Factors Affecting the Acceptance and Willingness-to-Pay of End-Users: A Survey Analysis on Automated Vehicles

Jiang, Xiaobei; Yu, Wenlin; Li, Wenjie; Guo, Jiawen; Chen, Xizheng; Guo, Hongwei; Wang, Wuhong; Chen, Tao

doi:10.3390/su132313272

Open AccessArticle

Factors Affecting the Acceptance and Willingness-to-Pay of End-Users: A Survey Analysis on Automated Vehicles

by

Xiaobei Jiang

¹,

Wenlin Yu

¹,

Wenjie Li

¹,

Jiawen Guo

¹,

Xizheng Chen

¹,

Hongwei Guo

¹,

Wuhong Wang

¹ and

Tao Chen

^2,*

¹

School of Mechanical Engineering, Beijing Institute of Technology, Beijing 100081, China

²

Key Laboratory of Transportation Industry of Automotive Transportation Safety Enhancement Technology, Chang’an University, Xi’an 710064, China

^*

Author to whom correspondence should be addressed.

Sustainability 2021, 13(23), 13272; https://doi.org/10.3390/su132313272

Submission received: 4 November 2021 / Revised: 23 November 2021 / Accepted: 24 November 2021 / Published: 30 November 2021

(This article belongs to the Special Issue Mobility Sustainability: Ecological, Smart and Connected Transportation Systems)

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Abstract

:

The emergence of automated vehicles (AVs) is expected to have a huge impact on traffic safety and environmental improvement. In order to promote the sustainable development of AVs, it is urgent to study the public’s acceptance of and willingness-to-pay for automated vehicles and their influencing factors. Based on a questionnaire survey and descriptive research, this paper investigates the public’s general views on AVs. A psychological model considering technical trust (TT), perceived benefit (PB), perceived risk (PR), and perceived ease of use (PU) was constructed to study the factors that influence the public’s acceptance of and willingness-to-pay for AVs. Logistic regression models based on demographic factors such as monthly income (MI) and driving experience (DE) and psychological factors were established to predict end-users’ acceptance and willingness-to-pay. The accuracy of the two models is 93.2% and 87.9%, respectively. Based on the results, the following policies can be put forward to promote the development of AVs: (1) more information to enhance TT; (2) pricing and easy maintenance based on PU; (3) education and training based on TT and PB; and (4) personalized sales based on DE and MI.

Keywords:

automated vehicles; acceptance; willingness-to-pay; technical trust; perceived benefit; perceived risk; perceived ease of use; monthly income; driving experience

1. Introduction

Sustainable transport plays a leading role in economic and social development. Automated vehicles are prime movers in transport development. According to the National Motor Vehicle Crash Causation Survey (NMVCCS), more than 94% of traffic accidents are caused by human driving errors. The main reasons for driving errors are the driver’s limitations and the uncontrollability of information processing [1]. In order to reduce drivers’ mistakes and improve road traffic safety, automated driving has become the focus of many researchers [2,3,4,5].

An automated vehicle is a vehicle that can sense external stimuli and complete certain specific driving tasks without manual operation [1]. According to the Society of Automotive Engineers (SAE)’s taxonomy for vehicle automation, vehicles with conditional automation (Level 3), high automation (Level 4), and full automation (Level 5) can work in the “self-driving” (“automated driving”) mode.

The emergence of automated vehicles will have a huge impact on society, the economy, and the environment. First, automated vehicles no longer need to be controlled by the driver, avoiding operating errors and, thereby, reducing the occurrence of traffic accidents [6]. Second, automated vehicles are expected to reduce environmental pollution by optimizing the traffic flow and improving fuel economy [6]. Third, automated vehicles can be used to reduce users’ commuting time, free up users’ time in the car, and improve the mobility of some people (the elderly, children, and those without a driver’s license) [7]. Finally, automated vehicles may transform car ownership into an on-demand service and shift the design focus of the automotive industry from optimizing the driving experience to enjoying it [8].

