Infrastructures

30 pages, 3685 KB

Open AccessArticle

Conflict Risk Assessment Between Pedestrians and Right-Turn Vehicles: A Trajectory-Based Analysis of Front and Rear Wheel Dynamics

by Rui Li, Guohua Liang, Chenzhu Wang, Said M. Easa, Yajuan Deng, Baojie Wang and Yi Mao

Infrastructures 2025, 10(12), 330; https://doi.org/10.3390/infrastructures10120330 - 2 Dec 2025

Abstract

Right-turning vehicles at intersections permitting right turn on red (RTOR) frequently conflict with pedestrians, posing significant safety risks. Existing studies often simplify vehicle trajectories by treating vehicles as centroid points, ignoring the spatial disparities between pedestrians and vehicles. To address this gap, we [...] Read more.

Right-turning vehicles at intersections permitting right turn on red (RTOR) frequently conflict with pedestrians, posing significant safety risks. Existing studies often simplify vehicle trajectories by treating vehicles as centroid points, ignoring the spatial disparities between pedestrians and vehicles. To address this gap, we propose a conflict risk assessment framework based on front and rear wheel trajectories (FRWTs), which accounts for the dynamic differences in vehicle segments during turns. First, we partition vehicles into four segments (inner/outer and front/rear wheels) and develop a trajectory prediction model to quantify risk variations across these segments. Our analysis reveals that the inner front wheel poses the highest collision risk due to its speed, trajectory curvature, and pedestrian proximity. Next, we introduce three conflict interaction modes—hard interaction, no interaction, and soft interaction—and evaluate the applicability of conflict indicators (e.g., Time to Collision (TTC) and Post-Encroachment Time (PET)) under each mode. Using a Support Vector Machine (SVM) classification algorithm, we classify risk severity with high accuracy: 96% for hard interaction, 96% for no interaction, and 97% for soft interaction modes when TTC-PET dual indicators are employed. Our findings demonstrate that FRWT-based modeling significantly improves conflict risk assessment accuracy compared to centroid-point approaches. This work provides actionable insights for proactive traffic safety management and supports the development of targeted conflict mitigation strategies at RTOR intersections. Full article

(This article belongs to the Special Issue Data-Driven Innovations in Smart and Safe Transportation Infrastructure)

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38 pages, 883 KB

Open AccessArticle

Barriers and Enablers in Implementing the Vision Zero Approach to Road Safety: A Case Study of Haryana, India, with Lessons from Sweden

by Mahfooz Ulhaq Bajwa, Wafaa Saleh and Grigorios Fountas

Infrastructures 2025, 10(12), 329; https://doi.org/10.3390/infrastructures10120329 - 1 Dec 2025

Abstract

Empirical studies on barriers and enablers to implementing Vision Zero remain limited, especially in low- and middle-income countries (LMICs), limiting broader adoption. India exemplifies this gap: while some cities and states have adopted Vision Zero, national uptake has been slow. The purpose of [...] Read more.

Empirical studies on barriers and enablers to implementing Vision Zero remain limited, especially in low- and middle-income countries (LMICs), limiting broader adoption. India exemplifies this gap: while some cities and states have adopted Vision Zero, national uptake has been slow. The purpose of this study is to investigate barriers and enablers in the Indian state of Haryana. Using a qualitative approach, we conducted semi-structured interviews with 16 Vision Zero experts selected through purposive and snowball sampling. Data was analyzed using inductive content analysis following Graneheim and Lundman’s approach. The findings revealed five categories and 21 sub-categories of barriers and four categories with 13 sub-categories of enablers. Cultural and institutional barriers were most prominent, including poor road safety culture, staff shortages, limited technical expertise and weak research capacity. Operational, financial and political barriers were less frequently discussed but included complex management processes, delayed funding and lack of political will in certain states. Key enablers included strong political support, long-term vision, ambitious road safety targets, and continuous monitoring and evaluation. Identifying these factors can strengthen the implementation capacity in LMICs and guide policymakers in overcoming challenges and leveraging enablers to advance Vision Zero. Full article

(This article belongs to the Special Issue Sustainable Road Design and Traffic Management)

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18 pages, 4358 KB

Open AccessArticle

Investigation on Bearing Characteristics for Critical Fittings of Transmission Lines Undergoing Coupled Ice–Wind Loads

by Zhiguo Li, Guoliang Ye, Dongjia Liu, Zhiyi Liu, Xiaohui Zhang and Guizao Huang

Infrastructures 2025, 10(12), 328; https://doi.org/10.3390/infrastructures10120328 - 1 Dec 2025

Abstract

The safe and stable operation of ultra-high-voltage (UHV) transmission lines is fundamental to ensuring efficient and large-capacity power delivery. Critical fittings, as essential load-bearing components connecting towers, conductors, and insulator strings, are highly susceptible to damage under complex ice–wind conditions, thereby posing significant [...] Read more.

