AI is used in manufacturing to optimize production processes, improve quality control, and enhance automation. It employs machine learning algorithms, robotics, and real-time data analysis to increase efficiency, reduce defects, and enable predictive maintenance, leading to improved productivity and cost savings in manufacturing operations.
Researchers from the University of Birmingham unveil a novel 3D edge detection technique using unsupervised learning and clustering. This method, offering automatic parameter selection, competitive performance, and robustness, proves invaluable across diverse applications, including robotics, augmented reality, medical imaging, automotive safety, architecture, and manufacturing, marking a significant leap in computer vision capabilities.
Researchers present YOLO_Bolt, a lightweight variant of YOLOv5 tailored for industrial workpiece identification. With optimizations like ghost bottleneck convolutions and an asymptotic feature pyramid network, YOLO_Bolt outshines YOLOv5, achieving a 2.4% increase in mean average precision (mAP) on the MSCOCO dataset. Specialized for efficient bolt detection in factories, YOLO_Bolt offers improved detection accuracy while reducing model size, paving the way for enhanced quality assurance in industrial settings.
Researchers leverage synchrotron X-ray imaging and machine learning models, including deep convolutional neural networks (ConvNets) and semantic segmentation, to predict laser absorptance and segment vapor depressions in metal additive manufacturing. The end-to-end and modular approaches showcase efficient and interpretable solutions, offering potential for real-time monitoring and decision-making in industrial processes.
Researchers pioneer a versatile technique, integrating droplet-based microfluidics and simulation-guided design, for mass-producing soft microrobots with programmable magnetic and structural anisotropy. This breakthrough enables precise control over collective behaviors, offering potential applications in biomedical functions such as drug delivery and biosensing within complex physiological environments.
The article emphasizes the pivotal role of Human Factors and Ergonomics (HFE) in addressing challenges and debates surrounding trust in automation, ethical considerations, user interface design, human-AI collaboration, and the psychological and behavioral aspects of human-robot interaction. Understanding knowledge gaps and ongoing debates is crucial for shaping the future development of HFE in the context of emerging technologies.
This paper delves into the critical role of industrial robots equipped with gripping systems in modern manufacturing. The article emphasizes the need for automated customization of gripping solutions for efficiency and productivity. The proposed modular architecture, comprehensive classification, and machine-readable encoding paradigm offer a pathway for swift, contextually fitting grippers, ensuring flexible and dexterous robotic handling in Industry 4.0.
This study explores the synergies between artificial intelligence (AI) and electronic skin (e-skin) systems, envisioning a transformative impact on robotics and medicine. E-skins, equipped with diverse sensors, offer a wealth of health data, and the integration of advanced machine learning techniques promises to revolutionize data analysis, optimize hardware, and propel applications from prosthetics to personalized health diagnostics.
Researchers proposed a hybrid optimization approach, combining Artificial Neural Network (ANN) and Genetic Algorithm (GA), to enhance plastic injection molding. Addressing quality, production efficiency, and sustainability, the method demonstrated effectiveness in achieving global multi-objective optimization, providing a valuable tool for smart, sustainable, and economically efficient production processes.
This article critically reviews the challenges and advancements in intelligent vehicle safety within complex multi-vehicle interactions. Addressing data collection methods, vehicle interaction dynamics, and risk evaluation techniques, the study categorizes risk assessment into state inference-based and trajectory prediction-based methods. It underscores the need for deeper analysis of multi-vehicle behaviors and emphasizes the advantages and limitations of existing risk assessment approaches.
This scientific report explores the potential of mega-castings to replace steel sheets in automotive structures, offering cost efficiency and design flexibility. Researchers propose a novel two-phase optimization pipeline combining topology optimization, response-surface-based techniques, and machine learning to balance crash demands, castability, and structural goals. The approach outperforms traditional workflows, generating weight-optimized designs within shorter timeframes.
This article delves into the unequal impacts of automation on urban and non-urban labor markets. Analyzing Italian data, it reveals that automation universally displaces workers, challenging assumptions about urban immunity. The study emphasizes the need for ongoing research to understand the evolving landscape of automation, its impact on workforce composition, and the potential for exacerbating inequalities between privileged urban occupations and excluded low-skill workers.
Researchers emphasize the growing significance of radar-based human activity recognition (HAR) in safety and surveillance, highlighting its advantages over vision-based sensing in challenging conditions. The study reviews classical Machine Learning (ML) and Deep Learning (DL) approaches, with DL's advantage in avoiding manual feature extraction and ML's robust empirical basis. A comparative study on benchmark datasets evaluates performance and computational efficiency, aiming to establish a standardized assessment framework for radar-based HAR techniques.
This research delves into the realm of electronic board manufacturing, aiming to enhance reliability and lifespan through the automated detection of solder splashes using cutting-edge machine learning algorithms. The study meticulously compares object detection models, emphasizing the efficacy of the custom-trained YOLOv8n model with 1.9 million parameters, showcasing a rapid 90 ms detection speed and an impressive mean average precision of 96.6%. The findings underscore the potential for increased efficiency and cost savings in electronic board manufacturing, marking a significant shift from manual inspection to advanced machine learning techniques.
Researchers introduce a pioneering framework leveraging IoT and wearable technology to enhance the adaptability of AR glasses in the aviation industry. The multi-modal data processing system, employing kernel theory-based design and machine learning, classifies performance, offering a dynamic and adaptive approach for tailored AR information provision.
This article features a groundbreaking 3D printing platform that integrates advanced machine vision, allowing real-time adjustments for precise material deposition. The vision-controlled system enables high-resolution, multi-material printing, eliminating the need for mechanical planarization and expanding the possibilities in creating intricate structures, from robotic hands to fluidic pumps, with potential applications across various domains like soft robotics and metamaterials.
This study delves into the intricate dynamics between industrial robot (IR) applications and China's global value chain participation (GVCP) from 2006 to 2014. Findings reveal that while IR applications facilitated import substitution, reducing backward participation, manufacturing localization led to a decline in China's opportunities to export intermediate inputs, impacting forward participation in global value chains.
This paper addresses challenges in traditional smoke alarm calibration methods and presents a comprehensive framework for modeling and monitoring using a digital twin system. The proposed approach, validated in a real-world calibration scenario, improves calibration success rates and reduces defective product rates, showcasing the effectiveness of digital twin technology in manufacturing processes.
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.
This article explores the challenges of deep-sea exploration and how bioinspired soft robots have emerged as a transformative solution. Drawing inspiration from deep-sea organisms, these robots combine innovative actuation, pressure resilience, and sensing strategies to navigate and interact with the extreme conditions of the deep ocean.
This article explores the impact of industrial robot adoption on corporate green innovation in China. The study uses data from Chinese manufacturing companies and analyzes the role of industrial robots in improving green innovation by promoting environmental management and enhancing productivity.
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.