Your search keyword '"machine theory"' showing total 8,971 results

1. Prediction model for specific cutting energy of nickel-based Inconel 718 under NMQL condition.

Author

Pan, Zhirong, Yao, Bin, Cai, Zhiqin, and Lan, Qixin

Subjects

*SURFACE hardening, *CUTTING fluids, *MACHINE theory, *NANOPARTICLES, *PREDICTION models

Abstract

The cutting characteristics of Inconel 718 alloy are high hardness and surface hardening, causing fast tool wear, severe chipping, and inadequate machining accuracy. In order to overcome the existing challenges, this study proposes a method to enhance the cutting performance by injecting fullerene C60 nanoparticle cutting fluid with minimum quantity lubrication (MQL) into the cutting zone. Leveraging the Johnson–Cook constitutive model and the imaginary heat source method, this study simulates the cooling effect and friction reduction characteristics of the cutting contact interface under minimum quantity lubrication conditions, and assessment of cutting energy consumption using predicted and measured specific cutting energy (SCE). Through friction wear tests, the friction coefficient changes under various lubrication conditions are measured. The impact of lubrication conditions on friction and wear mechanism is analyzed. The cutting test results demonstrate that variations in cutting parameters significantly influence energy efficiency, with specific cutting energy exhibiting a downward trend as the material removal rate (MRR) increases. Notably, C60 nanoparticle minimum quantity lubrication (NMQL) stands out excellent friction reduction and cooling effects among other lubrication methods. Experimental data indicate that NMQL compared with dry cutting, flood cutting, and pure MQL, the specific cutting energy is reduced by 31.3%, 19.13%, and 17.37%, respectively, and that the cutting energy performance is significantly improved. The maximum error of the SCE prediction model is 17.5%, and the prediction results align well with the experimental findings. Moreover, this study provides novel insights for advancing machining theory and exploring sustainable green machining of nickel-based alloys. [ABSTRACT FROM AUTHOR]

Published

2024

2. Semi-automated title-abstract screening using natural language processing and machine learning.

Author

Pilz, Maximilian, Zimmermann, Samuel, Friedrichs, Juliane, Wördehoff, Enrica, Ronellenfitsch, Ulrich, Kieser, Meinhard, and Vey, Johannes A.

Subjects

*NATURAL language processing, *MACHINE learning, *LANGUAGE models, *MACHINE theory, *PROGRAMMING languages

Abstract

Background: Title-abstract screening in the preparation of a systematic review is a time-consuming task. Modern techniques of natural language processing and machine learning might allow partly automatization of title-abstract screening. In particular, clear guidance on how to proceed with these techniques in practice is of high relevance. Methods: This paper presents an entire pipeline how to use natural language processing techniques to make the titles and abstracts usable for machine learning and how to apply machine learning algorithms to adequately predict whether or not a publication should be forwarded to full text screening. Guidance for the practical use of the methodology is given. Results: The appealing performance of the approach is demonstrated by means of two real-world systematic reviews with meta analysis. Conclusions: Natural language processing and machine learning can help to semi-automatize title-abstract screening. Different project-specific considerations have to be made for applying them in practice. [ABSTRACT FROM AUTHOR]

Published

2024

3. Advancements in Emotion Classification via Facial and Body Gesture Analysis: A Survey.

Author

Diwan, Anjali, Sunil, Reshma, Mer, Parita, Mahadeva, Rajesh, and Patole, Shashikant P.

Subjects

*COMPUTER vision, *NONVERBAL communication, *CONVOLUTIONAL neural networks, *PSYCHOLOGICAL research, *MACHINE theory, *DEEP learning

Abstract

ABSTRACT Machine vision has had a substantial impact on human‐computer interaction and psychological research. The ability of robots to generate realistic facial expressions has been enhanced by advancements in artificial intelligence, neural networks, and deep learning, thereby nurturing more profound emotive connections between humans and machines. This paper offers an in‐depth look of the most recent developments in emotion classification technologies, with a specific focus on the period from 2019 to 2023. This research addresses the integration of facial and body gesture analysis into emotion detection, emphasising the development of methods such as partial transfer learning, sign‐based measurement systems, and lightweight convolutional neural networks. By analysing the most recent research, the paper not only provides a comprehensive overview of the most advanced methods, but also emphasises their superiority over previous approaches in terms of efficiency, and applicability. The integration of gestures into emotion analysis is underscored as a critical area for further investigation, providing novel opportunities for comprehending and interpreting the intricate layers of nonverbal communication. The objective of this survey is to provide a resource for researchers and practitioners who are interested in advancing the field of emotion classification by utilising innovative methodologies. [ABSTRACT FROM AUTHOR]

Published

2024

4. Perturbation Theory Machine Learning Model for Phenotypic Early Antineoplastic Drug Discovery: Design of Virtual Anti-Lung-Cancer Agents.

Author

Kleandrova, Valeria V., Cordeiro, M. Natália D. S., and Speck-Planche, Alejandro

Subjects

MACHINE learning, DRUG discovery, PERTURBATION theory, MACHINE theory, VIRTUAL design

Abstract

Lung cancer is the most diagnosed malignant neoplasm worldwide and it is associated with great mortality. Currently, developing antineoplastic agents is a challenging, time-consuming, and costly process. Computational methods can speed up the early discovery of anti-lung-cancer chemicals. Here, we report a perturbation theory machine learning model based on a multilayer perceptron (PTML-MLP) model for phenotypic early antineoplastic drug discovery, enabling the rational design and prediction of new molecules as virtual versatile inhibitors of multiple lung cancer cell lines. The PTML-MLP model achieved an accuracy above 80%. We applied the fragment-based topological design (FBTD) approach to physicochemically and structurally interpret the PTML-MLP model. This enabled the extraction of suitable fragments with a positive influence on anti-lung-cancer activity against the different lung cancer cell lines. By following the aforementioned interpretations, we could assemble several suitable fragments to design four novel molecules, which were predicted by the PTML-MLP model as versatile anti-lung-cancer agents. Such predictions of potent multi-cellular anticancer activity against diverse lung cancer cell lines were rigorously confirmed by a well-established virtual screening tool reported in the literature. The present work envisages new opportunities for the application of PTML models to accelerate early antineoplastic discovery from phenotypic assays. [ABSTRACT FROM AUTHOR]

Published

2024

5. Comparison of direct‐drive Vernier wind generators for potential use at ≥10 MW power level.

Author

Kana Padinharu, Dileep Kumar, Li, Guang‐Jin, Zhu, Zi‐Qiang, Wang, Peng, Clark, Richard, and Azar, Ziad

Subjects

*PERMANENT magnet generators, *ELECTRIC power production, *ELECTRIC generators, *PERMANENT magnets, *ELECTROMAGNETS, *AUTOMOBILE power trains

Abstract

This paper investigates the benefits and challenges of the multi‐MW direct‐drive offshore wind Vernier generators. It is worth noting that the comparison of generator topologies presented in ref. [1] was for the same power level and therefore a reduced machine volume for the surface‐mounted permanent magnet Vernier (SPM‐V) generators. This would mainly impact the capital expenditure (CAPEX) cost between the different investigated machines. Whereas in this paper, the performance is compared for the same machine volume that allows the Vernier generators to produce a much higher energy yield than a conventional SPM generator. As the extra energy yield would be beneficial over the lifetime of the turbine, this will have a bigger impact than the CAPEX cost savings with a reduced machine volume. In addition, a novel Vernier machine with magnets on both the stator and rotor has been proposed to further improve the energy yield. In addition to the basic electromagnetic performance, the levelised cost of energy (LCOE) of the three generator topologies, that is, the conventional SPM, SPM‐V and the proposed Vernier machines, has been compared. The direct‐drive powertrain systems with SPM‐V and the proposed Vernier generators can achieve LCOE of 12.3% and 24% lower than that of the conventional SPM generators, indicating their huge potential as an alternative to reduce the overall cost of energy. [ABSTRACT FROM AUTHOR]

Published

2024

6. Comparison of direct‐drive Vernier wind generators for potential use at ≥10 MW power level

Author

Dileep Kumar Kana Padinharu, Guang‐Jin Li, Zi‐Qiang Zhu, Peng Wang, Richard Clark, and Ziad Azar

Subjects

electric generators, electric power generation, machine theory, permanent magnet generators, permanent magnet machines, wind power, Applications of electric power, TK4001-4102

Abstract

Abstract This paper investigates the benefits and challenges of the multi‐MW direct‐drive offshore wind Vernier generators. It is worth noting that the comparison of generator topologies presented in ref. [1] was for the same power level and therefore a reduced machine volume for the surface‐mounted permanent magnet Vernier (SPM‐V) generators. This would mainly impact the capital expenditure (CAPEX) cost between the different investigated machines. Whereas in this paper, the performance is compared for the same machine volume that allows the Vernier generators to produce a much higher energy yield than a conventional SPM generator. As the extra energy yield would be beneficial over the lifetime of the turbine, this will have a bigger impact than the CAPEX cost savings with a reduced machine volume. In addition, a novel Vernier machine with magnets on both the stator and rotor has been proposed to further improve the energy yield. In addition to the basic electromagnetic performance, the levelised cost of energy (LCOE) of the three generator topologies, that is, the conventional SPM, SPM‐V and the proposed Vernier machines, has been compared. The direct‐drive powertrain systems with SPM‐V and the proposed Vernier generators can achieve LCOE of 12.3% and 24% lower than that of the conventional SPM generators, indicating their huge potential as an alternative to reduce the overall cost of energy.

