Electronics

19 pages, 675 KB

Open AccessArticle

Efficient n-th Root Computation on Microcontrollers Employing Magic Constants and Modified Newton and Householder Methods

by Cezary J. Walczyk, Maciej Jurgielewicz and Jan L. Cieśliński

Electronics 2026, 15(1), 129; https://doi.org/10.3390/electronics15010129 (registering DOI) - 26 Dec 2025

Abstract

With the growing number of applications in embedded systems—such as IoT modules, smart sensors, and wearable devices—there is an increasing demand for fast and accurate computations on resource-constrained platforms. In this paper, we present a new method for computing n-th roots in floating-point [...] Read more.

With the growing number of applications in embedded systems—such as IoT modules, smart sensors, and wearable devices—there is an increasing demand for fast and accurate computations on resource-constrained platforms. In this paper, we present a new method for computing n-th roots in floating-point arithmetic based on an initial estimate generated by a “magic constant,” followed by one or two iterations of a modified Newton–Raphson or Householder algorithm. For cubic and quartic roots, we provide C implementations operating in single-precision floating-point format. The proposed algorithms are evaluated in terms of maximum relative error and execution time on selected microcontrollers. They exhibit high accuracy and noticeably reduced computation time. For example, our methods for computing cubic roots outperform the standard library function cbrtf() in both speed and precision. The results may be useful in a variety of fields, including biomedical and biophysical applications, statistical analysis, and real-time image and signal processing. Full article

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

19 pages, 5799 KB

Open AccessArticle

An Improved Single-Stage Object Detection Model and Its Application to Oil Seal Defect Detection

by Yangzhuo Chen, Yuhang Wu, Xiaoliang Wu, Weiwei He, Guangtian He and Xiaowen Cai

Electronics 2026, 15(1), 128; https://doi.org/10.3390/electronics15010128 (registering DOI) - 26 Dec 2025

Abstract

Oil seals, as core industrial components, often exhibit defects with sparse features and low contrast, posing significant challenges for traditional vision-based inspection methods. Although deep learning facilitates automatic feature extraction for defect detection, many instance segmentation models are computationally expensive, hindering their deployment [...] Read more.

Oil seals, as core industrial components, often exhibit defects with sparse features and low contrast, posing significant challenges for traditional vision-based inspection methods. Although deep learning facilitates automatic feature extraction for defect detection, many instance segmentation models are computationally expensive, hindering their deployment in real-time edge applications. In this paper, we present an efficient oil seal defect detection model based on an enhanced YOLOv11n architecture (YOLOv11n_CDK). The proposed approach introduces several dynamic convolution variants and integrates the Kolmogorov–Arnold Network (KAN) into the backbone. A newly designed parallel module, the nested asynchronous pooling convolutional module (NAPConv), is also incorporated to form a lightweight yet powerful feature extraction network. Experimental results demonstrate that, compared to the baseline YOLOv11n, our model reduces computational cost by 4.76% and increases mAP@0.5 by 2.14%. When deployed on a Jetson Nano embedded device, the model achieves an average processing time of 6.3 ms per image, corresponding to a frame rate of 105–110 FPS. These outcomes highlight the model’s strong potential for high-performance, real-time industrial deployment, effectively balancing detection accuracy with low computational complexity. Full article

(This article belongs to the Special Issue Computer Vision for Defect Detection, Segmentation and Quality Control in Manufacturing Systems)

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26 pages, 7632 KB

Open AccessArticle

FracLogGPT: A Multimodal Large Language Model for Fracture Interpretation in Imaging Logging

by Hushuang Shen, Ang Li, Liyan Zhang and Xiangxiang Liu

Electronics 2026, 15(1), 127; https://doi.org/10.3390/electronics15010127 (registering DOI) - 26 Dec 2025

Abstract

Imaging logging serves as a critical technology for identifying and characterizing fractures in unconventional oil and gas reservoirs. Despite significant progress in deep learning for automated fracture recognition in this field, the integration of fracture interpretation with large language models remains insufficient. To [...] Read more.