However, in the past few years, automated vehicle accidents, including fatal accidents, have been reported. Dozens of news items and studies show that automated vehicles are distrusted by drivers. Users can benefit from AVs depending on their acceptance [9,10,11,12]. Some studies have investigated the interaction between drivers and automated vehicles, and the results show that drivers do not fully trust in AVs, and automated driving cannot perfectly replace drivers [13]. Therefore, it is particularly important to study the public’s acceptance when introducing new technology into a growing market. The promotion of new technology is a daunting challenge; many products have failed before they are put on the market because they fail to meet the needs of users and are not accepted by users [14,15]. The main obstacles to the application of automated vehicles include not only technical problems, but also people’s trust and acceptance [16].

Academic and professional researchers, private enterprises, and auto-related websites have conducted surveys to understand public opinions about AV technologies and related aspects. In this study, we performed a detailed literature analysis, focusing on acceptance and willingness-to-pay.

Interviews and questionnaires have been used to study users’ acceptance of AVs. Most of the respondents were positive about automated driving [17]. Men are more receptive than women [18]. Research findings show that age, location, and education may influence users’ acceptance; a well-educated young man living in an urban area is more willing to accept automated vehicles [19]. The influence of local traffic safety on people’s acceptance of automated vehicles has also been investigated [20]. Moreover, an on-road vehicle experiment has been conducted, and the results showed that 64% of the study’s participants had a worse sense of safety in automated buses, especially women [21]. However, the survey was restarted, and the results showed that most of the respondents felt more secure [22]. This shows that advances in technology have made people more willing to accept automated vehicles.

People’s willingness-to-pay for automated vehicles is also a research hotspot. Some studies have explored the influence of demographic factors on willingness-to-pay. Significant differences can be found among different countries [10]. Performance expectations, pay expectations, and community have a positive impact on willingness-to-pay [23]. Personal innovation may reinforce this positive influence and persons with more crash experience are more willing to pay for AVs. The public’s willingness-to-pay at different automation levels has also been studied. The higher the automation level, the more significant the increase in the respondents’ willingness-to-pay. Most respondents are only willing to pay for fully automated vehicles [24,25]. A structural model has been proposed to analyze the influence of psychological factors on willingness-to-pay. Trust and perceived benefit are important and positive factors, while perceived risk is a negative factor [26]. The price of AVs has been found to be a significant factor based on the ordered logit model [27].

Quantitative analysis and model applications of automated vehicles still need more work. In the existing models, the main influencing factors are demographic, psychological, and physiological attributes; for example, unified conclusions have been reached on perception, trust, and country factors. However, an in-depth discussion of travel-related and vehicle-related attributes is still lacking.

In order to determine the key factors affecting users’ acceptance of and willingness-to-pay for automated vehicles, this study used a survey to establish psychological and logical regression models. The results of this work could hopefully provide a theoretical basis for and data support to policy-makers and automobile manufacturers.

2. Methodology

2.1. Data Collection

This study focused on highly automated vehicles and used the SP survey method, which is very beneficial for researching respondents’ choices and intentions regarding things not currently available.

The questionnaire consists of two parts: (1) respondents’ demographic information; and (2) respondents’ psychological feelings about AVs. The former includes gender, age, education, income, and driving experience. The latter include technical trust, perceived benefits, perceived ease of use, perceived risk, and travelers’ acceptance of and willingness-to-pay for AVs. A Likert scale was used to measure the respondents’ understanding of the questions. The options for the income setting were based on China’s taxation level. Table 1 shows items and sources related to highly automated vehicles.

2.2. Survey Participants

The results of this study come from a questionnaire survey of 294 respondents. The gender, age, education, income, and driving experience of the interviewees were analyzed, and the results are shown in Table 2.

There are slightly more men than women among the respondents, of which men account for 56.12% and women account for 43.88%. A total of 84.35% of the respondents are under 40 years old, and the proportion below 30 years old is 53.33%. Most respondents (91.16%) have a bachelor’s degree or below, while 73.81% are undergraduates. Respondents with a monthly income of less than 25,000 account for 96.26%, and those with a monthly income of 5000 to 12,000 account for 46.94%. Respondents with 1–5 years of driving experience account for 50.68%.

