Skip to main content
Heliyon logoLink to Heliyon
. 2024 Feb 24;10(5):e26944. doi: 10.1016/j.heliyon.2024.e26944

Injury-severity analysis of crashes involving defective vehicles and accounting for the underlying socioeconomic mediators

Emmanuel Kofi Adanu a,, Richard Dzinyela b, Sunday Okafor c, Steven Jones a
PMCID: PMC10907794  PMID: 38434351

Abstract

Crashes occur from a combination of factors related to the driver, roadway, and vehicle factors. The impact of vehicles on road crashes is a critical consideration within road safety analysis, even though not much studies have been conducted in this area. This study assessed how various vehicle and other crash factors are significantly associated with crash outcomes. To do this, historical vehicle defect-related crashes were obtained for the state of Alabama from 2016 to 2020. After data cleaning, a crash injury severity model was developed using the random parameters multinomial logit with heterogeneity in means approach to account for possible unobserved heterogeneity in the data. A spatial analysis was further conducted to better understand vehicle defect crashes as a broader societal issue and potentially explore their connection with the socio-demographic characteristics of the drivers of these vehicles. The preliminary data analysis showed that brake and tire defects accounted for about 65% of the vehicle defects associated with the crashes. The model estimation results revealed that improper tread depth and headlight defects were associated with major injury outcomes, while brake defects were more associated with minor injuries. Also, crashes associated with speeding, drunk driving, failure to use seatbelts, and those that occurred on curved roads left with downgrades were likely to result in major injuries. Findings from the spatial analysis showed that postal codes with higher median incomes are more likely to record lower vehicle defect-related crashes, unlike those that have higher proportions of females and African Americans. The study's findings provide data-driven evidence for sustained safety campaigns, workshops, and training on basic vehicle maintenance practices in the low-income communities in the state.

Keywords: Road crashes, Vehicle defects, Injury severity, Spatial analysis

Highlights

  • The role of vehicles in road accidents holds significant importance in road safety analysis.

  • Crash occurrences were analyzed based on road, vehicle, driver, social and economic factors.

  • Random parameters logit models and Multiscale Geographically Weighted Regression (MGWR) models were used in this study.

  • Drivers from lower income zip codes are more likely to be involved in vehicle defect related crashes.

1. Introduction

Every year, thousands of people lose their lives and countless others are injured in road crashes across the globe. While human error is often cited as the primary cause of these crashes, vehicle defects have also been identified as a significant contributor [1]. Even with advanced safety technologies and strict regulations, defects in vehicles can still result in severe crashes, causing injuries, fatalities, and extensive property damage. In the United States, vehicle defect-related crashes have been a persistent safety concern for decades, with design flaws, manufacturing errors, and lack of maintenance leading to numerous incidents [2]. These defects can range from minor issues, such as worn-out tires and brakes, to major structural problems [3]. Carfax [2] estimates that greater than one out of every five US vehicles that are on the road have outstanding recalls, meaning that they have a known defective part or design. According to the National Motor Vehicle Crash Causation Survey (NMVCCS) conducted from 2005 to 2007, vehicle defects were found to be 2% of the last failure in the causal chain of events leading to crash out of 5470 crashes that were surveyed. Out of the 2% of crashes associated with vehicle defects, tire problems constituted about 35%, brakes form 22% and other parts constituted the remaining 43% [3]. As the number of older vehicles continues to increase and a high number of defective vehicles continue to be driven on US roads, it is crucial to understand the impact of vehicle defects on road safety and to identify strategies to mitigate the risk of these incidents. This is particularly important in light of efforts towards the development of autonomous vehicles where road safety concerns may shift from the driver to vehicle-related factors and general system failures.

Previous research has largely attributed vehicle crashes to human errors [[4], [5], [6], [7]]. In the seminal study on the Tri-level causes of traffic crashes [1], human factors were cited as probable causes in 92.6% of crashes investigated and environmental factors were cited as the probable cause in 33.8%, while vehicular factors were identified as probably causes in 12.6% of the crashes. The major vehicular causes identified in the study were brake failure, inadequate tread depth, side-to-side brake imbalance, under-inflation, and vehicle-related vision obstructions. In another study, vehicle defects were one of the 15 safety problems identified by the National Highway Traffic Safety Administration during vehicle inspection [8]. Unlike human errors, vehicle defects are more technical in nature and can be addressed through direct solutions [9]. While vehicle defects are typically repairable, the capacity of drivers or vehicle owners to address these issues is influenced by various factors, including financial limitations. For example [10], identified a significant association between the ownership of defective vehicles and the socioeconomic status of drivers. This underscores the importance of adopting a human-centered approach in addressing road safety concerns related to vehicle defects. Implementing suitable countermeasures targeted at drivers and vehicle owners with defective vehicles is crucial. The effectiveness of these measures, such as education and awareness campaign, relies on the accurate identification of the geographic distribution of these drivers. For instance, Carfax [2] suggested that drivers in the southern parts of the US are most likely to have cars with open recalls. Their research found that southern states like Alabama have the highest open recall percentage. As such, efforts to address the issue of defective vehicles and road safety can appropriately be targeted to residents in these states.

In contrast to crash studies that primarily focus on human factors, there has been a limited number of studies conducted to explore the contribution of vehicle defects to crash occurrence and outcomes. One such earlier study conducted an “on-the-spot” investigation of 502 crashes involving commercial vehicles and buses in South Africa [11]. The results from this study revealed that vehicle defects contributed to 9% of the crashes. Another study investigated the contribution of mechanical failures to motor vehicle crashes in the Pretoria region of South Africa [12]. The study data from the crash response unit (ARU) revealed that tires and brakes were the major contributors to mechanical failures resulting in crashes. Further analysis using roadside survey (potential mechanical defect tests) indicated that 40% of the vehicles surveyed on the suburban road and 29% of the vehicles surveyed on the highway had mechanical defects that may contribute to crash occurrence as a result of a mechanical failure. Tire inflation pressure were identified as a cause of concern in minibus surveys. Most recent studies also indicated that mechanical failures are the most common vehicle defects responsible for crashes [13,14].

Regarding vehicle components that are mostly involved in vehicle defect-related crashes, a study identified that brake system defects, running gear defects and tire defects were the key factors that contribute to road crashes [15]. The study also revealed that older vehicles were more prone to crashes due to inadequate service and maintenance, which is consistent with the findings of other research efforts [[16], [17], [18], [19]]. Another study investigated the common vehicle defects that contribute to road crashes using data gleaned from inspecting private passenger vehicles and found that worn out tires and structural integrity were the two most common vehicle defects associated with private passenger vehicles [9]. The study also found that vehicles sent for voluntary inspections have a higher probability of failure as compared to vehicles sent for routine inspections. Using 7 years crash data (2010–2016) from Louisiana [19], also identified worn-out tires and defective brakes as being overrepresented in vehicle defect associated crashes.

Aside from identifying vehicle components that are more likely to fail, some researchers also investigated the factors contributing to those failures. For instance Ref. [20], investigated factors affecting tire failures using ten years (2007–2016) of historical crash data along I-80 in Wyoming. Results from the study revealed that vehicle speeds greater than 75 mph, commercial motor vehicles, summer season, daytime, the presence of rough surface, downgrades, and concrete pavement are all related to higher tire failure occurrences. In addition, tire failure in combination with fire or explosion, rollover, guardrail hits, ran-off road, angle, rear-end, clear weather, speeding, downgrades, and curved segments were found to be associated with severe injuries. In another study, factors affecting brake failure and their corresponding injury were investigated using crash data from Wyoming [21]. It was found that people in older vehicles (>15 years), trucks, and downhill grade segments were more likely to experience brake failures. Brake failure related crashes involving vehicle age greater than 15 years, truck and SUV/Pick up, female driver and airbag deployment results in a more severe injury.

