Your search keyword '"power electronics"' showing total 54,253 results

1. Analytical model and experimental validation of critical dependency of pGaN gated AlGaN/GaN enhancement-mode high electron mobility transistor characteristics on trap-assisted tunneling.

Author

Jeyakumar, Ranie S., James, J. J., Ganguly, Swaroop, and Saha, Dipankar

Subjects

*MODULATION-doped field-effect transistors, *TWO-dimensional electron gas, *ENERGY levels (Quantum mechanics), *FERMI energy, *POWER electronics

Abstract

Enhancement-mode GaN-based high electron mobility transistors are essential for switching applications in power electronics. A heavily Mg-doped pGaN region is a critical feature of these devices. It pulls the Fermi energy level toward its valence band, depleting the two-dimensional electron gas region at the AlGaN/GaN interface at equilibrium. While a step profile of Mg doping in the pGaN region is desirable, it is difficult to achieve due to the out-diffusion of Mg-dopants, and the barrier AlGaN layer becomes unintentionally p-doped. This p-doping primarily leads to traps in the AlGaN barrier, leading to gate current through trap-assisted tunneling (TAT) and degradation of mobility due to the diffusion of the Mg-dopants to the channel region. The contribution of holes in the channel region and mobility degradation on the transistor characteristics are well understood. Here, we report the effect of TAT, which requires an improved understanding as it determines the key gate characteristics and transistor behavior. An increased TAT current increases the gate current and degrades the sub-threshold slope, which deteriorates transistor characteristics. However, TAT current makes the surface potential less sensitive to the change in gate voltage in the subthreshold regime, resulting in an increased transistor threshold voltage. Hence, an increase in the threshold voltage from the TAT current improves the fail-safe operation required for power-electronic applications. We show that the gate current and threshold voltage need to be tuned together for the desired performance of the enhancement-mode transistors. [ABSTRACT FROM AUTHOR]

Published

2024

2. Significantly enhancing the through-plane thermal conductivity of epoxy dielectrics by constructing aramid nanofiber/boron nitride three-dimensional interconnected framework.

Author

Ren, Jun-Wen, Zeng, Rui-Chi, Yang, Jun, Wang, Zi, Wang, Zhong, Zhao, Li-Hua, Wang, Guo-Long, and Jia, Shen-Li

Subjects

*BORON nitride, *PERMITTIVITY, *DIELECTRIC loss, *POWER electronics, *THERMAL conductivity

Abstract

Epoxy dielectrics with high through-plane thermal conductivity (λ) hold great promise for applications in the thermal management of advanced power electronics. Intensive attempts have been made to improve the λ of epoxy by filling with boron nitride nanosheets (BNNSs). However, it remains a great challenge to achieve a satisfactory increased λ by a small amount of BNNS loading. Herein, we reported a new strategy to prepare epoxy dielectrics with internal three-dimensional phonon transport channels by vacuum freeze-drying and vacuum impregnation. Aramid nanofibers (ANFs) and BNNSs were used for the collaborative construction of a vertical interconnected thermal framework. The resultant ANF-BNNS/epoxy achieved a high through-plane λ of 0.87 W m−1 K−1 at only 1.43 vol. % BNNS, which is ∼17.1% higher than that of the BNNS/epoxy counterpart with even 18.34 vol. % randomly distributed BNNS. The increasing efficiency of λ of epoxy by ANF-BNNS is tenfold more than that of the conventional blending methods. In addition, the ANF-BNNS/epoxy composite also exhibits a low dielectric constant and low dielectric loss. The findings of this study offer an inspired venue to develop high-performance thermally conductive epoxy dielectrics with a minimal BNNS loading. [ABSTRACT FROM AUTHOR]

Published

2024

3. A novel approach for improving the magnetic properties and reducing the power loss of FeSi3.5 composite at 200–500 kHz band.

Author

Wu, Peng, Cui, Jinghao, Wang, Ke, Hang, Yuandong, Sheng, Yanfei, Qiao, Liang, Wang, Tao, and Li, Fashen

Subjects

*EDDY current losses, *MAGNETIC flux density, *MAGNETIC properties, *POWER electronics, *FREQUENCY stability

Abstract

The easy-plane FeSi3.5 composite with excellent magnetic properties and power loss is proposed. The magnetic properties and power loss of the easy-plane FeSi3.5 composite are studied by using the none easy-plane FeSi3.5 composite as a control. This easy-plane FeSi3.5 composite has an initial permeability of 62, resonance frequencies of 100 MHz and 1.5 GHz, and frequency stability of 40 MHz. In addition, the easy-plane FeSi3.5 composite has also excellent loss properties, with a high-frequency power loss of only 108.12 kW/m3. The three kinds of power loss of the easy-plane FeSi3.5 composite are reduced compared with the none easy-plane FeSi3.5 composite through loss separation, especially the eddy current loss and the excess loss. The eddy current loss and the excess loss of the easy-plane FeSi3.5 composite are only 0.03 and 12.93 kW/m3 at 500 kHz, which reduce by 99.44% and 92% compared with the none easy-plane FeSi3.5 composite. Effective reduction of power loss and significant improvement of magnetic properties are important for solving the problem of power loss encountered by power electronic devices at the kHz band. Therefore, the application of the easy-plane FeSi3.5 composite with excellent power loss and high-frequency magnetic properties becomes a novel approach to meet the practical application of power electronics. The method that increases the working frequency and decreases the maximum magnetic flux density keeping the energy transformation efficiency constant is a new method to reduce power loss at the wide frequency band. [ABSTRACT FROM AUTHOR]

Published

2024

4. Status of h-BN quasi-bulk crystals and high efficiency neutron detectors.

Author

Alemoush, Z., Tingsuwatit, A., Maity, A., Li, J., Lin, J. Y., and Jiang, H. X.

Subjects

*NEUTRON counters, *THERMAL neutrons, *CRYSTAL growth, *CRYSTALS, *NEUTRON capture, *POWER electronics, *SCINTILLATORS

Abstract

III-nitrides have fomented a revolution in the lighting industry and are poised to make a huge impact in the field of power electronics. In the III-nitride family, the crystal growth and use of hexagonal BN (h-BN) as an ultrawide bandgap (UWBG) semiconductor are much less developed. Bulk crystals of h-BN produced by the high-temperature/high-pressure and the metal flux solution methods possess very high crystalline and optical qualities but are impractical to serve as substrates or for device implementation as their sizes are typically in millimeters. The development of crystal growth technologies for producing thick epitaxial films (or quasi-bulk or semi-bulk crystals) in large wafer sizes with high crystalline quality is a prerequisite for utilizing h-BN as an UWBG electronic material. Compared to traditional III-nitrides, BN has another unique application as solid-state neutron detectors, which however, also require the development of quasi-bulk crystals to provide high detection efficiencies because the theoretical efficiency (ηi) relates to the detector thickness (d) by η i = 1 − e − d λ , where λ denotes the thermal neutron absorption length which is 47 μm (237 μm) for 10B-enriched (natural) h-BN. We provide an overview and recent progress toward the development of h-BN quasi-bulk crystals via hydride vapor phase epitaxy (HVPE) growth and the attainment of thermal neutron detectors based on 100 μm thick 10B-enriched h-BN with a record efficiency of 60%. The thermal neutron detection efficiency was shown to enhance at elevated temperatures. Benchmarking the crystalline and optical qualities of h-BN quasi-bulk crystals with the state-of-the-art mm-sized bulk crystal flakes and 0.5 μm thick epitaxial films identified that reducing the density of native defects such as vacancies remains the most critical task for h-BN quasi-bulk crystal growth by HVPE. [ABSTRACT FROM AUTHOR]

Published

2024

5. Modeling of polarization reversal-induced interface sheet charge in wurtzite-type AlScN/GaN heterostructures.

Author

Yassine, M., Yassine, A., Nair, A., Sundarapandian, B., Afshar, N., Kirste, L., Fichtner, S., and Ambacher, O.

