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76 severe traffic accidents had been investigated in depth in an ongoing Volkswagen-Tongji University joint accident research project in JiaDing district, Shanghai, PR China since June 2005. With a methodology similar to German accident research units in Dresden and Hannover, a research team proceeds to the scene immediately after the incident to investigate and collect various data on environment, accident occurrence, vehicle state and deformations as well as injuries. The data combined with the results of accident reconstruction will be stored in a database for further statistical and casuistic analysis. The first outcome of the project supports the hypothesis that a main causation for the large number of traffic accidents in China is the lacking of risk awareness in Chinese driver behaviour. Low seat-belt use and the high proportion of vulnerable and poorly protected two-wheelers in traffic are reasons for the high injury and fatality rate in China. The research work shows that accident research in China is feasible and able to give support to tackle one of the urging problems in Chinese development.
The "Seven Steps Method" is an analysis and classification system, which describes the human participation factors and their causes in the temporal sequence (from the perceptibility to concrete action errors) taking into consideration the logical sequence of individual basic functions. By means of the "seven steps" it is possible to describe the relevant human causes of accidents from persons involved in the accident in an economic way with a sufficient degree of exactitude, because the causes can be further differentiated in their value (e.g. diversion as external diversion with regard to impact due to surroundings) and their sub values (e.g. external diversion with regard to impact due to surroundings in the shape of a "capture" of the perception by a prominent object of the traffic environment). Theoretically it is possible that one or more causing moments can be assigned to a person involved in an accident in each of the "seven steps"; however it is also possible to sufficiently clarify the cause in only one level (examples for this are described). In the practice of accident investigation at the site of the accident, the sequence chart is also relevant. With its assistance the questioning of the people involved in an accident can be accomplished in a structured way by assigning a set of questions to each step.
Due to recent years accident avoidance and crashworthiness on Austrian roads were mostly developed on national statistics and on-scene investigation respectively. Identification and elimination of black spots were main targets. In fact many fatal accidents do not occur on such black spots and black-spot investigation has reached a limit. New methods are required and therefore the Austrian Road Safety Programme was introduced by the Austrian Ministry of Transport, Innovation and Technology. The primary objective is the reduction of fatalities and severe injuries. Graz University of Technology initiated the project ZEDATU (Zentrale Datenbank tödlicher Unfälle) with the goal to identify similarities in different accident configurations. A matrix was established which categorizes risk and key factors of participating parties. Based on this information countermeasures were worked out.
NASS: the glass is half full
(2007)
The National Accident Sampling System (NASS) was born in the late 1970s. It was based on a substantial amount of experience and analysis of what was needed in the United States to understand the safety challenges of our highways. This work also showed how to collect high quality and useful crash data efficiently. Unfortunately, when Ronald Reagan - a President who believed in limited government - was elected, any hope of full funding for NASS was lost. The concept of 75 teams investigating about 18,000 serious crashes in detail annually was never realized. The system got up to 50 teams, then was cut to 36, and finally to 24 teams investigating fewer than a quarter of the originally anticipated number of crashes per year. Despite this, the NASS investigations provide a rich source of data, collected according to a sophisticated statistical sampling system to facilitate detailed national estimates of road casualties on our nation- highways and their causes. In addition, changes have been made in recent years to increase the number of more serious crashes of recent model vehicles to make the results more relevant to improving vehicle safety. A recent, detailed examination of hundreds of rollovers has provided considerable insight into rollover casualties and into what can be done to reduce them. Some of these results will be presented that show the value of the NASS system. Our experience with NASS and the Fatal Accident Reporting System (FARS) suggests a number of improvements that could be made in the United States" crash data systems. It also provides justification for a doubling or tripling of our national expenditures on crash data collection.