To be able to prioritize the implementation of vehicle defect-related crash countermeasures, there is the need to identify and quantify the extent of contribution of various defects to crashes and crash outcomes. Typically, this process involves the use of some statistical or mathematical analytic tool. Previous studies have used several methods in analyzing factors associated with vehicle defects. Some of the methods used include logistic regression [9], Bayesian data mining [19], Bayesian binary logit [20,21] and Chi-square analysis [21]. However, there are not many studies that explored and quantified the effect of vehicle defects on crash severity, using an advanced statistical/econometric modeling method that can account for unobserved heterogeneity in the crash data [22].

While previous studies have been successful in identifying factors that are associated with various vehicle defects, failing to account for unobserved heterogeneity in crash data during injury-severity analysis can lead to biased parameter estimates and potentially erroneous decisions and countermeasures [22]. The dearth of literature in this area limits an understanding of how vehicle defects and other related factors like open recalls are statistically associated with crash occurrence and different crash severities. This research seeks to fill the gap and add more information to the already existing literature in vehicle defect-related crashes. In doing so, the study used crash data from Alabama and adopted the random parameters multinomial logit modeling technique to explore relationships between vehicle defects and other crash factors and crash severity, while accounting for unobserved heterogeneity associated with the crash data. The random parameter multinomial logit approach was adopted because it is a leading heterogeneity modeling method that has extensively been used in several crash studies [[23], [24], [25], [26], [27]] to establish how a set of crash contributing factors are associated with crash severity. By adopting this analytical method, the model estimation results are expected to be more accurate and reliable for decision making. Also, spatial analysis was conducted to examine the correlation between the vehicle defect crashes and the socio-demographic factors of drivers’ residential zip code across the study areas. The findings of this study will be useful to guide in the design, development, and roll out of vehicles equipped with more advance technologies and durable features that are not prone to unexpected defects. It will also inform the prioritization of safety measures in areas more prone to vehicle defect crashes.

2. Data description

The Alabama crash data used for this study was obtained from the Critical Analysis Reporting Environment (CARE) software system developed by the University of Alabama Center for Advanced Public Safety (CAPS) for the period covering 2016 to 2020. This database contains all crashes that occur in the state and includes information related to the roadway, crash characteristics, driver attributes, temporal charactistics, vehicle characteristics, crash contributing circumstances, casualty information, etc. This is the primary source of crash data for academic research and policy decisions in the state. To obtain the necessary data for this study, the CARE system was queried to filter only crashes in which the reporting officer reports vehicle defect as a contributing circumstance of the crash. After cleaning the data, 15,054 crashes were available for analysis. Originally, the severity of the crashes was reported using the KABCO scale where K is a fatal crash, A is a suspected serious injury, B is suspected minor injury, C is possible injury, and O is property damage only. However, in this study, three crash severity categories were considered as major injury outcome (defined as crashes in K and A), minor injury outcome (defined as B and C), and no injury (defined as O). Based on this classification, 4.52% of the crashes were major injury, 19.68% were minor injury and the remaining 75.8% resulted in no injury.

Preliminary data analysis revealed that defective equipment was the primary contributing factor in 50.56% of the crashes, indicating that in a little over half of the total crash observations, some form of vehicle defect is deemed to be responsible for the crash. In the remaining 49.44% of the crashes, other factors were the primary contributing factor to the crash, but the vehicle defect played a secondary role. For instance, driving too fast (6.98%), misjudging stopping distance (6.46%) and followed too close (5.99%) were some of the other major primary contributing circumstances associated crashes in which the vehicle had some defect which also contribute either to the crash occurrence or the crash outcome. Considering driver demographics, male drivers (65.76%) were overrepresented in vehicle defect related crashes as compared to females (34.24%). In addition, drivers between 20 and 39 years (52.3%) formed majority of the age group represented in vehicle defect related crashes as compared to drivers between 15 and 19 years (14.78%), 40–59 years (24.09%) and drivers older than 60 years (8.83%).

Regarding the vehicle characteristics, passenger cars (45.1%), SUV (18.4%) and pick up (20.95%) were the major vehicle types associated with this type of crash. Vehicles older than 10 years also formed 67.06% of the total vehicles involved in the crash. A relatively smaller proportion of vehicles were between 0 and 5 years (15.4%) and 6–10 years (17.54%). This revealed that as vehicles age, they may develop some defects which will increase their likelihood of getting into a crash. For the specific vehicle defects, brake failure accounted for 42.02% of the compared to 22.41% for tire blow out, 10.81% for improper thread depth and 5.64% for defective wheels. The descriptive statistics of other variables associated with the vehicle defect crashes are summarized in the Table 1 below and Fig. 1, Fig. 2, Fig. 3 present the distribution of some key crash variables.

Table 1.

Descriptive statistics of variables associated with vehicle defect crashes.

Variable Frequency Percentage
Crash Severity Major Injury 681 4.52
Minor Injury 2962 19.68
No Injury 11411 75.8
Primary Contributing Factors Defective equipment 7611 50.56
Driving too fast for condition 1051 6.98
Misjudging stopping distance 973 6.46
Followed too close 901 5.99
Ran off road 417 2.77
Other -No improper driving 328 2.18
Ran traffic signal 248 1.65
Driving under influence (DUI) 129 0.86
Other 3396 22.56
Gender Male 9899 65.76
Female 5155 34.24
Driver Age 15–19 2225 14.78
20–39 7873 52.3
40–59 3627 24.09
more than 60 1329 8.83
Manner of Crash Single vehicle crash 6282 41.73
Rear end 4048 26.89
Side impact (90°) 693 4.6
Side impact (angled) 632 4.2
Head on 283 1.88
Other 3116 20.7
First harmful event Collision with Vehicle in Traffic 6092 40.47
Vehicle Defect/Component Failure 1746 11.6
Collision with Ditch 731 4.86
Collision with Tree 474 3.15
Overturn/Rollover 385 2.56
Collision with Concrete Barrier 349 2.32
Ran Off Road Right 898 5.97
Ran Off Road Straight 101 0.67
Ran Off Road Left 498 3.31
Other 3780 25.11
Safety Equipment Shoulder and Lap Belt Used 13296 88.32
No safety equipment used 630 4.18
Unknown 1128 7.49
Airbag status Airbag deployed 2754 18.29
Airbag not deployed 10496 69.72
Airbag not installed 1437 9.55
Others 367 2.44
Vehicle Age 0–5 years 2319 15.4
6–10 years 2640 17.54
more than 10 years 10095 67.06
Vehicle Type Passenger Car 6790 45.1
Pick-Up (Four-Tire Light Truck) 3154 20.95
Sport Utility Vehicle (SUV) 2770 18.4
Tractor/Semi-trailer 872 5.79
E Single-Unit Truck (2-Axle/6-Tire) 262 1.74
Others 1206 8.01
Contributing vehicle defect Brakes 6326 42.02
Tire Blowout/Separation 3374 22.41
Improper Tread Depth 1628 10.81
Headlights 109 0.72
Wheels 849 5.64
Taillights 110 0.73
Others 2658 17.66
Driver Employment Status Employed 8566 56.9
Unemployed 2491 16.55
Self-employed 875 5.81
Retired 553 3.67
Others 2569 17.07
Roadway curvature and Grade Straight and Level 9225 61.28
Straight with Down Grade 1963 13.04
Straight with Up Grade 1149 7.63
E Curve Left and Down Grade 445 2.96
Others 2272 15.09
Weather Clear 9296 61.75
Cloudy 2735 18.17
Rain 2462 16.35
Others 561 3.73

Fig. 1.

