Electronics

22 pages, 2533 KB

Open AccessArticle

Heuristic-Based Computing-Aware Routing for Dynamic Networks

by Zhiyi Lin, Lingjie Wang, Wenxin Ning, Yuxiang Zhao, Li Yu and Jian Jiang

Electronics 2025, 14(18), 3724; https://doi.org/10.3390/electronics14183724 - 19 Sep 2025

The development of the computing power network has brought about a revolutionary effect on network routing architecture. As a result, the computing-aware network routing problem has been raised to explore routing various computational tasks to appropriate computing resources in the dynamic network. In [...] Read more.

The development of the computing power network has brought about a revolutionary effect on network routing architecture. As a result, the computing-aware network routing problem has been raised to explore routing various computational tasks to appropriate computing resources in the dynamic network. In this study, we propose a heuristic-based computing-aware routing algorithm to achieve the optimal routing path by considering the dynamic network performance and computing resource status simultaneously. Our proposed approach models the dynamic network using time-varying node and edge weights, which are obtained by mapping basic performance indicators to weights according to quality-of-service requirements. This allows us to improve the user’s experience more effectively during the routing process. Moreover, a novel heuristic-based algorithm, which creatively transforms the computing-aware routing problem into a single-source shortest path problem, has been designed to achieve the comprehensive optimal routing path. The experimental results, based on both simulated networks and a real dedicated network in Zhejiang, demonstrate that our proposed method can obtain the comprehensive optimal routing path with a lower computing time cost than enumerating search. Furthermore, our proposed computing-aware routing method has been proven to be robust to the dynamics of the network, computing resources, and service load changes. Full article

15 pages, 2791 KB

Open AccessArticle

Multi-Branch Knowledge-Assisted Proximal Policy Optimization for Design of MS-to-MS Vertical Transition with Multi-Layer Pixel Structures

by Ze-Ming Wu, Zheng Li, Ruo-Yu Liang, Xiao-Chun Li, Ken Ning and Jun-Fa Mao

Electronics 2025, 14(18), 3723; https://doi.org/10.3390/electronics14183723 - 19 Sep 2025

Abstract

This article proposes a wideband microstrip-to-microstrip vertical transition with multi-layer pixel structures, alongside a multi-branch knowledge-assisted proximal policy optimization (MB-KPPO) method for its automatic design. The proposed transition consists of the three-layer pixel structures with high design degrees of freedom to realize a [...] Read more.

This article proposes a wideband microstrip-to-microstrip vertical transition with multi-layer pixel structures, alongside a multi-branch knowledge-assisted proximal policy optimization (MB-KPPO) method for its automatic design. The proposed transition consists of the three-layer pixel structures with high design degrees of freedom to realize a wide bandwidth. The MB-KPPO adopts a multi-branch policy network instead of a single-branch policy network in the PPO to improve design efficiency. In addition, the MB-KPPO integrates a fully connected shape generation mechanism to incorporate physical requirements. An MS-to-MS vertical multi-layer pixel transition is designed and fabricated by PCB technology. Measurement results show that the multi-layer transition has a frequency range from 3.5 to 17.8 GHz, with a bandwidth that is 25% higher than the single-layer pixel transition towards higher frequencies. Full article

(This article belongs to the Section Microwave and Wireless Communications)

24 pages, 4963 KB

Open AccessArticle

A Hybrid Deep Learning and Optical Flow Framework for Monocular Capsule Endoscopy Localization

by İrem Yakar, Ramazan Alper Kuçak, Serdar Bilgi, Onur Ferhanoglu and Tahir Cetin Akinci

Electronics 2025, 14(18), 3722; https://doi.org/10.3390/electronics14183722 - 19 Sep 2025

Abstract

Pose estimation and localization within the gastrointestinal tract, particularly the small bowel, are crucial for invasive medical procedures. However, the task is challenging due to the complex anatomy, homogeneous textures, and limited distinguishable features. This study proposes a hybrid deep learning (DL) method [...] Read more.

