Introduction

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CPSS Transactions on Power Electronics and Applications is sponsored and published by China Power Supply Society and technically co-sponsored by IEEE Power Electronics Society. It publishes original and high-quality peer-reviewed papers in the field of power electronics and its applications. With the goal of promoting the technology of power electronics including concepts, theory, modeling and control, analysis and simulation, emerging technology and applications, CPSS TPEA is expected to be a favorable platform to strengthen information exchange in this area. All accepted papers will be published in IEEE Xplore(Early-Access and Published Issue)and be indexed in Ei Compendex and Scopus.

SCOPE
    • Switching Power Supply: DC/DC Converter, Power Factor Correction Converter

    • Inverter and Control: DC/AC Inverter, Modulation and Control

    • Power Devices and Applications: Si, SiC and GaN Devices

    • Magnetics, Passive Integration, Magnetics for Wireless and EMI

    • Control, Modeling, Simulation, System Stability and Reliability

    • Conversion Technologies for Renewable Energy and Energy Saving

    • Power Electronics Applied to Transmission and Distribution Systems

    • Power Electronics Applied to Electric Vehicles and Railway Systems

    • Power Electronics Applied in Lighting and Consumer Electronics


Call for Papers

With the goal of promoting the technology of power electronics, CPSS TPEA is expected to be a favorable platform to strengthen information exchange in this area through publishing and disseminating research findings worldwide. Authors are cordially invited to submit your papers through the website.

The objective of this journal is to finish the 1st round review within 6 weeks from submission.

Current Issue

CPSS TPEA Vol.10 No.1 (March 30, 2025)


Regular Papers

Dynamic Estimation of Load-Side Equivalent Inertia by Using Clustering Method

Y. Li, S. Guo, G. Ma, Z. Li, J. Yang, and Z. Chen

Abstract With the increasing share of renewable energy and power electronics, the power system is gradually showing the characteristics of low inertia and spatial distribution. This transition deteriorates system’s frequency response and poses a major threat to system stability. The majority of research in this area investigates the methods of providing inertia from the supply side. However, the load response also plays a crucial role in determining the frequency response. Hence, in depth knowledge about the amount of inertia provided by load is extremely important for a future application of units supplying synthetic inertia. In order to accurately grasp the load inertia level, a data-driven equivalent inertia aggregation estimation method is proposed. To achieve the load-side inertia aggregation estimation under different fault scenarios, a dynamic aggregating method is proposed, which uses the K-means algorithm to aggregation the grid based on load-side spectral features. Then, according to voltage dependency and rotating characteristic under disturbances, an area inertia estimation model is constructed to estimate the inertia of the aggregated area. By applying the proposed method, the accuracy of inertia estimation under multiple operating conditions is increased by considering the dynamic behaviour of inertia distribution. Finally, using the IEEE 29 buses system, the proposed method is illustrated.

 

A Generalized Partial Fault-Tolerant Single-Phase Common-Ground Multilevel Inverter for PV System

S. Agrawal, M. Sahoo, S. K. Kuncham, and Y. P. Siwakoti

Abstract The common ground multilevel inverter (MLI) is highly appreciated in transformerless photovoltaic (PV) systems, hich have improved leakage current performance and reduced filter size. The fault-tolerant (FT) capability is essential in a common ground inverter to enhance the reliability of the system. This paper highlights a FT strategy for single-phase common ground MLI under different open switch fault conditions. The proposed circuit can self-balance the voltage across the switched capacitor (SC) in normal and switch open circuit (OC) fault conditions. Moreover, the employed modulation scheme enables the SCs to be connected in series or parallel to obtain a wide range of output voltages with reduced input voltage. Further, the circuit can be extended for higher voltage levels by adding SC cells. A detailed Markov reliability and cost function assessment highlights the merits of the proposed inverter over counter topologies. Finally, the inverters operational feasibility and effectiveness are validated through 500 W prototype experimentally.

 

An Innovative Islanding Detection Algorithm for Grid-Tied Inverter Utilizing In-Circuit Magnetic Characteristics of Inductors in LCL Filters

S. K. N B, S. Madichetty, C. Pannela, P. Kumar, and M. Shaik

Abstract Unintentional islanding in grid-connected photovoltaic inverters (GCPVI) poses a significant challenge to power system reliability and safety. This article introduces a novel islanding detection method that leverages the magnetic characteristics of the GCPVI system. The BH curve, which defines the relationship between the magnetic flux density (B) and the magnetic field strength (H), is derived from the voltage across the inverter-side and grid-side inductors, and the current flowing through them. These BH curves are obtained for each cycle of the measured signals and analysed over successive cycles to calculate the alienation coefficient and cumulative index. The computed coefficients and indices form a time series vector, referred to as the islanding index. This index is compared against a threshold to detect unintentional islanding, even in the non-detection zone (NDZ). The proposed algorithm is experimentally validated on a single-phase hardware-based grid-connected inverter driven by bipolar pulse-width modulation. The Measured voltage and current samples of the both side inductors are transmitted to a micro controller for real-time analysis. Using these samples, the method effectively distinguishes islanding from non-islanding events, such as load switching and distributed generation (DG) tripping, within a shorter time frame, adhering to international standards.

