i n}} \times 100 = \frac{112 \times 0.7474}{24 \times 3.874} \times 100 = 90 %

Figure 3
MATLAB / SIMULINK model of the proposed integrated DC-DC converter with PID controller

Figure 4
MATLAB / SIMULINK model of the proposed integrated DC-DC converter with FOPID controller

Thumbnail

Table 1
Parameters used for the simulation of the proposed hybrid DC-DC converter

Thumbnail

Table 2
PID controller parameters

Thumbnail

Table 3
FOPID controller Parameters

Figure 5
Gate pulse waveform for the switch S

Figure 6
Input DC voltage (V_in)

Figure 7
Input DC current (I_in)

Figure 8
Output DC voltage (V₀) with PID and FOPID controllers

Figure 9
Output DC current (I₀) with PID and FOPID controllers

Figure 10
Voltage across inductor L₁ (V_L1)

Figure 11
Voltage across inductor L₂ (V_L2)

Figure 12
Voltage across inductor L₃ (V_L3)

Figure 13
Voltage across capacitor C₁ (V_C1)

Figure 14
Voltage across capacitor C₂ (V_C2)

Figure 15
Voltage across capacitor C₃ (V_C3)

Figure 16
Voltage across capacitor C₄ (V_C4)

Figure 17
Voltage across diode D₁ (V_D1) and Current through diode D₁ (I_D1)

Figure 18
Voltage across diode D₂ (V_D2) and Current through diode D₂ (I_D2)

Figure 19
Voltage stress across switch S (V_S)

Figure 20
Current stress of switch S (I_S)

CONCLUSION

In this research article, the steady state performance of a non-isolated integrated single-switch SEPIC-Cuk DC-DC converter structure with PID and FOPID controllers has been analyzed. The suggested closed-loop configuration of the converter with positive output is operated in continuous inductor current mode. The integrated structure has high voltage gain compared to the traditional SEPIC / Cuk topologies. The performance validation of the proposed converter with duty ratio k = 0.7 is carried out using MATLAB / SIMULINK tool. The output voltage and output current waveforms of the converter are presented for the converter with suitably tuned PID and FOPID controllers. The reduced overshoot and reduced settling time are observed on both output voltage and output current waveforms for the case of converter with FOPID control scheme than that with PID controller. Thus, the FOPID controller improves the dynamic performance of the converter. The voltages across the inductors, capacitors, and the diodes of the converter with FOPID control are also presented for the same k = 0.7. The approximate power conversion efficiency of the proposed converter with k = 0.7 is calculated as 90%. Moreover, low voltage-current stress is observed on the power switch and the diodes for the case of converter with FOPID control scheme. The selection of output side capacitors C₃ and C₄ is in such a way that ripples are very much minimized in both the output voltage and current. The salient features of the proposed integrated DC-DC converter structure make it suitable for renewable energy based power generation applications.

Acknowledgments

The author acknowledges the technical support provided by the Department of Electrical and Electronics Engineering, Government College of Engineering, Srirangam, Tiruchirappalli, in carrying out the simulation work on the proposed converter.

