Mathematics

19 pages, 458 KB

Open AccessFeature PaperArticle

Converging Factors of a Class of Superfactorially Divergent Stieltjes Series

by Riccardo Borghi

Mathematics 2025, 13(18), 2974; https://doi.org/10.3390/math13182974 (registering DOI) - 14 Sep 2025

Padé approximants are computational tools customarily employed for resumming divergent Stieltjes series. However, they become ineffective or even fail when applied to Stieltjes series whose moments do not satisfy the Carleman condition. Differently from Padé, Levin-type transformations incorporate important structural information on the [...] Read more.

Padé approximants are computational tools customarily employed for resumming divergent Stieltjes series. However, they become ineffective or even fail when applied to Stieltjes series whose moments do not satisfy the Carleman condition. Differently from Padé, Levin-type transformations incorporate important structural information on the converging factors of a typical Stieltjes series. For example, the computational superiority of Weniger’s

δ

-transformation over Wynn’s epsilon algorithm is ultimately based on the fact that Stieltjes series converging factors can always be represented as inverse factorial series. In the present paper, the converging factors of an important class of superfactorially divergent Stieltjes series are investigated via an algorithm developed one year ago from the first-order difference equation satisfied by the Stieltjes series converging factors. Our analysis includes the analytical derivation of the inverse factorial representation of the moment ratio sequence of the series under investigation, and demonstrates the numerical effectiveness of our algorithm, together with its implementation ease. Moreover, a new perspective on the converging factor representation problem is also proposed by reducing the recurrence relation to a linear Cauchy problem whose explicit solution is provided via Faà di Bruno’s formula and Bell’s polynomials. Full article

(This article belongs to the Special Issue Computational Methods and Applications for Numerical Analysis, 2nd Edition)

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16 pages, 336 KB

Open AccessArticle

Variant Poisson Item Count Technique with Non-Compliance

by Man-Lai Tang, Qin Wu, Daisy Hoi-Sze Chow and Guo-Liang Tian

Mathematics 2025, 13(18), 2973; https://doi.org/10.3390/math13182973 (registering DOI) - 14 Sep 2025

Abstract

In this article, we propose a variant Poisson item count technique (VPICT) that explicitly accounts for respondent non-compliance in surveys involving sensitive questions. Unlike the existing Poisson item count technique (PICT), the proposed VPICT (i) replaces the sensitive item with a triangular model [...] Read more.

In this article, we propose a variant Poisson item count technique (VPICT) that explicitly accounts for respondent non-compliance in surveys involving sensitive questions. Unlike the existing Poisson item count technique (PICT), the proposed VPICT (i) replaces the sensitive item with a triangular model that combines the sensitive and an additional non-sensitive item; (ii) utilizes data from both control and treatment groups to estimate the prevalence of the sensitive characteristic, thereby improving the accuracy and efficiency of parameter estimation; and (iii) limits the occurrence of the floor effect to cases where the respondent neither possesses the sensitive characteristic nor meets the non-sensitive condition, thus protecting a subset of respondents from privacy breaches. The method introduces a mechanism to estimate the rate of non-compliance alongside the sensitive trait, enhancing overall estimation reliability. We present the complete methodological framework, including survey design, parameter estimation via the EM algorithm, and hypothesis testing procedures. Extensive simulation studies are conducted to evaluate performance under various settings. The practical utility of the proposed approach is demonstrated through an application to real-world survey data on illegal drug use among high school students. Full article

(This article belongs to the Section D1: Probability and Statistics)

24 pages, 368 KB

Open AccessArticle

Tail Conditional Expectation and Tail Variance for Extended Generalized Skew-Elliptical Distributions

by Pin Wang, Guojing Wang, Yang Yang and Jing Yao

Mathematics 2025, 13(18), 2972; https://doi.org/10.3390/math13182972 (registering DOI) - 14 Sep 2025

Abstract

This study derives explicit expressions for the Tail Conditional Expectation (TCE) and Tail Variance (TV) within the framework of the extended generalized skew-elliptical (EGSE) distribution. The EGSE family generalizes the class of elliptical distributions by incorporating a selection method, thereby allowing simultaneous and [...] Read more.