Imaging logging serves as a critical technology for identifying and characterizing fractures in unconventional oil and gas reservoirs. Despite significant progress in deep learning for automated fracture recognition in this field, the integration of fracture interpretation with large language models remains insufficient. To address this, this paper constructs a Chinese fracture image–text pair dataset covering multiple scenarios and proposes “FracLogGPT”, a three-stage multimodal large language model with a parameter scale of approximately 7 billion. Using Qwen2.5-VL-7B as the baseline model, this study employs Domain-Adaptive pre-training (DAPT) to tailor the model to geological and logging contexts. Efficient Supervised Fine-Tuning (SFT) is achieved via the LoRA method, while output style alignment is accomplished through Direct Preference Optimization (DPO) combined with expert preference data. Experimental results on an independent test set show that FracLogGPT achieves a Count-F1 of 0.70 for fracture-count classification, with location and morphology consistency accuracies of 0.49 and 0.43, respectively, and higher text-level BLEU and ROUGE-L scores than larger, non-domain-adapted external models evaluated under the same conditions. Comparative experiments across stages validate the effectiveness of the proposed workflow. In summary, “FracLogGPT” achieves automated identification and expert-like description of imaging logging fractures with approximately 7 billion parameters, providing a reusable training pathway and evaluation workflow for intelligent imaging logging interpretation. Full article

(This article belongs to the Section Artificial Intelligence)

23 pages, 4099 KB

Open AccessArticle

Knowledge-Enhanced Zero-Shot Graph Learning-Based Mobile Application Identification

by Dongfang Zhang, Jianan Huang, Manjun Tian and Lei Guan

Electronics 2026, 15(1), 126; https://doi.org/10.3390/electronics15010126 (registering DOI) - 26 Dec 2025

Abstract

With the proliferation of mobile devices, identifying previously unseen mobile applications has become a critical challenge in network security. Traditional application identification approaches rely heavily on fixed training categories and limited traffic features, making them ineffective in real-world environments. To address this problem, [...] Read more.

With the proliferation of mobile devices, identifying previously unseen mobile applications has become a critical challenge in network security. Traditional application identification approaches rely heavily on fixed training categories and limited traffic features, making them ineffective in real-world environments. To address this problem, we propose KZGNN, a knowledge-enhanced zero-shot graph neural network for mobile application identification. KZGNN first constructs a unified mobile application knowledge graph that integrates high-level semantic metadata with fine-grained network behavior, enabling structured representation of application characteristics. Building on this, KZGNN introduces a relation-aware dual-channel propagation mechanism that separates semantic relations and behavioral interactions into dedicated GNN pathways and adaptively fuses them through attention. To support zero-shot recognition, KZGNN projects node embeddings and category semantics into a shared embedding space, where a structure-preserving constraint maintains global semantic geometry and improves generalization to unseen categories. Experiments on a dataset of 160 mobile applications show that KZGNN outperforms nine state-of-the-art traffic classification baselines and achieves a 5.2% improvement in identifying unseen application categories, demonstrating its effectiveness for mobile application identification in zero-shot scenarios. Full article

(This article belongs to the Special Issue Novel Methods Applied to Security and Privacy Problems, Volume II)

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23 pages, 2840 KB

Open AccessArticle

A High-Performance Branch Control Mechanism for GPGPU Based on RISC-V Architecture

by Yao Cheng, Yi Man and Xinbing Zhou

Electronics 2026, 15(1), 125; https://doi.org/10.3390/electronics15010125 (registering DOI) - 26 Dec 2025

Abstract

General-Purpose Graphics Processing Units (GPGPUs) rely on warp scheduling and control flow management to organize parallel thread execution, making efficient control flow mechanisms essential for modern GPGPU design. Currently, the mainstream RISC-V GPGPU Vortex adopts the Single Instruction Multiple Threads (SIMT) stack control [...] Read more.

