Your search keyword '"truck-involved crashes"' showing total 6 results

1. XGBoost-SHAP and Unobserved Heterogeneity Modelling of Temporal Multivehicle Truck-Involved Crash Severity Patterns.

Author

Laphrom, Wimon, Se, Chamroeun, Champahom, Thanapong, Jomnonkwao, Sajjakaj, Wipulanusat, Warit, Satiennam, Thaned, and Ratanavaraha, Vatanavongs

Subjects

MACHINE learning, LOGISTIC regression analysis, DEVELOPING countries, PREDICTION models, TRUCKS, MOTORCYCLING accidents

Abstract

This paper aims to address the critical issue of multivehicle truck crashes in developing regions, with a focus on Thailand, by analyzing the factors that influence injury severity and comparing the effectiveness of predictive models. Utilizing advanced random parameters and the XGBoost machine learning algorithm, we conducted a comprehensive analysis of injury severity factors in multivehicle truck-involved accidents, contrasting weekdays and weekends. Our findings reveal that the XGBoost model significantly outperforms the heterogeneous logit model in predicting crash severity outcomes, demonstrating superior accuracy, sensitivity, specificity, precision, F1 score, and area under the curve (AUC) in both model training and testing phases. Key risk factors identified include motorcycle involvement, head-on collisions, and crashes occurring during late night/early morning hours, with environmental elements like road lane numbers and weekend hours also playing a significant role. The study introduces XGBoost as a novel and improved method for truck safety analysis, capable of capturing the complex interactions within multivehicle crash data and offering actionable insights for targeted interventions to reduce crash severity. By highlighting specific risk factors and the effectiveness of XGBoost, this research contributes to the development of data-driven strategies for enhancing truck safety in developing countries. [ABSTRACT FROM AUTHOR]

Published

2024

2. Analysis of Injury Severity of Work Zone Truck-Involved Crashes in South Carolina for Interstates and Non-Interstates.

Author

Madarshahian, Mahyar, Balaram, Aditya, Ahmed, Fahim, Huynh, Nathan, Siddiqui, Chowdhury K. A., and Ferguson, Mark

Abstract

This study investigates factors contributing to the injury severity of truck-involved work zones crashes in South Carolina (SC). The outcome of interest is injury or property damage only crashes, and the explanatory factors examined include the occupant, vehicle, collision, roadway, temporal, and environmental characteristics. Two mixed (random parameter) logit models are developed, one for non-interstates with speed limits less than 60 miles per hour (mph) and one for interstates with speed limits greater than or equal to 60 mph, using South Carolina statewide truck-involved work zone crash data from 2014 to 2020. Results of log-likelihood ratio tests indicate that separate speed models are warranted. The factors that were found to contribute to injury at the 90% confidence level in both models (interstate and non-interstate) are (1) dark lighting conditions, (2) female (at-fault) drivers, and (3) driving too fast for roadway conditions. Significant factors that apply only to non-interstates are SC or US primary roadways, activity area of the work zone, at-fault drivers under 35, sideswipe collision, presence of workers in the work zone, and collision with fixed objects. Significant factors that apply only to interstates are three or more vehicles, rear-end collision, location before the first work zone sign, and weekdays. [ABSTRACT FROM AUTHOR]

Published

2023

3. Exploring truck driver-injury severity at intersections considering heterogeneity in latent classes: A case study of North Carolina

Author

Li Song and Wei (David) Fan

Subjects

Truck-involved crashes, Intersection, severity analysis, Latent class analysis, Ordered logit, Transportation engineering, TA1001-1280

Abstract

The fatal rate of truck-involved crashes is increasing and crashes become more severe than passenger vehicles in recent years. Much research has been dedicated to exploring the truck crash factors while scarce research focused on the intersection scenarios. This study investigates the factors that affect the severity level of truck-involved crashes at cross- and T-intersections. Due to the unobserved heterogeneity inherent in crash data, latent class analysis is firstly conducted to divide the crash dataset into relatively homogeneous clusters. Considering the ordinal feature of the severities, general ordered logit models are subsequently developed to further explore the specific factors within each cluster. This study uses the North Carolina’s truck-involved crash at intersection data during 2005 to 2017 from the Highway Safety Information System (HSIS). The estimated parameters and associated marginal effects are combined to interpret the impact of the significant variables within specific clusters. Many factors are found to contribute to the severities, and T-intersection is found to be safer than cross-intersection. For driving behaviors, followed too closely, disregarded signs, disregarded signals, failed to yield, and exceeded speed are found to be top five factors that increase the crash severity at intersections. These results indicate that distraction and speed limits violation always result in severe injury for humans involved in the truck crashes at the intersections. The results of this research provide more reliable analysis for the impact factors of truck-involved crashes at intersections to engineering practitioners and researchers.