Pose estimation and localization within the gastrointestinal tract, particularly the small bowel, are crucial for invasive medical procedures. However, the task is challenging due to the complex anatomy, homogeneous textures, and limited distinguishable features. This study proposes a hybrid deep learning (DL) method combining Convolutional Neural Network (CNN)-based pose estimation and optical flow to address these challenges in a simulated small bowel environment. Initial pose estimation was used to assess the performance of simultaneous localization and mapping (SLAM) in such complex settings, using a custom endoscope prototype with a laser, micromotor, and miniaturized camera. The results showed limited feature detection and unreliable matches due to repetitive textures. To improve this issue, a hybrid CNN-based approach enhanced with Farneback optical flow was applied. Using consecutive images, three models were compared: Hybrid ResNet-50 with Farneback optical flow, ResNet-50, and NASNetLarge pretrained on ImageNet. The analysis showed that the hybrid model outperformed both ResNet-50 (0.39 cm) and NASNetLarge (1.46 cm), achieving the lowest RMSE of 0.03 cm, with feature-based SLAM failing to provide reliable results. The hybrid model also gained a competitive inference speed of 241.84 ms per frame, outperforming ResNet-50 (316.57 ms) and NASNetLarge (529.66 ms). To assess the impact of the optical flow choice, Lucas–Kanade was also implemented within the same framework and compared with the Farneback-based results. These results demonstrate that combining optical flow with ResNet-50 enhances pose estimation accuracy and stability, especially in textureless environments where traditional methods struggle. The proposed method offers a robust, real-time alternative to SLAM, with potential applications in clinical capsule endoscopy. The results are positioned as a proof-of-concept that highlights the feasibility and clinical potential of the proposed framework. Future work will extend the framework to real patient data and optimize for real-time hardware. Full article

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20 pages, 1266 KB

Open AccessReview

Research Trends and Challenges of Integrated Constant On-Time (COT) Buck Converters

by Seok-Tae Koh and Sunghyun Bae

Electronics 2025, 14(18), 3721; https://doi.org/10.3390/electronics14183721 - 19 Sep 2025

Abstract

Constant on-time (COT) buck converters offer fast transient responses and a simple architecture but face challenges like switching frequency variation, instability with low-equivalent series resistance (ESR) capacitors, and DC output voltage offset. This paper reviews advanced COT control techniques developed to overcome these [...] Read more.

Constant on-time (COT) buck converters offer fast transient responses and a simple architecture but face challenges like switching frequency variation, instability with low-equivalent series resistance (ESR) capacitors, and DC output voltage offset. This paper reviews advanced COT control techniques developed to overcome these limitations. We examine methods for frequency stabilization (e.g., adaptive on-time, phase-locked loop), stability with low-ESR capacitors (e.g., passive and active ripple injection, virtual inductor current), and improved DC regulation (e.g., offset cancellation). This review also covers techniques for optimizing transient response and multiphase architectures for high-current applications. Full article

(This article belongs to the Section Circuit and Signal Processing)

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22 pages, 410 KB

Open AccessArticle

Adapting Co-Design for Crisis Contexts: Lessons Learned Engaging Nonprofits

by Delvin Varghese, Joshua Paolo Seguin, Meriem Tebourbi, Tom Bartindale, Charishma Ratnam, Rebecca Powell, Rebecca Wickes and Patrick Olivier

Electronics 2025, 14(18), 3720; https://doi.org/10.3390/electronics14183720 - 19 Sep 2025

Abstract

During crisis situations like the COVID-19 pandemic, nonprofit organizations must rapidly adapt their community engagement approaches, yet traditional co-design methods often fall short in such time-sensitive, multi-stakeholder contexts. This paper examines how design methods need to evolve when working with nonprofits during crises [...] Read more.

