Development and Implementation of a Concept for the Meta Description

of Highway Driving Scenarios with Focus on Interactions of Road Users

Raphael Pfeffer, Jingyu He and Sax Eric

Institute for Information Processing Technologies, Karlsruhe Institute of Technology, Engesserstr. 5, Karlsruhe, Germany

Keywords:

Automated Driving, Scenario based Testing, Meta Model, Simulation Methods, Scenario Classification.

Abstract:

Nowadays reducing the individual risk for advanced driver assistant systems (ADAS) and automated driving

while guaranteeing the overall safety on the highway remains a big challenge. The identification of corner test

1 INTRODUCTION

With the rising public demand on the intelligent and

safe driving functionality, more and more key innova-

tions in the automotive domain include increasingly

autonomous features appeared in the recent decades,

especially under the conditions of driving on the high-

way, like Adaptive Cruise Control (ACC) in 1997

(Winner et al., 2012) and the first Lane Keeping Sup-

port (LKS) system in a Nissan production car in 2001

(Kawazoe et al., 2001). Bearing this in mind, many

metres in the real world. For example, Waymo an-

nounced in 2018 that its autonomous vehicles have

driven more than 16 million kilometres on public

roads in the United States (Alva, 2018). However,

for highly automated driving functions, this approach

is not a economically feasible method for a full vali-

dation as billions of kilometres are needed (Wachen-

feld and Winner, 2016). Contrary to this statisti-

cal approach of physical test coverage, with purely

simulation-based methods, a completeness of the re-

ficiency in test execution. In this context, scenario-

highly automated driving functions, defined scenarios

often serve as the basis for deriving relevant test cases

for the system-under-test (Otten et al., 2018).

However, even scenario-based testing does not an-

swer the question of the completeness of the test cov-

erage, since the prior requirements cannot be derived

in the laboratory for highly automated driving func-

tions. Therefore, in our research work a concept for a

new scenario meta-description is developed. It is ap-

plicable to use recorded data from series or fleet ve-

Development and Implementation of a Concept for the Meta Description of Highway Driving Scenarios with Focus on Interactions of Road Users.

DOI: 10.5220/0009341804400447

In Proceedings of the 6th International Conference on Vehicle Technology and Intelligent Transport Systems (VEHITS 2020), pages 440-447

ISBN: 978-989-758-419-0

Copyright

application of machine learning techniques using this

model data with a first target to discover the similarity

between random scenarios.

tions IV presents the implementation of the scenario

model in a simulation environment and the statistical

results of the generated scenario matrices. Section V

shows the first approach on how the matrices can be

used to classify highway scenarios.

2 RELATED WORK

To test functionality, reliability and maturity of ad-

vanced driver assistance system and automated driv-

ing functions many achievements have been made in

establishing scenario-based testing throughout the de-

is defined as a relationship between the context enti-

ties in the system architecture of automated vehicles.

A scene can be taken as a link between vehicle guid-

ance module and perception module whereas a situ-

ation refers to a central interface in vehicle guidance

(Ulbrich et al., 2014).

Geyer et al. propose a metaphor-based terminol-

ogy that consists of scenario, situation, scenery and

scene of vehicles (Geyer et al., 2014). A driving

scenario of a vehicle is metaphorized as a theatre.

cle (considered system) and instructions they become

a situation. A scenario consists of a series of situa-

tions (Figure 2).

Based on these works Ulbrich summarizes the

definitions and substantiations of the terms scenario,

situation and scene in the product life-cycle of au-

Figure 2: Metaphorical scenario concept according to

(Geyer et al., 2014).

standard development process (Ulbrich et al., 2015).