General-Purpose Graphics Processing Units (GPGPUs) rely on warp scheduling and control flow management to organize parallel thread execution, making efficient control flow mechanisms essential for modern GPGPU design. Currently, the mainstream RISC-V GPGPU Vortex adopts the Single Instruction Multiple Threads (SIMT) stack control mechanism. This approach introduces high complexity and performance overhead, becoming a major limitation for further improving control efficiency. To address this issue, this paper proposes a thread-mask-based branch control mechanism for the RISC-V architecture. The mechanism introduces explicit mask primitives at the Instruction Set Architecture (ISA) level and directly manages the active status of threads within a warp through logical operations, enabling branch execution without jumps and thus reducing the overhead of the original control flow mechanism. Unlike traditional thread mask mechanisms in GPUs, our design centers on RISC-V and realizes co-optimization at both the ISA and microarchitecture levels. The mechanism was modeled and validated on Vortex SimX. Experimental results show that, compared with the Vortex SIMT stack mechanism, the proposed approach maintains correct control semantics while reducing branch execution cycles by an average of 31% and up to 40%, providing a new approach for RISC-V GPGPU control flow optimization. Full article

(This article belongs to the Special Issue Celebrating the 70th Anniversary of Beijing University of Posts and Telecommunications—Computer Science and Engineering)

20 pages, 1176 KB

Open AccessArticle

DnCNN-Based Denoising Model for Low-Dose Myocardial CT Perfusion Imaging

by Mahmud Hasan, Aaron So and Mahmoud R. El-Sakka

Electronics 2026, 15(1), 124; https://doi.org/10.3390/electronics15010124 (registering DOI) - 26 Dec 2025

Abstract

Unlike high-dose scans, low-dose cardiac CT perfusion imaging reduces patient radiation exposure and thereby the risk of potential health effects. However, it introduces significant image noise, degrading diagnostic quality and limiting clinical assessment. Denoising is thus a critical preprocessing step to enhance image [...] Read more.

Unlike high-dose scans, low-dose cardiac CT perfusion imaging reduces patient radiation exposure and thereby the risk of potential health effects. However, it introduces significant image noise, degrading diagnostic quality and limiting clinical assessment. Denoising is thus a critical preprocessing step to enhance image quality without compromising anatomical or perfusion details. Traditionally used reconstruction-domain methods, such as Iterative Reconstruction and Compressed Sensing, are often limited by algorithmic complexity, dependence on raw sinogram data, and restricted adaptability. Conversely, image-domain methods offer more adaptable denoising options. Recently, learning-based approaches have further expanded this flexibility and demonstrated state-of-the-art performance across various denoising tasks. In this work, we present a deep learning-based denoising method specifically tuned for low-dose cardiac CT perfusion imaging. Our model is trained to reduce noise while preserving structural integrity and temporal contrast dynamics, which are critical for downstream analysis. Unlike many existing methods, our approach is optimized for perfusion data, where temporal consistency is essential. Residual cardiac motion remains a separate challenge, which we aim to address in our future work. Experimental results show significant improvements in quantitative image quality, using both reference-based and no-reference metrics, such as MSE/PSNR/SSIM and NIQE/FID/KID, as well as improved accuracy of perfusion measurements. Full article

(This article belongs to the Special Issue Recent Advances and Applications of Machine Learning in Pattern Recognition)

30 pages, 2489 KB

Open AccessArticle

Enhancing IoT Common Service Functions with Blockchain: From Analysis to Standards-Based Prototype Implementation

by Jiho Lee, Jieun Lee, Zehua Wang and JaeSeung Song

Electronics 2026, 15(1), 123; https://doi.org/10.3390/electronics15010123 (registering DOI) - 26 Dec 2025

Abstract

The proliferation of Internet of Things (IoT) applications in safety-critical domains, such as healthcare, smart transportation, and industrial automation, demands robust solutions for data integrity, traceability, and security that surpass the capabilities of centralized databases. This paper analyzes how blockchain technology can be [...] Read more.

The proliferation of Internet of Things (IoT) applications in safety-critical domains, such as healthcare, smart transportation, and industrial automation, demands robust solutions for data integrity, traceability, and security that surpass the capabilities of centralized databases. This paper analyzes how blockchain technology can be integrated with core IoT service functions—including data management, security, device management, group coordination, and automated billing—to enhance immutability, trust, and operational efficiency. Our analysis identifies practical use cases such as consensus-driven tamper-proof storage, role-based access control, firmware integrity verification, and automated micropayments. These use cases showcase blockchain’s potential beyond traditional data storage. Building on this, we propose a novel framework that integrates a permissioned distributed ledger with a standardized IoT service layer platform through a Blockchain Interworking Proxy Entity (BlockIPE). This proxy dynamically maps IoT service functions to smart contracts, enabling flexible data routing to conventional databases or blockchains based on the application requirements. We implement a Dockerized prototype that integrates a C-based oneM2M platform with an Ethereum-compatible permissioned ledger (implemented using Hyperledger Besu) via BlockIPE, incorporating security features such as role-based access control. For performance evaluation, we use Ganache to isolate proxy-level overhead and scalability. At the proxy level, the blockchain-integrated path achieves processing latencies (≈86 ms) comparable to, and slightly faster than, the traditional database path. Although the end-to-end latency is inherently governed by on-chain confirmation (≈0.586–1.086 s), the scalability remains high (up to 100,000 TPS). This validates that the architecture secures IoT ecosystems with manageable operational overhead. Full article

