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Although the number of road accident casualties in Europe (EU27) is falling the problem still remains substantial. In 2011 there were still over 30,000 road accident fatalities. Approximately half of these were car occupants and about 60 percent of these occurred in frontal impacts. The next stage to improve a car's safety performance in frontal impacts is to improve its compatibility. The objective of the FIMCAR FP7 EU-project was to develop an assessment approach suitable for regulatory application to control a car's frontal impact and compatibility crash performance and perform an associated cost benefit analysis for its implementation. This paper reports the cost benefit analyses performed to estimate the effect of the following potential changes to the frontal impact regulation: • Option 1 " No change and allow current measures to propagate throughout the vehicle fleet. • Option 2 " Add a full width test to the current offset Deformable Barrier (ODB) test. • Option 3 " Add a full width test and replace the current ODB test with a Progressive Deformable Barrier (PDB) test. For the analyses national data were used from Great Britain (STATS 19) and from Germany (German Federal Statistical Office). In addition in-depth real word crash data were used from CCIS (Great Britain) and GIDAS (Germany). To estimate the benefit a generalised linear model, an injury reduction model and a matched pairs modelling approach were applied. The benefits were estimated to be: for Option 1 "No change" about 2.0%; for Option 2 "FW test" ranging from 5 to 12% and for Option 3 "FW and PDB tests" 9 to 14% of car occupant killed and seriously injured casualties.
Rear-end collisions are the most frequent same and opposite-direction crashes. Common causes include momentary inattention, inadequate speed or inadequate distance. While most rear-end collisions in urban traffic only result in vehicle damage or slight injuries, rear-end collisions outside built-up areas or on motorways usually cause fatal or serious injuries. Driver assistance systems that detect dangerous situations in the longitudinal vehicle direction are therefore an essential safety plus. In view of this, for ADAC, systems that alert drivers to dangerous situations and initiate autonomous braking complement ESC as one of the most important active safety features in modern vehicles. The aim of ADAC is to provide consumers with technical advice and competent information about the systems available on the market. Reliable comparative tests that are based on standardised test criteria may provide motorists with important information and help them make a buying decision. In addition, they raise consumer awareness of the systems and speed up their market penetration. The assessment must focus on as many aspects of effectiveness as possible and include not only autonomous braking but also collision warning and autonomous brake assist. The work of the ADAC accident research is the development of the testing scenarios with direct link to accident situations and the identification of useful test criteria for testing.
Die EU hat für die Verkehrssicherheit in Europa ein anspruchsvolles Ziel vorgegeben: Bis 2010 soll die Anzahl der im Straßenverkehr Getöteten gegenüber 2000 halbiert werden. Für Deutschland kann eine erfolgreiche Zwischenbilanz gezogen werden: In den letzten 5 Jahren nahm trotz Vergrößerung des Kraftfahrzeugbestandes um 6% die Anzahl der Verkehrstoten um 29% ab, in den vergangenen 10 Jahren ist ein Rückgang um 43% zu verzeichnen. Diese im internationalen Vergleich überdurchschnittlichen Erfolge sind nicht zuletzt auch auf Fortschritte in der Fahrzeugtechnik zurückzuführen, wobei die zunehmende Verbreitung von Systemen der Aktiven Sicherheit wie ABS, BAS, ESP einen entscheidenden Anteil hat. Nach der deutlichen Reduzierung von Fahrunfällen durch ESP-® stehen nun die Auffahrunfälle im Fokus der Sicherheitsentwicklung von Mercedes-Benz. Das Paket aus verbessertem rückwärtigen Signalbild (Adaptives Bremslicht) und Brems-Assistent (BAS) wurde kürzlich durch radarbasierte Bremsassistenz ergänzt (BAS PLUS und PRE-SAFE-®-Bremse). Der Beitrag geht auf Funktion und Wirksamkeit der einzelnen Systeme ein und gibt einen Ausblick in die nähere Zukunft.
