Journal of Low Power Electronics and Applications

16 pages, 5447 KiB

Open AccessArticle

A Gate Driver for Crosstalk Suppression of eGaN HEMT Power Devices

by Longsheng Zhang, Kaihong Wang, Shilong Guo and Binxin Zhu

J. Low Power Electron. Appl. 2025, 15(3), 38; https://doi.org/10.3390/jlpea15030038 - 6 Jul 2025

The eGaN HEMT power devices face serious crosstalk problems when applied to high-frequency bridge circuits, thereby limiting the switching performance of these devices. To address this issue, a gate driver is proposed in this paper that can suppress both positive and negative crosstalk [...] Read more.

The eGaN HEMT power devices face serious crosstalk problems when applied to high-frequency bridge circuits, thereby limiting the switching performance of these devices. To address this issue, a gate driver is proposed in this paper that can suppress both positive and negative crosstalk of eGaN HEMT power devices, offering the advantages of simple control and easy integration. The basic idea is to suppress positive crosstalk by constructing a negative voltage capacitor, and to suppress negative crosstalk by reducing the impedance of the gate loop. To verify the capability of the proposed gate driver, double-pulse and synchronous Buck test platforms are constructed. The experimental results clearly demonstrate that the proposed gate driver reduces the positive and negative crosstalk spikes by 2.03 V and 1.54 V, respectively, ensuring that the positive and negative crosstalk spikes fall within a safe operating range. Additionally, the turn-off speed of the device is enhanced, leading to a reduction in switching loss. Full article

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29 pages, 2379 KiB

Open AccessArticle

An Analog Architecture and Algorithm for Efficient Convolutional Neural Network Image Computation

by Jennifer Hasler and Praveen Raj Ayyappan

J. Low Power Electron. Appl. 2025, 15(3), 37; https://doi.org/10.3390/jlpea15030037 - 25 Jun 2025

Abstract

This article presents an energy-efficient IC architecture implementation of an analog image-processing ML system, where the primary issue is analog architecture development for existing energy-efficient analog computing devices. An architecture is developed for image classification, transforming a typical imager input into a classified [...] Read more.

This article presents an energy-efficient IC architecture implementation of an analog image-processing ML system, where the primary issue is analog architecture development for existing energy-efficient analog computing devices. An architecture is developed for image classification, transforming a typical imager input into a classified result using a particular NN algorithm, a convolutional NN (ConvNN). These efforts show the need to continue to develop energy-efficient analog architectures alongside efficient analog circuits to fully exploit the opportunities of analog computing for system application. Full article

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13 pages, 31731 KiB

Open AccessArticle

Optimized Coupling Coil Geometry for High Wireless Power Transfer Efficiency in Mobile Devices

by Fahad M. Alotaibi

J. Low Power Electron. Appl. 2025, 15(2), 36; https://doi.org/10.3390/jlpea15020036 - 17 Jun 2025

Abstract

Wireless Power Transfer (WPT) enables efficient, contactless charging for mobile devices by eliminating mechanical connectors and wiring, thereby enhancing user experience and device longevity. However, conventional WPT systems remain prone to performance issues such as coil misalignment, resonance instability, and thermal losses. Addressing [...] Read more.

Wireless Power Transfer (WPT) enables efficient, contactless charging for mobile devices by eliminating mechanical connectors and wiring, thereby enhancing user experience and device longevity. However, conventional WPT systems remain prone to performance issues such as coil misalignment, resonance instability, and thermal losses. Addressing these challenges involves designing coil geometries that operate at lower resonant frequencies to strengthen magnetic coupling and decrease resistance. This work introduces a WPT system with a performance-driven coil design aimed at maximizing magnetic coupling and mutual inductance between the transmitting (Tx) and receiving (Rx) coils in mobile devices. Due to the nonlinear behavior of magnetic flux and the high computational cost of simulations, exploring the full design space for coils using ANSYS Maxwell becomes impractical. To address this complexity, a machine learning (ML)-based optimization framework is developed to efficiently navigate the design space. The framework integrates a hybrid sequential neural network and multivariate regression model to optimize coil winding and ferrite core geometry. The optimized structure achieves a mutual inductance of 12.52