This study derives explicit expressions for the Tail Conditional Expectation (TCE) and Tail Variance (TV) within the framework of the extended generalized skew-elliptical (EGSE) distribution. The EGSE family generalizes the class of elliptical distributions by incorporating a selection method, thereby allowing simultaneous and flexible control over location, scale, skewness, and tail heaviness in a unified parametric setting. As notable special cases, our results encompass the extended skew-normal, extended skew-Student-t, extended skew-logistic, and extended skew-Laplace distributions. The derived formulas extend existing results for generalized skew-elliptical distributions and reduce, to a considerable extent, the reliance on numerical integration, thus enhancing their tractability for actuarial and financial risk assessment. The practical utility of the proposed framework is further illustrated through an empirical analysis based on real stock market data, highlighting its effectiveness in quantifying and contrasting the heterogeneous tail risk profiles of financial assets. Full article

(This article belongs to the Special Issue Modeling, Analysis and Optimization for Mathematical Finance, Economics and Risks, 2nd Edition)

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33 pages, 1483 KB

Open AccessFeature PaperArticle

From Model to Mechanism: Enforcing Delegated Authority in SSI with Language-Based Security

by Muhamed Turkanović, Vid Keršič, Alen Horvat, Dominik Beron and Špela Čučko

Mathematics 2025, 13(18), 2971; https://doi.org/10.3390/math13182971 (registering DOI) - 14 Sep 2025

Abstract

Delegation of authority remains a critical yet insufficiently addressed capability in Self-Sovereign Identity (SSI) systems. Building on an existing delegation model that introduced the concept of a Verifiable Mandate (VM) for expressing authority and access rights, this paper extends the approach with a [...] Read more.

Delegation of authority remains a critical yet insufficiently addressed capability in Self-Sovereign Identity (SSI) systems. Building on an existing delegation model that introduced the concept of a Verifiable Mandate (VM) for expressing authority and access rights, this paper extends the approach with a rigorous formalization of delegation semantics, enabling unambiguous reasoning over roles, grants, and constraints. The formal model is aligned with standards from the World Wide Web Consortium (W3C), and its constructs are embedded into an extended credential schema that preserves compatibility with the Verifiable Credentials (VC) data model while introducing delegation-specific attributes. A generalized VM schema is defined, supporting both generic and business-specific instantiations, and ensuring structural and semantic interoperability. Policy compliance is operationalized through a policy-based enforcement architecture, where rules are authored in the Rego language and evaluated at runtime by the Open Policy Agent (OPA). The architecture incorporates trusted registries for schema and policy distribution, allowing verifiers to define and enforce context-specific delegation rules in a modular and interoperable manner. Validation through realistic scenarios, such as postal service and academic use cases, demonstrates how formal semantics, schema validation, and language-based policy enforcement can be combined to enable secure, verifiable, and context-aware delegation in SSI ecosystems. Full article

(This article belongs to the Special Issue Applied Cryptography and Blockchain Security)

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11 pages, 279 KB

Open AccessArticle

A Vertex Separator Problem for Power Graphs of Groups

by Haeder Younis Althoby, Mohammed A. Mutar and Daniele Ettore Otera

Mathematics 2025, 13(18), 2970; https://doi.org/10.3390/math13182970 (registering DOI) - 14 Sep 2025

Abstract

Given a graph G, an st-connected vertex separator (CVS) problem refers to the search for a minimum connected component in G whose removal leaves the pair of nodes s and t in two disjoint components. We investigate this specific problem on certain [...] Read more.

Given a graph G, an st-connected vertex separator (CVS) problem refers to the search for a minimum connected component in G whose removal leaves the pair of nodes s and t in two disjoint components. We investigate this specific problem on certain types of graphs—so-called power graphs associated with groups. We present a mathematical model and an algorithm to solve this problem in a reasonable time. Finally, numerical tests show that the algorithm runs considerably fast even on graphs of high orders. Full article

(This article belongs to the Special Issue Graph Theory and Applications, 3rd Edition)

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22 pages, 602 KB

Open AccessArticle

Calibration for Computer Models with Time-Varying Parameter

by Yang Sun and Xiangzhong Fang

Mathematics 2025, 13(18), 2969; https://doi.org/10.3390/math13182969 (registering DOI) - 13 Sep 2025

Abstract

Traditional calibration methods often assume constant parameters that remain unchanged across input conditions, which can limit predictive accuracy when parameters actually vary. To address this issue, we propose a novel calibration framework with time-varying parameters. Building on the idea of profile least squares, [...] Read more.