 

Design and Laboratory Validation of a Grid-Interfaced Totem-Pole PFC Converter with PR Controller and Isolated Phase Modulated Converter for Solar-Powered Next-Gen EV Charging System

K. K, P. Koothu Kesavan, N. Harischandrappa, and V. B.

Abstract This paper proposes a stationery reference frame proportional-resonant (PR) controller for current control of grid-tied converters in an EV charger application. Since it is a viable alternative to rotational reference frame PI compensators in AC applications, the PR controller has been adopted for achieving zero steady state error without using any computationally intensive reference frame transformations. In this paper, a method to design the structure of PR controller and its coefficients according to the desired transient behaviour of AC signal amplitude in PFC converter current loop has been proposed. The importance of suggested PR controller design method is that the grid current magnitude is varying constantly based on the available PV power and battery charger levels which necessitates the controller to act in desired transient behaviour. So, by this way the impact of variation in system parameters have been completely overcome by operating the converter controllers appropriately in a solar powered EV charger system. To verify the effectiveness of the proposed controller design, extensive simulations and experimental studies are performed in a 1.5 kW EV charger system under various PV irradiances and charger power levels. The experimental results obtained from the laboratory prototype confirms the simulation findings.

 

A Novel Topology and Modulation Strategy for the High-Gain Hybrid Active Neutral-Point-Clamped Three-Level Inverter

C. Hou, D. Jia, C. Qin, and X. Li

Abstract The hybrid active neutral-point-clamped (HANPC) three-level inverter (TLI) has the advantage of high efficiency and low cost due to the partial use of SiC devices. However, the magnitude of ac output voltage cannot exceed that of DC input voltage, which limits its application field. This paper puts forward a novel topology and modulation method of the high-gain HANPC TLI. The proposed topology combines the advantages of reduced count of SiC MOSFETs and single-stage boosting ability. To further improve system efficiency, a novel modulation method is designed, in which the SiC MOSFETs and Si IGBTs are operated in high frequency and fundamental frequency, respectively. To realize the function of voltage boosting without affecting the normal AC output voltage, the upper-shoot-through (UST) and lower-shoot-through (LST) states are inserted within the dwell times of small vectors. Moreover, the neutral point (NP) voltage balance is actively controlled by introducing a distribution factor to regulate duty cycle of redundant small vectors, which improve system reliability. Experimental tests verify the performance of the proposed topology and strategy.

 

Graph Theory-Based Sneak Circuit Time-Domain Analysis and Trigger of CLLC Resonant Converter With Parasitic Parameters

C. Wei, X. Zhu, K. Jin, and Y. Wu

Abstract The sneak circuits caused by internal parasitic parameters can lead to unexpected phenomena and affect the efficiency and reliability of CLLC resonant converter. Therefore, the characteristic analysis, trigger mechanism and suppression method of CLLC converter sneak circuit based on graph theory are proposed in this paper. The complete current based sneak circuit model and accurate CLLC time domain model are established. Then, the possible sneak circuit phenomena are described in detail to explain their negative effects on the converter operating characteristics, the trigger mechanism of sneak operating modes is put forward, and the suppression conditions are derived. By optimizing the parameter design and modulation parameters of CLLC converter, the unexpected sneak circuits can be avoided. Finally, the correctness of theoretical analysis is verified by experiment results, and the proposed suppression method avoids unnecessary power loss and suppresses the waveform oscillations.

 

Comparative Study of CCPS Based on Permanent Magnet and Electrically Excited HIA for Selecting Rational Topological Structure