Subjects

*HETEROSTRUCTURES, *GALLIUM nitride, *POWER electronics, *CRYSTAL lattices, *WURTZITE, *BORON nitride, *ZINC oxide films, *SPHALERITE

Abstract

In this work, the value and the polarity of the spontaneous and piezoelectric polarization have been investigated, as the use of two different reference structures for wurtzite-type group-III nitrides, namely, the zinc-blende and the layered-hexagonal crystal lattice, have resulted in different predictions. It was found that although the differences in value and polarity of the polarization for heterostructures such as wurtzite Al1−xScxN/GaN lead to similar interface sheet charges, a significant mismatch is observed when polarization reversal is considered. The interface sheet charge predicted before and after the polarization reversal in the wurtzite Al1−xScxN layer on GaN using the zinc-blende lattice as a reference predominantly shows a change in sign. When using the layered-hexagonal lattice as a reference, not only is the same polarity of the interface sheet charge maintained after polarization reversal, but it is even 30 times larger. In this case, the giant and positive spontaneous polarization values for metal-polar Al1−xScxN extracted from the ferroelectric switching, as well as the alignment of the piezoelectric polarization to it, were observed to be consistent with the predictions referenced to the layered-hexagonal lattice. Thus, it is concluded that the layered-hexagonal reference is not only more suitable for predicting the ferroelectric properties of wurtzite Al1−xScxN but should also be the correct reference when considering polarization reversal in heterostructures. If the significant increase in the interface sheet charge after polarization reversal is experimentally detected, it will allow the design and fabrication of novel devices for future high-frequency and power electronics applications. [ABSTRACT FROM AUTHOR]

Published

2024

6. Scheduling Electric Currents in Converter-Dominated Power Grids with Time-Slotted Energy Packets

Author

Schneider, Klemens, Schulz, Dominik, Helmig, Daniel, Wiegel, Friedrich, Hagenmeyer, Veit, Hiller, Marc, Zitterbart, Martina, Goos, Gerhard, Series Editor, Hartmanis, Juris, Founding Editor, Bertino, Elisa, Editorial Board Member, Gao, Wen, Editorial Board Member, Steffen, Bernhard, Editorial Board Member, Yung, Moti, Editorial Board Member, Jørgensen, Bo Nørregaard, editor, Ma, Zheng Grace, editor, Wijaya, Fransisco Danang, editor, Irnawan, Roni, editor, and Sarjiya, Sarjiya, editor

Published

2025

7. Numerical characterizations of the thermomechanical response of power modules with ceramic substrates and lead-free bonds

Author

Gharaibeh, Mohammad A. and Wilde, Jürgen

Published

2024

8. Robust sliding mode control for the MMC‐HVDC transmission system with SCR uncertainty.

Author

Gharaghani, Farzin and Asadi, Mehdi

Abstract

Modular multilevel green converter based high voltage direct current (MMC‐HVDC) transmission system has become a practical solution to interconnect renewable energy sources to main AC grids. Connecting the MMC to a weak AC system is still a challengeable problem. This paper proposes a sliding mode control‐based method for the MMC. By considering short circuit ratio parameter of the AC grid as uncertainty, a suitable mathematical model is developed. Also, relations among control parameters and their validity conditions are obtained. The proposed control scheme has faster dynamic responses to uncertainty and external disturbances compared to the conventional vector current control method with proportional–integral controller. At last, simulation results in the MATLAB/SIMULINK software environment are presented that the proposed control scheme is effective. [ABSTRACT FROM AUTHOR]

Published

2024

9. Design and implementation of a solar power optimizer for module level power electronics application.

Author

Allahverdinejad, Babak, Ajami, Ali, and Banaei, Mohamad Reza

Abstract

Partial shading on series‐connected photovoltaic (PV) panels in conventional PV systems results in lower harvested power. To resolve this, it is vital to utilize module level power electronics (MLPE) such as Solar Power Optimizers (SPOs). This paper introduced a non‐isolated common ground non‐inverting output voltage buck‐boost converter as an SPO. Proposed converter benefits from continuous input and output currents which has a significant role in designing SPOs. Having a quadratic gain, beside acceptable step‐down range are other features of the converter. Operating principle, design, steady‐state, small‐signal analysis, and dynamic performance of proposed converter are included. Proposed converter is compared with other buck‐boost converters in terms of voltage gain, voltage stresses, continuous input and output current, and output polarity. To validate the performance of introduced converter, experimental results for a prototype with input voltage 24 V, output voltage 72 V for step‐up and 15 V for step‐down modes are given and results are examined. The maximum efficiency of the prototype is 93% and 89% for step‐up and step‐down modes, respectively. To evaluate the effect of proposed SPO for extracting maximum available power from PVs, simulation results of a grid connected PV system with two series connected SPOs is discussed. [ABSTRACT FROM AUTHOR]

Published

2024

10. Analysis and control design for input‐series output‐parallel multi‐channel inductive power transfer system.

Author

Wang, Leyu, Sun, Pan, Liang, Yan, Wu, Xusheng, Deng, Qijun, and Rong, Enguo

Abstract

To realize high‐power inductive power transfer (IPT) for fast charging of electric vehicles (EVs), an input‐series output‐parallel (ISOP) multi‐channel IPT system is analysed in this paper, and an output control strategy based on single neuron controller is proposed to improve the stability of the system. Firstly, the steady‐state operating conditions of ISOP‐IPT system is analysed based on different compensation networks which shows that the constant‐voltage‐output compensation networks are more suitable for the proposed circuit structure. Then, to improve the voltage equalization between channels, an open‐loop control method combining parameter design and phase‐shift control is proposed against different coil misalignments. At the same time, based on the single neuron controller, the system output closed‐loop control is realized without the need of accurate system modelling. Finally, a three‐channel ISOP‐IPT experimental system was constructed, which operated stably at 2.9 kW with a power efficiency of 93.38%. The system closed‐loop control with control time of 22 ms is realized. The voltage equalization control offset is less than 1%. [ABSTRACT FROM AUTHOR]

Published

2024

11. A non‐isolated single‐input dual‐output DC–DC boost converter with high‐voltage gain.

Author

Abbasi, Saeed and Nahavandi, Ali

Abstract

This paper presents a new structure of a high step‐up DC–DC converter. The proposed converter has one input and two outputs with different voltage levels, suitable for applications that require multiple voltage levels such as photovoltaic systems, electric vehicles and DC microgrids. The proposed converter is expandable to more outputs and has a higher voltage conversion ratio compared to similar converters. The operational modes of the proposed converter are investigated and the conversion ratio of the converter is obtained. Additionally, small‐signal equations of the converter are derived, and using state‐space matrices, transfer functions of the converter are obtained and the controller is designed. Also, the proposed converter is compared with similar converters and power losses equations of the converter are derived. To investigate the converter's performance, simulations are done using MATLAB/Simulink software. Moreover, to validate the theoretical analysis, a laboratory prototype is implemented. The obtained results confirm the operation of the proposed converter. [ABSTRACT FROM AUTHOR]

Published

2024

12. High efficiency three‐dimensional wireless power transfer system using cylindrical transmitting coil.

Author

Ma, Qingfeng, Xu, Jiayi, Pang, Shui, Liu, Yehao, Li, HongYu, and Li, Xingfei

Abstract

Three‐dimensional (3D) wireless power transfer (WPT) is an attractive methodology to improve the charging safety and flexibility of portable electronic equipment and to meet the charging demand brought by the increase of electronic equipment. Herein a 3D WPT system using a cylindrical transmitting coil excited by a single power source is proposed to improve flexibility and efficiency. Specifically, the coil size is designed and the circuit model is analyzed. A method for determining inductor parameters of Inductor‐Capacity‐Capacity compensation is designed to achieve high efficiency. The power transmission performance of the WPT system is validated through an experimental platform. The measured maximum power is more than 50 W, and the maximum DC‐DC efficiency is up to 82.3%. The system can simultaneously charge multiple loads with different receiving coils at different positions. The proposed WPT system can improve the flexibility of equipment charging without control, and provide a reference for the design of portable equipment high efficiency wireless chargers. [ABSTRACT FROM AUTHOR]

Published

2024

13. Threshold voltage instability of SiC MOSFETs under very‐high temperature and wide gate bias.

Author

Chen, Cong, Cai, Yumeng, Sun, Peng, and Zhao, Zhibin

Abstract

Threshold voltage (VTH) instability affects the reliability of silicon carbide (SiC) MOSFETs. In this article, the influence of gate bias (VGS) and high temperature on VTH instability is investigated under wide VGS and very‐high temperature range (150°C to 275°C). The degradation mechanism of gate oxide under coupling of different electrical and thermal stress is revealed. When the device is subjected to +VGS, the relationship between VTH shift and temperature is not monotonic and there is a temperature turning point. This is mainly related to the capture/release and generation of electron traps. However, the VTH shift increases sharply and gate oxide breakdown for the device bias at +35 V, which is related to Fowler–Nordheim (F–N) tunnelling effect. For a large −VGS, the VTH shift is very small. Moreover, when the negative VGS decreases, the VTH shift is positively correlated with temperature, which may result from the activation and charge exchange of hole traps. However, the influence of moving ions changes the temperature dependence of VTH shift for the device bias at −30 V. Finally, the devices of different manufacturers are studied and similar change patterns are found. This finding provides guidance for the further application of SiC MOSFETs under high temperatures and different voltages. [ABSTRACT FROM AUTHOR]

Published

2024

14. A novel vehicle power line communication method based on switching ripple modulation.

Author

Zhu, He, Xie, Zhiyuan, Cao, Wangbin, Bai, Zonglong, and Hu, Zhengwei

Abstract

Power converters can perform power conversion and data transmission simultaneously. With the aim of mitigating the hardware requirements of vehicle power line communication (VPLC), a novel VPLC scheme based on switching ripple modulation (SRM) is proposed to eliminate the need for coupling circuits and specialized communication chips. By embedding data modulation techniques into traditional pulse width modulation systems, power/data multiplexing transmission is achieved by demodulating the voltage ripple on the DC bus. First, the theoretical foundation of the SRM is introduced, and power/data single carrier modulation using 2FSK and data demodulation based on the sliding discrete Fourier transform are provided. Subsequently, comprehensive analyses of the mutual influence between power conversion and communication in the buck converter are conducted. The impact of power conversion on communication primarily depends on the control loop compensation and perturbation depth. Moreover, the designs of the ripple conditioning circuit and communication frame are presented. Finally, an experimental prototype is constructed with two buck converters in parallel. The experimental results demonstrate a data transmission rate of 12.5 kbps within 3 m under steady‐state, transient input and output voltage, and transient load conditions, validating the correctness of the proposed methodology. [ABSTRACT FROM AUTHOR]