Traditional calibration methods often assume constant parameters that remain unchanged across input conditions, which can limit predictive accuracy when parameters actually vary. To address this issue, we propose a novel calibration framework with time-varying parameters. Building on the idea of profile least squares, we first apply local linear smoothing to estimate the discrepancy function between the computer model and the true process, and then use local linear smoothing again to obtain pointwise estimates of the functional calibration parameter. Through rigorous theoretical analysis, we establish the consistency and asymptotic normality of the proposed estimator. Simulation studies and an application to NASA’s OCO-2 mission demonstrate that the proposed method effectively captures parameter variation and improves predictive performance. Full article

(This article belongs to the Special Issue Parametric and Nonparametric Statistics: From Theory to Applications, 2nd Edition)

31 pages, 949 KB

Open AccessArticle

Evaluating the Effectiveness of Standardized Sales Incentive Contracts Under Agent Heterogeneity

by Ning Wang, Housheng Duan and Lang Ning

Mathematics 2025, 13(18), 2968; https://doi.org/10.3390/math13182968 (registering DOI) - 13 Sep 2025

Abstract

Salespeople, as the core executors of product distribution, form a classical principal–agent relationship with the firm. A substantial body of academic research has focused on how firms can develop optimal sales incentive contracts in various scenarios to achieve precise and effective motivation of [...] Read more.

Salespeople, as the core executors of product distribution, form a classical principal–agent relationship with the firm. A substantial body of academic research has focused on how firms can develop optimal sales incentive contracts in various scenarios to achieve precise and effective motivation of their salespeople. However, in sales management practice, firms face a tradeoff between management precision and control costs. Therefore, instead of tailoring contracts for each individual, they tend to adopt standardized incentive contracts for the broader range of salespeople. This practice has called the effectiveness of standardized incentive schemes into question. These questions have received limited attention in prior research, yet they hold significant theoretical and practical relevance for optimizing sales incentive mechanisms and improving managerial effectiveness. This study underscores the critical role of salesperson heterogeneity in shaping the effectiveness of standardized incentive contracts. By constructing game-theoretical models of standardized sales incentive contracts in two scenarios and analyzing how heterogeneous salespeople respond to these contracts, the study finds that heterogeneity weakens the incentive effectiveness of standardized contracts. To address this challenge, we propose two practical evaluation methods to help firms assess and adjust both the degree of salesperson heterogeneity and the actual effectiveness of standardized incentive contracts. Full article

(This article belongs to the Special Issue Advances in Mathematical Optimization in Operational Research)

31 pages, 2099 KB

Open AccessArticle

Rolling Horizon Optimization of Allocation-Location in Agricultural Emergency Supply Chains

by Qinxi Shi, Yiping Jiang and Jie Chu

Mathematics 2025, 13(18), 2967; https://doi.org/10.3390/math13182967 (registering DOI) - 13 Sep 2025

Abstract

Ensuring the smooth production and distribution of agricultural products is a crucial pathway to achieving a balance between supply and demand. However, the information within the agricultural product supply chain is characterized by its dynamic and asymmetric nature, compounded by frequent outbreaks of [...] Read more.

Ensuring the smooth production and distribution of agricultural products is a crucial pathway to achieving a balance between supply and demand. However, the information within the agricultural product supply chain is characterized by its dynamic and asymmetric nature, compounded by frequent outbreaks of infectious diseases that lead to supply interruptions and allocation difficulties. These factors collectively undermine the operational efficiency and resilience of the agricultural product supply chain. This study develops an integrated allocation-location optimization model for emergency agricultural product supply chains based on a rolling horizon approach. The model accounts for both supply shortage and sufficient scenarios, with objectives to maximize the comprehensive material satisfaction rate, minimize the activation cost of distribution centers, and minimize allocation time. The proposed model is solved using the Benders decomposition algorithm. Finally, a case study based on the Shanghai pandemic outbreak is conducted for numerical simulation. The results demonstrate the effectiveness of the model: the comprehensive material satisfaction rate increases progressively over the rolling periods, rising from approximately 84% in period 1 to 100% by period 3. Furthermore, fairness analysis confirms that the model also effectively ensures equitable distribution of supplies. Full article

(This article belongs to the Special Issue Recent Advances in Planning and Scheduling for Supply Chain Optimization)

13 pages, 333 KB

Open AccessArticle

Green’s Function for the Cauchy Problem to the Dissipative Linear Evolution Equation of Arbitrary Order

by Daniil R. Nifontov and Nikolay A. Kudryashov

Mathematics 2025, 13(18), 2966; https://doi.org/10.3390/math13182966 (registering DOI) - 13 Sep 2025

Abstract

This work addresses the Cauchy problem for a linear equation with a first-order time derivative t and an arbitrary-order spatial derivative x. This equation is a generalization of the linear heat equation of the second order in the case of arbitrary order [...] Read more.