(This article belongs to the Special Issue Blockchain Technologies: Emerging Trends and Real-World Applications)

24 pages, 4921 KB

Open AccessArticle

A Non-Reconstruction Multi-Coset Sampling-Based Algorithm for Frequency Estimation with FMCW Lidar

by Jianxin Gai, Bo Liu and Zhongle Gao

Electronics 2026, 15(1), 122; https://doi.org/10.3390/electronics15010122 (registering DOI) - 26 Dec 2025

Abstract

Frequency-Modulated Continuous Wave (FMCW) lidar for long-distance measurements face challenges in signal acquisition and frequency estimation due to the high sampling rates required, leading to increased processing load, cost, and power consumption. Although sub-Nyquist sampling can alleviate the burden of high sampling rates, [...] Read more.

Frequency-Modulated Continuous Wave (FMCW) lidar for long-distance measurements face challenges in signal acquisition and frequency estimation due to the high sampling rates required, leading to increased processing load, cost, and power consumption. Although sub-Nyquist sampling can alleviate the burden of high sampling rates, it requires a complex reconstruction process that degrades real-time performance. In this study, we propose a frequency estimation algorithm based on multi-coset sampling (MCS) that not only reduces the sampling rate but also avoids reconstructing the original signal. This algorithm performs a preliminary frequency estimation by exploiting the relationship among the signal support set, the measured sequences by sampling spectrum, and the original signal spectrum, and then refines the spectrum to obtain an accurate frequency estimate. Since the algorithm relies solely on the sampled sequences for estimation, frequency ambiguity may occur during the calculation. We analyze the causes of ambiguity and propose a support set determination method to eliminate this issue. Simulation results demonstrate that the proposed algorithm attains the Cramér–Rao lower bound (CRLB) at low signal-to-noise ratios. It achieves a 10-fold improvement over Nyquist method and a 35 dB SNR reduction compared with the original MCS, while maintaining stable performance down to −20 dB. Full article

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

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20 pages, 9176 KB

Open AccessArticle

Junction Temperature and Failure Behavior of High-Power Press Pack vs. Module Diodes Under High Anomalous Surge Currents

by Fawad Ahmad, Luis Vaccaro, Armel Asongu Nkembi, Mario Marchesoni, Federico Portesine and Giulio Anyanwu

Electronics 2026, 15(1), 121; https://doi.org/10.3390/electronics15010121 (registering DOI) - 26 Dec 2025

Abstract

Junction temperature is considered a critical parameter that can directly affect the reliability and power handling capabilities of semiconductor devices. Effective thermal management, particularly under high-surge-current conditions, is therefore essential to maintain a lower junction temperature in order to enhance device performance and [...] Read more.

Junction temperature is considered a critical parameter that can directly affect the reliability and power handling capabilities of semiconductor devices. Effective thermal management, particularly under high-surge-current conditions, is therefore essential to maintain a lower junction temperature in order to enhance device performance and prevent device failure. Among various thermal management strategies, packaging technology plays an important role in optimizing junction temperature and enhancing the robustness of the device. In this article, a comparative analysis of high-power diodes is performed by investigating their junction temperature behavior and surge current handling capability. Moreover, an insulated module diode and a press-pack diode with pressure contact technology (PCT), both with identical specifications and power ratings, are selected for analysis. A 10 ms half-sine surge current waveform generator is developed both experimentally and in simulations to replicate realistic surge events. Experimental measurements of the forward voltage drop across varying surge levels are used to analyze device failure behavior. In addition, electro-thermal simulations are also employed in PSIM 2025.0 software to estimate and compare the temperature. Furthermore, this study enables practical insights into device thermal performance, robustness, and surge current handling capabilities, enabling a performance comparison between the two packaging technologies. Full article