μ

H with a conventional core, outperforming many existing ML models. Finite element simulations and experimental results validate the robustness of the method, which offers a scalable solution for efficient wireless charging in compact, misalignment-prone environments. Full article

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19 pages, 8803 KiB

Open AccessArticle

An Accurate and Low-Complexity Offset Calibration Methodology for Dynamic Comparators

by Juan Cuenca, Benjamin Zambrano, Esteban Garzón, Luis Miguel Prócel and Marco Lanuzza

J. Low Power Electron. Appl. 2025, 15(2), 35; https://doi.org/10.3390/jlpea15020035 - 2 Jun 2025

Abstract

Dynamic comparators play an important role in electronic systems, requiring high accuracy, low power consumption, and minimal offset voltage. This work proposes an accurate and low-complexity offset calibration design based on a capacitive load approach. It was designed using a 65 nm CMOS [...] Read more.

Dynamic comparators play an important role in electronic systems, requiring high accuracy, low power consumption, and minimal offset voltage. This work proposes an accurate and low-complexity offset calibration design based on a capacitive load approach. It was designed using a 65 nm CMOS technology and comprehensively evaluated under Monte Carlo simulations and PVT variations. The proposed scheme was built using MIM capacitors and transistor-based capacitors, and it includes Verilog-based calibration algorithms. The proposed offset calibration is benchmarked, in terms of precision, calibration time, energy consumption, delay, and area, against prior calibration techniques: current injection via gate biasing by a charge pump circuit and current injection via parallel transistors. The evaluation of the offset calibration schemes relies on Analog/Mixed-Signal (AMS) simulations, ensuring accurate evaluation of digital and analog domains. The charge pump method achieved the best Energy-Delay Product (EDP) at the cost of lower long-term accuracy, mainly because of its capacitor leakage. The proposed scheme demonstrated superior performance in offset reduction, achieving a one-sigma offset of 0.223 mV while maintaining precise calibration. Among the calibration algorithms, the window algorithm performs better than the accelerated calibration. This is mainly because the window algorithm considers noise-induced output oscillations, ensuring consistent calibration across all designs. This work provides insights into the trade-offs between energy, precision, and area in dynamic comparator designs, offering strategies to enhance offset calibration. Full article

(This article belongs to the Special Issue Analog/Mixed-Signal Integrated Circuit Design)

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25 pages, 5557 KiB

Open AccessArticle

A Comprehensive Analysis of Losses and Efficiency in a Buck ZCS Quasi-Resonant DC/DC Converter

by Nikolay Hinov and Tsvetana Grigorova

J. Low Power Electron. Appl. 2025, 15(2), 34; https://doi.org/10.3390/jlpea15020034 - 2 Jun 2025

Abstract

As power electronics continue to advance, the demand for highly efficient and low-loss DC/DC converters has grown significantly. This article comprehensively analyses ZCS quasi-resonant switch cell losses and efficiency in buck L-type zero-current switching (ZCS) quasi-resonant DC/DC converters. The main part of the [...] Read more.

As power electronics continue to advance, the demand for highly efficient and low-loss DC/DC converters has grown significantly. This article comprehensively analyses ZCS quasi-resonant switch cell losses and efficiency in buck L-type zero-current switching (ZCS) quasi-resonant DC/DC converters. The main part of the study includes a comparative analysis of conduction losses in semiconductor switches of conventional PWM buck converters and zero-current switching (ZCS) quasi-resonant buck converters (L-type), utilizing both specific and generalized design equations. Novel coefficients are introduced that enable the evaluation of static power losses in the classical buck converter compared to those in L-type ZCS buck quasi-resonant converters under identical conditions. The article also discusses design considerations aimed at minimizing static losses. An L-type half-mode zero-current switching (ZCS) buck quasi-resonant DC/DC converter (QRC) is implemented to verify the analytical results. Various simulations were conducted using PSpice in the Texas Instruments simulation environment, along with experimental studies at different switching frequencies and load conditions. The proposed methodology integrates both analytical and simulation approaches to analyze energy losses and key parameters influencing the converter’s efficiency. The obtained results show that the relative error between the analytical, simulation, and experimental results is below 5%. Full article

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18 pages, 5430 KiB

Open AccessArticle

Elbow Joint Angle Estimation Using a Low-Cost and Low-Power Single Inertial Device for Daily Home-Based Self-Rehabilitation

by Manon Fourniol, Rémy Vauché, Guillaume Rao, Eric Watelain and Edith Kussener

J. Low Power Electron. Appl. 2025, 15(2), 33; https://doi.org/10.3390/jlpea15020033 - 19 May 2025

Abstract

In the context of aging populations, it has become necessary to develop new methods and devices for the daily home-based self-rehabilitation of elderly people. To this end, this paper proposes and evaluates the use of an easy-to-use single battery-powered device including a 3D [...] Read more.

