83 Unfall und Mensch
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The main focus of the benefit estimation of advanced safety systems with a warning interface by simulation is on the driver. The driver is the only link between the algorithm of the safety system and the vehicle, which makes the setup of a driver model for such simulations very important. This paper describes an approach for the use of a statistical driver model in simulation. It also gives an outlook on further work on this topic. The build-up process of the model suffices with a distribution of reaction times and a distribution of reaction intensities. Both were combined in different scenarios for every driver. Each scenario has then a specific probability to occur. To use the statistical driver model, every accident scene has to be simulated with each driver scenario (combinations of reaction times and intensities). The results of the simulations are then combined regarding the probabilities to occur, which leads to an overall estimated benefit of the specific system. The model works with one or more equipped participants and delivers a range for the benefit of advanced safety systems with warning interfaces.
This work describes the results of the experimental activity, illustrating the driving behavior observed in different conditions, relating them to the different methods of ADAS intervention and comparing the driver behavior without ADAS. In the present study, driver behavior was studied in road accidents involving elderly pedestrians, with different ADAS HMIs, as a base to develop a driver model in near missing pedestrian accidents. A literature research was conducted with the aim of finding out the main influencing factors, including environment, boundary conditions, configuration of impact, pedestrian and driver information, when pedestrian fatalities occur and an analysis of frequent road accidents was conducted to get more detailed information about the driver- behavior. In order to obtain more detailed information about pedestrian accidents, real road accidents were reconstructed with multibody simulations on PC-Crash and, by the comparison between literature findings and reconstructions, a generic accident scenario was defined. The generic accident scenario was implemented on the full scale dynamic driving simulator in use at the Laboratory for Safety and Traffic Accident Analysis (LaSIS, University of Florence, Italy) in order to analyse the driving behaviors of volunteers, also considering the influence of ADAS devices. Forty-five young volunteers were enrolled for this study, resulting in forty valid tests on different testing scenarios. Two different scenarios consisted in driving with or without ADAS in the vehicle. Different kinds of ADAS, acoustic and optical, with different time of intervention were tested in order to study the different reactions of the driver. The tests showed some interesting differences between driver's behavior when approaching the critical situation. Drivers with ADAS reacted earlier, but more slowly, depending also on the type of alarm, and often with double reaction when braking. In fact, the results of the activity showed that with ADAS intervention the time to collision (TTC) increases, but the reaction time and braking modality change: a) there is a sort of "latency" time between the accelerator pedal release and the brake pressure; b) the brake pressure is initially less intense. So the driver only partially takes advance from the TTC increase. These differences were valued not only qualitatively, but quantitatively as well. This work revealed to be useful to improve the knowledge of drivers" behavior, in order to realize a driver model that can be implemented to help attaining and assessing higher levels of automation through new technology.
Nach Anlage 5 (2) der Fahrerlaubnisverordnung (FeV) verlangt der Gesetzgeber von Bewerbern um die Erteilung oder Verlängerung einer Fahrerlaubnis der Klassen D, D1, DE, D1E sowie der Fahrerlaubnis zur Fahrgastbeförderung die Erfüllung besonderer Anforderungen hinsichtlich Belastbarkeit, Orientierungsleistung, Konzentrationsleistung, Aufmerksamkeitsleistung sowie Reaktionsfähigkeit. Die zur Untersuchung dieser Merkmale eingesetzten testpsychologischen Verfahren müssen nach dem Stand der Wissenschaft standardisiert und unter Aspekten der Verkehrssicherheit validiert sein. Zur Klärung der Fragen, wie ausgedehnt das Spektrum eingesetzter und akzeptierter Testverfahren ist und welche Erfahrungen die Gutachter bisher gemacht haben, fand am 07.11.2000 in der Bundesanstalt für Straßenwesen ein Expertengespräch statt. Dieses Gespräch zeigte unter anderem folgende Ergebnisse: Zum Einsatz kommen insbesondere das Act-and-React-Testsystem (ART) und das Wiener Testsystem (WTS), weiterhin die Testbatterien zur Aufmerksamkeitsprüfung (TAP). Die als Grenzwerte festgelegten Prozentränge von 33 beziehungsweise 16 sind empirische Setzungen, als Referenz wurden bewusst altersunabhängige Normwerte gewählt. In einigen Bundesländern sind die Begutachtungsstellen für Fahreignung erste Anlaufstellen, in anderen die Betriebs- oder Arbeitsmediziner. Die Durchführung der Testverfahren kann durch einen qualifizierten Arzt, Psychologen oder eine geschulte Testassistentin erfolgen. Sobald sich die Frage einer Kompensationsprüfung stellt, ist eine differenzierte psychologische Untersuchung erforderlich. Bei unauffälligen Befunden kann das Gutachten weitgehend standardisiert sein. Abschließend sind Forderungen für die weitere Entwicklung formuliert.
Nowadays human-created systems are increasing in complexity due to the interaction of humans and technology. Especially road traffic systems are composed of multitudinous resources (e.g. personnel, vehicles, organizations, etc.), which make it even harder to anticipate the positive and negative effects on safety. One key in achieving a significant reduction of fatalities is seen in driver assistant systems counterbalancing the lack of drivers' capabilities. But the actual outcome of implementing these sophisticated technologies especially on influencing driver's capabilities are yet unknown. Latest research exemplifies an increase of reaction times of drivers in case of dysfunctional driver assistant systems. This research paper applies STAMP/STPA (STAMP = systems-theoretic accident model and processes; STPA = systems-theoretic process analysis) to the German automobile traffic system focusing on the effects of driver assistant systems on drivers. By doing so, the potential hazards caused by technology can be identified.