To be specific, this is intended by use-case and

of at least one scene, action (or events) and goals (or

values). The authors suggest the following definition

for a scenario:

opment between several scenes in a sequence

of scenes. Every scenario starts with an initial

scene. Actions/events as well as goals/values

may be specified to characterize this tempo-

ral development in a scenario. Other than a

scene, a scenario spans a certain amount of

Another description of the scenario concept is pro-

on the previous developments to the scenario term,

Schuldt introduces a test method, which is called a

scenario-based testing approach. In this work a 4

layer model for a testing scenario is developed which

contains different description layers for road geome-

try and topology, situation-specific adaptation of the

road, environment and actors in which the previous

scenario definitions are integrated. Compared with

(Ulbrich et al., 2015), actions and goals are specified

in detail and summarized together with the dynamic

elements as the maneuvers.

Taking into account different requirements for the

representation of scenarios in various process steps

country roads or city streets, and to perform them with

different test tools. Ideally, the structure can support

the standardized usage of scenarios to seamlessly per-

test cases to be adapted to new or modified test ob-

jects. How can scenarios be represented technically

to fulfil the requirements on various layers of abstrac-

tion with a standard format?

cretization for scenes on a highway to three-state pos-

sibilities each in longitudinal and lateral direction.

In doing so, each of the dynamic objects, that ap-

pears surrounding the ego vehicle are taken into ac-

count of the scene description. We use an 1*6 matrix

where the first three digits represent the count of ob-

ject vehicles that longitudinally appear in the front,

same level and behind the ego vehicle. The last three

digits indicate the number of object vehicles that lat-

erally are located in the left lane, the same lane and

the right lane compared to the ego vehicle.

For example, if two object vehicles are longitudi-

lane, as a result, the last three digits of the 1*6 ma-

trix should be 1, 0 and 1. So the whole 1*6 matrix

description should be [0;0;2;1;0;1].

so-called basic maneuvers (e.g. lane change left for

all dynamic objects which allow clear transitions be-

tween the scenes respectively the depicted scenes ab-

straction. To describe the characteristics precisely,

additional parameters are recorded. For longitudinal

maneuvers, these are, for example, the initial and final

velocity, the duration and the distance. Lateral ma-

neuvers are described by the initial position and final

lateral position as well as the duration of the maneu-

ver. The maneuvers and their parameters are captured

and actions previously presented. These are recorded

for all objects along a (recorded) scenario sequence.

Along the time vector, time stamps of scene changes

and action/maneuver changes are stored (Figure5).

Figure 5: Principle of scenario meta information tensor for

dynamic objects.

The scenario description model presented allows the

storage of records of any length according to the pro-

cess described in Figure 1. The question arises, how

sor model (or be extracted from it). For example, a

lengths of time can be compared if they belong to the

same scenario class (e.g. ”overtaking”) since they still

have the same tensor representation length. Figure 6

shows an example for two consecutive scenes (as part

of an e.g. ”overtaking” scenario) and its scene matrix

representation. The 1*12 scenario matrix means the

chronological connection of two 1*6 scene matrices

and represents the transformation of different object

vehicle distributions in a scenario with two scenes.

SIMULATION

To identify the technical feasibility and adopt an engi-

neering assessment, the scenario tensors in the devel-

opment process can be extracted from real highway

driving. In this stage of our work the data is first gen-

erated in a virtual driving simulation. As a replace-

ment for a real test drive, the simulation software Car-

Maker is used. IPG CarMaker is a test platform which

allows to create real-world test scenarios in a vir-

tual environment, simulating every type of road and

Various of virtual sensors can be mounted on the ego

vehicle model representing a vehicle with ADAS or

automated driving functions (Figure 7).

and relative accelerations to all surrounding objects

Figure 7: Vehicle model equipped with sensors in CarMaker

and virtual highway environment.

Table 1: Test series in this work.

Test series 1 17.5 vehicles per km 743.1 km

Test series 2 7.5 vehicles per km 181.9 km

lation run in a post-processing step. In this work, we

density is 17.5 vehicles per kilometer (test series 1).

