CN115860461A - Risk factor evaluation method for traffic conflict of non-motor vehicles at plane intersection - Google Patents

Risk factor evaluation method for traffic conflict of non-motor vehicles at plane intersection Download PDF

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CN115860461A
CN115860461A CN202211453450.7A CN202211453450A CN115860461A CN 115860461 A CN115860461 A CN 115860461A CN 202211453450 A CN202211453450 A CN 202211453450A CN 115860461 A CN115860461 A CN 115860461A
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variable
motor vehicle
traffic
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陈一锴
陶正彬
张耀艺
刘林芝
吴基民
杨晓磊
坤土孜爱·库日万江
石琴
丁建勋
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Hefei University of Technology
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Abstract

The invention discloses a method for evaluating risk factors of traffic conflicts of non-motor vehicles at plane intersections, which comprises the following steps: 1. collecting vehicle running track data in a plane intersection by using an unmanned aerial vehicle aerial video, constructing a safety substitute evaluation index with quantified traffic conflict risk, identifying the traffic conflict of the non-motor vehicles, and dividing the traffic conflict into slight conflict and serious conflict according to the severity of the conflict approaching accident; 2. acquiring risk driving behavior data related to non-motor vehicle traffic conflicts by using a road fixed camera which is shot synchronously with the aerial photography of the unmanned aerial vehicle; 3. and establishing a random parameter binomial Logit model with heterogeneity of mean and variance, and quantitatively analyzing the influence of the risk driving behavior of the rider on the traffic conflict severity of the non-motor vehicle. The invention can realize the high-efficiency and objective evaluation of the traffic safety of the non-motor vehicles at the plane intersection so as to improve the accuracy of the analysis of the traffic accident risk factors.

Description

Risk factor evaluation method for traffic conflict of non-motor vehicles at plane intersection
Technical Field
The invention relates to a risk factor evaluation method for a non-motor vehicle traffic conflict under a plane intersection, and belongs to the field of traffic safety risk analysis based on traffic conflicts.
Background
With the rise of our country's shared economy and takeaway culture, the number of non-motor vehicles is growing rapidly. The non-motor vehicles are poor in driving stability and few in safety protection facilities, drivers do not need driving licenses and safety training, driving skills and safety consciousness are weak, dangerous driving behaviors such as violating traffic lights, occupying motor vehicle lanes, reversely driving, speeding and violating manned persons are frequent, and road traffic accidents caused by the non-motor vehicles are increased. Particularly, at plane intersections, the phenomenon of mixed movement of machines and non-machines is prominent, and traffic conflicts and traffic accidents are high. Therefore, it is urgently needed to analyze the traffic safety of non-motor vehicles at the plane intersection.
The traditional method for evaluating the traffic safety risk factors of the non-motor vehicles at the plane intersection mainly comprises a traffic accident statistical analysis method and a questionnaire survey method. The traffic accident statistical analysis method relies on the report data of police, researchers can extract accurate and reliable information, mainly focuses on external factors such as vehicles, roads, environments and the like, and driving behavior information before an accident happens can be rarely obtained from official records. And the defects of insufficient report, after-the-fact evaluation, long observation period and the like exist. Compared with the statistical analysis of traffic accidents, the questionnaire survey method can more comprehensively and deeply analyze the risky driving behaviors and relevant motivational factors thereof. However, the questionnaire survey method adopts a self-reporting mode, the data effectiveness is easily influenced by the memory deviation and social expectation, inaccurate estimation of risk factors is caused, and strong causal statement on the result is difficult to make.
Aiming at the limitations of the method, the evaluation of the traffic safety risk factors of the non-motor vehicles at the plane intersection based on the traffic conflict theory is widely applied. However, the existing method for evaluating the traffic safety risk factor of the non-motor vehicles at the plane intersection based on the traffic conflict theory has the following problems: 1. the analysis of the influence factors of the severity of the traffic conflict of the non-motor vehicles mainly focuses on the factors such as road characteristics and the like, and the systematic exploration on the risk driving behaviors of riders is lacked; 2. the selection of the traffic conflict index does not consider the vehicle motion conditions and conflict characteristics under different conflict angles, so that the traffic conflict risk before and after the conflict vehicle reaches the conflict point is difficult to accurately reflect; 3. the construction of statistical analysis models ignores the heterogeneity problem not observed in the data, and deviations in the estimated parameters can occur, leading to erroneous inferences and predictions.
Disclosure of Invention
The invention aims to overcome the problems in the prior art, and provides a method for evaluating risk factors of non-motor vehicle traffic conflicts at a plane intersection, so that the high-efficiency and objective evaluation on the non-motor vehicle traffic safety at the plane intersection can be realized, and the individual heterogeneity characteristics are fully excavated to improve the accuracy of the analysis of the traffic accident risk factors, thereby improving the traffic safety level of the non-motor vehicles.