Published

2024

7. AI AND THE PUBLIC.

Author

Enis, Matt

Subjects

*ARTIFICIAL intelligence, *PUBLIC libraries, *INFORMATION literacy, *COMPUTER literacy, *MACHINE theory

Abstract

The article deals the increasing use of artificial intelligence (AI) to generate misinformation and the role of public libraries to help patrons navigate this frontier of information literacy. Topics discussed include the increase in the number of websites with AI-generated false articles, the efforts of the Toronto Public Library (TPL) to promote digital literacy and digital skills, and the AI Ambassadors program created by the cooperatives LibraryLinkNJ and LibraryLinkNJ Tech Advisory Group.

Published

2024

8. PETIT-DÉJEUNER: Dopé par l'inflation.

Author

GUÉNOT, FRÉDÉRIQUE

Subjects

BREAKFAST cereals, ECONOMIC development, SMALL business, AUTOMATION, MACHINE theory

Abstract

The article highlights the continued growth of the breakfast market in terms of value, with a 3.4% increase in sales this year. Topics include the key contributors to this growth, such as spreads, coffee pods, and cereals, and the challenges faced by the market, including declining purchase frequency and lower promotional activity.

Published

2024

9. Modification of metals and ligands in two-dimensional conjugated metal-organic frameworks for CO2 electroreduction: A combined density functional theory and machine learning study.

Author

Xing, Guanru, Liu, Shize, Sun, Guang-Yan, and Liu, Jing-yao

Subjects

*ELECTRON affinity, *DENSITY functional theory, *HYDROGEN evolution reactions, *IONIZATION energy, *MACHINE theory

Abstract

[Display omitted] Electrochemical carbon dioxide reduction reaction (CO 2 RR) is a promising technology to establish an artificial carbon cycle. Two-dimensional conjugated metal–organic frameworks (2D c-MOFs) with high electrical conductivity have great potential as catalysts. Herein, we designed a range of 2D c-MOFs with different transition metal atoms and organic ligands, TMN x O 4-x -HDQ (TM = Cr∼Cu, Mo, Ru∼Ag, W∼Au; x = 0, 2, 4; HDQ = hexadipyrazinoquinoxaline), and systematically studied their catalytic performance using density functional theory (DFT). Calculation results indicated that all of TMN x O 4-x -HDQ structures possess good thermodynamic and electrochemical stability. Notably, among the examined 37 MOFs, 6 catalysts outperformed the Cu(2 1 1) surface in terms of catalytic activity and product selectivity. Specifically, NiN 4 -HDQ emerged as an exceptional electrocatalyst for CO production in CO 2 RR, yielding a remarkable low limiting potential (U L) of −0.04 V. CuN 4 -HDQ, NiN 2 O 2 -HDQ, and PtN 2 O 2 -HDQ also exhibited high activity for HCOOH production, with U L values of −0.27, −0.29, and −0.27 V, respectively, while MnN 4 -HDQ, and NiO 4 -HDQ mainly produced CH 4 with U L values of −0.58 and −0.24 V, respectively. Furthermore, these 6 catalysts efficiently suppressed the competitive hydrogen evolution reaction. Machine learning (ML) analysis revealed that the key intrinsic factors influencing CO 2 RR performance of these 2D c-MOFs include electron affinity (E A), electronegativity (χ), the first ionization energy (I e), p-band center of the coordinated N/O atom (ε p), the radius of metal atom (r), and d-band center (ε d). Our findings may provide valuable insights for the exploration of highly active and selective CO 2 RR electrocatalysts. [ABSTRACT FROM AUTHOR]

Published

2025

10. Low-carbon information quality dimensions and random forest algorithm evaluation model in digital marketing.

Author

Gao, Weiji, Ding, Zhihua, Lu, Junyu, and Wan, Yulong

Subjects

*RANDOM forest algorithms, *CONSUMER behavior, *CONSCIOUSNESS raising, *INTERNET marketing, *MACHINE theory

Abstract

The growing urgency for low-carbon lifestyles necessitates developing effective strategies to promote sustainable consumer choices. This study investigates key dimensions of information quality that shape consumer behavior within digital marketing to achieve this goal. Employing a mixed-methods approach that integrates grounded theory and machine learning, this study identifies three core dimensions of low-carbon information quality: matching quality, presentation quality, and interpretability quality. These dimensions underscore the importance of aligning information with consumer needs, ensuring clear and accurate presentation, and fostering transparency for trustworthiness. A Random Forest algorithm-based evaluation model is constructed to assess low-carbon information quality, demonstrating its effectiveness in identifying high-quality, sustainable content. This research provides a practical tool for digital marketers to enhance their strategies, raise consumer awareness of sustainable options, and ultimately contribute to the growth of the low-carbon consumption market. [ABSTRACT FROM AUTHOR]

Published

2024

11. Parameter Optimization of a Surface Mechanical Rolling Treatment Process to Improve the Surface Integrity and Fatigue Property of FV520B Steel by Machine Learning.

Author

Zhou, Yongxin, Xing, Zheng, Zhuang, Qianduo, Sun, Jiao, and Chu, Xingrong

Subjects

*FATIGUE limit, *STRENGTH of materials, *SUPPORT vector machines, *MACHINE theory, *ANALYSIS of variance, *TAGUCHI methods

Abstract

Surface integrity is a critical factor that affects the fatigue resistance of materials. A surface mechanical rolling treatment (SMRT) process can effectively improve the surface integrity of the material, thus enhancing the fatigue property. In this paper, an analysis of variance (ANOVA) and signal-to-noise ratio (SNR) are performed by orthogonal experimental design with SMRT parameters as variables and surface integrity indicators as optimization objectives, and the support vector machine-active learning (SVM-AL) model is proposed based on machine learning theory. The entire model includes three rounds of AL processes. In each round of the AL process, the SMRT parameters with relative average deviation and high output values from cross-validation are selected for the additional experimental supplement. The results show that the prediction accuracy and generalization ability of the SVM-AL model are significantly improved compared to the support vector machine (SVM) model. A fatigue test was also carried out, and the fatigue property of the SMRT specimens predicted by the SVM-AL model is also higher than that of the other specimens. [ABSTRACT FROM AUTHOR]

Published

2024

12. Accelerating multiscale electronic stopping power predictions with time-dependent density functional theory and machine learning.

Author

Ward, Logan, Blaiszik, Ben, Lee, Cheng-Wei, Martin, Troy, Foster, Ian, and Schleife, André

Subjects

TIME-dependent density functional theory, MACHINE learning, MACHINE theory, MATERIALS science, ELASTIC scattering

Abstract

Knowing the rate at which particle radiation releases energy in a material, the "stopping power," is key to designing nuclear reactors, medical treatments, semiconductor and quantum materials, and many other technologies. While the nuclear contribution to stopping power, i.e., elastic scattering between atoms, is well understood in the literature, the route for gathering data on the electronic contribution has for decades remained costly and reliant on many simplifying assumptions, including that materials are isotropic. We establish a method that combines time-dependent density functional theory (TDDFT) and machine learning to reduce the time to assess new materials to hours on a supercomputer and provide valuable data on how atomic details influence electronic stopping. Our approach uses TDDFT to compute the electronic stopping from first principles in several directions and then machine learning to interpolate to other directions at a cost of 10 million times fewer core-hours. We demonstrate the combined approach in a study of proton irradiation in aluminum and employ it to predict how the depth of maximum energy deposition, the "Bragg Peak," varies depending on the incident angle—a quantity otherwise inaccessible to modelers and far outside the scales of quantum mechanical simulations. The lack of any experimental information requirement makes our method applicable to most materials, and its speed makes it a prime candidate for enabling quantum-to-continuum models of radiation damage. The prospect of reusing valuable TDDFT data for training the model makes our approach appealing for applications in the age of materials data science. [ABSTRACT FROM AUTHOR]

