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.
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.
Meta's new 3DGen pipeline enables rapid, high-fidelity text-to-3D asset generation by integrating AssetGen for 3D shapes and TextureGen for detailed textures. Evaluations show 3DGen significantly outperforms industry standards in both speed and quality, particularly excelling with complex prompts.
Researchers have developed a novel deep-learning model to predict the compressive strength of slag-ash-based geopolymer concrete, an eco-friendly alternative to traditional cement. This model, coupled with SHapley additive exPlanations (SHAP) for transparency, and a software tool for optimizing mix designs based on strength and global warming potential, enhances sustainable construction practices by offering accurate, reliable, and interpretable predictions.
Researchers have proposed a novel framework using basic fuzzy logic to redefine group fairness in AI, separating it from social context and uncertainty. This framework translates complex fairness definitions into more accessible terms, allowing for continuous truth values based on stakeholder opinions and enhancing practical application and interpretability in diverse contexts.
In an article published in Computers and Education: Artificial Intelligence, researchers explored various methods for generating question-answer (QA) pairs using pre-trained large language models (LLMs) in higher education. They assessed pipeline, joint, and multi-task approaches across three datasets through automated metrics, teacher evaluations, and real-world educational settings.
The European project SIGNIFICANCE, using AI and deep learning, developed a platform to combat the illegal trafficking of cultural heritage goods. By identifying, tracking, and blocking illegal online activities, the platform increased the detection of illegal artifacts by 10-15%, aiding law enforcement in safeguarding cultural heritage.
Researchers introduced the RAVEN framework, a novel multitask retrieval-augmented vision-language model, achieving significant performance improvements without additional retrieval-specific parameters. It demonstrated substantial gains in image captioning and visual question answering, showcasing the efficacy of retrieval-augmented generation for efficient and accessible multimodal learning
Researchers in the Journal of the Air Transport Research Society evaluated 12 large language models (LLMs) across aviation tasks, revealing varied accuracy in fact retrieval and reasoning capabilities. A survey at Beihang University explored student usage patterns, highlighting optimism for LLMs' potential in aviation while emphasizing the need for improved reliability and safety standards.
A study in Plos One evaluated ChatGPT 3.5's ability to generate humor compared to humans across joke tasks and satirical headlines. Findings revealed that ChatGPT 3.5's humor was rated as equally or more funny than human-generated humor in diverse comedic tasks and matched professional standards in satirical news, challenging traditional views on AI's capacity for humor production.
Researchers introduced a novel task for embodied AI called human-aware vision-and-language navigation (HA-VLN) and developed the HA3D simulator to enhance realism in navigation tasks. This new framework incorporates human activities and dynamic environments, significantly improving the AI's ability to navigate real-world settings by following natural language instructions
The article introduces LiveBench, an innovative benchmark designed to mitigate test set contamination and biases inherent in current large language model (LLM) evaluations. Featuring continuously updated questions from recent sources, LiveBench automates scoring based on objective values and offers challenging tasks across six categories: math, coding, reasoning, data analysis, instruction following, and language comprehension.
Researchers explored the potential of large language models (LLMs) like GPT-4 and Claude 2 for automated essay scoring (AES), showing that these AI systems offer reliable and valid scoring comparable to human raters. The study underscores the promise of LLMs in educational technology, while highlighting the need for further refinement and ethical considerations.
A review in Artificial Intelligence in Agriculture compared machine learning (ML) and deep learning (DL) for weed detection. The study found DL offers higher accuracy, while ML excels in real-time processing with smaller models, addressing challenges like visual similarity and early-stage weed control.
Researchers in Machines developed an AI-based predictive maintenance framework, integrating Industry 4.0 technologies and machine learning to enhance production efficiency. Applied to electromechanical component lines, it linked machine states with product quality, cutting downtime and scrap costs significantly.
Researchers in Scientific Reports introduced an AI-based approach to predict rice production in China using multi-source data. Hybrid models, particularly RF-XGB, outperformed single models in accuracy, emphasizing the importance of soil properties and sown area over climate variables in determining rice yields.
A review in Materials & Design explores how big data, machine learning (ML), and digital twin technologies enhance additive manufacturing (AM). These technologies improve AM by optimizing design, material properties, and process efficiency, offering significant advancements in quality, efficiency, and sustainability.
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