2.3. Modeling Framework

The factors affecting acceptance and willingness-to-pay are technical trust, perceived benefit, perceived risk, and perceived ease of use [32]. In order to better explain the acceptance and willingness-to-pay, a psychological model of AVs was established. The effects of technical trust, perceived benefit, perceived ease of use, and perceived risk on acceptance and willingness-to-pay were studied. Intuitively, for the emerging technology, trust will make people want to use the technology, and a higher perceived benefit and perceived ease of use will also make people more willing to use the technology. At the same time, a higher perceived risk will make people not want to use the technology. Figure 1 shows the hypotheses of the psychological model.

2.4. Data Analysis

Cronbach’s alpha is a measure of the reliability of a scale or test [33]. We used it to analyze the reliability of the questionnaire items. The Cronbach’s alpha of perceived ease of use is 0.544 (less than 0.6), so the data need to be processed. The CITC indicates the overall correlation of the corrected terms. The CITC of PU2 in perceived ease of use is only 0.282 and has a low correlation with other options, so the reliability analysis was performed again after its deletion.

Table 3 was obtained by eliminating PU2. The Cronbach’s alpha of perceived ease of use is 0.546, but it is only composed of two items, so the reliability is acceptable. After the correction, the reliability of the questionnaire items was found to be acceptable.

The validity is generally evaluated from two perspectives: (1) the content validity is analyzed from a professional experience perspective; and (2) the structural validity is analyzed from an empirical perspective [34].

The content validity reflects the degree to which the content of the questionnaire fits the research topic, and the expert judgment method is generally used. The questionnaire was judged and revised by professionals, so we determined that the content of the questionnaire was appropriate.

The construct validity is used to test the measurement of variables. Firstly, a KMO test is carried out. If the value is lower than 0.6 and the degree of commonality is lower than 0.4, the item can be deleted. When there are only two items, the value is always 0.5. Table 4 shows the conclusions obtained after repeating the above steps until the value reached the target. It can be seen that the common values between the factors are all higher than 0.4, indicating that the information can be extracted effectively. In addition, the values of multiple variables are all between 0.6 and 0.7, which means that the data are valid.

3. Results

3.1. Descriptive Analysis of the Psychological Model

Pearson’s correlation coefficient was used to measure the vector similarity [35]. First, box plots and scatter plots of the variables were analyzed and outliers were eliminated. Second, the variables were judged on whether they basically conformed to a linear correlation. Then, the normality test was carried out, and the significance of the data was found to be greater than 0.05. Pearson’s correlation analysis was performed after the above conditions were met. The results are shown in Table 5.

The respondents’ technical trust has a high correlation with acceptance (H1 = 0.747) and shows a positive correlation with willingness-to-pay, but the correlation is relatively weak (H5 = 0.376). Perceived benefit has a high correlation with acceptance (H2 = 0.662) but has a small correlation with willingness-to-pay (H6 = 0.235), so perceived benefit is not a predictor of willingness-to-pay. The respondents’ perceived ease of use has a good correlation with acceptance and willingness-to-pay (H3 = 0.583 and H7 = 0.461, respectively). Perceived risk is negatively correlated with acceptance and willingness-to-pay, and the correlations are weak (H4 = −0.269 and H8 = −0.183, respectively). Therefore, perceived risk is not a predictor of the two variables for highly automated vehicles. The above data and the psychological model are shown in Figure 2.

According to the above correlation analysis, the variables that have a greater impact on acceptance are technical trust, perceived benefit, and perceived ease of use; the variables that have a greater impact on willingness-to-pay are technical trust and perceived ease of use.

3.2. Descriptive Analysis of Logistic Regression Model

Many studies have considered the influence of demographic variables on acceptance and willingness-to-pay [10,29,36]. Because of the concentrated distribution of age and education, this study only considered the influence of income and driving experience of the respondents. A logistic regression model can be used to understand the relationship between variables [37]. In accordance with the questionnaire, multiple logistic regression models were established to predict acceptance and willingness-to-pay. The variables in the demographic and psychological model were used to propose relevant policies that are needed to promote the use of AVs.