In order to achieve the purpose, the invention adopts the following technical scheme:
the invention relates to a method for evaluating risk factors of traffic conflicts of non-motor vehicles at plane intersections, which is characterized by comprising the following steps:
step 1, collecting vehicle running track data in a current plane intersection from an unmanned aerial vehicle aerial video, and extracting motion state data of a non-motor vehicle A and a vehicle B from the vehicle running track data, wherein the motion state data comprises the following steps: vehicle position and speed;
step 2, if the current non-motor vehicle A and the vehicle B approach each other on a horizontal straight line, executing step 2.1-step 2.3, and if the current non-motor vehicle A and the vehicle B approach each other in a staggered manner, executing step 2.4-step 2.7;
step 2.1, if the current non-motor vehicle A and the current vehicle B run on the same horizontal straight line in the same direction, calculating the time TTC of collision between the non-motor vehicle A and the current vehicle B at the current time t by using the formula (1) A,B (t):
Figure BDA0003952504130000021
In the formula (1), l A,B (t) represents the spatial distance from the front of the rear vehicle B to the rear of the front vehicle A at the current moment t, v B (t) speed of the vehicle of the following vehicle B at the present time t, v A (t) represents the speed of the preceding vehicle a at the current time t;
if the current non-motor vehicle A and the current vehicle B oppositely run on a horizontal straight line, calculating the time TTC of the collision between the non-motor vehicle A and the current vehicle B at the current time t by using an equation (2) A,B (t):
Figure BDA0003952504130000022
L 'in the formula (2)' A,B (t) represents the spatial distance between the heads of two vehicles at the current moment t, v A (t)、v B (t) respectively representing the speeds of the non-motor vehicle A and the vehicle B at the current moment t;
step 2.2, if the speed of the rear vehicle B is greater than that of the front vehicle A at the moment of t +1 or the speed of any one of the non-motor vehicle A and the vehicle B at the moment of t +1 is not 0 in the opposite driving process in the same-direction driving process, indicating that the two vehicles are expected to collide, assigning t +1 to t, returning to the step 2.1 to execute, otherwise, indicating that the two vehicles are not expected to collide, and selecting from all calculated collision time of the non-motor vehicle A and the vehicle BObtaining the minimum time to collide (minTTC) by taking the minimum value A,B
Step 2.3, obtaining the risk grade y of traffic conflict between the non-motor vehicle A and the vehicle B by using the formula (3) A,B If y is A,B If not, executing the step 3; otherwise, returning to the step 1;
Figure BDA0003952504130000023
in the formula (3), θ 1 Representing traffic conflict discrimination threshold, θ, based on TTC index 2 Representing a traffic conflict risk rating threshold based on the TTC index; y is A,B =0 for slight collision, y A,B =1 denotes a serious collision, y A,B = ∞ represents no collision;
step 2.4, calculating the traffic conflict risk measurement index of the non-motor vehicle A and the vehicle B at the current moment t by using the formula (4)
Figure BDA0003952504130000031
Figure BDA0003952504130000032
In the formula (4), d A (t) represents the distance between the intersection point of the expected tracks of the two vehicles and the non-motor vehicle A when the non-motor vehicle A and the vehicle B keep the current driving direction unchanged at the current moment t, d B (t) represents the distance between the intersection point of the expected tracks of the two vehicles and the vehicle B when the current driving direction of the non-off motor vehicle A and the vehicle B is kept unchanged at the current moment t;
step 2.5, if the tail of the non-motor vehicle A or the vehicle B passes through the intersection point of the driving tracks of the two vehicles, selecting the minimum value from all the calculated traffic conflict risk measurement indexes and recording the minimum value as the minimum traffic conflict risk measurement index
Figure BDA0003952504130000033
Otherwise, after assigning t +1 to t, returning to the step 2.4 for execution;
step 2.6, utilize formula (5)Calculating post-intrusion time index PET of non-motor vehicle A and vehicle B A,B
PET A,B =t A -t B (5)
In the formula (5), t A Indicating the moment, t, at which the head of the non-motor vehicle A passes the intersection B Indicating the moment at which the rear of vehicle B that first passed the intersection leaves the intersection;
step 2.7, obtaining the risk level y 'of traffic conflict between the non-motor vehicle A and the vehicle B by utilizing the formula (6)' A,B (ii) a If y' A,B If not, executing the step 3; otherwise, returning to the step 1;
Figure BDA0003952504130000034
in the formula (6), τ 1 、λ 1 Respectively representing risk measurement indexes T based on traffic conflicts 2 Traffic conflict discrimination threshold, τ, for post-intrusion time index PET 2 、λ 2 Respectively representing risk measurement indexes T based on traffic conflicts 2 The traffic conflict risk grade of the post-intrusion time index PET is divided into threshold values; y' A,B =0 denotes a slight conflict, y' A,B =1 indicates severe collision; y' A,B = ∞ represents no collision;
step 3, extracting K risky driving behaviors of the non-motor vehicle A driver from the road camera shooting data shot synchronously with the unmanned aerial vehicle aerial photography and forming an interpretation variable set X influencing any ith starting traffic conflict risk level i =(X i1 ,X i2 ,…,X ik ,…,X iK ) Wherein X is ik Indicating the k risky driving behavior of the ith traffic conflict; set X of interpretation variables for making ith traffic conflict risk level i Traffic conflict risk level y A,B Or y' A,B Is marked as y i (ii) a From X i And y i Forming an ith sample; thus obtaining N samples according to the processes of the step 1 to the step 3;
step 4, establishing a random parameter binomial Logit model with heterogeneity of mean and variance, and quantitatively analyzing influence factors influencing the severity of the traffic conflict of the non-motor vehicles;
step 4.1, when X ik When the variable is a continuous variable, the t test is adopted to X ik Performing single factor significance analysis when X is ik When classifying variables, chi-square test is used for X ik Performing single factor significance analysis, comparing the tested P value with the set significance level alpha, and adding a first interpretation variable set if the P value is less than the significance level alpha
Figure BDA0003952504130000041
If not, continuing to judge the next risk driving behavior; thus resulting in a final first interpretation variable set->
Figure BDA0003952504130000042
Step 4.2, calculating the final first interpretation variable set
Figure BDA0003952504130000043
And deleting the interpretation variables with the variance inflation factor larger than or equal to theta to obtain a second interpretation variable set ^ and ^ r>
Figure BDA0003952504130000044