Published

2024

13. Talk more about yourself: a data-driven extended theory of reasoned action for online health communities.

Author

Wang, Xi, Zuo, Zhiya, Tong, Xing, and Zhu, Yushan

Subjects

*HEALTH, *SOCIAL support, *MACHINE learning, *ECONOMETRICS, *MACHINE theory

Abstract

Online health communities (OHCs) are able to facilitate social support exchange among people with similar health concerns, and the relationship between self-disclosure and social support exchange has been widely discussed. Build upon the previous studies, we extend the seminal theory of reasoned action (TRA) in this research, through the adoption of an salient but understudied construct, user role, which captures user inclination toward providing or seeking social support, and further explore how it impacts OHC users' self-disclosure intention. We adopt a mixed methods approach including manual coding, machine learning algorithms, and econometric analyses, and investigate over 4 million posts over 17 years from a well-developed breast cancer OHC to uncover both direct and indirect effects of user role on OHC users' intention of future self-disclosure intention. The results reveal both the main and moderating effects of user roles regarding users' self-disclosure intention. First, user with a more clear intention of social support seeking or providing are more likely to disclose personal information. Second, the relative tendency of support provision magnifies the positive effects of attitudinal and normative factors toward future disclosure. We also discuss the findings and implications of the extended TRA framework to generate some actionable insights of OHC design. [ABSTRACT FROM AUTHOR]

Published

2024

14. Auto-Scaling Techniques in Cloud Computing: Issues and Research Directions.

Author

Alharthi, Saleha, Alshamsi, Afra, Alseiari, Anoud, and Alwarafy, Abdulmalik

Subjects

*TIME series analysis, *QUEUING theory, *CLOUD computing, *ENERGY consumption, *FORECASTING, *MACHINE theory

Abstract

In the dynamic world of cloud computing, auto-scaling stands as a beacon of efficiency, dynamically aligning resources with fluctuating demands. This paper presents a comprehensive review of auto-scaling techniques, highlighting significant advancements and persisting challenges in the field. First, we overview the fundamental principles and mechanisms of auto-scaling, including its role in improving cost efficiency, performance, and energy consumption in cloud services. We then discuss various strategies employed in auto-scaling, ranging from threshold-based rules and queuing theory to sophisticated machine learning and time series analysis approaches. After that, we explore the critical issues in auto-scaling practices and review several studies that demonstrate how these challenges can be addressed. We then conclude by offering insights into several promising research directions, emphasizing the development of predictive scaling mechanisms and the integration of advanced machine learning techniques to achieve more effective and efficient auto-scaling solutions. [ABSTRACT FROM AUTHOR]

Published

2024

15. CONTROL SYSTEMS SYNTHESIS FOR ROBOTS ON THE BASE OF MACHINE LEARNING BY SYMBOLIC REGRESSION.

Author

Diveev, Askhat, Konyrbaev, Nurbek, Baishemirov, Zharasbek, Galymzhankyzy, Asem, and Abdullayev, Oralbek

Subjects

ROBOTS, MACHINE learning, MACHINE theory, ARTIFICIAL intelligence, TECHNOLOGICAL innovations

Abstract

This paper presents a novel numerical method for solving the control system synthesis problem through the application of machine learning techniques, with a particular focus on symbolic regression. Symbolic regression is used to automate the development of control systems by constructing mathematical expressions that describe control functions based on system data. Unlike traditional methods, which often require manual programming and tuning, this approach leverages machine learning to discover optimal control solutions. The paper introduces a general framework for machine learning in control system design, with an emphasis on the use of evolutionary algorithms to optimize the generated control functions. The key contribution of this research lies in the development of an algorithm based on the principle of small variations in the baseline solution. This approach significantly enhances the efficiency of discovering optimal control functions by systematically exploring the solution space with minimal adjustments. The method allows for the automatic generation of control laws, reducing the need for manual coding, which is especially beneficial in the context of complex control systems, such as robotics. To demonstrate the applicability of the method, the research applies symbolic regression to the control synthesis of a mobile robot The results of this case study show that symbolic regression can effectively automate the process of generating control functions, significantly reducing development time while improving accuracy. However, the paper also acknowledges certain limitations, including the computational demands required for symbolic regression and the challenges associated with real-time implementation in highly dynamic environments. These issues represent important areas for future research, where further optimization and hybrid approaches may enhance the method’s practicality and scalability in real-world applications. [ABSTRACT FROM AUTHOR]

Published

2024

16. Pose Measurement of the EndoWrist Round Tip Scissor Instrument with Optical Coherence Tomography.

Author

Schöne, Sandra, Pol, Nirmal, and Kahrs, Lueder A.

Subjects

OPTICAL coherence tomography, COMPUTER vision, ARTIFICIAL intelligence, ALGORITHMS, MACHINE theory

Abstract

To automate surgical (sub-)tasks in robotic surgery, the knowledge of the exact pose of the instrument is mandatory. The application of Optical Coherence Tomography (OCT) to the problem of pose measurement appears promising due to its advantages of 3D imaging and micron-scale resolution. To investigate this, 175 image sequences of the EndoWrist Round Tip Scissor Tool were acquired with an OCT system. The images differ in the opening angles of the scissor blades and the rotation angles of the entire instrument about its central axis. These image sequences were further processed through computer vision methods of the individual images followed by point cloud generation. For pose estimation, an Iterative Closest Point algorithm was implemented to register the acquired point clouds to reference point clouds created from the instrument CAD file. The implemented algorithm was able to determine the opening angle with an overall error of 2∘ ± 1.3∘ and the rotation angle with a standard deviation between several runs of 0.6∘ ±2.8∘. However, the overall processing time of (39 ± 17)s on a standard PC leaves room for further investigations. [ABSTRACT FROM AUTHOR]

Published

2024

17. Handling of uncertainty in medical data using machine learning and probability theory techniques: a review of 30 years (1991–2020).

Author

Alizadehsani, Roohallah, Roshanzamir, Mohamad, Hussain, Sadiq, Khosravi, Abbas, Koohestani, Afsaneh, Zangooei, Mohammad Hossein, Abdar, Moloud, Beykikhoshk, Adham, Shoeibi, Afshin, Zare, Assef, Panahiazar, Maryam, Nahavandi, Saeid, Srinivasan, Dipti, Atiya, Amir F., and Acharya, U. Rajendra

Subjects

*MONTE Carlo method, *PROBABILITY theory, *DEEP learning, *MACHINE learning, *MACHINE theory

Abstract

Understanding the data and reaching accurate conclusions are of paramount importance in the present era of big data. Machine learning and probability theory methods have been widely used for this purpose in various fields. One critically important yet less explored aspect is capturing and analyzing uncertainties in the data and model. Proper quantification of uncertainty helps to provide valuable information to obtain accurate diagnosis. This paper reviewed related studies conducted in the last 30 years (from 1991 to 2020) in handling uncertainties in medical data using probability theory and machine learning techniques. Medical data is more prone to uncertainty due to the presence of noise in the data. So, it is very important to have clean medical data without any noise to get accurate diagnosis. The sources of noise in the medical data need to be known to address this issue. Based on the medical data obtained by the physician, diagnosis of disease, and treatment plan are prescribed. Hence, the uncertainty is growing in healthcare and there is limited knowledge to address these problems. Our findings indicate that there are few challenges to be addressed in handling the uncertainty in medical raw data and new models. In this work, we have summarized various methods employed to overcome this problem. Nowadays, various novel deep learning techniques have been proposed to deal with such uncertainties and improve the performance in decision making. [ABSTRACT FROM AUTHOR]

Published

2024

18. Artificial Intelligence Translator DeepL Translation Quality Control.

Author

Linlin, Li

Subjects

ARTIFICIAL intelligence, PARTS of speech, MACHINE theory, EVALUATION methodology, TRANSLATORS, MACHINE translating

Abstract

With the advancement of language technology, artificial intelligence translators are also constantly developing. As an intelligent translator, the emergence of DeepL provides new opportunities for the development of human translation industry. Based on the theory of machine translation quality control, this article analyzed the translation quality control strategy of DeepL. By analyzing the performance of the designed source and target languages in the text input stage, the impact of part of speech tagging and syntactic analysis on translation quality in the text processing stage was evaluated. The machine translation quality evaluation method based on semantic similarity calculation was adopted to evaluate the translation quality of DeepL, and DeepL was compared and analyzed with other translators. This research found that DeepL translation performed well in terms of translation accuracy, fluency, and naturalness. The overall score of DeepL was 100, reaching 94.13. [ABSTRACT FROM AUTHOR]

Published

2024

19. Real-time tracking of structural evolution in 2D MXenes using theory-enhanced machine learning.

Author

Hollenbach, Jonathan D., Pate, Cassandra M., Jia, Haili, Hart, James L., Clancy, Paulette, and Taheri, Mitra L.