The safe and stable operation of ultra-high-voltage (UHV) transmission lines is fundamental to ensuring efficient and large-capacity power delivery. Critical fittings, as essential load-bearing components connecting towers, conductors, and insulator strings, are highly susceptible to damage under complex ice–wind conditions, thereby posing significant threats to grid security. To address the prevalent issues of jumper spacer breakage and conductor abrasion observed in field maintenance, a systematic finite element analysis model incorporating bundled conductors, jumper structures, and associated fittings was established. This model enabled comprehensive investigation of the effects of non-uniform ice accretion, wind loading, and ice-shedding impacts on the bearing characteristics of critical fittings. Through high-throughput computational simulations, a large-scale dataset capturing the bearing characteristics of jumper spacers was constructed. Based on this dataset, a damage risk assessment model under complex ice–wind conditions was developed using a multi-layer feedforward deep neural network (MLF-DNN). The results indicated that wind loading had a relatively minor influence on jumper spacers, whereas ice accretion and ice-shedding impacts were the dominant factors leading to damage. In particular, non-uniform ice-shedding readily induced unbalanced forces among sub-conductors, significantly increasing stress levels in jumper spacers and resulting in substantial risk. The proposed risk assessment model demonstrated high predictive accuracy and strong generalization capability, providing effective support for rapid evaluation and early warning of damage to fittings in UHV transmission lines under complex ice–wind environments. Full article

(This article belongs to the Special Issue Advanced Technologies for Climate Resilient Infrastructures)

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25 pages, 2975 KB

Open AccessArticle

Laboratory Study on the Effect of Kraft Lignin and Sasobit on Construction Temperatures, Compactability and Physical Properties of Hot and Warm Mix Asphalt

by Ali Rezazad Gohari, Sébastien Lamothe, Jean-Pascal Bilodeau, Ahmad Mansourian and Alan Carter

Infrastructures 2025, 10(12), 327; https://doi.org/10.3390/infrastructures10120327 - 1 Dec 2025

Abstract

This study investigates the feasibility of using Kraft lignin in Hot and Warm Mix Asphalt (HMA and WMA), with a particular focus on its integration alongside Sasobit^®. The research aims to evaluate the impact of Kraft lignin and Sasobit, individually and [...] Read more.

This study investigates the feasibility of using Kraft lignin in Hot and Warm Mix Asphalt (HMA and WMA), with a particular focus on its integration alongside Sasobit^®. The research aims to evaluate the impact of Kraft lignin and Sasobit, individually and in combination, on the construction temperatures, compactability, and physical properties of asphalt mixtures. The experimental program included a reference HMA and modified mixes with 20% Kraft lignin, 3% Sasobit, and their combinations. These mixes were designed and subjected to tests to assess their volumetric and mass properties and to determine the construction temperatures using the Superpave Gyratory Compactor (SGC). The results demonstrated that adding Kraft lignin increased construction temperatures, while Sasobit effectively reduced these temperatures by lowering binder viscosity. When used together, Sasobit offset the increase in construction temperatures caused by Kraft lignin, resulting in compaction temperatures similar to the reference HMA mix. Additionally, Kraft lignin increased air voids, leading to reduced compactability at higher gyration levels. It also exhibited indications of a dual role, functioning as both a binder replacement and a filler. In conclusion, the combination of 20% Kraft lignin with 3% Sasobit offers a promising solution for enhancing the sustainability of asphalt mixtures. Full article

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24 pages, 3275 KB

Open AccessArticle

Multiple Regression and Neural Network-Based Models for the Prediction of the Ultimate Strength of CFRP-Confined Columns

by Baylasan Mohamad, Muna Hamadeh, Firas Al Mahmoud and George Wardeh

Infrastructures 2025, 10(12), 326; https://doi.org/10.3390/infrastructures10120326 - 1 Dec 2025

Abstract

Carbon Fiber-Reinforced Polymers (CFRPs) are gaining popularity as a reliable strengthening technique for reinforced concrete (RC) columns. Several efficient models were developed to predict the stress–strain (σ-ε) curve of CFRP-confined concrete based on experiment findings. The ultimate strength is a crucial parameter for [...] Read more.