REFERENCES

¹
Blaabjerg F, Yang Y, Ma K, Wang X. Power electronics - The key technology for renewable energy system. Proceedings of the 4th International Conference on Renewable Energy Research and Applications (ICRERA’15), Palermo (Italy), 2015; 1618-26. doi.org/10.1109/ICRERA.2015.7418680.
» https://doi.org/10.1109/ICRERA.2015.7418680
²
Das D, Esmaili R, Xu L, Nichols D. An optimal design of a grid connected hybrid wind/photovoltaic/fuel cell system for distributed energy production. Proceedings of the 31st Annual Conference of IEEE Industrial Electronics Society (IECON 2005), Raleigh (NC), 2005; 2499-2504. doi.org/10.1109/IECON.2005.1569298.
» https://doi.org/10.1109/IECON.2005.1569298
³
Li W, He X. Review of nonisolated high- step-up DC-DC converters in photovoltaic grid-connected applications. IEEE Trans Ind Electron. 2011 Apr; 58(4):1239-50.
⁴
Jemei S, Hissel D, Pera MC, Kauffmann JM. A new modeling approach of embedded fuel-cell power generators based on artificial neural network. IEEE Trans Ind Electron. 2008 Jan; 51(1):437-47.
⁵
Guilbert D, Mobarakeh BN, Pierfederici S, Bizon N, Mungporn P, Thounthong P. Comparative study of adaptive Hamiltonian control laws for DC microgrid stabilization: An Fuel cell boost converter. Appl Sci Eng Progress. 2022 Sep; 15(3):1-17.
⁶
Sivakumar S, Sathik MJ, Manoj PS, Sundararajan G. An assessment on performance of DC-DC converters for renewable energy applications. Renew Sustain Energy Rev. 2016 May; 58:1475-85.
⁷
Kolli A, Gaillard A, De Bernardinis A, Bethoux O, Hissel D, Khatir Z. A review on DC/DC converter architectures for power fuel cell applications. Energy Convers Manag. 2015 Nov; 105:716-30.
⁸
Mumtaz F, Yahaya NZ, Meraj ST, Singh B, Ramani Kannan, Ibrahim O. Review on non-isolated DC-DC converters and their control techniques for renewable energy applications. Ain Shams Eng J. 2021 Dec; 12(4):3747-63.
⁹
Koc Y, Birbir Y, Bodur H. Non-isolated high step-up DC/DC converters - An overview. Alexandria Eng J. 2022 Feb; 61(2):1091-132.
¹⁰
Premkumar M, Kumar C, Sowmya R. Analysis and implementation of high-performance DC-DC step-up converter for multilevel boost structure. Front Energy Res. 2019 Dec; 7:1-11.
¹¹
Liu D, Deng F, Wang Y, Chen Z. Improved control strategy for T-type isolated DC/DC converters. J Power Electron. 2017 Jul; 17(4):874-83.
¹²
Yilmaz M, Krein PT. Review of the impact of vehicle-to-grid technologies on distribution systems and utility interfaces. IEEE Trans Power Electron. 2013 Dec; 28(12):5673-89.
¹³
Park DR, Kim Y. Design and implementation of improved high step-down DC-DC converter for electric vehicles. Energies, 2021 Jul; 14:1-19.
¹⁴
Wu H, Xu P, Hu H, Zhou Z, Xing Y. Multiport converters based on integration of full-bridge and bidirectional DC-DC topologies for renewable generation systems. IEEE Trans Ind Electron. 2014 Feb; 61(2):856-69.
¹⁵
Chub A, Vinnikov D, Blaabjerg F, Peng FZ. A review of galvanically isolated impedance-source DC-DC converters. IEEE Trans Power Electron. 2016 Apr; 31(4):2808-28.
¹⁶
Babaei E, Abbasi F, Tarzamni H, Kolahian P. Isolated high step-up switched-boost DC/DC converter with modified control method. IET Power Electronics, 2019 Nov; 12(14):3635-45.
¹⁷
Mounica V, Obulesu YP. A comprehensive review on non-isolated bidirectional DC-DC converter topologies for electric vehicle application. Advances in Automation, Signal Processing, Instrumentation, and Control, Lecture Notes in Electrical Engineering, 2021 Mar; 700:2097-108.
¹⁸
Blaabjerg F, Bhaskar MS, Padmanaban S. Non-isolated DC-DC converters for renewable energy applications. CRC Press, 2021 Apr; 1st Edition.
¹⁹