In the context of aging populations, it has become necessary to develop new methods and devices for the daily home-based self-rehabilitation of elderly people. To this end, this paper proposes and evaluates the use of an easy-to-use single battery-powered device including a 3D accelerometer and a 3D gyroscope, where light algorithms, such as the complementary filter and the Kalman filter, are implemented to estimate the elbow joint angle. During experiments, a robotic arm and a human arm were used to obtain an error interval for each tested algorithm; the robotic arm allows for reproducible movements and reproducible results, which allows us to independently verify the impact of parameters such as the sensor’s movement speed on the algorithm precision. The experimental results show that the algorithm that uses only accelerometer data is one of the most relevant since it allows us to obtain a Root Mean Square Error between 1.83° and 5.52° at a sensor data rate of 100 Hz, which is similar to the results obtained using the data fusion algorithms tested. Nevertheless, it has a lower power consumption since it requires only 58 cycles when using an ARM Cortex-M4 processor (which is lower than that of the other data fusion algorithms tested by a factor of at least two), and it does not necessitate the additional sensor required by the other data fusion algorithms tested (such as a gyroscope or a magnetometer). The algorithm using only accelerometer data also seems to be the algorithm with the lowest power consumption and should be preferred. Moreover, its power consumption can be reduced by more than the increase in the error when reducing the rate of the data output by the sensor. In this work, a reduction in the data rate from 100 Hz to 10 Hz increased the RMSE by a factor of 1.8 but could reduce the power consumption associated with the sensor and the algorithm’s computation by a factor of 10. Finally, the experimental results show that the higher the speed of the sensor’s motion, the higher the error obtained using only accelerometer data. Nevertheless, the algorithm that uses only accelerometer data remains well suited to rehabilitation exercises or mobility evaluations since the speed of the sensor’s movement is also moderate. Full article

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12 pages, 2371 KiB

Open AccessCommunication

A 0.8 V Low-Power Wide-Tuning-Range CMOS VCO for 802.11ac and IoT C-Band Applications

by Jung-Jen Hsu, Yao-Chian Lin and Stephen J. H. Yang

J. Low Power Electron. Appl. 2025, 15(2), 32; https://doi.org/10.3390/jlpea15020032 - 16 May 2025

Abstract

This paper presents a 0.8 V low-power CMOS voltage-controlled oscillator (VCO) with a wide tuning range, fabricated using a TSMC 0.18 μm process. The proposed design incorporates body-biasing techniques and an optimized varactor structure to achieve a tuning range of 1124 MHz (5.829–4.705 [...] Read more.

This paper presents a 0.8 V low-power CMOS voltage-controlled oscillator (VCO) with a wide tuning range, fabricated using a TSMC 0.18 μm process. The proposed design incorporates body-biasing techniques and an optimized varactor structure to achieve a tuning range of 1124 MHz (5.829–4.705 GHz) and low phase noise of −117.6 dBc/Hz at a 1 MHz offset. Operating at an ultra-low supply voltage of 0.8 V, the VCO consumes only 3.4 mW, demonstrating excellent power efficiency. A buffer circuit is also employed to enhance output symmetry and suppress flicker noise without introducing additional control complexity. With a figure-of-merit (FOM) of −188.6 dBc/Hz and a wide tuning range of 22.2%, the proposed VCO is well-suited for modern low-power communication systems, including 802.11ac, 5G transceivers, satellite links, and compact IoT devices. Full article

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17 pages, 869 KiB

Open AccessArticle

Impact of Mother Wavelet Choice on Fast Wavelet Transform Performances for Integrated ST Segment Monitoring

by Béatrice Guénégo, Caroline Lelandais-Perrault, Emilie Avignon-Meseldzija, Gérard Sou and Philippe Bénabès

J. Low Power Electron. Appl. 2025, 15(2), 31; https://doi.org/10.3390/jlpea15020031 - 12 May 2025

Abstract

The ST segment of an ECG signal is a feature that changes in the event of cardiac ischemia, a condition that is an early warning sign of myocardial infarction. Being able to monitor this feature in real time would be highly beneficial for [...] Read more.

