CN111915888A - Method for calculating complexity of traffic participants in automatic driving test scene - Google Patents

Abstract

The invention relates to a method for calculating the complexity of traffic participants in an automatic driving test scene, which comprises the following steps: s1: obtaining dynamic parameter threshold values R of all types of traffic participants in test scene_type(ii) a S2: according to the initial state of each traffic participant and the dynamic parameter threshold value R_typeAnd calculating to obtain a corresponding longitudinal sampling distance set S^type(ii) a S3: obtaining a longitudinal sampling distance set S through an optimization search algorithm^typeThe optimal longitudinal control quantity corresponding to each sampling distance; s4: calculating the reachable domain omega of each traffic participant within the predicted time t according to the sampling distance and the optimal longitudinal control quantity^type(ii) a S5: according to the reachable domain omega of each traffic participant^typeCompared with the prior art, the method for calculating the complexity H of the traffic participants in the test scene provides basis for the state and parameter design of the dynamic traffic participants in the automatic driving test scene, and has the advantages ofThe efficiency of the automatic driving automobile test is improved.

Description

Method for calculating complexity of traffic participants in automatic driving test scene

Technical Field

The invention relates to the field of testing and evaluation in the technology of automatically driving automobiles, in particular to a method for calculating the complexity of a traffic participant in an automatically driving test scene.

Background

In recent years, the technology of autonomous driving cars is one of the hot spots of current research, both in academic and industrial areas. However, with the rapid development of the automatic driving technology, the frequent occurrence of dangerous accidents gradually highlights some safety-oriented problems. One of the means to solve these problems is to perform accurate, sufficient, and complete tests on an autonomous vehicle. A complete test process, which comprises the steps of carrying out multiple tests on a tested object in the same environment, quantizing the test result by using standard evaluation indexes, and then feeding back to a test scene designer; and the designer iterates and updates the arrangement and the layout of the test scene according to the evaluation result so as to accelerate the test process of the automatic driving automobile and improve the test efficiency.

However, at present, the evaluation of the automatic driving test scenario lacks a unified standard, which includes the complexity evaluation of a typical test scenario of each vehicle driven by an individual vehicle, especially the related research of a complexity quantification method of dynamic traffic participants in the test scenario, resulting in poor lateral comparability of the dynamic traffic participants and the test scenario under different parameter configurations. Therefore, the research of the complexity quantification of the dynamic traffic participants in the automatic driving test scene is a big vacancy in the field.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provide a method for calculating the complexity of traffic participants in an automatic driving test scene, fill the blank of the research field of the complexity quantification of dynamic traffic participants in the automatic driving test scene, provide a basis for the design and arrangement of the dynamic traffic participants in the automatic driving test scene, enable different complexity scenes facing the same tested object or different tested objects under the same complexity to have a transverse contrast condition, improve the efficiency of testing an automatic driving automobile and accelerate the landing of the automatic driving automobile.

The purpose of the invention can be realized by the following technical scheme:

a method for calculating the complexity of traffic participants in an automatic driving test scene comprises the following steps:

s1: obtaining dynamic parameter threshold values R of all types of traffic participants in test scene_type；

S2: according to the initial state of each traffic participant and the dynamic parameter threshold value R_typeAnd calculating to obtain a corresponding longitudinal sampling distance set S^type；

S3: obtaining a longitudinal sampling distance set S through an optimization search algorithm^typeThe optimal longitudinal control quantity corresponding to each sampling distance;

s4: calculating the reachable domain omega of each traffic participant within the predicted time t according to the sampling distance and the optimal longitudinal control quantity^type；

S5: according to the reachable domain omega of each traffic participant^typeAnd calculating the complexity H of the traffic participants of the test scene.

Further, the kinetic parameter threshold value R_typeThe expression of (a) is:

R_type＝(A,D)

wherein type is the type of the traffic participant, A is the longitudinal maximum acceleration of the traffic participant, and D is the longitudinal minimum deceleration of the traffic participant.

