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Since 2005 the German In-Depth Accident Study (GIDAS) also records aspects of active vehicle safety. This is done because vehicles are fitted with an increasing number of active safety devices which have undoubtedly an influence on the number, severity and course of accidents. Accident researchers expect that collecting active safety data will facilitate to assess and quantify the impact of these and future devices. It is the aim of this paper to outline benefits and limitations associated with the recording of active safety aspects within indepth studies. An overview about possible areas where active safety data can be useful will be given. For that purpose single safety or comfort systems will be selected to estimate the effects of an accident database which includes variables associated with these systems. Questions with regard to the limitations of collecting active safety data will be addressed. Possible items are for example the usability of the data recorded, the real accident cause, the small number of relevant accidents, the time span needed to gather a sufficient dataset, the small share of vehicles equipped with a certain system or different functionalities of systems that are supposed to fall in the same category. As a result user needs for a reasonable data collection of active safety elements will be elaborated.
An approach to the standardization of accident and injury registration systems (STAIRS) in Europe
(1998)
STAIRS is a European Commission funded study whose aim is to produce a set of guidelines for a harmonised, crash injury database. The need to evaluate the effectiveness of the forthcoming European Union front and side impact directives has emphasised the need for real world crash injury data-sets that can be representative of the crash population throughout Europe. STAIRS will provide a methodology to achieve this. The ultimate aim of STAIRS is to produce a set of data collection tools which will aid decision making on vehicle crashworthiness as well as providing a means to evaluate the effectiveness of safety regulations. This paper will disseminate the up-to-date findings of the group as they try to harmonise their methods. The stage has been reached where studies into the diverse methods of the UK, French and German systems of crash injury investigation have been undertaken. An assessment has already been made of the relationships between the three current systems in order to define the areas of agreement and divergence. The conclusions reached stated that there were many areas that are already closely related and that the differences were only at the detailed level. With the emphasis on secondary safety and injury causation, core data sets were decided upon, taking into account: vehicle description, collision configuration, structural response of vehicles, restraint and airbag performance, child restraint performance, Euro NCAP, pedestrian and vehicle occupant kinematics, injury description and causation. Each variable was studied objectively, the important elements isolated and developed into a form that all partners were agreeable on. A glossary of terms is being developed as the project progresses which includes ISO standards and other definitions from the associated CAREPLUS project, which addresses the comparability of national data sets. A major consideration of the group was the data collection method to be employed. The strengths and weaknesses of each study were investigated to obtain a clear idea of which aspects offered the best way forward. The quality of this information and transference into a common format, as well as the necessary error checking systems to be employed have just been completed and are described. In tandem with this area of study the problem of the statistical relationship of each sample to the national population is also being investigated. The study proposes a mechanism to use a sample of crash injury data to represent the national and international crash injury problem
It is commonly agreed that active safety will have a significant impact on reducing accident figures for pedestrians and probably also bicyclists. However, chances and limitations for active safety systems have only been derived based on accident data and the current state of the art, based on proprietary simulation models. The objective of this article is to investigate these chances and limitations by developing an open simulation model. This article introduces a simulation model, incorporating accident kinematics, driving dynamics, driver reaction times, pedestrian dynamics, performance parameters of different autonomous emergency braking (AEB) generations, as well as legal and logical limitations. The level of detail for available pedestrian accident data is limited. Relevant variables, especially timing of the pedestrian appearance and the pedestrian's moving speed, are estimated using assumptions. The model in this article uses the fact that a pedestrian and a vehicle in an accident must have been in the same spot at the same time and defines the impact position as a relevant accident parameter, which is usually available from accident data. The calculations done within the model identify the possible timing available for braking by an AEB system as well as the possible speed reduction for different accident scenarios as well as for different system configurations. The simulation model identifies the lateral impact position of the pedestrian as a significant parameter for system performance, and the system layout is designed to brake when the accident becomes unavoidable by the vehicle driver. Scenarios with a pedestrian running from behind an obstruction are the most demanding scenarios and will very likely never be avoidable for all vehicle speeds due to physical limits. Scenarios with an unobstructed person walking will very likely be treatable for a wide speed range for next generation AEB systems.
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.
There is a need for detecting characteristics of pedestrian movement before car-pedestrian collisions to trigger a fully reversible pedestrian protection system. For this purpose, a pedestrian sensor system has been developed. In order to evaluate the effectiveness of the sensor system, the in-depth knowledge of car-pedestrian impact scenarios is needed. This study aims at the evaluation of the sensor system. The accident data are selected from the STRADA database. The accident scenarios available in this database were evaluated and the knowledge of the most common scenarios was developed in terms of the pedestrian trajectory, the pedestrian speed, the car trajectory, the car velocity, etc. A mathematical model was then established to evaluate the sensor system with different detective angles. It was found that in order to detect all the pedestrians in the most common scenarios on time the sensor detective angle must be kept larger than 60 degrees.