The ST segment of an ECG signal is a feature that changes in the event of cardiac ischemia, a condition that is an early warning sign of myocardial infarction. Being able to monitor this feature in real time would be highly beneficial for preventing recurrent heart attacks. However, to be worn daily, such a monitoring device must be extremely miniaturized, down to the scale of a single integrated circuit. Currently, it is possible to integrate a heart rate detector, but, to our knowledge, no existing work presents a chip capable of detecting ST segment deviation. This is mainly because accurate ST segment measurement requires low-distortion signal processing, as specified in the International Electrotechnical Commission (IEC) standard. At the same time, the system is required to filter out baseline wander, whose frequency components may partially overlap with those of the ST segment. In this study, we relied on wavelet-based analysis and reconstruction to compare several wavelet types. We optimized their hyperparameters to minimize implementation complexity while satisfying the low-distortion constraints. We also propose an ASIC-oriented architecture and evaluate its post-layout performance in terms of area and power consumption. The post-layout results indicate that the Daubechies wavelet db3 offers the best trade-off among the evaluated configurations. It exhibits an area utilization of

1.18

mm² and a post-layout power consumption of

4.89

μ

W, while preserving the ST segment in compliance with the IEC standard, thanks in particular to its effective baseline wandering filtering of

6.9

dB. These results demonstrate the feasibility of embedding automatic ST segment extraction on-chip. Full article

(This article belongs to the Topic Advanced Integrated Circuit Design and Application)

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14 pages, 9820 KiB

Open AccessArticle

Design and Analysis of an Ultra-Wideband High-Precision Active Phase Shifter in 0.18 μm SiGe BiCMOS Technology

by Hao Jiang, Zenglong Zhao, Nengxu Zhu and Fanyi Meng

J. Low Power Electron. Appl. 2025, 15(2), 30; https://doi.org/10.3390/jlpea15020030 - 7 May 2025

Abstract

This paper presents an active phase shifter for phased array system applications, implemented using 0.18 μm SiGe BiCMOS technology. The phase shifter circuit consists of a wideband quadrature signal generator, a vector modulator, an input balun, and an output balun. To enhance the [...] Read more.

This paper presents an active phase shifter for phased array system applications, implemented using 0.18 μm SiGe BiCMOS technology. The phase shifter circuit consists of a wideband quadrature signal generator, a vector modulator, an input balun, and an output balun. To enhance the bandwidth, a polyphase filter is employed as the quadrature signal generator, and a two-stage RC-CR filter with a highly symmetrical miniaturized layout is cascaded to create multiple resonant points, thus extending the phase shifter’s bandwidth to cover the required range. The gain of the variable-gain amplifier within the vector modulator is adjustable by varying the tail current, thereby enlarging the range of selectable points, improving phase-shifting accuracy, and reducing gain fluctuations. The measurement results show that the proposed active phase shifter achieves an RMS phase error of less than 2° and a gain variation ranging from −1.2 dB to 0.1 dB across a 20 GHz to 30 GHz bandwidth at room temperature. The total chip area is 0.4 mm², with a core area of 0.165 mm², and consumes 19.5 mW of power from a 2.5 V supply. Full article

(This article belongs to the Topic Advanced Integrated Circuit Design and Application)

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14 pages, 16692 KiB

Open AccessArticle

A New Type of DC-DC Buck Converter with Soft Start Function and Reduced Voltage Stress

by Xin Wang, Zishuo Li, Zhen Lin and Fanyi Meng

J. Low Power Electron. Appl. 2025, 15(2), 29; https://doi.org/10.3390/jlpea15020029 - 7 May 2025

Abstract

This paper introduces a novel topology called the dual-path step-down converter with auxiliary switches to minimize voltage stress and enable wide voltage conversion ranges. The proposed dual-path step-down converter with auxiliary switches, which uses an inductor and flying capacitor as power conversion components, [...] Read more.