Further preferably, the initial state of the transportation participant comprises an initial position S₀Initial velocity v₀And an initial acceleration a₀。

Further, the longitudinal control amount includes acceleration and deceleration of the vehicle in the longitudinal direction.

Still further preferably, said set of longitudinal sampling distances S is characterized by^typeIncluding the initial state and dynamic parameter threshold value R of the corresponding traffic participant within the prediction time t_typeDown, reachable position and initiationPosition S₀The longitudinal distance of (a).

Further, the step S3 specifically includes:

s31: initializing the jth sampling distance

Longitudinal control amount of

S32: calculating the longitudinal control quantity of the corresponding traffic participant

Next, the longitudinal distance S that can be reached within the time t is predicted_i；

S33: judging the calculated longitudinal distance S_iWhether or not to equal the sampling distance

Corresponding preset longitudinal distance S_jIf yes, outputting the current longitudinal control quantity

As the sampling distance

Is controlled by the optimum longitudinal control quantity U_j ^*Otherwise, go to step S34;

s34: to make the sampling distance

Optimizing search for direction with maximized transverse distance X, and updating longitudinal control quantity

And returns to perform step S32;

s35: and repeatedly executing the steps S31-S34 until the optimal longitudinal control quantity corresponding to all the sampling distances is obtained.

Further, it is characterized byThe optimal longitudinal control quantity comprises n longitudinal discrete control quantities a in the prediction time t_iThe step S4 specifically includes:

s41: for longitudinal discrete control quantity a_iIterative search is carried out, and the jth sampling distance of the corresponding traffic participant is calculated

Next, the maximum lateral distance X that can be achieved by the motion trajectory within the prediction time t is predicted_maxDetermining the track boundary at the sampling distance;

s42: repeatedly executing the step S41 to obtain the track boundaries under all the sampling distances, and obtaining the reachable domain omega of the corresponding traffic participant within the prediction time t according to the track boundaries under all the sampling distances^type；

S43: repeating the steps S41-S42 to obtain the reachable domain omega of each traffic participant within the predicted time t^type。

Further, the step S5 specifically includes:

s51: calculate reachable Domain omega^typeArea and the reachable region omega selected by the corresponding traffic participant is obtained^typeThe probability of a certain track is recorded as the track probability

S52: calculating motion trail complexity H of each traffic participant in test scene based on information entropy theory_txpe；

S53: judging whether the number of the traffic participants in the test scene is more than one, if so, executing a step S54, otherwise, outputting the motion trail complexity H of the traffic participants_typeThe complexity H of the traffic participants as a test scenario;

s54: the reachable domain omega of all traffic participants in the test scene^typeSumming the sets and subtracting the reachable domain omega^typeObtaining the total reachable domain of the test scene according to the area occupied by the sizes of all the traffic participants;

s55: obtaining the total complexity of the test scenario by using the total reachable domain calculationH_totalTraffic participant complexity H as a test scenario.

Furthermore, the motion trail complexity H of the traffic participant_typeThe calculation formula of (A) is as follows:

wherein the content of the first and second substances,

in the reachable domain omega for traffic participants^typeProbability of selecting x tracks from the inner m tracks.

The total complexity H_totalThe calculation formula of (A) is as follows:

wherein the content of the first and second substances,

the reachable domain of the tau-th traffic participant is shown, and M is the number of the traffic participants in the test scene.

Preferably, the type of transportation participant comprises a car, a bus, a motorcycle, a bicycle and a pedestrian.