Motorcycle safety research
(2007)
Honda- global motorcycle sales exceeded the 10 million units mark since 2004, and further expansion is expected. As a responsibility for a company to provide mobility, Honda is focusing on motorcycle safety as top priority and has been working on various activities for both aspects of hardware and software. Here, we present Honda- activity for the safety technology of motorcycles. At present, Honda is promoting motorcycle safety in the four themes of prevention and collision safety such as safety education, recognition assistance, accident prevention and injury reduction. First, in the area of the safety education, the "Honda Safety Driving Promotion Center" was established in 1970, and motorcycle riders and vehicle driver trainings have been organized, and the traffic training centers are used as an actual practice field not only in Japan but also in many other regions in the world. Through our training activities, the new area of safety training with hardware assistance was developed and Honda- unique technology was accumulated such as the riding simulator which can provide experience of potentially dangerous situations without risk. Especially, the "riding trainer", the popular version of the riding simulator, was introduced at several motor shows in various countries and launched in September 2005. It was distributed first in Europe and is expected to expand globally aiming at 3000 units worldwide.. And in Europe, the newest version, which includes the suburban roads program, jointly developed with ADAC, will be released in near future. In the area of recognition assistance, "vehicle to vehicle communication technology" is under development using the advantage of being a manufacturer of both motorcycles and cars. This technology is under research as Honda "ASV-3" in Japan, and as part of C2C activity in Europe. As for the accident prevention, advanced brake systems for motorcycles to assist more effective brake operation have been expanded, Honda signed the European Road Safety Charter in April 2004 with the advanced brake systems commitment and furthermore, they are expanding according to vehicle characteristics and region. Then all models above 250 cc will have a version of the system by 2010. And as the last theme, "motorcycle airbag system" is introduced which is equipped on a mass production motorcycle for the first time in the world. It has been researched and developed for a long time as an injury reduction technology for collision accidents. Honda automobile technology was used for the research and development of the motorcycle airbag, and many specific issues such as the analysis of the collision conditions particular to motorcycles have been solved to realize today- success. It might be known that ADAC in-house crash test held in August this year confirmed the high effectiveness of the airbag system and showed a positive result. This motorcycle airbag system is equipped to the Honda Gold Wing and launched in North America in August, 2006. Also in Europe, it will be sold by the end of this year. Each theme of Honda motorcycle safety technology can be seen at the Honda booth.
The overall purpose of the ASSESS project is to develop a relevant and standardised set of test and assessment methods and associated tools for integrated vehicle safety systems, primarily focussing on currently available pre-crash sensing systems. The first stage of the project was to define casualty relevant accident scenarios so that the test scenarios will be developed based on accident scenarios which currently result in the greatest injury outcome, measured by a combination of casualty severity and casualty frequency. The first analysis stage was completed using data from a range of accident databases, including those which were nationally representative (STATS19, UK and STRADA, SE) and in-depth sources which provided more detailed parameters to characterise the accident scenarios (GIDAS, DE and OTS, UK). A common analysis method was developed in order to compare the data from these different sources, and while the data sets were not completely compatible, the majority of the data was aligned in such a way that allowed a useful comparison to be made. As the ASSESS project focuses on pre-crash sensing systems fitted to passenger cars, the data selected for the analysis was "injury accidents which involved at least one passenger car". The accident data analysis yielded the following ranked list of most relevant accident scenarios: Rank Accident scenario 1 Driving accident - single vehicle loss of control 2 Accidents in longitudinal traffic (same and opposite directions) 3 Accidents with turning vehicle(s) or crossing paths in junctions 4 Accidents involving pedestrians The ranked list highlights the relatively large role played by "accidents in longitudinal traffic", and "accidents with turning vehicle(s) or crossing paths in junctions" (the second and third most prevalent accident scenarios, respectively). The pre-crash systems addressed in ASSESS propose to yield beneficial safety outcomes with specific regard to these accident scenarios. This indicates that the ASSESS project is highly relevant to the current casualty crash problem. In the second stage of the analysis a selection of these accident scenarios were analysed further to define the accident parameters at a more detailed level .This paper describes the analysis approach and results from the first analysis stage.
