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For the assessment of vehicle safety in frontal collisions compatibility (which consists of self and partner protection) between opponents is crucial. Although compatibility has been analysed worldwide for over 10 years, no final assessment approach has been defined to date. Taking into account the European Enhanced Vehicle safety Committee (EEVC) compatibility and frontal impact working group (WG15) and the FP5 VC-COMPAT project activities, two test approaches have been identified as the most promising candidates for the assessment of compatibility. Both are composed of an off-set and a full overlap test procedure. In addition another procedure (a test with a moving deformable barrier) is getting more attention in current research programmes. The overall objective of the FIMCAR project is to complete the development of the candidate test procedures and propose a set of test procedures suitable for regulatory application to assess and control a vehicle- frontal impact and compatibility crash safety. In addition an associated cost benefit analysis should be performed. The objectives of the work reported in this deliverable were to review existing full-width test procedures and their discussed compatibility metrics, to report recent activities and findings with respect to full-width assessment procedures and to assess test procedures and metrics. Starting with a review of previous work, candidate metrics and associated performance limits to assess a vehicle- structural interaction potential, in particular its structural alignment, have been developed for both the Full Width Deformable Barrier (FWDB) and Full Width Rigid Barrier (FWRB) tests. Initial work was performed to develop a concept to assess a vehicle- frontal force matching. However, based on the accident analyses performed within FIMCAR frontal force matching was not evaluated as a first priority and thus in line with FIMCAR strategy the focus was put on the development of metrics for the assessment of structural interaction which was evaluated as a first priority.
Cost benefit analysis
(2014)
Although the number of road accident casualties in Europe is falling the problem still remains substantial. In 2011 there were still over 30,000 road accident fatalities [EC 2012]. Approximately half of these were car occupants and about 60 percent of these occurred in frontal impacts. The next stage to improve a car- safety performance in frontal impacts is to improve its compatibility for car-to-car impacts and for collisions against objects and HGVs. Compatibility consists of improving both a car- self and partner protection in a manner such that there is good interaction with the collision partner and the impact energy is absorbed in the car- frontal structures in a controlled way which results in a reduction of injuries. Over the last ten years much research has been performed which has found that there are four main factors related to a car- compatibility [Edwards 2003, Edwards 2007]. These are structural interaction potential, frontal force matching, compartment strength and the compartment deceleration pulse and related restraint system performance. The objective of the FIMCAR FP7 EC-project was to develop an assessment approach suitable for regulatory application to control a car- frontal impact and compatibility crash performance and perform an associated cost benefit analysis for its implementation.
The objective of this deliverable is to describe the expected influence of the candidate test procedures developed in FIMCAR for frontal impact on other impact types. The other impact types of primary interest are front-to-side impacts, collisions with road restraint systems (e.g. guardrails), and heavy goods vehicle impacts. These collision types were chosen as they involve structures that can be adapted to improve safety. Collisions with vulnerable road users (VRU) were not explicitly investigated in FIMCAR. It is expected that the vehicle structures of interest in FIMCAR can be designed into a VRU friendly shell. Information used for this deliverable comes from simulations and car-to-car crash tests conducted in FIMCAR or review of previous research. Three test configurations (full width, offset, and moving deformable barriers) were the input to the FIMCAR selection process. There are three different types of offset tests and two different full width tests. During the project test procedures could be divided into three groups that provide different influences or outcomes on vehicle designs: 1. The ODB barrier provides a method to assess part of the vehicles energy absorption capabilities and compartment test in one test. 2. The FWRB and FWDB have similar capabilities to control structural alignment, further assess energy absorption capabilities, and promote the improvements in the occupant restraint system for high deceleration impacts. 3. The PDB and MPDB can be used to promote better load spreading in the vehicle structures, in addition to assessing energy absorption and occupant compartment strength in an offset configuration. The consortium selected the ODB and FWDB as the two best candidates for short term application in international rulemaking. The review of how all candidates would affect vehicle performance in other impacts (beside front-to-front vehicle or frontal impacts with fixed obstacles) however is reported in this deliverable to support the benefit analysis reported in FIMCAR. The grouping presented above is used to discuss all five test candidates using similarities between certain tests and thereby simplify the discussion.