Compared with the prior art, the invention has the following advantages:

1) the method for quantizing the complexity of the dynamic traffic participants in the automatic driving test scene can fill the gap of the method for quantizing the complexity of the current automatic driving test scene, provides a basis for the design and arrangement of the dynamic traffic participants in the automatic driving test scene, enables different complexity scenes facing the same tested object or different tested objects under the same complexity to have transverse comparison conditions, and improves the efficiency of testing the automatic driving automobile, so that the problems of a tested automobile system can be quickly found, the iterative update of the automatic driving automobile is promoted, and the landing of the automatic driving automobile is accelerated;

2) the method utilizes the information entropy theory to calculate the motion trail complexity of the traffic participants in the automatic driving test scene, and improves the accuracy of the calculation of the test scene complexity;

3) the method is based on vehicle kinematics, the transverse and longitudinal motions of the vehicle are described by using the control quantity, and the calculated vehicle reachable region can relatively comprehensively reflect the driving possibility of the vehicle in a certain prediction time in the future based on the current state, so that the complexity calculation of the traffic participants determined by the reachable region is relatively reasonable;

4) the algorithm used by the invention is developed and completed on MATLAB, and can also be used for calculating the vehicle reachable domain and complexity under the determined vehicle control quantity obtained by the subsequent simulation of vehicle motion control.

Drawings

FIG. 1 is a schematic flow chart of the method of the present invention;

FIG. 2 is a schematic overall flow chart of the present invention;

FIG. 3 is a flow chart of an optimized search algorithm of the present invention;

FIG. 4 is a schematic diagram of reachable domains of traffic participants in a test scenario of an embodiment, where (4a) is the maximum reachable domain of a bus, and (4b) is the maximum reachable domain of a car;

FIG. 5 is a schematic diagram of the total reachable region of two vehicles in the test scenario of the embodiment.

Detailed Description

The invention is described in detail below with reference to the figures and specific embodiments. It is to be understood that the embodiments described are only a few embodiments of the present invention, and not all embodiments. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, shall fall within the scope of protection of the present invention.

As shown in fig. 1, the present invention provides a method for calculating complexity of traffic participants in an automatic driving test scenario, comprising the following steps:

s1: obtaining dynamic parameter threshold values R of all types of traffic participants in test scene_type；

S2: according to the initial state of each traffic participant and the dynamic parameter threshold value R_typeAnd calculating to obtain a corresponding longitudinal sampling distance set S^type；

S3: obtaining a longitudinal sampling distance set S through an optimization search algorithm^typeThe optimal longitudinal control quantity corresponding to each sampling distance;

s4: calculating the reachable domain omega of each traffic participant within the predicted time t according to the sampling distance and the optimal longitudinal control quantity^type；

S5: according to the reachable domain omega of each traffic participant^typeAnd calculating the complexity H of the traffic participants of the test scene.

(1) Step S1

S1: obtaining dynamic parameter threshold values R of all types of traffic participants in test scene_typeThreshold value R of kinetic parameter_typeThe expression of (a) is:

R_type＝(A,D)

wherein type is the type of the traffic participant, A is the longitudinal maximum acceleration of the traffic participant, and D is the longitudinal minimum deceleration of the traffic participant.

Firstly, determining the dynamic parameter threshold value range R of different types of traffic participants_type(A, D), wherein the dynamic parameters are the longitudinal maximum acceleration A and the minimum deceleration D of the traffic participant, namely the dynamic parameter threshold range R_typeThe set of (c) may be:

wherein A is_carFor maximum acceleration of the car, D_carFor minimum deceleration of cars, A_busMaximum acceleration of the passenger car, D_busFor minimum deceleration of passenger cars, A_motoFor maximum acceleration of the motorcycle, D_motoFor minimum deceleration of motorcycle, A_bikeMaximum acceleration of the bicycle, D_bikeFor minimum deceleration of the bicycle, the invention takes into account different traffic participantsSize and dynamics parameters, which classify the type of traffic participant including, but not limited to, cars, coaches, motorcycles, bicycles, pedestrians, etc.