Because the sample size was not sufficient, the data needed to be processed. The demographic variables include monthly income (MI) and driving experience (DE), and the psychological variables include technical trust (TT), perceived benefit (PB), perceived ease of use (PU), and perceived risk (PR). A total of 80% of the sample was randomly sampled for modeling, and the remainder was used to verify the accuracy of the model. The results of virtual processing of variables are shown in Table 6 and Table 7.

A multiple logistic regression model of acceptance was developed. The processed independent variables and dependent variables were used to train the logistic regression models. We used the forward maximum likelihood estimation method. The “0” group was selected as a reference, and Table 8 shows the acceptance model parameters. P indicates the significance of the variable. OR indicates how many times the number of study subjects is higher than lower. The accuracy of the model is 93.2%.

The variables that affect acceptance in this model are technical trust, perceived benefit, and perceived ease of use. Income, driving experience, and perceived risk were eliminated because they are not significant. The remaining 20% of the data was used to verify the model. The model has good accuracy (91.8%).

This study finds that the regression coefficients of users’ technical trust, perceived benefit, and perceived ease of use are positive, which means that they have a significant positive impact on acceptance (p < 0.05). The advantages of these three items are great (10.222, 5.536, and 6.359, respectively). Compared with people with lower perceptions (PB, PU, and TT), the acceptance will increase by 10.222, 5.536, and 6.359 times, respectively.

Similarly, a model of willingness-to-pay with an accuracy of 87.9% was established. The results are shown in Table 9. The variables influencing willingness-to-pay include income, driving experience, technical trust, and perceived ease of use. The remaining data were used to validate the model, and the accuracy was found to be 82.5%.

This study finds that the regression coefficients of driving experience, perceived ease of use, and technical trust are positive, which means that they have a significant positive impact (p < 0.05). The willingness-to-pay of drivers with 1–5 years of driving experience is 3.678 times that of trainee drivers (<1 year), and the willingness-to-pay of drivers with more than 5 years of driving experience is 3.859 times that of trainee drivers. As the driving experience increases, the respondents’ willingness-to-pay increases significantly. Compared with people with a lower perceived ease of use, the willingness-to-pay will increase by 3.497 times. There are 4.337 times as many respondents who trust technology as respondents who do not trust technology. The variable corresponding to the high-income group is not significant (p > 0.05). The regression coefficient of respondents with a monthly income of 5000–12,000 is negative, indicating that income has a significant negative impact on willingness-to-pay (p < 0.01).

4. Discussion

4.1. Psychological Factors

In this study, acceptance and willingness-to-pay were used to measure the public’s awareness of automated driving technology. Psychological factors such as technical trust, perceived benefit, perceived risk, and perceived ease of use were used to assess people’s acceptance of and willingness-to-pay for automated vehicles. To sum up, there are three findings:

First, technical trust and perceived ease of use play a direct role in the acceptance of and willingness-to-pay for AVs. A study was conducted on American automobile factory employees, and it was found that there is a significant positive correlation between perceived benefit, perceived ease of use, and acceptance [38]. In a word, whether in the psychological model or the logistic regression model, technical trust and perceived ease of use were found to have a direct impact on public acceptance of and willingness-to-pay for AVs. This shows that users are most concerned about the reliability and convenience.

Second, perceived risk has little influence on the two dependent variables. Some studies have put forward evidence to support perceived risk as a negative factor of technology acceptance [39]. However, perceived risk is not a significant factor in people’s willingness to use automated vehicles [28]. In this study, the correlation between the respondents’ acceptance, willingness-to-pay, and perceived risk is weak. Among the influencing factors, technical trust and perceived ease of use play a greater role than perceived risk. The same conclusion was reached in the logistic regression model. As a result, perceived risk is an unstable predictive variable for AVs.

Third, perceived benefit is a significant predictor of users’ acceptance, not of willingness-to-pay. At present, there is no consistent conclusion in the research on willingness-to-pay [26]. Some studies show that a higher perceived benefit will lead to a greater willingness to use automated vehicles [40]. In this survey, perceived benefit has a positive impact on acceptance, but the correlation with willingness-to-pay is weak. In the logistic regression model, perceived benefit was not a predictive variable of willingness-to-pay. These results show that a high perceived benefit will encourage users to accept AVs, but the respondents’ willingness-to-pay has little to do with perceived benefit, which should be related to other factors such as demographic variables.