Fig. 1

Distribution of number of crashes by contributing vehicle defects.

Fig. 2.

Fig. 2

Distribution of number of crashes by vehicle type.

Fig. 3.

Fig. 3

Distribution of number of crashes by vehicle age.

The socioeconomic data from about 559 zip codes in Alabama was extracted from the United States Census Bureau (https://data.census.gov/all?q=zip+code&g=040XX00US01$8600000_860XX00US30165). Regarding the number of crashes per zip code, crash frequency ranged from 1 to 215. The average median household income was $52,081, with certain households within a zip code earning as low as $5761 and as high as $138,438. Regarding gender, the average number of females in the zip codes under study was 4,553, and people with only high school diplomas ranged from 0 to 9062. The number of Blacks/African Americans also varied from 0 to 35,694 across zip codes. Table 2 presents the descriptive statistics of the socioeconomic data.

Table 2.

Descriptive statistics of socio-economic variables associated with zip codes in Alabama.

Variable Mean Standard Deviation Min Max
Number of crashes per zip code 23.7 25.78 1 215
Median household income 52081.37 18559.96 5761 138438
Female 4553.14 5016.94 18 29737
High school diploma 1533.78 1464.43 0 9062
Black alone 2344.41 4132.20 0 35694
Population 8862.13 9617.57 108 57077

3. Methodology

3.1. Injury severity analysis

Over the years, safety researchers have adopted different modeling techniques to uncover the relationship between crash severity outcomes and their contributing factors to facilitate the proposition of more effective countermeasures. While all modeling techniques have inherent limitations, some are seemingly more robust and can account for unobserved heterogeneity usually associated with crash data [28]. Accounting for unobserved heterogeneity in crash severity studies is essential in improving statistical model inference and has become an acceptable standard in this area of research [22]. Heterogeneity models enable analysts to develop better model estimates by accounting for observation-specific variations in the effects of explanatory variables [22,29,30]. Some of the commonly used heterogeneity models include random parameter ordered probability models [31], random parameter multinomial logit models [30,32,33], random parameter models with heterogeneity in means and variances [34,35], latent class model [36], and latent class logit and mixed logit models [37,38]. This study utilizes a random parameters (mixed) logit model with heterogeneity in means to accommodate potential variations in the observations.

To start with, a severity function Skn that determines the probability that crash severity level k will result in crash n was defined as [39],

Skn=βkXkn+εkn (1)

where Xkn is a vector of explanatory variable that affect severity level k (major injury, minor injury, no injury) in crash n, and εin is the disturbance (error) term [39] assumed to follow an independent and identically extreme value of Type-1 distribution [40] Also, in Eq. (1), βk represents a vector of estimable parameters that varies across crash observations to account for unobserved heterogeneity [22]. This is expressed mathematically in Eq. (2) as:

βn=b+ΘZn+φn (2)

where b is the mean parameter estimate across all crash observations, Zn is a vector of explanatory variables from crash n that influence the mean of βn, Θ is a vector of estimable parameters, and φn is a stochastic term that captures unobserved heterogeneity across crashes.

By allowing crash-specific unobserved heterogeneity, βn vector is made to have a continuous density function P(βn=β)=f(β|φ), where φ is a vector of parameters characterizing this function. Thus, the resulting random parameters multinomial logit crash severity probabilities are:

Pn(i)=exp(βkXkn)Σexp(βkXkn)f(β|φ)dβ (3)

where Pn(i) is the probability of crash severity k in crash n conditioned on f(β|φ). This model is estimated by simulated maximum likelihood estimation where the logit probabilities shown in Eq. (3) are approximated by drawing values of β from f(β|φ) for given values of φ. According to Ref. [41], Halton sequence approach [42] is an efficient method of drawing values to compute the logit probabilities. For this study, 1500 Halton draws was used to estimate possible mixing distributions and the normal probability density function was considered most appropriate for the random parameters among other statistical distributions like uniform, lognormal, Weibull, and triangular distributions. This distribution has also been used in several other safety-related studies [43,44].

Additionally, the marginal effects were computed to investigate the effect of explanatory variables on the crash severity outcome probabilities [39]. By coding all the explanatory variables as indicator variables, the marginal effects are calculated using Eq. (4).

MEXijkPij=Pij(Xijk=1)Pij(Xijk=0) (4)

The marginal effects indicate the effect of the explanatory variable increasing from a value of 0 (i.e., no effect) to 1 on the crash severity outcomes [39,45,46]. Therefore, in Eq. (4), the marginal effect of kth indicator variable, Xijk is the probability difference when Xijk changes from 0 to 1 while other variables are constant. The marginal effects for variables with random parameter were computed as the mean of the marginal effects across all crash observations.

3.2. Spatial analysis

Spatial analysis of the crashes was further conducted to understand the correlation between vehicle defect crashes and the underlying socio-demographic factors of the regions (specifically zip codes) where the drivers live. A Multiscale Geographically Weighted Regression (MGWR) model was developed, and the results were compared to those obtained from an Ordinary Least Square (OLS) model to see which of the two models provides a better fit and understanding of the data. OLS as one of the mostly used linear regression for spatial analysis can model the relationship between the response variable and a set of explanatory variables. Given a set of n explanatory variables, the OLS model can be expressed as shown in Eq. (5) [47,48].

y=β0+i=1nβixi+ε (5)

where y is the response variable, xi is the i-th explanatory variable in the model, β0 represents the model intercept, βi is the vector of estimated global coefficient for xi and ε is the estimated random error.

The MGWR is an improved version of the geographically weighted model (GWR) capable of accommodating the nonstationary relationships between the response variable and the predictors at different spatial scales. Unlike the traditional linear regression that is build on the assumption that the same stimulus triggers the same response across space, the GWR account for the nonstationary behavior of some spatial data, meaning that the relationship between the response variable and the predictors may vary spatially. The GWR accommodate this potential variation by modifying the coefficients of different locations [49]. The GWR model formulation can be represented as follows in Eq. (6).

yi=j=0mβj(ui,vi)xij+εi (6)

where yi is the response variable xij is the j th predictor variable, βj(ui,vi) is the j th coefficient, and εi is the error term.

While the GWR can capture the nonstationary spatial relationships, it ignores the influence of scale – a fundamental geographic concept. It assumes that relationship between the response variable and the predictors vary at the same spatial scale. The MGWR relaxes this assumption by allowing the relationship between the response variable and the predictors to vary at different spatial scales [50]. This relationship is expressed as shown in Eq. (7) [48,49].

yi=j=0mβbwj(ui,vi)xij+εi (7)

where bwj in βbwj represents the bandwidth used for calibrating the j-th conditional relationship.

4. Results

4.1. Injury severity model results

The estimated results for the vehicle defect related crash severity are summarized in Table 3. Variables were entered into the model if they were found to be significant at 0.05 significance level. The McFadden Pseudo ρ2 for the estimated model was 0.43. In all, 25 variables were found to be significant, indicating their significant associations with crash severity. The indicator variables for “Shoulder and Lap belt Used”, “Male driver”, and “Overturn/Rollover” were found to be random parameters. The model was estimated using Nlogit version 6.

Table 3.

Model results including the marginal effects.