This paper introduces a novel topology called the dual-path step-down converter with auxiliary switches to minimize voltage stress and enable wide voltage conversion ranges. The proposed dual-path step-down converter with auxiliary switches, which uses an inductor and flying capacitor as power conversion components, helps to reduce the voltage stress on the power switches. By adding auxiliary switches, the proposed topology achieves the same voltage conversion ratio range as that of a conventional buck converter. Additionally, soft-start technology is incorporated to reduce the initial inrush current. Furthermore, this paper introduces a system-level design procedure for DC-DC converters. Designed for low-power applications with lithium-ion (Li-ion) batteries, the proposed converter steps down the battery voltage to 1.2 V. With a 380 nH inductor and a 5 µF output capacitor, the converter attains a peak efficiency of 90% under the conditions of 2.7 V to 1.2 V conversion. Full article

(This article belongs to the Topic Application of Innovative Power Electronic Technologies, 2nd Edition)

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14 pages, 3868 KiB

Open AccessArticle

Analytical Implementation of Electron–Phonon Scattering in a Schottky Barrier CNTFET Model

by Ibrahim L. Abdalla, Fatma A. Matter, Ahmed A. Afifi, Mohamed I. Ibrahem, Hesham F. A. Hamed and Eslam S. El-Mokadem

J. Low Power Electron. Appl. 2025, 15(2), 28; https://doi.org/10.3390/jlpea15020028 - 2 May 2025

Abstract

This paper elaborates on the proposal of a new analytical model for a non-ballistic transport scenario for Schottky barrier carbon nanotube field effect transistors (SB-CNTFETs). The non-ballistic transport scenario depends on incorporating the effects of acoustic phonon (A-Ph) and optical phonon (O-Ph) electron [...] Read more.

This paper elaborates on the proposal of a new analytical model for a non-ballistic transport scenario for Schottky barrier carbon nanotube field effect transistors (SB-CNTFETs). The non-ballistic transport scenario depends on incorporating the effects of acoustic phonon (A-Ph) and optical phonon (O-Ph) electron scattering mechanisms. The analytical model is rooted in the solution of the Landauer integral equation, which is modified to account for non-ballistic transport through a set of approximations applied to the Wentzel–Kramers–Brillouin (WKB) transmission probability and the Fermi–Dirac distribution function. Our proposed model was simulated to evaluate the total current and transconductance, considering scenarios both with and without the electron–phonon scattering effect. The simulation results revealed a substantial decrease of approximately 78.6% in both total current and transconductance due to electron–phonon scattering. In addition, we investigated the impact of acoustic phonon (A-Ph) and optical phonon (O-Ph) scattering on the drain current under various conditions, including different temperatures, gate lengths, and nanotube chiralities. This comprehensive analysis helps in understanding how these parameters influence device performance. Compared with experimental data, the model’s simulation results demonstrate a high degree of agreement. Furthermore, our fully analytical model achieves a significantly faster runtime, clocking in at around 2.726 s. This validation underscores the model’s accuracy and reliability in predicting the behavior of SB-CNTFETs under non-ballistic conditions. Full article

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15 pages, 1313 KiB

Open AccessArticle

mTanh: A Low-Cost Inkjet-Printed Vanishing Gradient Tolerant Activation Function

by Shahrin Akter and Mohammad Rafiqul Haider

J. Low Power Electron. Appl. 2025, 15(2), 27; https://doi.org/10.3390/jlpea15020027 - 2 May 2025

Abstract

Inkjet-printed circuits on flexible substrates are rapidly emerging as a key technology in flexible electronics, driven by their minimal fabrication process, cost-effectiveness, and environmental sustainability. Recent advancements in inkjet-printed devices and circuits have broadened their applications in both sensing and computing. Building on [...] Read more.