Step 4.3, constructing a stepwise regression model, and integrating the second interpretation variables
Figure BDA0003952504130000045
Introducing the explained variables into a regression equation one by one, respectively performing F test on all the explained variables in the regression equation during each introduction, if the P value obtained by the test is more than or equal to the set significant level alpha, rejecting the corresponding explained variables, and otherwise, reserving the corresponding explained variables to obtain a third explained variable set (ion-value-based analysis method or mean-value-based analysis method) based on the third explained variable set>
Figure BDA0003952504130000046
Step 4.4, establishing a Logit regression model by using the formula (7):
Figure BDA0003952504130000047
in the formula (7), p i Indicates the probability of the ith sample being a severe collision, 1-p i Representing the probability that the ith sample is a slight conflict; beta is a beta i A parameter vector to be estimated for the ith sample is obtained by the formula (8); epsilon i A random error term for the ith sample;
β i =β+δ i M ii exp(ω i s i )v i (8)
in the formula (8), β represents a parameter vector β i Mean value of (D), M i Is the influence parameter vector beta i Interpretation of the mean variable vector, δ i Is M i Corresponding estimated parameter vector, s i To capture beta i Standard deviation of (a) i Interpretive variable vector of medium heterogeneity, omega i Is s i A corresponding estimated parameter vector; v. of i Is the perturbation term for the ith sample;
step 4.4, assume third set of interpretation variables
Figure BDA0003952504130000051
Parameter vector beta of i Are all random parameters, and specify a probability density function for the distribution of the random parameters, a variable vector M will be explained i And interpreting the variable vector s i Are initialized to a set of explanatory variables X i
And 4.5, performing parameter estimation on the Logit regression model by adopting a simulation-based maximum likelihood method, and solving an estimated parameter vector beta 'when the likelihood function shown as the formula (9) is maximum' i 、δ′ i 、ω′ i And as a model regression result;
Figure BDA0003952504130000052
step (ii) of4.6, according to the regression result of the model, if the third interpretation variable set
Figure BDA0003952504130000053
Of an interpretive variable in the estimated parameter vector β' i If the P values of the standard deviation and the mean value of the corresponding estimated parameters in the set are less than the set significance level alpha, setting the corresponding explanatory variables as random parameters, and determining the corresponding explanatory variables in the estimated parameter vector beta 'based on the goodness of fit of the Logit regression model' i Otherwise, setting the estimation parameters of the corresponding interpretation variables as fixed parameters;
if the variable vector M is explained i Is in the estimated parameter vector delta' i The P value of the corresponding estimated parameter is less than the set significance level alpha, then the variable vector M is explained i The corresponding interpretation variable is retained, otherwise, from M i Eliminating corresponding explanation variables;
if the variable vector sigma is explained i Of an interpretive variable in the estimated parameter vector ω' i The P value of the corresponding estimated parameter is less than the set significance level alpha, then the variable vector sigma is explained i In which the corresponding interpretation variable is retained, otherwise, from σ i Removing corresponding explanation variables;
step 4.7, processing according to the processes of the step 4.5 to the step 4.6 until the P values of the estimated parameters in the model regression result are all smaller than the set significance level alpha, so as to obtain a final model regression result;
step 4.8, according to the final model regression result, when the third interpretation variable set
Figure BDA0003952504130000054
Mth interpretation variable>
Figure BDA0003952504130000055
For successive variables, the value of the elasticity coefficient->
Figure BDA0003952504130000056
When interpreting the set of variables +>
Figure BDA0003952504130000057
Is explained in>
Figure BDA0003952504130000058
For categorizing a variable, the value of the pseudo-elasticity coefficient of the variable->
Figure BDA0003952504130000059
Figure BDA00039525041300000510
Figure BDA00039525041300000511
In the formula (11), the reaction mixture is,
Figure BDA0003952504130000061
indicates when an interpretation variable>
Figure BDA0003952504130000062
The probability of a severe collision occurring when equal to 1,
Figure BDA0003952504130000063
indicates when an interpretation variable>
Figure BDA0003952504130000064
Probability of severe collision when equal to 0;
step 4.9, obtaining a third interpretation variable set according to the process of the step 4.8
Figure BDA0003952504130000065
The marginal effects of all the explained variables in the (A) and the (B) are sorted in descending order, and a third explained variable set is judged to be greater than or equal to>
Figure BDA0003952504130000066
And the influence of each risky driving behavior on the traffic conflict risk degree is used as a risk factor evaluation result of the traffic conflict of the non-motor vehicles at the plane intersection.
The electronic device comprises a memory and a processor, and is characterized in that the memory is used for storing programs for supporting the processor to execute the risk factor evaluation method, and the processor is configured to execute the programs stored in the memory.
The invention relates to a computer-readable storage medium, on which a computer program is stored, characterized in that the computer program, when being executed by a processor, performs the steps of the risk factor assessment method.
Compared with the prior art, the invention has the beneficial effects that:
1. compared with the traditional method for evaluating the traffic safety risk factors of the non-motor vehicles at the plane intersection, the method for evaluating the traffic safety risk factors of the non-motor vehicles at the plane intersection has the advantages that the severity of the conflict approach accident is measured by constructing the traffic conflict index, the risk driving behaviors of the non-motor vehicles at the plane intersection are fully considered, the influence rule of the risk driving behaviors on the traffic conflict risk of the non-motor vehicles is analyzed, and the statistical advantage characteristics of large sample, short period, small area, high reliability and the like are realized, so that the high efficiency and the objectivity of the traffic safety analysis of the non-motor vehicles at the plane intersection are improved.
2. In the invention, the uncertainty of the mobility of the conflict point under the linear traffic conflict and the expected collision under the non-linear traffic conflict is considered, the safety substitute evaluation index reflecting the traffic conflict risk before and after the conflict vehicle reaches the conflict point is accurately constructed, and the accuracy of the traffic conflict risk evaluation is improved.