Variables In Injury severity of: Parameter estimates: t-statistics Marginal Effects
Major Injury Minor Injury No Injury
Constant 1.47 17.91
Random Parameter
Shoulder and Lap Belt Used Major Injury −3.01 −3.75 −0.0066 0.0009 0.0057
Standard deviation “Shoulder and Lap Belt Used” (Normally distributed) 1.94 3.24
Male driver Minor Injury −1.13 −5.29 −0.0006 0.011 −0.0104
Standard deviation “Male” (Normally distributed) 1.99 6.83
Overturn/Rollover Minor Injury 0.69 2.19 −0.0014 0.012 −0.0106
Standard deviation “Overturn/Rollover” (Normally distributed) 2.66 2.9
Heterogeneity in means
Shoulder and Lap Belt Used: Tire blowout or separation 0.56 3.57
Male driver: Tire blowout or separation −0.34 −2.81
Overturn/Rollover: Tire blowout or separation 0.54 1.84
Crash characteristics
DUI Major Injury 0.61 2.46 0.0008 −0.0001 −0.0006
Head on crash Major Injury 0.79 3.21 0.001 −0.0002 −0.0008
No shoulder and lap belt used Major Injury 0.78 6.22 0.0056 −0.0011 −0.0045
Airbag deployed Minor Injury 1.27 14.22 −0.0011 0.0177 −0.0166
Collision with a ditch (First harmful event) No Injury −0.38 −3.38 0.0007 0.0021 −0.0029
Driving too Fast for Conditions No Injury −0.35 −3.73 0.001 0.003 −0.0039
Rear end collision No Injury 0.36 5.61 −0.0039 −0.0108 0.0127
Driver Characteristics
Teenage driver (13–19 years) Minor Injury 0.48 4.86 −0.0004 0.0086 −0.0081
Driver Age (20–39 years) Minor Injury 0.45 5.74 −0.0015 0.0275 −0.026
Employed No Injury 0.39 7.86 −0.006 −0.0219 0.0279
Driver age (40–59 years) No Injury −0.25 −3.17 0.0021 0.0058 −0.0079
Road and Environmental Characteristics
Curve Left and Down Grade Major Injury 0.70 3.32 0.0014 −0.0003 −0.0011
Rain Major Injury −0.60 −3.94 −0.003 0.0006 0.0025
Vehicle Characteristics
Improper Tread Depth (Vehicle defect) Major Injury 1.12 7.65 0.0079 −0.0015 −0.0064
Pick up Major Injury −0.48 −3.82 −0.0032 0.0005 0.0027
Brake (Vehicle defect) Minor Injury 0.43 6.79 −0.0009 0.0229 −0.022
Component failure (first harmful event) Minor Injury −0.46 −4.18 0.0002 −0.0041 0.0039
Passenger car No Injury 0.21 4.09 −0.0027 −0.0109 0.0136
Wheels (Vehicle defect) No Injury 0.33 2.66 −0.0004 −0.0016 0.002
Headlight (vehicle defect) No Injury −1.12 −4.59 0.0005 0.0011 −0.0015
Vehicle age (less than 6 years) No Injury 0.39 5.26 −0.0015 −0.0057 0.0072
Vehicle age (6–10 years) No Injury 0.26 3.99 −0.0012 −0.0049 0.0061
Model Statistics
Number of Observations 15054
Log-likelihood at constants −16538.51
Log-likelihood at convergence −9396.51
McFadden Pseudo r squared 0.43

Regarding the random parameters, the indicator variable “Shoulder and Lap belt used” defined for the major injury function had a mean of −3.01 and a standard deviation of 1.94. From the normal distribution curve these numbers indicate that for 6.04% of crashes where the seat and lap belts were used, the probability of major injury was high but for the remaining 93.96% of crashes where shoulder and lap belts were used, the probability of major injury was low. The indicator variable for “Male driver” (defined for the minor injury function) had a mean of −1.13 and a standard deviation of 1.99. On the normal distribution curve, these numbers indicate that for 28.51% of crashes involving male drivers, there was a higher probability of minor injury. For the remaining 71.49%, the probability of minor injury was low. Furthermore, the indicator variable “Overturn/Rollover” defined for the minor injury had a mean of 0.69 and standard deviation of 2.67, revealing that for 60.20% of crashes where the vehicle overturned or rolled over, the probability of minor injury was high. For the rest of the 39.80% of crashes where the vehicle overturned or rolled over, the probability of minor injury was low. Concerning the heterogeneity in means of the random variables, the indicator variable for “tire blowout/separation” increased the mean of the “shoulder and lap belt use” and “overturn/rollover” random parameter variables and decreased the mean of the male driver random parameter variable. This reveals that tire blowouts or separation crashes involving drivers using shoulder and lap belts were more likely to result in major injury. Also, tire blow out or separation crashes where vehicles rolled over or overturned were more likely to result in minor injuries. However, tire blowouts/separation crashes involving male drivers were less likely to result in minor injuries.

The marginal effects result showed that crashes, where shoulder and lap belt were used, were less likely to result in major injury while the likelihood of minor and no injury was high. For crashes involving male drivers, the probability of major and no injury was low while the likelihood of minor injury is high. Lastly, the indicator variable, “Overturn/Rollover” increased the probability of minor injury by 1.2% and decreased the likelihood of major and no injury by 0.14% and 1.06% respectively. The marginal effects of the non-random variables were summarized below.

4.2. Crash characteristics

Several variables related to the crash characteristics were found to significantly influence the injury severity of the crashes. The marginal effects of head-on crashes, drivers charged with drinking under the influence, and drivers not using lap and shoulder belts increased the probability of major injury by 0.001, 0.0008, and 0.0056 respectively while the probability of minor and no injury is low. In addition, crashes involving collision with a ditch and driving too fast for the condition were more likely to result in major and minor injuries while the probability of no injury was low. In crashes where an airbag was deployed, the probability of major and no injury was low while the probability of minor injury was high. Similarly, the “rear end collision” indicator variable reduced the probability of major and minor injury by 0.0039 and 0.108 respectively and increased the of no injury by 0.0127.

4.3. Driver characteristics

Regarding the demographics associated with the at-fault driver, the indicator variable for “Teenage driver (15–19)” and “Driver aged (20–39)” increased the probability of minor injury by 0.0086 and 0.0275 respectively while the probability of major and no injury was low. However, crashes involving drivers between 40 and 59 years were more likely to result in major and minor injury while the probability of no injury was low. In addition, the marginal effects showed that crashes involving employed drivers reduced the likelihood of major and minor injury by 0.006 and 0.0219 respectively while the probability of no injury increased by 0.0279.

4.4. Road and environmental characteristics

The nature of the roadway plays an important role in the occurrence of crashes. Crashes that occurred on roads that are curved left with downgrades were likely to result in major injuries while the probability of minor and no injury is low. Also, the indicator variable for rain reduced the probability of major injury by 0.003 while the probability of minor and no injury was high.

4.5. Vehicle characteristics

Some of the vehicle defect variables are discussed in this section. For instance, the indicator variable for improper tread depth increased the likelihood of major injury by 0.0079 while the probability of minor and no injury was low. It was further found that crashes involving defective brakes were less likely to result in major and no injury while the probability of minor injury was high. In addition, crashes involving wheel defect were less likely to result in major and minor injuries while the probability of no injury was high. Furthermore, indicator variable for headlight defect increased the probability of major and minor injury by 0.005 and 0.0011 respectively while the probability of no injury was low.

Regarding vehicle type, crashes involving pick up trucks with a defective component were less likely result to in major injury while the probability of minor and no injury is low. Conversely, the marginal effect of the passenger car indicator variable reduced the probability of major and minor injuries by 0.0027 and 0.0109 while the probability of no injury was low. Also, crashes involving vehicles aged less than 6 years and vehicles aged between 6 and 10 were both less likely to result in major and minor injury while the probability of no injury was high.

