AI is utilized in predictive maintenance to monitor and predict the health and performance of equipment or machinery. It employs machine learning algorithms and sensor data analysis to detect anomalies, forecast potential failures, and optimize maintenance schedules, enabling proactive and cost-effective maintenance practices.
Mining 4.0 technologies are reshaping workforce roles and operational dynamics, emphasizing the need for skills adaptation and well-being strategies in a digitally connected environment.
Research explores how large language models (LLMs) can revolutionize network engineering by enhancing design, implementation, analytics, and management. It highlights the potential of LLMs to automate tasks and improve efficiency in dynamic and complex network environments.
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 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 reviewed AI advancements in electric power systems, highlighting its transformative potential due to modern microprocessors and data storage. The study categorizes AI applications into four areas and presents detailed case studies in wind power forecasting, smart grid security, and fault detection.
A review in Data & Knowledge Engineering investigates how AI enhances digital twins, highlighting improved functionalities and key research gaps. The integration of these technologies shows promise across various sectors, from healthcare to smart cities.
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.
Researchers present an innovative ML-based approach, leveraging GANs for synthetic data generation and LSTM for temporal patterns, to tackle data scarcity and temporal dependencies in predictive maintenance. Despite challenges, their architecture achieves promising results, underlining AI's potential in enhancing maintenance practices.
Researchers introduced a novel fusion model for predicting lithium-ion battery Remaining Useful Life (RUL), integrating Stacked Denoising Autoencoder (SDAE) and transformer capabilities. This model outperformed others in accuracy and robustness, offering a promising direction for battery life prediction research, crucial for battery management systems and predictive maintenance strategies.
The paper published in the journal Electronics explores the crucial role of Artificial Intelligence (AI) and Explainable AI (XAI) in Visual Quality Assurance (VQA) within manufacturing. While AI-based Visual Quality Control (VQC) systems are prevalent in defect detection, the study advocates for broader applications of VQA practices and increased utilization of XAI to enhance transparency and interpretability, ultimately improving decision-making and quality assurance in the industry.
Researchers explored safety in autonomous mining using Bayesian networks (BN). They developed a proactive approach to detect faults and fire hazards in mining machinery, utilizing diverse sensors and AI-driven predictive maintenance. This study offers a comprehensive framework for improving safety in the rapidly advancing field of autonomous mining.
Researchers have conducted a comprehensive review of the offshore wind energy industry, emphasizing the role of machine learning (ML) and artificial intelligence (AI) in addressing challenges related to turbine size, efficiency, environmental impact, and deep-water deployment. ML applications include climate forecasting, environmental impact assessment, wind farm optimization, and more.
This paper explores the integration of artificial intelligence (AI) and computer vision (CV) technologies in addressing urban expansion challenges, particularly in optimizing container movement within seaports. Through a systematic review, it highlights the significant role of AI and CV in sustainable parking ecosystems, offering valuable insights for enhancing seaport management and smart city development.
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 propose TwinPort, a cutting-edge architecture that combines digital twin technology and drone-assisted data collection to achieve precise ship maneuvering in congested ports. The approach incorporates a recommendation engine to optimize navigation during the docking process, leading to enhanced efficiency, reduced fuel consumption, and minimized environmental impact in smart seaports.
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