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Article

A Cost–Benefit Analysis to Assess the Effectiveness of Frontal Center Curtain Airbag

1
Department of Information & Industrial Engineering, Yonsei University, 50 Yonsei-ro Seodaemun-gu, Seoul 03722, Korea
2
Research and Development Division for Hyundai Motor Company and Kia Motors Corporation, Namyang-myun, Whasung-gun, Kyunggi-do 445-706, Korea
*
Author to whom correspondence should be addressed.
Sustainability 2017, 9(10), 1745; https://doi.org/10.3390/su9101745
Submission received: 3 August 2017 / Revised: 20 September 2017 / Accepted: 20 September 2017 / Published: 27 September 2017

Abstract

:
Several new varieties of airbags are under consideration for development. However, their commercialization decision must be backed by a positive Cost–Benefit Analysis (CBA) outcome. In this study, we propose a CBA framework for the frontal center curtain airbag, a newly designed safety system intended to reduce the injury risk of rear-seat passengers. The proposed CBA covers not only economic benefits of the producer but also the effectiveness in sustainable reduction of the fatal and injury rate. In this context, with accumulated field data on road traffic accidents, a forecasting method reflecting the reduced casualties and the market share of vehicle sales associated with frontal center curtain airbag is utilized. Our results suggest that the use of frontal center curtain airbags helps to reduce the number of casualties with a Maximum Abbreviated Injury Scale (MAIS) of 3 or above by 87.4%. Furthermore, both the initial market penetration rate and price of the frontal center curtain airbag significantly influence its socioeconomic benefits. By evaluating the effectiveness of the frontal center curtain airbag, our study can contribute to the decision making for its commercialization.

1. Introduction

The launch of a new type of safety system in a market requires the estimation of its socioeconomic effects, which is necessary for the sustainable management of technology [1,2,3]. In this context, some previous works developed the Cost–Benefit Analysis (CBA) framework, which has generally been used to assess the effectiveness of safety systems quantitatively. However, these works primarily rely on field accident cases. Thus, the application of the established CBA framework is limited for a new safety system that has not been installed in a fleet. To fill this gap, this study proposes a CBA framework with a forecasting model for a newly-developed safety system that has not been launched in the market yet. Herein, we consider the case of the frontal center curtain airbag.
In the proposed framework, we predict the injury severity reduction of potential passengers based on the functionality of a safety system using data from the National Automotive Sampling System—Crashworthiness Data System (NASS-CDS). This study focuses on the role of the safety system in sustainable reduction in fatal and injury rate with considering the monetary value of injury severity reduction as the benefits of the safety system installation [4]. Additionally, to estimate the potential passengers who will benefit from the safety system, we forecast the future sales of vehicles that include this system as a basic option. We utilize the past sales records of the automaker that developed a safety system. Then, for sensitivity analysis, we conduct multiple CBAs by adjusting the parameters of market saturation periods and the cumulative market penetration rate.
Subsequently, we apply the proposed framework to the frontal center curtain airbag, a new type of safety system. Airbags have been considered as safety systems that can reduce the severity of injuries by preventing direct crashes into the interior parts of the vehicle. Many previous studies have investigated the effectiveness of airbags according to their types [5,6,7,8]. However, these studies solely focused on the protection of the front-seat passengers.
On the other hand, the frontal center curtain airbag is designed to protect rear-seat passengers from direct collisions with various injury sources at the front side. As shown in Figure 1, this airbag is installed inside the headlining, and horizontally in the roof between the front and the rear seats. The frontal center curtain airbag is expected to be deployed between the front seat and the rear seat right after the deployment of the frontal airbag in the first row to prevent frontal crash, side crash, or roll-over accident.
We consider such distinctive features of the new safety system in the proposed CBA framework.
The remainder of the paper is organized as follows. Section 2 presents related studies and Section 3 describes the steps of the proposed framework. Section 4 analyzes the case of the frontal center curtain airbag. Finally, Section 5 concludes the study and discusses future research directions.

2. Literature Review

2.1. Cost–Benefit Analysis of Safety Systems

Many previous studies have attempted to investigate the socioeconomic effects of vehicle safety systems by CBA [9]. Previous studies on the effectiveness of safety systems are summarized in Table 1.
Most studies utilized traffic accident data and considered accident reduction as the benefit of safety systems. In terms of benefit, the expected injury reductions of safety systems are assessed by experts [10] based on previous studies [11] or on traffic accident data or test data.
Fildes et al. [10] conducted CBA for full-size driver airbags and facebags and compared their effectiveness. The authors considered harm reduction for front-seat occupants to analyze the effectiveness of these devices. Since airbags play an important role in protecting passengers from frontal impacts, the authors utilized frontal crash data from Australia. Similarly, Evans [12] studied the effectiveness of front airbags using the Fatality Analysis Reporting System (FARS) and NASS-CDS data. The author extracted two Maximum Abbreviated Injury Scale (MAIS) distributions for the accident cases in these databases: one where the front airbag was deployed and the other where it was not deployed. Thereafter, two injury risk probabilities are compared in terms of the MAIS, and the reduced MAIS is considered for the effectiveness of the airbags.
As seen in Table 1, CBA has been utilized to assess the effectiveness of not only airbags but also several safety systems. The COWI [11] performed a CBA on 18 different safety devices based on different market share scenarios. It estimated the effectiveness of 21 different safety devices across European countries, and each nation’s Gross Domestic Product (GDP) per capita was reflected to correct the differences in the economic wealth of the countries. Particularly, the casualty costs-unit rates are controlled according to the national GDP per capita.
In addition, Robinson et al. [13] conducted a CBA on an advanced emergency braking system (AEBS) and a lane-departure warning (LDW) system with data from the STATS 19 database. Their study suggested Benefit–Cost Ratio (BCR) values with regard to the cost and performance levels of these systems.
Similar to COWI [11], ASSESS [14] estimated the effectiveness of pre-crash safety systems across European countries with reflecting each nation’s GDP per capita to consider economic wealth of the countries. This study shows the comparisons of effectiveness for pre-crash safety systems across European countries in 2020 and 2030, with the estimation of fatality rates based on the ProgTrans World Transport Report 2010/2011 data on vehicle mileage and Eurostat data on fatalities during 2000–2009.
Although most of the CBA research recognized the necessity of forecasting steps to predict future beneficiaries, to the best of our knowledge, a proper forecasting model, such as the Holt model, to predict the market diffusion trends of new systems/products, has not yet been employed.
Furthermore, the CBA is based on many assumptions. For example, Mendivil et al. [15] investigated the benefits of installation of speed cameras on the beltways of Barcelona; they also performed sensitivity analysis by considering both the minimum and maximum number of people who avoided injury. The sensitivity analysis results suggest that the benefits range from 5.6 to 23.1 million Euros. In this context, a CBA framework should include sensitivity analysis with a range of parameters for not only estimating the effectiveness of new systems/technologies but also forecasting the number of potential beneficiaries.