The National Highways Development Project in India is aimed at upgrading over 12,000 km of national highways from 2-lane undivided roads to 4-lane divided roads. With nearly 40% of fatal crashes being reported on national highways, the effect of this project on road safety needs to be assessed. Researchers carried out on-site crash investigations and in-depth crash data collection for a period of 45 to 60 days on four 2-lane undivided highways and a 4-lane divided highway. Based on 76 crashes examined, researchers found a shift of crash pattern from head-on collisions on undivided 2- lane highways to front-rear collisions on divided 4-lane highways. This paper presents the methodology, analysis of crashes examined, and the critical safety problems identified for greater consideration in future highway development projects. This paper also highlights the need and significance of in-depth crash investigations to understand local traffic conditions and problems in India.
Annual report 2011/2012
(2013)
Traffic on German roads is increasing continuously. The research of the Federal Institute for Materials Research (BASt) is concerned with a road system that will be functioning well in the future, that is safe and economically and ecologically sustainable. Every two years, BASt reports on its tasks, research projects and selected administrative topics. The current report comprises the years of 2011 and 2012. On 151 pages, it provides an idea of current research about important topics of roads and traffic. The projects SKRIBT and SKRIBTPlus examined the behaviour of drivers in tunnels in hazardous situations. It was discovered that in situations like this many people often react inadequately and too late. The collected data were used to develop new concepts that improve behaviour in hazardous situations in tunnels. In recent years, new safety systems that improve braking behaviour in hazardous situations have been installed in vehicles. However, for end users it is difficult to compare different systems because they have no access to suitable assessments. The EU project ASSESS (Assessment of Integrated Vehicle Safety Systems for improved vehicle safety) in which BASt is involved as a key partner therefore developed a uniform procedure for assessment and legal questions. Many European countries agree: Alcohol, drugs and medication in road traffic constitute a safety risk on European roads. In order to gain new insights and to develop suitable countermeasures, the European Commission approved of the largest research project to improve road safety to date: DRUID (Driving Under the Influence of Drugs, Alcohol and Medicines). This BASt-coordinated project took five years and involved institutes from 18 European countries. The result is a comprehensive stock taking and concrete suggestions on measures to be taken. A mayor part of the work of BASt also comprises extension and maintenance of the entire road infrastructure. The report "How will we make constructions in the future: Road construction without oil?" for instance examines the question how we will maintain and extend our roads in the future with resources becoming scarcer and more expensive. Furthermore, the campaign "on" the road plays a major part at BASt. For years there has been a shortage of parking spaces for trucks on federal highways. To remedy this situation, BAST has developed a new control approach: The so-called compact parking system increases capacities and uses them more effectively by parking trucks in a line according to their planned departure time.
Annual report 2018
(2019)
With this annual report, BASt is giving the 2018 research year a face. A part of its work is present and in the focus of the public, for example the field test of long trucks, the unique research area duraBASt at the motorway junction Cologne East or the innovative measuring vehicle MESAS for the condition assessment of road surfaces in flowing traffic. A large part of the BASt's work is less effective in attracting public attention but no less important, such as the essential updating of regulations, the testing and approval of products and processes, and the compilation of forecasts and statistics. More than 50 employees report on their research activities and thus give an insight into the tasks of BASt with its core areas of vehicle technology, traffic safety, traffic engineering, road construction as well as bridge and civil engineering. Highlights as well as facts and figures in short and concise form complete the report.
Annual Report 2019
(2020)
In its Annual Report 2019, the BASt has compiled a selection of its research. For example, the climate impact analysis, among other things, describes an essential research focus for the federal main road network. The new information and evaluation platform "BaustellenCheck" is presented, and reports on digitization in road equipment and maintenance as well as on various activities on the innovative test site duraBASt.
The results of current simulator and test track studies are also part of the annual report, as are the results of level 3 automation studies in real road traffic with an appropriately equipped test vehicle. Approaches to solutions for the infrastructure requirements of automated driving on motorways and federal trunk roads are presented, as well as the current status of the development of regulations in the field of vehicle technology.
The BASt scientists investigated the significance of virtual reality in road safety work. Whether influencers can be used effectively in road safety communication was also considered, as well as other proposed measures to reduce the risk of accidents, especially among young novice drivers.
Highlights as well as facts and figures in short and concise form complete the report.
Annual Report 2021
(2022)
In the Annual Report 2021, the BASt presents a selection of research activities of the year 2021.
In almost 40 contributions, projects from 5 specialist areas are presented. The spectrum of topics ranges from digital transformations in bridges and structural technology to sustainable, climate-resistant highway construction, efficient, ecological and digital traffic engineering, automated, environmentally conscious automotive engineering and the safety of all who participate in traffic.
Highlights as well as facts and figures in short and concise form complete the report.