(This article belongs to the Special Issue Advances in Semiconductor Devices and Applications)

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23 pages, 10893 KB

Open AccessArticle

Reducing the Contact Erosion of AC Contactors Based on Novel Control Circuits

by Angxin Tong and Xiaojun Tang

Electronics 2026, 15(1), 120; https://doi.org/10.3390/electronics15010120 - 26 Dec 2025

Abstract

During the switch-off process, the contact erosion generated by the AC contactor will seriously affect its performance, thereby directly influencing the normal operation of the power equipment. Therefore, aiming at the problem of contact erosion caused by contact bounce during the switch-on and [...] Read more.

During the switch-off process, the contact erosion generated by the AC contactor will seriously affect its performance, thereby directly influencing the normal operation of the power equipment. Therefore, aiming at the problem of contact erosion caused by contact bounce during the switch-on and switch-off period of AC contactors, this paper designed the driving circuits during the switch-on, holding, and switch-off processes. During the switch-on process, DC excitation was used instead of AC excitation to eliminate or reduce the contact bounce. During the holding process, low-voltage DC was used instead of high-voltage AC to save energy and reduce coil losses. During the switch-off process, the contact current was used as the control factor, and the scheme of shunting control was employed to achieve the goal of few or even no arcs. In addition, in order to detect the high voltage and large current signals in the main circuit, the three-phase voltage acquisition circuit and three-phase current acquisition circuit were designed. Therefore, a whole process dynamic control which included the switch-on, holding, and switch-off was formed. Through simulation testing and relevant experimental testing, the results demonstrated the correctness and effectiveness of the designed circuit. Full article

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14 pages, 2571 KB

Open AccessArticle

RMP: Robust Multi-Modal Perception Under Missing Condition

by Xin Ma, Xuqi Cai, Yuansheng Song, Yu Liang, Gang Liu and Yijun Yang

Electronics 2026, 15(1), 119; https://doi.org/10.3390/electronics15010119 - 26 Dec 2025

Abstract

Multi-modal perception is a core technology for edge devices to achieve safe and reliable environmental understanding in autonomous driving scenarios. In recent years, most approaches have focused on integrating complementary signals from diverse sensors, including cameras and LiDAR, to improve scene understanding in [...] Read more.

Multi-modal perception is a core technology for edge devices to achieve safe and reliable environmental understanding in autonomous driving scenarios. In recent years, most approaches have focused on integrating complementary signals from diverse sensors, including cameras and LiDAR, to improve scene understanding in complex traffic environments, thereby attracting significant attention. However, in real-world applications, sensor failures frequently occur; for instance, cameras may malfunction in scenarios with poor illumination, which severely reduces the accuracy of perception models. To overcome this issue, we propose a robust multi-modal perception pipeline designed to improve model performance under missing modality conditions. Specifically, we design a missing feature reconstruction mechanism to reconstruct absent features by leveraging intra-modal common clues. Furthermore, we introduce a multi-modal adaptive fusion strategy to facilitate adaptive multi-modal integration through inter-modal feature interactions. Extensive experiments on the nuScenes benchmark demonstrate that our method achieves SOTA-level performance under missing-modality conditions. Full article

(This article belongs to the Special Issue Hardware and Software Co-Design in Intelligent Systems)

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2 pages, 139 KB

Open AccessCorrection

Correction: Etemad et al. A New Approach for the Incorporation of the End-User’s Smart Power–Electronic Interface in Voltage Support Application. Electronics 2022, 11, 765

by Reza Etemad, Mohammad Sadegh Ghazizadeh, Mehrdad Ahmadi Kamarposhti, Ilhami Colak and Kei Eguchi

Electronics 2026, 15(1), 118; https://doi.org/10.3390/electronics15010118 - 26 Dec 2025

Abstract

In the original publication [...] Full article

13 pages, 730 KB

Open AccessArticle

A Binary Convolution Accelerator Based on Compute-in-Memory

by Wenpeng Cui, Zhe Zheng, Pan Li, Ming Li, Yu Liu and Yingying Chi

Electronics 2026, 15(1), 117; https://doi.org/10.3390/electronics15010117 - 25 Dec 2025

Abstract

As AI workloads move to edge devices, the von Neumann architecture is hindered by memory- and power-wall limitations We present an SRAM-based compute-in-memory binary convolution accelerator that stores and transports only 1-bit weights and activations, maps MACs to bitwise XNOR–popcount, and fuses BatchNorm, [...] Read more.

