Artificial Intelligence (AI) refers to the simulation of human intelligence processes by machines, especially computer systems. These processes include learning (the acquisition of information and rules for using the information), reasoning (using rules to reach approximate or definite conclusions), and self-correction.
This paper explores advanced drowning prevention technologies that integrate embedded systems, artificial intelligence (AI), and the Internet of Things (IoT) to enhance real-time monitoring and response in swimming pools. By utilizing computer vision and deep learning for accurate situation identification and IoT for real-time alerts, these systems significantly improve rescue efficiency and reduce drowning incidents
A recent study introduced an AI-based approach using transformer + UNet and ResNet-18 models for rock strength assessment and lithology identification in tunnel construction. The method showed high accuracy, reducing errors and enhancing safety and efficiency in geological engineering.
A recent study explored the use of a large language model-based voice-enabled digital intelligent assistant in manufacturing assembly processes. It found that while the system effectively reduced cognitive load and improved product quality, it did not significantly impact lead times.
Researchers developed a machine learning technique to predict obesity risk by analyzing sociodemographic, lifestyle, and health factors. The study, which achieved 79% accuracy, identified significant predictors like age, sex, education, diet, and smoking habits, offering valuable insights for personalized obesity prevention.
CYBERSECEVAL 3 introduces new security benchmarks to evaluate large language models like Llama 3, focusing on offensive security capabilities and risks. These benchmarks help assess and mitigate threats, advancing AI-driven cybersecurity for developers, end-users, and third-party applications.
An innovative AI-driven platform, HeinSight3.0, integrates computer vision to monitor and analyze liquid-liquid extraction processes in real-time. Utilizing machine learning for visual cues like liquid levels and turbidity, this system significantly optimizes LLE, paving the way for autonomous lab operations.
Machine learning models predicted potato leaf blight with 98.3% accuracy using over 4000 weather records. Techniques like K-means clustering, PCA, and copula analysis identified key weather factors. Feature selection significantly enhanced model precision, aiding proactive disease management in agriculture.
Researchers introduced a novel method using reinforcement learning to lock lasers to optical cavities, enhancing performance and reliability. By replacing traditional controls with a Q-Learning agent, this approach significantly extended lock duration, showing promise for high-sensitivity physics experiments and applications.
A study in Nature reveals that AI models degrade into gibberish when trained on data from other AIs, a phenomenon called "model collapse." This poses significant challenges to the sustainability and reliability of generative AI models, emphasizing the need for original data.
Researchers explored the decision-making process of Gaussian process (GP) models, focusing on loss landscapes and hyperparameter optimization. They emphasized the importance of the Matérn kernel's ν-continuity, used catastrophe theory to analyze critical points, and evaluated GP ensembles. This study offers insights and practical methods to enhance GP performance and interpretability across various datasets.
Researchers introduced an adaptive backdoor attack method to steal private data from pre-trained large language models (LLMs). This method, tested on models like GPT-3.5-turbo, achieved a 92.5% success rate. By injecting triggers during model customization and activating them during inference, attackers can extract sensitive information, underscoring the need for advanced security measures.
A study in Computers & Graphics examined model compression methods for computer vision tasks, enabling AI techniques on resource-limited embedded systems. Researchers compared various techniques, including knowledge distillation and network pruning, highlighting their effectiveness in reducing model size and complexity while maintaining performance, crucial for applications like robotics and medical imaging.
Researchers evaluated AI's potential to reduce energy consumption and emissions in US medium office buildings. Their study demonstrated that AI could significantly enhance building energy efficiency, achieving up to a 21% reduction in energy use and substantial carbon emissions reductions by 2050, particularly when combined with supportive energy policies and low-carbon power sources.
Researchers leverage AI to optimize the design, fabrication, and performance forecasting of diffractive optical elements (DOEs). This integration accelerates innovation in optical technology, enhancing applications in imaging, sensing, and telecommunications.
Generative adversarial networks (GANs) have transformed generative modeling since 2014, with significant applications across various fields. Researchers reviewed GAN variants, architectures, validation metrics, and future directions, emphasizing their ongoing challenges and integration with emerging deep learning frameworks.
Researchers introduced a method to develop interpretable ML models for estimating seismic demand in reinforced concrete (RC) buildings, focusing on maximum inter-story drift (MID) under pulse-like earthquakes.
Researchers utilized deep learning techniques to detect anomalies in the European banking sector, finding significant correlations between European Banking Authority events and banking anomalies.
Researchers introduced an AI-driven framework for automated warehouse layout generation using constrained beam search. This method optimizes layouts for storage capacity, accessibility, and throughput, demonstrating significant improvements over traditional manual designs and validating its effectiveness in real-world applications.
Researchers highlighted the efficacy of machine learning (ML) in improving uranium spectral gamma-ray logging, particularly using backpropagation (BP) neural networks. Addressing challenges like low statistical efficacy and spectral drift, their study demonstrated that ML models, especially BP, significantly enhance the accuracy and stability of uranium quantification in high-speed logging, outperforming traditional methods.
Researchers introduced MetaUrban, an advanced simulation platform designed for AI systems in urban environments. It generates diverse, interactive urban scenes for point-to-point navigation and social interaction tasks, leveraging reinforcement and imitation learning to enhance the reliability of mobile agents like delivery robots and robotic canines.
Terms
While we only use edited and approved content for Azthena
answers, it may on occasions provide incorrect responses.
Please confirm any data provided with the related suppliers or
authors. We do not provide medical advice, if you search for
medical information you must always consult a medical
professional before acting on any information provided.
Your questions, but not your email details will be shared with
OpenAI and retained for 30 days in accordance with their
privacy principles.
Please do not ask questions that use sensitive or confidential
information.
Read the full Terms & Conditions.