2.2. Rear-Seat Passenger Safety Systems

Various studies have been conducted to analyze the effectiveness of airbags to reduce the risk of injury to passengers. However, most of these studies have focused on the injury levels of the front-seat passengers from the frontal or side airbags [5,6,7,8,16,17,18]. Moreover, studies on safety systems for rear-seat passengers have been conducted to analyze the benefits of seatbelts during accidents. For example, Evans [19] estimated the effectiveness of a rear-restraint system in the form of a lap belt, using a double-pair comparison method based on data from the Fatality Analysis Reporting System (FARS). The average effectiveness of the restraint system for two outboard rear-seating positions was estimated, showing that 18 ± 9% of fatalities can be reduced. In addition, Shimamura et al. [20] estimated the effectiveness of seatbelts for rear-seat passengers by applying a logistic regression to national accident data in Japan. The result shows that the number of rear-seat passengers killed or seriously injured can be reduced by 45% if seatbelts are worn. Moreover, a notable finding of the study is that wearing seatbelts has a positive influence, in that it reduces the risk of injury for not only rear-seat passengers but also frontal occupants. Kuppa et al. [21] examined NASS-CDS and FARS data, and engaged in controlled collisions using an experimental dummy. They confirmed the positive influence of seatbelts on reducing injury levels for rear-seat passengers, and suggested longer distances between rear and front seats to reduce the probability of injury to rear-seat passengers. Further, Zhu et al. [22] applied a matched-set cohort design to estimate the association of rear-seat safety belt use in car accidents. The authors employed FARS data between 2000 and 2004, and found that the mortality rate from traffic crashes of rear-seat passengers can be reduced by 55–75% when seatbelts are used.
Although numerous studies have been conducted on seatbelts, only a few studies have dealt with the benefits of airbag-type safety systems for rear-seat passengers. McCartt and Kyrychenko [23] studied the efficacy of side airbags in reducing driver death through a regression model, and concluded that head-protecting airbags and torso-only side airbags reduced driver death risk by 37% and 26%, respectively. Bohman et al. [24] investigated the effectiveness of thoracic side airbags for rear-seat occupants, and showed that thoracic side airbags reduce rib deflection of occupants.