Carbon Fiber-Reinforced Polymers (CFRPs) are gaining popularity as a reliable strengthening technique for reinforced concrete (RC) columns. Several efficient models were developed to predict the stress–strain (σ-ε) curve of CFRP-confined concrete based on experiment findings. The ultimate strength is a crucial parameter for accurate (σ-ε) behavior prediction, since it constitutes an initial step in estimating the corresponding axial strain, as it provides a direct indication of the desired increase in strength. Literature analytical models often produce inconsistent results due to errors in estimating the confinement pressure or effectively confined area or the lack of a strong and stable correlation between ultimate strength and confinement parameters. This study looked at a large collection of experimental results from existing research. It used a statistical method (Pearson’s coefficient) to see how well ultimate strength correlated with various confinement factors. For normal-strength concrete columns with circular sections, there was a strong linear correlation between ultimate strength and the thickness of the CFRP jacket. This correlation weakened for high-strength concrete (HSC) and for rectangular columns. A sensitivity analysis was performed to identify the most influential confinement parameters, showing that the number of CFRP layers (n

\times

t) is the most dominant factor, particularly with normal-strength concrete (NSC) in circular columns, accounting for the vast majority of the variance in ultimate strength. Using multiple linear regression equations to predict ultimate strength was also explored; this method demonstrated the best performance with HSC in circular sections, but the results were less promising with NSC. Artificial Neural Networks (ANNs) were developed and trained on the built database, and four statistical metrics were computed for evaluation (R², RMSE, MAE, MRAE), proving highly accurate and superior to linear regression equations, with mean relative absolute errors MRAEs between 2.4–7.2% for ultimate strength prediction, opening new avenues for optimizing CFRP-strengthened element designs. Full article

(This article belongs to the Topic Rehabilitation and Strengthening Techniques for Reinforced Concrete)

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26 pages, 5454 KB

Open AccessArticle

The Importance of Structural Configuration in the Seismic Performance and Reliability of Buildings

by Rodolfo J. Tirado-Gutiérrez, Ramón González-Drigo and Yeudy F. Vargas-Alzate

Infrastructures 2025, 10(12), 325; https://doi.org/10.3390/infrastructures10120325 - 26 Nov 2025

Abstract

The optimal performance of buildings strongly depends on their structural configuration, as it influences the structural response to expected loads during life service. For instance, structural arrangements oriented to reduce torsional effects increase performance and, in turn, mitigate vulnerability to seismic events. However, [...] Read more.

The optimal performance of buildings strongly depends on their structural configuration, as it influences the structural response to expected loads during life service. For instance, structural arrangements oriented to reduce torsional effects increase performance and, in turn, mitigate vulnerability to seismic events. However, several structural analyses should be performed to ensure that these structural arrangements are robust This can be computationally expensive depending on the type of analysis. The objective of this research is twofold. The first objective is to compare the dynamic response of two reinforced concrete buildings that are almost identical in height and floor area but whose structural elements are placed differently. The dynamic response of both structures was calculated via nonlinear dynamic analysis (NLDA) by considering a large set of ground motion records. Second, NLDA results were compared with those stemming from a spectral-based methodology. The comparison is made on the basis of the fragility and damage functions given different return periods. The results show that an adequate spatial distribution of structural elements reduces materials and increases safety and stability, since the expected damage is lower. Likewise, it is observed that the results based on reduced-order procedures accurately represent those obtained from NLDA while entailing a significantly lower computational cost. Full article

(This article belongs to the Topic Resilient Civil Infrastructure, 2nd Edition)

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24 pages, 4839 KB

Open AccessArticle

An Aerial-Ground Collaborative Framework for Asphalt Pavement Quality Inspection

by Peng Li, Sijin Wei, Tao Lei, Lei Niu, Wenyang Han, Chunhua Su, Guangyong Wang, Kai Chen, Ting Cui, Zhang Ding and Zhi Fu

Infrastructures 2025, 10(12), 324; https://doi.org/10.3390/infrastructures10120324 - 26 Nov 2025

Abstract

To overcome the limitations of conventional methods, this study developed a novel aerial-ground collaborative framework for multi-dimensional quality assessment of asphalt pavement. The quality inspection of asphalt pavement in the whole construction process is realized. Multiple non-destructive testing (NDT) techniques were integrated, including [...] Read more.

To overcome the limitations of conventional methods, this study developed a novel aerial-ground collaborative framework for multi-dimensional quality assessment of asphalt pavement. The quality inspection of asphalt pavement in the whole construction process is realized. Multiple non-destructive testing (NDT) techniques were integrated, including drone-based infrared thermography, ground-penetrating radar (GPR), and a nuclear-free density gauge. Results showed a strong correlation (R² > 0.95) between the radar-derived dielectric constant and core samples, enabling rapid, full-coverage characterization. The density gauge achieved less than 3% error. Furthermore, a compactness prediction model based on the dielectric constant and an air void content evaluation model based on temperature parameters are further constructed. This system enables aerial screening, point verification, and ground diagnosis, significantly enhancing inspection efficiency and comprehensiveness. Full article

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26 pages, 4516 KB

Open AccessArticle

Hybrid AI–FEA Framework for Seismic Assessment of Confined Masonry Walls Using Crack Image-Based Material Property Inference

by Piero R. Yupanqui, Jeferson L. Orihuela and Rick M. Delgadillo

Infrastructures 2025, 10(12), 323; https://doi.org/10.3390/infrastructures10120323 - 25 Nov 2025

Abstract

Recent advances in computer vision and artificial intelligence have enabled new approaches for non-destructive post-earthquake assessment of masonry structures. This study proposes a hybrid AI–FEA framework that integrates a MobileNetV2 convolutional neural network for crack-image-based material property inference with nonlinear finite element analysis [...] Read more.