Karthikeyan M, Elavarasu R, Ramesh P, Bharatiraja C, Sanjeevikumar P, Mihet-Popa L, et al. A hybridization of Cuk and Boost converter using single switch with higher voltage gain capability. Energies, 2020 May; 13(2312):1-24.
²⁰
Murali D. A transformerless boost-modified Cuk combined single-switch DC-DC converter topology with enhanced voltage gain. Braz Arch Biol Technol, 2023 Apr; 66:1-20.
²¹
Khather SI, Ibrahim MA. Modeling and simulation of SEPIC controlled converter using PID controller. Int J Power Electron Drive Syst. 2020 June; 11(2):833-43.
²²
Mamat MN, Ishak D. Analysis of SEPIC-Boost converter using several PID feedback tuning methods for renewable energy applications. J Adv Res Appl Sci Eng Tech. 2022 Mar; 26(1):105-17.
²³
Mouslim S, Oubella M, Kourchi M, Ajaamoum M. Simulation and analyses of SEPIC converter using linear PID and fuzzy logic controller. Mater Today, 2020 May; 27(4):3199-208.
²⁴
Senthilkumar R, Sunil Dhas GJ. Fractional order controller design for SEPIC converter using metaheuristic algorithm. J Intell Fuzzy Syst. 2018 Dec; 35(6):6269-76.
²⁵
Yilmaz M, Corapsiz MF, Corapsiz MR. Voltage control of Cuk converter with PI and Fuzzy logic controller in continuous conduction mode. Balkan J Electri Comp Eng. 2020 Apr; 8(2):127-34.
²⁶
Sevim D, Gider V. Designing a control interface and PID controller of CUK converter. Eur. J. Tech. 2021 May; 11(1):93-100.
²⁷
Shoumi HN, Sudiharto I, Sunarno E. Design of the CUK converter with PI controller for battery charging. Proceedings of the International Seminar on Application for Technology of Information and Communication (iSemantic’20), Semarang (Indonesia), 2020 Sep; 1-5. doi.org/10.1109/iSemantic50169.2020.9234294.
» https://doi.org/10.1109/iSemantic50169.2020.9234294.
²⁸
Gupta M, Gupta N, Garg MM. Performance analysis of IMC-PID controller designed for Cuk converter with model reduction. Proceedings of the 1st International Conference on Sustainable Technology for Power and Energy Systems (STPES’22). Srinagar (India). 2022 July; 1-6. doi.org/10.1109/STPES54845.2022.10006465.
» https://doi.org/10.1109/STPES54845.2022.10006465.
²⁹
Utomo WM, Isa NAA, Baker AA, Gani AFHA, Prasetyo BE, Elmunsyah H, et al. Voltage tracking of bridgeless PFC Cuk converter using PI controller. Int J Power Electron Drive Syst. 2020 Mar; 11(1):367-73.
³⁰
Rayeen Z, Tiwari S, Hanif O. Fractional order PID controller for tuning interleaved Cuk converter. Proceedings of the International Conference on Electrical, Electronics and Computer Electronics and Computer Engineering (UPCON 2019). Aligarh (India). 2019 Nov; 1-6. doi.org/10.1109/UPCON47278.2019.8980252.
» https://doi.org/10.1109/UPCON47278.2019.8980252.
³¹
Tiwari S, Rayeen Z, Hanif O. Design and analysis of fractional order PID controller tuning via Genetic Algorithm for CUK converter. Proceedings of the 13th IEEE International Conference on Industrial and Information Systems (ICIIS 2018). Robar (Punjab). 2018 Dec; 1-6. doi.org/10.1109/ICIINFS.2018.8721419.
» https://doi.org/10.1109/ICIINFS.2018.8721419.
³²
Xiong B, Kong Q, Chen X. A fractional order PID controller tuning via PSO of Cuk converter. Int J Wirel Mob Comput. 2017 Jan; 12(2):147-53.
³³
Meng F, Liu S, Liu AK. Design of an optimal fractional order PID for constant tension control system. IEEE Access. 2020 Mar; 8:58933-39.
³⁴
Aleksei T, Eduard P, Juri B. A flexible MATLAB tool for optimal fractional-order PID controller design subject to specifications. Proceedings of 31st Chinese Control Conference, Heifi (China), 2012 Jul; 4698-703.
³⁵
Priyadarshi N, Bhaskar MS, Padmanaban S, Blaabjerg F, Azam F. New CUK-SEPIC converter based photovoltaic power system with hybrid GSA-PSO algorithm employing MPPT for water pumping applications. IET Power Electronics, 2020 Mar; 13(13):2824-30.