3. Model: The Cost–Benefit Analysis Framework

Given that the frontal center airbag is a new safety system, evaluation of its socioeconomic effectiveness is necessary. The evaluation process is shown in Figure 2.
Step 1. Target data and distribution of MAIS from NASS-CDS
Step 1-1. Define functionality
First, we define the functionality of the safety system to draw the distribution of injury risk. Based on the specifications of the safety system, the target population and accident scenarios are identified.
Step 1-2. Extract target population
Thereafter, we define the target population, which refers to occupants who could be influenced by the function of the safety system in a group of accidents. Of many accident datasets available, we use the NASS-CDS dataset, which contains rich information about accident situations. From NASS-CDS, data on accidents that meet certain conditions related to the vehicle and the passenger, including the vehicle type, accident mode, seat position, injured body region, and injury source, are extracted.
Step 1-3. MAIS distribution by accident scenario
The accident scenario is analyzed through the combination of certain conditions, including the injured body region, accident mode, Barrier Equivalent Speed (BES), and passenger’s age. Since the effectiveness of the safety system may differ depending on the accident scenarios, investigating the distribution of injury risk according to these conditions is necessary. In this study, we present injury risk with the MAIS, similar to most previous works. The MAIS is an injury severity scale, which ranges from 1 (minor) to 6 (maximum). The data were obtained from the medical records of the accidents.
Step 2. Distribution of the MAIS from MADYMO
Since the CBA framework is proposed for a new safety system that has not yet been launched in the market, we compare the injury risks between the vehicles with safety systems installed and those without it. Thus, we simulate using the mathematical dynamical model program, MADYMO, which is useful to understand the situation of the vehicle accident [25]. The result of the simulation shows the probability of the MAIS level after the installation of the safety system.
Step 3. Forecast of the number of potential passengers
To estimate the socioeconomic benefits after launching the safety system, it is necessary to forecast the number of potential passengers who will benefit from the safety system installation. Therefore, in Step 3, we forecast the sales of vehicles having the safety system by using the Holt model.
Since a new type of safety system is developed by a specific automaker, the parameters of the Holt model, which are used to forecast future sales, can be defined based on the automaker’s past sales record: the total number of registered passenger vehicles at time t; the sales of passenger vehicles with the new safety system at time t; and the number of casualties, who are occupants of passenger vehicles with the safety system, at time t. These values are derived by applying the Holt model, which reflects the trends in the passenger vehicle sales and casualties. In this study, we omit the Holt model function.
Furthermore, we set the maximum penetration rate of the safety system to derive a realistic number of potential passengers who will benefit from the safety system installation, by reflecting the diffusion of the safety system. We considered two cases according to the time required to achieve the maximum penetration rate of the new safety system. Case A indicates the market penetration rate in 10 years, and Case B indicates that in 20 years. In addition, we assumed that the penetration rate of the new safety system has a tendency to gradually increase over time, following an S-curve. In order to derive information on the passengers and vehicles that would benefit from the installation of the new safety system, the penetration rate of safety systems at time t is calculated by applying a logistic function, using the initial and maximum penetration rates of the new safety system, as shown below:
penetration   rate ( t ) = exp ( α + β t ) 1 + exp ( α + β t )
where α is the intercept; and β is the growth ratio of the penetration rate with time.
The maximum penetration rate can be obtained from the technical and market experts in firms that manufacture safety systems, or related automobile firms. Finally, to forecast the number of casualties for the occupants of passenger vehicles with the new safety system, we apply the concept of cumulative market penetration rate to total casualty. The cumulative market penetration rate at time t indicates the proportion of passenger vehicles with the safety system among the entire registered passenger vehicles at time t. This can reflect the percentage of all passenger vehicles that benefit from a new safety system.
The cumulative market penetration rate at time t is derived by the following function:
CMP ( t ) = F S ( 1 ) + + F S ( t ) H ( t ) ,
where FS ( t ) ( = passenger   vehicle   sales ( t ) × penetration   rate ( t ) ) indicates the sales of passenger vehicles with the safety system at time t; t represents the elapsed years after releasing the safety system (t = 1, ..., 20); and H(t) denotes the total number of registered passenger vehicles at time t.
Step 4. Estimation of the benefit of the safety system
In this step, we calculate the benefit of the safety system based on the expected injury reduction by the installation of the safety system. We apply the MAIS distribution from Step 1 to the number of future casualties from Step 3, to predict the number of injured rear-seat passengers when the safety system is not installed (AS-IS). In a similar context, we apply the MAIS distribution from Step 2 to the forecasted number of casualties from accidents involving vehicles with the safety system (TO-BE).
The benefit for passengers (P) from the frontal center curtain airbag is measured by the reduced costs of traffic accidents, due to a decrease in the severity of the injuries incurred in crash accidents ( B e n e f i t   1 p ), and to the discounted car insurance from installing the safety system ( B e n e f i t   2 p ). B e n e f i t   1 p is derived from comparing the number of casualties in AS-IS with those of TO-BE. The benefit for passengers at time t and the T o t a l   B e n e f i t p are given as follows:
Benefit   1 p ( t ) = m = 1 3 i = 1 3 j = 1 3 k = 1 2 l = 1 6 [ N ( t ) × P T m i j k l × C T l ( t ) ]
m = 1 3 i = 1 3 j = 1 3 k = 1 2 l = 0 6 [ N ( t ) × P T m i j k l × C T l ( t ) ]
Benefit   2 p ( t ) = a = 1 t F S ( a ) × D P
T o t a l   B e n e f i t p = t = 1 20 [ Benefit   1 p ( t ) + Benefit   2 p ( t ) ] × ( 1 + r ) t
where N ( t ) is the number of forecast casualties who are occupants of a passenger vehicle with the safety system at time t; P T m i j k l is the probability of the injury severity level for the accident scenario, as defined by the accident mode (m), BES (i), injured body region (j), and age of the casualty (k); P T m i j k l is the probability of the injury severity level for the accident scenario, after the passenger uses the safety system; C T l ( t ) is the total cost associated with the MAIS class l, as a result of a traffic accident; D P is the discounted car insurance due to the presence of the safety system; and and r is the discount rate, considering the GDP growth rate.
Step 5. Estimation of the cost of the safety system
We consider the purchase costs of the safety system as the cost in the CBA process. The values for the total cost of traffic accidents ( T o t a l   C o s t s p ) are forecasted using the exponentially weighted moving average (EWMA), considering the GDP growth rate. The cost incurred by the passengers ( P ) at time t and the total costs are considered as follows:
C o s t p ( t ) = F S ( t ) × P A
T o t a l   C o s t s p = t = 1 20 C o s t p ( t ) × ( 1 + r ) t
where P A is the price of the safety system.
Step 6. Cost-benefit ratio and sensitivity analysis
Based on the results of the previous step, we calculate the benefit–cost ratio (BCR). The BCR is sensitive to certain variables; consequently, sensitivity analysis must be conducted with regard to the important variables [26,27].