Inkjet-printed circuits on flexible substrates are rapidly emerging as a key technology in flexible electronics, driven by their minimal fabrication process, cost-effectiveness, and environmental sustainability. Recent advancements in inkjet-printed devices and circuits have broadened their applications in both sensing and computing. Building on this progress, this work has developed a nonlinear computational element coined as mTanh to serve as an activation function in neural networks. Activation functions are essential in neural networks as they introduce nonlinearity, enabling machine learning models to capture complex patterns. However, widely used functions such as Tanh and sigmoid often suffer from the vanishing gradient problem, limiting the depth of neural networks. To address this, alternative functions like ReLU and Leaky ReLU have been explored, yet these also introduce challenges such as the dying ReLU issue, bias shifting, and noise sensitivity. The proposed mTanh activation function effectively mitigates the vanishing gradient problem, allowing for the development of deeper neural network architectures without compromising training efficiency. This study demonstrates the feasibility of mTanh as an activation function by integrating it into an Echo State Network to predict the Mackey–Glass time series signal. The results show that mTanh performs comparably to Tanh, ReLU, and Leaky ReLU in this task. Additionally, the vanishing gradient resistance of the mTanh function was evaluated by implementing it in a deep multi-layer perceptron model for Fashion MNIST image classification. The study indicates that mTanh enables the addition of 3–5 extra layers compared to Tanh and sigmoid, while exhibiting vanishing gradient resistance similar to ReLU. These results highlight the potential of mTanh as a promising activation function for deep learning models, particularly in flexible electronics applications. Full article

(This article belongs to the Special Issue Advancements in Low-Power Ubiquitous Sensing, Computing, and Communication Interfaces for IoT: Circuits, Systems, and Applications)

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Graphical abstract

10 pages, 2701 KiB

Open AccessArticle

Ultra-Thin Al₂O₃ Grown by PEALD for Low-Power Molybdenum Disulfide Field-Effect Transistors

by Shiwei Sun, Dinghao Ma, Boxi Ye, Guanshun Liu, Nanting Luo and Hao Huang

J. Low Power Electron. Appl. 2025, 15(2), 26; https://doi.org/10.3390/jlpea15020026 - 30 Apr 2025

Abstract

The lack of ultra-thin, controllable dielectric layers poses challenges for reducing power consumption in 2D FETs. In this study, plasma-enhanced atomic layer deposition was employed to fabricate a highly reliable, ultra-thin aluminum oxide (Al₂O₃) dielectric layer with a thickness [...] Read more.

The lack of ultra-thin, controllable dielectric layers poses challenges for reducing power consumption in 2D FETs. In this study, plasma-enhanced atomic layer deposition was employed to fabricate a highly reliable, ultra-thin aluminum oxide (Al₂O₃) dielectric layer with a thickness of 4 nm. The Al₂O₃ film grown on highly conductive silicon substrates demonstrated a maximum breakdown field of 5.98 MV/cm and a leakage current density as low as 2.48 × 10⁻⁷ A/cm² at 1 MV/cm. MoS₂ FETs incorporating this Al₂O₃ gate dielectric exhibited high-performance n-type characteristics at a low operating voltage of 1 V, achieving a subthreshold swing (SS) of 65 mV/dec, a threshold voltage (V_th) of −0.96 V, a high carrier mobility (μ) of 34.85 cm²·V⁻¹·s⁻¹, and an on/off current ratio exceeding 10⁶. These results highlight the potential of Al₂O₃ in enabling low-power 2D electronic devices for post-Moore applications. Full article

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10 pages, 2362 KiB

Open AccessArticle

Full-Bridge DC-DC Converter with Synchronous Rectification Based on GaN Transistors

by Xin Wang, Qingsong Zhao, Zenglong Zhao and Fanyi Meng

J. Low Power Electron. Appl. 2025, 15(2), 25; https://doi.org/10.3390/jlpea15020025 - 22 Apr 2025

Cited by 2

Abstract

This study presents a hard-switching full-bridge DC-DC converter with synchronous rectification based on Gallium Nitride (GaN) transistors to evaluate the advantages of GaN devices in power supplies. In comparison to traditional silicon-based devices, GaN transistors are utilized in both the primary and secondary [...] Read more.

This study presents a hard-switching full-bridge DC-DC converter with synchronous rectification based on Gallium Nitride (GaN) transistors to evaluate the advantages of GaN devices in power supplies. In comparison to traditional silicon-based devices, GaN transistors are utilized in both the primary and secondary stages of the converter, exploiting GaN’s lower on-resistance to enhance performance. The converter operates at a switching frequency of 300 kHz, with an input voltage range of 36 V to 75 V, delivering an output of 28 V/42 A. Experimental results show that the GaN-based converter achieves an output power of 1176 W within standard half-brick package dimensions. The measured peak efficiency is 97.1%, and the power density reaches 430 W/in³. These findings demonstrate that GaN-based converters offer superior efficiency and power density compared to conventional silicon-based designs, making them highly suitable for aerospace, automotive, and communication power supplies. Full article

