Machine learning is a subfield of artificial intelligence that focuses on developing algorithms and models capable of automatically learning and making predictions or decisions from data without being explicitly programmed. It involves training models on labeled datasets to recognize patterns and make accurate predictions or classifications in new, unseen data.
Researchers have developed AI-based computer vision systems to identify growth-stunted salmon, with YoloV7 achieving the highest accuracy. This technology offers efficient and reliable monitoring, improving fish welfare and production in aquaculture.
A recent review in the Journal of Materials Research and Technology explores machine learning's transformative potential in designing and optimizing magnesium (Mg) alloys. By leveraging ML, researchers can efficiently enhance Mg alloy properties, expediting their development and broadening industrial applications.
Researchers use MLPs in ONIOM schemes to refine drug-protein structures efficiently and accurately, highlighting potential applications in drug development.
Integrating blockchain with the Internet of Drones (IoD) promises enhanced security, connectivity, and efficiency in drone applications like delivery, surveillance, and rescue operations.
Researchers analyzed the Cambridge Structural Database (CSD) to understand lanthanide coordination chemistry, providing insights for designing better ligands for rare-earth element (REE) separations. The study focused on trends in coordination numbers, first shell distances, and ligand types, which will guide future data-driven ligand design for efficient REE separation.
Researchers developed and validated machine learning models for predicting turbulent combustion speed in hydrogen-natural gas spark ignition engines, showcasing their superiority over traditional methods. By leveraging data from a MINSEL 380 engine and employing techniques like random forest and artificial neural networks, the study demonstrated high forecasting accuracy, making these models valuable for industrial applications such as engine monitoring and simulation tools.
Researchers utilized machine learning algorithms to predict life satisfaction with high accuracy (93.80%) using data from a Danish government survey. By identifying 27 key questions and employing models such as KNN, SVM, and Bayesian networks, the study highlighted the significant impact of health conditions on life satisfaction and made the best predictive model publicly available.
A study in Heliyon introduced a machine learning-based approach for predicting defects in BLDC motors used in UAVs. Researchers compared KNN, SVM, and Bayesian network models, with SVM demonstrating superior accuracy in fault classification, highlighting its potential for improving UAV operational safety and predictive maintenance.
This article showcases a machine learning approach using K-nearest neighbors (KNN) and linear regression to assess seismic damage in moment-resisting frame buildings. By training on data generated through a new simulation procedure, researchers achieved accurate predictions of the Park-Ang structural damage index, with KNN demonstrating superior performance.
A recent article in "Artificial Intelligence in Agriculture" reviewed machine learning (ML) techniques for detecting plant diseases in apple, cassava, cotton, and potato crops. The study highlighted the superior accuracy of convolutional neural networks (CNNs) and emphasized ML's potential to enhance crop yield and quality, despite challenges related to data quality and ethical considerations.
Researchers in Nature explore the application of deep learning to analyze plasma plume dynamics in pulsed laser deposition (PLD). Using ICCD image sequences, a (2 + 1)D convolutional neural network correlates plume behavior with deposition conditions, enabling real-time monitoring and predictive insights for optimizing thin film growth.
DeepCNT-22, a machine learning force field, powers simulations revealing the atomic-level dynamics of SWCNT formation. It challenges conventional growth models, highlighting stochastic defects and conditions for defect-free growth.
Researchers combined density functional theory (DFT) with machine learning (ML) to screen 41,400 metal halide perovskites (MHPs), identifying 10 promising candidates with improved stability and optoelectronic properties. Highlighting CsGe0.3125Sn0.6875I3 and CsGe0.0625Pb0.3125Sn0.625Br3, this study offers a new framework for optimizing perovskites for solar cells.
Researchers have introduced InsectSound1000, a dataset featuring over 169,000 labeled sound samples from 12 insect species. This dataset, recorded in an anechoic box with high precision, is primed for training deep-learning models to enhance pest and ecological monitoring systems.
Researchers presented a novel dual-branch selective attention capsule network (DBSACaps) for detecting kiwifruit soft rot using hyperspectral images. This approach, detailed in Nature, separates spectral and spatial feature extraction, then fuses them with an attention mechanism, achieving a remarkable 97.08% accuracy.
Researchers introduce a novel electronic tongue (E-tongue), the multichannel triboelectric bioinspired E-tongue (TBIET), engineered with advanced triboelectric components on a single glass slide chip. Through comprehensive classification studies across medical, environmental, and beverage samples, the TBIET demonstrates exceptional taste classification accuracy, promising significant advancements in on-site liquid sample detection and analysis.
A recent scientometric review highlighted the transformative impact of machine learning (ML) in seismic engineering, showcasing advancements in material performance prediction and seismic resistance. The study, published in the journal Buildings, analyzed 3189 papers using the Scopus database, identifying key research trends and fostering collaboration within the field.
This study highlights the use of a next-generation reservoir computing (NG-RC) algorithm to control chaotic dynamics with high sensitivity and efficiency. Implemented on an FPGA, the NG-RC-based controller outperformed conventional chaos control techniques by stabilizing various unstable states and trajectories with minimal power consumption, suggesting promising applications in diverse fields like autonomous systems and biological control.
In a Nature Machine Intelligence paper, researchers unveiled ChemCrow, an advanced LLM chemistry agent that autonomously tackles complex tasks in organic synthesis and materials design. By integrating GPT-4 with 18 expert tools, ChemCrow excels in chemical reasoning, planning syntheses, and guiding drug discovery, outperforming traditional LLMs and showcasing its potential to transform scientific research.
Researchers introduced DPA-1, a deep potential model with a gated attention mechanism, for representing atomic system conformation and chemical spaces. DPA-1 demonstrated superior performance in learning potential energy surfaces (PES) compared to existing benchmarks, offering efficiency and interpretability.
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