Funding:

This research received no external funding.

Edited by

Editor-in-Chief:

Alexandre Rasi Aoki

Associate Editor:

Daniel Navarro Gevers

Publication Dates

Publication in this collection
29 Apr 2024
Date of issue
2024

History

Received
27 July 2023
Accepted
08 Jan 2024

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ¹
Blaabjerg F, Yang Y, Ma K, Wang X. Power electronics - The key technology for renewable energy system. Proceedings of the 4th International Conference on Renewable Energy Research and Applications (ICRERA’15), Palermo (Italy), 2015; 1618-26. doi.org/10.1109/ICRERA.2015.7418680.
» https://doi.org/10.1109/ICRERA.2015.7418680

[2] ²
Das D, Esmaili R, Xu L, Nichols D. An optimal design of a grid connected hybrid wind/photovoltaic/fuel cell system for distributed energy production. Proceedings of the 31st Annual Conference of IEEE Industrial Electronics Society (IECON 2005), Raleigh (NC), 2005; 2499-2504. doi.org/10.1109/IECON.2005.1569298.
» https://doi.org/10.1109/IECON.2005.1569298

[3] ³
Li W, He X. Review of nonisolated high- step-up DC-DC converters in photovoltaic grid-connected applications. IEEE Trans Ind Electron. 2011 Apr; 58(4):1239-50.

[4] ⁴
Jemei S, Hissel D, Pera MC, Kauffmann JM. A new modeling approach of embedded fuel-cell power generators based on artificial neural network. IEEE Trans Ind Electron. 2008 Jan; 51(1):437-47.

[5] ⁵
Guilbert D, Mobarakeh BN, Pierfederici S, Bizon N, Mungporn P, Thounthong P. Comparative study of adaptive Hamiltonian control laws for DC microgrid stabilization: An Fuel cell boost converter. Appl Sci Eng Progress. 2022 Sep; 15(3):1-17.

[6] ⁶
Sivakumar S, Sathik MJ, Manoj PS, Sundararajan G. An assessment on performance of DC-DC converters for renewable energy applications. Renew Sustain Energy Rev. 2016 May; 58:1475-85.

[7] ⁷
Kolli A, Gaillard A, De Bernardinis A, Bethoux O, Hissel D, Khatir Z. A review on DC/DC converter architectures for power fuel cell applications. Energy Convers Manag. 2015 Nov; 105:716-30.

[8] ⁸
Mumtaz F, Yahaya NZ, Meraj ST, Singh B, Ramani Kannan, Ibrahim O. Review on non-isolated DC-DC converters and their control techniques for renewable energy applications. Ain Shams Eng J. 2021 Dec; 12(4):3747-63.

[9] ⁹
Koc Y, Birbir Y, Bodur H. Non-isolated high step-up DC/DC converters - An overview. Alexandria Eng J. 2022 Feb; 61(2):1091-132.

[10] ¹⁰
Premkumar M, Kumar C, Sowmya R. Analysis and implementation of high-performance DC-DC step-up converter for multilevel boost structure. Front Energy Res. 2019 Dec; 7:1-11.

[11] ¹¹
Liu D, Deng F, Wang Y, Chen Z. Improved control strategy for T-type isolated DC/DC converters. J Power Electron. 2017 Jul; 17(4):874-83.

[12] ¹²
Yilmaz M, Krein PT. Review of the impact of vehicle-to-grid technologies on distribution systems and utility interfaces. IEEE Trans Power Electron. 2013 Dec; 28(12):5673-89.

[13] ¹³
Park DR, Kim Y. Design and implementation of improved high step-down DC-DC converter for electric vehicles. Energies, 2021 Jul; 14:1-19.

[14] ¹⁴
Wu H, Xu P, Hu H, Zhou Z, Xing Y. Multiport converters based on integration of full-bridge and bidirectional DC-DC topologies for renewable generation systems. IEEE Trans Ind Electron. 2014 Feb; 61(2):856-69.

[15] ¹⁵
Chub A, Vinnikov D, Blaabjerg F, Peng FZ. A review of galvanically isolated impedance-source DC-DC converters. IEEE Trans Power Electron. 2016 Apr; 31(4):2808-28.

[16] ¹⁶
Babaei E, Abbasi F, Tarzamni H, Kolahian P. Isolated high step-up switched-boost DC/DC converter with modified control method. IET Power Electronics, 2019 Nov; 12(14):3635-45.

