Clustering with AI involves using machine learning algorithms to group a set of data points into clusters based on their similarities, without prior knowledge of these groupings. It's a type of unsupervised learning used in various fields like market segmentation, image segmentation, and anomaly detection.
Researchers have introduced StyleInV, an innovative video generation model that leverages pre-trained StyleGAN for superior motion generation and quality in long, high-resolution videos, outperforming existing methods in both quantitative and qualitative evaluations.
Researchers introduce VideoCutLER, an innovative unsupervised technique for multi-instance segmentation and tracking in videos. By leveraging synthetic video generation and a novel three-step process, VideoCutLER outperforms optical flow-based methods and achieves remarkable performance in video instance segmentation benchmarks.
Researchers present an open-source gaze-tracking solution for smartphones, using machine learning to achieve accurate eye tracking without the need for additional hardware. By utilizing convolutional neural networks and support vector regression, this approach achieves high levels of accuracy comparable to costly mobile trackers.
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 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 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 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.
This article introduces cutting-edge deep learning techniques as a solution to combat evolving web-based attacks in the context of Industry 5.0. By merging human expertise and advanced models, the study proposes a comprehensive approach to fortify cybersecurity, ensuring a safer and more resilient future for transformative technologies.
Researchers propose an innovative approach to enhance the air pollutant removal system in coal-fired power plants. By integrating AI-driven models, Monte Carlo simulations, and multi-criteria decision-making, this study offers an optimized configuration for sustainable pollutant control.
The proposed setup showcases promising outcomes, including economic efficiency, environmental quality improvement, and enhanced reliability, underscoring the potential for transforming pollutant management in the energy industry.
Researchers introduce an innovative solution for intelligent identification of natural gas pipeline defects. By enhancing the Flower Pollination Algorithm (FPA) with adaptive adjustments and Gaussian mutation, the Improved Flower Pollination Algorithm (IFPA) optimizes input weights for the Extreme Learning Machine (ELM). IFPA-ELM achieves impressive defect recognition rates of 97% and 96%, surpassing benchmarks and showcasing potential for advanced pipeline defect diagnosis.
This study presents a novel approach to identifying typical car-to-powered two-wheelers (PTWs) crash scenarios for autonomous vehicle (AV) safety testing. By utilizing stacked autoencoder methods to extract embedded features from high-dimensional crash data, followed by k-means clustering, six high-risk scenarios are identified. Unlike previous research, this method eliminates manual selection of clustering variables and provides a more detailed scenario description, resulting in more robust and effective AV testing scenarios.
Researchers present CQDA, a lightweight and interpretable model for complex query answering over knowledge graphs. CQDA outperforms existing methods by achieving higher accuracy with limited training data, supporting reasoning with negations, and demonstrating data efficiency and robustness in out-of-domain evaluations.
Researchers utilize GPT-4, an advanced natural language processing tool, to automate information extraction from scientific articles in synthetic biology. Through the integration of AI and machine learning, they demonstrate the effectiveness of data-driven approaches for predicting fermentation outcomes and expanding the understanding of nonconventional yeast factories, paving the way for faster advancements in biomanufacturing and design.
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