As AI workloads move to edge devices, the von Neumann architecture is hindered by memory- and power-wall limitations We present an SRAM-based compute-in-memory binary convolution accelerator that stores and transports only 1-bit weights and activations, maps MACs to bitwise XNOR–popcount, and fuses BatchNorm, HardTanh, and binarization into a single affine-and-threshold uni. Residual paths are handled by in-accumulator summation to minimize data movement. FPGA validation shows 87.6% CIFAR 10 accuracy consistent with a bit-accurate software reference, a compute-only latency of 2.93 ms per 32 × 32 image at 50 MHz, sustained at only 1.52 W. These results demonstrate an efficient and practical path to deploying edge models under tight power and memory budgets. Full article

(This article belongs to the Special Issue Wireless Multimodal Communications for Integrated Heterogeneous Networks)

29 pages, 994 KB

Open AccessArticle

A High-Performance Computing Cluster Intelligent Scheduling Algorithm Based on Graph Neural Network and Actor–Critic

by Xuemei Bai, Jingbo Zhou and Zhijun Wang

Electronics 2026, 15(1), 116; https://doi.org/10.3390/electronics15010116 - 25 Dec 2025

Abstract

With the rapid growth of computation-intensive applications, high-performance computing (HPC) clusters have become essential for scientific computing, AI training, and industrial simulation. However, job scheduling in HPC clusters remains challenging due to heterogeneous resources, diverse task demands, and complex constraints. Traditional scheduling methods [...] Read more.

With the rapid growth of computation-intensive applications, high-performance computing (HPC) clusters have become essential for scientific computing, AI training, and industrial simulation. However, job scheduling in HPC clusters remains challenging due to heterogeneous resources, diverse task demands, and complex constraints. Traditional scheduling methods such as FCFS, SJF, and Backfilling show limited adaptability and struggle to achieve global optimization in large-scale environments. To address these issues, this paper proposes an intelligent scheduling method based on graph neural networks (GNNs) and deep reinforcement learning. A resource-constrained job–node bipartite graph is constructed to model task–node matching relationships, with node and task features capturing resource states and task demands. A GNN is employed to encode the scheduling state, and an Actor–Critic reinforcement learning framework is used to guide scheduling decisions. Simulation results show that, compared with other schedulers, the proposed GNN–Actor–Critic approach significantly improves average waiting time, average turnaround time, average slowdown, and overall resource utilization, demonstrating its effectiveness and practicality for HPC cluster scheduling. Full article

(This article belongs to the Section Computer Science & Engineering)

26 pages, 8097 KB

Open AccessArticle

A Prediction Error Order Scheme for Reversible Data Hiding in Image

by Yonghui Chen and Weichen Fang

Electronics 2026, 15(1), 115; https://doi.org/10.3390/electronics15010115 - 25 Dec 2025

Abstract

Prediction Error Ordering (PEO) can integrate the encoding gains of both prediction and sorting by replacing the PVO (Pixel Value Ordering) pixel blocks with prediction-error blocks before sorting. It remains an open topic to construct a consistent, high-accuracy, and block-based prediction method for [...] Read more.

Prediction Error Ordering (PEO) can integrate the encoding gains of both prediction and sorting by replacing the PVO (Pixel Value Ordering) pixel blocks with prediction-error blocks before sorting. It remains an open topic to construct a consistent, high-accuracy, and block-based prediction method for both the cover and stego images, which are the images before and after embedding the secret data. This paper proposes a novel scheme that explicitly exploits image self-similarity through a deterministic, non-linear prediction framework. Our scheme constructs four independent but self-similar images using a down-sampling and a bicubic-based up-sampling algorithm. Then, a linear ridge regression model learns the self-similarity among pixels with the same coordinates across the four dependent images. It also provides two new 2D mappings to reduce embedding disturbances further. Experimental results demonstrate that our PEO scheme achieves average PSNRs of 59.7 and 58.6 dB at 0.04 bpp, 56.7 and 56.0 dB at 0.08 bpp on the Kodak and USC-SIPI image datasets, respectively. Full article