(This article belongs to the Topic Application of Innovative Power Electronic Technologies, 2nd Edition)

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15 pages, 7333 KiB

Open AccessArticle

0.7 V Supply SC Circuits with Relaxed Slew Rate Requirements Using GB-Enhanced Multiple-Output Class AB/AB Op-Amps

by Hector Daniel Rico-Aniles, Anindita Paul, Jaime Ramirez-Angulo, Antonio Lopez-Martin and Ramon G. Carvajal

J. Low Power Electron. Appl. 2025, 15(2), 24; https://doi.org/10.3390/jlpea15020024 - 15 Apr 2025

Abstract

A family of improved low-voltage switched-capacitor circuits is introduced. It is based on the utilization of multiple-output class AB/AB op-amp architectures that provide true sample and hold outputs that are not subject to a reset phase as with conventional switched-capacitor circuits. This feature [...] Read more.

A family of improved low-voltage switched-capacitor circuits is introduced. It is based on the utilization of multiple-output class AB/AB op-amp architectures that provide true sample and hold outputs that are not subject to a reset phase as with conventional switched-capacitor circuits. This feature essentially relaxes the op-amp slew rate requirements, allowing a higher speed and simple low-voltage operation. A power-efficient GB boosting technique based on resistive local common mode feedback is used to significantly improve the GB and internal/external slew rate of the op-amps with only a 36.5% additional power dissipation. Full article

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17 pages, 6539 KiB

Open AccessArticle

Charge Pump Phase-Locked Loop-Based Frequency Conditioning of a MEMS Resonator

by Xinyuan Hu and Yanfeng Jiang

J. Low Power Electron. Appl. 2025, 15(2), 23; https://doi.org/10.3390/jlpea15020023 - 12 Apr 2025

Abstract

MEMS resonators have attracted attention for their wide applications in highly accurate clock references, sensors, wireless communications, frequency control, etc. Most of the output frequencies of MEMS resonators require post-processing or calibration to be accurate enough. In this paper, a charge pump phase-locked [...] Read more.

MEMS resonators have attracted attention for their wide applications in highly accurate clock references, sensors, wireless communications, frequency control, etc. Most of the output frequencies of MEMS resonators require post-processing or calibration to be accurate enough. In this paper, a charge pump phase-locked loop-based frequency conditioning method for MEMS resonators is explored. An optimization scheme is proposed to enhance the frequency stability and signal quality of MEMS resonators. The experimental results show that the method significantly improves the resonator performance and achieves effective control of the resonant frequency. This research provides a new technical path for the design of high-performance MEMS oscillators, which has important theoretical significance and practical application value. Full article

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17 pages, 2374 KiB

Open AccessArticle

A Lightweight and Configurable Flash Filesystem for Low-Power Devices

by Ondrej Kachman, Peter Malík, Marcel Baláž, Libor Majer and Gábor Gyepes

J. Low Power Electron. Appl. 2025, 15(2), 22; https://doi.org/10.3390/jlpea15020022 - 11 Apr 2025

Abstract

Low-power embedded devices are widely used in sensor networks, monitoring systems, and industrial applications. These devices typically rely on internal flash memory, where storage is constrained by bootloaders, communication stacks, and other software. Adding external memory increases cost and energy consumption, making efficient [...] Read more.

Low-power embedded devices are widely used in sensor networks, monitoring systems, and industrial applications. These devices typically rely on internal flash memory, where storage is constrained by bootloaders, communication stacks, and other software. Adding external memory increases cost and energy consumption, making efficient memory utilization essential. This article presents key design concepts for developing an efficient, lightweight, and reliable embedded filesystem. It introduces an improved version of the configurable flash filesystem (CFFS), designed to maximize memory utilization, minimize flash wear, and support portability across hardware platforms and operating systems. Reliability mechanisms integrated into CFFS are also discussed. We compare CFFS with widely used low-power embedded filesystems—LittleFS, SPIFFS, and FDS—highlighting its advantages in memory efficiency and reduced flash memory wear. Experimental results demonstrate that CFFS achieves up to 99% memory utilization while significantly reducing erase operations. Full article

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15 pages, 3377 KiB

Open AccessArticle

Machine Learning Using Approximate Computing

by Padmanabhan Balasubramanian, Syed Mohammed Mosayeeb Al Hady Zaheen and Douglas L. Maskell

J. Low Power Electron. Appl. 2025, 15(2), 21; https://doi.org/10.3390/jlpea15020021 - 9 Apr 2025

Abstract

Approximate computation has emerged as a promising alternative to accurate computation, particularly for applications that can tolerate some degree of error without significant degradation of the output quality. This work analyzes the application of approximate computing for machine learning, specifically focusing on k-means [...] Read more.