Subjects

*ELECTRON energy loss spectroscopy, *TRANSMISSION electron microscopy, *MACHINE learning, *MACHINE theory, *OPTICAL properties, *DEEP learning

Abstract

In situ Electron Energy Loss Spectroscopy (EELS) combined with Transmission Electron Microscopy (TEM) has traditionally been pivotal for understanding how material processing choices affect local structure and composition. However, the ability to monitor and respond to ultrafast transient changes, now achievable with EELS and TEM, necessitates innovative analytical frameworks. Here, we introduce a machine learning (ML) framework tailored for the real-time assessment and characterization of in operando EELS Spectrum Images (EELS-SI). We focus on 2D MXenes as the sample material system, specifically targeting the understanding and control of their atomic-scale structural transformations that critically influence their electronic and optical properties. This approach requires fewer labeled training data points than typical deep learning classification methods. By integrating computationally generated structures of MXenes and experimental datasets into a unified latent space using Variational Autoencoders (VAE) in a unique training method, our framework accurately predicts structural evolutions at latencies pertinent to closed-loop processing within the TEM. This study presents a critical advancement in enabling automated, on-the-fly synthesis and characterization, significantly enhancing capabilities for materials discovery and the precision engineering of functional materials at the atomic scale. [ABSTRACT FROM AUTHOR]

Published

2024

20. From Adaptive Communication Anti‐Jamming to Intelligent Communication Anti‐Jamming: 50 Years of Evolution.

Author

Zhou, Quan and Niu, Yingtao

Subjects

TELECOMMUNICATION systems, MACHINE theory, GAME theory, RADAR interference, WIRELESS communications, COMPUTATIONAL intelligence

Abstract

Herein, a comprehensive review of the evolution of intelligent communication anti‐jamming techniques is provided. First, a clear definition of the concept and elaboration on the inherent connotations and capability characteristics of intelligent communication anti‐jamming is provided. Additionally, the initial construction of an intelligent communication anti‐jamming system architecture is outlined. Subsequently, the development of intelligent communication anti‐jamming is delved, tracing its progression from early‐stage adaptive anti‐jamming techniques to the more recent advancements in intelligent anti‐jamming, which are primarily based on game theory and machine learning. Moreover, the latest research findings in this domain are thoroughly examined and the existing challenges and bottlenecks that hinder current research progress are highlighted. Finally, several viable research directions for future studies in the field of intelligent anti‐jamming are proposed. The objective is to facilitate readers in gaining a comprehensive understanding of the concept, characteristics, and system architecture of intelligent communication anti‐jamming. Additionally, it is aimed to provide a comprehensive overview of the developmental process and current state of research, thereby furnishing conceptual and theoretical support for the design of more effective and practical intelligent communication anti‐jamming systems. [ABSTRACT FROM AUTHOR]

Published

2024

21. Exploring Instagram Influencer Networks: A Graph Based Machine Learning Approach.

Author

Renganathan, Krishna Kumari, Krishnan, Sivaneasan Bala, Subramanian, Siva Shankar, and Chakrabarti, Prasun

Subjects

MACHINE learning, VIRTUAL communities, MACHINE theory, CONSUMER psychology, SOCIAL media

Abstract

This research article explores Instagram influencer networks using graph theory and machine learning techniques. With the growing impact of social media personalities, understanding their network structures and dynamics is crucial for effective marketing and brand engagement. We model Instagram's influencer ecosystem as a graph and apply several machine learning algorithms, including Node2Vec and Word2Vec, to perform tasks such as link prediction and community detection. Our analysis reveals significant patterns in influencer interactions and network connectivity, providing actionable insights into influencer behavior and the formation of online communities. These findings offer valuable implications for optimizing marketing strategies and enhancing brand collaborations within the social media landscape. [ABSTRACT FROM AUTHOR]

Published

2024

22. Harmonizing the CBCL and SDQ ADHD scores by using linear equating, kernel equating, item response theory and machine learning methods.

Author

Jović, Miljan, Haeri, Maryam Amir, Whitehouse, Andrew, and van den Berg, Stéphanie M.

Subjects

ITEM response theory, MACHINE learning, MACHINE theory, CHILD Behavior Checklist, ATTENTION-deficit hyperactivity disorder, DATA harmonization, PRESCHOOL children

Abstract

Introduction: A problem that applied researchers and practitioners often face is the fact that different institutions within research consortia use different scales to evaluate the same construct which makes comparison of the results and pooling challenging. In order to meaningfully pool and compare the scores, the scales should be harmonized. The aim of this paper is to use different test equating methods to harmonize the ADHD scores from Child Behavior Checklist (CBCL) and Strengths and Difficulties Questionnaire (SDQ) and to see which method leads to the result. Methods: Sample consists of 1551 parent reports of children aged 10-11.5 years from Raine study on both CBCL and SDQ (common persons design). We used linear equating, kernel equating, Item Response Theory (IRT), and the following machine learning methods: regression (linear and ordinal), random forest (regression and classification) and Support Vector Machine (regression and classification). Efficacy of the methods is operationalized in terms of the root-mean-square error (RMSE) of differences between predicted and observed scores in cross-validation. Results and discussion: Results showed that with single group design, it is the best to use the methods that use item level information and that treat the outcome as interval measurement level (regression approach). [ABSTRACT FROM AUTHOR]

Published

2024

23. Machine Learning Models and Applications for Early Detection.

Author

Zapata-Cortes, Orlando, Arango-Serna, Martin Darío, Zapata-Cortes, Julian Andres, and Restrepo-Carmona, Jaime Alonso

Subjects

*ARTIFICIAL neural networks, *MACHINE theory, *LITERATURE reviews, *FRAUD investigation, *SUPPORT vector machines, *K-nearest neighbor classification, *MACHINE learning

Abstract

From the various perspectives of machine learning (ML) and the multiple models used in this discipline, there is an approach aimed at training models for the early detection (ED) of anomalies. The early detection of anomalies is crucial in multiple areas of knowledge since identifying and classifying them allows for early decision making and provides a better response to mitigate the negative effects caused by late detection in any system. This article presents a literature review to examine which machine learning models (MLMs) operate with a focus on ED in a multidisciplinary manner and, specifically, how these models work in the field of fraud detection. A variety of models were found, including Logistic Regression (LR), Support Vector Machines (SVMs), decision trees (DTs), Random Forests (RFs), naive Bayesian classifier (NB), K-Nearest Neighbors (KNNs), artificial neural networks (ANNs), and Extreme Gradient Boosting (XGB), among others. It was identified that MLMs operate as isolated models, categorized in this article as Single Base Models (SBMs) and Stacking Ensemble Models (SEMs). It was identified that MLMs for ED in multiple areas under SBMs' and SEMs' implementation achieved accuracies greater than 80% and 90%, respectively. In fraud detection, accuracies greater than 90% were reported by the authors. The article concludes that MLMs for ED in multiple applications, including fraud, offer a viable way to identify and classify anomalies robustly, with a high degree of accuracy and precision. MLMs for ED in fraud are useful as they can quickly process large amounts of data to detect and classify suspicious transactions or activities, helping to prevent financial losses. [ABSTRACT FROM AUTHOR]

Published

2024

24. The Ergonomic Design Appearance of Vertical Machining Center.

Author

Lifu Liu, Xinyuan Cai, Weijie Zhou, Canyu Yang, and Wei Li

Subjects

*MACHINE theory, *DATABASE design, *HUMAN-computer interaction, *LIGHTING equipment, *ERGONOMICS

Abstract

To improve the accuracy of machining and quality of the equipment used, it is important to consider the human--machine environment when designing a vertical machining center. The designer should make full use of ergonomic principles to design the appearance of the product. This paper considers the variety of unit components that feature in the design of the CY-VMC850 vertical machining center based on its function and aesthetics. The authors propose an ergonomic design for the vertical machining center. In light of applications of the equipment, the vertical machining center and its functional components were designed using data based on human--machine theory and achieved good results. Fully consider the ergonomic equipment structure configuration, machine interface layout, operator's comfort level and psychological state and other factors, effectively improve the operating environment of operators, to reduce operator fatigue, improve the efficiency of complex parts processing. [ABSTRACT FROM AUTHOR]

Published

2024

25. Machine Learning and Optimization in Energy Management Systems for Plug-In Hybrid Electric Vehicles: A Comprehensive Review.

Author

Recalde, Angel, Cajo, Ricardo, Velasquez, Washington, and Alvarez-Alvarado, Manuel S.