3. The invention establishes a random parameter binomial Logit model with heterogeneity of mean and variance, and quantitatively analyzes the influence of the risk driving behavior of the rider on the non-motorized traffic conflict. By specifying the distribution function of the model estimation parameters and taking the mean value and the variance of the distribution function as the estimation functions of the observed interpretation variables, the problem of unobserved heterogeneity in data is captured, and the accuracy of the model parameter estimation and the inference results is improved.
Drawings
FIG. 1 is a flow chart of a risk factor assessment method of the present invention.
Detailed Description
In this embodiment, as shown in fig. 1, a method for evaluating risk factors of non-motor vehicle traffic conflicts at a plane intersection is performed according to the following steps, taking a cross-shaped signal plane intersection of a tung city road and a turnip lake road in a central urban area of Hefei city, anhui province as an example:
step 1, collecting vehicle running track data in a current plane intersection from an unmanned aerial vehicle aerial video, and extracting motion state data of a non-motor vehicle A and a vehicle B from the vehicle running track data, wherein the data comprises the following steps: vehicle position and speed;
step 2, if the current non-motor vehicle A and the current non-motor vehicle B approach each other on a horizontal straight line, and the mobility of the conflict point under the straight line traffic conflict is considered, executing the step 2.1-the step 2.3, and measuring the risk of the straight line traffic conflict; if the current non-motor vehicle A and the current non-motor vehicle B approach each other in a staggered mode, and uncertainty of expected collision of non-linear traffic conflict is considered, executing the step 2.4-the step 2.7, and comprehensively reflecting the approaching degree of the vehicles before and after reaching the conflict point;
step 2.1, if the current non-motor vehicle A and the current vehicle B run on the same horizontal straight line in the same direction, calculating the time TTC of collision between the non-motor vehicle A and the current vehicle B at the current time t by using the formula (1) A,B (t), identifying a rear-end collision:
Figure BDA0003952504130000071
in the formula (1), l A,B (t) represents the spatial distance from the front of the rear vehicle B to the rear of the front vehicle A at the current moment t, v B (t) represents the speed of the vehicle of the following vehicle B at the present time t, v A (t) represents the speed of the preceding vehicle a at the current time t;
if the current non-motor vehicle A and the current non-motor vehicle B oppositely run on a horizontal straight line, calculating the time TTC of the collision between the non-motor vehicle A and the current non-motor vehicle B at the current time t by using the formula (2) A,B (t), identifying the forward directionConflict:
Figure BDA0003952504130000072
in the formula (2), l A,B (t) represents the spatial distance between the heads of two vehicles at the current moment t, v A (t)、v B (t) respectively representing the speeds of the non-motor vehicle A and the vehicle B at the current moment t;
step 2.2, if the speed of the rear vehicle B is greater than that of the front vehicle A at the moment of t +1 or the speed of any one of the non-motor vehicle A and the vehicle B at the moment of t +1 is not 0 in the opposite driving process, indicating that the two vehicles are expected to collide, assigning t +1 to t, returning to the step 2.1 to execute, otherwise, indicating that the two vehicles are not expected to collide, and selecting the minimum value from all calculated collision time of the non-motor vehicle A and the vehicle B to obtain the minimum collision time minTTC A,B ,;
Step 2.3, selecting theta 1 Using =3s as collision time TTC index to judge threshold of collision, and selecting theta 2 And (4) taking The Time of Collision (TTC) as an index for dividing threshold values of slight conflict and serious conflict to obtain the risk grade y of traffic conflict between the non-motor vehicle A and the vehicle B by using the formula (3) A,B (ii) a If y A,B If not, executing the step 3; otherwise, returning to the step 1;
Figure BDA0003952504130000073
in the formula (3), θ 1 Representing traffic conflict discrimination thresholds, theta, based on TTC index 2 Representing a traffic conflict risk rating threshold based on the TTC index; y is A,B =0 for slight collision, y A,B =1 denotes a serious collision, y A,B = ∞ represents no collision;
step 2.4, calculating the traffic conflict risk measurement index of the non-motor vehicle A and the vehicle B at the current moment t by using the formula (4)
Figure BDA0003952504130000081
Measurement ofRisk of traffic collision before vehicle reaches conflict point under non-linear traffic collision:
Figure BDA0003952504130000082
in the formula (4), d A (t) represents the distance between the intersection point of the expected tracks of the two vehicles and the non-motor vehicle A when the non-motor vehicle A and the vehicle B keep the current driving direction unchanged at the current moment t, d B (t) represents the distance between the intersection point of the expected tracks of the two vehicles and the vehicle B when the current driving direction of the non-motor vehicle A and the vehicle B is kept unchanged at the current moment t;
step 2.5, if the tail of the non-motor vehicle A or the vehicle B passes through the intersection point of the driving tracks of the two vehicles, selecting the minimum value from all the calculated traffic conflict risk measurement indexes and recording the minimum value as the minimum traffic conflict risk measurement index
Figure BDA0003952504130000083
Otherwise, after assigning t +1 to t, returning to the step 2.4 for execution;
step 2.6, calculating the post-invasion time index PET of the non-motor vehicle A and the vehicle B by using the formula (5) A,B And (3) measuring the risk of the vehicle after reaching the conflict point in the non-linear traffic conflict:
PET A,B =t A -t B (5)
in the formula (5), t A Indicating the moment, t, at which the head of the non-motor vehicle A passes the intersection B Indicating the moment at which the rear of vehicle B that first passed the intersection leaves the intersection;
step 2.7, select tau separately 1 =3s、λ 1 =3s as traffic conflict risk metric T 2 Judging conflict threshold value by post-invasion time index PET index, selecting tau 2 =1.5s、λ 2 =1.5s as T 2 The PET index is divided into threshold values of slight conflict and serious conflict, and the risk level y 'of traffic conflict between the non-motor vehicle A and the vehicle B is obtained by utilizing the formula (6)' A,B (ii) a If y' A,B If not, executing the step 3; otherwiseReturning to the step 1;
