Automotive Lidar Modelling Approach Based on Material Properties and Lidar Capabilities

Automotive Lidar Modelling Approach Based on Material Properties and Lidar Capabilities

Development and validation of reliable environment perception systems for automated driving functions requires the extension of conventional physical test drives with simulations in virtual test environments. In such a virtual test environment, a perception sensor is replaced by a sensor model. A ma...

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Vol. 20; no. 11; p. 3309
Main Authors: Muckenhuber, Stefan, Holzer, Hannes, Bockaj, Zrinka
Format: Journal Article
Language:English
Published: Basel MDPI AG 10-06-2020
MDPI
Subjects:
Automation
Automobiles
Cameras
Computer simulation
Infrared radiation
Laboratories
Material properties
Modelling
Parameterization
Perception
Physical tests
Reflectance
Sensors
Simulation
Virtual environments
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Summary:Development and validation of reliable environment perception systems for automated driving functions requires the extension of conventional physical test drives with simulations in virtual test environments. In such a virtual test environment, a perception sensor is replaced by a sensor model. A major challenge for state-of-the-art sensor models is to represent the large variety of material properties of the surrounding objects in a realistic manner. Since lidar sensors are considered to play an essential role for upcoming automated vehicles, this paper presents a new lidar modelling approach that takes material properties and corresponding lidar capabilities into account. The considered material property is the incidence angle dependent reflectance of the illuminated material in the infrared spectrum and the considered lidar property its capability to detect a material with a certain reflectance up to a certain range. A new material classification for lidar modelling in the automotive context is suggested, distinguishing between 7 material classes and 23 subclasses. To measure angle dependent reflectance in the infrared spectrum, a new measurement device based on a time of flight camera is introduced and calibrated using Lambertian targets with defined reflectance values at 10 % , 50 % , and 95 % . Reflectance measurements of 9 material subclasses are presented and 488 spectra from the NASA ECOSTRESS library are considered to evaluate the new measurement device. The parametrisation of the lidar capabilities is illustrated by presenting a lidar measurement campaign with a new Infineon lidar prototype and relevant data from 12 common lidar types.
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ISSN:1424-8220
1424-8220
DOI:10.3390/s20113309