4. Results: A Case Study of the Frontal Center Curtain Airbag

In this section, the proposed CBA procedure is applied to the case of the frontal center curtain airbag, which has not been launched in the market yet. In addition, we calculate the BCR of this new safety system considering the US market.
Step 1. Target data and distribution of the MAIS from NASS-CDS
Step 1-1. Define functionality
First, we define the functionality of the frontal center curtain airbag, which is intended to protect rear-seat passengers from direct collision injury sources. This airbag is installed between the front and rear seats to reduce the impact on rear-seat passengers. The detailed description is shown in Table 2.
The frontal center curtain airbag would be installed in passenger vehicles to protect rear-seat passengers. This safety system is expected to prevent or reduce the head and chest injuries from the collision with interior sources in vehicles, as shown in Table 2. The frontal center airbag would be effectively deployed for front crash, side crash and roll-over protection. Furthermore, the effectiveness of this safety system is expected to differ based on the age of passengers due to the size of the body.
Step 1-2. Extract target population
Based on the functionality of the frontal center curtain airbag, as shown in Table 2, we select the proper target population dataset from the NASS-CDS data. According to this functionality, the effectiveness of this safety system differs depending on the accident scenario. Therefore, we propose a total of 54 (3 × 3 × 3 × 2) scenarios based on the conditions at the time of the accident; there are three accident modes (front crash, side crash, and roll over), three injured body regions (head, chest, and both head and chest), three levels of BES (low, intermediate, and high), and two age groups (child and adult). Among all possible accident situations, these 54 accident scenarios are the cases in which the frontal center curtain airbag can have an effect on protecting the rear-seat passenger.
The BES presents the change in velocity due to the impact from the crash. The WinSmash software calculates this speed, considering the size, weight, and body type of the passenger vehicle. Thus, to measure the effectiveness of airbag-type safety systems, it is more appropriate to use BES, rather than travel speed, for the speed index. In this study, we define the speed interval based on the BES as follows: low (less than 17 kph); intermediate (between 17 and 33 kph); and high (over 33 kph). The speed intervals are set by the developing company of the safety system, according to its internal crash experimental criterion. The child condition refers to an age of less than 14, while the adult condition refers to an age equal to or greater than 14.
We extracted accident cases from NASS-CDS according to the above-mentioned 54 accident scenarios defined by the combination of various conditions. From 2003 to 2011, the number of passengers involved in our accident scenarios is 111,373, out of 2,697,054 total passengers. The number of injured passengers for the three accident modes is presented in Figure 3. These numbers are obtained by applying the Ratio Inflation Factor in order to adjust for the difference between the sample and actual accident data.
Step 1-3. MAIS distribution by accident scenario
With the extracted data in Step 1-2, we could derive the MAIS distribution according to the accident scenarios. The probability for an accident scenario is as follows:
P T m i j k l = N u m b e r   o f   c a s u a l t i e s   b e t w e e n   2003   a n d   2011 m i j k l m = 1 3 i = 1 3 j = 1 3 k = 1 2 l = 1 6 [ N u m b e r   o f   c a s u a l t i e s   b e t w e e n   2003   a n d   2011 m i j k l ]
where m is the accident mode, m ∈ {1: front crash; 2: side crash; 3: roll-over}; i is the BES, i ∈ {1: low; 2: intermediate; 3: high}; j is the injured body region, j ∈ {1: head; 2: chest; 3: head and chest}; and k is the age of the casualty, k ∈ {1: adult; 2: child}; and l is the MAIS level.
An example of the MAIS distribution is shown in Table 3. For instance, among all casualties reported in NASS-CDS, the ratio of a head-injured adult involved in a frontal-crash accident at a low speed is 0.0008. This probability is derived from the ratio of the number of injured passengers with head injuries at frontal crash accident in low BES (2157) to the total number of passengers (2,697,054). Furthermore, the head-injured adult occupant who experienced the front crash with low BES would have an MAIS score of 1 with a probability of 0.97848. All distributions for each accident scenario are shown in Appendix A. This probability distribution is employed to determine the effectiveness of the frontal center curtain airbag in Step 4 in order to estimate the benefits of the safety system.
Step 2. Distribution of the MAIS from MADYMO
As mentioned previously, MADYMO is a simulation program that is useful for understanding the conditions of the vehicle and the passenger [25]. This program simulates multi-body dynamics through a mathematical dynamical model. From MADYMO, we obtain the Head Injury Criterion (HIC)—a predictor of the risk of head injury, developed from cadaver studies—and Chest G (or chest acceleration)—an index for chest injury risk, measured by g at the center of gravity of the thoracic region. Both HIC and Chest G are most widely used for measuring a safety system’s effectiveness tests.
As the HIC and Chest G values can be different, depending on the weight or height of the passengers, we assess this difference by using both adult-size and child-size unbelted dummies. These dummies were located in outboard seats, according to Federal Motor Vehicle Safety Standards (FMVSS) 208 specifications, and the simulation experiments were carried out at 16, 32, and 40 kph, for different BES levels—low, intermediate, and high, respectively. In addition, the different crash directions, which present the accident modes, are simulated. Thus, we can obtain HIC and Chest G values for each accident scenario using the result of the MADYMO simulation. Next, we convert the HIC and Chest G values to MAIS levels for head and chest, respectively. We employed the conversion formulae from the expanded Prasad/Mertz curves for head MAIS, and used the data for 55 cadaver sled tests, provided by the National Highway Traffic Safety Administration (NHTSA), for chest MAIS.
By comparing the casualties between the MAIS distribution from NASS-CDS and those from MADYMO, we are able to identify the effectiveness of the safety system in terms of injury reduction.
Table 4 shows these results. These probabilities will be used to determine the effectiveness of the frontal center curtain airbag in the future. For example, after the installation of the frontal center curtain airbag, the probability of a Child will get head injury at the AIS 1 level from a front crash with intermediate speed is 0.02. All distributions for each accident scenario with the frontal center curtain airbag are shown in Appendix B.
Step 3. Forecasting
We assumed the initial and maximum penetration rates (5.0% and 20.7%, respectively) of the frontal center curtain airbag. The maximum penetration rate was obtained from the technical and market experts at H* Motors. Moreover, the front safety system can be diffused differently according to the consumer’s preference; we set two different cases according to the market’s saturation periods: 10 years (Case A) and 20 years (Case B).
In the Holt model, the smoothing parameters for updating the local mean level ( ω 1 ) and local trend ( ω 2 ) are set up to minimize Mean Absolute Percentage Error (MAPE), and these values are displayed in Appendix C. All MAPE values are less than 10%, which indicate that the forecasting is reliable.
The total number of registered passenger vehicles, at time t ( H ( t ) ); the sales of passenger vehicles with frontal center curtain airbag, at time t ( FS ( t ) ); and the number of casualties who are occupants of passenger vehicles with frontal center curtain airbag, at time t ( N ( t ) ), in the US, are shown in Table 5.
Step 4. Estimation of the benefit of the safety system
To obtain the benefit of injury reduction by installing the frontal center curtain airbag, we apply each probability of the injury severity, from Steps 1 and 2, to the N ( t ) from Step 3. By comparing the number of casualties in both cases, we consider their difference as the effectiveness of the safety system. Table 6 presents the predicted number of injured passengers, with and without the safety system, in the US market. By using the frontal center curtain airbag, the number of casualties with MAIS level 3 or above reduced by 87.4%.
To transform injury reduction into a monetary benefit, we use the cost according to MAIS level l   ( C T l ) , from an NHTSA report in 2000. We estimate C T l for 2015 using EWMA with the GDP growth rate in the US from 2000 to 2012. The weight value is set to 0.7 and, consequently, the discount rate, considering the GDP growth rate ( r ), is 2.01%. The annual GDP growth data were obtained from the World Bank. Table 7 presents the C T l values of 2000 along with the estimated values for 2015.
This study sets the discounted car insurance benefit ( DP ) value as $22. Moreover, the information related to the DP (per vehicle in one year) is obtained from the websites of car insurance companies.
Step 5. Estimation of the cost of the safety system
The cost of the frontal center curtain airbag ( PA ) is $600; this value was obtained from a car manufacturer, and is derived by considering the cost of R&D, commercialization, and production of the airbag.
Step 6. Benefit–cost ratio and sensitivity analysis
Based on the estimated benefit and cost of frontal center curtain airbag, we calculate the BCR. These results are shown in Table 8.
The BCR is sensitive to certain variables; consequently, a sensitivity analysis must be conducted with regard to the important variables [15]. We examine the BCR values for the US, as well as how they are affected when the initial market penetration rate, maximum market penetration rate, and price of the safety system are changed. The price of the frontal center curtain airbag is high, and most customers would be sensitive to price. Accordingly, we perform a sensitivity analysis of the price of the safety system. The results are shown in Figure 4 and Appendix D. When the product penetrates the target market rapidly—high initial and maximum market penetration rates—the BCR of the frontal center curtain airbag increases. Conversely, the BCR decreases when the price of the frontal center curtain airbag increases. Thus, firms need to consider higher penetration rates and lower price strategies.