This work addresses the Cauchy problem for a linear equation with a first-order time derivative t and an arbitrary-order spatial derivative x. This equation is a generalization of the linear heat equation of the second order in the case of arbitrary order with respect to spatial variable. The considered linear equation arises from the linearization of the Burgers hierarchy of equations. The Cauchy problem to a linear equation can be solved using the Green function method. The Green function is explicitly constructed for the case of dissipative and dispersive equations and is expressed in terms of generalized hypergeometric functions. The general formulas obtained for representing Green’s function are new. A discussion of specific cases of the equation is also provided. Full article

(This article belongs to the Section E: Applied Mathematics)

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22 pages, 1579 KB

Open AccessArticle

Stance Detection in Arabic Tweets: A Machine Learning Framework for Identifying Extremist Discourse

by Arwa K. Alkhraiji and Aqil M. Azmi

Mathematics 2025, 13(18), 2965; https://doi.org/10.3390/math13182965 (registering DOI) - 13 Sep 2025

Abstract

Terrorism remains a critical global challenge, and the proliferation of social media has created new avenues for monitoring extremist discourse. This study investigates stance detection as a method to identify Arabic tweets expressing support for or opposition to specific organizations associated with extremist [...] Read more.

Terrorism remains a critical global challenge, and the proliferation of social media has created new avenues for monitoring extremist discourse. This study investigates stance detection as a method to identify Arabic tweets expressing support for or opposition to specific organizations associated with extremist activities, using Hezbollah as a case study. Thousands of relevant Arabic tweets were collected and manually annotated by expert annotators. After extensive preprocessing and feature extraction using term frequency–inverse document frequency (tf-idf), we implemented traditional machine learning (ML) classifiers—Support Vector Machines (SVMs) with multiple kernels, Multinomial Naïve Bayes, and Weighted K-Nearest Neighbors. ML models were selected over deep learning (DL) approaches due to (1) limited annotated Arabic data availability for effective DL training; (2) computational efficiency for resource-constrained environments; and (3) the critical need for interpretability in counterterrorism applications. While interpretability is not a core focus of this work, the use of traditional ML models (rather than DL) makes the system inherently more transparent and readily adaptable for future integration of interpretability techniques. Comparative experiments using FastText word embeddings and tf-idf with supervised classifiers revealed superior performance with the latter approach. Our best result achieved a macro F-score of 78.62% using SVMs with the RBF kernel, demonstrating that interpretable ML frameworks offer a viable and resource-efficient approach for monitoring extremist discourse in Arabic social media. These findings highlight the potential of such frameworks to support scalable and explainable counterterrorism tools in low-resource linguistic settings. Full article

(This article belongs to the Special Issue Machine Learning Theory and Applications)

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26 pages, 2373 KB

Open AccessArticle

Enhancing Road Freight Price Forecasting Using Gradient Boosting Ensemble Supervised Machine Learning Algorithm

by Artur Budzyński and Maria Cieśla

Mathematics 2025, 13(18), 2964; https://doi.org/10.3390/math13182964 (registering DOI) - 12 Sep 2025

Abstract

For effective logistics planning and pricing strategies, it is essential to predict road freight transportation costs accurately. Using a real-world dataset with 45,569 freight offers and 52 different variables, including financial, logistical, geographical, and temporal characteristics, this study presents a data-driven method for [...] Read more.

For effective logistics planning and pricing strategies, it is essential to predict road freight transportation costs accurately. Using a real-world dataset with 45,569 freight offers and 52 different variables, including financial, logistical, geographical, and temporal characteristics, this study presents a data-driven method for forecasting transport prices. To create a strong predictive model, the approach combines hyperparameter optimization, evolutionary feature selection, and extensive feature engineering. Because gradient boosting works well for modelling intricate, nonlinear relationships, it was used as the main algorithm. Temporal dependencies were maintained through a nested cross-validation framework with a time-series split, which improved the generalizability of the model. With a mean absolute percentage error (MAPE) of 6.27%, the model showed excellent predictive accuracy. Key predictive factors included total transport distance, load and delivery quantities, temperature constraints, and aggregated categorical features such as route and vehicle type. The results confirm that evolutionary algorithms are capable of efficiently optimizing model parameters, as well as feature subsets, greatly enhancing interpretability and performance. In the freight logistics industry, this method offers useful insights for operational and dynamic pricing decision-making. This model may be expanded in future research to include external data sources and investigate its suitability for use in various geographic locations and modes of transportation. Full article