During crisis situations like the COVID-19 pandemic, nonprofit organizations must rapidly adapt their community engagement approaches, yet traditional co-design methods often fall short in such time-sensitive, multi-stakeholder contexts. This paper examines how design methods need to evolve when working with nonprofits during crises by analyzing our intensive six-month collaboration with five Australian nonprofits serving migrant youth communities. Through Action Research involving over 130 co-design sessions, workshops, and stakeholder meetings, we developed and iteratively refined a social media engagement playbook. Our findings reveal three key methodological innovations: (1) adapting co-design methods for crisis contexts through flexible, asynchronous engagement; (2) managing multiple stakeholder relationships through what we term “nonprofit ecologies”—understanding organizations’ overlapping roles and relationships—and (3) balancing immediate needs with long-term goals through infrastructuring approaches that build sustainable capacity. This research contributes practical methods for conducting collaborative design during crises while advancing a theoretical understanding of how traditional design approaches must adapt to support nonprofits in complex, time-sensitive situations. Full article

(This article belongs to the Special Issue Advances in Human-Computer Interaction: Challenges and Opportunities)

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26 pages, 4236 KB

Open AccessArticle

Transfer Learning-Based Distance-Adaptive Global Soft Biometrics Prediction in Surveillance

by Sonjoy Ranjon Das, Henry Onilude, Bilal Hassan, Preeti Patel and Karim Ouazzane

Electronics 2025, 14(18), 3719; https://doi.org/10.3390/electronics14183719 - 19 Sep 2025

Abstract

Soft biometric prediction—including age, gender, and ethnicity—is critical in surveillance applications, yet often suffers from performance degradation as the subject-to-camera distance increases. This study hypothesizes that embedding distance-awareness into the training process can mitigate such degradation and enhance model generalization across varying visual [...] Read more.

Soft biometric prediction—including age, gender, and ethnicity—is critical in surveillance applications, yet often suffers from performance degradation as the subject-to-camera distance increases. This study hypothesizes that embedding distance-awareness into the training process can mitigate such degradation and enhance model generalization across varying visual conditions. We propose a distance-adaptive, multi-task deep learning framework built upon EfficientNetB3, augmented with task-specific heads and trained progressively across four distance intervals (4 m to 10 m). A weighted composite loss function is employed to balance classification and regression objectives. The model is evaluated on a hybrid dataset combining the Front-View Gait (FVG) and MMV annotated pedestrian datasets, totaling over 19,000 samples. Experimental results demonstrate that the framework achieves up to 95% gender classification accuracy at 4 m and retains 85% accuracy at 10 m. Ethnicity prediction maintains an accuracy above 65%, while age estimation achieves a mean absolute error (MAE) ranging from 1.1 to 1.5 years. These findings validate the model’s robustness across distances and its superiority over conventional static learning approaches. Despite challenges such as computational overhead and annotation demands, the proposed approach offers a scalable and real-time-capable solution for distance-resilient biometric systems. Full article

(This article belongs to the Special Issue Multi-Modal Biometrics for Surveillance and Digital Evidence Processing in Smart Cities)

21 pages, 5551 KB

Open AccessArticle

State-Space Modelling of Schottky Diode Rectifiers Including Parasitic and Coupling Effects up to the Terahertz Band

by Martins Aizanabor Odiamenhi, Haleh Jahanbakhsh Basherlou, Chan Hwang See, Naser Ojaroudi Parchin, Keng Goh and Hongnian Yu

Electronics 2025, 14(18), 3718; https://doi.org/10.3390/electronics14183718 - 19 Sep 2025

Abstract

A nonlinear state-space model for Schottky diode rectifiers is presented that incorporates junction dynamics, layout parasitic effects, and electromagnetic coupling effects. Unlike prior approaches, the model resolves conduction intervals under harmonic-rich excitation and integrates electromagnetic voltage–current feedback to capture field-induced perturbations at high [...] Read more.

A nonlinear state-space model for Schottky diode rectifiers is presented that incorporates junction dynamics, layout parasitic effects, and electromagnetic coupling effects. Unlike prior approaches, the model resolves conduction intervals under harmonic-rich excitation and integrates electromagnetic voltage–current feedback to capture field-induced perturbations at high frequencies. The framework was validated through the design of a 5.8 GHz rectifier, achieving 62% RF–DC efficiency at −10 dBm into a 500 Ω load, with close agreement between the simulation and measurement. The results confirm the model’s predictive accuracy and its utility for high-efficiency rectenna systems in microwave and terahertz applications. Full article

(This article belongs to the Special Issue Low-Voltage Mixed-Signal CMOS Integrated Circuits for Emerging Applications)