In Finland all fatal motor vehicle accidents are studied in-depth on-the-spot by multidisciplinary (police, road and vehicle engineers, physician and behavioural scientist) road accident investigation teams (legislation 2001, work started 1968), which operate in every province. The purpose of the teams is to uncover risk factors that turned an ordinary driving situation into a serious accident and give safety recommendations for improving road safety. The investigation teams do not take a stand on guilt or insurance compensation. When analysing accidents the teams use the concepts of key event, immediate, background and injury risk factors. Compiled investigation folders of each case contain investigation forms from each member, preinvestigation protocol, photographs, sketches etc. About 500 items of information are collected from each accident party. The collected information is also coded into a computer database. Both the database and the investigation folders are widely utilized by researchers and authorities conducting safety work.
In the context of this study, different data sources for accident research were examined regarding their possible data access and evaluated concerning the individual quality and extent of the data. Analyses of accidents require detailed and comprehensive information in particular concerning vehicle damages, injury patterns and descriptions of the accident sequence. The police documentation supplies the basic accident statistics and is amended in the context of the forensic treatment by further information, e.g. by medical and technical appraisals and witness questionings. As a new approach to the data acquisition for the analysis of fatal traffic accidents, the information was made usable which was collected by the police and by the investigations of the public prosecutor. The best strategy for obtaining reliable, extensive and complete data consists of combining the information from these two sources: the very complete, but elementary statistic data of the Niedersächsisches Landesamt für Statistik (Lower Saxony State Authority of Statistics), based on the police documentation as well as the very extensive accident information resulting from the investigation documentation of the public prosecutor after conclusion of the procedure, the so-called Court Records. Of all 715 fatal traffic accidents, which happened in the year 2003 in the German State of Lower Saxony, 238 cases were selected by means of a statistically coincidental selective procedure based on a statistically representative manner (every third accident). These cases cover the investigation documents of the 11 responsible public prosecutor- offices, which were requested and evaluated while preserving the data security. Of the 238 cases 202 cases were available, which were individually coded and stored in a data base using 160 variables. Thus a data base of a sample of representative data for fatal accidents in Lower Saxony was set up. The data base contains extensive information concerning general accident data (35 variables), concerning road and road surface data (30 variables), concerning vehicle-specific data (68 variables) as well as concerning personal and injury data (27 variables).
The accident research project in Dresden was founded in July 1999. To date over 6.000 crash investigations have been undertaken. About 10.000 vehicles have been documented and over 13.000 participants have been debriefed. But there is much more than this scientific success. Because of the interdisciplinary character between the medical and technical focus, the project affords an important contribution for the education of the involved students. Over 200 students of different fields of study have got experiences not only for the occupational career. This lecture describes the additional effects of the accident research project regarding the education of the students, the capacity for teamwork and learning about dealing with accident casualties.