(This article belongs to the Special Issue Evolutionary Machine Learning for Real-World Applications)

19 pages, 1988 KB

Open AccessArticle

Enhanced Fault Diagnosis of Drive-Fed Induction Motors Using a Multi-Scale Wide-Kernel CNN

by Prince, Byungun Yoon and Prashant Kumar

Mathematics 2025, 13(18), 2963; https://doi.org/10.3390/math13182963 (registering DOI) - 12 Sep 2025

Abstract

Induction motor (IM) drives are widely used in industrial applications, particularly within the renewable energy sector, owing to their fast dynamic response and robust performance. Reliable condition monitoring is essential to ensure uninterrupted operation, minimize unexpected downtime, and avoid associated financial losses. Although [...] Read more.

Induction motor (IM) drives are widely used in industrial applications, particularly within the renewable energy sector, owing to their fast dynamic response and robust performance. Reliable condition monitoring is essential to ensure uninterrupted operation, minimize unexpected downtime, and avoid associated financial losses. Although numerous studies have introduced advanced fault detection techniques for IMs, early fault identification remains a significant challenge, especially in systems powered by electronic drives. To address the limitations of manual feature extraction, deep learning methods, particularly conventional convolutional neural networks (CNNs), have emerged as promising tools for automated fault diagnosis. However, enhancing their capability to capture a broader spectrum of spatial features can further improve detection accuracy. This study presents a novel fault detection framework based on a multi-wide-kernel convolutional neural network (MWK-CNN) tailored for drive-fed induction motors. By integrating convolutional kernels of varying widths, the proposed architecture effectively captures both fine-grained details and large-scale patterns in the input signals, thereby enhancing its ability to distinguish between normal and faulty operating states. Electrical signals acquired from drive-fed IMs under diverse operating conditions were used to train and evaluate the MWK-CNN. Experimental results demonstrate that the proposed model exhibits heightened sensitivity to subtle fault signatures, leading to superior diagnostic accuracy and outperforming existing state-of-the-art approaches for fault detection in drive-fed IM systems. Full article

19 pages, 403 KB

Open AccessArticle

On the Critical Parameters of Branching Random Walks

by Daniela Bertacchi and Fabio Zucca

Mathematics 2025, 13(18), 2962; https://doi.org/10.3390/math13182962 (registering DOI) - 12 Sep 2025

Abstract

Given a discrete spatial structure X, we define continuous-time branching processes

{η_{t}}_{t \geq 0}

that model a population breeding and dying on X. These processes are usually called branching random walks, and

η_{t} (x)

[...] Read more.

Given a discrete spatial structure X, we define continuous-time branching processes

{η_{t}}_{t \geq 0}

that model a population breeding and dying on X. These processes are usually called branching random walks, and

η_{t} (x)

denotes the number of individuals alive at site x at time t. They are characterised by breeding rates

k_{x y}

(governing the rate at which individuals at x send offspring to y) and by a multiplicative speed parameter

λ

. These processes also serve as models for epidemic spreading, where

λ k_{x y}

represents the infection rate from x to y. In this context,

η_{t} (x)

represents the number of infected individuals at x at time t, and the removal of an individual is due to either death or recovery. Two critical parameters of interest are the global critical parameter

λ_{w}

, related to global survival, and the local critical parameter

λ_{s}

, related to survival within finite sets (with

λ_{w} \leq λ_{s}

). In disease or pest control, the primary goal is to lower

λ

so that the process dies out, at least locally. Nevertheless, a process that survives globally can still pose a threat, especially if sudden changes cause global survival to transition into local survival. In fact, local modifications to the rates can affect the values of both critical parameters, making it important to understand when and how they can be increased. Using results on the comparison of the extinction probabilities for a single branching random walk across different sets, we extend the analysis to the extinction probabilities and critical parameters of pairs of branching random walks whose rates coincide outside a fixed set

A \subseteq X

. We say that two branching random walks are equivalent if their rates coincide everywhere except on a finite subset of X. Given an equivalence class of branching random walks, we prove that if one process has