5. Discussion

This study developed a CBA framework, including a forecasting model, to a new type of safety system that has not been applied in a vehicle so far. The established literature has attempted to estimate the potential benefits and costs of safety system installation. However, the inclusion of a forecasting method in a CBA framework has not been suggested so far. Furthermore, we performed sensitivity analyses in order to adjust to a wide variety of market situations. Our results, especially those focusing on the socioeconomic effects, can help in the commercialization decision and eventually encourage sustainable automotive innovation.
We applied the proposed CBA framework to frontal center curtain airbag, a new type of airbag developed to prevent collisions between front-and rear-seat passengers by separating the two areas with an airbag. The BCR turned out to be lower than 1, but exceeded the expectation of the developer in terms of societal contribution. This is because unlike commercial purposed product/service which is focused to be economically sustainable, a safety system is critical in risk management to reach sustainable mobility society. In this context, to maximize the effectiveness of the frontal center curtain airbag, we proposed a high rate of initial market penetration and a relatively low price for the frontal center curtain airbag.
It would be interesting to apply the suggested procedure to estimate the effect of the safety system in different markets by considering each market’s characteristics, when detailed information concerning traffic accidents by country is obtained. Future research must consider this possibility.

Acknowledgments

This research was partly supported by the Hyundai Motor Company. This work was supported by the National Research Foundation of Korea (NRF) grant funded by the Korea government (MSIP) (2016R1A2A1A05005270).

Author Contributions

Bo Kyeong Lee reviewed the related literature, collected data, conducted the analysis, and wrote the manuscript. Eun Jin Han conducted the analysis, interpreted the results, and wrote the manuscript. So Young Sohn implemented the research, designed the study, outlined the methodology, and helped to draft the paper. Yong Sun Kim, Jong Young Yoon, and Jun Yeol Choi provided the results of MADYMO simulation for frontal center curtain airbag along with the necessary background information for the related data extract from NASS/CDS.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A. Probability Distributions of Injury Risk without the Frontal Center Curtain Airbag

Table A1. Frontal crash case.
Table A1. Frontal crash case.
FrontBESAgeProbabilityMAIS 1MAIS 2MAIS 3MAIS 4MAIS 5MAIS 6
HeadLowAdult0.00080.9784800.0056950.015825000
Child0.0007210.7071480.2928520000
IntermediateAdult0.0040810.8686950.0961610.0067770.0246340.0037330
Child0.0015670.858960.0084540.0151260.1174600
HighAdult0.0008490.6433030.1282930.0178630.2068670.0036750
Child0.0007060.9653940.0155620.01765900.0013850
ChestLowAdult0.0028560.9228220.0517230.025455000
Child0.0021170.8796720.10503400.01529400
IntermediateAdult0.0115590.8695210.115890.0130110.00157800
Child0.0043460.9329440.0350680.031988000
HighAdult0.0014640.6488190.0619840.0761120.1731420.0216270.018316
Child0.0010370.7515640.1247950.123641000
Head & ChestLowAdult0.0000553100000
Child0.000291100000
IntermediateAdult0.000203000000
Child0.0007590.9142240.0236960.062080000
HighAdult0.000214100000
Child0.0000767000000
Table A2. Side crash case.
Table A2. Side crash case.
SideBESAgeProbabilityMAIS 1MAIS 2MAIS 3MAIS 4MAIS 5MAIS 6
HeadLowAdult0.0000993000000
Child0.00000765000000
IntermediateAdult0.00032000000
Child0.000584000000
HighAdult0.0001440.5853610.12492100.1395660.1293010.02085
Child0.0001150.8817700.08644700.03178300
ChestLowAdult0.00001210.2524400.2524400.495120000
Child0.000199100000
IntermediateAdult0.0004460.6130550.0828240.0134310.2906900
Child0.0004690.6511760.1450950.203728000
HighAdult0.0001820.2141950.0104780.4681650.1280010.1791610
Child0.000330.8680840.0326210.099294000
Head & ChestLowAdult0.000575100000
Child0000000
IntermediateAdult0.0000524100000
Child0.0000119100000
HighAdult0.0000950.98011300.019887000
Child0.00005730.79099500.0474910.16151500
Table A3. Roll-over case.
Table A3. Roll-over case.
Roll-overBESAgeProbabilityMAIS 1MAIS 2MAIS 3MAIS 4MAIS 5MAIS 6
HeadLowAdult0.0001520.799551000.20044900
Child0.0000118100000
IntermediateAdult0.000018010000
Child0.0012870.99588400000.004116
HighAdult0.0003060.95630800.011917000.031775
Child0.00000805001000
ChestLowAdult0.0000484001000
Child0000000
IntermediateAdult0.0013210.8942550.0881800.017566000
Child0.000226100000
HighAdult0.0002680.8469420.0531650.099893000
Child0000000
Head & ChestLowAdult0000000
Child0000000
IntermediateAdult0.000244100000
Child0.00000362100000
HighAdult00.9762090.0237910000
Child0100000
Notes: BES = Barrier Equivalent Speed, MAIS = Maximum Abbreviated Injury Scale.