4.6. Spatial analysis results

The number of crashes was aggregated by postal code of the at-fault driver's residence (this information was obtained by the reporting officer from the license of the driver). Fig. 4 (a and b) presents the distribution of vehicle defect-related crashes based on the average income and population of the residential code of the driver. The maps were generated using ArcGIS Pro. The number of crashes was normalized using the population and median household income for the residential postal code of the at-fault driver. From the choropleth map, postal codes in counties like Mobile, Baldwin, Greene, Talladega, Jefferson, and Montgomery recorded a significantly high number of vehicle defect crashes based on median household income. Regarding the population, postal code areas in counties like Greene, Conecuh, Mobile, St. Clair and Shelby recorded high number of crashes per 100,000 population.

Fig. 4.

Fig. 4

Distribution of the number of crashes per (a) Income and (b) Population.

Considering how crash numbers were distributed based on social and economic variables like population and median household income, a thorough spatial analysis was conducted using other variables like postal code race and educational background information to investigate how these factors affect vehicle defect related crashes using Ordinary Least Square (OLS) and Multiscale Geographically Weighted Regression (MGWR) models. Prior to developing the model, a Variance Inflation Factor (VIF) test was conducted to select variables that will improve regression results and reduce multicollinearity among predictors. A VIF of 5 was selected as a threshold. Median household income has a VIF score of 1.416543, female population had a score of 3.621027, High school diploma holder population had a score of 4.423583, and Black/African American population had a score of 2.460583.

4.7. Spatial regression results

The study used the MGWR and OLS to explore the spatial relationship between the frequency of crashes in different postal codes and various social/economic variables. The two models were also compared based on the goodness of fit. Using the R-squared and the corrected Akaike information criterion (AICc), the MGWR was observed to outperform the OLS (see Table 5). The Variance Inflation Factor (VIF) was also used in selecting the independent variables to avoid multicollinearity. This was done to avoid using independent variables that are highly correlated with each other. A VIF threshold of 5 was chosen in selecting variables based on previous research by Ref. [51]. Variables like Median household income, number of people with high school diploma, number of black/African American in the postal code area, and the number of females were selected for the model (See Table 4). The model was estimated using ArcGIS pro.

Table 5.

OLS and MGWR estimation results for exploring the relationship between number of crashes and selected social/economic variables.

Variables OLS
t-statistics MGWR
Coefficient Coefficient
Optimal Number of Neighbors
Mean Max Std Dev
Intercept 1.85 1.40 0.0083 0.3428 0.1533 41
Median Household Income −0.000022 −0.88 −0.041 0.1386 0.0701 55
Female pop 0.000767 3.93 0.2068 0.6336 0.2159 55
Only high school Diploma pop 0.01 16.13 0.5095 0.8655 0.1501 35
Black/African American pop 0.002 13.41 0.3052 0.5355 0.1599 55
R squared 0.8797 0.9554
AICc 4047.0898 124.4677

Table 4.

VIF scores for selected variables.

Median household income Female pop High school diploma pop Black/African American alone pop
VIF scores 1.42 3.62 4.42 2.46

The result of the OLS shows that the number of females have a positive correlation with the number of vehicle defect related crashes. The variables “Black/African American” and “Only high school diploma” also have strong positive correlation with the number of crashes involving drivers in the postal codes. However, the variable “Median Household Income” has a negative correlation with the frequency of crashes. This trend is similar in the MGWR model. In comparing both models, the MGWR fits better with a higher R-squared value (0.96) as compared to OLS (0.88). The MGWR also has significantly lower AICc scores than OLS.

5. Discussion

Road crashes are often influenced by vehicle defects, which encompass faults or malfunctions in mechanical or electrical components that can compromise the vehicle's safety, reliability, and performance. Some common vehicle defects, identified from historical crash data, include braking system failure, tire blowouts, and improper tire thread depth. When these defects coexist with other crash-contributing factors, they can lead to more severe crash outcomes. For example, if a vehicle experience braking system failure while speeding, the likelihood of a severe crash increases significantly. To investigate the impact of various crash factors on the severity of vehicle defect-related crashes, this study utilized an advanced econometric modeling technique that considers unobserved heterogeneity across crash observations. This research is particularly crucial given the ongoing development of autonomous vehicles. As the world moves towards a future with self-driving cars, safety concerns may shift from human error to vehicle-related factors and general system failures. Therefore, understanding the contribution of vehicle defects to crash severity becomes increasingly important to ensure the safety and reliability of autonomous vehicle technology.

In order to gain deeper insights into the impact of vehicle defects on crash occurrences and injury severity, this research used historical crash data from Alabama. The initial analysis revealed that brake defects accounted for a significant proportion, representing 42% of all the defects that were deemed to be associated with the crashes, followed by tire blowouts which made up 22.4%. A related study also highlighted the prevalence of worn tires and defective brakes in vehicle defect-related crashes, indicating that these issues were overrepresented [3]. Additionally, it was observed that airbags were not deployed in around 70% of the crashes, and approximately 67% of the defective vehicles were more than a decade old. These findings provide valuable information about the key factors contributing to crashes and injury severity related to vehicle defects in the state of Alabama. A study by DEKRA Automobil GmbH [15] found that older vehicles are more prone to crashes because of poor maintenance. These findings underscore the safety concerns related to aging vehicles and insufficient or improper vehicle maintenance. As a result, it becomes crucial to prioritize regular maintenance and timely repairs to identify and rectify any potential defects that could lead to serious crashes. By taking proactive measures, such as regular inspections and addressing issues promptly, we can significantly reduce the risk of road crashes caused by vehicle defects and ensure safer road conditions for everyone. As common in most road traffic crash studies [[52], [53], [54]], factors such as driving too fast for condition, DUI, road curvature, and non-compliance with the use of lap and shoulder belts increased the probability of major injury outcomes. However, vehicle defects can play a significant role in the final crash outcomes. An earlier study noted that vehicle defects were among the last in the chain of events leading to final crash outcome [3]. Most vehicle defects like brake failure can limit the ability of the driver to bring the vehicle to a stop during a crash event.

Approximately 42% of the crashes in this study were linked to brake defects, and these defects were found to be more associated with minor injuries. It is possible that some drivers, aware of their braking system issues, choose to drive with a sense of caution, possibly avoiding situations that require sudden or hard braking. Such drivers could be considered risk-takers. The results also showed that improper tread depth or worn-out tires are associated with major injury crashes. These vehicle defects are more likely to result in tire blowouts. At higher speeds, tire blowouts could lead to severe injury outcomes. Implementing measures to encourage drivers to prioritize regular vehicle maintenance can help to minimize the risk of crashes. Such measures can include installing in-vehicle safety features that alert the driver to check the tire road worthiness after a set threshold. By addressing and eliminating vehicle defects from the chain of events leading to the final crash outcomes, we could potentially limit the severity of crash outcomes.

The random parameters account for the potential variations of the effects of the random variables across the crash observations due to unobserved factors contributing to the crash outcomes. For instance, the results showed that the probability of major injury crashes is high for only 6.04% of the crashes when shoulder and lap belt is used. It implies that seatbelt use reduces the possibility of severe outcomes for 93.96% of vehicle defect-related crashes. While seatbelt is associated with severe injury outcomes for a small proportion of the observations, tire blowout during a crash increases the likelihood of severe injury outcomes.