Published

2024

15. Circuit topology aware GNN-based multi-variable model for DC-DC converters dynamics prediction in CCM and DCM.

Author

Khamis, Ahmed K. and Agamy, Mohammed

Subjects

*GRAPH neural networks, *ELECTRIC circuits, *POWER electronics, *BOND graphs, *MACHINE learning

Abstract

A regression model based on graph neural network, tailored for electric circuit dynamics prediction is introduced, providing converter performance predictions on converter circuit level and internal parameter variations. Regardless of the number of components or connections present in a converter circuit, the proposed model can be readily scaled to incorporate different converter circuit topologies. Moreover, the model can be used to analyse converter circuits with any number of circuit components and any control parameters variation. To enable the use of machine learning methods and applications, all physical and switching circuit properties such as converter circuits operating in continuous conduction mode or discontinuous conduction mode are accurately mapped to graph representation. Three of the most common converters (Buck, Boost, and Buck-boost) are used as example circuits applied to model and the target is to predict the gain and current ripples in inductor. The model achieves 99.51% on the R 2 measure and a mean square error of 0.0263. [ABSTRACT FROM AUTHOR]

Published

2024

16. Grid‐forming converters in interconnected power systems: Requirements, testing aspects, and system impact.

Author

Rogalla, Soenke, Ernst, Philipp, Lens, Hendrik, Schaupp, Thomas, Schöll, Christian, Singer, Roland, and Ungerland, Jakob

Abstract

In this study, the integration of grid‐forming (GFM) converters in power systems is discussed in terms of both the fundamental aspects of system stability and the technical possibilities of converter‐based resources. The paper provides a survey and comparison of various GFM control concepts with respect to their transient and stationary behavior. A method for black box characterization and conformity testing of GFM converters is presented and relevant results of lab and field tests with GFM converters are discussed. Finally, important system aspects are addressed. This includes an approach to consider the behavior of GFM converters in distribution grid models and investigations on the minimum share of GFM units required to ensure system stability. The findings of this paper provide valuable insights for the design and implementation of GFM converters in modern converter‐based power systems. [ABSTRACT FROM AUTHOR]

Published

2024

17. Remarkably Boosted High‐Temperature Electrostatic Energy Storage of Polyetherimide Film Induced by TiO2@Au@AlOx@Au Core‐shell Nanofibers.

Author

Ren, Zengliang, Lei, Li, Zhu, Linwei, Xia, Shuimiao, Fan, Runhua, Dastan, Davoud, Cui, Hongzhi, and Shi, Zhicheng

Subjects

*COULOMB blockade, *ENERGY storage, *DIELECTRIC strength, *ENERGY density, *POWER electronics

Abstract

Polymer dielectrics have broad applications in advanced electronics and power systems. However, they suffer from low energy density and poor breakdown performance at high temperatures, limiting their applications in high‐temperature environments. Herein, TiO2@Au@AlOx@Au nanofibers with double coulomb blockade nanolayers are obtained via a physical sputtering strategy to improve the high‐temperature energy storage performance of polyetherimide composites. Experimental studies and finite elemenet phase‐field simulations demonstrate that the double‐layer coulomb blockade effect and micro‐capacitor effect of Au nanoparticles synergistically enhance the breakdown strength and dielectric permittivity of polyetherimide composite at high temperatures. Notably, the composite exhibits ultra‐high discharged energy densities of 11.33 and 9.70 J cm−3 at 150 and 200 °C, respectively, along with high charge–discharge efficiencies of 93.4% and 84%, which far exceed that of the polymer nanocomposites reported so far. Furthermore, the composite exhibits excellent charge–discharge cycling performance (>50000 cycles at 400 MV m−1) and high‐power density (1.16 MW cm−3) at 200 °C, making it an ideal candidate for high‐temperature capacitors. Hopefully, these nanofibers not only serve as excellent nanofillers for high‐temperature energy storage dielectric composites but also holds tremendous potential and inspirational significance for other applications such as electronics, biomedical fields, optics, and catalysis. [ABSTRACT FROM AUTHOR]

Published

2024

18. Substantial improvement of InGaN/GaN visible-light polarization-induced self-depletion phototransistor by thermally oxidized Al2O3.

Author

Lv, Zesheng, Peng, Tianzhi, Wang, Gang, and Jiang, Hao

Subjects

*SURFACE passivation, *POWER electronics, *INDIUM gallium nitride, *ELECTRIC insulators & insulation, *SURFACE recombination

Abstract

Atomic layer deposited (ALD) Al2O3 acting as gate dielectric and surface passivation is widely adopted in power electronics but seldom used in optoelectronic fields for its sophisticated and expensive technology. Herein, a simple but efficient Al2O3 passivation is used in the fabrication of InGaN/GaN visible-light (VL) polarization-induced self-depletion field effect phototransistors (FEPTs), for suppressing the surface leakage and recombination. The Al2O3 layer obtained by thermal oxidation (TO) of 2-nm-thick thermally evaporated metal Al shows high electrical insulation and even better passivation effect than the ALD-Al2O3. As a result, the dark current of TO-Al2O3 passivated device decreases by about 2 orders of magnitudes; meanwhile, the photoresponse increases by about 65%. Under a weak VL illumination of 6.8 μW/cm2, the InGaN/GaN FEPT exhibits a large photo-to-dark current ratio of 3.1 × 108 and an ultrahigh shot-noise-limited detectivity of 1.9 × 1018 jones. In addition, the FEPTs exhibit a strong wavelength selectivity with a 600 nm/400 nm spectral response rejection ratio exceeding 5 × 105. All these performances show huge potential in emerging VL applications that are limited by the insufficiencies of current Si photodetectors. [ABSTRACT FROM AUTHOR]

Published

2024

19. Research on assessment method of maximum distributed generation hosting capacity in distribution system with high shares of renewables and power electronics.

Author

Wan, Dai, Fan, Kailun, He, Jingyu, Zhang, Haochong, Yang, Gexing, and Duan, Xujin

Subjects

*POWER electronics, *ELECTRICAL load, *ELECTRIC power distribution grids, *RESEARCH methodology, *ALGORITHMS

Abstract

With the rapid development of distributed generation (DG) within the framework of modern power systems, accurately assessing the maximum DG hosting capacity in distribution networks is crucial for ensuring the safe and stable operation of the power grid. This paper first introduces an assessment model of maximum DG hosting capacity in distribution network based on optimal power flow (OPF). Then, a two-step method that combines the linearization method and the recursive method is proposed, which consists of two parts: firstly, using linearization method to quickly calculate the preliminary assessment value of maximum DG hosting capacity, and then using a recursive method to accurately correct the preliminary assessment value. Additionally, the proposed improved comprehensive sensitivity index and safety constraint verification method can enhance the computational efficiency and accuracy of the recursive algorithm. Finally, the proposed methods were simulated and validated on the IEEE 33-bus system. [ABSTRACT FROM AUTHOR]

Published

2024

20. Substantial improvement of InGaN/GaN visible-light polarization-induced self-depletion phototransistor by thermally oxidized Al2O3.

Author

Lv, Zesheng, Peng, Tianzhi, Wang, Gang, and Jiang, Hao

Subjects

SURFACE passivation, POWER electronics, INDIUM gallium nitride, ELECTRIC insulators & insulation, SURFACE recombination

Abstract

Atomic layer deposited (ALD) Al2O3 acting as gate dielectric and surface passivation is widely adopted in power electronics but seldom used in optoelectronic fields for its sophisticated and expensive technology. Herein, a simple but efficient Al2O3 passivation is used in the fabrication of InGaN/GaN visible-light (VL) polarization-induced self-depletion field effect phototransistors (FEPTs), for suppressing the surface leakage and recombination. The Al2O3 layer obtained by thermal oxidation (TO) of 2-nm-thick thermally evaporated metal Al shows high electrical insulation and even better passivation effect than the ALD-Al2O3. As a result, the dark current of TO-Al2O3 passivated device decreases by about 2 orders of magnitudes; meanwhile, the photoresponse increases by about 65%. Under a weak VL illumination of 6.8 μW/cm2, the InGaN/GaN FEPT exhibits a large photo-to-dark current ratio of 3.1 × 108 and an ultrahigh shot-noise-limited detectivity of 1.9 × 1018 jones. In addition, the FEPTs exhibit a strong wavelength selectivity with a 600 nm/400 nm spectral response rejection ratio exceeding 5 × 105. All these performances show huge potential in emerging VL applications that are limited by the insufficiencies of current Si photodetectors. [ABSTRACT FROM AUTHOR]

Published

2024

21. Local adaptive insulation in amorphous powder cores with low core loss and high DC bias via ultrasonic rheomolding.

Author

Li, H. Z., Yan, Y. Q., Cai, W. S., Li, L. Y., Yan, A., Liu, L. H., Ma, J., Ke, H. B., Li, Q., Sun, B. A., Wang, W. H., and Yang, C.

