Steve Pechberti scite author profile

Development of Full Speed Range ACC with SiVIC, a virtual platform for ADAS Prototyping, test and evaluation

Gruyer¹,

Pechberti²,

Glaser³

2013

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Abstract-LIVIC-IFSTTAR develops driving assistance services in order to improve the driving safety. These systems are tested on several real prototypes equipped with sensors and perception, decision and control modules. But tests on real prototypes are not always available, effectively some hardware architectures could be too expensive to implement, scenario may lead to hazardous situations. Moreover, lots of reasons could lead to the inability to obtain both sensors and ground truth data for ADAS evaluation. However, safety applications must be tested in order to guaranty their reliability. For this task, simulation appears as a good alternative to the real prototyping and testing stages. In this context, the simulation must provide the same opportunities as reality, by providing all the necessary data to develop and to prototype different types of ADAS based on local or extended environment perception. The sensor data provided by simulation must be as noised and imperfect as those obtained with real sensors. To address this issue, the SiVIC platform has been developed; it provides a virtual road environment including realistic dynamic models of mobile entities (vehicles), realistic sensors, and sensors for ground truth. To test real embedded applications, an interconnection has been developed between SiVIC and third party applications (ie. RTMaps). In this way, the prototyped application can be directly embedded in real prototypes in order to test it in real conditions. A Full Speed Range ACC application is presented in this paper to illustrate the capabilities and the functionalities of this virtual platform.

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Collision warning dissemination in vehicles strings: An empirical measurement

Demmel

¹

,

Gruyer²,

Besnier³

et al. 2011

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Proposal of a virtual and immersive 3D architecture dedicated for prototyping, test and evaluation of eco-driving applications

Gruyer¹,

Orfila²,

Judalet³

et al. 2013

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Radar simulation in SiVIC platform for transportation issues. Antenna and propagation channel modelling

Pechberti¹,

Gruyer²,

Vigneron

³

2012

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This paper proposes a new radar sensor modelling for Advanced Driver Assistance Systems (ADAS) prototyping. The model is embedded on the SiVIC platform (Simulator for Vehicle, Infrastructure and Sensors). Lots of simulators already exist for this issue, but none is designed to address the objectives of real-time computation, highly sampled signal generation. And few simulators offer the ability to be integrated in a dynamic platform for the ADAS prototyping. In this paper, several radar technologies will be presented. Then, a radar designed especially for automotive domain will be described exploring each subparts, radar antenna andi.e. propagation channel. Such as the generic model, hypothesis done on electromagnetic waves and environmental objects modelling will also be provided. A first model of simple duplex radar with Frequency Shift Keying (FSK) modulation is implemented and shown as illustration for the defined architecture. Finally, in order to optimize the duration for signal generation, several software architecture solution will be proposed.

show abstract

Development of Full Speed Range ACC with SiVIC, a virtual platform for ADAS Prototyping, Test and Evaluation

Gruyer¹,

Pechberti²,

Glaser³

2013

View full text Add to dashboard Cite

Abstract-LIVIC-IFSTTAR develops driving assistance services in order to improve the driving safety. These systems are tested on several real prototypes equipped with sensors and perception, decision and control modules. But tests on real prototypes are not always available, effectively some hardware architectures could be too expensive to implement, scenario may lead to hazardous situations. Moreover, lots of reasons could lead to the inability to obtain both sensors and ground truth data for ADAS evaluation. However, safety applications must be tested in order to guaranty their reliability. For this task, simulation appears as a good alternative to the real prototyping and testing stages. In this context, the simulation must provide the same opportunities as reality, by providing all the necessary data to develop and to prototype different types of ADAS based on local or extended environment perception. The sensor data provided by simulation must be as noised and imperfect as those obtained with real sensors. To address this issue, the SiVIC platform has been developed; it provides a virtual road environment including realistic dynamic models of mobile entities (vehicles), realistic sensors, and sensors for ground truth. To test real embedded applications, an interconnection has been developed between SiVIC and third party applications (ie. RTMaps). In this way, the prototyped application can be directly embedded in real prototypes in order to test it in real conditions. A Full Speed Range ACC application is presented in this paper to illustrate the capabilities and the functionalities of this virtual platform.

show abstract

Steve Pechberti

Development of Full Speed Range ACC with SiVIC, a virtual platform for ADAS Prototyping, test and evaluation

Collision warning dissemination in vehicles strings: An empirical measurement

Proposal of a virtual and immersive 3D architecture dedicated for prototyping, test and evaluation of eco-driving applications

Radar simulation in SiVIC platform for transportation issues. Antenna and propagation channel modelling

Development of Full Speed Range ACC with SiVIC, a virtual platform for ADAS Prototyping, Test and Evaluation

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