Published

2021

4. Analysis of Injury Severity of Work Zone Truck-Involved Crashes in South Carolina for Interstates and Non-Interstates

Author

Mahyar Madarshahian, Aditya Balaram, Fahim Ahmed, Nathan Huynh, Chowdhury K. A. Siddiqui, and Mark Ferguson

Subjects

Renewable Energy, Sustainability and the Environment, crash injury severity, truck-involved crashes, work zone crashes, mixed logit model, Geography, Planning and Development, Building and Construction, Management, Monitoring, Policy and Law

Abstract

This study investigates factors contributing to the injury severity of truck-involved work zones crashes in South Carolina (SC). The outcome of interest is injury or property damage only crashes, and the explanatory factors examined include the occupant, vehicle, collision, roadway, temporal, and environmental characteristics. Two mixed (random parameter) logit models are developed, one for non-interstates with speed limits less than 60 miles per hour (mph) and one for interstates with speed limits greater than or equal to 60 mph, using South Carolina statewide truck-involved work zone crash data from 2014 to 2020. Results of log-likelihood ratio tests indicate that separate speed models are warranted. The factors that were found to contribute to injury at the 90% confidence level in both models (interstate and non-interstate) are (1) dark lighting conditions, (2) female (at-fault) drivers, and (3) driving too fast for roadway conditions. Significant factors that apply only to non-interstates are SC or US primary roadways, activity area of the work zone, at-fault drivers under 35, sideswipe collision, presence of workers in the work zone, and collision with fixed objects. Significant factors that apply only to interstates are three or more vehicles, rear-end collision, location before the first work zone sign, and weekdays.

Published

2023

5. Latent Factors Of Severity In Truck-Involved And Non-Truck-Involved Crashes On Freeways

Author

Shin-Hyung Cho, Dong-Kyu Kim, and Seung-Young Kho

Subjects

truck-involved crashes, crash on freeway, macromolecular substances, Crash severity, multiple group analysis, human activities, structural equation modeling

Abstract

Truck-involved crashes have higher crash severity than non-truck-involved crashes. There have been many studies about the frequency of crashes and the development of severity models, but those studies only analyzed the relationship between observed variables. To identify why more people are injured or killed when trucks are involved in the crash, we must examine to quantify the complex causal relationship between severity of the crash and risk factors by adopting the latent factors of crashes. The aim of this study was to develop a structural equation or model based on truck-involved and non-truck-involved crashes, including five latent variables, i.e. a crash factor, environmental factor, road factor, driver’s factor, and severity factor. To clarify the unique characteristics of truck-involved crashes compared to non-truck-involved crashes, a confirmatory analysis method was used. To develop the model, we extracted crash data from 10,083 crashes on Korean freeways from 2008 through 2014. The results showed that the most significant variable affecting the severity of a crash is the crash factor, which can be expressed by the location, cause, and type of the crash. For non-truck-involved crashes, the crash and environment factors increase severity of the crash; conversely, the road and driver factors tend to reduce severity of the crash. For truck-involved crashes, the driver factor has a significant effect on severity of the crash although its effect is slightly less than the crash factor. The multiple group analysis employed to analyze the differences between the heterogeneous groups of drivers., {"references":["Kim, K., P. Pant, and E. Yamashita. Measuring Influence of Accessibility on Accident Severity with Structural Equation Modeling. In Transportation Research Record: Journal of the Transportation Research Board, No. 2236, Transportation Research Board of the National Academies, Washington, D.C., 2011, pp. 1-10.","Hassan, H. M., and M. A. Abdel-Aty. Analysis of Drivers' Behavior under Reduced Visibility Conditions Using a Structural Equation Modeling Approach. Transportation Research Part F: Psychology Behavior, Vol. 14, No. 6, 2011, pp. 614–625.","Zhu, X., and S. Srinivasan. A Comprehensive Analysis of Factors Influencing the Injury Severity of Large-truck Accident. Accident Analysis and Prevention, Vol. 43, No.1, 2011, pp. 49-57.","Lee, J. Y., J. H. Chung, and B. Son. Analysis of Traffic Accident Size for Korean Highway Using Structural Equation Models. Accident Analysis and Prevention, Vol. 40, No.6, 2008, pp. 1955–1963.","U.S. Department of Transportation, Bureau of Transportation Statistics (2014), Transportation Statistics Annual Report (2013), available at http://www.rita.dot.gov/bts/sites/rita.dot.gov.bts/files/TSAR_2013.pdf, Accessed July 20, 2015.","The Road Traffic Authority. Statistical Yearbook of Traffic Accident. 2015.","Miaou, S. P. The Relationship between Truck Accidents and Geometric Design of Road Sections: Poisson versus Negative Binomial Regression. Accident Analysis and Prevention, Vol. 26, No.4, 1994, pp. 471-182.","Charbotel, B., J. L. Martin, B. Gadegbeku, and M. Chiron, Severity Factors for Truck Drivers' Injuries. American Journal of Epidemiology, Vol.158, No. 8, 2003, pp. 753-759.","Häkkänen, H. and H. Summala. Fatal Traffic Accidents among Trailer Truck Drivers and Accident Caused as Viewed by Other Truck Drivers. Accident Analysis and Prevention, Vol. 33, No.2, 2001, pp. 187-196.\n[10]\tPark, S., K. Jang, S. H. Park, D.-K. Kim, and K. S. Chon. Analysis of Injury Severity in Traffic Crashes: A Case Study of Korean Expressways. KSCE Journal of Civil Engineering, Vol. 16, No. 7, 2012, pp. 1280-1288.\n[11]\tKhattak, A. J. Risk Factors in Large Truck Rollovers and Injury Severity: Analysis of Single-vehicle Collisions. Presented at 82nd Annual Meeting of the Transportation Research Board, Washington, D.C., 2003.\n[12]\tCantor, D. E., T. M. Corsi, C. M. Grimm, and K. Ozpolat. A Driver Focused Truck Crash Prediction Model. Transportation Research Part E: Logistics and Transportation Review, Vol. 46, No. 5, 2010, pp. 683-692.\n[13]\tBunn, T. L., S. Slavova, T. W. Struttmann, and S. R. Browning. Sleepiness/fatigue and Distraction/inattention as Factors for Fatal versus Nonfatal Commercial Motor Vehicle Driver Injuries. Accident Analysis and Prevention, Vol. 37, No. 5, 2005, pp. 862-869.\n[14]\tXu, C., W. Wang, P. Liu, R. Guo, Z. Li, and F. Zhang. Real-time Freeway Crash Risk Assessment Using Structural Equation Modeling and Segmentation Analysis Approach, Presented at 93rd Annual Meeting of the Transportation Research Board, Washington, D.C., 2014.\n[15]\tChang, L. Y., and F. Mannering. Analysis of Injury Severity and Vehicle Occupancy in Truck- and Non-truck-involved Crashes. Accident Analysis and Prevention, Vol. 31, No. 5, 1999, pp. 579-592.\n[16]\tKhorashadi, A., D. Niemeier, V. Shankar, and F. Mannering. (2005), Differences in Rural and Urban Driver-injury Severities in Accidents Involving Large-trucks: an Exploratory Analysis. Accident Analysis and Prevention, Vol. 37, No.5, 2005, pp. 910-921.\n[17]\tChen, F., and S. Chen. Injury Severities of Truck Drivers in Single-and Multi-vehicle Accidents on Rural Highways. Accident Analysis and Prevention, Vol. 43, No. 5, 2011, pp. 1677-1688.\n[18]\tKorean Statistical Information Service, Statistics Korea, Korea. http://kosis.kr/. Accesed July 20, 2015.\n[19]\tSchumacker, R. E., and R. G. Lomax, A Beginner's Guide to Structural Equation Modeling, 3rd ed. Routledge, New York. 2010.\n[20]\tAmerican Association of State Highway and Transportation Officials, Highway Safety Manual, 1st edition. Washington, D.C., July 2010.\n[21]\tLomax, R. G. A Structural Model of Public and Private Schools. Jounal of Experimental Education, Vol. 53, No. 4, 1985, pp. 216-226.\n[22]\tArbuckle, J. L., and W. Wothke. Amos 5.0 user's guide. Smallwaters Corporation, Chicago, Illinois, 2003."]}