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15 pages, 8567 KB

Open AccessArticle

Color-to-Grayscale Image Conversion Based on the Entropy and the Local Contrast

by Lina Zhang, Jiale Yang and Yamei Xu

Electronics 2026, 15(1), 114; https://doi.org/10.3390/electronics15010114 - 25 Dec 2025

Abstract

Color-to-grayscale conversion is a fundamental preprocessing task with widespread applications in digital printing, electronic ink displays, medical imaging, and artistic photo stylization. A primary challenge in this domain is to simultaneously preserve global luminance distribution and local contrast. To address this, we propose [...] Read more.

Color-to-grayscale conversion is a fundamental preprocessing task with widespread applications in digital printing, electronic ink displays, medical imaging, and artistic photo stylization. A primary challenge in this domain is to simultaneously preserve global luminance distribution and local contrast. To address this, we propose an adaptive conversion method centered on a novel objective function that integrates information entropy with Edge Content (EC), a metric for local gradient information. The key advantage of our approach is its ability to generate grayscale results that maintain both rich overall contrast and fine-grained local details. Compared with previous adaptive linear methods, our approach demonstrates superior qualitative and quantitative performance. Furthermore, by eliminating the need for computationally expensive edge detection, the proposed algorithm provides an effective solution to the color-to-grayscale conversion. Full article

(This article belongs to the Section Computer Science & Engineering)

20 pages, 906 KB

Open AccessArticle

Towards Bridging GIS and 3D Modeling: A Framework for Learning Coordinate Conversion Using Machine Learning

by Thamir M. Qadah, Shema Alhazmi, Mohd Khaled Shambour, Mohammed Murad and Abdullah N. Al-Hawsawi

Electronics 2026, 15(1), 113; https://doi.org/10.3390/electronics15010113 - 25 Dec 2025

Abstract

Simulating what-if scenarios in 3D environments has become popular due to its potential to improve planning and operations for large-scale, complex events, such as the annual Hajj. Despite the extensive availability of spatial data through Geographic Information Systems (GIS)—information systems specialized in collecting, [...] Read more.

Simulating what-if scenarios in 3D environments has become popular due to its potential to improve planning and operations for large-scale, complex events, such as the annual Hajj. Despite the extensive availability of spatial data through Geographic Information Systems (GIS)—information systems specialized in collecting, organizing, and analyzing geospatial information—these resources remain underutilized for such use cases. Three-dimensional modelers create simulations for these use cases and build them from scratch despite the availability of GIS data, which can be tedious and error-prone. We raise the question of whether it is reasonable to use machine learning (ML) algorithms to learn coordinate conversion systems, laying the foundations for accelerating the construction of 3D environments and achieving more accurate results. In this paper, we introduce a simple yet novel framework that facilitates learning coordinate conversion systems. Using our framework, we evaluate 35 ML models and provide a detailed analysis of their prediction performance, overfitting characteristics, and trade-offs in terms of time and model size. Notably, 14 of the ML models demonstrate near-perfect learning (i.e., R-squared very close to 1.0). Furthermore, we use grid search to find better parameter settings for underperforming models. Our results demonstrate that ML can help 3D modelers automate manual tasks and improve the efficiency of 3D modeling from GIS data. Full article

(This article belongs to the Section Artificial Intelligence)

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23 pages, 5034 KB

Open AccessArticle

A3DSimVP: Enhancing SimVP-v2 with Audio and 3D Convolution

by Junfeng Yang, Mingrui Long, Hongjia Zhu, Limei Liu, Wenzhi Cao, Qin Li and Han Peng

Electronics 2026, 15(1), 112; https://doi.org/10.3390/electronics15010112 - 25 Dec 2025

Abstract

In modern high-demand applications, such as real-time video communication, cloud gaming, and high-definition live streaming, achieving both superior transmission speed and high visual fidelity is paramount. However, unstable networks and packet loss remain major bottlenecks, making accurate and low-latency video error concealment a [...] Read more.