(2) Step S2

S2: according to the initial state of each traffic participant and the dynamic parameter threshold value R_typeAnd calculating to obtain a corresponding longitudinal sampling distance set S^type。

The initial state of the vehicle includes an initial position S₀Initial velocity v₀And an initial acceleration a₀A set of determined longitudinal sampling distances S^typeThe element in (1) is a sampling distance, namely a longitudinal distance between an initial position point and an reachable point:

m is the number of sampling distances, and the distance interval between each sampling distance can be set to 1m or other values.

(3) Step S3-step S4

S3: obtaining a longitudinal sampling distance set S through an optimization search algorithm^typeCorresponding to each sampling distance.

S4: calculating the reachable domain omega of each traffic participant within the predicted time t according to the sampling distance and the optimal longitudinal control quantity^type。

Dynamic parameter threshold R from using an optimized search algorithm_typeSelecting within range at each sampling distance

Lower optimal longitudinal control quantity U_j ^*：

Wherein the optimum longitudinal control quantity U_j ^*Longitudinal discrete control quantity a contained in predicted time t_i(i-1, 2, …, n), n being the predicted timeDiscrete control quantity a in t_iThe number of (a) and each discrete control amount a_iThe time interval therebetween is Δ t.

By controlling the discrete control quantity a_iIterative search is carried out to calculate the sampling distance of the traffic participants within the predicted time t

The maximum lateral distance X of the track can be reached, further the reachable domain determined by the track boundary under the sampling distance is determined, and finally the reachable domain omega of the traffic participant in the prediction time t is obtained^type：

The optimization search algorithm specifically comprises the following steps:

s31: initializing the jth sampling distance

Longitudinal control amount of

S32: calculating the longitudinal control quantity of the corresponding traffic participant

Next, the longitudinal distance S that can be reached within the time t is predicted_i；

S33: judging the calculated longitudinal distance S_iWhether or not to equal the sampling distance

Corresponding preset longitudinal distance S_jIf yes, outputting the current longitudinal control quantity

As the sampling distance

Is controlled by the optimum longitudinal control quantity U_j ^*Otherwise, go to step S34;

s34: to make the sampling distance

Optimizing search for direction with maximized transverse distance X, and updating longitudinal control quantity

And returns to perform step S32;

s35: and repeatedly executing the steps S31-S34 until the optimal longitudinal control quantity corresponding to all the sampling distances is obtained.

The iterative search specifically comprises the following steps:

s41: for longitudinal discrete control quantity a_iIterative search is carried out, and the jth sampling distance of the corresponding traffic participant is calculated

Next, the maximum lateral distance X that can be achieved by the motion trajectory within the prediction time t is predicted_maxDetermining the track boundary at the sampling distance;

s42: repeatedly executing the step S41 to obtain the track boundaries under all the sampling distances, and obtaining the reachable domain omega of the corresponding traffic participant within the prediction time t according to the track boundaries under all the sampling distances^type；

S43: repeating the steps S41-S42 to obtain the reachable domain omega of each traffic participant within the predicted time t^type。

(4) Step S5

S5: according to the reachable domain omega of each traffic participant^typeAnd calculating the complexity H of the traffic participants of the test scene.

For convenience of calculation, the trajectory of the traffic participant is considered to be in the reachable domain Ω^typeThe interior is uniformly distributed, and the vehicle selects the track probability of a certain track in the reachable domain

Wherein<Ω^type>To pass the reachable domain area of the traffic participant under the constraint of the kinetic parameters,

when the complexity H of the traffic participants of the test scene is calculated based on the information entropy theory, two situations are specifically included:

(1) only one traffic participant exists in the scene, and the motion trail complexity H of the traffic participant_typeI.e. the traffic participant complexity H of the test scenario.