Subjects

COOPERATIVE binding (Biochemistry), POWER electronics, SMART structures, STRAINS & stresses (Mechanics), MAGNETIC properties

Abstract

Amorphous powder cores are promising components for next-generation power electronics. However, they present inherent challenges of internal air gaps and stresses during cold compaction, which significantly deteriorate soft magnetic properties. Here, we report the formation of a local adaptive insulation structure of biconcave lens in amorphous powder cores by ultrasonic rheomolding. Consequently, compared with conventional cold-compacted powder cores, the ultrasonic rheomolded powder cores offer significant simultaneous improvements in the permeability from 31.3–32.4 to 41.8–43.3 and the direct-current bias performance from 69.4–69.7% to 87.4–87.8% (7960 A/m), thereby overcoming the trade-off between permeability and direct-current bias performance. In particular, their core losses are as low as 13.73–15.45 kW/m3, approximately one twentieth of that of the cold-compacted powder cores (282.84–304.03 kW/m3) at a magnetic field of 100 mT and 100 kHz. The biconcave-lens insulation structure can effectively buffer the impact of high mechanical stress on the magnetization of magnetic powder particles, allowing for the ultrasonic rheomolded powder cores to maintain better magnetization efficiency and consequently resulting in excellent soft magnetic properties under the cooperative effect of very low internal stresses and low porosity. The ultrasonic rheomolded powder cores can be used as alternative core components in next generation miniaturized power electronics. Amorphous powder cores with superior soft magnetic properties are promising components for next-generation power electronics. Here, authors introduce an ultrasonic rheomolding method to modulate a local adaptive insulation in amorphous powder cores, which induces low core loss and high DC bias. [ABSTRACT FROM AUTHOR]

Published

2024

22. A high gain quasi Z‐source based full‐bridge isolated DC‐DC converter with extendable structure for grid‐tied/standalone PV system.

Author

Nallaiya Gounder, Kanagaraj, Murugesan, Ramasamy, Madhaiyan, Vijayakumar, and Aldosari, Obaid

Subjects

ELECTRIC power production, PHOTOVOLTAIC power generation, PHOTOVOLTAIC power systems, RENEWABLE energy sources, POWER electronics

Abstract

A multi‐input single‐output converter that is based on the impedance network and the standard isolated converters is presented. The topology is named quasi Z‐source full‐bridge isolated converter (qZSFBIC). The proposed topology helps to integrate various renewable power generation systems with a common three‐phase grid‐connected inverter. It was also capable of providing isolation between the input and output circuits in addition to the boost function. The integration of multiple energy sources is achieved using fewer components than conventional converters. As a result, it achieves greater conversion efficiency and has improved circuit characteristics. It offers a larger voltage control range as compared to the conventional ZSC and enhances the input‐output voltage transformation ratio. To determine whether or not the suggested converter is technically feasible, the circuit architecture, operating principle, control mechanism, and simulation results are presented. An improved proportional resonant‐second order general integrator (IPR‐SOGI) has been utilized to provide a gating signal for the voltage source inverter. The 1.5 kW, 400 V, 50 Hz model is designed to authenticate the proposed scheme with qZSFBIC. The results showed that the proposed converter offered double the time of boosting than the conventional ZSC converter and the conversion efficiency is around 89%. [ABSTRACT FROM AUTHOR]

Published

2024

23. Dynamic weighting factor assignment method for the predictive control of electrical drives.

Author

Bándy, Kristóf and Stumpf, Péter

Subjects

POWER electronics, ELECTRIC drives, IDEAL sources (Electric circuits), INDEPENDENT variables, PREDICTION models

Abstract

This article presents an innovative approach for real‐time allocation of weighting factor values in model predictive control of electrical drive systems. In the proposed dynamic weighting factor assignment method, the cost associated with a specific variable is determined based on its corresponding set of predictions. This approach can be employed to optimize weighting factor values for a given system or even enhance performance metrics in comparison to conventional approaches that employ fixed weighting factors. Furthermore, the method determines the optimal value of weighting factors in real‐time with low added calculation complexity. The proposed method is able to provide reliable constant weighting factors for a given working point as well. The practical application of this method is demonstrated through a case study of an LC filter equipped PMSM drive; the system encompasses six independent variables that require regulation. Experimental results utilizing both two and three level voltage source inverters and using various transient and steady‐state situations prove the feasibility of the proposed dynamic weighting factor assignment method. [ABSTRACT FROM AUTHOR]

Published

2024

24. Two efficient three‐mode control strategies for four‐switch buck‐boost converters.

Author

Zhang, Da, Gu, Yu, Zhang, Donglai, Zhang, Xiaofeng, Li, Haijin, and Li, Anshou

Subjects

POWER electronics, TOPOLOGY, ALGORITHMS

Abstract

The bidirectional DC‐DC conversion, as an important application scenario, places certain requirements on the topology structure. The four‐switch buck‐boost (FSBB) converter has received widespread attention due to its simple structure, flexible control and state switchability. However, the traditional control strategy makes it difficult to meet the requirements of high performance, high stability and high security at the same time. Furthermore, the control methods commonly adopted in domestic and international practical applications rely heavily on analogue control, which cannot maintain efficiency over a wide stability range. The use of digital control methods allows for optimized control algorithms, maintaining stable system operation and improving efficiency. Therefore, it is very important to use the digital control method to further improve the smoothness and steady‐state efficiency of the system multi‐mode switching while maintaining a wide input and output range, based on this, this study proposes two new three‐mode control modes: interleaved bias control mode and dual‐edge bias control mode. [ABSTRACT FROM AUTHOR]

Published

2024

25. Active elimination of DC bias current of a SiC based dual active bridge by controlling the dead time period.

Author

Perumal, Ganesan, Hatua, Kamalesh, and Rajagopal, Manju

Subjects

FIELD programmable gate arrays, POWER electronics, DC transformers, AUTOMATIC timers

Abstract

Dual active bridge (DAB) is an isolated DC‐DC converter gaining wider attention in power electronics applications. The high frequency (HF) transformer is an integral part of the DAB which is prone to saturation. Silicon carbide (SiC) based DAB are generally preferred for highly efficient power conversions, calling for an extremely low DC resistance of the transformer. This aggravates the DC bias issue significantly. The DC bias current generally flows due to the mismatch in static and transient switching of active devices, leading to eventual saturation of the transformer. This paper proposes an active method to precisely control the dead time of the devices (8–100 ns) without sacrificing the voltage utilization of the converter. This method does not require a sophisticated DC offset current measurement technique. The field programmable gate array (FPGA) based control platform on the gate driver side executes the proposed algorithm. The proposed control is experimentally verified in a 5 kW SiC based converter. The control implementation methodology is discussed with the support of necessary experimental results. [ABSTRACT FROM AUTHOR]

Published

2024

26. An enhanced 13‐level triple voltage gain switched capacitor inverter with lower power electronics devices.

Author

Derakhshandeh, Masoumeh, Hosseinpour, Majid, Seifi, Ali, and Shahparasti, Mahdi

Subjects

POWER semiconductor switches, POWER electronics, SEMICONDUCTOR devices, CAPACITORS, SWITCHING systems (Telecommunication)

Abstract

In this study, a 13‐level switched‐capacitor inverter with triple voltage gain is proposed. The proposed structure generates 13‐level output voltage using only one DC source, eleven switches, and three capacitors. The capacitors have the capability of self‐balancing without the use of additional circuits or complex control methods. Additionally, the inrush current of the capacitors has been reduced using a soft charging method. The proposed structure has been compared with different 13‐level structures presented in recent studies in terms of various parameters such as the number of semiconductor devices, the number of DC sources, voltage gain, Maximum Blocking Voltage (MBV), and Total standing Voltage (TSV). Another advantage of the proposed structure is the non‐use of any diode and its cost‐effectiveness. In addition, the power losses of the proposed structure have been evaluated, and its efficiency has been calculated for various output powers. Finally, the performance of the proposed structure has been verified through simulation and laboratory implementation under both stable and various dynamic conditions. [ABSTRACT FROM AUTHOR]

Published

2024

27. Gate driver, snubber and circuit design considerations for fast‐switching series‐connected SiC MOSFETs.

Author

Ubostad, Tobias Nieckula and Peftitsis, Dimosthenis

Subjects

ENERGY dissipation, METAL oxide semiconductor field-effect transistor circuits, LINE drivers (Integrated circuits), POWER electronics, DYNAMIC balance (Mechanics), METAL oxide semiconductor field-effect transistors

Abstract

Series connection of Silicon Carbide (SiC) Metal‐Oxide‐Semiconductor Field‐Effect Transistors (MOSFETs) is an interesting solution to design switches for voltages that are not yet commercially available or limited for single‐die devices. However, inherent static and dynamic voltage balancing must be achieved. Voltage imbalance is caused by the device parameters spread, whose impact is pronounced in low‐inductive circuit layouts. This study investigates the optimal design and tuning limits of resistor‐capacitor (RC)‐snubber circuits and non‐adaptive, standard, voltage‐source gate drivers for achieving the best balancing in transient and steady‐state voltage distributions among series‐connected discrete SiC MOSFETs operating at speeds up to 90kV/μs$90 \,\mathrm{k}\mathrm{V}/{\umu }\mathrm{s}$. It has been shown that a larger parameter mismatch will lead to uneven switching energy losses and larger voltage imbalances. It was also experimentally shown that increasing the gate resistor to slow down the devices will not always improve balancing when their parameter spread is large. Thus, tuning recommendations for the RC‐snubber circuit and gate driver were developed based on these findings. [ABSTRACT FROM AUTHOR]