Recent advances in computer vision and artificial intelligence have enabled new approaches for non-destructive post-earthquake assessment of masonry structures. This study proposes a hybrid AI–FEA framework that integrates a MobileNetV2 convolutional neural network for crack-image-based material property inference with nonlinear finite element analysis (FEA) of confined masonry walls. The model predicts key mechanical parameters, including elastic modulus, compressive and tensile strengths, and fracture energies, directly from crack morphology, and these parameters are subsequently used as input for DIANA FEA to simulate the wall’s seismic response. The framework is validated against reference experimental data, achieving a strong parametric correlation (R² = 0.91) and accurately reproducing characteristic nonlinear behavior such as stiffness degradation, diagonal cracking, and post-peak softening in pushover analysis. Photographs from the Limatambo urban area in Lima, Peru, are included to illustrate typical damage patterns in a high-seismic-risk context, although the numerical model represents a standardized confined masonry wall typology rather than site-specific buildings. The proposed methodology offers a consistent, non-destructive, and efficient tool for seismic performance evaluation and supports the digital modernization of structural diagnostics in earthquake-prone regions. Full article

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24 pages, 9002 KB

Open AccessArticle

Evaluation of Construction Methods for Ultra-High Performance Concrete Invert Linings in Corrugated Metal Pipe Culverts

by Brian Lassy and Alexandra Hain

Infrastructures 2025, 10(12), 322; https://doi.org/10.3390/infrastructures10120322 - 25 Nov 2025

Abstract

Corrugated metal pipe (CMP) culverts are key pieces of infrastructure in drainage and waterway management, but many are reaching their end of life and require rehabilitation. While existing repair methods have a long track record of success, they can be cost prohibitive and [...] Read more.

Corrugated metal pipe (CMP) culverts are key pieces of infrastructure in drainage and waterway management, but many are reaching their end of life and require rehabilitation. While existing repair methods have a long track record of success, they can be cost prohibitive and may significantly affect the hydraulic properties of culverts. Ultra-high performance concrete is internally reinforced, stronger, and more durable than conventional concrete, offering a modern solution to culvert deterioration. The seven mockups described include trials with top-formed UHPC, thixotropic UHPC, and a UHPC shotcrete placement. Shotcrete UHPC was not found to be viable at this time due to challenges with maintaining mix consistency and adhesion to the substrate. Top forming and thixotropic UHPC were found to be the best options for building a consistent invert lining for culvert rehabilitation but posed unique challenges in design, construction, and material consistency. This paper describes the methods of construction, challenges during construction, and the results of each test. It is the author’s intent to give owners a new tool for culvert rehabilitation, provide designers with each of the variables in implementation, and help contractors mitigate risks by discussing the challenges encountered for UHPC invert linings. Full article

(This article belongs to the Special Issue Fiber Reinforced Polymer-Ultra High Performance Concrete (FRP-UHPC): Design, Performance, and Application)

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28 pages, 8126 KB

Open AccessArticle

Hybrid Steel Fibers and RCA in RCC Pavements: Mechanical Recovery, Freeze–Thaw Durability, and Eco-Efficiency

by Omid Hassanshahi, Maryam Salati, Nima Azimi and Mohammad Bakhshi

Infrastructures 2025, 10(12), 321; https://doi.org/10.3390/infrastructures10120321 - 25 Nov 2025

Cited by 1

Abstract

This study investigates the combined use of recycled concrete aggregate (RCA) and steel fibers—industrial (ISF), recycled (RSF), and hybrid ISF/RSF (HSF)—to enhance the mechanical performance, freeze–thaw durability, and environmental efficiency of roller-compacted concrete pavement (RCCP). Twenty mixtures incorporating two RCA levels (0% and [...] Read more.