4.2. Logistic Regression Model Factors

In this paper, logistic multiple regression models with a good degree of fit for acceptance and willingness-to-pay were established. The variables predictive of acceptance are technical trust, perceived benefit, and perceived ease of use. The variables that can predict willingness-to-pay are income, driving experience, technical trust, and perceived ease of use.

Compared with the psychological model, the psychological variables of the two models are highly consistent. Trust and perceived ease of use can be used to predict public acceptance of and willingness-to-pay for advanced automated vehicles. This shows that the respondents have great expectations for the reliability, practicality, and convenience of AVs. Perceived benefit can be used to predict acceptance, which shows that perceived benefit can affect people’s acceptance of AVs. There are not only psychological variables but also demographic variables that can predict the willingness-to-pay. People’s income and driving experience will affect their willingness-to-pay, which shows that people’s willingness-to-pay is closely related to their own experience. Students in school have lower incomes, and research shows that they are more likely to accept new technologies [32]. In addition, middle-income people may still be skeptical about automated vehicles. Therefore, monthly income is a negative factor. The analysis of driving experience shows that experienced drivers have a deep understanding of the traffic environment that increases their confidence in automated vehicles.

4.3. Future Research and Limitations

There are several limitations to the current research on AVs. More respondents are needed in order to increase the accuracy of the model. In this study, most of the respondents were young people. Previous studies have shown that age has no effect on the intention to accept and use AVs [18]. However, the emergence of automated vehicles will change the travel mode of certain groups of people (such as the elderly, children, people without a driver’s license, and disabled people). In future research, the potential differences in users’ ages need be further considered. In addition, although the data in this paper were collected nationwide, the respondents generally had a higher educational background. Some of the respondents are university students. Because there are systematic differences between students’ perception of new technology and the general target population [41], it would be meaningful to study respondents with different educational backgrounds. Finally, cross-cultural research is also needed. Previous studies on the acceptance of AVs show that users in different countries have situational and cultural differences in their perceptions of automated vehicles [24,42]. The acceptance of and willingness-to-pay for AVs of users in different countries need to be analyzed in the future.

5. Conclusions

AVs maximize the use of road capacity and prevent accidents caused by human error, such as dangerous driving, fatigue, and drunk driving. AVs play an important role in reducing the urban traffic pressure and the incidence and severity of traffic accidents [43]. People’s acceptance of and willingness-to-pay for AVs are the key factors in the popularity of AVs and maintaining the market share. Studying people’s acceptance and willingness-to-pay is necessary for the sustainable development of autonomous vehicles. There are several considerations that should be put into focus by manufacturers and policy-makers based on several aspects:

First, more information to enhance TT. As automated vehicles become more complex, technical trust has become particularly important. The more people know about the development of automated driving technology, the easier it is for people to trust. Moreover, the perfection of laws related to AVs will also help to enhance users’ trust. Through the improvement of automated vehicles, users’ technical trust will eventually increase. The higher the technical trust, the higher the users’ acceptance and willingness-to-pay.

Second, pricing and easy maintenance based on PU. A reasonable price and a convenient maintenance service will be of benefit to users’ acceptance and willingness-to-pay. Reducing the manufacturing cost while retaining quality and car sharing and after sale services will eventually increase the public’s perceived ease of use and, thus, users’ acceptance and willingness-to-pay.

Thirdly, education and training based on TT and PB. Personal training and feelings will be important factors affecting acceptance and willingness-to-pay. People’s opportunities to experience automated technology need to be increased. Automated vehicle test rides and test drive experiences should be continuously provided. These activities can give people a better understanding of what the car is doing and why it is doing it. Through learning, users’ awareness of this technology can be improved, and finally technical trust and perceived benefit can be increased.

Fourth, personalized sales based on DE and MI. According to the logistic regression model, driving experience and income will have an impact on willingness-to-pay. User-oriented sales should be the focus of consideration. Based on a standard product or service, a specialized sales solution for an individual can effectively enhance their willingness-to-pay.