Published

2024

28. A CC/VC‐based power tracking method for photovoltaic inverter operated in voltage control mode.

Author

Wang, ZhenXiong, Peng, Yingjie, Yi, Hao, Zhang, Wei, Wu, Jingting, Li, Qiru, and Zhuo, Fang

Subjects

POWER electronics, VOLTAGE control, ELECTRIC power distribution grids, ENERGY storage, VOLTAGE

Abstract

The active power control of photovoltaic (PV) inverters without energy storage can flatten the fluctuating power and support the voltage amplitude and frequency of the grid. When operated in grid‐forming voltage‐control mode, because the PV power can change rapidly and widely, the PV inverter needs to track the power commands quickly and precisely. Traditionally, this goal is achieved with the estimation of PV power curve or PI‐based multiple‐loop feedback control, where flexibility, availability and accuracy are not satisfactory. Therefore, a CC/VC‐based power tracking (CVPT) method is proposed, which only uses single‐loop in control. The proposed method does not need to tune multiple loops and can respond faster, which is important for grid‐forming voltage control. Furthermore, the different operating modes due to the limitation of PV maximum power are analysed, and a mode switch method is proposed. Simulation and experimental results demonstrate that the PV inverter can cope with power disturbances from both the power and grid sides and maintain the quality of grid voltage. [ABSTRACT FROM AUTHOR]

Published

2024

29. A capacitive power transfer system with LCL primary compensation for very‐low‐power portable devices.

Author

Huang, Jiasheng, Dou, Yi, Zhang, Zhe, Ouyang, Ziwei, and Andersen, Michael A. E.

Subjects

CONSTANT current sources, POWER capacitors, POWER electronics, SYSTEMS design, DIODES

Abstract

This paper investigates and technically demonstrates a capacitive power transfer (CPT) system applicable to the charging of emerging very‐low‐power portable devices. The constant‐current operation of the primary LCL compensation in CPT is implemented and analysed to simplify the system design process and minimize the configuration on the receiving side. Additionally, the system design considerations for the capacitive coupler and the diode rectifier are presented based on the battery charging specifications. All the design concepts and considerations are validated through experimentation with a 13.56 MHz CPT system, which achieves load‐independent constant‐current output from full‐load to light‐load (one‐tenth of the full load) charging operations. [ABSTRACT FROM AUTHOR]

Published

2024

30. SiO2‐GaN Interface Improvement by Wet Cleaning and In Situ Annealing for GaN MOS Transistors.

Author

Henn, Mirjam, Ziegler, Johannes, Huber, Christian, Rodriguez‐Alvarez, Humberto, and Kaminski, Nando

Subjects

*CHEMICAL vapor deposition, *STREAM channelization, *GALLIUM nitride, *SILICON oxide, *POWER electronics, *METAL oxide semiconductor field-effect transistors, *ANNEALING of metals

Abstract

Herein, ex situ wet cleaning and in situ high‐temperature annealing of GaN surfaces prior to low pressure chemical vapor deposition (LPCVD) of the SiO2 gate oxide, aiming at effective SiO2‐GaN interface engineering for channel improvement of metal–oxide semiconductor (MOS) transistors, are investigated. Additionally, the combination of in situ annealing and gate oxide deposition in an LPCVD tool provides the advantage of an industrially preferred batch process. A strong impact of the pretreatments on the interface state density Dit$D_{\text{it}}$ and flatband voltage VFB$V_{\text{FB}}$ of the fabricated n‐type GaN MOS capacitors is demonstrated. Combined HF wet cleaning and NH3$_{3}$ annealing result in a low peak interface state density DitHF+NH3=1.5×1011 cm−2 eV−1$D_{\text{it}}^{\text{HF} + \left(\text{NH}\right)_{3}} = 1.5 \times \left(10\right)^{11} \textrm{ } \left(\text{cm}\right)^{- 2} \textrm{ } \left(\text{eV}\right)^{- 1}$ and a close to ideal C–V curve with a nearly ideal flatband voltage VFBHF+NH3=−0.1 V$V_{\text{FB}}^{\text{HF} + \left(\text{NH}\right)_{3}} = - 0.1 \textrm{ } \textrm{ } \text{V}$. Furthermore, the I–V characteristics exhibit a positive voltage shift of the current onset and substantially reduced I‐V hysteresis, i.e., negligible temporary charging. Physical root causes are assumed to be reduced contamination due to nondestructive yet efficient HF cleaning combined with subsequent high temperatures and the reduction of near‐interface, quasi‐permanent traps due to the saturation of dangling bonds by the annealing in hydrogen‐containing atmosphere. [ABSTRACT FROM AUTHOR]

Published

2024

31. Low‐Pressure, Modified Halide Vapor‐Phase Epitaxy for Chemically Pure GaN Epilayers.

Author

Leach, Jacob H., Udwary, Kevin, Dodson, Gregg, Tran, Tinh B., and Splawn, Heather A.

Subjects

*POWER electronics, *GALLIUM nitride, *DOPING agents (Chemistry), *SURFACE roughness, *EPITAXY

Abstract

The halide vapor‐phase epitaxy (HVPE) technique has been extensively used for the production of freestanding GaN crystals for GaN wafer manufacturing, but has had renewed interest in recent years as a technique for producing high‐quality GaN epilayers at high growth rates and without the issues of carbon incorporation which complicate the growth of GaN using metal–organic vapor phase epitaxy. Herein, thick epilayers grown by HVPE using a low‐pressure modified quartz reactor with controlled H2 injection are presented which exhibit surface root‐mean‐square roughnesses <0.5 nm with low background doping concentrations <2E15 cm−3 and room‐temperature mobilities >1200 cm2 V−1 s−1. Such films are considered to be strong contenders for the production of lightly doped GaN drift layers for vertical power electronics devices. [ABSTRACT FROM AUTHOR]

Published

2024

32. Utilizing Island Growth in Superlattice Buffers for the Realization of Thick GaN‐on‐Si(111) PIN‐Structures for Power Electronics.

Author

Michler, Sondre, Thapa, Sarad, Besendörfer, Sven, Albrecht, Martin, Weingärtner, Roland, and Meissner, Elke

Subjects

*METAL organic chemical vapor deposition, *ATOMIC force microscopy, *TRANSMISSION electron microscopy, *POWER electronics, *DISLOCATION density

Abstract

In this study, the effect of implementing island growth in an AlN/Al0.1Ga0.9N superlattice on the structural properties of vertical GaN‐on‐Si(111) PIN‐structures is investigated. It is demonstrated by scanning electron microscopy (SEM) and atomic force microscopy (AFM) that islands are formed on‐top of V‐pits present in the AlN nucleation layer and that the island coalescence height can be controlled by the growth temperature. Defect selective etching analyses confirm a noteworthy reduction in the threading dislocation density (TDD), which diminishes from 1.2 × 109 cm−2 ± 7.5 × 107 cm−2 to 8.5 × 108 cm−2 ± 7.3 ×107 cm−2 as the island coalescence height increases from ≈160 nm to ≈450 nm, achieved by increasing the growth temperature. Cross‐sectional transmission electron microscopy (TEM) shows that island growth is particularly favorable for the reduction of a‐type dislocations. As a consequence of the significant reduction of a‐type dislocations in the buffer, stress relaxation during the GaN film growth is reduced, which is supported by in situ wafer curvature measurements and high‐resolution X‐ray diffraction (XRD). Owing to the optimized island growth conditions, thick and crack‐free GaN layers on Si(111) substrates are obtained with an absolute wafer bow of <50 μm. [ABSTRACT FROM AUTHOR]

Published

2024

33. A Sustainable and Eco-Friendly Membrane for PEM Fuel Cells Using Bacterial Cellulose.

Author

Yang, Xiaozhen, Huang, Lin, Deng, Qiang, and Dong, Weifu

Subjects

*PROTON exchange membrane fuel cells, *PROTON conductivity, *CHEMICAL stability, *POWER resources, *POWER electronics, *IONOMERS

Abstract

Bacterial cellulose (BC) is an advantageous polymer due to its renewable nature, low cost, environmental compatibility, biocompatibility, biodegradability, chemical stability, and ease of modification. With these advantages, BC is an interesting candidate for the development of novel eco-friendly materials for proton-exchange membrane (PEM) applications. However, its practical applications have been limited by its relatively high dispersion in water, which usually occurs during the operation of proton-exchange membrane fuel cells (PEMFCs). In addition, the proton conductivity of bacterial cellulose is poor. In this study, functionalized BC modified with 3-aminopropyltriethoxysilane (APTES) was prepared using a solvent casting method to enhance its performance. The results showed that the water stability of the modified BC membrane was significantly improved, with the contact angle increasing from 54.9° to 103.3°. Furthermore, the optimum ratio of BC and APTES was used to prepare a proton-exchange membrane with a maximum proton conductivity of 62.2 mS/cm, which exhibited a power generation performance of 4.85 mW/cm2 in PEMFCs. It is worth mentioning that modified BC membranes obtained by combining an alkaline proton carrier (-NH2) with BC have rarely been reported. As fully bio-based conductive membranes for PEMFCs, they have the potential to be a low-cost, eco-friendly, and degradable alternative to expensive, ecologically problematic fluoric ionomers in short-term or disposable applications, such as biodegradable electronics and portable power supplies. [ABSTRACT FROM AUTHOR]

Published

2024

34. Comparison of Bi-Directional Topologies for On-Board Charger: A 10.9 kW High-Efficiency High Power Density of DC-DC Stage.