Subjects

*PLUG-in hybrid electric vehicles, *ENERGY management, *MACHINE learning, *INDUSTRIAL efficiency, *FUZZY logic, *MACHINE theory, *OPTIMIZATION algorithms, *STOCHASTIC programming, *KNOWLEDGE gap theory

Abstract

This paper provides a comprehensive review of machine learning strategies and optimization formulations employed in energy management systems (EMS) tailored for plug-in hybrid electric vehicles (PHEVs). EMS stands as a pivotal component facilitating optimized power distribution, predictive and adaptive control strategies, component health monitoring, and energy harvesting, thereby enabling the maximal exploitation of resources through optimal operation. Recent advancements have introduced innovative solutions such as Model Predictive Control (MPC), machine learning-based techniques, real-time optimization algorithms, hybrid optimization approaches, and the integration of fuzzy logic with neural networks, significantly enhancing the efficiency and performance of EMS. Additionally, multi-objective optimization, stochastic and robust optimization methods, and emerging quantum computing approaches are pushing the boundaries of EMS capabilities. Remarkable advancements have been made in data-driven modeling, decision-making, and real-time adjustments, propelling machine learning and optimization to the forefront of enhanced control systems for vehicular applications. However, despite these strides, there remain unexplored research avenues and challenges awaiting investigation. This review synthesizes existing knowledge, identifies gaps, and underscores the importance of continued inquiry to address unanswered research questions, thereby propelling the field toward further advancements in PHEV EMS design and implementation. [ABSTRACT FROM AUTHOR]

Published

2024

26. ELMOPP: an application of graph theory and machine learning to traffic light coordination.

Author

Sheriff, Fareed

Subjects

MACHINE theory, GRAPH theory, INTELLIGENT transportation systems, TRAFFIC cameras, TRAFFIC patterns, TRAFFIC congestion, MACHINE learning

Abstract

Purpose: This paper presents the Edge Load Management and Optimization through Pseudoflow Prediction (ELMOPP) algorithm, which aims to solve problems detailed in previous algorithms; through machine learning with nested long short-term memory (NLSTM) modules and graph theory, the algorithm attempts to predict the near future using past data and traffic patterns to inform its real-time decisions and better mitigate traffic by predicting future traffic flow based on past flow and using those predictions to both maximize present traffic flow and decrease future traffic congestion. Design/methodology/approach: ELMOPP was tested against the ITLC and OAF traffic management algorithms using a simulation modeled after the one presented in the ITLC paper, a single-intersection simulation. Findings: The collected data supports the conclusion that ELMOPP statistically significantly outperforms both algorithms in throughput rate, a measure of how many vehicles are able to exit inroads every second. Originality/value: Furthermore, while ITLC and OAF require the use of GPS transponders and GPS, speed sensors and radio, respectively, ELMOPP only uses traffic light camera footage, something that is almost always readily available in contrast to GPS and speed sensors. [ABSTRACT FROM AUTHOR]

Published

2024

27. Identifying discriminative features of brain network for prediction of Alzheimer's disease using graph theory and machine learning.

Author

Karim, S. M. Shayez, Fahad, Md Shah, and Rathore, R. S.

Subjects

ALZHEIMER'S disease, LARGE-scale brain networks, GRAPH theory, MACHINE theory, MACHINE learning

Abstract

Alzheimer's disease (AD) is a challenging neurodegenerative condition, necessitating early diagnosis and intervention. This research leverages machine learning (ML) and graph theory metrics, derived from resting-state functional magnetic resonance imaging (rs-fMRI) data to predict AD. Using Southwest University Adult Lifespan Dataset (SALD, age 21-76 years) and the Open Access Series of Imaging Studies (OASIS, age 64-95 years) dataset, containing 112 participants, various ML models were developed for the purpose of AD prediction. The study identifies key features for a comprehensive understanding of brain network topology and functional connectivity in AD. Through a 5-fold cross-validation, all models demonstrate substantial predictive capabilities (accuracy in 82-92% range), with the support vector machine model standing out as the best having an accuracy of 92%. Present study suggests that top 13 regions, identified based on most important discriminating features, have lost significant connections with thalamus. The functional connection strengths were consistently declined for substantia nigra, pars reticulata, substantia nigra, pars compacta, and nucleus accumbens among AD subjects as compared to healthy adults and aging individuals. The present finding corroborate with the earlier studies, employing various neuroimagining techniques. This research signifies the translational potential of a comprehensive approach integrating ML, graph theory and rs-fMRI analysis in AD prediction, offering potential biomarker for more accurate diagnostics and early prediction of AD. [ABSTRACT FROM AUTHOR]

Published

2024

28. Imaginación artificial, imagen poshumana y pensamiento humano.

Author

Català Domènech, Josep M.

Subjects

ARTIFICIAL intelligence, MACHINE theory, ONTOLOGY, IMAGINATION, CAPITALISM

Abstract

Copyright of Uru: Revista de Comunicación y Cultura is the property of Universidad Andina Simon Bolivar, Sede Ecuador and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

29. FULLY ABSTRACT ENCODINGS OF λ-CALCULUS IN HOcore THROUGH ABSTRACT MACHINES.

Author

BIERNACKA, MAŁGORZATA, BIERNACKI, DARIUSZ, LENGLET, SERGUEÏ, POLESIUK, PIOTR, POUS, DAMIEN, and SCHMITT, ALAN

Subjects

MACHINE theory, LAMBDA calculus, CALCULUS, ENCODING

Abstract

We present fully abstract encodings of the call-by-name and call-by-value λ- calculus into HOcore, a minimal higher-order process calculus with no name restriction. We consider several equivalences on the λ-calculus side--normal-form bisimilarity, applicative bisimilarity, and contextual equivalence--that we internalize into abstract machines in order to prove full abstraction of the encodings. We also demonstrate that this technique scales to the λµ-calculus, i.e., a standard extension of the λ-calculus with control operators. [ABSTRACT FROM AUTHOR]

Published

2024

30. Carnival Carnivore.

Author

Link, David

Subjects

ARTIFICIAL intelligence, MACHINE theory, MACHINE learning, CARNIVAL, WORKFLOW

Abstract

Copyright of Artnodes is the property of Universitat Oberta de Catalunya and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

31. Machine learning : hands-on for developers and technical professionals.

Author

Bell, Jason

Subjects

Algorithms, Computers and IT, Machine theory

Abstract

Summary: This book provides hands-on instruction and fully-coded working examples for the most common machine learning techniques used by developers and technical professionals. It contains a breakdown of each ML variant, explaining how it works and how it is used within certain industries, allowing readers to incorporate the presented techniques into their own work as they follow along. It is an accessible, comprehensive guide for the non-mathematician, providing clear guidance that allows readers to: learn the languages of machine learning including Hadoop, Mahout, and Weka; understand decision trees, Bayesian networks, and artificial neural networks; implement association rule, real time, and batch learning; develop a strategic plan for safe, effective, and efficient machine learning

Published

2020

32. IndustrialNeRF: Accurate 3D Industrial Digital Twin Based on Integrating Neural Radiance Fields Using Unsupervised Learning.

Author

Zhou, Hui, Xu, Juangui, Lin, Hongbin, Nie, Zhenguo, and Zheng, Li

Subjects

DIGITAL twins, SUPERVISED learning, MACHINE theory, RADIANCE, MULTIPLE comparisons (Statistics), MANUFACTURING processes, REINFORCEMENT learning

Abstract

In the era of Industry 4.0, digital twin technology is revolutionizing traditional manufacturing paradigms. However, the adoption of this technology in modern manufacturing systems is fraught with challenges due to the scarcity of labeled data. Specifically, existing supervised machine learning algorithms, with their reliance on voluminous training data, find their applicability constrained in real-world production settings. This paper introduces an unsupervised 3D reconstruction approach tailored for industrial applications, aimed at bridging the data void in creating digital twin models. Our proposed model, by ingesting high-resolution 2D images, autonomously reconstructs precise 3D digital twin models without the need for manual annotations or prior knowledge. Through comparisons with multiple baseline models, we demonstrate the superiority of our method in terms of accuracy, speed, and generalization capabilities. This research not only offers an efficient approach to industrial 3D reconstruction but also paves the way for the widespread adoption of digital twin technology in manufacturing. [ABSTRACT FROM AUTHOR]

Published

2024

33. Exhaustive Variant Interaction Analysis Using Multifactor Dimensionality Reduction.

Author

Gómez-Sánchez, Gonzalo, Alonso, Lorena, Pérez, Miguel Ángel, Morán, Ignasi, Torrents, David, and Berral, Josep Ll.

