A neural network is a computational model inspired by the structure and function of the human brain. It consists of interconnected artificial neurons that process and transmit information, enabling machine learning tasks such as pattern recognition, classification, and regression by learning from labeled data.
Researchers present a novel myoelectric control (MEC) framework employing Bayesian optimization to enhance convolutional neural network (CNN)-based gesture recognition systems using surface electromyogram (sEMG) signals. The study demonstrates improved accuracy and generalization, crucial for advancing prosthetic devices and human-computer interfaces, and highlights the potential for broader applications in diverse sEMG signal types and neural network architectures.
Researchers from multiple countries introduced a groundbreaking method using machine learning (ML) models to predict the effluent soluble chemical oxygen demand (SCOD) in a two-stage anaerobic onsite sanitation system. Outperforming conventional models, the ML approach, led by the artificial neural network (ANN), not only enhances prediction accuracy but also offers simplicity, speed, and reliability in optimizing and controlling wastewater treatment processes, marking a significant leap in sustainable sanitation technology.
In a groundbreaking study, researchers revolutionized mine fire simulations by integrating neural networks with the Fire Dynamics Simulator (FDS) software. The hybrid approach provided rapid and accurate estimates of environmental parameters during mine fires, offering crucial insights for timely emergency decision-making in confined spaces.
Researchers from Iran and Turkey showcase the power of machine learning, employing artificial neural networks (ANN) and support vector regression (SVR) to analyze the optical properties of zinc titanate nanocomposite. The study compares these machine learning techniques with the conventional nonlinear regression method, revealing superior accuracy and efficiency in assessing spectroscopic ellipsometry data, offering insights into the nanocomposite's potential applications in diverse fields.
This article introduces LC-Net, a novel convolutional neural network (CNN) model designed for precise leaf counting in rosette plants, addressing challenges in plant phenotyping. Leveraging SegNet for superior leaf segmentation, LC-Net incorporates both original and segmented leaf images, showcasing robustness and outperforming existing models in accurate leaf counting, offering a promising advancement for agricultural research and high-throughput plant breeding efforts.
This study introduces an advanced AI-driven model for optimizing the conjunctive operation of groundwater and surface water resources. Focused on mitigating water scarcity challenges in semiarid regions like Iran, the hybrid simulation-optimization model, integrating symbiotic organism search and moth swarm algorithms with an artificial neural network (ANN) simulator, outperforms traditional methods, offering a powerful solution for sustainable water resource management in arid environments.
This research pioneers the use of acoustic emission and artificial neural networks (ANN) to detect partial discharge (PD) in ceramic insulators, crucial for electrical system reliability. With a focus on defects caused by environmental factors, the study achieved a 96.03% recognition rate using ANNs, further validated by support vector machine (SVM) and K-nearest neighbor (KNN) algorithms, showcasing a significant advancement in real-time monitoring for electrical power network safety.
Researchers unveil LGN, a groundbreaking graph neural network (GNN)-based fusion model, addressing the limitations of existing protein-ligand binding affinity prediction methods. The study demonstrates the model's superiority, emphasizing the importance of incorporating ligand information and evaluating stability and performance for advancing drug discovery in computational biology.
Scientists present a groundbreaking study published in Scientific Reports, introducing an intelligent transfer learning technique utilizing deep learning, particularly a convolutional neural network (CNN), to predict diseases in black pepper leaves. The research showcases the potential of advanced technologies in plant health monitoring, offering a comprehensive approach from dataset acquisition to the development of deep neural network models for early-stage leaf disease identification in agriculture.
Canadian researchers at Western University and the Vector Institute unveil a groundbreaking method employing deep neural networks to predict the memorability of face photographs. Outperforming previous models, this innovation demonstrates near-human consistency and versatility in handling different face shapes, with potential applications spanning social media, advertising, education, security, and entertainment.
Researchers unveil a groundbreaking approach to tackle escalating construction solid waste challenges through a machine vision (MV) algorithm. By automating the generation and annotation of synthetic datasets, the study significantly enhances efficiency and accuracy, demonstrating superior performance in construction waste sorting over manually labeled datasets, paving the way for sustainable urban waste management.
This groundbreaking article presents a comprehensive three-tiered approach, utilizing machine learning to assess Division-1 Women's basketball performance at the player, team, and conference levels. Achieving over 90% accuracy, the predictive models offer nuanced insights, enabling coaches to optimize training strategies and enhance overall sports performance. This multi-level, data-driven methodology signifies a significant leap in the intersection of artificial intelligence and sports analytics, paving the way for dynamic athlete development and strategic team planning.
In a groundbreaking article, researchers unveil an automated eyelid measurement system employing neural network (NN) technology. This innovative system showcases high accuracy and efficiency, providing precise measurements of critical parameters and effective detection of eyelid abnormalities, demonstrating its potential for transformative applications in clinical settings.
Researchers from the Technical University of Darmstadt delve into the interplay between different datasets and machine learning models in the realm of human risky choices. Their analysis uncovers dataset bias, particularly between online and laboratory experiments, leading to the proposal of a hybrid model that addresses increased decision noise in online datasets, shedding light on the complexities of understanding human decision-making through the combination of machine learning and theoretical reasoning.
This paper unveils FaceNet-MMAR, an advanced facial recognition model tailored for intelligent university libraries. By optimizing traditional FaceNet algorithms with innovative features, including mobilenet, mish activation, attention module, and receptive field module, the model showcases superior accuracy and efficiency, garnering high satisfaction rates from both teachers and students in real-world applications.
Researchers introduce machine learning-powered stretchable smart textile gloves, featuring embedded helical sensor yarns and IMUs. Overcoming the limitations of camera-based systems, these gloves provide accurate and washable tracking of complex hand movements, offering potential applications in robotics, sports training, healthcare, and human-computer interaction.
This study introduces a groundbreaking approach using wavelet-activated quantum neural networks to accurately identify complex fluid compositions in tight oil and gas reservoirs. Overcoming the limitations of manual interpretation, this quantum technique demonstrates superior performance in fluid typing, offering a quantum leap in precision and reliability for crucial subsurface reservoir analysis and development planning.
Researchers harness Convolutional Neural Networks (CNNs) to enhance the predictability of the Madden-Julian Oscillation (MJO), a critical tropical weather pattern. Leveraging a 1200-year simulation and explainable AI methods, the study identifies moisture dynamics, particularly precipitable water anomalies, as key predictors, pushing the forecasting skill to approximately 25 days and offering insights into improving weather and climate predictions.
Researchers introduce the multi-feature fusion transformer (MFT) for named entity recognition (NER) in aerospace text. MFT, utilizing a unique structure and integrating radical features, outshines existing models, demonstrating exceptional performance and paving the way for enhanced AI applications in aerospace research.
This paper delves into the transformative role of attention-based models, including transformers, graph attention networks, and generative pre-trained transformers, in revolutionizing drug development. From molecular screening to property prediction and molecular generation, these models offer precision and interpretability, promising accelerated advancements in pharmaceutical research. Despite challenges in data quality and interpretability, attention-based models are poised to reshape drug discovery, fostering breakthroughs in human health and pharmaceutical science.
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