Figure BDA0003952504130000084
in the formula (6), τ 1 、λ 1 Respectively represent a radical based on T 2 Traffic conflict discrimination threshold value of PET index, tau 2 、λ 2 Respectively represent a radical based on T 2 The traffic conflict risk grade of the PET index is divided into a threshold value; y' A,B =0 denotes slight conflict, y' A,B =1 represents a serious collision;
step 3, extracting 18 (K = 18) risky driving behaviors of the non-motor vehicle A driver from the road camera shooting data shot synchronously with the unmanned aerial vehicle aerial photography and forming an interpretation variable set X influencing any ith initial traffic conflict risk level i =(X i1 ,X i2 ,…,X ik ,…,X i18 ) Wherein X is ik The k-th risky driving behavior of the ith traffic conflict is shown, and in order to facilitate the fitting of the discrete result model, the explanatory variables are recoded and assigned as shown in the table 1; set X of interpretation variables for making ith traffic conflict risk level i Traffic conflict risk level y A,B Or y' A,B Is marked as y i (ii) a From X i And y i Forming an ith sample; thus, N =438 samples were obtained according to the procedure of step 1-step 3;
TABLE 1 explanatory variables for analysis of impact factors for non-motor traffic conflict risk levels
Figure BDA0003952504130000091
Figure BDA0003952504130000101
Step 4, establishing a random parameter binomial Logit model with heterogeneity of mean value and variance, and quantitatively analyzing influence factors influencing the severity of traffic conflicts of the non-motor vehicles;
step 4.1, when X ik When the variable is a continuous variable, the t test is adopted to X ik Performing single factor significance analysis when X is ik For classifying variables, chi-square test is used for X ik Performing single factor significance analysis, comparing the tested P value with the set significance level alpha, and adding a first interpretation variable set if the P value is less than the significance level alpha
Figure BDA0003952504130000102
If not, continuing to judge the next risky driving behavior; thus resulting in a final first interpretation variable set->
Figure BDA0003952504130000103
In an embodiment, a set of interpretation variables X i The interpretation variables in (1) are all classification variables, so the chi-square test is adopted to carry out single-factor significance test, when the significance evaluation index P value is less than 0.05 (alpha = 0.05), the alternative interpretation variables are considered to have significant influence on the severity of the traffic conflict of the non-motor vehicle, otherwise, the alternative interpretation variables are deleted, and the result is shown in table 2:
TABLE 2 Single factor analysis results
Figure BDA0003952504130000111
As can be seen from Table 2, 8 explanatory variables, including gender, takeaway deliverer, running a red light, occupying motorway, not observing the coming vehicle at the rear while turning, not decelerating while driving into an intersection, violating road right-of-way, and not maintaining safe lateral distance, have statistical significance (P)<= 0.05). Thus, the above explained variables are retained, resulting in a first set of explained variables
Figure BDA0003952504130000112
Figure BDA0003952504130000113
Figure BDA0003952504130000114
Step 4.2, calculating the final first interpretation variable set
Figure BDA0003952504130000115
And the variance inflation factor of each interpretation variable is deleted, and the interpretation variables with the variance inflation factor of more than or equal to 10 (theta = 10) are deleted, so that a second set of interpretation variables ≥ is obtained>
Figure BDA0003952504130000116
The method eliminates the influence of multiple collinearity existing among the explained variables, meets the requirement that the variables are mutually independent when the Logit regression model carries out parameter estimation, and the multiple collinearity test is shown in a table 3:
TABLE 3 multiple collinearity diagnostic results
Figure BDA0003952504130000121
As can be seen from Table 3, all the VIF values of the 8 explanatory variables selected in step 4.2 with statistical significance are less than 2, and the multiple collinearity problem does not exist. Thus, the 8 explanatory variables described above are retained, resulting in a second set of explanatory variables
Figure BDA0003952504130000122
Figure BDA0003952504130000123
Step 4.3, constructing a stepwise regression model, and integrating the second interpretation variables
Figure BDA0003952504130000124
The explained variables are introduced into the regression equation one by one, all the explained variables in the regression equation are subjected to F test during each introduction, if the P value obtained by the test is more than or equal to the set significant level alpha, the corresponding explained variables are removed, otherwise, the corresponding explained variables are retained, and therefore a third explained variable set with significant prediction effect is further screened out
Figure BDA0003952504130000125
The stepwise regression results are shown in table 4:
TABLE 4 stepwise regression results
Figure BDA0003952504130000126
As can be seen from Table 4, the set of explanatory variables obtained by stepwise regression results screening
Figure BDA0003952504130000127
Figure BDA0003952504130000128
Step 4.4, establishing a Logit regression model by using the formula (7):
Figure BDA0003952504130000129
in formula (7), p i Indicates the probability of the ith sample being a severe collision, 1-p i Representing the probability that the ith sample is a slight conflict; beta is a i A parameter vector to be estimated for the ith sample is obtained by the formula (8); epsilon i A random error term for the ith sample;
β i =β+δ i M ii exp(ω i s i )v i (8)
in the formula (8), β represents a parameter vector β i Mean value of M i Is the influence parameter vector beta i Interpretation of the mean variable vector, δ i Is M i Corresponding estimated parameter vector, s i To catch beta i Standard deviation of (a) i Interpretive variable vector of medium heterogeneity, omega i Is s i A corresponding estimated parameter vector; v. of i Is the perturbation term for the ith sample;
step 4.4, assume third set of interpretation variables
Figure BDA0003952504130000131
Parameter vector beta of i Are random parameters, and are assigned to obey normal distribution or log-normal distribution or uniform distribution, and the variable vector M will be explained i And interpreting the variable vector s i Are initialized to a set of interpretation variables X i
And 4.5, performing parameter estimation on the Logit regression model by adopting a simulation-based maximum likelihood method, and solving an estimated parameter vector beta 'when the likelihood function shown as the formula (9) is maximum' i 、δ′ i 、ω′ i And as a model regression result;