This study investigates the combined use of recycled concrete aggregate (RCA) and steel fibers—industrial (ISF), recycled (RSF), and hybrid ISF/RSF (HSF)—to enhance the mechanical performance, freeze–thaw durability, and environmental efficiency of roller-compacted concrete pavement (RCCP). Twenty mixtures incorporating two RCA levels (0% and 25%) and different fiber systems were tested. The results showed that, although RCA slightly reduced strength, hybrid fibers effectively compensated for this loss, improving toughness, tensile capacity, and resistance to freeze–thaw degradation. A life-cycle assessment demonstrated that substituting natural aggregates and industrial fibers with RCA and RSF lowers the embodied carbon and energy demand. A multi-criteria decision analysis identified mixtures with 25% RCA and hybrid fibers (0.9% HSF) as the most balanced solutions, combining an improved performance with a reduced environmental burden. The findings highlight hybrid fiber-reinforced, RCA-based RCCP as a practical and eco-efficient option for sustainable pavement infrastructure. Full article

(This article belongs to the Section Sustainable Infrastructures)

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25 pages, 4008 KB

Open AccessArticle

Simplified Impact Load Model Analysis of Vehicle-to-Bridge Pier Collision

by Chaoran Xu and Chung C. Fu

Infrastructures 2025, 10(12), 320; https://doi.org/10.3390/infrastructures10120320 - 24 Nov 2025

Abstract

As a key member of the bridge substructure, the pier is always the most critical part under a variety of hazards, among which vehicle-induced impact is a rare but extreme load hazard that may result in significant structural damage and even the full [...] Read more.

As a key member of the bridge substructure, the pier is always the most critical part under a variety of hazards, among which vehicle-induced impact is a rare but extreme load hazard that may result in significant structural damage and even the full failure of the bridge. Current design provisions, such as those in the AASHTO Load and Resistance Factor Design (LRFD) Bridge Design Specifications, adopt a constant equivalent static force (ESF) of 600 kips to represent vehicle impact loads. However, this simplified assumption neglects key parameters—such as vehicle speed, mass, and pier geometry—that significantly influence impact behavior. This study develops and evaluates two simplified impact load estimation models to improve the accuracy and practicality of design-level assessments: a reduced-order dynamic model and a response surface model. The reduced-order dynamic model captures vehicle–pier interaction through a simplified mass–spring system, while the response surface model uses regression-based relationships derived from extensive finite element (FE) simulations conducted in LS-DYNA. Sensitivity analyses identify the most influential parameters governing impact loads, including vehicle velocity, cargo mass, pier diameter, and impact height. The results show that both models can effectively predict peak dynamic and equivalent static impact loads, providing more accurate and physically interpretable results than the current constant-load approach. The proposed frameworks offer practical tools for bridge engineers to evaluate vehicle–pier collision scenarios and can be further extended for use in truck-to-pier and ship-to-pier impact analyses. Full article

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12 pages, 827 KB

Open AccessArticle

Enhancing the Superelevation Runoff Method in Circular Arcs for Mountainous Terrain Alignments

by Antonios E. Trakakis, Vassilios Matragos, Konstantinos Apostoleris, Kiriakos Amiridis, Stergios Mavromatis, Nikiforos Stamatiadis and Basil Psarianos

Infrastructures 2025, 10(12), 319; https://doi.org/10.3390/infrastructures10120319 - 24 Nov 2025

Abstract

Despite the recognized importance of spiral curve implementation in highway design, several design manuals permit spiral omission depending on the geometric layout and the performance characteristics of road users. A critical safety issue associated with these methodologies arises from the potential exceedance of [...] Read more.

Despite the recognized importance of spiral curve implementation in highway design, several design manuals permit spiral omission depending on the geometric layout and the performance characteristics of road users. A critical safety issue associated with these methodologies arises from the potential exceedance of the maximum allowable side friction coefficient and the design utilization factor on a circular arc, particularly under wet pavement conditions. The present study aims to address a gap in geometric design manuals and the international literature by optimizing the superelevation design of the runoff section in the tangent-to-curve transition for circular arcs in mountainous terrain with a maximum design superelevation rate of up to 5%. The proposed methodology is supported by an analysis based on fundamental vehicle dynamics equilibrium equations, aiming to resolve concerns among practitioners regarding the elimination of superelevation rate transitions within the circular arc itself, with particular focus on the evaluation of the utilization factor and the applicability in icy conditions. The comparative evaluation of the demanded utilization factors resulting from this method and those defined by existing guidelines, along with the safety levels it maintains under icy conditions (i.e., compound slope up to 10%), encourages its immediate implementation in circular arcs with a design superelevation rate up to 5%, as well as further investigation into the potential application of this method in circular arcs with a design superelevation rate greater than 5% in mountainous and rolling terrains. Full article

(This article belongs to the Special Issue Safer Roads Ahead: Exploring the Latest Innovations and Advancements in Road Design and Safety Technology)

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28 pages, 1785 KB

Open AccessArticle

A Systematic Framework for Assessing the Temporally Variable Protective Capacity of Nature-Based Solutions Against Natural Hazards

by Erik Kuschel, Michael Obriejetan, Tamara Kuzmanić, Matjaž Mikoš, Lukas Seifert, Slaven Conevski, Maria Wirth, Eriona Canga, Sérgio Fernandes, Johannes Hübl and Rosemarie Stangl

Infrastructures 2025, 10(12), 318; https://doi.org/10.3390/infrastructures10120318 - 22 Nov 2025

Abstract

Natural hazards pose an increasing threat to infrastructures, lives, and livelihoods in alpine regions due to climate change and the growing demand for settlement space. While grey protective structures are commonly deployed to provide immediate safety, their sustainability, and thus protective function, is [...] Read more.