Appendix B

Table A4. Probability of Injury Risk with the Frontal Center Curtain Airbag.
Table A4. Probability of Injury Risk with the Frontal Center Curtain Airbag.
Front crash for head injuryBESAgeMAIS 0MAIS 1MAIS 2MAIS 3MAIS 4MAIS 5MAIS 6
LowAdult1
Child1
IntermediateAdult0.930.050.010.01
Child0.970.020.01
HighAdult0.890.060.030.02
Child0.460.340.130.060.01
Front crash for chest injuryLowAdult1
Child1
IntermediateAdult0.470.53
Child1
HighAdult0.390.61
Child1
Front crash for head and chest injuryLowAdult0.70.3
Child1
IntermediateAdult0.470.53
Child1
HighAdult1
Child0.440.320.180.06
Side crash for head injuryBESAgeMAIS 0MAIS1MAIS 2MAIS 3MAIS 4MAIS 5MAIS 6
LowAdult1
Child1
IntermediateAdult0.930.050.010.01
Child0.970.020.01
HighAdult0.890.060.030.02
Child0.460.340.130.060.01
Side crash for chest injuryLowAdult0.70.3
Child1
IntermediateAdult1
Child1
HighAdult0.390.320.210.08
Child0.440.320.180.06
Side crash for head and chest injuryLowAdult1
Child1
IntermediateAdult0.470.53
Child1
HighAdult1
Child0.440.320.180.06
Roll over for head injuryBESAgeMAIS 0MAIS1MAIS 2MAIS 3MAIS 4MAIS 5MAIS 6
LowAdult1
Child1
IntermediateAdult0.930.050.010.01
Child0.970.020.01
HighAdult0.890.060.030.02
Child0.460.340.130.060.01
Roll over for Chest injuryLowAdult0.70.3
Child1
IntermediateAdult0.470.53
Child1
HighAdult1
Child1
Roll over for head and chest injuryLowAdult1
Child1
IntermediateAdult1
Child1
HighAdult1
Child1

Appendix C

Table A5. The Smoothing Parameters and MAPE.
Table A5. The Smoothing Parameters and MAPE.
The Registered VehicleVehicle SalesCasualty
w10.910.950.95
w20.950.050.68
MAPE0.71%6.67%2.67%

Appendix D

Table A6. Sensitivity Analysis.
Table A6. Sensitivity Analysis.
VariableChangeScenario 1 (t = 10)Scenario 2 (t = 20)
Initial market penetration rate1%0.4830.396
3%0.5190.474
5%0.5420.514
7%0.5600.542
9%0.5750.563
Maximum market penetration rate16.70%0.5530.532
18.70%0.5470.523
20.70%0.5420.514
22.70%0.5370.507
24.70%0.5340.500
Price of front center airbag$5000.6500.617
$5500.5910.561
$6000.5420.514
$6500.5000.475

