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Die Europäischen Normen für Erdarbeiten werden im CEN/TC 396 "Earthworks" erarbeitet. Das Sekretariat des CEN/TC 396 wird vom französischen Normungsinstitut AFNOR gehalten. Die Normungsarbeit wird im DIN-Ausschuss NA 005-05-22 AA "Erdarbeiten (SpA zu CEN/TC 396), Gemeinschaftsausschuss mit FGSV GA 5.01" gespiegelt. Vertreter des Spiegelausschussesarbeiten in den verschiedenen Arbeitsgruppen (working groups (WG)) des CEN/TC 396 mit. In den Jahren 2009 und 2010 wurden die Gremien konstituiert und mit der Normungsarbeit begonnen, zunächst überwiegend durch die Zusammenstellung der vorhandenen Regelungen in den Mitgliedsstaaten (siehe auch Beitrag Vogel/Leister/Heyer zur Erd- und Grundbautagung 2013). Im November 2014 wurden vom CEN/TC 396 die Arbeitsaufträge("work items") offiziell gestartet.
Die Europäischen Normen für Erdarbeiten werden im CEN/TC 396 "Earthworks" erarbeitet. Das Sekretariat des CEN/TC 396 wird vom französischen Normungsinstitut AFNOR gehalten. Die Normungsarbeit wird im DIN-Ausschuss NA 005-05-22 AA "Erdarbeiten (SpA zu CEN/TC 396), Gemeinschaftsausschuss mit FGSV GA 5.01" gespiegelt. Vertreter des Spiegelausschusses arbeiten in den verschiedenen Arbeitsgruppen (Working Groups (WG)) des CEN/TC 396 mit. In den Jahren 2009 und 2010 wurden die Gremien konstituiert und mit der Normungsarbeit begonnen, zunächst überwiegend durch die Zusammenstellung der vorhandenen Regelungen in den Mitgliedsstaaten (siehe auch Beitrag Vogel/Leister/Heyer zur Erd- und Grundbautagung 2013). Im November 2014 wurden vom CEN/TC 396 die Arbeitsaufträge ("work items") offiziell gestartet.
Im Rahmen des Forschungsprojektes Cyber-Safe fand am 10. März 2016 bei der Bundesanstalt für Straßenwesen (BASt) in Bergisch Gladbach ein Workshop zum Thema "Steigerung der IT-Sicherheit von Verkehrs- und Tunnelleitzentralen" statt. An diesem Workshop beteiligten sich 40 Experten der Verkehrs- und Tunnelüberwachung. Die Tätigkeitsfelder der Teilnehmer reichten von Tunneloperatoren über Tunnelmanager und IT-Fachleute bis hin zu Sicherheitsbeauftragten.
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.
In-depth accident investigation offers many advantages for the analysis and comprehension of crash mechanisms. IFSTTAR makes such investigations since 1992 without interruption. The corresponding database contains more than 1200 accident case studies. Currently, in-depth accident investigation is one of the best ways to determine the speed or cars involved in accidents. This paper first presents the methods used for accident investigation and for accident kinematic reconstruction. Then, in order to illustrate the interest and possible applications of such accident data, it shows some results from a recent study based on the IFSTTAR in-depth accident study programme (IDAS) and dealing with the link between travelling speed and accident risk.
This study investigates the protection offered by passive head-restraints with different stiffness and energy dissipation properties. For this purpose, computational multi-body models of a generic car seat and a biofidelic 50thpercentile male human for rear impact are used to study different seat designs and passive head-restraints. The validated seat-occupant model is also used in the design of two different car-seat models which are shown to effectively mitigate whiplash by utilising a crash-energy distribution technique. Five different passive head-restraints with varying stiffness (low-medium-high) and energy dissipation percentages (low-high) are successively attached to four different car-seat models. The simulation results indicate that the protection offered by head restraints is strongly dependent on the seat design. It has also been shown that the stiffness of the passive head-restraint has much more influence on whiplash-risk in comparison to its energy dissipation capacity.
At IAM RoadSmart we share the excitement about autonomous cars " who wouldn't! However over half of the drivers we polled supported concentrating on making drivers safer " among IAM RoadSmart members it was 70%. Driverless cars are still years away but delivering safer drivers can help reduce death and injury from tomorrow. Governments, academics and car makers need to work hard to convince sceptical British and American drivers that autonomous cars can deliver the benefits promised such as a 90% plus reduction in road deaths.
Millions of kilometers are driven and recorded by car manufacturers and researchers every year to gather information about realistic traffic situations. The focus of these studies is often the recording of critical situations to create test scenarios for the development of new systems before introducing them into the market. This paper shows a novel Analysis and Investigation Method for All Traffic Scenarios (AIMATS) based on real traffic scenes. It also shows how to get detailed information about speeds, trajectories and behavior of all participants without driving thousands of kilometers at the example of conflict situations with animals. Basis of the AIMATS is the identification of the most relevant locations as "Points of Interest" (POI), the recording of the critical situations and their "base lines" at these POI. This paper presents a new method to identify critical scenarios involving both vehicles and animals as well as preliminary results of a study done in Saxony using this new method.
Although road infrastructure is developed extensively Brazil is still one of the countries with the most dangerous roads in the world. In order to stop the increasing trend of traffic fatalities of the last few years and to improve traffic safety on Brazilian roads a pilot study on behalf of SAE Brazil started in March 2016 with the goal to lay the foundations for a long-term research activity. Piloting for an in-depth accident investigation the city of Campinas, roughly 100 km north of São Paulo was chosen. The pilot project was carried out with the local partner, the Empresa Municipal de Desenvolvimento de Campinas (EMDEC). The paper reports on the initial training of evidence based accident data collection on-spot, the implementation of the new digital database, the data collection and the first results. An outlook on the planned long-term accident investigations is given.
This paper gives an overview of the in-depth crash investigation activity conducted by the Centre for Automotive Safety Research (CASR) at the University of Adelaide, in South Australia. Recent changes in method include: an expansion in on-call hours for the crash investigation team, providing the option of a phone interview for crash participants to discuss the crash, and downloading objective crash data from vehicle airbag control modules. These changes have resulted in: increased representativeness of crashes by hour of day; a decrease in the over-representation of fatal crashes in our sample; an increase in the proportion of crashes that involved a pedestrian, bicycle or scooter (moped); an increase in the proportion of crash participants consenting to an interview; and an increase in the objective data available, through airbag control module downloads. Our in-depth crash investigations enabled research into road departures that found barriers were a more feasible solution than clear zones for eliminating serious and fatal injury resulting from run off road crashes.