Natural hazards pose an increasing threat to infrastructures, lives, and livelihoods in alpine regions due to climate change and the growing demand for settlement space. While grey protective structures are commonly deployed to provide immediate safety, their sustainability, and thus protective function, is limited by cost-intensive maintenance. Nature-based solutions (NbS) can alleviate these shortcomings by offering cost-effective, adaptive protection that strengthens over time, making their deployment a key factor in building resilience to climate-induced hazards. This paper introduces a systematic methodology for the strategic deployment of NbS to enhance climate resilience. It integrates a three-level hazard classification system with an expert-led assessment rating 74 NbS against 29 hazards. A subsequent Principal Component Analysis (PCA) synthesises these into six functional groupings based on their shared mitigation characteristics. The core of this framework introduces two key innovations: a novel Mitigation Score and a Hazard Mitigation Profile. Together, they evaluate NbS effectiveness dynamically through the different phases of natural hazards, surpassing traditional static ratings by evaluating NbS performance across the hazard management cycle—from predisposition to post-event recovery. Significant variation in mitigation scoring was observed for individual hazard classes and types. Erosion processes (e.g., sheet, rill, and gully erosion) achieved the highest mitigation scores (1.90), as they can be addressed by many highly effective NbS (21–33 types). Conversely, flood-related hazards, such as fluvial and pluvial floods, showed moderate scores (1.64–1.66) with a balanced mix of mitigative and supportive NbS, while options for mitigating impact floods and coastal floods were far more limited (1.00–1.42). The resulting methodology provides a crucial, practical link between specific climate-related threats and viable, nature-based responses, serving as a robust framework to guide the decisions of planners, engineers, and policymakers. By enabling a more strategic and temporally aware deployment of NbS, our findings inform the development of adaptive management strategies to ensure their long-term effectiveness. Full article

(This article belongs to the Special Issue Nature-Based Solutions and Resilience of Infrastructure Systems)

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23 pages, 603 KB

Open AccessArticle

Exploring the Contribution of Road Infrastructure and Environmental Factors to Crash Severity at Intersections in Mixed Traffic Settings

by Steffel Ludivin Tezong Feudjio, Isaac Ndumbe Jackai II, Elvis Chia Ngwah, Stephen Kome Fondzenyuy, Tevoh Lordswill Ndingwan, Davide Shingo Usami and Luca Persia

Infrastructures 2025, 10(12), 317; https://doi.org/10.3390/infrastructures10120317 - 21 Nov 2025

Abstract

Road traffic crashes claim approximately 1.19 million lives annually worldwide, with low- and middle-income countries (LMICs) bearing a disproportionately high share of this burden. Intersections in these contexts are particularly hazardous due to mixed, non-lane-based traffic and infrastructural constraints. This study analysed 1242 [...] Read more.

Road traffic crashes claim approximately 1.19 million lives annually worldwide, with low- and middle-income countries (LMICs) bearing a disproportionately high share of this burden. Intersections in these contexts are particularly hazardous due to mixed, non-lane-based traffic and infrastructural constraints. This study analysed 1242 police-reported intersection crashes (2021–2025) from Douala and Yaoundé, Cameroon, using binary probit and logistic regression models to identify infrastructural and environmental determinants of crash severity. Results from both models were consistent, indicating that late-night and early-morning crashes (00:00–05:59) significantly increased the probability of severe outcomes by 13.5% (p-value < 0.05), while single-lane roads raised it by 21.5% (p-value < 0.05; OR = 5.38), and two-lane roads raised the probability by 9.1% (p-value < 0.05; OR = 3.90) compared with multilane sections. Additionally, centre lines were associated with safer outcomes than physical separation (p-value < 0.05; OR = 0.30). Although model fit indices were modest (Nagelkerke R² = 0.118), typical of cross-sectional crash-severity models, the findings underscore the dominant influence of road geometry and lighting-related temporal exposure in shaping intersection crash outcomes. These insights provide a basis for targeted interventions such as road widening, improved night-time illumination, and simplified midblock designs to enhance safety in Cameroon and similar LMIC urban settings. Full article

(This article belongs to the Special Issue Safer Roads Ahead: Exploring the Latest Innovations and Advancements in Road Design and Safety Technology)

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17 pages, 5934 KB

Open AccessArticle

The Impact of Sealed Crack Labeling on Deep Learning Accuracy for Detecting, Segmenting and Quantifying Distresses in Airport Pavements

by Valerio Perri, Misagh Ketabdari, Stefano Cimichella, Maurizio Crispino and Emanuele Toraldo

Infrastructures 2025, 10(12), 316; https://doi.org/10.3390/infrastructures10120316 - 21 Nov 2025

Abstract

Using deep learning in automated pavement distress detection has shown huge improvements for transport infrastructure, but a noticeable challenge remains in distinguishing sealed cracks from active ones, which are more evident in high-resolution aerial imagery of airport pavements. Misclassifying sealed cracks, an indicator [...] Read more.