Figure BDA0003952504130000132
step 4.6, according to the model regression result, if the third interpretation variable set
Figure BDA0003952504130000133
Of an interpretive variable in the estimated parameter vector β' i If the standard deviation and the mean value P of the corresponding estimation parameters are less than the set significance level alpha, setting the corresponding interpretation variables as random parameters, and determining the estimated parameter vector beta of the corresponding interpretation variables based on the goodness of fit of the Logit regression model i ' the probability density function of the corresponding estimation parameter, otherwise, the estimation parameter of the corresponding interpretation variable is set as a fixed parameter;
if the variable vector M is explained i Of an interpretive variable in the estimated parameter vector δ' i The P value of the corresponding estimated parameter is less than the set significance level alpha, then the variable vector M is explained i The corresponding interpretation variable is retained, otherwise, from M i Removing corresponding explanation variables;
if the variable vector sigma is explained i Of an interpretive variable in the estimated parameter vector ω' i The P value of the corresponding estimated parameter is less than the set significance level alpha, then the variable vector sigma is explained i Middle retention phaseVariables should be interpreted, otherwise, from σ i Removing corresponding explanation variables;
step 4.7, processing according to the processes of the step 4.5 to the step 4.6 until the P values of the estimated parameters in the model regression result are all smaller than the set significance level α, so as to obtain a final model regression result, as shown in table 5:
TABLE 5 random parameter Lomit model parameter estimation results of mean and variance heterogeneity
Figure BDA0003952504130000141
As can be seen from table 5, the interpretation variables do not slow down when driving into the intersection, run a red light, take out deliverers, violate road traffic, do not maintain safe lateral distance, and occupy motorways have a significant impact on the severity of the non-motor traffic conflict. The explanation variable does not decelerate when entering the intersection, has random parameter characteristics, and has variance heterogeneity in the 'gender' explanation variable. Compared with a triangular distribution (-239.00217) and a uniform distribution (-239.06153), the random parameter obeys normal distribution when the model converges, and has a better log-likelihood value (-238.96525), and the fitting goodness of the model is optimal. Thus, a normal distribution with a mean of 1.84469 and a variance of 2.31186 is determined as a probability density function of random parameters, i.e., 78.75% of the riders are prone to severe collisions and 21.25% of the riders are less likely to have severe collisions for non-motor riders that do not slow down when entering the intersection. The remaining explanatory variable estimation parameters are fixed parameters.
Step 4.8, according to the final model regression result, when the third interpretation variable set
Figure BDA0003952504130000142
The mth interpretation variable->
Figure BDA0003952504130000143
For continuous variables, the value of the elasticity coefficient->
Figure BDA0003952504130000144
Represents a variable->
Figure BDA0003952504130000145
The change in (b) corresponds to a change value of the probability of the non-motor vehicle experiencing a severe collision; when interpreting the set of variables->
Figure BDA0003952504130000146
Is explained in>
Figure BDA0003952504130000147
For categorizing a variable, the value of the pseudo-elasticity coefficient ≥ of the variable is calculated using equation (11)>
Figure BDA0003952504130000148
Indicates that the interpretation variable->
Figure BDA0003952504130000149
When the reference value is changed into the current value, the non-motor vehicle has a change value of the serious conflict probability; therefore, the influence of the risky driving behaviors on the severity of the traffic conflict of the non-motor vehicle is quantitatively analyzed;
Figure BDA0003952504130000151
Figure BDA0003952504130000152
in the formula (11), the reaction mixture is,
Figure BDA0003952504130000153
indicates when the interpretation variable->
Figure BDA0003952504130000154
Probability of a severe conflict occurring equal to 1, <' >>
Figure BDA0003952504130000155
Indicates when the interpretation variable->
Figure BDA0003952504130000156
Probability of a severe collision occurring when equal to 0;
in the embodiment, the selected interpretation variables are all classification variables, so the influence of the interpretation variables on the severity of the non-motor vehicle traffic conflict is quantified through a calculation formula (11).
Step 4.9, obtaining a third interpretation variable set according to the process of the step 4.8
Figure BDA0003952504130000157
The marginal effects of all the explained variables in the (A) and the (B) are sorted in descending order, and a third explained variable set is judged to be greater than or equal to>
Figure BDA0003952504130000158
The influence of each risky driving behavior on the traffic conflict risk degree is used as a risk factor evaluation result of the traffic conflict of the non-motor vehicles at the intersection, and the result is shown in table 6:
TABLE 6 average marginal effect of significant variables on severity of non-motor vehicle traffic conflicts
Figure BDA0003952504130000159
As can be seen from table 6, interpreting variables that run red light, do not maintain lateral safe distance, violate road right of way, take delivery, occupy motorways, and drive into intersections without slowing down significantly increases the probability of a serious conflict with a non-motor vehicle. Wherein, the probability of serious conflict of non-motor vehicles caused by red light running is the maximum, and is 3.51 percent; secondly, the transverse safety distance is not kept, and is 2.78%; the probability of serious conflict of the non-motor vehicles caused by violation of road right of way, the fact that the riders are takeaway distributors and the fact that the riders occupy the motor vehicle lanes is equivalent to 1.71%, 1.69% and 1.68% respectively; the speed reduction is lowest when the automobile enters the intersection and is 0.52 percent.
In this embodiment, an electronic device includes a memory for storing a program that supports a processor to execute the risk factor assessment method, and a processor configured to execute the program stored in the memory.
In this embodiment, a computer-readable storage medium stores a computer program, and the computer program is executed by a processor to perform the steps of the risk factor assessment method.