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15 pages, 673 KB

Open AccessArticle

Integrating and Benchmarking KpqC in TLS/X.509

by Minjoo Sim, Gyeongju Song, Siwoo Eum, Minwoo Lee, Seyoung Yoon, Anubhab Baksi and Hwajeong Seo

Electronics 2025, 14(18), 3717; https://doi.org/10.3390/electronics14183717 - 19 Sep 2025

Abstract

Advances in quantum computing pose a fundamental threat to classical public-key cryptosystems, including RSA and elliptic-curve cryptography (ECC), which form the foundation for authentication and key exchange in the Transport Layer Security (TLS) protocol. In response to these emerging threats, Korea launched the [...] Read more.

Advances in quantum computing pose a fundamental threat to classical public-key cryptosystems, including RSA and elliptic-curve cryptography (ECC), which form the foundation for authentication and key exchange in the Transport Layer Security (TLS) protocol. In response to these emerging threats, Korea launched the KpqC (Korea Post-Quantum Cryptography) project in 2021 to design, evaluate, and standardize domestic PQC algorithms. To the best of our knowledge, this is the first systematic evaluation of the finalized Korean PQC algorithms (HAETAE, AIMer, SMAUG-T, NTRU+) within a production-grade TLS/X.509 stack, enabling direct comparison against NIST PQC and ECC baselines. To contextualize KpqC performance, we further compare against NIST-standardized PQC algorithms and classical ECC baselines. Our evaluation examines both static overhead (certificate size) and dynamic overhead (TLS 1.3 handshake latency) across computation-bound (localhost) and network-bound (LAN) scenarios, including embedded device and hybrid TLS configurations. Our results show that KpqC certificates are approximately 4.6–48.8× larger than ECC counterparts and generally exceed NIST PQC sizes. In computation-bound tests, both NIST PQC (ML-KEM) and KpqC hybrids exhibited similar handshake latency increases of approximately 8–9× relative to ECC. In network-bound tests, the difference between the two families was negligible, with relative overhead typically around 30–41%. These findings offer practical guidance for balancing security level, key size, packet size, and latency and support phased PQC migration strategies in real-world TLS deployments. Full article

(This article belongs to the Special Issue Trends in Information Systems and Security)

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16 pages, 5288 KB

Open AccessArticle

Development of a Load Monitoring Sensor for the Wire Tightener

by Yuxiong Zhang, Qikun Yuan, Tao Shui, Gang Hu, Xuanlin Chen and Yan Shi

Electronics 2025, 14(18), 3716; https://doi.org/10.3390/electronics14183716 - 19 Sep 2025

Abstract

The wire tightener is a critical tool in the construction and maintenance of power lines. Failure to detect tension overload in a timely manner may lead to plastic deformation or even breakage of the tool, potentially causing serious safety accidents. To address this [...] Read more.

The wire tightener is a critical tool in the construction and maintenance of power lines. Failure to detect tension overload in a timely manner may lead to plastic deformation or even breakage of the tool, potentially causing serious safety accidents. To address this issue, a force monitoring sensor was developed to track the real-time load on wire tighteners. In terms of hardware design, a foil strain gauge was integrated with an ultra-low-power mixed-signal microcontroller based on the mechanical characteristics of the wire tightener, enabling accurate acquisition and processing of load data. Low-power LoRa technology was employed for wireless data transmission, and an adaptive sleep–wake strategy was implemented to optimize power efficiency during data collection. The sensor’s material, geometry, and structure were tailored to the tool’s composition and working environment. Experimental results showed that the average relative error between the sensor readings and the reference values was less than 0.5%. The sensor has been successfully deployed in practical engineering applications, consuming approximately 4500 mWh over an 8 h continuous monitoring period. Full article

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24 pages, 902 KB

Open AccessArticle

Differentiable Selection of Bit-Width and Numeric Format for FPGA-Efficient Deep Networks

by Kawthar Dellel, Emanuel Trabes, Aymen Zayed, Hassene Faiedh and Carlos Valderrama

Electronics 2025, 14(18), 3715; https://doi.org/10.3390/electronics14183715 - 19 Sep 2025

Abstract

Quantization-aware training (QAT) has emerged as a key strategy for enabling efficient deep learning inference on resource-constrained platforms. Yet, most existing approaches rely on static, manually selected numeric formats—fixed-point or floating-point—and fixed bit-widths, limiting their adaptability and often requiring extensive design effort or [...] Read more.