L. Liu, K. Yu, X. Xie, and Z. Liu

Abstract In order to facilitate the selection of an optimal topological structure for rational pulsed capacitor charging power supplies (CCPS), this paper presents a comparative analysis of CCPS based on permanent magnet excited (PME) and electrically excited (EE) homopolar inductor alternators (HIA). The findings indicate that the d-axis transient inductance of the PME HIA is marginally greater than that of the EE HIA, a result that contradicts initial expectations. Notably, the PME HIA does not require consideration of transient flux variations, whereas the EE HIA does. The study establishes relationships among the enhancement of charge performance, efficiency, capacitance, frequency, and field winding (FW) resistance. It is observed that as capacitance, frequency, and FW resistance increase, there is a corresponding improvement in charge performance. The equipotential line representing the enhancement of charge performance approximates an inverse proportional function, suggesting that if the product of FW resistance and capacitance, or the product of FW resistance and frequency, remains constant, the improvement in charge performance will also be constant. Furthermore, it is noted that as capacitance and frequency increase, the improvement in efficiency diminishes, which is contrary to the trend observed in charge performance. To comprehensively evaluate the enhancement of charge performance and efficiency, a weighted function is proposed. This function aids in the selection of a rational topological structure for CCPS, distinguishing between those based on PME HIA and those based on EE HIA. Based on the results derived from the weighted improvement analysis, appropriate topological structures for CCPS can be identified according to varying capacitance, frequency, and FW resistance. Specifically, when the product of capacitance and FW resistance, or the product of frequency and FW resistance, is substantial, the PME HIA is recommended; conversely, the EE HIA is preferred in other scenarios.

 

Driving Range Extension of a PV Array Fed Anti-Windup and MTPA Controlled PMaSyRM Drive for LEV With Regeneration

S. Kumar, S. Kumar, and S. Kurm

Abstract This paper presents a permanent magnet assisted synchronous reluctance motor driven light electric vehicle integrated with solar photovoltaic (SPV) panels and battery storage. The proposed system leverages regenerative braking and energy harvesting from rooftop mounted SPV to extend the driving range, contributing significantly to green mobility. A bidirectional DC-DC converter (BDDC) is employed to facilitate energy flow between the battery and the motor drive in either direction. During regenerative braking, the kinetic energy of the PMaSyRM drive-based vehicle is converted into electrical energy. This recovered energy is injected into the battery, effectively charging the battery. This process not only extends the driving range of the vehicle but also minimizes energy loss, thereby enhancing overall efficiency. The conditional integrator-based anti-windup technique is employed for the speed control of LEV, which eliminates the problem of ringing and overshooting during the speed transitions. For better torque control of the PMaSyRM, maximum torque per ampere (MTPA) technique is used. Based on the torque command, MTPA technique produces set of current commands to minimize the magnitude of current vector. Constant voltage, current and torque curve study of the PMaSyRM assures that current and voltage of the drive remains in the safe limit.

 

Study on Composite Structure of Tian-Font Magnetic Shielding and Anti-Series Active Coils for Wireless Power Transfer System

Z. Li, W. Zhang, Z. Gan, and B. Li

Abstract In the wireless power transfer (WPT) system of electric vehicles, conventional magnetic shielding techniques usually rely on a large number of magnetic cores and aluminum plates, posing a cost challenge. To address this issue, this paper proposes a composite structure of Tian-font magnetic shielding and antiseries active coils to minimize material use while maintaining safe magnetic leakage levels. First, a calculation method of the magnetic field is introduced to analyze magnetic leakage in the target region of the system, providing a theoretical basis for optimization. Secondly, a composite shielding structure is introduced, its working principle is analyzed in detail and its circuit model is derived. Subsequently, a method for optimizing coil parameters is presented, and the optimal coil and shielding material parameters are determined. Finally, a WPT system based on this structure is built and verified through simulation and experiment. Results show that under a transmission power of 4 kW, the maximum magnetic leakage in the target region before and after offset is lower than 27 µT and the transmission efficiency is more than 93%. Compared to the same size, non-gouged magnetic shield structure, it saves 36.78% of the magnetic core and 32.52% of the aluminum plate.


Developed Wide-Band Frequency Transformer Model for Conducted Common Mode Characteristics Prediction

K. Fu, J. Tu, W. Chen, and L. Huang

Abstract Isolated power converters are widely used for its safety and flexible adjustment between input and output voltage range. EMI occurs due to the presence of switching process. The existence of parasitic parameters in transformers causes the work of EMI prediction in isolated DC-DC power converters more complicated. Parasitic parameters in transformer are the crucial propagation paths for CM noise conduction. For improving the accuracy of EMI prediction, this paper developed a wide-band frequency transformer model based on the two-capacitance model, further considering both the effect capacitive and inductive coupling on conductive common mode noise. Furthermore, the influence of permeability versus frequency of Mn-Zn ferrite on CM transmission, is investigated in detail. Two-port measurement is used for the validation of the proposed high frequency model. The experiment results demonstrate that the proposed wind-band frequency transformer model can well predict the CM noise behavior in the frequency range of 100 kHz to 100 MHz.


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Editor-in-Chief

Prof. LIU Jinjun

College of Electrical Engineering

Xi'an Jiaotong University

No.28, Xianning West Road, Xi'an,

Shaanxi, 710049, China

jjliu@mail.xjtu.edu.cn



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  • China Power Supply Society (CPSS)
  • IEEE Power Electronics Society (IEEE PELS)
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  • IEEE Trans. on Power Eletronics (IEEE TPEL)
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