This work aims at bringing evidence for mass incompatibility in frontal impact for cars built according to the UNECE R94 regulation. French national injury accidents database census for years 2005 to 2008 were used for the analysis. The heterogeneity of frontal self-protection among cars of different masses is investigated, as well as the partner protection parameter offered by these cars. The last part of the analysis deals with the estimation of the benefit, in terms of fatal and severe injuries avoided, if crashworthiness was harmonized for the whole fleet of vehicle. This calculation is done for France and is extended to all Europe.
An analysis of NASS and FARS was conducted to determine crash conditions that involved injuries that are not currently being directly addressed by vehicle safety standards or by consumer information test protocols. Analysis of both field data and US NCAP tests were conducted to determine the relative safety provided by seating position and by vehicle model year. Opportunities for improvements were determined by crash categories with large populations of injuries that were not addressed by safety tests or smaller numbers that were increasing in frequency. Areas of opportunities include improved occupant restrain in rollovers, improved frontal protection for rear seat occupants and improved fire prevention in frontal and rollover crashes.
The share of high-tensile steel in car bodies has increased over the last years. While occupant safety has generally benefited from this measure, there is a potential risk that, as a result, rescue time may increase considerably. In more than 60% of all car occupant fatalities a technical rescue has been necessary. These are in particular those cases where occupants die immediately at the accident scene. Therefore, in these cases "rescue time" is a very sensitive parameter. In addition to the general analysis of the need of technical rescue and the actual rescue time depending on model years, the injury pattern of occupants requiring technical rescue will be analysed to provide advice for rescue teams. Furthermore, a detailed analysis of rescue measures for the most popular car models depending on the safety cell design is given.
The paper presents a methodology for the benefit estimation of several secondary safety systems for pedestrians, using the exceptional data depth of GIDAS. A total of 667 frontal pedestrian accidents up to 40kph and more than 500 AIS2+ injuries have been considered. In addition to the severity, affected body region, exact impact point on the vehicle, and the causing part of every injury, the related Euro NCAP test zone was determined. One results of the study is a detailed impact distribution for AIS2+ injuries across the vehicle front. It can be stated, how often a test zone or vehicle part is hit by pedestrians in frontal accidents and which role the ground impact plays. Basing on that, different secondary safety measures can be evaluated by an injury shift method concerning their real world effectiveness. As an example, measures concerning the Euro NCAP pedestrian rating tests have been evaluated. It was analysed which Euro NCAP test zones are the most effective ones. In addition, real test results have been evaluated. Using the presented methodology, other secondary safety like the active bonnet (pop-up bonnet) or a pedestrian airbag measures can be evaluated.
Qualität von on-trip Verkehrsinformationen im Straßenverkehr : BASt-Kolloquium 23. und 24.03.2011
(2011)