Quantization-aware training (QAT) has emerged as a key strategy for enabling efficient deep learning inference on resource-constrained platforms. Yet, most existing approaches rely on static, manually selected numeric formats—fixed-point or floating-point—and fixed bit-widths, limiting their adaptability and often requiring extensive design effort or architecture search. In this work, we introduce a novel QAT framework that breaks this rigidity by jointly learning, during training, both the numeric representation format and the associated bit-widths in an end-to-end differentiable manner. At the core of our method lies a unified parameterization that is capable of emulating both fixed- and floating-point arithmetic, paired with a bit-aware loss function that penalizes excessive precision in a hardware-aligned fashion. We demonstrate that our approach achieves state-of-the-art trade-offs between accuracy and compression on MNIST, CIFAR-10, and CIFAR-100, reducing average bit-widths to as low as 1.4 with minimal accuracy loss. Furthermore, FPGA implementation using Xilinx FINN confirms over

5 \times

LUT and

4 \times

BRAM savings. This is the first QAT method to unify numeric format learning with differentiable precision control, enabling highly deployable, precision-adaptive deep neural networks. Full article

(This article belongs to the Special Issue Intelligent Embedded Systems: Latest Advances and Applications)

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21 pages, 3009 KB

Open AccessArticle

A Synergistic Fault Diagnosis Method for Rolling Bearings: Variational Mode Decomposition Coupled with Deep Learning

by Shuzhen Wang, Xintian Su, Jinghan Li, Fei Li, Mingwei Li, Yafei Ren, Guoqiang Wang, Nianfeng Shi and Huafei Qian

Electronics 2025, 14(18), 3714; https://doi.org/10.3390/electronics14183714 - 19 Sep 2025

Abstract

To address the limitations of the traditional methods that are used to extract features from non-stationary signals and capture temporal dependency relationships, a rolling bearing fault diagnosis method combining variational mode decomposition (VMD) and deep learning is proposed. A hybrid VMD-CNN-Transformer model is [...] Read more.

To address the limitations of the traditional methods that are used to extract features from non-stationary signals and capture temporal dependency relationships, a rolling bearing fault diagnosis method combining variational mode decomposition (VMD) and deep learning is proposed. A hybrid VMD-CNN-Transformer model is constructed, where VMD is used to adaptively decompose bearing vibration signals into multiple intrinsic mode functions (IMFs). The convolutional neural network (CNN) captures the local features of each modal time series, while the multi-head self-attention mechanism of the Transformer captures the global dependencies of each mode, enabling the global analysis and fusion of features from each mode. Finally, a fully connected layer is used to classify the 10 fault types. The experimental results on the Case Western Reserve University bearing dataset demonstrate that the model achieves a fault diagnosis accuracy of 99.48%, which is significantly higher than that of single or traditional combined methods, providing a new technical path for the intelligent diagnosis of rolling bearing faults. Full article

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22 pages, 14929 KB

Open AccessArticle

Educational Evaluation with MLLMs: Framework, Dataset, and Comprehensive Assessment

by Yuqing Chen, Yixin Li, Yupei Ren, Yixin Liu and Yiping Ma

Electronics 2025, 14(18), 3713; https://doi.org/10.3390/electronics14183713 - 19 Sep 2025

Abstract

With the rapid development of Multimodal Large Language Models (MLLMs) in education, their applications have mainly focused on content generation tasks such as text writing and courseware production. However, automated assessment of non-exam learning outcomes remains underexplored. This study shifts the application of [...] Read more.