References

  1. Jones-Lee, M.; Aven, T. The role of social cost–benefit analysis in societal decision-making under large uncertainties with application to robbery at a cash depot. Reliab. Eng. Syst. Saf. 2009, 94, 1954–1961. [Google Scholar] [CrossRef]
  2. Jeon, J.; Sohn, S.Y. Product failure pattern analysis from warranty data using association rule and Weibull regression analysis: A case study. Reliab. Eng. Syst. Saf. 2015, 133, 176–183. [Google Scholar] [CrossRef]
  3. Jung, C.S.; Sohn, S.Y. Investigating the relationship between ammunition stockpile information and subsequent performance. Reliab. Eng. Syst. Saf. 2010, 95, 426–430. [Google Scholar] [CrossRef]
  4. Nilsen, P.; Hudson, D.; Lindqvist, K. Economic analysis of injury prevention–applying results and methodologies from cost-of-injury studies. Int. J. Inj. Control Saf. Promot. 2006, 13, 7–13. [Google Scholar] [CrossRef] [PubMed]
  5. Deery, H.A.; Morris, A.P.; Fildes, B.N.; Newstead, S.V. Airbag technology in Australian passenger cars: Preliminary results from real world crash investigations. Traffic Inj. Prev. 1999, 1, 121–128. [Google Scholar] [CrossRef]
  6. Segui-Gomez, M. Driver Airbag Effectiveness by Severity of the Crash. Am. J. Public Health. 2000, 90, 1575–1581. [Google Scholar] [PubMed]
  7. Pintar, F.A.; Yoganandan, N.; Gennarelli, T.A. Airbag effectiveness on brain trauma in frontal crashes. Assoc. Adv. Automot. Med. 2000, 44, 149–170. [Google Scholar]
  8. Zador, P.L.; Ciccone, M.A. Automobile Driver Fatalities in Frontal Impacts: Air Bags Compared with Manual Belts. Am. J. Public Health. 1993, 83, 661–666. [Google Scholar] [CrossRef] [PubMed]
  9. Aven, T.; Kørte, J. On the use of risk and decision analysis to support decision-making. Reliab. Eng. Syst. Saf. 2003, 79, 289–299. [Google Scholar] [CrossRef]
  10. Fildes, B.N.; Cameron, M.H.; Vulcan, A.P.; Digges, K.H.; Taylor, D. Airbag and facebag benefits and costs. Accid. Anal. Prev. 1994, 26, 339–346. [Google Scholar] [CrossRef]
  11. COWI. Cost Benefit assessment and prioritization of vehicle safety technologies. In European Commission Directorate General Energy and Transport; Final Report; European Commission: Brussels, Belgium, 2006. [Google Scholar]
  12. Evans, L. Airbag Benefits, Airbag Costs; SAE Technical Paper 2004-01-0840; SAE International: Washington, DC, USA, 2004. [Google Scholar] [CrossRef]
  13. Robinson, B.; Hulshof, W.; Cookson, R.; Cuerden, R.; Hutchins, R.; Delmonte, E. Cost Benefit Evaluation of Advanced Primary Safety Systems: Final Report; No. PPR 586; Transport Research Laboratory: Wokingham, UK, 2011. [Google Scholar]
  14. ASSESS (Assessment of Vehicle Safety System). Socio-economic impact of safety systems. In European Commission—DG RTD.TRANSPORT—SST 2008.4.1.1: Safety and Security by Design GA No. 233942; European Commission: Brussels, Belgium, 2008. [Google Scholar]
  15. Mendivil, J.; García-Altés, A.; Pérez, K.; Marí-Dell’Olmo, M.; Tobías, A. Speed cameras in an urban setting: A cost–benefit analysis. Inj. Prev. 2012, 18, 75–80. [Google Scholar] [CrossRef] [PubMed]
  16. Kent, R.; Viano, D.C.; Crandall, J. The Field of Performance of Frontal Airbags: A Review of the Literature. Traffic Inj. Prev. 2005, 6, 1–23. [Google Scholar] [CrossRef] [PubMed]
  17. Ferguson, S.A.; Schneider, L.W. An overview of frontal air bag performance with changes in frontal crash-test requirements: Findings of the blue ribbon panel for the evaluation of advanced technology air bags. Traffic Inj. Prev. 2008, 9, 421–431. [Google Scholar] [CrossRef] [PubMed]
  18. Gabauer, D.; Gabler, H. The effects of airbags and seatbelts on occupant injury in longitudinal barrier crashes. J. Saf. Res. 2010, 41, 9–15. [Google Scholar] [CrossRef] [PubMed]
  19. Evans, L. Rear Seat Restraint System Effectiveness in Preventing Fatalities. Accid. Anal. Prev. 1988, 20, 129–136. [Google Scholar] [CrossRef]
  20. Shimamura, M.; Yamazaki, M.; Fujita, G. Method to Evaluate the Effect of Safety Belt Use by Rear-seat passengers on the Injury Severity of Front-seat occupants. Accid. Anal. Prev. 2005, 37, 5–17. [Google Scholar] [CrossRef] [PubMed]
  21. Kuppa, S.; Saunders, J.; Fessahaie, O. Rear-seat occupant protection in front crashes. In Proceedings of the 19th International Technical Conference on Enhanced Safety of Vehicles (ESV), Washington, DC, USA, 6–9 June 2005. [Google Scholar]
  22. Zhu, M.; Cummings, P.; Chu, H.; Cook, L.J. Association of rear seat safety belt use with death in a traffic crash: A matched cohort study. Inj. Prev. 2007, 13, 183–185. [Google Scholar] [CrossRef] [PubMed]
  23. McCartt, A.T.; Kyrychenko, S.Y. Efficacy of Side Airbags in Reducing Driver Deaths in Driver-Side Car and SUV Collisions. Traffic Inj. Prev. 2007, 8, 162–170. [Google Scholar] [CrossRef] [PubMed]
  24. Bohman, K.; Rosén, E.; Sunnevang, C.; Boström, O. Rear-seat occupant Thorax Protection in Near Side Impacts. Ann. Adv. Automot. Med. Annu. Sci. Conf. 2009, 53, 3–12. [Google Scholar]
  25. Rueda, F.; Gilchrist, M.D. Comparative Multibody Dynamics Analysis of Falls from Playground Climbing Frames. Forensic Sci. Int. 2009, 191, 52–57. [Google Scholar] [CrossRef] [PubMed]
  26. Wu, T.; Zhao, H.; Ou, X. Vehicle ownership analysis based on GDP per capita in China: 1963–2050. Sustainability 2014, 6, 4877–4899. [Google Scholar] [CrossRef]
  27. Kim, Y.S.; Han, E.J.; Sohn, S.Y. Demand Forecasting for Heavy-Duty Diesel Engines Considering Emission Regulations. Sustainability 2017, 9, 166. [Google Scholar] [CrossRef]
Figure 1. Concept of frontal center curtain airbag.
Figure 1. Concept of frontal center curtain airbag.
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Figure 2. Economic evaluation process for a safety system.
Figure 2. Economic evaluation process for a safety system.
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Figure 3. The number of injured passengers for each accident mode.
Figure 3. The number of injured passengers for each accident mode.
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Figure 4. Sensitivity analysis.
Figure 4. Sensitivity analysis.
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Table 1. Summary of previous studies on the effectiveness of safety systems.
Table 1. Summary of previous studies on the effectiveness of safety systems.
Fildes et al. [10]Safety systemFull size Airbag, Facebag
DataAustralian database (Crashed Vehicle File)
BenefitHarm reduction (The expected injury reductions of facebag is assessed by experts)
CostAirbag and facebag costs
BCRFull size Airbag = 1.17, Facebag (Maximum) = 0.98, Facebag (Intermediate) = 0.69, Facebag (Minimum) = 0.58
CharacteristicThe different benefit scenarios for facebag (Maximum, Intermediate, Minimum)