In conclusion, the method for evaluating the risk factors of the traffic conflicts of the non-motor vehicles at the plane intersection has feasibility, can objectively and efficiently analyze the factors influencing the severity of the traffic conflicts of the plane intersection, fully excavates the heterogeneous characteristics in the data and improves the accuracy of analyzing the risk factors of the traffic accidents.

Claims (3)

1. A method for evaluating risk factors of non-motor vehicle traffic conflicts at plane intersections is characterized by comprising the following steps:
step 1, collecting vehicle running track data in a current plane intersection from an unmanned aerial vehicle aerial video, and extracting motion state data of a non-motor vehicle A and a vehicle B from the vehicle running track data, wherein the motion state data comprises the following steps: vehicle position and speed;
step 2, if the current non-motor vehicle A and the vehicle B approach each other on a horizontal straight line, executing step 2.1-step 2.3, and if the current non-motor vehicle A and the vehicle B approach each other in a staggered manner, executing step 2.4-step 2.7;
step 2.1, if the current non-motor vehicle A and the current vehicle B run on the same horizontal straight line in the same direction, calculating the time TTC of collision between the non-motor vehicle A and the current vehicle B at the current time t by using the formula (1) A,B (t):
Figure FDA0003952504120000011
In the formula (1), l A,B (t) represents the spatial distance from the front of the rear vehicle B to the rear of the front vehicle A at the current moment t, v B (t) speed of the vehicle of the following vehicle B at the present time t, v A (t) shows the preceding vehicle A at the present time tSpeed;
if the current non-motor vehicle A and the current non-motor vehicle B oppositely run on a horizontal straight line, calculating the time TTC of the collision between the non-motor vehicle A and the current non-motor vehicle B at the current time t by using the formula (2) A,B (t):
Figure FDA0003952504120000012
L 'in the formula (2)' A,B (t) represents the spatial distance between the heads of two vehicles at the current moment t, v A (t)、v B (t) respectively representing the speeds of the non-motor vehicle A and the vehicle B at the current moment t;
step 2.2, if the speed of the rear vehicle B is greater than that of the front vehicle A at the moment of t +1 or the speed of any one of the non-motor vehicle A and the vehicle B at the moment of t +1 is not 0 in the opposite driving process, indicating that the two vehicles are expected to collide, assigning t +1 to t, returning to the step 2.1 to execute, otherwise, indicating that the two vehicles are not expected to collide, and selecting the minimum value from all calculated collision time of the non-motor vehicle A and the vehicle B to obtain the minimum collision time minTTC A,B
Step 2.3, obtaining the risk grade y of traffic conflict between the non-motor vehicle A and the vehicle B by using the formula (3) A,B If y is A,B If not, executing the step 3; otherwise, returning to the step 1;
Figure FDA0003952504120000013
in the formula (3), θ 1 Representing traffic conflict discrimination thresholds, theta, based on TTC index 2 Representing a traffic conflict risk rating threshold based on the TTC index; y is A,B =0 for slight collision, y A,B =1 denotes a serious collision, y A,B = ∞ denotes no collision;
step 2.4, calculating the traffic conflict risk measurement index of the non-motor vehicle A and the vehicle B at the current moment t by using the formula (4)
Figure FDA0003952504120000021
Figure FDA0003952504120000022
In the formula (4), d A (t) represents the distance between the intersection point of the expected tracks of the two vehicles and the non-motor vehicle A when the non-motor vehicle A and the vehicle B keep the current driving direction unchanged at the current moment t, d B (t) represents the distance between the intersection point of the expected tracks of the two vehicles and the vehicle B when the current driving direction of the non-off motor vehicle A and the vehicle B is kept unchanged at the current moment t;
step 2.5, if the tail of the non-motor vehicle A or the vehicle B passes through the intersection point of the driving tracks of the two vehicles, selecting the minimum value from all the calculated traffic conflict risk measurement indexes and recording the minimum value as the minimum traffic conflict risk measurement index
Figure FDA0003952504120000023
Otherwise, after assigning t +1 to t, returning to the step 2.4 for execution;
step 2.6, calculating the post-invasion time index PET of the non-motor vehicle A and the vehicle B by using the formula (5) A,B
PET A,B =t A -t B (5)
In the formula (5), t A Indicating the moment, t, at which the head of the non-motor vehicle A passes the intersection B Indicating the moment at which the rear of vehicle B that first passed the intersection leaves the intersection;
step 2.7, obtaining the risk level y 'of traffic conflict between the non-motor vehicle A and the vehicle B by utilizing the formula (6)' A,B (ii) a If y' A,B If not, executing the step 3; otherwise, returning to the step 1;
Figure FDA0003952504120000024
in the formula (6), τ 1 、λ 1 Respectively representing risk measurement indexes T based on traffic conflicts 2 Traffic conflict discrimination threshold, τ, for post-intrusion time index PET 2 、λ 2 Respectively representing risk measurement indexes T based on traffic conflicts 2 The traffic conflict risk level of the post-invasion time index PET is divided into threshold values; y' A,B =0 denotes a slight conflict, y' A,B =1 represents a serious collision; y' A,B = ∞ represents no collision;
step 3, extracting K risky driving behaviors of the non-motor vehicle A driver from road camera shooting data shot synchronously with unmanned aerial vehicle aerial photography and forming an interpretation variable set X influencing any ith traffic conflict risk level i =(X i1 ,X i2 ,…,X ik ,…,X iK ) Wherein X is ik The k risky driving behavior of the ith traffic conflict is shown; set X of interpretation variables for making ith traffic conflict risk level i Traffic conflict risk rating y A,B Or y' A,B Is marked as y i (ii) a From X i And y i Forming an ith sample; thus obtaining N samples according to the processes of the step 1 to the step 3;
step 4, establishing a random parameter binomial Logit model with heterogeneity of mean and variance, and quantitatively analyzing influence factors influencing the severity of the traffic conflict of the non-motor vehicles;
step 4.1, when X ik When the variable is a continuous variable, the t test is adopted to X ik Performing single factor significance analysis when X is ik When classifying variables, chi-square test is used for X ik Performing single factor significance analysis, comparing the tested P value with the set significance level alpha, and if the P value is less than the significance level alpha, adding a first interpretation variable set