At the moment, the probability parameter P in the information entropy calculation formula is the probability that the vehicle selects a certain track x in the reachable domain, namely

I.e. the complexity of the movement path of the traffic participant H_typeThe calculation formula of (A) is as follows:

(2) a plurality of traffic participants are arranged in the scene

At the moment, the reachable domains of M different traffic participants in the same scene need to be merged, the area occupied by the size of the traffic participants in the reachable domains is subtracted, the total reachable domain in the scene is obtained, and finally the total complexity H of the test scene is obtained_totalComplexity H of traffic participants as test scenario, total complexity H of test scenario_totalThe calculation formula of (A) is as follows:

wherein the content of the first and second substances,

the reachable domain of the tau-th traffic participant is shown, and M is the number of the traffic participants in the test scene.

Example 1

In this embodiment, the traffic participant types in the test scenario include car (car) and bus (bus), and it is determined that the dynamic parameter thresholds of the car (car) and the bus (bus) are respectively:

threshold value R of dynamic parameter of car_car(-7.5,6.9), bus dynamics parameter threshold, R_bus＝(-6.0,4.0)。

The initial state parameter configuration of two kinds of vehicles is the same, specifically:

S₀＝0；

a₀＝0.5；(ms^-2)

v₀＝15；(ms^-1)

then, calculating according to the initial state of the vehicle and the dynamic threshold range to obtain the final longitudinal position 15 of the full-force deceleration of the car and the final longitudinal position 162 of the full-force acceleration of the car, so that the car sampling distance set S^carSample distance set S of 16,17, …,162 for a similarly large bus^bus＝{19,20,…,125}。

The optimal longitudinal control quantity corresponding to each sampling distance is obtained through optimization search, the coordinate parameter of the vehicle under each timestamp is determined according to the optimal longitudinal control quantity, the maximum reachable domain boundaries of the car and the bus obtained after connection of each coordinate point are respectively shown in fig. 4, and the reachable domain range is the range of the region which the vehicle can reach when the vehicle starts from the lane center line position of the lower lane and changes lanes to the upper lane.

In this embodiment, each longitudinal sampling distance

The determined reachable domain boundary is composed of 50 points, and the time interval between each coordinate point is 0.1s, so that the predicted time t is 5s in the embodiment, that is, the reachable domain of the vehicle in the future of 5s can be obtained.

After the sampling distance sets and the optimal longitudinal control quantity of the two vehicles are obtained, the reachable domain areas of the two vehicles can be calculated: calculating the reachable area omega for each longitudinal sampling distance^typeObtaining the maximum reachable domain area omega of the car through iteration^car＝830.5701m²Maximum reachable area omega of bus^bus＝616.2915m²And is combined withCalculating the motion track complexity H of the car_car9.70BIT, motion trajectory complexity H of motor coach_bus＝9.27BIT。

When the car and the bus are located in the same test scene, as shown in fig. 5, the total area of the reachable region in the test scene is the area of the reachable region of the car minus the area occupied by the bus, the size of the bus selected in this embodiment is 5990mm, the width is 2050mm, that is, the total reachable region area is Ω_total＝818.2736m²Finally, the total complexity H of the scene is obtained through calculation_total＝9.67BIT。

While the invention has been described with reference to specific embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. A method for calculating the complexity of traffic participants in an automatic driving test scene is characterized by comprising the following steps:

s1: obtaining dynamic parameter threshold values R of all types of traffic participants in test scene_type；

S2: according to the initial state of each traffic participant and the dynamic parameter threshold value R_typeAnd calculating to obtain a corresponding longitudinal sampling distance set S^type；

S3: obtaining a longitudinal sampling distance set S through an optimization search algorithm^typeThe optimal longitudinal control quantity corresponding to each sampling distance;

s4: calculating the reachable domain omega of each traffic participant within the predicted time t according to the sampling distance and the optimal longitudinal control quantity^type；

S5: according to the reachable domain omega of each traffic participant^typeAnd calculating the complexity H of the traffic participants of the test scene.

2. An autonomous drive according to claim 1The method for calculating the complexity of the traffic participants in the test scene is characterized in that the dynamic parameter threshold value R_typeThe expression of (a) is:

R_type＝(A,D)

wherein type is the type of the traffic participant, A is the longitudinal maximum acceleration of the traffic participant, and D is the longitudinal minimum deceleration of the traffic participant.