Author

Oh, Hyeong-Seok, Hong, Seong-Yong, Lee, Ju, and Lee, Jae-Bum

Subjects

*DC-to-DC converters, *BRIDGE circuits, *ELECTRIC vehicle charging stations, *POWER electronics, *POWER density

Abstract

In recent years, the trend in power electronics has been toward high-efficiency and high-power-density converters. Additionally, this trend has allowed electric vehicles to accommodate larger batteries, which necessitate bi-directional capabilities not only for driving but also for vehicle to grid (V2G), etc. This article proposes a comparative analysis of GaN-based bi-directional topologies, namely the dual active bridge (DAB) converter and the CLLC converter. To ensure a fair analysis of the proposed topologies, prototypes with the same target of efficiency above 97.5% and a power density of 5.5 kW/L have been constructed. This research can support the adoption of 10.9 kW bi-directional topologies in GaN-based on-board chargers (OBCs) for EVs. [ABSTRACT FROM AUTHOR]

Published

2024

35. Survey of Reliability Challenges and Assessment in Power Grids with High Penetration of Inverter-Based Resources.

Author

Haghighi, Rouzbeh, Bui, Van-Hai, Wang, Mengqi, and Su, Wencong

Subjects

*RENEWABLE energy sources, *POWER electronics, *ELECTRIC power distribution grids, *CONVERTERS (Electronics), *RELIABILITY in engineering

Abstract

Decarbonization is driving power systems toward more decentralized, self-governing models. While these technologies improve efficiency, planning, operations, and reduce the carbon footprint, they also introduce new challenges. In modern grids, particularly with the integration of power electronic devices and high penetration of Renewable Energy Sources (RES) and Inverter-Based Resources (IBRs), traditional reliability concepts may no longer ensure adequate performance due to systemic restructuring. This shift necessitates new or significantly modified reliability indices to capture the characteristics of the evolving power system. Ensuring converter reliability is essential for effective planning, which requires precise, component-to-system-level modeling, as different converters impact system performance indicators. However, the existing literature in this field faces a significant limitation, as most studies focus on a singular perspective. Some examine reliability at the device-level, others at the component-level, while broader reviews in power systems often emphasize system-level analysis. In this paper, we aim to bridge these gaps by comprehensively reviewing the interconnections between these levels and analyzing the mutual influence of power converter and system reliability. A key point to highlight is that, with the rapid evolution of modern power grids, decision-makers must adopt a multi-level approach that incorporates insights from all levels to enable more accurate and realistic planning and operational strategies. Our ultimate goal is to provide an in-depth investigation of studies addressing the unique challenges posed by modern power grids. Finally, we will highlight the gaps in the literature and suggest directions for future research. [ABSTRACT FROM AUTHOR]

Published

2024

36. Commutation strategy for reduced output voltage ripple in alternative cascaded boost converter.

Author

García‐Vite, Pedro Martín, Rebullosa‐Castillo, Josué Francisco, García‐Perales, Manuel Alejandro, Reyes‐García, Brenda Lizeth, and García‐Guendulain, Crescencio

Subjects

*ENERGY storage, *CASCADE converters, *ELECTROLYTIC capacitors, *POWER electronics, *LITERATURE reviews

Abstract

Summary: With the rapid penetration of low‐voltage direct current (DC) generators such as photovoltaic panels and storage energy systems, the need for processing energy has propitiated the optimization of power electronics converters. Conventional topologies of power electronics converters have well‐known limitations, mainly due to the parasitic elements and finite commutation times, which do not allow for obtaining a sufficient voltage gain. The literature review has demonstrated that cascade topologies are suited to overcome these limitations. However, to provide a low‐ripple output voltage, they require high values of capacitances. This paper presents an alternative boost converter developed by cascading two power cells. The conventional configuration is slightly modified, producing an alternative power cell. Even though the number of elements is increased, following the suggested commutation strategy, the derived converter can substantially reduce the output voltage ripple. Therefore, capacitors of small value can be employed, avoiding using electrolytic capacitors with shorter life spans than their film counterparts. Besides, given the cascaded connection, the converter possesses a quadratic‐type gain since two independent commanding signals are applied. The different states of commutation are analyzed in depth, allowing the selection of an adequate commutation strategy, which gives the advantage of canceling the output voltage ripple. The mathematical model of the converter is presented and then validated via a scale‐lab prototype. The simulation results evidence the good dynamic performance of the control‐loop design by means of the frequency response analysis. [ABSTRACT FROM AUTHOR]

Published

2024

37. A Novel High-Gain Switched-Capacitor Multilevel Inverter with Reduced Components for Grid Integration.

Author

Nanda, Haresh, Sharma, Himanshu, Arora, Krishan, Yadav, Arvind, Joshi, Gyanendra Prasad, and Cho, Woong

Subjects

IDEAL sources (Electric circuits), RELIABILITY in engineering, CAPACITORS, VOLTAGE, COMPARATIVE studies, POWER electronics

Abstract

This paper introduces a novel Multi-Level Inverter (MLI) design which utilizes a single input and leverages capacitor voltages source to generate a four-fold increase in output voltage as the main problem that stays with the inverters is their low boost ability and efficiency while maintaining power quality at the same time. One capacitor is charged to match the input voltage magnitude, while the other two capacitors store twice this magnitude. Through a series-parallel combination with switching operations, all capacitors are effectively charged and discharged within each cycle, ensuring natural voltage balance. A comprehensive comparative analysis is conducted to highlight the advantages of this innovative approach, particularly in terms of component reduction and mitigation of voltage stress. Detailed assessment of power losses within the proposed circuit is undertaken, simulation studies are first carried out while extensive experimentation verifies its operational efficiency under diverse conditions such as varying modulation indices, loads, and supply-side fluctuations with an impressive maximum efficiency of 96.9 % at a 200 W power rating, our research contributes to advancing compact power converters, addressing crucial challenges in modern power electronics applications, and paving the way for enhanced performance and reliability in such systems. [ABSTRACT FROM AUTHOR]

Published

2024

38. Indoor Solar Cells.

Subjects

PHOTOVOLTAIC power systems, SILICON solar cells, CLEAN energy, SOLAR cells, POWER electronics, FLEXIBLE electronics

Abstract

The article discusses the development of indoor solar cells to power the increasing number of IoT devices expected to be used indoors. Researchers are focusing on materials that can harvest indoor light efficiently, with organic photovoltaics, dye-sensitized solar cells, and perovskite solar cells being key technologies. Companies like Epishine, Saule Technologies, and Oxford PV are already showcasing products powered by indoor solar technologies, indicating a growing interest in integrating solar cells into electronics for sustainable energy solutions. [Extracted from the article]

Published

2024

39. КЕРУВАННЯ ДИНАМІКОЮ ІМПУЛЬСНОГО ПЕРЕТВОРЮВАЧА З М’ЯКИМ ПЕРЕМИКАННЯМ, ЩО ПРАЦЮЄ НА ДУГОВЕ НАВАНТАЖЕННЯ.

Author

Верещаго, Є. М., Костюченко, В. І., Стогнієнко, Є. В., and Грєшнов, А. Ю.

Subjects

CLOSED loop systems, POWER resources, METAL cutting, POWER electronics, AUTOMATIC control systems

Abstract

Issues of design and research of energy-efficient and reliable semiconductor DC voltage converters for wide application in power supply devices of arc plasmatrons used in plasma metal cutting installations are considered. An estimated structural dynamic model of a soft-switching DC converter with a closed-loop control system combining the power part and the control system, intended for use as part of the latter as a digital module, was built. A technique is proposed and methods of controlling the converter are found, which provide the specified duration of transient processes, the permissible value of load current pulsations in a quasi-steady mode and the astatism of the output current, which confirms the correctness of the proposed technique. A prototype of a pulse stabilizer with digital control was made. The results of experimental studies of the sample confirm the effectiveness of the developed control device, namely the achievement of the specified duration of transient processes caused by a step change in the load current, close to 10-12 periods of conversion and astatism of the output current. It is shown that the application of a pulse stabilizer, in which a digital control loop is used, has significant advantages compared to analog options and has the advantages of a strategic plan. The use of combined control allows you to significantly reduce the requirements for the overall gain of the main control channel, which greatly facilitates the choice of sequential digital correction. Research results may be of interest to specialists in the field of power electronics, power supply systems of autonomous objects and control systems. References 14, figures 11. [ABSTRACT FROM AUTHOR]

Published

2024

40. Design optimization for enhancing performances of integrated planar inductor for power electronics applications.

Author

Ahmed, M. Si, Guettef, Y., Mokaddem, A., Mokhefi, A., Hamid, A., Spiteri, P., and Medjaoui, F. Z.