[17] ¹⁷
Mounica V, Obulesu YP. A comprehensive review on non-isolated bidirectional DC-DC converter topologies for electric vehicle application. Advances in Automation, Signal Processing, Instrumentation, and Control, Lecture Notes in Electrical Engineering, 2021 Mar; 700:2097-108.

[18] ¹⁸
Blaabjerg F, Bhaskar MS, Padmanaban S. Non-isolated DC-DC converters for renewable energy applications. CRC Press, 2021 Apr; 1st Edition.

[19] ¹⁹
Karthikeyan M, Elavarasu R, Ramesh P, Bharatiraja C, Sanjeevikumar P, Mihet-Popa L, et al. A hybridization of Cuk and Boost converter using single switch with higher voltage gain capability. Energies, 2020 May; 13(2312):1-24.

[20] ²⁰
Murali D. A transformerless boost-modified Cuk combined single-switch DC-DC converter topology with enhanced voltage gain. Braz Arch Biol Technol, 2023 Apr; 66:1-20.

[21] ²¹
Khather SI, Ibrahim MA. Modeling and simulation of SEPIC controlled converter using PID controller. Int J Power Electron Drive Syst. 2020 June; 11(2):833-43.

[22] ²²
Mamat MN, Ishak D. Analysis of SEPIC-Boost converter using several PID feedback tuning methods for renewable energy applications. J Adv Res Appl Sci Eng Tech. 2022 Mar; 26(1):105-17.

[23] ²³
Mouslim S, Oubella M, Kourchi M, Ajaamoum M. Simulation and analyses of SEPIC converter using linear PID and fuzzy logic controller. Mater Today, 2020 May; 27(4):3199-208.

[24] ²⁴
Senthilkumar R, Sunil Dhas GJ. Fractional order controller design for SEPIC converter using metaheuristic algorithm. J Intell Fuzzy Syst. 2018 Dec; 35(6):6269-76.

[25] ²⁵
Yilmaz M, Corapsiz MF, Corapsiz MR. Voltage control of Cuk converter with PI and Fuzzy logic controller in continuous conduction mode. Balkan J Electri Comp Eng. 2020 Apr; 8(2):127-34.

[26] ²⁶
Sevim D, Gider V. Designing a control interface and PID controller of CUK converter. Eur. J. Tech. 2021 May; 11(1):93-100.

[27] ²⁷
Shoumi HN, Sudiharto I, Sunarno E. Design of the CUK converter with PI controller for battery charging. Proceedings of the International Seminar on Application for Technology of Information and Communication (iSemantic’20), Semarang (Indonesia), 2020 Sep; 1-5. doi.org/10.1109/iSemantic50169.2020.9234294.
» https://doi.org/10.1109/iSemantic50169.2020.9234294.

[28] ²⁸
Gupta M, Gupta N, Garg MM. Performance analysis of IMC-PID controller designed for Cuk converter with model reduction. Proceedings of the 1st International Conference on Sustainable Technology for Power and Energy Systems (STPES’22). Srinagar (India). 2022 July; 1-6. doi.org/10.1109/STPES54845.2022.10006465.
» https://doi.org/10.1109/STPES54845.2022.10006465.

[29] ²⁹
Utomo WM, Isa NAA, Baker AA, Gani AFHA, Prasetyo BE, Elmunsyah H, et al. Voltage tracking of bridgeless PFC Cuk converter using PI controller. Int J Power Electron Drive Syst. 2020 Mar; 11(1):367-73.

[30] ³⁰
Rayeen Z, Tiwari S, Hanif O. Fractional order PID controller for tuning interleaved Cuk converter. Proceedings of the International Conference on Electrical, Electronics and Computer Electronics and Computer Engineering (UPCON 2019). Aligarh (India). 2019 Nov; 1-6. doi.org/10.1109/UPCON47278.2019.8980252.
» https://doi.org/10.1109/UPCON47278.2019.8980252.

[31] ³¹
Tiwari S, Rayeen Z, Hanif O. Design and analysis of fractional order PID controller tuning via Genetic Algorithm for CUK converter. Proceedings of the 13th IEEE International Conference on Industrial and Information Systems (ICIIS 2018). Robar (Punjab). 2018 Dec; 1-6. doi.org/10.1109/ICIINFS.2018.8721419.
» https://doi.org/10.1109/ICIINFS.2018.8721419.

