AI is employed in image processing to enhance and manipulate images through various techniques like denoising, super-resolution, and image restoration. Deep learning models and algorithms enable improved image quality, object recognition, and advanced image editing capabilities for a wide range of applications including photography, medical imaging, and computer vision.
Researchers introduced "DeepRFreg," a hybrid model combining deep neural networks and random forests, significantly enhancing particle identification (PID) in high-energy physics experiments. This innovation improves precision and reduces misidentification in particle detection.
Researchers have developed a bridge inspection method using computer vision and augmented reality (AR) to enhance fatigue crack detection. This innovative approach utilizes AR headset videos and computer vision algorithms to detect cracks, displaying results as holograms for improved visualization and decision-making.
Researchers applied deep learning (DL) models, including ResNet-34, to segment canola plants from other species in the field, treating non-canola plants as weeds. Using datasets containing 3799 canola images, the study demonstrated that ResNet-34 achieved superior performance, highlighting its potential for precision agriculture and innovative weed control strategies.
Researchers developed an automated system utilizing UAVs and deep learning to monitor and maintain remote gravel runways in Northern Canada. This system accurately detects defects and evaluates runway smoothness, proving more effective and reliable than traditional manual methods in harsh and isolated environments.
A systematic review in the journal Sensors analyzed 77 studies on facial and pose emotion recognition using deep learning, highlighting methods like CNNs and Vision Transformers. The review examined trends, datasets, and applications, providing insights into state-of-the-art techniques and their effectiveness in psychology, healthcare, and entertainment.
A comprehensive review highlights the evolution of object-tracking methods, sensors, and datasets in computer vision, guiding developers in selecting optimal tools for diverse applications.
Researchers developed an advanced automated system for early plant disease detection using an ensemble of deep-learning models, achieving superior accuracy on the PlantVillage dataset. The study introduced novel image processing and data balancing techniques, significantly enhancing model performance and demonstrating the system's potential for real-world agricultural applications.
A novel framework combining deep learning and preprocessing algorithms significantly improved particle detection in manufacturing, addressing challenges posed by heterogeneous backgrounds. The framework, validated through extensive experimentation, enhanced in-situ process monitoring, offering robust, real-time solutions for diverse industrial applications.
Researchers harness convolutional neural networks (CNNs) to recognize Shen embroidery, achieving 98.45% accuracy. By employing transfer learning and enhancing MobileNet V1 with spatial pyramid pooling, they provide crucial technical support for safeguarding this cultural art form.
Researchers present a groundbreaking study on the crystallization kinetics of (Ba,Ra)SO4 solid solutions, vital in subsurface energy applications. Leveraging microfluidic experiments coupled with computer vision techniques, they unveil crystal growth rates and morphologies, overcoming challenges posed by radium's radioactivity.
In a recent paper published in Scientific Reports, researchers introduced a novel image denoising approach that combines dense block architectures and residual learning frameworks. The Sequential Residual Fusion Dense Network efficiently handles Gaussian and real-world noise by progressively integrating shallow and deep features, demonstrating superior performance across diverse datasets.
Researchers introduce a novel method for edge detection in color images by integrating Support Vector Machine (SVM) with Social Spider Optimization (SSO) algorithms. The two-stage approach demonstrates superior accuracy and quality compared to existing methods, offering potential applications in various domains such as object detection and medical image analysis.
Researchers combined X-ray tomography with machine learning (ML) to analyze degradation in Pb-free solder balls, revealing intergranular fatigue cracking as the primary failure mode during thermal cycling. Their study investigated the effect of bismuth (Bi) content on solder properties, enhancing fatigue resistance and delaying recrystallization. The findings advance the development of sustainable solder alloys and offer insights for optimizing microelectronics reliability.
Researchers introduced a deep convolutional neural network (DCNN) model for accurately detecting and classifying grape leaf diseases. Leveraging a dataset of grape leaf images, the DCNN model outperformed conventional CNN models, demonstrating superior accuracy and reliability in identifying black rot, ESCA, leaf blight, and healthy specimens.
This review explores the critical role of image-processing technologies in structural health monitoring (SHM) for civil infrastructures. It highlights the integration of artificial intelligence (AI) and machine learning (ML) to enhance SHM automation and accuracy. Various imaging modalities, including drones, thermography, LiDAR, and satellite imagery, are discussed for damage detection, crack identification, and deformation monitoring.
Researchers introduced two novel predictive models employing metaheuristic algorithms, Backtracking Search Algorithm (BSA) and Equilibrium Optimizer (EO), combined with artificial neural networks (ANNs) to assess the bearing capacity of footings on two-layered soil masses. Both BSA-ANN and EO-ANN models demonstrated improved prediction accuracy over conventional ANN models, with EO exhibiting superior performance.
Researchers unveil IMS-VSLAM, an advanced algorithm blending visual and inertial sensors to bolster wheeled robot navigation in low-texture environments. With superior accuracy and real-time performance, it marks a significant leap in robotic autonomy and efficiency.
Researchers from China introduce CDI-YOLO, an algorithm marrying coordination attention with YOLOv7-tiny for swift and precise PCB defect detection. With superior accuracy and a balance between parameters and speed, it promises efficient quality control in electronics and beyond.
Researchers introduced a groundbreaking method for rectangling stitched images using a reparameterized transformer structure and assisted learning network. Their approach, emphasizing content fidelity and boundary regularity, outperformed existing methods with minimal parameters, showcasing its potential for diverse applications requiring panoramic views.
Researchers employ deep learning (DL) techniques alongside fine-tuned optimizers to enhance the detection of parasitic organisms in microscopy images, presenting a breakthrough in medical diagnostics. By leveraging diverse datasets and optimizing DL models with various optimizers, including Adam, SGD, and RMSprop, exceptional accuracy rates of up to 99.96% are achieved, revolutionizing the efficiency of parasitic disease diagnosis.
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