Generally, vehicle defect-related crashes can be attributed to the neglect of basic vehicle maintenance, which may be due to ignorance or financial constraints faced by some vehicle owners. To understand these crashes as a broader societal issue and potentially explore their connection with socio-demographic characteristics, a spatial analysis was undertaken. This study delved into the social, economic, and educational backgrounds of drivers based on their residential zip codes. Previous studies (e.g., Adanu et al. [55]) have observed that drivers that share a common regional socioeconomic context are more likely to experience similar road safety problems. The ability to identify clusters of drivers with common road safety problems presents an opportunity for a targeted implementation of countermeasures. To explore the complex interplay of these factors and to identify potential clusters of drivers who were involved in vehicle defect-related crashes a Mixed Geographically Weighted Regression model was employed within ArcGIS 3.0. This innovative method allowed coefficients of explanatory variables to vary across different spatial locations. Unlike the traditional Geographically Weighted Regression (GWR), this approach considered the distinct characteristics of various neighborhoods for each explanatory variable, offering a more nuanced and detailed analysis of the relationship between socio-demographic factors and vehicle defect-related crashes. The results of this analysis validated findings in previous studies regarding the driver population that is most likely to be involved in vehicle defect-related crashes. It was found that there is a negative correlation between median household income and the frequency of vehicle defect crashes, indicating that drivers from lower-income zip codes are more prone to such incidents. While a previous study by Ref. [10] demonstrated that drivers from low-income areas have lower overall crash rates, they also found that crashes specifically related to vehicle defects are more prevalent in lower-income areas. The study posited that their observation may be attributed to the financial burden associated with vehicle maintenance, repairs, and acquiring newer vehicle models. Interestingly, our study found that zip codes with a higher number of female residents were associated with a higher frequency of vehicle defect-related crashes. Although female drivers are often perceived as more cautious, previous research from PEMCO Insurance [56] indicated that female drivers are less likely to engage in self-maintenance of their vehicles compared to men. This may perhaps be due to a lower knowledge of the mechanical design and operation of vehicles among female drivers. Also, while women are more inclined to rely on repair shops, they may also face higher price quotes compared to men [57]. These factors, among others, contribute to a lower likelihood of female drivers to maintain their vehicles properly and therefore exposing them to vehicle defect-related crashes.

Regarding racial and educational attainment distributions, zip codes with a higher population of African Americans and those that had a higher number of individuals with only a high school diploma exhibited a positive correlation with vehicle defect-related crashes. Interestingly, these zip codes are also associated with higher levels of poverty in the state. Indeed, data on poverty rates among different racial groups in Alabama, as reported by Alabama Possible, a statewide nonprofit organization in 2017 indicated that 31.2% of African Americans and 16.54% of individuals with only a high school diploma in Alabama were living in poverty [58]. These regions are therefore good candidates for the implementation of countermeasures related to education and awareness creation, and policies for subsidies on basic vehicle maintenance. Incentive schemes may also be developed to encourage vehicle owners in the poorer regions of the state to undertake regular vehicle checks.

6. Conclusions

Vehicle defects have the potential to influence the severity of crashes. This study focused on investigating the factors associated with vehicle defect-related crash injury severity. A random parameter multinomial logit model with heterogeneity in mean was developed to uncover the relationship between the response variable (crash severity levels) and the explanatory factors while accounting for the existence of unobserved heterogeneity within the crash observations. The crash data used for this study was obtained from the Critical Analysis Reporting Environment (CARE) software system developed by the University of Alabama Center for Advanced Public Safety (CAPS) for the period covering 2016 to 2020. Preliminary data analysis revealed that defective equipment was the primary contributing factor in 50.56% of the crashes, indicating that in a little over half of the total crash observations, some form of vehicle defect is deemed to be responsible for the crash. With regard to the specific defects, it was observed that brake defects accounted for a significant proportion, representing 42% of all vehicle defects associated with the crashes, followed by tire blowouts at 22.4%. The model estimation results revealed some interesting findings. For instance, it was found that crashes that occurred on roads that are curved left with downgrades were likely to result in major injuries. Also, it was revealed that crashes involving drivers between 40 and 59 years were more likely to result in major and minor injury while younger drivers had lower probability of sustaining major injuries.

To better understand vehicle defect crashes as a broader societal issue and potentially explore their connection with socio-demographic characteristics, a spatial analysis was undertaken using a Mixed Geographically Weighted Regression model that delved into the social, economic, and educational backgrounds of drivers based on their residential zip codes. It was found that there is a negative correlation between median household income and the frequency of vehicle defect crashes, indicating that drivers from lower-income zip codes are more prone to such incidents. It was further observed that zip codes with a higher population of Black Americans and individuals with only a high school diploma exhibited a positive correlation with a higher frequency of vehicle defect-related crashes.

While the study presents intriguing findings, it is essential to acknowledge that the crash data relies on police-reported incidents, and the accuracy of the collected data cannot be independently verified by the authors. This becomes particularly crucial as reporting officers had to assess the contributing role of vehicle defects in the crash, a determination often subject to the subjective judgment of the reporting officer in low injury severity incidents. This introduces a potential bias in the study's data, although it is worth noting that this challenge is not exclusive to the database used. Nevertheless, the study's findings offer valuable and data-driven insights, emphasizing the need for ongoing safety campaigns, workshops, and training initiatives focused on basic vehicle maintenance practices in low-income communities within the state. Subsequent research endeavors could extend the scope of this study by incorporating multiple states to examine whether the prevalence of vehicle defect-related crashes is influenced by mandatory policies on annual vehicle inspections in some states.

Data availability statement

The data used for this study will be made available upon reasonable request.

CRediT authorship contribution statement

Emmanuel Kofi Adanu: Writing – review & editing, Writing – original draft, Methodology, Data curation, Conceptualization. Richard Dzinyela: Writing – review & editing, Writing – original draft, Formal analysis, Data curation. Sunday Okafor: Writing – review & editing, Writing – original draft, Data curation. Steven Jones: Writing – review & editing, Writing – original draft.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgments

The authors would like to thank the University of Alabama Center for Advanced Public Safety (CAPS) for providing the data and the Alabama Transportation Institute for supporting this study.

Contributor Information

Emmanuel Kofi Adanu, Email: ekadanu@crimson.ua.edu.

Richard Dzinyela, Email: dzinyela_1@tamu.edu.

Sunday Okafor, Email: scokafor1@crimson.ua.edu.

Steven Jones, Email: steven.jones@ua.edu.