With the rapid development of Multimodal Large Language Models (MLLMs) in education, their applications have mainly focused on content generation tasks such as text writing and courseware production. However, automated assessment of non-exam learning outcomes remains underexplored. This study shifts the application of MLLMs from content generation to content evaluation and designs a lightweight and extensible framework to enable automated assessment of students’ multimodal work. We constructed a multimodal dataset comprising student essays, slide decks, and presentation videos from university students, which were annotated by experts across five educational dimensions. Based on horizontal educational evaluation dimensions (Format Compliance, Content Quality, Slide Design, Verbal Expression, and Nonverbal Performance) and vertical model capability dimensions (consistency, stability, and interpretability), we systematically evaluated four leading multimodal large models (GPT-4o, Gemini 2.5, Doubao1.6, and Kimi 1.5) in assessing non-exam learning outcomes. The results indicate that MLLMs demonstrate good consistency with human evaluations across various assessment dimensions, with each model exhibiting its own strengths. Additionally, they possess high explainability and perform better in text-based tasks than in visual tasks, but their scoring stability still requires improvement. This study demonstrates the potential of MLLMs for non-exam learning assessment and provides a reference for advancing their applications in education. Full article

(This article belongs to the Special Issue Techniques and Applications of Multimodal Data Fusion)

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18 pages, 1018 KB

Open AccessArticle

An Event-Based Time-Incremented SNN Architecture Supporting Energy-Efficient Device Classification

by David L. Weathers, Michael A. Temple and Brett J. Borghetti

Electronics 2025, 14(18), 3712; https://doi.org/10.3390/electronics14183712 - 19 Sep 2025

Abstract

Recent advances in Radio Frequency (RF)-based device classification have shown promise in enabling secure and efficient wireless communications. However, the energy efficiency and low-latency processing capabilities of neuromorphic computing have yet to be fully leveraged in this domain. This paper is a first [...] Read more.

Recent advances in Radio Frequency (RF)-based device classification have shown promise in enabling secure and efficient wireless communications. However, the energy efficiency and low-latency processing capabilities of neuromorphic computing have yet to be fully leveraged in this domain. This paper is a first step toward enabling an end-to-end neuromorphic system for RF device classification, specifically supporting development of a neuromorphic classifier that enforces temporal causality without requiring non-neuromorphic classifier pre-training. This Spiking Neural Network (SNN) classifier streamlines the development of an end-to-end neuromorphic device classification system, further expanding the energy efficiency gains of neuromorphic processing to the realm of RF fingerprinting. Using experimentally collected WirelessHART transmissions, the TI-SNN achieves classification accuracy above 90% while reducing fingerprint density by nearly seven-fold and spike activity by over an order of magnitude compared to a baseline Rate-Encoded SNN (RE-SNN). These reductions translate to significant potential energy savings while maintaining competitive accuracy relative to Random Forest and CNN baselines. The results position the TI-SNN as a step toward a fully neuromorphic “RF Event Radio” capable of low-latency, energy-efficient device discrimination at the edge. Full article

(This article belongs to the Special Issue Advances in 5G and Beyond Mobile Communication)

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27 pages, 5516 KB

Open AccessArticle

A Robot Companion with Adaptive Object Preferences and Emotional Responses Enhances Naturalness in Human–Robot Interaction

by Marcos Maroto-Gómez, Sofía Álvarez-Arias, Juan Rodríguez-Huelves, Arecia Segura-Bencomo and María Malfaz

Electronics 2025, 14(18), 3711; https://doi.org/10.3390/electronics14183711 - 19 Sep 2025

Abstract

Autonomous robot companions must engage users to create long-lasting bonds that promote their better and frequent use. Previous studies in the area revealed that a personalised human–robot interaction facilitates such connections, leading people to use robots more frequently, improving how they perceive the [...] Read more.

Autonomous robot companions must engage users to create long-lasting bonds that promote their better and frequent use. Previous studies in the area revealed that a personalised human–robot interaction facilitates such connections, leading people to use robots more frequently, improving how they perceive the robot. This paper presents a biologically inspired system based on reinforcement learning to endow care-dependent robot companions with adaptive preferences for objects and dynamic emotional responses that depend on the interaction context. The system generates and adapts the robot’s preferences towards objects based on user actions, simulated internal needs, and other factors such as the kind of object. We integrate the system into Mini, which is a robot companion that simulates behaviour inspired by the famous Tamagotchi toy to promote human–robot bonding. Mini encourages users to care for it by providing objects that restore its hunger, thirst, and boredom, reacting to the actions taken by users. We conducted a within-subjects user study where participants interacted with two robots: with preferences towards objects and emotional responses, and without them. The results indicate that participants perceived the robot with preferences and emotions as more natural—Animacy, Intelligence, and Agency dimensions—but not more likeable and sociable; however, most explicitly indicated their preferences towards the robot with adaptive preferences and emotions in the posterior analysis. Full article