The other test series represents a lower traffic density

situation of 7.5 vehicles per kilometer, which has 56

vehicles on the 7.3 km highway (test series 2). Based

on these two basic tests we created random variations

by manipulating parameters like cruising speed of ego

vehicle, driver aggressiveness or the lane change be-

haviour of the dynamic objects. Finally, we run all

variations and saved the ego vehicle’s (sensor) data

with a sample rate of 10 samples per second, from

The scenario meta-description has a wide range of

applications. The precise description of a feature

from a whole scenario is among the first. Maneuvers

between two or more unique scenes we can use scene

sequences to identify specific scenarios. Finally, our

concept can be used to identify more complex ma-

neuvers (than the basic maneuvers captured), maneu-

ver sequences, or even specific scenarios in the meta-

description. For this purpose we simply use the scene

encodings in the following application. In this con-

text, the concept can be used to classify and extract

specific scenarios out of a time series which can be

used for a particular unit-under-test. Figure 8 shows

possible examples with its scenario meta-descriptions

for four common scenarios on a highway.

Figure 8: Scenario descriptions using scene matrix.

In today’s scenario-based testing for automated func-

tions, a common approach is the manual scenario

specification (Ulbrich et al., 2015) which can be ex-

tremely time-consuming if parameter boundaries are

scenario meta model to a test process where the data

is derived from real test drives and the scenarios can

be extracted automatically. Doing so, it is a necessity

to be able to distinguish between new and so far un-

seen scenarios and known scenarios from e.g. former

recordings. For an existing database of an arbitrary

quantity of scenarios in terms of the interaction be-

function under test, test scenarios with new features

and new content are added to the existing test scenario

data pool. To solve this task we choose to apply the

narios) in a first implementation which is presented

as follows:

Auto-encoders are artificial neural networks with

the ability to learn a compressed representation (en-

coding) for a set of data and thus also to extract es-

sential features. Therefore, the similarity of exter-

nal data to a training data set can be derived using

the trained auto-encoder. While training the auto-

encoder, the trained model is validated with the val-

idation data in each training epoch. To get the model

with the best performance, the training hyperparame-

ters, in this case batch size and learning rate, are ad-

justed and the average training error is compared after

each training process. The Mean Square Error (MSE)

is used as the reconstruction error.

Figure 9: Calculation for uniqueness of scenario matrix us-

ing auto-encoders.

To ensure the uniqueness of the added data, sce-

the test series 2 data and to filter the data that are sim-

ilar to test series 1. The scenario matrices from test

series 1 in CarMaker are set as the training data and

the data from the test series 2 are used to be detected

resent scenario descriptions consisting of one single

scene up to four consecutive scenes. For the training

data for each auto-encoder, the data set is split into

training data and validation data with a ratio of 9:1.

In the training data from test series 1, scenario with

one unique scene has 1439 samples, scenario with two

unique scenes has 6312 samples, scenario with three

in test series 2 are classified into two classes. Those

with reconstruction errors below the threshold are re-

garded as known scenarios, while the others with re-

Figure 10 describes the confusion matrix for sce-

narios with one unique scene in contrast to scenarios

with four unique scenes. The results are evaluated in a

confusion matrix in which each row of the matrix rep-

resents the scenarios in a predicted class while each

column represents the scenarios in the ground truth.

The visualization for the performance of the two clas-

sifications shows the marked difference in precision

rate. With respect to the rate of positive predicted test

series 2 data, the scenario matrices with one unique

scenarios according to our meta model.

6 FUTURE WORKS

There are lots of additional challenges to be addressed

with regards to the superior testing process we refer

to in the introduction. Some ideas that would need

further investigation are the following. A concept for

the driving scenario meta-description is proposed in

this contribution with its advantages as mentioned be-

fore. However, this concept in the current stage only

considers the behaviour of the dynamic elements of

With regards to the auto-encoder, it has been

shown that the auto-encoder is an efficient algorithm

used so far which do not seem deep enough to learn

more features and fit larger data sets. In the future

study we will extend the structure of auto-encoder so

that it can reconstruct new scenarios more efficiently

and achieve a better performance for classifying the

known and unknown data from the existing scenario

database.

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