λ_{w}^{*} \neq λ_{s}^{*}

, then

λ_{w}^{*}

is the maximal possible value of this parameter within the class. We describe the possible configurations for the critical parameters within these equivalence classes. Full article

(This article belongs to the Special Issue Applied Probability, Statistics and Operational Research)

17 pages, 6529 KB

Open AccessArticle

Assessing the Credibility of AIS-Calculated Risks in Busy Waterways: A Case Study of Hong Kong Waters

by Yao Jiang, Wenyu Xu and Dong Yang

Mathematics 2025, 13(18), 2961; https://doi.org/10.3390/math13182961 - 12 Sep 2025

Abstract

The increasing complexity of maritime traffic, driven by the expansion of international trade and growing shipping demand, has resulted in frequent ship collisions with significant consequences. This paper evaluates the credibility of the risk, calculated using the automatic identification system (AIS), in busy [...] Read more.

The increasing complexity of maritime traffic, driven by the expansion of international trade and growing shipping demand, has resulted in frequent ship collisions with significant consequences. This paper evaluates the credibility of the risk, calculated using the automatic identification system (AIS), in busy waterways and integrates AIS data with video surveillance data to comprehensively analyze the risk of ship collision. Specifically, this study utilizes the IALA Waterways Risk Assessment Program (IWRAP) tool to simulate maritime traffic flow and assess collision risk probabilities across various study areas and time periods. In addition, we analyze data from 2019 to 2022 to explore the impact of the COVID-19 pandemic on maritime traffic and find that the number of ship arrivals during the epidemic has decreased, resulting in a decrease in accident risk. We identify four traffic conflict areas in the real-world study area and point out that there are multi-directional ship interactions in these areas, but compliance with traffic rules can effectively reduce the risk of accidents. Additionally, simulations suggest that even a 13.5% increase in ocean-going vessel (OGV) traffic would raise collision risk by only 0.0247 incidents/year. To more accurately analyze the risk of waterways, we investigate the capture of dynamic information for ships in waterways by using the learning-driven detection model for real-time ship detection. These findings highlight the effectiveness of combining AIS and visual data for waterway risk assessment, offering critical insights for improving safety measures and informing policy development. Full article

36 pages, 3354 KB

Open AccessArticle

Optimization of EHA Hydraulic Cylinder Buffer Design Using Enhanced SBO–BP Neural Network and NSGA-II

by Shuai Cao, Weibo Li, Kangzheng Huang, Xiaoqing Deng and Rentai Li

Mathematics 2025, 13(18), 2960; https://doi.org/10.3390/math13182960 - 12 Sep 2025

Abstract

In order to solve a certain type of Electro-Hydrostatic Actuators (EHA) hydraulic cylinder small cavity buffer end impact problem, based on AMESim to establish a hydraulic cylinder small cavity buffer machine–hydraulic joint simulation model. First, four important structural parameters, namely, the fitting clearance [...] Read more.

In order to solve a certain type of Electro-Hydrostatic Actuators (EHA) hydraulic cylinder small cavity buffer end impact problem, based on AMESim to establish a hydraulic cylinder small cavity buffer machine–hydraulic joint simulation model. First, four important structural parameters, namely, the fitting clearance G of the buffer sleeve and buffer hole, the fixed orifice D, the wedge face angle , and the wedge face length L₁ were selected to analyze their influence on the pressure of the buffer chamber and the end speed of the piston. Second, enhanced Social Behavior Optimization (SBO) was used to optimize the back-propagation neural network (BP) model to construct a prediction model for the buffer time T of the small chamber of the hydraulic cylinder, the end-piston speed V_e, the rate of change of the end-piston speed V_r, and the return speed of the hydraulic oil V_h. The SBO–BP model performed well in several key performance evaluation metrics, showing better prediction accuracy and generalization performance. Finally, the multi-objective Non-dominated Sorting Genetic Algorithm II (NSGA-II) was used to optimize the hydraulic cylinder small-cavity buffer structure using the multi-objective NSGA-II with the objectives of the shortest buffer time, the minimum end-piston speed, the minimum change rate of the end-piston speed, and the minimum hydraulic oil reflux speed. The optimized design reduced the piston end speed from 0.060 m/s to 0.032 m/s, corresponding to a 46.7% improvement. The findings demonstrate that the proposed hybrid optimization approach effectively alleviates the end-impact problem of EHA small-cavity buffers and provides a novel methodology for achieving high-performance and reliable actuator designs. Full article