Using deep learning in automated pavement distress detection has shown huge improvements for transport infrastructure, but a noticeable challenge remains in distinguishing sealed cracks from active ones, which are more evident in high-resolution aerial imagery of airport pavements. Misclassifying sealed cracks, an indicator of maintenance intervention, as structural distress leads to false positives that cause overestimation in distress metrics and, ultimately, inaccurate Pavement Condition Index (PCI) scores. This study tries to address this limitation by investigating whether explicitly labeling sealed cracks as a separate class during training can improve model performance. In this regard, aerial orthophotos of taxiways from one selected airport, as a case study, were collected via Unmanned aerial vehicle (UAV) surveys, and three instance segmentation models based on YOLOv11 (version 11 from You Only Look Once family) were trained on different datasets: one excluding sealed cracks (including only longitudinal and transvers cracks), one including sealed cracks without explicit labeling, and one treating sealed cracks as a separate class. Validation against ground-truth field surveys revealed that the model trained with explicit sealed crack annotations achieved significantly lower error rates, with a 56.7% reduction for longitudinal cracks and a 75.2% reduction for transverse cracks with respect to traditional detection methods. This improvement led to fewer false positives and a more reliable quantification of both longitudinal and transverse cracking. The results demonstrate that tailored annotation strategies, which in this study means distinguishing sealed cracks, substantially improve the accuracy of deep learning models for real-world pavement condition assessment. Full article

(This article belongs to the Special Issue Pavement Performance and Maintenance: Smart Technologies and Sustainable Practices)

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18 pages, 15741 KB

Open AccessArticle

Three-Dimensional Refined Modeling and Mechanical Response Analysis of Tunnel Structure Safety in Karst Areas

by Guansi Gu, Fei Yang, Yunhao Dong, Wei Liu and Mingze Xu

Infrastructures 2025, 10(11), 315; https://doi.org/10.3390/infrastructures10110315 - 20 Nov 2025

Abstract

Deep-buried tunnels in karst regions are prone to complex deformation and stress redistribution due to the heterogeneity of surrounding rock and the presence of cavities. This study establishes a three-dimensional finite element model to investigate the mechanical behavior of tunnel linings under varying [...] Read more.

Deep-buried tunnels in karst regions are prone to complex deformation and stress redistribution due to the heterogeneity of surrounding rock and the presence of cavities. This study establishes a three-dimensional finite element model to investigate the mechanical behavior of tunnel linings under varying karst distributions and distances. The model incorporates realistic geological parameters and boundary conditions to analyze stress evolution and radial displacement of the lining under coupled mechanical effects. The results indicate that karst cavities located near the tunnel, especially beneath it, significantly amplify radial deformation and induce asymmetric stress concentrations. As the distance between the karst and the tunnel increases, the influence on lining response rapidly decreases and becomes negligible beyond approximately 3 m. The introduction of a secondary lining effectively reduces both tensile and compressive stresses by more than 65% and mitigates local deformation. The study concludes that the spatial position of karst features is the dominant factor affecting lining performance, and the composite lining structure provides an efficient means of ensuring safety and stability in water-rich karst tunnels. Full article

(This article belongs to the Special Issue Smart Technologies for Sustainable and Resilient Underground Infrastructures)

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24 pages, 13270 KB

Open AccessArticle

Numerical Analysis Research on Tunnel Damage Under the Action of Oblique Slip Faults Based on Multiple Slip Surfaces

by Chunhua Gao, Xuyang Hua, Xule Liu, Jingyu Ge and Cong Xiang

Infrastructures 2025, 10(11), 314; https://doi.org/10.3390/infrastructures10110314 - 20 Nov 2025

Abstract

In the field of tunnel engineering, it is often difficult to avoid crossing active faults. During an earthquake, tunnels across faults are highly vulnerable to damage. Therefore, conducting research on their mechanical responses and failure mechanisms is of great significance. This paper takes [...] Read more.