Subjects

POWER electronics, ELECTRONIC systems, GEOMETRIC shapes, GEOMETRIC analysis, ELECTRONIC equipment

Abstract

Goal. In this work, the performance of an integrated planar inductor with a square geometric shape using different materials for the substrate: Ni-Fe, Mn-Zn and Ni-Zn have been analyzed and investigated in order to assess the impact of the substrate material on the performance of the integrated planar inductor and to determine the optimal material in the various applications of power modules in power electronics. Methods. To this end, we carried out an in-depth analysis of the geometric dimensions of the integrated planar inductor, by calculating all the geometric parameters of the proposed structure, to establish an equivalent physical model of the integrated planar inductor in order to evaluate its different electrical specifications. The numerical simulation, based on the threedimensional mathematical model of the system using Maxwell’s equations, was realized by COMSOL Multiphysics software. Results show the importance of the substrate material for the performance of the integrated planar inductor, and specify that the use of Ni-Fe ferrite as a substrate of the integrated planar inductor gives very interesting performance compared to other materials studied. The presented results provide valuable information on the influence of substrate material on the performance of embedded integrated planar inductor and can help to design and optimize these components for use in power electronic systems. Practical value. These results are significant for a wide range of applications, where the integrated planar inductor performance and efficiency can have a significant impact on the overall performance and cost-effectiveness of the power electronic device. [ABSTRACT FROM AUTHOR]

Published

2024

41. Electrochemical Sacrificial Alchemy: Crafting Hollow Hydroxide Hierarchy for Practical Aqueous Energy Storage Solution.

Author

Sun, Fang‐Fang, Wu, Chongchong, Guan, Xinwei, Huang, Zi‐Hang, Han, Xu, Zhang, Yue, Li, Hui, Song, Yu, and Ma, Tianyi

Subjects

*ENERGY density, *POWER electronics, *NANORODS, *ELECTRIC fields, *PROOF of concept

Abstract

Effective utilization of internal active sites in high‐mass loading electrode materials is essential for advancing practical energy storage. Herein, a novel electrochemical sacrificial alchemy for the first time to directly transform the solid Co‐Ni‐Zn carbonate hydroxide (CH) into its hollow structure with a strategic hierarchical architecture is introduced. In contrast to the complex and often cumbersome procedures of traditional methods, the approach is built on the simple electrochemically induced in situ etching and remodeling process. The experimental and theoretical analyses highlight the significant role of electric field force‐induced Zn sacrificial etching and hydroxide redeposition in creating internal cavities and regenerating external active sites, leading to the final hollow hierarchical structure with primary 1D hollow nanorod arrays and secondary reconstructed 2D nanoflakes, effectively exposing abundant energy storage sites. Benefiting from the synergistic effect, the resulting Co‐Ni‐Zn CH exhibited exceptional electrochemical performance. As proof of concept, a modular pouch‐type hybrid supercapacitor (HSC) composed of Co‐Ni‐Zn CH cathode achieved an ultrahigh energy density of 46.9 Wh kg−1. This device can efficiently power consumer electronics with a faster charging speed compared to commercial shared power banks. This research unveils a facile electrochemical approach for structuring electrode materials in energy storage solutions. [ABSTRACT FROM AUTHOR]

Published

2024

42. MHz High Performance of Soft Magnetic Composite with Ordered Domain Structure for Efficient Conversion of Electrical Energy.

Author

Jin, Xiaowei, Li, Tong, Yao, Yuping, Wang, Chaojie, Shi, Huigang, Chai, Guozhi, Gao, Daqiang, Jia, Chenglong, Xi, Li, and Xue, Desheng

Subjects

*SOFT magnetic materials, *WIDE gap semiconductors, *MAGNETIC permeability, *POWER electronics, *MAGNETIC domain

Abstract

Soft magnetic materials are a core element of power electronics and electrical machines. However, none of the soft magnetic materials is able to exploit the full potential of wide bandgap semiconductors, which operate above MHz frequency for efficient energy conversion in power electronic systems. Here, a high‐performance Fe–Si soft magnetic composites with a 2D ordered domain structure are reported, enabling efficient energy conversion at MHz frequencies. By transforming spherical particles into flakes and arranging them in layers, 2D magnetic domains are created within the composite. This leads to a 90% increase in permeability and a tenfold decrease in loss at 3 MHz compared to composite made with spherical particles. The significantly increased cut‐off frequency indicates that the ordered flaky particles are suitable for MHz applications, unlike the disordered spherical particles. These findings provide an effective approach for fabricating high performance soft magnetic composites from traditional spherical particles and miniaturizing magnetic devices for efficient power electronics operation. [ABSTRACT FROM AUTHOR]

Published

2024

43. Powering the circular future: Climate change and economic perspectives on second‐life batteries in the Belgian context.

Author

Huber, Dominik, van den Oever, Anne, Philippot, Maeva Lavigne, Costa, Daniele, Coosemans, Thierry, and Messagie, Maarten

Subjects

*PRODUCT life cycle assessment, *STORAGE batteries, *ECONOMIC change, *INDUSTRIAL ecology, *POWER electronics

Abstract

This paper calculates the future levelized cost of storage (LCOS) and conducts a prospective life cycle assessment (PLCA) for second‐life batteries (SLB) in Flanders, Belgium. A cradle‐to‐grave approach is chosen for climate change (CC) and economic impacts of SLB. Impacts of processes related to the first and the second life are allocated according to the delivered electricity. Furthermore, impacts are determined according to their temporal occurrence. For LCOS, activities are time adjusted by discounting. For PLCA, new background databases are generated and changed based on the activities occurrence in time. Additionally, future CC impact of three Belgian energy paths is modeled, introducing user‐defined scenarios of PLCA. To conceptualize impacts, three use cases are defined: (a) residential, (b) industrial and (c) utility use case (UTI). The residential and industrial use cases (INDs) represent photovoltaic (PV) installations with battery storage, the UTI is a large‐scale battery participating in the Belgian secondary reserve market. Lowest LCOS of the SLB in 2050 are found in the IND, namely 39.66 €/MWh, and are below the benchmark batteries. CC impact of SLB in the residential is 58.7 gCO2eq$\text{gCO}_2{\rm eq}$/kWh and below the benchmark batteries. The CC impact of SLB is 75.2 and 78.5 gCO2eq$\text{gCO}_2{\rm eq}$/kWh in the industrial and UTI and thus higher than the benchmark batteries. Crucial for both assessments are increased dismantling and repurposing facility throughput, fair charging tariffs, the manufacturing, the charging electricity generated by PV installations, and power electronics. On the contrary, changing the background does not lead to major changes in CC. [ABSTRACT FROM AUTHOR]

Published

2024

44. Performance analysis of DC-DC Buck converter with innovative multi-stage PIDn(1+PD) controller using GEO algorithm.

Author

Jabari, Mostafa, Izci, Davut, Ekinci, Serdar, Bajaj, Mohit, and Zaitsev, Ievgen

Subjects

*DC-to-DC converters, *METAHEURISTIC algorithms, *POWER electronics, *CLOSED loop systems, *VOLTAGE references

Abstract

Power electronic converters are widely used in various fields of electrical equipment. Due to their fast dynamics and non-linear nature, controlling them requires dealing with various complexities. Therefore, having a well-designed, high-speed, and robust controller is critical to ensure the effective operation of these devices. In a DC-DC converter, steady-state performance with minimum error and fast dynamic response relies on controller design. This paper presents the design of a multi-stage PID controller with an N-filter combined with a one plus proportional derivative (1+PD) controller. This controller illustrates fast tracking reference voltage; additionally, it shows incredible results when the DC-DC converter operates in different modes. The parameters of the proposed controller are effectively determined using the golden eagle optimization (GEO) algorithm. Furthermore, a comprehensive comparison between the proposed controller, proportional–integral–derivative (PID), and fractional order PID (FOPID) controllers, as well as different metaheuristic optimization methods in various conditions, has been conducted to demonstrate the effectiveness of the proposed controller. The behavior of the closed-loop system under different conditions has been thoroughly investigated. The superior time and frequency domain characteristics of the closed-loop system with the PIDn(1+PD) controller highlight its superiority over other controllers. The demonstrated enhancements in settling time, voltage regulation accuracy, and transient response emphasize the potential applicability of the proposed control strategy in real-world power electronics systems, particularly in scenarios requiring high efficiency, stability, and dynamic performance. [ABSTRACT FROM AUTHOR]

Published

2024

45. Aggregate data‐driven dynamic modeling of active distribution networks with DERs for voltage stability studies.

Author

Subedi, Sunil, Vasquez‐Plaza, Jesus D., Andrade, Fabio, Rekabdarkolaee, Hossein Moradi, Fourney, Robert, Tonkoski, Reinaldo, and Hansen, Timothy M.