25 pages, 2747 KB

Open AccessArticle

A Dynamic Information-Theoretic Network Model for Systemic Risk Assessment with an Application to China’s Maritime Sector

by Lin Xiao, Arash Sioofy Khoojine, Hao Chen and Congyin Wang

Mathematics 2025, 13(18), 2959; https://doi.org/10.3390/math13182959 - 12 Sep 2025

Abstract

This paper develops a dynamic information-theoretic network framework to quantify systemic risk in China’s maritime–commodity nexus with a focus on the Yangtze River Basin using eight monthly indicators, CCFI, CBCFI, BDI, YRCFI, GAUP, MPCT, CPUS, and ASMC. We resample, impute, standardize, and difference [...] Read more.

This paper develops a dynamic information-theoretic network framework to quantify systemic risk in China’s maritime–commodity nexus with a focus on the Yangtze River Basin using eight monthly indicators, CCFI, CBCFI, BDI, YRCFI, GAUP, MPCT, CPUS, and ASMC. We resample, impute, standardize, and difference series to achieve stationary time series. Nonlinear interdependencies are estimated via KSG mutual information (MI) within sliding windows; networks are filtered using the Planar Maximally Filtered Graph (PMFG) with bootstrap edge validation (95th percentile) and benchmarked against the MST. Average MI indicates moderate yet heterogeneous dependence (about 0.13–0.17), revealing a container/port core (CCFI–YRCFI–MPCT), a bulk/energy spine (BDI–CPUS), and commodity bridges via GAUP. Dynamic PMFG metrics show a generally resilient but episodically vulnerable structure: density and compactness decline in turbulence. Stress tests demonstrate high redundancy to diffuse link failures (connectivity largely intact until ∼70–80% edge removal) but pronounced sensitivity of diffusion capacity to targeted multi-node outages. Early-warning indicators based on entropy rate and percolation threshold Z-scores flag recurring windows of elevated fragility; change point detection evaluation of both metrics isolates clustered regime shifts (2015–2016, 2018–2019, 2021–2022, and late 2023–2024). A Systemic Importance Index (SII) combining average centrality and removal impact ranks MPCT and CCFI as most critical, followed by BDI, with GAUP/CPUS mid-peripheral and ASMC peripheral. The findings imply that safeguarding port throughput and stabilizing container freight conditions deliver the greatest resilience gains, while monitoring bulk/energy linkages is essential when macro shocks synchronize across markets. Full article

(This article belongs to the Section E: Applied Mathematics)

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37 pages, 1134 KB

Open AccessArticle

SOMTreeNet: A Hybrid Topological Neural Model Combining Self-Organizing Maps and BIRCH for Structured Learning

by Yunus Doğan

Mathematics 2025, 13(18), 2958; https://doi.org/10.3390/math13182958 - 12 Sep 2025

Abstract

This study introduces SOMTreeNet, a novel hybrid neural model that integrates Self-Organizing Maps (SOMs) with BIRCH-inspired clustering features to address structured learning in a scalable and interpretable manner. Unlike conventional deep learning models, SOMTreeNet is designed with a recursive and modular topology that [...] Read more.

This study introduces SOMTreeNet, a novel hybrid neural model that integrates Self-Organizing Maps (SOMs) with BIRCH-inspired clustering features to address structured learning in a scalable and interpretable manner. Unlike conventional deep learning models, SOMTreeNet is designed with a recursive and modular topology that supports both supervised and unsupervised learning, enabling tasks such as classification, regression, clustering, anomaly detection, and time-series analysis. Extensive experiments were conducted using various publicly available datasets across five analytical domains: classification, regression, clustering, time-series forecasting, and image classification. These datasets cover heterogeneous structures including tabular, temporal, and visual data, allowing for a robust evaluation of the model’s generalizability. Experimental results demonstrate that SOMTreeNet consistently achieves competitive or superior performance compared to traditional machine learning and deep learning methods while maintaining a high degree of interpretability and adaptability. Its biologically inspired hierarchical structure facilitates transparent decision-making and dynamic model growth, making it particularly suitable for real-world applications that demand both accuracy and explainability. Overall, SOMTreeNet offers a versatile framework for learning from complex data while preserving the transparency and modularity often lacking in black-box models. Full article

(This article belongs to the Special Issue New Advances in Data Analytics and Mining)

