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 present the innovative Cost-sensitive K-Nearest Neighbor using Hyperspectral Imaging (CSKNN) method for accurately identifying diverse wheat seed varieties. By addressing challenges such as noise and limited spatial utilization, CSKNN harnesses the power of hyperspectral imaging, noise reduction, feature extraction, and cost sensitivity, outperforming traditional and deep learning methods.
Researchers highlight the role of solid biofuels and IoT technologies in smart city development. They introduce an IoT-based method, Solid Biofuel Classification using Sailfish Optimizer Hybrid Deep Learning (SBFC-SFOHDL), which leverages deep learning and optimization techniques for accurate biofuel classification.
Researchers explore the power of machine learning models to predict effective microbial strains for combatting drought's impact on crop production. By comparing various models, the study reveals that gradient boosted trees (GBTs) offer high accuracy, though considerations of computational resources and application needs are vital when choosing a model for real-world implementation.
A review published in Humanities and Social Sciences Communications highlights the pressing issue of age-related bias in AI systems, termed digital ageism. The study reveals the extent of age bias in AI data, deployment, and societal impact, emphasizing the need for collaborative efforts to mitigate this bias and ensure equitable AI for all age groups.
Researchers propose a hybrid model that integrates sentiment analysis using Word2vec and Long Short-Term Memory (LSTM) for accurate exchange rate trend prediction. By incorporating emotional weights from Weibo data and historical exchange rate information, combined with CNN-LSTM architecture, the model demonstrates enhanced prediction accuracy compared to traditional methods.
Researchers explore 11 ML algorithms to accurately estimate the uniaxial compressive strength of nanosilica-reinforced concrete. The study highlights the significance of nanomaterial concentration and type in enhancing concrete mechanics, paving the way for informed design and improved water management practices.
Researchers devise interpretable and non-interpretable ML models optimized by particle swarm optimization to accurately estimate crop evapotranspiration for winter wheat. By utilizing limited meteorological data, these models offer insights into water usage and agricultural sustainability, aiding water management practices in the face of climate challenges.
A groundbreaking innovation, the TE-VS combines triboelectrification and electromagnetic power generation to revolutionize wearables. With machine learning integration and applications in healthcare and sustainable energy, the TE-VS promises accurate motion monitoring and energy harvesting, shaping a brighter future for technology and well-being.
Researchers delve into the realm of Citizen-Centric Digital Twins (CCDT), exploring cutting-edge technologies that enable predictive, simulative, and visualizing capabilities to address city-level issues through citizen engagement. The study highlights data acquisition methods, machine learning algorithms, and APIs, offering insights into enhancing urban management while fostering public participation.
Researchers analyze proprietary and open-source Large Language Models (LLMs) for neural authorship attribution, revealing distinct writing styles and enhancing techniques to counter misinformation threats posed by AI-generated content. Stylometric analysis illuminates LLM evolution, showcasing potential for open-source models to counter misinformation.
Researchers evaluated various machine learning algorithms to predict sheep body weights, highlighting the effectiveness of models like MARS, BRR, ridge regression, SVM, and gradient boosting for improving animal production decisions, ensuring economic growth and food security. Their study showcases the potential of AI in transforming animal husbandry practices.
Researchers delve into the transformative potential of large AI models in the context of 6G networks. These wireless big AI models (wBAIMs) hold the key to revolutionizing intelligent services by enabling efficient and flexible deployment. The study explores the demand, design, and deployment of wBAIMs, outlining their significance in creating sustainable and versatile wireless intelligence for 6G networks.
Researchers examine the multifaceted applications of artificial intelligence (AI) and machine learning (ML) in revolutionizing construction processes and fostering sustainable communities. Covering the entire architecture, engineering, construction, and operations (AECO) domain, the study categorizes and explores existing and emerging roles of AI and ML in indoor and outdoor sustainability enhancements, construction lifecycles, and innovative integration with blockchain, digital twins, and robotics.
Researchers present a novel approach utilizing a residual network (ResNet-18) combined with AI to classify cooling system faults in hydraulic test rigs with 95% accuracy. As hydraulic systems gain prominence in various industries, this innovative method offers a robust solution for preventing costly breakdowns, paving the way for improved reliability and efficiency.
The study delves into the integration of deep learning, discusses the dataset, and showcases the potential of AI-driven fault detection in enhancing sustainable operations within hydraulic systems.
Researchers introduce the Gap Layer modified Convolution Neural Network (GL-CNN) coupled with IoT and Unmanned Aerial Vehicles (UAVs) for accurate and efficient monitoring of palm tree seedling growth. This approach utilizes advanced image analysis techniques to predict seedling health, addressing challenges in early-stage plant monitoring and restoration efforts. The GL-CNN architecture achieves impressive accuracy, highlighting its potential for transforming ecological monitoring in smart farming.
Researchers delve into AI's role in carbon reduction in buildings, discussing energy prediction, ML-driven emission mitigation, and carbon accounting. The paper underscores urgent emission reduction in construction, highlighting ML's potential to drive sustainable practices, with a focus on AI's positive impact on the low-carbon building sector.
Researchers have introduced a transformative approach utilizing deep reinforcement learning (DRL) and a transformer-based policy network to optimize energy-efficient routes for electric logistic vehicles. By addressing the Energy-Minimization Electric Vehicle Routing Problem (EM-EVRP), this study aimed to reduce operating expenses for electric fleets while accommodating factors like vehicle dynamics, road features, and charging losses.
Researchers propose the synergy of cooperative Deep Reinforcement Learning (DRL) and the Shapley value reward system to revolutionize traffic signal management. This approach leverages intelligent agents representing intersections that collaborate through communication and information sharing, optimizing traffic flow.
Researchers introduce a novel approach using TinyML sensors and models to estimate the shelf life of fresh dates non-destructively. The study develops a lightweight TinyML system combining a miniature NIR spectral sensor and an Arduino microcontroller for on-device inference. This edge computing approach enables real-time prediction of date shelf life, eliminating the need for continuous cloud connectivity.
Researchers present a distributed, scalable machine learning-based threat-hunting system tailored to the unique demands of critical infrastructure. By harnessing artificial intelligence and machine learning techniques, this system empowers cyber-security experts to analyze vast amounts of data in real-time, distinguishing between benign and malicious activities, and paving the way for enhanced threat detection and protection.
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