Author Contributions

Conceptualization, W.Y. and W.L.; methodology, W.Y. and X.J.; software, W.Y.; validation, X.J.; formal analysis, W.Y., W.L., and J.G.; investigation, X.C. and J.G.; resources, T.C., W.W., and X.J.; data curation, W.Y.; writing—original draft preparation, W.Y.; writing—review and editing, X.J.; visualization, W.Y.; supervision, W.W. and H.G.; project administration, W.W. and H.G.; funding acquisition, T.C., W.W., and X.J. All authors have read and agreed to the published version of the manuscript.

Funding

This work was financially supported by funds of the Key Laboratory of Transportation Industry of Automotive Transportation Safety Enhancement Technology (Chang’an University) (No.300102221505), the First Batch of 2020 MOE of the PRC Industry–University Collaborative Education Program (No. 202001JG05, the Kingfar-CES “Human Factors and Ergonomics” Program), and the National Natural Science Foundation of China (No. 51805034, 51878045).

Institutional Review Board Statement

Our university does not have an institutional review board for similar research. The study was quite rigorous in guaranteeing the anonymity of participants and emphasizing that data would be used for research purposes only. Before distributing the questionnaire, we obtained informed consent from the participants, informing them that the survey would not have any impact on them. Follow-up research can only be carried out with their permission.

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

Data will be made available on reasonable request from the first author.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Hypotheses of the psychological model.

Figure 2. Result of the acceptance and willingness-to-pay psychological model. Notes: ** p < 0.01.

Table 1. Variables, content, and sources in the questionnaire.

Constructs	Items	Contents	Sources
Technical trust	TT1	It will be trustworthy	[28]
Technical trust	TT2	It will be reliable
Perceived benefit	PB1	It will reduce the severity of accidents
	PB2	It will reduce the incidence of traffic accidents	[29]
	PB3	It will reduce travel costs
	PB4	It will reduce mental and physical fatigue while driving
	PB5	I will find it useful when I am doing irrelevant things, such as eating
	PB6	I will find it useful when I am impaired
Perceived ease of use	PU1	It will be easily obtained
	PU2	I will find it easy to use
	PU3	It will be easy to repair when it fails
Perceived risk	PR1	I am worried that there will be equipment or system failures	[29]
	PR2	I am worried that it will leak personal information
	PR3	I am worried about the legal liability of the driver or owner
	PR4	I am worried that the cost of it will be too high
Acceptance	UA1	I will use and rent it	[28]
	UA2	I will purchase it	[30]
	UA3	I will recommend it to my family and friends
Willingness-to-pay	WP	How much are you willing to spend extra to buy it? (percentage)	[31]

Table 2. Summary of demographic and driving experience.

Variable		Percentage
Gender	Male	56.12%
Gender	Female	43.88%
Age	<30 years old	53.33%
	30–40 years old	31.02%
	40–50 years old	13.61%
	>50 years old	2.04%
Education	Junior high school	2.04%
	High school graduate	15.31%
	Bachelor’s degree	73.81%
	Postgraduate degree	8.84%
Monthly income	<5000	25.85%
	5000–12,000	46.94%
	12,000–25,000	23.47%
	>25,000	3.74%
Driving experience	0 year	15.31%
	<1 year	17.35%
	1–3 years	27.89%
	3–5 years	22.79%
	5–10 years	11.22%
	>10 years	5.44%

Table 3. Reliability test results.

Constructs	Items	CITC	Cronbach’s Alpha (after PU2 Was Deleted)	Cronbach’s Alpha
Technical trust	TT1	0.465	-	0.632
Technical trust	TT2	0.465	-	0.632
Perceived benefit	PB1	0.565	0.645	0.715
	PB2	0.470	0.669
	PB3	0.373	0.701
	PB4	0.418	0.685
	PB5	0.400	0.695
	PB6	0.497	0.662
Perceived ease of use	PU1	0.381	-	0.546
Perceived ease of use	PU3	0.381	-	0.546
Perceived risk	PR1	0.483	0.550	0.651
	PR2	0.382	0.622
	PR3	0.468	0.556
	PR4	0.401	0.603
Acceptance	UA1	0.483	0.647	0.699
	UA2	0.550	0.562
	UA3	0.517	0.604

Table 4. Validity test results.