Subjects

TYPE 2 diabetes, MACHINE learning, STATISTICAL learning, MACHINE theory

Abstract

One of the main goals of human genetics is to understand the connections between genomic variation and the predisposition to develop a complex disorder. These disease–variant associations are usually studied in a single independent manner, disregarding the possible effect derived from the interaction between genomic variants. In particular, in a background of complex diseases, these interactions can be directly linked to the disorder and may play an important role in disease development. Although their study has been suggested to help complete the understanding of the genetic bases of complex diseases, this still represents a big challenge due to large computing demands. Here, we take advantage of high-performance computing technologies to tackle this problem by using a combination of machine learning methods and statistical approaches. As a result, we created a containerized framework that uses multifactor dimensionality reduction (MDR) to detect pairs of variants associated with type 2 diabetes (T2D). This methodology was tested on the Northwestern University NUgene project cohort using a dataset of 1,883,192 variant pairs with a certain degree of association with T2D. Out of the pairs studied, we identified 104 significant pairs: two of which exhibit a potential functional relationship with T2D. These results place the proposed MDR method as a valid, efficient, and portable solution to study variant interaction in real reduced genomic datasets. [ABSTRACT FROM AUTHOR]

Published

2024

34. A journey with ASMETA from requirements to code: application to an automotive system with adaptive features.

Author

Arcaini, Paolo, Bonfanti, Silvia, Gargantini, Angelo, Riccobene, Elvinia, and Scandurra, Patrizia

Subjects

*ADAPTIVE control systems, *MACHINE theory, *SYSTEMS engineering, *METHODS engineering, *REQUIREMENTS engineering

Abstract

Modern automotive systems with adaptive control features require rigorous analysis to guarantee correct operation. We report our experience in modeling the automotive case study from the ABZ2020 conference using the ASMETA toolset, based on the Abstract State Machine formal method. We adopted a seamless system engineering method: from an incremental formal specification of high-level requirements to increasingly refined ASMETA models, to the C++ code generation from the model. Along this process, different validation and verification activities were performed. We explored modeling styles and idioms to face the modeling complexity and ensure that the ASMETA models can best capture and reflect specific behavioral patterns. Through this realistic automotive case study, we evaluated the applicability and usability of our formal modeling approach. [ABSTRACT FROM AUTHOR]

Published

2024

35. Machine Learning in Assessing Canine Bone Fracture Risk: A Retrospective and Predictive Approach.

Author

Kostenko, Ernest, Šengaut, Jakov, and Maknickas, Algirdas

Subjects

BONE fractures, MACHINE learning, MACHINE theory, VETERINARY medicine, RANDOM forest algorithms, SAMPLE size (Statistics), HOUGH transforms

Abstract

In the ever-evolving world of veterinary care, the occurrence of bone fractures in canines poses a common and complex problem, especially in extra-small breeds and dogs that are less than 1 year old. The objective of this research is to fill a gap in predicting the risk of canine bone fractures. A machine learning method using a random forest classifier was constructed. The algorithm was trained on a dataset consisting of 2261 cases that included several factors, such as canine age, gender, breed, and weight. The performance of the algorithm was assessed by examining its capacity to forecast the probability of fractures occurring. The findings of our study indicate that the tool has the capability to provide dependable predictions of fracture risk, consistent with our extensive dataset on fractures in canines. However, these results should be considered preliminary due to the limited sample size. This discovery is a crucial tool for veterinary practitioners, allowing them to take preventive measures to manage and prevent fractures. In conclusion, the implementation of this prediction tool has the potential to significantly transform the quality of care in the field of veterinary medicine by enabling the detection of patients at high risk, hence enabling the implementation of timely and customized preventive measures. [ABSTRACT FROM AUTHOR]

Published

2024

36. Designing and Testing a Picking and Selecting Integrated Remote-Operation-Type Dragon-Fruit-Picking Device.

Author

Yao, Penghui, Qiu, Liqi, Sun, Qun, Xu, Lipeng, Zhao, Ying, Fan, Zhongxing, and Zhang, Andong

Subjects

ORDER picking systems, PITAHAYAS, MACHINE theory, FRUIT harvesting, FRUIT growing, STRUCTURAL analysis (Engineering)

Abstract

In order to effectively solve the problems of the complex growth state of dragon fruit and how the picking process is mostly manual, this study designed a picking and selecting integrated remote-operation-type dragon-fruit-picking device. Based on SOLIDWORKS 2020 software for the three-dimensional digital design and overall assembly of key components, the structure and working theory of the machine are introduced. By improving the high-recognition-rate dragon fruit target detection algorithm based on YOLOv5, better recognition and locating effects were achieved for targets with a small size and high density, as well as those in bright-light scenes. Serial communication, information acquisition, and the precise control of each picking action were realized by building the software and hardware platforms of the picking device control system. By analyzing the working principle of the mechanical system and the mechanics of the machine picking process, the critical factors affecting the net picking rate and damage rate of the dragon-fruit-picking device were confirmed. Based on the force and parameter analysis of the test results, it was confirmed that the machine had an optimal picking influence when the flexible claw closing speed was 0.029 m/s, the electric cylinder extending speed was 0.085 m/s, and the mechanical arm moving speed was 0.15 m/s. The net picking rate of the device reached 90.5%, and the damage rate reached 2.9%. The picking device can complete the picking of a single dragon fruit, as well as a plurality of fruits grown at a growing point, and integrates the integration of picking fruits, removing bad fruits, and sorting fruits, which can improve the efficiency of dragon fruit harvesting and replace manual work. [ABSTRACT FROM AUTHOR]

Published

2024

37. DEVELOPING GAME THEORY-BASED METHODS FOR MODELING INFORMATION CONFRONTATION IN SOCIAL NETWORKS.

Author

Moldabayev, Damir, Suchkov, Mikhail, Abdiakhmetova, Zukhra, and Kartbayev, Amandyk

Subjects

GAME theory, SOCIAL network analysis, ALGORITHMS, MACHINE theory, SOCIAL space

Abstract

This paper explores the essential dynamics of social networks, specifically examining the phenomenon of information confrontation among users. The goal of the research is the development of a novel simulation methodology that integrates game-theoretic principles with probabilistic techniques to provide a robust model for these interactions. The theoretical framework of the study is founded on the conceptualization of user conflicts as a strategic game between two players. The primary objective for each player in this game is to exert influence and control over as many nodes within the network as possible. To capture the essence of these strategic interactions, we have introduced an innovative algorithm that facilitates dynamic strategy adaptation. This algorithm is pivotal in allowing players to modify their decision-making processes in real-time, based on the continually changing conditions of the network. For practical implementation and validation of the methodology, we used the Facebook Researcher open dataset, with a particular focus on its Kazakhstani segment. This dataset provides a rich source of empirical data, reflecting diverse user interactions and network configurations, which are essential for testing the model. This approach stands out by offering significant improvements in computational efficiency and resource management. By dynamically tracking and updating the network’s status, the proposed method reduces the computational resources required, thereby enhancing the scalability of the simulation. In comparing our methodology with other existing models in the field, it becomes evident that it not only matches but in several respects surpasses these methodologies in terms of flexibility. This study makes substantial contributions to the field of social network analysis by providing a sophisticated tool that can be effectively employed to navigate and analyze the complexities of information confrontation in digital social spaces. [ABSTRACT FROM AUTHOR]

Published

2024

38. NEMAS: Norm Entrepreneurship in Multi-Agent Systems †.

Author

Anavankot, Amritha Menon, Cranefield, Stephen, and Savarimuthu, Bastin Tony Roy

Subjects

MULTIAGENT systems, NEMATODES, ENTREPRENEURSHIP, MACHINE theory, GAME theory

Abstract

We propose a framework that integrates norm entrepreneurship from human society into the dynamics of an agent society. Most work in agent coordination in a distributed environment studies norms that are provided to agents as part of their specification or distributed from centralised agents. Exploring an alternate perspective, we focus on peer-to-peer interaction by providing the agents with the freedom to initiate norm creation in demanding situations like a potential interference. This paper explores the concept of norm entrepreneurship through proactive establishment and emergence of norms by agents. A common approach in prior work focuses on coordination problems that are reduced to simple game theory models involving the simultaneous performance of a single action by each agent. Instead, we define the concept of a local coordination plan (LCP), which is a sequence of actions from each agent to cope with an interference in their normal course of action. We identify LCPs across various scenarios and abstract these plans using coordination state machines (CSMs). A coordination state machine contains a separate state machine for each agent where the states encapsulate the potentially constrained and suboptimal movement options agents have at a given time. We also explore how multiple LCPs lead to a coordination state machine of the same format and how a coordination state machine can abstract across multiple scenarios. [ABSTRACT FROM AUTHOR]