Published

2017

6. Investigating occupant injury severity of truck-involved crashes based on vehicle types on a mountainous freeway: A hierarchical Bayesian random intercept approach.

Author

Haq, Muhammad Tahmidul, Zlatkovic, Milan, and Ksaibati, Khaled

Subjects

*TRUCK accidents, *WOUNDS & injuries, *WEATHER, *EXPRESS highways, *VEHICLE models, *TRUCK drivers

Abstract

• Truck-involved crashes result in more severe injuries. • Different factors contribute to injury severity of occupants in truck-involved crashes. • Separate models needed for each occupant of each vehicle type. • There is a correlation of occupant injury severity in the same crash and the same vehicle. • Actions of car and SUV/pickup drivers have more significant impacts on crash severity. Earlier research on injury severity of truck-involved crashes focused primarily on single-truck and multi-vehicle crashes with truck involvement, or investigated truck-involved injury severity based on rural and urban locations, time of day variations, lighting conditions, roadway classification, and weather conditions. However, the impact of different vehicle-truck collisions on corresponding occupant injury severity is lacking. Therefore, this paper advances the current research by undertaking an extensive assessment of the occupant injury severity in truck-involved crashes based on vehicle types (i.e., single-truck, truck-car, truck-SUV/pickup, and truck-truck), and identifies the major occupant-, crash-, and geometric-related contributing factors. A series of log-likelihood ratio tests were conducted to justify that separate model by vehicle and occupant types are warranted. Injury severity models were developed using 10 years of crash data (2007–2016) on I-80 in Wyoming through binary logistic modeling with a Bayesian inference approach. The modeling results indicated that there were significant differences between the influences of a variety of variables on the injury severities when the truck-involved crashes are broken down by vehicle types and separated by occupant types. The age and gender of occupants, truck driver occupation, driver residency, sideswipes, presence of junctions, downgrades, curves, and weather conditions were found to have significantly different impacts on the occupant injury severity in different vehicle-truck crashes. Finally, with the incorporation of the random intercept in the modeling procedure, the presence of intra-crash and intra-vehicle correlations (effects of the common crash- and vehicle-specific unobserved factors) in injury severities were identified among persons within the same crash and same vehicle. [ABSTRACT FROM AUTHOR]

Published

2020