Nonaveraged control‐oriented modeling and relative stability analysis of DC‐DC switching converters

Al‐Turki, Yusuf; Aroudi, Abdelali El; Mandal, Kuntal; Giaouris, Damian; Abusorrah, Abdullah; Hindawi, Mohammed Al; Banerjee, Soumitro

doi:10.1002/cta.2387

Cited by 7 publications

(8 citation statements)

References 42 publications

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“…The gain margin is infinite because the total loop gain presents six stable poles (four from the power stage and two from the controller) and four stable zeros (three from the power stage and one from the controller), and the asymptotic behavior at high frequencies is similar to a minimum phase continuous-time second order system whose phase never crosses −180 degrees; therefore, the gain can be increased as much as possible without destabilizing the system. However, the values of the gain and the phase obtained from the small-signal average model are different from the actual phase of the switched system in the vicinity of the Nyquist frequency, as was recently reported in [37]. Indeed, it will be shown later using accurate discrete-time modeling that the system exhibits instability in the form of subharmonic oscillation for values of irradiance larger than approximately 820 W/m 2 with the fixed values of parameters shown in Tables 1-3.…”

Section: Small-signal Model Of the Dc-dc Quadratic Boost Converter Anmentioning

confidence: 67%

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Analysis of Nonlinear Dynamics of a Quadratic Boost Converter Used for Maximum Power Point Tracking in a Grid-Interlinked PV System

Aroudi

Al-Numay

García³

et al. 2018

Energies

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In this paper, the nonlinear dynamics of a PV-fed high-voltage-gain single-switch quadratic boost converter loaded by a grid-interlinked DC-AC inverter is explored in its parameter space. The control of the input port of the converter is designed using a resistive control approach ensuring stability at the slow time-scale. However, time-domain simulations, performed on a full-order circuit-level switched model implemented in PSIM© software, show that at relatively high irradiance levels, the system may exhibit undesired subharmonic instabilities at the fast time-scale. A model of the system is derived, and a closed-form expression is used for locating the subharmonic instability boundary in terms of parameters of different nature. The theoretical results are in remarkable agreement with the numerical simulations and experimental measurements using a laboratory prototype. The modeling method proposed and the results obtained can help in guiding the design of power conditioning converters for solar PV systems, as well as other similar structures for energy conversion systems.

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Section: Small-signal Model Of the Dc-dc Quadratic Boost Converter Anmentioning

confidence: 67%

“…Once the MPP voltage is obtained by maximizing the PV power, the steady-state duty cycle D is determined according to (16). The expression of v i (DT) that appears in (39) can be obtained from (37) in steady-state:…”

Section: Stability Analysis Of Periodic Orbitsmentioning

confidence: 99%

Analysis of Nonlinear Dynamics of a Quadratic Boost Converter Used for Maximum Power Point Tracking in a Grid-Interlinked PV System

Aroudi

Al-Numay

García³

et al. 2018

Energies

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“…Operation between subsystems 0 and 1 presents CCM of the boost converter. The equilibrium states of the boost converter in CCM for a fixed desired duty-ratio d are, according to (2), equal to…”

Section: Operating Of the Boost Convertermentioning

confidence: 99%

“…Because of the switching dynamics, the control of power converters is very demanding and complex. For that reason, there is a need for better control algorithms and estimation and reduction of the instabilities in the converter . In this work, we propose a nonlinear model predictive controller (NMPC) for a specific type of power converters, namely, DC‐DC converters.…”

Section: Introductionmentioning

confidence: 99%

Microsecond nonlinear model predictive control for DC‐DC converters

Lekić

Hermans

Jovičić

et al. 2020

Circuit Theory & Apps

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Summary In this paper, we present a novel nonlinear model predictive control (NMPC) formulation for the transient control of a DC‐DC converter. We demonstrate that a real‐time implementation of the proposed NMPC scheme using the PANOC solver can be efficiently applied to control DC‐DC converters in the microsecond range. Moreover, an embedded, code‐generated version of PANOC can be implemented using microcontrollers or digital signal processors. The algorithm is incorporated in the transient simulator of PWM DC‐DC converters, and the operation of the simulator on the boost converter's example is presented, comparing the performance of our NMPC‐controller with that of a classical PID controller. The operation of the boost converter controlled using the proposed NMPC algorithm is validated experimentally.

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“…Hence, accurate techniques to predict and avoid their occurrence in PV applications is essential in order to maximize the efficiency of the overall system. A variety of different control algorithms for DC‐DC converters have been proposed in the literature to avoid such undesirable behavior 12‐15 …”

Section: Introductionmentioning

confidence: 99%

Application of the Filippov Method to PV‐fed DC‐DC converters modeled as hybrid‐DAEs

Hayes

Condon

Giaouris

2020

Engineering Reports

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In this article, a method to study the nonlinear dynamics of a PV-fed boost converter is developed. The model for the solar panel introduces an algebraic constraint into the system and the resulting mathematical model is a set of hybrid differential algebraic equations (DAEs). The behavior of the system is observed to exhibit undesired operation as parameter values vary. Conventional mathematical tools developed to analyze DC-DC converters are not directly applicable to systems modeled as a set of hybrid DAEs. In order to find the monodromy matrix to assess the eigenvalues of the system, we modify the Filippov method to calculate the saltation matrix. The derived formula is general and versatile such that it can be applied to any PV-fed DC-DC converter irrespective of the topology or control algorithm employed. Two case studies are investigated: current mode control and maximum power point tracking. Each case study serves to demonstrate different considerations that must be taken into account when conducting stability analysis of hybrid-DAEs. K E Y W O R D S DC-DC converters, hybrid differential algebraic equations, maximum power point tracking, nonlinear dynamics, photovoltaic, saltation matrix This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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Nonaveraged control‐oriented modeling and relative stability analysis of DC‐DC switching converters

Cited by 7 publications

References 42 publications

Analysis of Nonlinear Dynamics of a Quadratic Boost Converter Used for Maximum Power Point Tracking in a Grid-Interlinked PV System

Analysis of Nonlinear Dynamics of a Quadratic Boost Converter Used for Maximum Power Point Tracking in a Grid-Interlinked PV System

Microsecond nonlinear model predictive control for DC‐DC converters

Application of the Filippov Method to PV‐fed DC‐DC converters modeled as hybrid‐DAEs

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