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32 pages, 1551 KB

Open AccessFeature PaperArticle

Free Vibration Analysis of Porous FGM Plates on Elastic Foundations with Temperature-Dependent Material Properties

by Aleksandar Radaković, Dragan Čukanović, Aleksandar Nešović, Petar Knežević, Milan T. Djordjević and Gordana Bogdanović

Mathematics 2025, 13(18), 2957; https://doi.org/10.3390/math13182957 - 12 Sep 2025

Abstract

This study investigates the free vibration behaviors of functionally graded (FGM) plates with a porous structure, resting on a Kerr-type elastic foundation, while accounting for thermal effects and complex material property distributions. Within the framework of higher-order shear deformation theory (HSDT), two novel [...] Read more.

This study investigates the free vibration behaviors of functionally graded (FGM) plates with a porous structure, resting on a Kerr-type elastic foundation, while accounting for thermal effects and complex material property distributions. Within the framework of higher-order shear deformation theory (HSDT), two novel shape functions are introduced to accurately model transverse shear deformation across the plate thickness without employing shear correction factors. These functions are constructed to satisfy shear stress boundary conditions and capture nonlinear effects induced by material gradation and porosity. A variational formulation is developed to describe the dynamic response of FGM plates in a thermo-mechanical environment, incorporating temperature-dependent material properties and three porosity distributions: uniform, linear, and trigonometric. Numerical solutions are obtained using in-house MATLAB codes, allowing complete control over the formulation and interpretation of the results. The model is validated through detailed comparisons with existing literature, demonstrating high accuracy. The findings reveal that the porosity distribution pattern and gradient intensity significantly influence natural frequencies and mode shapes. The trigonometric porosity distribution exhibits favorable dynamic performance due to preserved stiffness in the surface regions. Additionally, the Kerr-type elastic foundation enables fine tuning of the dynamic response, depending on its specific parameters. The proposed approach provides a reliable and efficient tool for analyzing FGM structures under complex loading conditions and lays the groundwork for future extensions involving nonlinear, time-dependent, and multiphysics analyses. Full article

(This article belongs to the Special Issue Mathematical Modelling, Analysis, and Optimization for Engineering and Mechanics)

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27 pages, 2378 KB

Open AccessArticle

Advancing Graph Neural Networks for Complex Relational Learning: A Multi-Scale Heterogeneity-Aware Framework with Adversarial Robustness and Interpretable Analysis

by Hao Yang, Yunhong Zhou, Xianzhe Ji, Zifan Liu, Zhen Tian, Qiang Tang and Yanchao Shi

Mathematics 2025, 13(18), 2956; https://doi.org/10.3390/math13182956 - 12 Sep 2025

Abstract

Graph Neural Networks (GNNs) face fundamental algorithmic challenges in real-world applications due to a combination of data heterogeneity, adversarial heterophily, and severe class imbalance. A critical research gap exists for a unified framework that can simultaneously address these issues, limiting the deployment of [...] Read more.

Graph Neural Networks (GNNs) face fundamental algorithmic challenges in real-world applications due to a combination of data heterogeneity, adversarial heterophily, and severe class imbalance. A critical research gap exists for a unified framework that can simultaneously address these issues, limiting the deployment of GNNs in high-stakes domains like financial fraud detection and social network analysis. This paper introduces HAG-CFNet, a novel framework designed to bridge this gap by integrating three key innovations: (1) a heterogeneity-aware message-passing mechanism that uses relation-specific attention to capture rich semantic information; (2) a dual-channel heterophily detection module that explicitly identifies and neutralizes adversarial camouflage through separate aggregation pathways; and (3) a domain-aware counterfactual generator that produces plausible, actionable explanations by co-optimizing feature and structural perturbations. These are supported by a synergistic imbalance correction strategy combining graph-adapted oversampling with cost-sensitive learning. Extensive testing on large-scale financial datasets validates the framework’s impact: HAG-CFNet achieves a 4.2% AUC-PR improvement over state-of-the-art methods, demonstrates superior robustness by reducing performance degradation under structural noise by over 50%, and generates counterfactual explanations with 91.8% validity while requiring minimal perturbations. These advances provide a direct pathway to building more trustworthy and effective AI systems for critical applications ranging from financial risk management to supply chain analysis and social media content moderation. Full article

(This article belongs to the Special Issue New Advances in Graph Neural Networks (GNNs) and Applications)

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