References

  • 1.Treat J.R., Tumbas N.S., McDonald S.T., Shinar D., Hume R.D., Mayer R.E., Stansifer R.L., Castellan N.J. Executive summary; 1979. Tri-level Study of the Causes of Traffic Accidents: Final Report. [Google Scholar]
  • 2.Carfax . Prnewswire; 2018. 57 Million Vehicles on U.S. Roads Have Open Recalls.https://www.prnewswire.com/news-releases/carfax-57-million-vehicles-on-us-roads-have-open-recalls-300618100.html [Google Scholar]
  • 3.Singh S. (Traffic Safety Facts Crash•Stats. Report No. DOT HS 812 115), Washington, DC. 2015. Stats critical reasons for crashes investigated in the National motor vehicle crash Causation survey. [Google Scholar]
  • 4.Iden R., Shappell S.A. A human error analysis of U.S. Fatal highway crashes 1990–2004. Proc. Hum. Factors Ergon. Soc. Annu. Meet. 2006;50:2000–2003. doi: 10.1177/154193120605001761. [DOI] [Google Scholar]
  • 5.Singh H., Kushwaha V., Agarwal A.D., Sandhu S.S. Fatal road traffic accidents: causes and factors responsible. J. Indian Acad. Forensic Med. 2016;38:52. doi: 10.5958/0974-0848.2016.00014.2. [DOI] [Google Scholar]
  • 6.Allen T., Newstead S., Lenné M.G., McClure R., Hillard P., Symmons M., Day L. Contributing factors to motorcycle injury crashes in Victoria, Australia. Transport. Res. F Traffic Psychol. Behav. 2017;45:157–168. doi: 10.1016/j.trf.2016.11.003. [DOI] [Google Scholar]
  • 7.Varmazyar S., Mortazavi S.B., Hajizadeh E., Arghami S. The relationship between driving Aberrant behavior and self-reported accidents involvement amongst professional bus drivers in the public transportation company. Health Scope. 2013;2:110–115. doi: 10.17795/jhealthscope-11552. [DOI] [Google Scholar]
  • 8.Green E.R., Agent K.R., Pigman J.G., Ross P.A. Kentucky; 2017. Analysis of Traffic Crash Data in Kentucky. 2012-2016. [DOI] [Google Scholar]
  • 9.Solah M.S., Hamzah A., Ariffin A.H., Paiman N.F., Abdul Hamid I., Abdul Wahab M.A.F., Mohd Jawi Z., Osman M.R. Private vehicle Roadworthiness in Malaysia from the vehicle inspection Perspective. Journal of the Society of Automotive Engineers Malaysia. 2017;1:262–271. doi: 10.56381/jsaem.v1i3.67. [DOI] [Google Scholar]
  • 10.L, Ozelim S., Zephaniah E.K., Adanu R., Smith S. Jones. 17th International Conference Road Safety on Five Continents (RS5C 2016) Statens väg-och transportforskningsinstitut; Rio de Janeiro, Brazil: 2016. Factors in differential safety performance across different income levels. [Google Scholar]
  • 11.Kinsey G. 2nd Conference. National Institute of Transport and Road Research; Pietersburg, South Africa: 1976. Contribution of unroadworthy vehicles to accidents. [Google Scholar]
  • 12.van Schoor O., van Niekerk J.L., Grobbelaar B. Mechanical failures as a contributing cause to motor vehicle accidents — South Africa. Accid. Anal. Prev. 2001;33:713–721. doi: 10.1016/S0001-4575(00)00083-X. [DOI] [PubMed] [Google Scholar]
  • 13.Conroy C., Tominaga G.T., Erwin S., Pacyna S., Velky T., Kennedy F., Sise M., Coimbra R. The influence of vehicle damage on injury severity of drivers in head-on motor vehicle crashes. Accid. Anal. Prev. 2008;40:1589–1594. doi: 10.1016/j.aap.2008.04.006. [DOI] [PubMed] [Google Scholar]
  • 14.Hoque M.S., Hasan M.R. International Conference on Road Safety in Developing Countries, Dhaka, Bangladesh. 2006. Vehicle factors in road accidents: the context of developing countries. [Google Scholar]
  • 15.DEKRA Automobil GmbH . 2015. ROAD SAFETY REPORT 2015 A Future Based on Experience DEKRA Automobil GmbH Strategies for Preventing Accidents on European Roads.www.dekra.de [Google Scholar]
  • 16.Akloweg Y., Hayshi Y., Kato H. The effect of used cars on African road traffic accidents: a case study of Addis Ababa, Ethiopia. Int. J. Unity Sci. 2011;15:61–69. doi: 10.1080/12265934.2011.580153. [DOI] [Google Scholar]
  • 17.Al-Ghaweel I., Saleh P., Mursi A., Jack J.P., Joel I. LIBYA; 2009. Road Traffic Accidents in Libya 7 FACTORS AFFECTING ROAD TRAFFIC ACCIDENTS IN BENGHAZI.www.ntclibya.comU [PMC free article] [PubMed] [Google Scholar]
  • 18.Islam M., Kanitpong K. Identification of factors in road accidents through in-depth accident analysis. IATSS Res. 2008;32:58–67. doi: 10.1016/S0386-1112(14)60209-0. [DOI] [Google Scholar]
  • 19.Das S., Dutta A., Geedipally S.R. Applying Bayesian data mining to measure the effect of vehicular defects on crash severity. J. Transport. Saf. Secur. 2021;13:605–621. doi: 10.1080/19439962.2019.1658674. [DOI] [Google Scholar]
  • 20.Haq M.T., Zlatkovic M., Ksaibati K. Assessment of tire failure related crashes and injury severity on a mountainous freeway: Bayesian binary logit approach. Accid. Anal. Prev. 2020;145 doi: 10.1016/j.aap.2020.105693. [DOI] [PubMed] [Google Scholar]
  • 21.Haq M.T., Ampadu V.-M.K., Ksaibati K. An investigation of brake failure related crashes and injury severity on mountainous roadways in Wyoming. J. Saf. Res. 2023;84:7–17. doi: 10.1016/j.jsr.2022.10.003. [DOI] [PubMed] [Google Scholar]
  • 22.Mannering F.L., Shankar V., Bhat C.R. Unobserved heterogeneity and the statistical analysis of highway accident data. Anal Methods Accid Res. 2016;11 doi: 10.1016/j.amar.2016.04.001. [DOI] [Google Scholar]
  • 23.Anastasopoulos P.Ch, Mannering F.L. An empirical assessment of fixed and random parameter logit models using crash- and non-crash-specific injury data. Accid. Anal. Prev. 2011;43:1140–1147. doi: 10.1016/j.aap.2010.12.024. [DOI] [PubMed] [Google Scholar]
  • 24.Hosseinzadeh A., Moeinaddini A., Ghasemzadeh A. Investigating factors affecting severity of large truck-involved crashes: comparison of the SVM and random parameter logit model. J. Saf. Res. 2021;77:151–160. doi: 10.1016/j.jsr.2021.02.012. [DOI] [PubMed] [Google Scholar]
  • 25.Okafor S., Adanu E.K., Jones S. Severity analysis of crashes involving in-state and out-of-state large truck drivers in Alabama: a random parameter multinomial logit model with heterogeneity in means and variances. Heliyon. 2022;8 doi: 10.1016/j.heliyon.2022.e11989. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 26.Adanu E.K., Powell L., Jones S., Smith R. Learning about injury severity from no-injury crashes: a random parameters with heterogeneity in means and variances approach. Accid. Anal. Prev. 2023;181 doi: 10.1016/j.aap.2022.106952. [DOI] [PubMed] [Google Scholar]
  • 27.Islam S., Jones S. Pedestrian at-fault crashes on rural and urban roadways in Alabama. Accid. Anal. Prev. 2014;72:267–276. doi: 10.1016/j.aap.2014.07.003. [DOI] [PubMed] [Google Scholar]
  • 28.Savolainen P.T., Mannering F.L., Lord D., Quddus M.A. The statistical analysis of highway crash-injury severities: a review and assessment of methodological alternatives. Accid. Anal. Prev. 2011;43:1666–1676. doi: 10.1016/j.aap.2011.03.025. [DOI] [PubMed] [Google Scholar]
  • 29.Behnood A., Mannering F.L. An empirical assessment of the effects of economic recessions on pedestrian-injury crashes using mixed and latent-class models. Anal Methods Accid Res. 2016;12 doi: 10.1016/j.amar.2016.07.002. [DOI] [Google Scholar]