[32] ³²
Xiong B, Kong Q, Chen X. A fractional order PID controller tuning via PSO of Cuk converter. Int J Wirel Mob Comput. 2017 Jan; 12(2):147-53.

[33] ³³
Meng F, Liu S, Liu AK. Design of an optimal fractional order PID for constant tension control system. IEEE Access. 2020 Mar; 8:58933-39.

[34] ³⁴
Aleksei T, Eduard P, Juri B. A flexible MATLAB tool for optimal fractional-order PID controller design subject to specifications. Proceedings of 31st Chinese Control Conference, Heifi (China), 2012 Jul; 4698-703.

[35] ³⁵
Priyadarshi N, Bhaskar MS, Padmanaban S, Blaabjerg F, Azam F. New CUK-SEPIC converter based photovoltaic power system with hybrid GSA-PSO algorithm employing MPPT for water pumping applications. IET Power Electronics, 2020 Mar; 13(13):2824-30.

Parameters	Symbol	Value
Input voltage	V_in	24 V (DC)
Output voltage Inductor Inductors Capacitors Capacitors Switching frequency Load resistance Load power Average output current Duty ratio of the switch	V₀ L₁ L_2, L₃ C₁, C₂ C₃, C₄ f_s R₀ P₀ I₀ D	112 V (DC) 100 µH 700 µH each 3.3 µF each 0.5 µF each 15 kHz 150 Ω 85 W 0.7474 A 0.7

Parameters	Symbol	Value
Proportional gain	K_p	5.6×10^-5
Integral gain Derivative gain	K_I K_d	2 1×10^-5

Parameters	Symbol	Value
Proportional gain	K_p	3.47×10^-3
Integral gain Derivative gain Differential order Integral order	K_I K_d µ λ	1 1×10^-5 4.568×10^-4 0.37

Brasil

Brasil

Closed-loop Implementation of a Non-isolated High Step-up Integrated SEPIC-CUK DC-DC Converter Structure with Single Switch

Abstract

HIGHLIGHTS

INTRODUCTION

WORKING OF THE PROPOSED HYBRID CONVERTER STRUCTURE

Operation of the converter during Mode-I (t₀<t<t₁):

Operation of the converter during Mode-II (t1<t<t2):

Operation of the converter during Mode-III (t2<t<t3):

Derivation of voltage gain of the proposed converter:

CONTROLLERS FOR THE PROPOSED INTEGRATED CONVERTER STRUCTURE

Classical PID controller:

Fractional Order PID (FOPID) controller:

DESIGN OF THE PROPOSED INTEGRATED CONVERTER CIRCUIT COMPONENTS

Design of inductors and capacitors:

SIMULATION OF THE PROPOSED INTEGRATED CONVERTER: RESULTS AND DISCUSSION

CONCLUSION

Acknowledgments

REFERENCES

Funding:

Edited by

Editor-in-Chief:

Associate Editor:

Publication Dates

History

Brasil

Brasil

Closed-loop Implementation of a Non-isolated High Step-up Integrated SEPIC-CUK DC-DC Converter Structure with Single Switch

Abstract

HIGHLIGHTS

INTRODUCTION

WORKING OF THE PROPOSED HYBRID CONVERTER STRUCTURE

Operation of the converter during Mode-I (t0<t<t1):

Operation of the converter during Mode-II (t1<t<t2):

Operation of the converter during Mode-III (t2<t<t3):

Derivation of voltage gain of the proposed converter:

CONTROLLERS FOR THE PROPOSED INTEGRATED CONVERTER STRUCTURE

Classical PID controller:

Fractional Order PID (FOPID) controller:

DESIGN OF THE PROPOSED INTEGRATED CONVERTER CIRCUIT COMPONENTS

Design of inductors and capacitors:

SIMULATION OF THE PROPOSED INTEGRATED CONVERTER: RESULTS AND DISCUSSION

CONCLUSION

Acknowledgments

REFERENCES

Funding:

Edited by

Editor-in-Chief:

Associate Editor:

Publication Dates

History

Operation of the converter during Mode-I (t₀<t<t₁):