Subjects

POWER distribution networks, POWER system simulation, POWER electronics, ELECTRIC networks, POWER resources

Abstract

Electric distribution networks increasingly host distributed energy resources based on power electronic converter (PEC) toward active distribution networks (ADN). Despite advances in computational capabilities, electromagnetic transient models are limited in scalability because of their reliance on exact data about the distribution system and each of its components. Similarly, the use of the DER_A model, which is intended to examine the combined dynamic behavior of many DERs, is limited by the difficulty in parameterization. There is a need for improved dynamic models of DERs for use in large power system simulations for stability analysis. This paper proposes an aggregate model‐free, data‐driven approach for deriving a dynamic partitioned model (DPM) of ADNs. Detailed residential distribution feeders were first developed, including PEC‐based DERs and composite load models (CMLDs), from which the aggregated DPM was derived. The performance was evaluated through various case studies and validated against the detailed ADN model and state‐of‐the‐art DER_A model with CMLD. The data‐driven DPM achieved a fitpercent${\it fitpercent}$ of over 90%, accurately representing the aggregated dynamic behavior of ADNs. Furthermore, the DPM significantly accelerated the simulation process with a computational speedup of 68 times compared to the detailed ADN and a 3.5 times speedup compared to the DER_A CMLD model. [ABSTRACT FROM AUTHOR]

Published

2024

46. Fast switching Ga2O3 Schottky barrier power diode with beveled-mesa and BaTiO3 field plate edge termination.

Author

Sun, N., Gong, H. H., Hu, T. C., Zhou, F., Wang, Z. P., Yu, X. X., Ren, F.-F, Gu, S. L., Lu, H., Zhang, R., and Ye, J. D.

Subjects

*POWER electronics, *ELECTRIC fields, *STRAY currents, *CONFIGURATION management, *LEAKAGE

Abstract

Power devices rely on ideal edge termination to suppress the electric field crowding and avoid premature breakdown before the material's critical field is reached. In this work, a hybrid electric field management configuration, featuring the combination of beveled-mesa (BM) termination and high-k oxide BaTiO3 field plate (FP), was implemented in Ga2O3 Schottky barrier diodes (SBDs). This BMFP-SBD realizes a breakdown voltage (BV) of 1.7 kV with extremely low reverse leakage current, outperforming the BM terminated SBD with BV of 0.64 kV and bare SBD with BV of 0.22 kV. Based on the temperature-dependent reverse characteristics, the dominant leakage mechanism transforms from Poole–Frenkel (P–F) emission in BM-SBD to variable-range-hopping (VRH) in BMFP-SBD at high bias. In particular, under switching conditions of di/dt up to 420 A/μs, the BMFP-SBD exhibits superior dynamic switching characteristics with a short reverse recovery time of 10.1 ns, which are comparable with those in advanced commercial SiC SBDs. These findings underscore the potential of Ga2O3 SBD enabled by BM and high-k FP edge termination for high-speed and high-voltage power electronics applications. [ABSTRACT FROM AUTHOR]

Published

2024

47. Electric vehicles in emergencies and evacuations: a review of resilience and future research directions.

Author

Babaei, Mohammad Hossein and Wong, Stephen D.

Subjects

*INFRASTRUCTURE (Economics), *EMERGENCY vehicles, *POWER electronics, *POWER resources, *EXECUTIVE power

Abstract

Disasters often require large-scale evacuations, and damage key infrastructure (e.g., power, transportation). With growing electric vehicle (EV) adoption and electrification of transportation, governments and utilities may face significant power challenges during disasters, especially during the evacuation stage. Low state-of-charge, sporadic charging infrastructure, or power outages could significantly hamper safe and effective evacuations. Yet, EVs also offer possible resilience benefits to emergency response by more easily charging electronics or sending power back to the grid through vehicle-to-grid (V2G) technology. This paper focuses on the opportunities, benefits, and drawbacks of EVs in disasters and evacuations through a systematic review of current literature, reports, and sources. Overall, this review discovered EVs show promise as modes of transportation and mobile energy supply units. However, crucial challenges such as charging infrastructure locations, upfront cost of resilience technologies, and user behavior necessitate more dedicated research to overcome shortcomings and guide more realistic implementation of benefits. [ABSTRACT FROM AUTHOR]

Published

2024

48. Oscillation Suppression of Grid-Following Converters by Grid-Forming Converters with Adaptive Droop Control.

Author

Qiu, Lifeng, Gu, Miaosong, Chen, Zhongjiang, Du, Zhendong, Zhang, Ligang, Li, Wenrui, Huang, Jingyi, and Fang, Jingyang

Subjects

*RENEWABLE energy sources, *PHASE-locked loops, *POWER electronics, *REACTIVE power, *SHORT circuits, *MICROGRIDS

Abstract

The high penetration of renewable energy sources (RESs) and power electronics devices has led to a continuous decline in power system stability. Due to the instability of grid-following converters (GFLCs) in weak grids, the grid-forming converters (GFMCs) have gained widespread attention featuring their flexible frequency and voltage regulation capabilities, as well as the satisfactory grid-supporting services, such as inertia and damping, et al. Notably, the risk of wideband oscillations in modern power grids is increasingly exacerbated by the reduced number of synchronous generators (SGs). Thus, the wideband oscillation suppression method based on adaptive active power droop control of GFMCs is presented in this paper. First, the stability of the hybrid grid-forming and grid-following system is obtained according to the improved short circuit ratio (ISCR), where the GFMC is in parallel at the point of common coupling (PCC) of the GFLC. Then, an adaptive adjustment strategy of the active power droop control is proposed to enhance the oscillation suppression capability across the full frequency range, thereby mitigating the wideband oscillation caused by phase-locked loop (PLL) synchronization in the GFLCs. Additionally, a first-order inertia control unit is added to the active and reactive power droop controllers to mitigate frequency and voltage variations as well as suppress potential mid-to-high frequency resonance. Finally, the wideband oscillation suppression strategy is validated by the simulation and experimental results. [ABSTRACT FROM AUTHOR]

Published

2024

49. Advancements in Flexible and Stretchable Electronics for Resistive Hydrogen Sensing: A Comprehensive Review.

Author

Park, Kwonpil and Kim, Minsoo P.

Subjects

*FLEXIBLE electronics, *SENSOR networks, *HYDROGEN detectors, *TECHNOLOGICAL innovations, *CLEAN energy, *POWER electronics

Abstract

Flexible and stretchable electronics have emerged as a groundbreaking technology with wide-ranging applications, including wearable devices, medical implants, and environmental monitoring systems. Among their numerous applications, hydrogen sensing represents a critical area of research, particularly due to hydrogen's role as a clean energy carrier and its explosive nature at high concentrations. This review paper provides a comprehensive overview of the recent advancements in flexible and stretchable electronics tailored for resistive hydrogen sensing applications. It begins by introducing the fundamental principles underlying the operation of flexible and stretchable resistive sensors, highlighting the innovative materials and fabrication techniques that enable their exceptional mechanical resilience and adaptability. Following this, the paper delves into the specific strategies employed in the integration of these resistive sensors into hydrogen detection systems, discussing the merits and limitations of various sensor designs, from nanoscale transducers to fully integrated wearable devices. Special attention is paid to the sensitivity, selectivity, and operational stability of these resistive sensors, as well as their performance under real-world conditions. Furthermore, the review explores the challenges and opportunities in this rapidly evolving field, including the scalability of manufacturing processes, the integration of resistive sensor networks, and the development of standards for safety and performance. Finally, the review concludes with a forward-looking perspective on the potential impacts of flexible and stretchable resistive electronics in hydrogen energy systems and safety applications, underscoring the need for interdisciplinary collaboration to realize the full potential of this innovative technology. [ABSTRACT FROM AUTHOR]

Published

2024

50. Fully Integrated Direct Current Triboelectric Nanogenerators Coupled with Charge Pump and Electric Field Enhancing Effect Enabling Improved Output Performance.

Author

Chen, Chen, Fang, Lin, Zhang, Haonan, Wang, Zixun, Zheng, Tianxiang, Tu, Xinbo, Wang, Longsen, Wang, Feixiang, Li, Zhe, Shu, Leilei, Liu, Di, Wang, Jie, and Wang, Peihong

Subjects

*ELECTRIC charge, *ELECTRIC field effects, *NANOGENERATORS, *ENERGY conversion, *POWER electronics, *ON-chip charge pumps, *RECTIFICATION (Electricity)

Abstract

Direct‐current triboelectric nanogenerators (DC‐TENGs) arising from electrostatic breakdown have garnered significant attention due to their advantages of rectification‐free operation, constant current output, and high output power density. Previous studies have primarily concentrated on improving its performance through structural design and parameter optimization, neglecting the potential benefits of external charge excitation. Here, a facile and universal strategy coupling charge pump and electric field enhancing effect with DC‐TENG (CE‐DC‐TENG) is proposed to improve the output performance of DC‐TENG. An alternating current TENG is used as the charge pump. A field‐enhancing conductive layer, which is introduced under the main DC‐TENG, is connected with the pump TENG to accumulate the charge and enhance the electric field for electrostatic breakdown. The effectiveness of this method is demonstrated by linear and rotary sliding mode TENGs. Furthermore, a fully integrated rotary sliding mode CE‐DC‐TENG is designed and fabricated, and it exhibits impressive performance with a 13‐fold higher power density of 1.56 W m−2 compared to conventional DC‐TENG. Moreover, it can directly power small electronics or be combined with a designed power management circuit for more efficient energy conversion. This work presents a new design strategy for improving the performance of DC‐TENG and facilitating its practical applications. [ABSTRACT FROM AUTHOR]

Published

2024