Published

2024

39. Cross-Validation Visualized: A Narrative Guide to Advanced Methods.

Author

Allgaier, Johannes and Pryss, Rüdiger

Subjects

MACHINE learning, RESEARCH personnel, MACHINE theory, REPRESENTATIONS of graphs

Abstract

This study delves into the multifaceted nature of cross-validation (CV) techniques in machine learning model evaluation and selection, underscoring the challenge of choosing the most appropriate method due to the plethora of available variants. It aims to clarify and standardize terminology such as sets, groups, folds, and samples pivotal in the CV domain, and introduces an exhaustive compilation of advanced CV methods like leave-one-out, leave-p-out, Monte Carlo, grouped, stratified, and time-split CV within a hold-out CV framework. Through graphical representations, the paper enhances the comprehension of these methodologies, facilitating more informed decision making for practitioners. It further explores the synergy between different CV strategies and advocates for a unified approach to reporting model performance by consolidating essential metrics. The paper culminates in a comprehensive overview of the CV techniques discussed, illustrated with practical examples, offering valuable insights for both novice and experienced researchers in the field. [ABSTRACT FROM AUTHOR]

Published

2024

40. Improving Time Series Regression Model Accuracy via Systematic Training Dataset Augmentation and Sampling.

Author

Ströbel, Robin, Mau, Marcus, Puchta, Alexander, and Fleischer, Jürgen

Subjects

TIME series analysis, REGRESSION analysis, STATISTICAL sampling, DATA augmentation, MACHINE learning, MACHINE theory, MILLING-machines

Abstract

This study addresses a significant gap in the field of time series regression modeling by highlighting the central role of data augmentation in improving model accuracy. The primary objective is to present a detailed methodology for systematic sampling of training datasets through data augmentation to improve the accuracy of time series regression models. Therefore, different augmentation techniques are compared to evaluate their impact on model accuracy across different datasets and model architectures. In addition, this research highlights the need for a standardized approach to creating training datasets using multiple augmentation methods. The lack of a clear framework hinders the easy integration of data augmentation into time series regression pipelines. Our systematic methodology promotes model accuracy while providing a robust foundation for practitioners to seamlessly integrate data augmentation into their modeling practices. The effectiveness of our approach is demonstrated using process data from two milling machines. Experiments show that the optimized training dataset improves the generalization ability of machine learning models in 86.67% of the evaluated scenarios. However, the prediction accuracy of models trained on a sufficient dataset remains largely unaffected. Based on these results, sophisticated sampling strategies such as Quadratic Weighting of multiple augmentation approaches may be beneficial. [ABSTRACT FROM AUTHOR]

Published

2024

41. LoRa Radio Frequency Fingerprinting with Residual of Variational Mode Decomposition and Hybrid Machine-Learning/Deep-Learning Optimization.

Author

Baldini, Gianmarco and Bonavitacola, Fausto

Subjects

RADIO frequency, ELECTRONIC equipment, CONVOLUTIONAL neural networks, DEEP learning, HILBERT-Huang transform, MACHINE theory, HUMAN fingerprints

Abstract

Radio Frequency Fingerprinting (RFF) refers to the technique for identifying and classifying wireless devices on the basis of their physical characteristics, which appear in the digital signal transmitted in space. Small differences in the radio frequency front-end of the wireless devices are generated across the same wireless device model during the implementation and manufacturing process. These differences create small variations in the transmitted signal, even if the wireless device is still compliant with the wireless standard. By using data analysis and machine-learning algorithms, it is possible to classify different electronic devices on the basis of these variations. This technique has been well proven in the literature, but research is continuing to improve the classification performance, robustness to noise, and computing efficiency. Recently, Deep Learning (DL) has been applied to RFF with considerable success. In particular, the combination of time-frequency representations and Convolutional Neural Networks (CNN) has been particularly effective, but this comes at a great computational cost because of the size of the time-frequency representation and the computing time of CNN. This problem is particularly challenging for wireless standards, where the data to be analyzed is extensive (e.g., long preambles) as in the case of the LoRa (Long Range) wireless standard. This paper proposes a novel approach where two pre-processing steps are adopted to (1) improve the classification performance and (2) to decrease the computing time. The steps are based on the application of Variational Mode Decomposition (VMD) where (in opposition to the known literature) the residual of the VMD application is used instead of the extracted modes. The concept is to remove the modes, which are common among the LoRa devices, and keep with the residuals the unique intrinsic features, which are related to the fingerprints. Then, the spectrogram is applied to the residual component. Even after this step, the computing complexity of applying CNN to the spectrogram is high. This paper proposes a novel step where only segments of the spectrogram are used as input to CNN. The segments are selected using a machine-learning approach applied to the features extracted from the spectrogram using the Local Binary Pattern (LBP). The approach is applied to a recent LoRa radio frequency fingerprinting public data set, where it is shown to significantly outperform the baseline approach based on the full use of the spectrogram of the original signal in terms of both classification performance and computing complexity. [ABSTRACT FROM AUTHOR]

Published

2024

42. Metodología de estimación del tiempo de venta a través de modelos de supervivencia.

Author

Sánchez-Cabrera, David, González-Arias, Julio, and Rey-Blanco, David

Subjects

*HOUSE selling, *MACHINE learning, *DECISION making, *ACQUISITION of data, *APARTMENTS, *PROBABILITY theory, *PUBLIC spaces, *MACHINE theory

Abstract

Knowing in detail those factors that are most relevant to the probability of selling homes can be of utmost importance, among other things, as it is a long-term investment. After identifying a series of blocks that mark the evolution of their sale, such as the internal characteristics of the property in question, its location, its degree of overpricing and, above all, a real interest on the part of the buyer, a novel study is presented that models the probability of selling properties over time using machine learning techniques applied to survival problems, achieving C-index values of 76% and 72% in chalets and apartments, respectively. The methodological process has been tested in the capital of Spain, Madrid, based on data collected from the country’s main market platform during the 2018-2019 period, weighted according to official information, but the methodology is scalable to any municipality. Not only sellers, buyers or intermediaries can benefit from this contribution, but also public agents, in order to make decisions focused on design or prevention in the area of housing. [ABSTRACT FROM AUTHOR]

Published

2024

43. Exploring Antiviral Drugs on Monolayer Black Phosphorene: Atomistic Theory and Explainable Machine Learning-Assisted Platform.

Author

Laref, Slimane, Harrou, Fouzi, Sun, Ying, Gao, Xin, and Gojobori, Takashi

Subjects

*THERMODYNAMICS, *MACHINE learning, *MACHINE theory, *PHOSPHORENE, *ANTIVIRAL agents, *DENSITY functional theory

Abstract

Favipiravir (FP) and ebselen (EB) belong to a diverse class of antiviral drugs known for their significant efficacy in treating various viral infections. Utilizing molecular dynamics (MD) simulations, machine learning, and van der Waals density functional theory, we accurately elucidate the binding properties of these antiviral drugs on a phosphorene single-layer. To further investigate these characteristics, this study employs four distinct machine learning models—Random Forest, Gradient Boosting, XGBoost, and CatBoost. The Hamiltonian of antiviral molecules within a monolayer of phosphorene is appropriately trained. The key aspect of utilizing machine learning (ML) in drug design revolves around training models that are efficient and precise in approximating density functional theory (DFT). Furthermore, the study employs SHAP (SHapley Additive exPlanations) to elucidate model predictions, providing insights into the contribution of each feature. To explore the interaction characteristics and thermodynamic properties of the hybrid drug, we employ molecular dynamics and DFT calculations in a vacuum interface. Our findings suggest that this functionalized 2D complex exhibits robust thermostability, indicating its potential as an effective and enabled entity. The observed variations in free energy at different surface charges and temperatures suggest the adsorption potential of FP and EB molecules from the surrounding environment. [ABSTRACT FROM AUTHOR]

Published

2024

44. Research on geometric error compensation of ultra-precision turning-milling machine tool based on macro–micro composite technology.