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4 pages, 179 KB

Open AccessEditorial

Advanced Control Techniques for Power Converter and Drives

by Daniele Scirè and Gianpaolo Vitale

Electronics 2025, 14(18), 3710; https://doi.org/10.3390/electronics14183710 - 19 Sep 2025

Abstract

Advanced control is now central to performance, robustness, and the ability to achieve the highest power density in modern power converters [...] Full article

(This article belongs to the Special Issue Advanced Control Techniques for Power Converter and Drives)

16 pages, 3480 KB

Open AccessArticle

Reinforcement Learning for Robot Assisted Live Ultrasound Examination

by Chenyang Li, Tao Zhang, Ziqi Zhou, Baoliang Zhao, Peng Zhang and Xiaozhi Qi

Electronics 2025, 14(18), 3709; https://doi.org/10.3390/electronics14183709 - 19 Sep 2025

Abstract

Due to its portability, non-invasiveness, and real-time capabilities, ultrasound imaging has been widely adopted for liver disease detection. However, conventional ultrasound examinations heavily rely on operator expertise, leading to high workload and inconsistent imaging quality. To address these challenges, we propose a Robotic [...] Read more.

Due to its portability, non-invasiveness, and real-time capabilities, ultrasound imaging has been widely adopted for liver disease detection. However, conventional ultrasound examinations heavily rely on operator expertise, leading to high workload and inconsistent imaging quality. To address these challenges, we propose a Robotic Ultrasound Scanning System (RUSS) based on reinforcement learning to automate the localization of standard liver planes. It can help reduce physician burden while improving scanning efficiency and accuracy. The reinforcement learning agent employs a Deep Q-Network (DQN) integrated with LSTM to control probe movements within a discrete action space, utilizing the cross-sectional area of the abdominal aorta region as the criterion for standard plane determination. System performance was comprehensively evaluated against a target standard plane, achieving an average Peak Signal-to-Noise Ratio (PSNR) of 24.51 dB and a Structural Similarity Index (SSIM) of 0.70, indicating high fidelity in the acquired images. Furthermore, a mean Dice coefficient of 0.80 for the abdominal aorta segmentation confirmed high anatomical localization accuracy. These preliminary results demonstrate the potential of our method for achieving consistent and autonomous ultrasound scanning. Full article

(This article belongs to the Topic Robot Manipulation Learning and Interaction Control)

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17 pages, 3136 KB

Open AccessArticle

MS Mamba: Spectrum Forecasting Method Based on Enhanced Mamba Architecture

by Dingyin Liu, Donghui Xu, Guojie Hu and Wang Zhang

Electronics 2025, 14(18), 3708; https://doi.org/10.3390/electronics14183708 - 18 Sep 2025

Abstract

Spectrum prediction is essential for cognitive radio, enabling dynamic management and enhanced utilization, particularly in multi-band environments. Yet, its complex spatiotemporal nature and non-stationarity pose significant challenges for achieving high accuracy. Motivated by this, we propose a multi-scale Mamba-based multi-band spectrum prediction method. [...] Read more.

Spectrum prediction is essential for cognitive radio, enabling dynamic management and enhanced utilization, particularly in multi-band environments. Yet, its complex spatiotemporal nature and non-stationarity pose significant challenges for achieving high accuracy. Motivated by this, we propose a multi-scale Mamba-based multi-band spectrum prediction method. The core Mamba module combines Bidirectional Selective State Space Models (SSMs) for long-range dependencies and dynamic convolution for local features, efficiently extracting spatiotemporal characteristics. A multi-scale pyramid and adaptive prediction head select appropriate feature levels per prediction step, avoiding full-sequence processing to ensure accuracy while reducing computational cost. Experiments on real-world datasets across multiple frequency bands demonstrate effective handling of spectrum non-stationarity. Compared to baseline models, the method reduces root mean square error (RMSE) by 14.9% (indoor) and 7.9% (outdoor) while cutting GPU memory by 17%. Full article