Constructs	Items	Common Factor VARIANCE	KMO
Technical trust	TT1	0.732	0.500
Technical trust	TT2	0.732	0.500
Perceived benefit	PB1	0.626	0.647
	PB2	0.614
	PB6	0.524
Perceived ease of use	PU1	0.690	0.500
Perceived ease of use	PU3	0.690	0.500
Perceived risk	PR1	0.561	0.699
	PR2	0.414
	PR3	0.533
	PR4	0.461
Acceptance	UA1	0.584	0.667
	UA2	0.665
	UA3	0.625

Table 5. Pearson’s correlation coefficient results.

	TT	PB	PU	PR
UA	+0.747 **	+0.662 **	+0.583 **	−0.269 **
WP	+0.376 **	+0.235 **	+0.461 **	−0.183 **

Notes: ** p < 0.01.

Table 6. Result of virtual processing of independent variables.

Independent Variables		Figure
Gender	Male	0
Gender	Female	1
MI	<5000	0
	5000–12,000	1
	>12,000	2
DE	<1 year	0
	1–5 years	1
	>5 years	2
TT	<=5	0
TT	>5	1
PB	<8	0
PB	>=8	1
PU	<=5	0
PU	>5	1
PR	<8	0
PR	>=8	1

Table 7. Result of virtual processing of dependent variables.

Dependent Variable		Figure
UA	<8	0
UA	>=8	1
WP	<3	0
WP	>=3	1

Table 8. Parameters of the acceptance model.

Variable	B	S.E	p	OR	OR (95%)
PB	2.325	0.62	<0.01	10.222	3.033	34.448
PU	1.711	0.521	<0.01	5.536	1.995	15.363
TT	1.85	0.963	<0.05	6.359	0.963	42.002
Constant	−2.548	1.009	<0.05	0.078

Table 9. Parameters of the willingness-to-pay model.

Variable	B	S.E	p	OR	OR (95%)
MI			<0.01
MI (1)	−1.751	0.459	<0.01	0.174	0.071	0.427
MI (2)	−0.28	0.402	0.486	0.756	0.343	1.662
DE			<0.01
DE (1)	1.302	0.471	<0.01	3.678	1.462	9.253
DE (2)	1.35	0.401	<0.01	3.859	1.759	8.468
PU	1.252	0.381	<0.01	3.497	1.659	7.372
TT	1.467	0.709	<0.05	4.337	1.081	17.393
Constant	−1.718	0.797	<0.05	0.179

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Jiang, X.; Yu, W.; Li, W.; Guo, J.; Chen, X.; Guo, H.; Wang, W.; Chen, T. Factors Affecting the Acceptance and Willingness-to-Pay of End-Users: A Survey Analysis on Automated Vehicles. Sustainability 2021, 13, 13272. https://doi.org/10.3390/su132313272

AMA Style

Jiang X, Yu W, Li W, Guo J, Chen X, Guo H, Wang W, Chen T. Factors Affecting the Acceptance and Willingness-to-Pay of End-Users: A Survey Analysis on Automated Vehicles. Sustainability. 2021; 13(23):13272. https://doi.org/10.3390/su132313272

Chicago/Turabian Style

Jiang, Xiaobei, Wenlin Yu, Wenjie Li, Jiawen Guo, Xizheng Chen, Hongwei Guo, Wuhong Wang, and Tao Chen. 2021. "Factors Affecting the Acceptance and Willingness-to-Pay of End-Users: A Survey Analysis on Automated Vehicles" Sustainability 13, no. 23: 13272. https://doi.org/10.3390/su132313272

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Factors Affecting the Acceptance and Willingness-to-Pay of End-Users: A Survey Analysis on Automated Vehicles

Abstract

1. Introduction

2. Methodology

2.1. Data Collection

2.2. Survey Participants

2.3. Modeling Framework

2.4. Data Analysis

3. Results

3.1. Descriptive Analysis of the Psychological Model

3.2. Descriptive Analysis of Logistic Regression Model

4. Discussion

4.1. Psychological Factors

4.2. Logistic Regression Model Factors

4.3. Future Research and Limitations

5. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Conflicts of Interest

References

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