Author

Sun, Hongchang, Qiao, Yingwei, Zhang, Zhijing, Dong, Yiming, Deng, Sanpeng, Jin, Xin, Zhang, Chaoxiao, and Zheng, Zhongpeng

Subjects

*MULTIBODY systems, *GEOMETRIC modeling, *SYSTEMS theory, *LASER interferometers, *MACHINE theory, *MACHINE tools

Abstract

In this paper, the geometric error modeling and compensation methods of macro–micro composite five-axis turn-milling composite machining center is studied. Firstly, the machine topological structure of the branches, intermediates, and terminal bodies of the macro–micro composite multi-body system is analyzed. Then, the tool chain transformation matrix and the end position of the workpiece chain are established to obtain the geometric error model. Based on the error compensation theory of traditional machine tool structure, the compensation mechanism of macro-level compensation and micro-level sub-micron compensation is proposed. Then, the compensation model of micro-axis error is given. Furthermore, the macro–micro composite error compensation experiment is setup; the laser interferometer is used to judge the positioning accuracy and straightness before and after compensation. The results show that the accuracy of the micro-motion platform after compensation reaches the sub-micron level, which verifies the compensation method, and the machining accuracy of the micron level is achieved through the cutting experiment. [ABSTRACT FROM AUTHOR]

Published

2024

45. Equipment Health Assessment: Time Series Analysis for Wind Turbine Performance.

Author

Backhus, Jana, Rao, Aniruddha Rajendra, Venkatraman, Chandrasekar, Padmanabhan, Abhishek, Kumar, A. Vinoth, and Gupta, Chetan

Subjects

WIND turbines, TIME series analysis, MACHINE performance, MACHINE theory

Abstract

In this study, we leverage SCADA data from diverse wind turbines to predict power output, employing advanced time series methods, specifically Functional Neural Networks (FNN) and Long Short-Term Memory (LSTM) networks. A key innovation lies in the ensemble of FNN and LSTM models, capitalizing on their collective learning. This ensemble approach outperforms individual models, ensuring stable and accurate power output predictions. Additionally, machine learning techniques are applied to detect wind turbine performance deterioration, enabling proactive maintenance strategies and health assessment. Crucially, our analysis reveals the uniqueness of each wind turbine, necessitating tailored models for optimal predictions. These insight underscores the importance of providing automatized customization for different turbines to keep human modeling effort low. Importantly, the methodologies developed in this analysis are not limited to wind turbines; they can be extended to predict and optimize performance in various machinery, highlighting the versatility and applicability of our research across diverse industrial contexts. [ABSTRACT FROM AUTHOR]

Published

2024

46. Machine Learning in Quasi-Newton Methods.

Author

Krutikov, Vladimir, Tovbis, Elena, Stanimirović, Predrag, Kazakovtsev, Lev, and Karabašević, Darjan

Subjects

*ORTHOGONALIZATION, *QUASI-Newton methods, *DERIVATIVES (Mathematics), *MACHINE theory, *ORTHOGONAL functions, *FUNCTION spaces, *MACHINE learning

Abstract

In this article, we consider the correction of metric matrices in quasi-Newton methods (QNM) from the perspective of machine learning theory. Based on training information for estimating the matrix of the second derivatives of a function, we formulate a quality functional and minimize it by using gradient machine learning algorithms. We demonstrate that this approach leads us to the well-known ways of updating metric matrices used in QNM. The learning algorithm for finding metric matrices performs minimization along a system of directions, the orthogonality of which determines the convergence rate of the learning process. The degree of learning vectors' orthogonality can be increased both by choosing a QNM and by using additional orthogonalization methods. It has been shown theoretically that the orthogonality degree of learning vectors in the Broyden–Fletcher–Goldfarb–Shanno (BFGS) method is higher than in the Davidon–Fletcher–Powell (DFP) method, which determines the advantage of the BFGS method. In our paper, we discuss some orthogonalization techniques. One of them is to include iterations with orthogonalization or an exact one-dimensional descent. As a result, it is theoretically possible to detect the cumulative effect of reducing the optimization space on quadratic functions. Another way to increase the orthogonality degree of learning vectors at the initial stages of the QNM is a special choice of initial metric matrices. Our computational experiments on problems with a high degree of conditionality have confirmed the stated theoretical assumptions. [ABSTRACT FROM AUTHOR]

Published

2024

47. Pricing Chinese Convertible Bonds with Learning-Based Monte Carlo Simulation Model.

Author

Zhu, Jiangshan, Wen, Conghua, and Li, Rong

Subjects

*CONVERTIBLE bonds, *MONTE Carlo method, *PRICES, *MACHINE learning, *MACHINE theory, *BOND market, *RANDOM forest algorithms

Abstract

In this paper, we explore a novel model for pricing Chinese convertible bonds that seamlessly integrates machine learning techniques with traditional models. The least squares Monte Carlo (LSM) method is effective in handling multiple state variables and complex path dependencies through simple regression analysis. In our approach, we incorporate machine learning techniques, specifically support vector regression (SVR) and random forest (RF). By employing Bayesian optimization to fine-tune the random forest, we achieve improved predictive performance. This integration is designed to enhance the precision and predictive capabilities of convertible bond pricing. Through the use of simulated data and real data from the Chinese convertible bond market, the results demonstrate the superiority of our proposed model over the classic LSM, confirming its effectiveness. The development of a pricing model incorporating machine learning techniques proves particularly effective in addressing the complex pricing system of Chinese convertible bonds. Our study contributes to the body of knowledge on convertible bond pricing and further deepens the application of machine learning in the field in an integrated and supportive manner. [ABSTRACT FROM AUTHOR]

Published

2024

48. Symmetrical and Asymmetrical Sampling Audit Evidence Using a Naive Bayes Classifier.

Author

Sheu, Guang-Yih and Liu, Nai-Ru

Subjects

*NAIVE Bayes classification, *AUDIT trails, *MACHINE learning, *BIG data, *MACHINE theory

Abstract

Taiwan's auditors have suffered from processing excessive audit data, including drawing audit evidence. This study advances sampling techniques by integrating machine learning with sampling. This machine learning integration helps avoid sampling bias, keep randomness and variability, and target risker samples. We first classify data using a Naive Bayes classifier into some classes. Next, a user-based, item-based, or hybrid approach is employed to draw audit evidence. The representativeness index is the primary metric for measuring its representativeness. The user-based approach samples data symmetrically around the median of a class as audit evidence. It may be equivalent to a combination of monetary and variable samplings. The item-based approach represents asymmetric sampling based on posterior probabilities for obtaining risky samples as audit evidence. It may be identical to a combination of non-statistical and monetary samplings. Auditors can hybridize those user-based and item-based approaches to balance representativeness and riskiness in selecting audit evidence. Three experiments show that sampling using machine learning integration has the benefits of drawing unbiased samples; handling complex patterns, correlations, and unstructured data; and improving efficiency in sampling big data. However, the limitations are the classification accuracy output by machine learning algorithms and the range of prior probabilities. [ABSTRACT FROM AUTHOR]

Published

2024

49. High-Frequency Financial Market Simulation and Flash Crash Scenarios Analysis: An Agent-Based Modelling Approach.

Author

Kang Gao, Vytelingum, Perukrishnen, Weston, Stephen, Luk, Wayne, and Ce Guo

Subjects

FINANCIAL markets, STOCK index futures, SECURITIES trading, MONTE Carlo method, FUTURES market, MACHINE theory

Abstract

This paper describes simulations and analysis of flash crash scenarios in an agent-based modelling framework. We design, implement, and assess a novel high-frequency agent-based financial market simulator that generates realistic millisecond-level financial price time series for the E-Mini S&P 500 futures market. Specifically, a microstructure model of a single security traded on a central limit order book is provided, where different types of traders follow different behavioural rules. The model is calibrated using the machine learning surrogate modelling approach. Statistical test and moment coverage ratio results show that the model has excellent capability of reproducing realistic stylised facts in financial markets. By introducing an institutional trader that mimics the real-world Sell Algorithm on May 6th, 2010, the proposed high-frequency agent-based financial market simulator is used to simulate the Flash Crash that took place on that day. We scrutinise the market dynamics during the simulated flash crash and show that the simulated dynamics are consistent with what happened in historical flash crash scenarios. With the help of Monte Carlo simulations, we discover functional relationships between the amplitude of the simulated 2010 Flash Crash and three conditions: the percentage of volume of the Sell Algorithm, the market maker inventory limit, and the trading frequency of fundamental traders. Similar analyses are carried out for mini flash crash events. An innovative "Spiking Trader" is introduced to the model, replicating real-world scenarios that could precipitate mini flash crash events. We analyse the market dynamics during the course of a typical simulated mini flash crash event and study the conditions affecting its characteristics. The proposed model can be used for testing resiliency and robustness of trading algorithms and providing advice for policymakers. [ABSTRACT FROM AUTHOR]

Published

2024

50. Machine mind readers.

Author

Gent, Edd

Subjects

*HUMAN behavior, *THEORY of mind, *MACHINE translating, *MACHINE theory, *ARTIFICIAL intelligence, *DEEP learning

Abstract

One of the key ways to test theory of mind in infants, says Tenenbaum, is to show them videos of people and then quiz the children about what the people are trying to achieve, and his team wanted to try this with AIs. Features SUPERHUMAN artificial intelligence is already among us. While learning-based approaches are likely to play an important role in developing more potent AIs, says Tenenbaum, explicitly building in shared ways to represent knowledge may be crucial for humans to trust and communicate with AI. But Cicero's ability to model players' mental processes still falls short of true theory of mind, says Tenenbaum, because the models are highly specific to Diplomacy and can't be repurposed for other tasks. [Extracted from the article]

Published

2023