(This article belongs to the Special Issue Cognitive Radio Networks: Recent Developments and Emerging Trends)

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13 pages, 733 KB

Open AccessCommunication

Real-Time-Sensing-Assisted Intelligent Communication for Internet of Things

by Shengfeng Zhang, Lizhi Qin and Weixing Sheng

Electronics 2025, 14(18), 3707; https://doi.org/10.3390/electronics14183707 - 18 Sep 2025

Abstract

With the rapid development of the Internet of Things (IoT), electromagnetic devices are increasingly being deployed in dense and resource-limited environments, resulting in severe mutual interference within limited spectral and spatial resources. To address this issue, a real-time sensing-assisted intelligent communication method is [...] Read more.

With the rapid development of the Internet of Things (IoT), electromagnetic devices are increasingly being deployed in dense and resource-limited environments, resulting in severe mutual interference within limited spectral and spatial resources. To address this issue, a real-time sensing-assisted intelligent communication method is proposed which adaptively selects appropriate communication schemes based on the electromagnetic environment to achieve robust, intelligent communication. A key challenge lies in mitigating the self-interference caused by the communication transmit signal on wideband sensing. Focusing on self-interference suppression for wideband sensing receivers, this paper first presents a self-interference reconstruction and suppression architecture. Then, a closed-form expression for suppression performance is theoretically derived, and the impact of imperfect time synchronization between the interference and reference signals on suppression effectiveness is analyzed. Simulation results verify the theoretical analysis and demonstrate that, under identical normalized fractional delays, the degradation in interference suppression performance of the compressed sensing-based receiver is smaller than that of the uncompressed receiver. Specifically, when the normalized time synchronization error is 0.5, the 2-fold compressed wideband receiver achieves a 6.9 dB improvement in suppression capability compared to the uncompressed receiver. Full article

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19 pages, 1003 KB

Open AccessArticle

Health Assessment of Electricity Meters Based on Deep Learning-Improved Survival Analysis Model

by Jing Yang, Wenbo Ye, Jianchuan Wu, Renxin Xiao and Minyong Xin

Electronics 2025, 14(18), 3706; https://doi.org/10.3390/electronics14183706 - 18 Sep 2025

Abstract

The health of electricity meters directly affects measurement accuracy and the interests of users. Traditional evaluation methods for electricity meters are limited by static error detection and manual calibration, and are unable to capture dynamic operating conditions or the complex influence of the [...] Read more.

The health of electricity meters directly affects measurement accuracy and the interests of users. Traditional evaluation methods for electricity meters are limited by static error detection and manual calibration, and are unable to capture dynamic operating conditions or the complex influence of the power environment. To address this issue, this paper proposes an enhanced Cox proportional hazard (CoxPH) model based on Transformer for evaluating the health of electricity meters through a data-driven approach. This model integrates the data collected by the terminal (such as three-phase voltage, current, power, etc.) and operation and maintenance records. After data preprocessing, key covariates were extracted, including the average values of three-phase voltage and current fluctuations, current polarity reversal, and measurement error. The Transformer-based Cox proportional hazard (Trans CoxPH) model overcomes the linear assumption of the traditional CoxPH model by utilizing the self-attention and multi-head attention mechanisms of Transformer, and is able to capture the nonlinear relationships and time dependencies in time-series power data. Experimental results show that the performance of the Trans CoxPH model is superior to the traditional CoxPH model, temporal convolutional network-based Cox proportional hazard (TCN-CoxPH) model, extreme gradient boosting-based Cox proportional hazard (XGBoost CoxPH) model, and DeepSurvival long short-term memory (DeepSurvival LSTM) model. On the validation set, its concordance index (C-index) reaches 0.7827 with a Brier score of only 0.0501, significantly improving prediction accuracy and generalization ability. This model can effectively identify complex patterns and provides a reliable tool for the intelligent operation and maintenance of a power metering system. Full article

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