Den bisherigen Richtlinien zu Verkehrserhebungen ist gemeinsam, dass sie - wenn überhaupt - nur sehr wenige Aussagen zur erreichbaren Datenqualität enthalten. Normative Vorgaben und konkrete Handlungsanweisungen, die zu einer Verbesserung der Datenqualität von Erhebungen führen, fehlen in der Regel für die meisten Erhebungsverfahren. Abgesehen von Einzelaspekten wie beispielsweise den Kernelementen für Haushaltsbefragungen zum Verkehrsverhalten gibt es keine Qualitätsstandards für die Konzipierung, Durchführung und Auswertung einer Verkehrserhebung. Ziel der vorliegenden Studie ist es, mit Blick auf verschiedene Datennutzer und Arten der Datenverwendung wissenschaftlich abgesicherte Qualitätsstandards für Verkehrserhebungen zu erarbeiten. Im Kern sollten Hinweise gegeben werden, durch welche konkreten methodischen Ansätze und praktische Maßnahmen man für die unterschiedlichen Erhebungsverfahren im Verkehrswesen (Zählungen, Messungen, Verhaltensbeobachtungen und Befragungen) die jeweils bestmögliche Datenqualität erreichen kann. Die Ergebnisse dieses Projektes sollen darüber hinaus auch als eine Grundlage für die Fortschreibung der neuen "Empfehlungen für Verkehrserhebungen (EVE)" dienen. Im Kapitel 2 wird zur Schaffung eines geeigneten theoretischen Rahmens nach einer allgemeinen, an den Ansätzen des Qualitätsmanagements orientierten Definition von Datenqualität zunächst ein umfassendes Datenqualitätskonzept dargestellt, welches im Bereich der amtlichen Statistik auf europäischer Ebene entwickelt worden ist. Kapitel 3 stellt wichtige verkehrswissenschaftliche Grundlagen der vorliegenden Untersuchung zusammen. Ausgangspunkt ist eine allgemeine Charakterisierung von Verkehrserhebungen. In Kapitel 4 wird der konzeptuelle Rahmen für die Ermittlung von Standards der Datenqualität dargestellt. Hierzu werden allgemeine Indikatoren der Datenqualität auf Verkehrserhebungen übertragen. Anschließend werden die verschiedenen Anspruchsgruppen und deren Anforderungen an die Datenqualität betrachtet und darauf aufbauend die Elemente einer Qualitätsstrategie für Verkehrserhebungen entwickelt. Wie eine angemessene Datenqualität bei den verschiedenen Arten von Verkehrserhebungen erreicht werden kann, wird in den Kapiteln 5 bis 8 dargestellt. Hier werden Hinweise und Empfehlungen zum Stichprobenverfahren gegeben und es wird aufgezeigt, wie systematische Fehler (Nichterfassung von Stichprobeneinheiten, Fehler bei der Erfassung von Merkmalen, bei der Datenaufbereitung und -auswertung sowie der Darstellung von Ergebnissen) vermieden oder zumindest reduziert werden können. Abschließend werden in Kapitel 9 die wesentlichen Erkenntnisse zusammengefasst und ein Dokumentationsschema vorgestellt, welches einen Orientierungsrahmen für die Durchführung von Verkehrserhebungen liefert.
Mit Hilfe der Datenbestände von 7 Städten werden die Grundlagen für eine praxisgerechte Weiterentwicklung des Bewertungsverfahrens für den messtechnisch erfassten Zustand von Innerortsstraßen mit den erforderlichen Normierungsfunktionen, den Ziel-, Warn- und Schwellenwerten und maßgeblichen Funktionsklassen erarbeitet. Für die Auswerteabschnitte ergab sich eine Länge von 10 m als sinnvoll, aus der problemlos Zustandsindikatoren auch für längere Abschnitte ermittelt werden können. Die bisher verwendeten Zustandsindikatoren für die Längsebenheit, Querebenheit und Substanz werden auf ihre Brauchbarkeit untersucht und verbesserte beziehungsweise neue Indikatoren mit den dazugehörigen Normierungsfunktionen vorgeschlagen. Für die Griffigkeit standen keine Analysedaten zur Verfügung. Hier konnte für die Festlegung von Ziel-, Warn- und Schwellenwerten auf entsprechende Normierungsfunktionen für Außerortsstraßen zurückgegriffen werden. Weiterhin werden Vorschläge für die Verknüpfung zum Gebrauchs-und Substanzwert erarbeitet. Für die Relativierung der Anforderungen an den Zustand von Asphaltfahrbahnen werden zwei Funktionsklassen für die Straßenkategorien "Hauptverkehrs-/verkehrs-/Sammelstraßen" (FK 1) und "Anlieger-/Wohnstraßen" (FK 2) vorgeschlagen. Weiterhin wird eine dritte Funktionsklasse für Pflasterstraßen eingeführt. Ihre unterschiedlichen Normierungsfunktionen gewährleisten bei gleichen Zustandsausprägungen eine unterschiedliche Einstufung der Dringlichkeit von Maßnahmearten. Die Untersuchungsergebnisse sind zusätzlich in Form eines Arbeitspapiers aufbereitet.