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 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.
Researchers have introduced a groundbreaking wireless AI microrobot capable of real-time in-situ monitoring and diagnostics. The microrobot integrates a self-sensing mechanism that responds to changes in its microenvironment without the need for internal power. Through the manipulation of electromagnetic fields, the microrobot navigates the body, detects anomalies, and offers potential applications in early disease diagnosis and targeted treatments.
Researchers present an innovative study focused on accurate temperature prediction for greenhouse management. By comparing Multiple Linear Regression (MLR), Radial Basis Function (RBF), and Support Vector Machine (SVM) models, they identify the RBF model with the Levenberg–Marquardt (LM) learning algorithm as the most effective. This model achieves precise greenhouse temperature forecasting, enhancing crop yields, and minimizing energy waste.
Researchers employ a combination of artificial intelligence (AI) methods, logical-mathematical models, and physicochemical parameters to predict water quality (WQ) in the challenging context of the Loa River basin in the Atacama Desert. By integrating AI-driven techniques, such as Random Forest (RF), with expert insights, the study introduces a novel method for generating WQ labels and classifications.
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 introduce an innovative AI model that outperforms existing methods in Parkinson's disease (PD) detection. Leveraging a transformer-based architecture and neural network, this model utilizes vocal features to achieve superior accuracy, providing potential for early intervention in PD cases.
Researchers unveil MM-Vet, a pioneering benchmark to rigorously assess complex tasks for Large Multimodal Models (LMMs). By combining diverse capabilities like recognition, OCR, knowledge, language generation, spatial awareness, and math, MM-Vet sheds light on the performance of LMMs in addressing intricate vision-language tasks, revealing the potential for further advancements.
Researchers delve into the realm of intelligent packaging powered by AI to ensure food freshness, offering insights into global advancements. The study highlights the potential of AI-driven solutions for monitoring freshness, though challenges in sensor technology and algorithm optimization remain.
Researchers propose a game-changing approach, ELIXR, that combines large language models (LLMs) with vision encoders for medical AI in X-ray analysis. The method exhibits exceptional performance in various tasks, showcasing its potential to revolutionize medical imaging applications and enable high-performance, data-efficient classification, semantic search, VQA, and radiology report quality assurance.
This cutting-edge research explores a novel deep learning approach for network intrusion detection using a smaller feature vector. Achieving higher accuracy and reduced computational complexity, this method offers significant advancements in cybersecurity defense against evolving threats.
Researchers have explored ChatGPT's ability to distinguish between human-written and AI-generated text. The study revealed that while ChatGPT performs well in identifying human-written text, it struggles to detect AI-generated text accurately. On the other hand, GPT-4 exhibited overconfidence in labeling text as AI-generated, leading to potential misclassifications.
Researchers discuss the integration of artificial intelligence (AI) and networking in 6G networks to achieve efficient connectivity and distributed intelligence. It explores the use of Transfer Learning (TL) algorithms in 6G wireless networks, demonstrating their potential in optimizing learning processes for resource-constrained IoT devices and various IoT paradigms such as Vehicular IoT, Satellite IoT, and Industrial IoT. The study emphasizes the importance of optimizing TL factors like layer selection and training data size for effective TL solutions in 6G technology's distributed intelligence networks.
This study explores the practical applications of machine learning in luminescent biosensors and nanostructure synthesis. Machine learning techniques are shown to optimize nanomaterial synthesis, improve luminescence sensing accuracy, and enhance sensor arrays for various analyte detection, revolutionizing analytical chemistry and biosensing applications.
The DCTN model, combining deep convolutional neural networks and Transformers, demonstrates superior accuracy in hydrologic forecasting and climate change impact evaluation, outperforming traditional models by approximately 30.9%. The model accurately predicts runoff patterns, aiding in water resource management and climate change response.
Researchers demonstrated the use of heterogeneous machine learning (ML) classifiers and explainable artificial intelligence (XAI) techniques to predict strokes with high accuracy and transparency. The proposed model, utilizing a novel ensemble-stacking architecture, achieved exceptional performance in stroke prediction, with 96% precision, accuracy, and recall. The XAI techniques used in the study allowed for better understanding and interpretation of the model, paving the way for more efficient and personalized patient care in the future.
Researchers conducted a comprehensive study to explore the utilization of AI tools in the construction sector. They employed a hybrid multi-criteria decision-making (MCDM) approach that integrated the Delphi method, TOPSIS, and ANP within a fuzzy context. The study highlights AI's significance in improving safety, sustainability, project planning, and construction processes, and provides valuable insights for decision-makers on the role of AI in the construction industry.
Researchers introduce FERN, a neural encoder-decoder model designed to revolutionize earthquake rate forecasting. By overcoming the limitations of traditional models like ETAS, FERN leverages the power of artificial intelligence and deep learning algorithms to provide more accurate and flexible earthquake predictions. With its ability to incorporate diverse geophysical data and offer improved short-term forecasts, FERN holds promise for enhancing seismic risk management and ensuring safer communities in earthquake-prone regions.
Researchers from China Jiliang University and Hangzhou Aihua Intelligent Technology Co., Ltd. propose a novel approach using dual-branch residual networks to enhance urban environmental sound classification in smart cities. By accurately identifying and classifying various sounds, this advanced system offers valuable insights for city management, security, environmental monitoring, traffic management, and urban planning, leading to more livable and sustainable urban environments.
This paper presents a comprehensive study comparing the effectiveness of specialized language models and the GPT-3.5 model in detecting Sustainable Development Goals (SDGs) within text data. The research highlights the challenges of bias and sensitivity in large language models and explores the trade-offs between broad coverage and precision. The study provides valuable insights for researchers and practitioners in choosing the appropriate model for specific tasks.
Researchers delve into the world of Green AI, a promising technology that combines artificial intelligence with sustainability practices to address energy forecasting and management challenges. The article explores applications in green energy load forecasting, power consumption prediction, and electricity price forecasting, highlighting the potential of Green AI to optimize energy distribution, promote renewable energy sources, and foster a greener and more sustainable future.
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