Am 23. und 24. März 2011 veranstaltete die Bundesanstalt fuer Straßenwesen ein, um die Ergebnisse der erwähnten Projekte und Initiativen präsentieren zu lassen und mit anderen Experten zu diskutieren. Der vorliegende Tagungsband fasst die Ergebnisse des Kolloquiums zur "Qualität von on-trip Verkehrsinformationen" zusammen. Die Bereitstellung von Verkehrsinformationen ist geprägt von vielen Akteuren. Die Wertschöpfungskette beginnt bei der Sammlung grundlegender Verkehrsdaten zur Erstellung von Verkehrsinformationen und setzt sich mit der Datenverarbeitung und -interpretation bis hin zur Meldungserstellung fort. Die Weitergabe kann über verschiedene Übertragungsmedien erfolgen und beim Nutzer (z.B. im Navigationsgerät) empfangen werden. Jeder einzelne Schritt der Wertschoepfungskette kann sowohl von unterschiedlichen Partnern (privat oder öffentlich) übernommen werden als auch in der Hand eines Partners liegen. Diese Komplexität der Zusammenarbeit spiegelt sich demzufolge auch in Qualitätsmanagementprozessen wider. Im Rahmen des Kolloquiums wurden zwei wesentliche Qualitätsaspekte näher betrachtet: - die Datenqualität mit dem Focus auf Aktualitaet, Stimmigkeit der Daten verglichen mit einer gemessenen Realitaet sowohl zu Beginn der Wertschöpfungskette als auch an jeglichen Schnittstellen, - die Prozessqualität, welche sich insbesondere mit der reibungslosen Datenübergabe an den Schnittstellen der Wertschoepfungskette beschäftigt. Beide Qualitätsaspekte helfen zu verstehen, worin die heutigen Qualitätsprobleme bestehen und welche Massnahmen im Einzelnen ergriffen werden müssten, um eine nachhaltige Verbesserung zu erreichen. Einerseits kann es vorkommen, dass die Information über ein Verkehrsereignis an einer oder mehreren Stellen der Wertschöpfungskette korrekt vorliegt, jedoch durch ungenuegende technische oder organisatorische Schnittstellen im Prozessablauf wieder verloren geht und dem Nutzer folglich nicht zur Verfügung steht. Prominentes Beispiel eines solchen Problems in der Prozessqualität ist die fehlerhafte Interpretation der Meldung im Navigationsgerät, denkbar sind solche Informationsverluste jedoch an jeder Stelle der Wertschoepfungskette. Eine wichtige Massnahme zur Verbesserung der Prozessqualität ist die Standardisierung sowie die Überprüfung, ob die definierten Standards an jeder Stelle der Wertschöpfungskette eingehalten werden. Andererseits kann es vorkommen, dass die Datenqualität in Bezug auf ihre Genauigkeit von Anfang an so schlecht ist, dass der Nutzer eine fehlerhafte oder gar keine Nachricht übermittelt bekommt. Beispiel hierfür ist die Vielzahl von Stauereignissen, die entweder nicht gesendet wurden oder gesendet wurden, obwohl sie nicht vorhanden waren. Eine wichtige Massnahme zur Verbesserung dieser Situation ist die Verbesserung der Ereignisdetektion. Der Tagungsband enthaelt Präsentationen, die den Status Quo analysieren, Methoden zur verbesserten Datenerfassung vorschlagen und Möglichkeiten zur Verbesserung von Daten- und Prozessqualität vorstellen. Offen geblieben sind darüber hinaus folgende Fragestellungen: - Wie kann die Prozessqualität der gesamten Wertschöpfungskette bei der Vielzahl der Partner kontrolliert werden? Wer überwacht die Wertschöpfungskette? Wird hierfuer überhaupt eine zentrale Stelle benötigt? Oder ist es ausreichend, wenn jeder Partner eine angemessene Eingangs bzw. Ausgangskontrolle durchführt? - Obwohl es nur eine Realität gibt, entsteht doch Wettbewerb über die (Qualität der) Information zu dieser Realität. Wie kann Konsistenz zwischen allen Anbietern von sicherheitsrelevanten Informationen erreicht werden? Wo sollte der Wettbewerb enden und wie kann dies technisch, organisatorisch und wirtschaftlich realisiert werden? - Welche Prozesse sollten geschaffen werden, um Partner zu integrieren, die sich nicht an geschaffene Qualitätsstandards halten (z.B. kommerzielle Diensteanbieter, die nicht mit der Verkehrsinformationsszene vernetzt sind)? - Und nicht zuletzt, wie kann die Wahrnehmung des Nutzers über verschiedene Qualitätslevel unterschiedlicher Produkte verbessert werden? Ist der Nutzer in der Lage, die unterschiedlichen Qualitätsstufen von Verkehrssystemen zu unterscheiden? Falls nicht, welche Art von Unterstuetzung braucht der Kunde? Ein "European Information Services Assessment Programme" vergleichbar zu Euro NCAP für Fahrzeuge? Die Ergebnisse des Kolloquiums sollen die laufende Diskussion um die Verbesserung der Qualität von Verkehrsinformationen unterstützen.