COWI [11]Safety system21 vehicle safety technologies
DataEU CARE database
BenefitA reduced number of fatalities/injuries × Accident costs
CostThe installment costs
BCR0.04–8.2
CharacteristicPromotion (Do-nothing, Do-something scenarios)
Evans [12]Safety systemFrontal airbag
DataFatality Analysis Reporting System (FARS) data, NASS-CDS
BenefitThe net annual benefit (Injury reduction - replacement costs)
CostThe initial total purchase costs ÷ a 10 year life of the car
BCRFor drivers, net annual benefit = $1.14 billion, net annual cost = $3.00 billion
For passengers, net annual benefit = -$0.13 billion, net annual cost = $2.42 billion
Characteristic-
Robinson et al. [13]Safety systemAEBS (Advanced Emergency Brake Systems), LDWS (Lane Departure Warning Systems), Youth key
DataSTATS19 data
BenefitAnnual casualty savings
CostSystem costs
BCRAEBS for passenger = 0.07–2.78, AEBS for pedestrian = 0.19–1.04, LDWS = 0.25–2.12, Youth key = 0.69–11.2
CharacteristicReductions in serious and slight casualties
ASSESS [14]Safety systemPre-crash safety system (Emergency Braking System)
DataNASS CDS, eIMPACT's ProgTrans data
BenefitAnnual system cost × Fleet penetration rate × Car fleet
CostBreak even costs
BCR-
CharacteristicMarket penetration, Accident trend
Table 2. Functionality of the frontal center curtain airbag.
Table 2. Functionality of the frontal center curtain airbag.
ConditionDescription
Vehicle typePassenger vehicle (Sedan, Hatchback, Station wagon, Auto base panel, Large limousine, Compact utility, or Large utility)
Seat positionRear seat (Passengers in second row rear seat)
Injured body regionHead (face or head)
Chest (chest, abdomen, back, arm, forearm, shoulder, wrist/hand, or upper limbs)
Injury sourceSeat, A-pillar, B-pillar, C-pillar, seatbelt, CRS, roof, windshield, side window glass, floor, center console, C/PAD, door trim, interior trim, outside part, exterior, and cargo in vehicle
Accident modeFront crash, side crash, and roll over
AgeAdult/ChildAdult (Over 14 years old), Child (Under 14 years old)
Deployment ConditionFront crashWhen one of the airbags located at the driver and front passenger seats is deployed
Side crashWhen one of the airbags located at the driver and front passenger seats is deployed
Roll overMore than one quarter roll
Table 3. Probability distribution of injury risk without the frontal center curtain airbag.
Table 3. Probability distribution of injury risk without the frontal center curtain airbag.
Front crash for head injuriesBESAgeProbabilityMAIS 1MAIS 2MAIS 3MAIS 4MAIS 5MAIS 6
LowAdult0.00080.978480.0056950.015825000
Child0.0007210.7071480.2928520000
IntermediateAdult0.0040810.8686950.0961610.0067770.0246340.0037330
Child0.0015670.858960.0084540.0151260.1174600
HighAdult0.0008490.6433030.1282930.0178630.2068670.0036750
Child0.0007060.9653940.0155620.01765900.0013850
Notes: BES = Barrier Equivalent Speed, MAIS = Maximum Abbreviated Injury Scale.
Table 4. Probabilities of injury risk with the frontal center curtain airbag.
Table 4. Probabilities of injury risk with the frontal center curtain airbag.
Front crash for Head injuriesBESAgeAIS 0AIS 1AIS 2AIS 3AIS 4AIS 5AIS 6
LowAdult1
Child1
IntermediateAdult0.930.050.010.01
Child0.970.020.01
HighAdult0.890.060.030.02
Child0.460.340.130.060.01
Notes: BES = Barrier Equivalent Speed, AIS = Abbreviated Injury Scale.
Table 5. H ( t ) , FS ( t ) , and N ( t ) in the US.
Table 5. H ( t ) , FS ( t ) , and N ( t ) in the US.
t H ( t ) F S ( t ) N ( t )
Case A (10 years)Case B (20 years)Case A (10 years)Case B (20 years)
1130,434,284358,293358,29333583358
2129,434,829424,536388,64073507013
3128,435,374502,138421,40412,08410,987
4127,435,919592,702456,74917,68815,309
5126,436,463697,924494,85024,30420,005
6125,437,008819,549535,88432,09425,105
7124,437,553959,301580,03541,23630,643
8123,438,0981,118,795627,49451,92436,651
9122,438,6431,299,412678,45364,36843,166
10121,439,1871,502,169733,10778,79150,227
11120,439,7321,504,262791,65193,29057,873
12119,440,2771,506,355854,279107,86566,149
13118,440,8221,508,448921,182122,52075,099
14117,441,3661,510,541992,543137,25584,770
15116,441,9111,512,6341,068,538152,07295,213
16115,442,4561,514,7271,149,329166,974106,479
17114,443,0011,516,8201,235,064181,960118,621
18113,443,5461,518,9131,325,872197,035131,695
19112,444,0901,521,0061,421,857212,199145,759
20111,444,6351,523,0991,523,099227,454160,871
Notes: H ( t ) = number of registered passenger vehicles, at time t; FS ( t ) = sales of luxury passenger vehicles with frontal center curtain airbag, at time t; and N ( t ) = number of casualties who are occupants of luxury passenger vehicles with frontal center curtain airbag, at time t.
Table 6. Number of casualties with and without the safety system.
Table 6. Number of casualties with and without the safety system.
MAISCase A (10 years)Case B (20 years)
Casualties without the Safety SystemCasualties with the Safety SystemCasualties without the Safety SystemCasualties with the Safety System
0 and 169,17163,13346,01141,994
2611216,076406610,693
320674671,375310
42003981,33265
533302220
6870580
Total79,77479,77453,06353,063
Notes: MAIS = Maximum Abbreviated Injury Scale.
Table 7. The costs of traffic accidents in the US.
Table 7. The costs of traffic accidents in the US.
Classification C T l (2000) C T l (2015)
Injury Severity ( l )
MAIS 0$1962$2644
MAIS 1$10,562$14,236
MAIS 2$66,820$90,063
MAIS 3$186,097$250,831
MAIS 4$348,133$469,231
MAIS 5$1,096,161$1,477,459
MAIS 6$977,208$1,317,129
Notes: C T l = cost according to MAIS level l .
Table 8. Benefit–cost ratio for the US by scenario.
Table 8. Benefit–cost ratio for the US by scenario.
Case A (10 years)Case B (20 years)
Benefit$5,973,979,316$3,974,155,672
Cost$11,027,777,826$7,727,474,206
BCR0.5420.514
Notes: BCR = benefit–cost ratio.

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MDPI and ACS Style

Lee, B.K.; Han, E.J.; Sohn, S.Y.; Kim, Y.S.; Yoon, J.Y.; Choi, J.Y. A Cost–Benefit Analysis to Assess the Effectiveness of Frontal Center Curtain Airbag. Sustainability 2017, 9, 1745. https://doi.org/10.3390/su9101745

AMA Style

Lee BK, Han EJ, Sohn SY, Kim YS, Yoon JY, Choi JY. A Cost–Benefit Analysis to Assess the Effectiveness of Frontal Center Curtain Airbag. Sustainability. 2017; 9(10):1745. https://doi.org/10.3390/su9101745

Chicago/Turabian Style

Lee, Bo Kyeong, Eun Jin Han, So Young Sohn, Yong Sun Kim, Jong Young Yoon, and Jun Yeol Choi. 2017. "A Cost–Benefit Analysis to Assess the Effectiveness of Frontal Center Curtain Airbag" Sustainability 9, no. 10: 1745. https://doi.org/10.3390/su9101745

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