In the field of tunnel engineering, it is often difficult to avoid crossing active faults. During an earthquake, tunnels across faults are highly vulnerable to damage. Therefore, conducting research on their mechanical responses and failure mechanisms is of great significance. This paper takes Xianglushan Tunnel as a research example and uses finite element software to carry out numerical simulation of the tunnel under the action of the left-lateral normal fault activity. Moreover, the effectiveness of this model is verified using the actual measurement data of the damaged tunnels during the Kumamoto earthquake. By comparing the damage conditions and stress states of the tunnel under the action of left-lateral normal faults and strike-slip faults, and conducting a systematic and refined study on relevant fault parameters, the following research results are obtained: First, compared with oblique-slip faults, strike-slip faults cause more severe damage to the tunnel; second, tunnel damage is mainly concentrated in the area where the fault slip surface is located; third, an increase in fault displacement can significantly exacerbate structural damage and is the main factor leading to tunnel failure; fourth, the dip angle of the fault affects the stress distribution of the tunnel. As the dip angle increases, the damaged area gradually shrinks; fifth, the change in the width of the fault fracture zone will alter the failure mode of the tunnel. Reasonably choosing to cross a wider fault can reduce the structural damage. This research provides theoretical support and practical reference for the seismic design of tunnels across faults. Full article

(This article belongs to the Special Issue Smart Technologies for Sustainable and Resilient Underground Infrastructures)

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27 pages, 18434 KB

Open AccessArticle

A Numerical Simulation Study on Vertical Vibration Response for Rail Squat Detection with a Train in Regular Traffic

by Zhicheng Hu and Albert Lau

Infrastructures 2025, 10(11), 313; https://doi.org/10.3390/infrastructures10110313 - 19 Nov 2025

Abstract

Squat is a type of rail defect that frequently poses challenges for railway tracks, as they generate dynamics and accelerate track degradation. Detecting rail squats is resource-intensive, given their relatively small size compared to the railway track. Often, by the time they are [...] Read more.

Squat is a type of rail defect that frequently poses challenges for railway tracks, as they generate dynamics and accelerate track degradation. Detecting rail squats is resource-intensive, given their relatively small size compared to the railway track. Often, by the time they are detected, damage has usually already occurred in other track components. Currently, rail squats are primarily detected using dedicated railway measurement vehicles. There has been a recent trend in research towards utilizing trains in regular traffic to monitor the condition of railway tracks. However, there is a lack of research and general guidelines regarding the optimal placement of accelerometers or sensors on trains for squat detection. In this study, multibody simulation software GENSYS Rel.2209 is employed to simulate a passenger train traversing rail squats under various scenarios, with each scenario characterized by a distinct set of typical feature values for the squats. The results demonstrate that the front wheel set, positioned closest to the defects, exhibits the highest sensitivity to vertical accelerations. Squat length is much more sensitive than depth for detection at typical speeds, and accelerometers on bogies or the car body require speeds below 40 km/h to ensure reliability. The acceleration response mechanism during squat traversal is explored, revealing the effects of varying squat geometries and train speeds. This finding enables a detection method capable of locating squats and estimating their length with over 90% accuracy. Practical recommendations are provided for optimizing squat detection systems, including squat width detection, sensor selection criteria, and suggested train speeds. It offers a pathway to detect squat more efficiently with optimized installation locations of accelerometers on a train. Full article

(This article belongs to the Special Issue Smart Transportation Infrastructure: Optimization and Development)

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23 pages, 6160 KB

Open AccessArticle

An Automated Information Modeling Workflow for Existing Bridge Inspection Management

by Adriana Marra, Ilaria Trizio and Giovanni Fabbrocino

Infrastructures 2025, 10(11), 312; https://doi.org/10.3390/infrastructures10110312 - 18 Nov 2025

Abstract

The safety, conservation, and efficient management of existing road bridges have assumed a key role in recent years due to the strategic importance of these structures for local territories and their exposure to natural and anthropogenic risks. Many assets are in a state [...] Read more.

The safety, conservation, and efficient management of existing road bridges have assumed a key role in recent years due to the strategic importance of these structures for local territories and their exposure to natural and anthropogenic risks. Many assets are in a state of degradation due to adverse environmental conditions, unforeseen loads in the design phase, and lack of maintenance, with often dramatic consequences. In response to these critical issues, integrated approaches based on the exploitation of different digital technologies are emerging to support inspection, monitoring, and maintenance activities. This paper proposes a digital workflow for bridge inspection management, based on the integration of information modeling, online databases, and automated data exchange and updating. The designed workflow enables the creation of a dynamic information model that evolves with the time-dependent data collected during periodic inspections by means of a Visual Programming Language. The data, stored in an online database, are filtered, analyzed, and dynamically associated with model elements, ensuring consistency, traceability, and reduction in manual input errors. The workflow was validated through a field application to an existing bridge, demonstrating its effectiveness in automating information management and providing the basis for the development of an interoperable and scalable platform for the digital management of infrastructure assets. Full article

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