3. The method as claimed in claim 2, wherein the initial state of the traffic participant comprises an initial position S₀Initial velocity v₀And an initial acceleration a₀。

4. The method of claim 1, wherein the longitudinal control variables comprise acceleration and deceleration of the vehicle in a longitudinal direction.

5. The method as claimed in claim 3, wherein the set of vertical sampling distances S is a set of vertical sampling distances S^typeIncluding the initial state and dynamic parameter threshold value R of the corresponding traffic participant within the prediction time t_typeThe reachable position and the initial position S₀The longitudinal distance of (a).

6. The method for calculating the complexity of the traffic participants in the automatic driving test scenario as claimed in claim 1, wherein the step S3 specifically includes:

s31: initializing the jth sampling distance

Longitudinal control amount of

S32: calculating the longitudinal control quantity of the corresponding traffic participant

Next, the longitudinal distance S that can be reached within the time t is predicted_i；

S33: judging the calculated longitudinal distance S_iWhether or not to equal the sampling distance

Corresponding preset longitudinal distance S_jIf yes, outputting the current longitudinal control quantity

As the sampling distance

Is controlled by the optimum longitudinal control quantity U_j ^*Otherwise, go to step S34;

s34: to make the sampling distance

Optimizing search for direction with maximized transverse distance X, and updating longitudinal control quantity

And returns to perform step S32;

s35: and repeatedly executing the steps S31-S34 until the optimal longitudinal control quantity corresponding to all the sampling distances is obtained.

7. The method as claimed in claim 6, wherein the optimal longitudinal control quantity comprises n longitudinal discrete control quantities a within the predicted time t_iThe step S4 specifically includes:

s41: for longitudinal discrete control quantity a_iPerforming iterative search to calculate pairsShould the traffic participant at the jth sampling distance

Next, the maximum lateral distance X that can be achieved by the motion trajectory within the prediction time t is predicted_maxDetermining the track boundary at the sampling distance;

s42: repeatedly executing the step S41 to obtain the track boundaries under all the sampling distances, and obtaining the reachable domain omega of the corresponding traffic participant within the prediction time t according to the track boundaries under all the sampling distances^type；

S43: repeating the steps S41-S42 to obtain the reachable domain omega of each traffic participant within the predicted time t^type。

8. The method for calculating the complexity of the traffic participants in the automatic driving test scenario as claimed in claim 1, said step S5 specifically includes:

s51: calculate reachable Domain omega^typeArea and the reachable region omega selected by the corresponding traffic participant is obtained^typeThe probability of a certain track is recorded as the track probability

S52: calculating motion trail complexity H of each traffic participant in test scene based on information entropy theory_type；

S53: judging whether the number of the traffic participants in the test scene is more than one, if so, executing a step S54, otherwise, outputting the motion trail complexity H of the traffic participants_typeThe complexity H of the traffic participants as a test scenario;

s54: the reachable domain omega of all traffic participants in the test scene^typeSumming the sets and subtracting the reachable domain omega^typeObtaining the total reachable domain of the test scene according to the area occupied by the sizes of all the traffic participants;

s55: obtaining the total complexity H of the test scene by using the total reachable domain calculation_totalTraffic participant complexity H as a test scenario.

9. The method as claimed in claim 7, wherein the complexity of the motion trajectory of the traffic participant is H_typeThe calculation formula of (A) is as follows:

wherein

In the reachable domain omega for traffic participants^typeProbability of selecting x track from the inner m tracks;

the total complexity H_totalThe calculation formula of (A) is as follows:

wherein the content of the first and second substances,

the reachable domain of the tau-th traffic participant is shown, and M is the number of the traffic participants in the test scene.

10. The method of claim 1, wherein the traffic participants are of the type selected from the group consisting of cars, coaches, motorcycles, bicycles, and pedestrians.

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