Approximate computation has emerged as a promising alternative to accurate computation, particularly for applications that can tolerate some degree of error without significant degradation of the output quality. This work analyzes the application of approximate computing for machine learning, specifically focusing on k-means clustering, one of the more widely used unsupervised machine learning algorithms. The k-means algorithm partitions data into k clusters, where k also denotes the number of centroids, with each centroid representing the center of a cluster. The clustering process involves assigning each data point to the nearest centroid by minimizing the within-cluster sum of squares (WCSS), a key metric used to evaluate clustering quality. A lower WCSS value signifies better clustering. Conventionally, WCSS is computed with high precision using an accurate adder. In this paper, we investigate the impact of employing various approximate adders for WCSS computation and compare their results against those obtained with an accurate adder. Further, we propose a new approximate adder (NAA) in this paper. To assess its effectiveness, we utilize it for the k-means clustering of some publicly available artificial datasets with varying levels of complexity, and compare its performance with the accurate adder and many other approximate adders. The experimental results confirm the efficacy of NAA in clustering, as NAA yields WCSS values that closely match or are identical to those obtained using the accurate adder. We also implemented hardware designs of accurate and approximate adders using a 28 nm CMOS standard cell library. The design metrics estimated show that NAA achieves a 37% reduction in delay, a 22% reduction in area, and a 31% reduction in power compared to the accurate adder. In terms of the power-delay product that serves as a representative metric for energy efficiency, NAA reports a 57% reduction compared to the accurate adder. In terms of the area-delay product that serves as a representative metric for design efficiency, NAA reports a 51% reduction compared to the accurate adder. NAA also outperforms several existing approximate adders in terms of design metrics while preserving clustering effectiveness. Full article

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13 pages, 6647 KiB

Open AccessArticle

A Power-Efficient 50 MHz-BW 76.8 dB Signal-to-Noise-and-Distortion Ratio Continuous-Time 2-2 MASH Delta-Sigma Analog-to-Digital Converter with Digital Calibration

by Zhiyu Li, Xueqian Shang, Haigang Feng and Xinpeng Xing

J. Low Power Electron. Appl. 2025, 15(2), 20; https://doi.org/10.3390/jlpea15020020 - 9 Apr 2025

Abstract

Continuous-time Sigma-Delta (CTSD) Analog-to-Digital Converter (ADC) is widely used in wireless receivers due to its built-in anti-aliasing and resistive input. In order to achieve a wide bandwidth while ensuring low power consumption, this paper proposes a CT 2-2 Multi-stAge Noise-sHaping (MASH) ADC for [...] Read more.

Continuous-time Sigma-Delta (CTSD) Analog-to-Digital Converter (ADC) is widely used in wireless receivers due to its built-in anti-aliasing and resistive input. In order to achieve a wide bandwidth while ensuring low power consumption, this paper proposes a CT 2-2 Multi-stAge Noise-sHaping (MASH) ADC for wireless communication. In order to reduce power consumption, the loop filter adopts a feedforward structure, and the operational amplifier uses complementary differential input pairs and feedforward compensation. The pseudo-random sequence injection and Least Mean Squares (LMS) algorithm are adopted to calibrate the digital noise cancelation filter to match the analog transfer function. The simulation results obtained in 40 nm CMOS show that the presented 2-2 CT MASH ADC achieves a 76.8 dB signal-to-noise-and-distortion ratio (SNDR) at a 50MHz bandwidth (BW) with a 1.6 GHz sampling rate and consumes 29.7 mW power under 1.2/0.9 V supply, corresponding to an excellent figure of merit (FoM) of 169.1 dB. Full article

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Journal of Low Power Electronics and Applications

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