Figure FDA0003952504120000031
If not, continuing to judge the next risky driving behavior; thus resulting in a final first interpretation variable set->
Figure FDA0003952504120000032
Step 4.2, calculate the final first interpretationVariable set
Figure FDA0003952504120000033
And deleting the interpretation variables with the variance inflation factor larger than or equal to theta to obtain a second interpretation variable set ^ and ^ r>
Figure FDA0003952504120000034
Step 4.3, constructing a stepwise regression model, and integrating the second interpretation variables
Figure FDA0003952504120000035
The explained variables are introduced into the regression equation one by one, all the explained variables in the regression equation are subjected to F test each time the explained variables are introduced, if the P value obtained by the test is more than or equal to the set significant level alpha, the corresponding explained variables are removed, otherwise, the corresponding explained variables are retained, and the third explained variable set (or the third explained variable set) is obtained>
Figure FDA0003952504120000036
Step 4.4, establishing a Logit regression model by using the formula (7):
Figure FDA0003952504120000037
in formula (7), p i Indicates the probability of the ith sample being a severe collision, 1-p i Representing the probability that the ith sample is a slight conflict; beta is a i A parameter vector to be estimated for the ith sample is obtained by the formula (8); epsilon i A random error term for the ith sample;
β i =β+δ i M ii exp(ω i s i )v i (8)
in the formula (8), β represents a parameter vector β i Mean value of (D), M i Is an influence parameter vector beta i Interpretation of the mean variable vector, δ i Is M i Corresponding estimated parameter vector, s i To catch beta i Standard deviation of (a) i Interpretive variable vector of medium heterogeneity, omega i Is s i A corresponding estimated parameter vector; v. of i Is the perturbation term for the ith sample;
step 4.4, assume third set of interpretation variables
Figure FDA0003952504120000041
Parameter vector beta of i Are all random parameters, and specify a probability density function for the distribution of the random parameters, a variable vector M will be explained i And interpreting the variable vector s i Are initialized to a set of interpretation variables X i
Step 4.5, carrying out parameter estimation on the Logit regression model by adopting a simulation-based maximum likelihood method, and solving an estimated parameter vector beta when the likelihood function shown as the formula (9) is maximized i ′、δ′ i 、ω′ i And as a model regression result;
Figure FDA0003952504120000042
step 4.6, according to the model regression result, if the third interpretation variable set
Figure FDA0003952504120000043
In the estimation of the parameter vector beta i If the P values of the standard deviation and the mean value of the corresponding estimated parameters are less than the set significance level alpha, the corresponding interpretation variables are set as random parameters, and the goodness of fit of the Logit regression model is used for determining the corresponding interpretation variables in the estimated parameter vector beta i ' the probability density function of the corresponding estimation parameter, otherwise, the estimation parameter of the corresponding interpretation variable is set as a fixed parameter;
if the variable vector M is explained i Of an interpretive variable in the estimated parameter vector δ' i The P value of the corresponding estimation parameter is less than the set significance level alpha, then the solution is carried outVector of variables M i The corresponding interpretation variable is retained, otherwise, from M i Eliminating corresponding explanation variables;
if the variable vector sigma is explained i Of an interpretive variable in the estimated parameter vector ω' i The P value of the corresponding estimated parameter is less than the set significance level alpha, then the variable vector sigma is explained i In which the corresponding interpretation variable is retained, otherwise, from σ i Eliminating corresponding explanation variables;
step 4.7, processing according to the processes of the step 4.5 to the step 4.6 until the P values of the estimated parameters in the model regression result are all smaller than the set significance level alpha, so as to obtain a final model regression result;
step 4.8, according to the final model regression result, when the third interpretation variable set
Figure FDA0003952504120000044
The mth interpretation variable->
Figure FDA0003952504120000045
For continuous variables, the value of the elasticity coefficient->
Figure FDA0003952504120000046
When interpreting the set of variables->
Figure FDA0003952504120000047
An interpretation variable in->
Figure FDA0003952504120000048
For categorizing a variable, the value of the pseudo-elasticity coefficient ≥ of the variable is calculated using equation (11)>
Figure FDA0003952504120000049
Figure FDA00039525041200000410
Figure FDA00039525041200000411
In the formula (11), the reaction mixture is,
Figure FDA0003952504120000051
indicates when the interpretation variable->
Figure FDA0003952504120000052
Probability of a severe conflict occurring equal to 1, <' >>
Figure FDA0003952504120000053
Indicates when the interpretation variable->
Figure FDA0003952504120000054
Probability of a severe collision occurring when equal to 0;
step 4.9, obtaining a third interpretation variable set according to the process of the step 4.8
Figure FDA0003952504120000055
The marginal effects of all the explained variables in the (A) and the (B) are sorted in descending order, and a third explained variable set is judged to be greater than or equal to>
Figure FDA0003952504120000056
The influence of each risky driving behavior on the traffic conflict risk degree is used as a risk factor evaluation result of the non-motor vehicle traffic conflict at the plane intersection.
2. An electronic device comprising a memory and a processor, wherein the memory is configured to store a program that enables the processor to perform the risk factor assessment method of claim 1, and wherein the processor is configured to execute the program stored in the memory.
3. A computer-readable storage medium, having a computer program stored thereon, wherein the computer program, when executed by a processor, performs the steps of the risk factor assessment method of claim 1.
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* Cited by examiner, † Cited by third party
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