In the context of AI, a Decision Tree is a type of supervised learning algorithm that is mostly used in classification problems. It works for both categorical and continuous input and output variables. In this technique, we split the data into two or more homogeneous sets based on the most significant differentiator in input variables. Each internal node of the tree corresponds to an attribute, and each leaf node corresponds to a class label.
Researchers pioneer individual welfare assessment for gestating sows using machine learning and behavioral data. Clustering behavioral patterns and employing a decision tree for classification, the study achieves an 80% accuracy in categorizing sows into welfare clusters, emphasizing the potential for automated decision support systems in livestock management. The innovative approach addresses gaps in individual welfare assessment, showcasing adaptability to real-time farm data for proactive animal welfare management.
This paper demonstrates the efficacy of advanced machine learning techniques in accurately estimating crucial water distribution uniformity metrics for efficient sprinkler system analysis, design, and evaluation. The study explores the intersection of hydraulic parameters, meteorological influences, and machine learning models to optimize sprinkler uniformity, providing valuable insights for precision irrigation management.
Researchers explored the application of artificial intelligence (AI), specifically long short-term memory (LSTM) and artificial neural networks (ANN), in assessing and predicting surface water quality. The study, conducted on the Ashwini River in Himachal Pradesh, India, showcased the effectiveness of LSTM models in accurate water quality prediction, emphasizing the potential of AI in resource management and environmental protection
This study introduces a novel approach for forecasting sugarcane yield in major Chinese production regions. Utilizing the Water Cycle Algorithm (WCA) to fine-tune the Least Squares Support Vector Machine (LSSVM) model, the proposed method demonstrates superior accuracy and generalization capabilities, offering valuable insights for optimizing sugarcane production practices.
Researchers have developed an advanced early warning system for gas explosions in coal mines, utilizing real-time data from intelligent mining systems. The system, based on the Random Forest algorithm, achieved 100% accuracy in prediction, surpassing the performance of the Support Vector Machine model, offering a promising approach to improve coal mine safety through multidimensional data analysis and intelligent mining technologies.
This research paper compared various computational models to predict ground vibration from mining blasts. The study found that a blackhole-optimized LSTM model provided the highest predictive accuracy, outperforming conventional and advanced methods, offering a robust foundation for AI-powered solutions in vibration forecasting and design optimization in the mining industry.
Researchers reviewed the application of machine learning (ML) techniques to bolster the cybersecurity of industrial control systems (ICSs). ML plays a vital role in detecting and mitigating cyber threats within ICSs, encompassing supervised and unsupervised approaches, and can be integrated into intrusion detection systems (IDS) for improved outcomes.
Researchers introduced the Science4Cast benchmark to forecast future AI research, emphasizing the importance of network features for precise predictions. This approach offers a promising tool to accelerate scientific progress in artificial intelligence.
This research paper introduces innovative machine learning techniques, including Artificial Neural Networks (ANN) and Support Vector Machines (SVM), to assess critical speeds on railway tracks, especially those on soft soils. The study's dataset, created through advanced numerical methods and validated experiments, supports the development of predictive models for assessing critical speeds in various track sections.
This research paper explores the impact of various factor screening methods on predictive modeling accuracy for landslide susceptibility mapping. Using 2014 landslide data from Jingdong County, the study employs factor screening techniques and a random forest model to improve prediction accuracy, with the Information Gain Ratio (IGR) and Random Forest (IGR_RF) model emerging as the most effective approach.
This study employs Explainable Artificial Intelligence (XAI) to analyze obesity prevalence across 3,142 U.S. counties. Machine learning models, coupled with interpretability techniques, reveal physical inactivity, diabetes, and smoking as primary contributors to obesity disparities. XAI advances understanding and intervention in obesity-related health challenges.
This research delves into the application of machine learning (ML) algorithms in wastewater treatment, examining their impact on this essential environmental discipline. Through text mining and analysis of scientific literature, the study identifies popular ML models and their relevance, emphasizing the increasing role of ML in addressing complex challenges in wastewater treatment, while also highlighting the importance of data quality and model interpretation.
Researchers have leveraged machine learning and deep learning techniques, including BiLSTM networks, to classify maize gene expression profiles under biotic stress conditions. The study's findings not only demonstrate the superior performance of the BiLSTM model but also identify key genes related to plant defense mechanisms, offering valuable insights for genomics research and applications in developing disease-resistant maize varieties.
This article delves into the application of artificial intelligence (AI) techniques in predicting water quality indices and classifications. It highlights the advantages and challenges of implementing AI in water quality monitoring and modeling and explores advancements in machine learning for assessing various water quality parameters.
Researchers have introduced an innovative Intrusion Detection System (IDS) model, IDSNet-PDO, built on one-dimensional convolutional neural networks (1D-CNN) and fine-tuned with the Prairie Dog Optimization (PDO) algorithm. This IDS model demonstrates high accuracy in predicting Distributed Denial of Service (DDoS) attacks in the context of Agriculture 4.0, addressing cybersecurity challenges in interconnected IoT devices used in modern agriculture.
This article discusses the growing menace of advanced persistent threats (APTs) in the digital landscape and presents a multi-stage machine learning approach to detect and analyze these sophisticated cyberattacks. The research introduces a Composition-Based Decision Tree (CDT) model, outperforming existing algorithms and offering new insights for improved intrusion detection and prevention systems.
This study delves into the intricate relationship between human emotions and body motions, using a controlled lab experiment to simulate real-world interactions. Researchers successfully induced emotions in participants and employed machine learning models to classify emotions based on a comprehensive range of motion parameters, shedding light on the potential for emotion recognition through naturalistic body expressions.
Researchers have developed a robust web-based malware detection system that utilizes deep learning, specifically a 1D-CNN architecture, to classify malware within portable executable (PE) files. This innovative approach not only showcases impressive accuracy but also bridges the gap between advanced malware detection technology and user accessibility through a user-friendly web interface.
Researchers have harnessed the power of artificial intelligence to predict chloride resistance in concrete compositions, a key factor in enhancing structural durability and preventing corrosion. By leveraging machine learning techniques, they created a reliable model that can forecast chloride migration coefficients, reducing the need for labor-intensive and time-consuming experimentation, and paving the way for more cost-effective and sustainable construction practices.
Researchers highlight the critical role of pipelines in global oil, gas, and water transport and introduce the innovative Relative Risk Scoring (RRS) method for pipeline risk assessment. RRS outperforms traditional machine learning algorithms and offers more accurate predictions for leakage, corrosion, and classification, making it a promising tool for ensuring the secure and efficient transportation of products through pipelines.
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