  • 30.Adanu E.K., Dzinyela R., Agyemang W. A comprehensive study of child pedestrian crash outcomes in Ghana. Accid. Anal. Prev. 2023;189 doi: 10.1016/j.aap.2023.107146. [DOI] [PubMed] [Google Scholar]
  • 31.Azimi G., Rahimi A., Asgari H., Jin X. Severity analysis for large truck rollover crashes using a random parameter ordered logit model. Accid. Anal. Prev. 2020;135 doi: 10.1016/j.aap.2019.105355. [DOI] [PubMed] [Google Scholar]
  • 32.Cheng L., Caset F., de Vos J., Derudder B., Witlox F. Investigating walking accessibility to recreational amenities for elderly people in Nanjing, China. Transp Res D Transp Environ. 2019;76:85–99. doi: 10.1016/j.trd.2019.09.019. [DOI] [Google Scholar]
  • 33.Ahmadi A., Jahangiri A., Berardi V., Machiani S.G. Crash severity analysis of rear-end crashes in California using statistical and machine learning classification methods. J. Transport. Saf. Secur. 2020;12:522–546. doi: 10.1080/19439962.2018.1505793. [DOI] [Google Scholar]
  • 34.Behnood A., Mannering F. The effect of passengers on driver-injury severities in single-vehicle crashes: a random parameters heterogeneity-in-means approach. Anal Methods Accid Res. 2017;14:41–53. doi: 10.1016/J.AMAR.2017.04.001. [DOI] [Google Scholar]
  • 35.Damsere-Derry J., Adanu E.K., Ojo T.K., Sam E.F. Injury-severity analysis of intercity bus crashes in Ghana: a random parameters multinomial logit with heterogeneity in means and variances approach. Accid. Anal. Prev. 2021;160 doi: 10.1016/J.AAP.2021.106323. [DOI] [PubMed] [Google Scholar]
  • 36.Shaheed M.S., Gkritza K. A latent class analysis of single-vehicle motorcycle crash severity outcomes. Anal Methods Accid Res. 2014;2:30–38. doi: 10.1016/J.AMAR.2014.03.002. [DOI] [Google Scholar]
  • 37.Behnood A., Mannering F.L. An empirical assessment of the effects of economic recessions on pedestrian-injury crashes using mixed and latent-class models. Anal Methods Accid Res. 2016;12:1–17. doi: 10.1016/j.amar.2016.07.002. [DOI] [Google Scholar]
  • 38.Agyemang W., Adanu E.K., Liu J., Jones S. A latent class multinomial logit analysis of factors associated with pedestrian injury severity of inter-urban highway crashes. J. Transport. Saf. Secur. 2022:1–21. doi: 10.1080/19439962.2022.2153952. [DOI] [Google Scholar]
  • 39.Washington S., Karlaftis M., Mannering F., Anastasopoulos P. Chapman and Hall/CRC; 2020. Statistical and Econometric Methods for Transportation Data Analysis. [DOI] [Google Scholar]
  • 40.McFadden D. Structural Analysis of Discrete Data with Econometric Applications. 198272nd ed. The MIT Press; Cambridge, MA: 1981. Econometric models of probabilistic choice. [Google Scholar]
  • 41.Bhat C.R. Simulation estimation of mixed discrete choice models using randomized and scrambled Halton sequences. Transp. Res. Part B Methodol. 2003;37:837–855. doi: 10.1016/S0191-2615(02)00090-5. [DOI] [Google Scholar]
  • 42.Halton J.H. On the efficiency of certain quasi-random sequences of points in evaluating multi-dimensional integrals. Numer. Math. 1960;2 doi: 10.1007/BF01386213. [DOI] [Google Scholar]
  • 43.Li Y., Song L., David Fan W. Day-of-the-week variations and temporal instability of factors influencing pedestrian injury severity in pedestrian-vehicle crashes: a random parameters logit approach with heterogeneity in means and variances. Anal Methods Accid Res. 2021;29 doi: 10.1016/j.amar.2020.100152. [DOI] [Google Scholar]
  • 44.Damsere-Derry J., Adanu E.K., Ojo T.K., Sam E.F. Injury-severity analysis of intercity bus crashes in Ghana: a random parameters multinomial logit with heterogeneity in means and variances approach. Accid. Anal. Prev. 2021;160 doi: 10.1016/j.aap.2021.106323. [DOI] [PubMed] [Google Scholar]
  • 45.Ulfarsson G.F., Mannering F.L. Differences in male and female injury severities in sport-utility vehicle, minivan, pickup and passenger car accidents. Accid. Anal. Prev. 2004;36 doi: 10.1016/S0001-4575(02)00135-5. [DOI] [PubMed] [Google Scholar]
  • 46.Chen F., Chen S. Injury severities of truck drivers in single- and multi-vehicle accidents on rural highways. Accid. Anal. Prev. 2011;43:1677–1688. doi: 10.1016/J.AAP.2011.03.026. [DOI] [PubMed] [Google Scholar]
  • 47.Li X., Dadashova B., Yu S., Zhang Z. Rethinking highway safety analysis by Leveraging Crowdsourced Waze data. Sustainability. 2020;12 doi: 10.3390/su122310127. [DOI] [Google Scholar]
  • 48.Cui W., Li J., Xu W., Güneralp B. Industrial electricity consumption and economic growth: a spatio-temporal analysis across prefecture-level cities in China from 1999 to 2014. Energy. 2021;222 doi: 10.1016/j.energy.2021.119932. [DOI] [Google Scholar]
  • 49.Fotheringham A.S., Yang W., Kang W. Multiscale geographically weighted regression (MGWR) Ann. Assoc. Am. Geogr. 2017;107:1247–1265. doi: 10.1080/24694452.2017.1352480. [DOI] [Google Scholar]
  • 50.Yang W. Doctoral Dissertation, University of St Andrews); 2014. An Extension of Geographically Weighted Regression with Flexible Bandwidths. [Google Scholar]
  • 51.Li X., Yu S., Huang X., Dadashova B., Cui W., Zhang Z. Do underserved and socially vulnerable communities observe more crashes? A spatial examination of social vulnerability and crash risks in Texas. Accid. Anal. Prev. 2022;173 doi: 10.1016/j.aap.2022.106721. [DOI] [PubMed] [Google Scholar]
  • 52.Bogstrand S.T., Larsson M., Holtan A., Staff T., Vindenes V., Gjerde H. Associations between driving under the influence of alcohol or drugs, speeding and seatbelt use among fatally injured car drivers in Norway. Accid. Anal. Prev. 2015;78:14–19. doi: 10.1016/J.AAP.2014.12.025. [DOI] [PubMed] [Google Scholar]
  • 53.Okafor S., Adanu E.K., Lidbe A., Jones S. Severity analysis of single-vehicle left and right run-off-road crashes using a random parameter ordered logit model. Traffic Inj. Prev. 2023;24:251–255. doi: 10.1080/15389588.2023.2174376. [DOI] [PubMed] [Google Scholar]
  • 54.Adanu E.K., Okafor S., Penmetsa P., Jones S. Understanding the factors associated with the temporal variability in crash severity before, during, and after the COVID-19 Shelter-in-Place order. Saf. Now. 2022;8:42. doi: 10.3390/safety8020042. [DOI] [Google Scholar]
  • 55.Adanu E.K., Smith R., Powell L., Jones S. Multilevel analysis of the role of human factors in regional disparities in crash outcomes. Accid. Anal. Prev. 2017;109 doi: 10.1016/j.aap.2017.09.022. [DOI] [PubMed] [Google Scholar]
  • 56.PEMCO Insurance . Prnewswire; 2015. Northwest Men Lead Ladies on DIY Car Maintenance.https://www.prnewswire.com/news-releases/northwest-men-lead-ladies-on-diy-car-maintenance-300023740.html [Google Scholar]
  • 57.Danielle K. 2013. Auto Repair Shops Really Do Charge Women More (Sometimes), USNews.https://www.usnews.com/news/articles/2013/06/27/study-auto-repair-shops-really-do-charge-women-more-sometimes [Google Scholar]
  • 58.Possible Alabama. 2017. Alabama Poverty Data Sheet, Alabama Possible.https://alabamapossible.org/wp-content/uploads/2016/02/AP_PovertyFactSheet_2017.pdf [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Data Availability Statement

The data used for this study will be made available upon reasonable request.


Articles from Heliyon are provided here courtesy of Elsevier

RESOURCES