In modern high-demand applications, such as real-time video communication, cloud gaming, and high-definition live streaming, achieving both superior transmission speed and high visual fidelity is paramount. However, unstable networks and packet loss remain major bottlenecks, making accurate and low-latency video error concealment a critical challenge. Traditional error control strategies, such as Forward Error Correction (FEC) and Automatic Repeat Request (ARQ), often introduce excessive latency or bandwidth overhead. Meanwhile, receiver-side concealment methods struggle under high motion or significant packet loss, motivating the exploration of predictive models. SimVP-v2, with its efficient convolutional architecture and Gated Spatiotemporal Attention (GSTA) mechanism, provides a strong baseline by reducing complexity and achieving competitive prediction performance. Despite its merits, SimVP-v2’s reliance on 2D convolutions for implicit temporal aggregation limits its capacity to capture complex motion trajectories and long-term dependencies. This often results in artifacts such as motion blur, detail loss, and accumulated errors. Furthermore, its single-modality design ignores the complementary contextual cues embedded in the audio stream. To overcome these issues, we propose A3DSimVP (Audio- and 3D-Enhanced SimVP-v2), which integrates explicit spatio-temporal modeling with multimodal feature fusion. Architecturally, we replace the 2D depthwise separable convolutions within the GSTA module with their 3D counterparts, introducing a redesigned GSTA-3D module that significantly improves motion coherence across frames. Additionally, an efficient audio–visual fusion strategy supplements visual features with contextual audio guidance, thereby enhancing the model’s robustness and perceptual realism. We validate the effectiveness of A3DSimVP’s improvements through extensive experiments on the KTH dataset. Our model achieves a PSNR of 27.35 dB, surpassing the 27.04 of the SimVP-v2 baseline. Concurrently, our improved A3DSimVP model reduces the loss metrics on the KTH dataset, achieving an MSE of 43.82 and an MAE of 385.73, both lower than the baseline. Crucially, our LPIPS metric is substantially lowered to 0.22. These data tangibly confirm that A3DSimVP significantly enhances both structural fidelity and perceptual quality while maintaining high predictive accuracy. Notably, A3DSimVP attains faster inference speeds than the baseline with only a marginal increase in computational overhead. These results establish A3DSimVP as an efficient and robust solution for latency-critical video applications. Full article

(This article belongs to the Special Issue Digital Intelligence Technology and Applications, 2nd Edition)

27 pages, 12739 KB

Open AccessArticle

Unveiling Tank-Liquid Sloshing Effect on Joint Boom Stability of a Field Sprayer Under Different Running Process

by Shunzeng Wang, Zhenduo Zhang, Guoping Wang, Xianhui Zhou and Junjie Li

Electronics 2026, 15(1), 111; https://doi.org/10.3390/electronics15010111 - 25 Dec 2025

Abstract

The strong vibration excited by the tank-liquid sloshing of the field sprayer can result in uneven spraying, vehicle-body cartwheel, and the break of the boom during running process. So, it is crucial to investigate the stability of a field-sprayer boom under hazardous operating [...] Read more.

The strong vibration excited by the tank-liquid sloshing of the field sprayer can result in uneven spraying, vehicle-body cartwheel, and the break of the boom during running process. So, it is crucial to investigate the stability of a field-sprayer boom under hazardous operating conditions on a specified ground surface, focusing on the coupled effects of tank-liquid sloshing, boom-connection stiffness, and nozzle jetting-force characteristics. A fluid–structure interaction framework combining volume of fluid (VOF)-based sloshing simulation, finite element modeling, and full-scale experiments is developed. It is shown that high liquid-filling ratios significantly amplify transient sloshing forces during braking and swerving, inducing strong direction-dependent boom vibrations and a distinct resonance band near 50–60 Hz. Increasing connection stiffness raises natural frequencies and reduces damping, thereby enlarging vibration amplitudes. The jetting-force amplitude attenuates X-direction vibration, while frequency variation produces notable resonance excitation aligned with the harmonics of the boom. Simulation and experimental results demonstrate strong consistency, validating the proposed model. The findings reveal key coupling mechanisms governing boom stability and provide practical guidance for structural optimization and vibration suppression in field sprayers. Full article

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