Accident analysis
(2014)
For the assessment of vehicle safety in frontal collisions compatibility (which consists of self and partner protection) between opponents is crucial. Although compatibility has been analysed worldwide for years, no final assessment approach has been defined to date. Taking into account the European Enhanced Vehicle safety Committee (EEVC) compatibility and frontal impact working group (WG15) and the EC funded FP5 VC-COMPAT project activities, two test approaches have been identified as the most promising candidates for the assessment of compatibility. Both are composed of an off-set and a full overlap test procedure. In addition another procedure (a test with a moving deformable barrier) is getting more attention in today- research programmes. The overall objective of the FIMCAR project is to complete the development of the candidate test procedures and propose a set of test procedures suitable for regulatory application to assess and control a vehicle- frontal impact and compatibility crash safety. In addition an associated cost benefit analysis should be performed. The specific objectives of the work reported in this deliverable were: - Determine if previously identified compatibility issues are still relevant in current vehicle fleet: Structural interaction, Frontal force matching, Compartment strength in particular for light cars. - Determine nature of injuries and injury mechanisms: Body regions injured o Injury mechanism: Contact with intrusion, Contact, Deceleration / restraint induced. The main data sources for this report were the CCIS and Stats 19 databases from Great Britain and the GIDAS database from Germany. The different sampling and reporting schemes for the detailed databases (CCIS & GIDAS) sometimes do not allow for direct comparisons of the results. However the databases are complementary " CCIS captures more severe collisions highlighting structure and injury issues while GIDAS provides detailed data for a broader range of crash severities. The following results represent the critical points for further development of test procedures in FIMCAR.
The off-set assessment procedure potentially contributes to the FIMCAR objectives to maintain the compartment strength and to assess load spreading in frontal collisions. Furthermore it provides the opportunity to assess the restraint system performance with different pulses if combined with a full-width assessment procedure in the frontal assessment approach. Originally it was expected that the PDB assessment procedure would be selected for the FIMCAR assessment approach. However, it was not possible to deliver a compatibility metric in time so that the current off-set procedure (ODB as used in UNECE R94) with some minor modifications was proposed for the FIMCAR Assessment Approach. Nevertheless the potential to assess load spreading, which appears not to be possible with any other assessed frontal impact assessment procedure was considered to be still high. Therefore the development work for the PDB assessment procedure did not stop with the decision not to select the PDB procedure. As a result of the decisions to use the current ODB and to further develop the PDB procedure, both are covered within this deliverable. The deliverable describes the off-set test procedure that will be recommended by FIMCAR consortium, this corresponds to the ODB test as it is specified in UN-ECE Regulation 94 (R94), i.e. EEVC deformable element with 40% overlap at a test speed of 56 km/h. In addition to the current R94 requirements, FIMCAR will recommend to introduce some structural requirements which will guarantee sufficiently strong occupant compartments by enforcing the stability of the forward occupant cell. With respect to the PDB assessment procedure a new metric, Digital Derivative in Y direction - DDY, was developed, described, analysed, and compared with other metrics. The DDY metric analyses the deformation gradients laterally across the PDB face. The more even the deformation, the lower the DDY values and the better the metric- result. In order analyse the different metrics, analysis of the existing PDB test results and the results of the performed simulation studies was performed. In addition, an assessment of artificial deformation profiles with the metrics took place. This analysis shows that there are still issues with the DDY metric but it appears that it is possible to solve them with future optimisations. For example the current metric assesses only the area within 60% of the half vehicle width. For vehicles that have the longitudinals further outboard, the metric is not effective. In addition to the metric development, practical issues of the PDB tests such as the definition of a scan procedure for the analysis of the deformation pattern including the validation of the scanning procedure by the analysis of 3 different scans at different locations of the same barrier were addressed. Furthermore the repeatability and reproducibility of the PDB was analysed. The barrier deformation readings seem to be sensitive with respect to the impact accuracy. In total, the deliverable is meant to define the FIMCAR off-set assessment procedure and to be a starting point for further development of the PDB assessment procedure.
The BASt-project group "Legal consequences of an increase in vehicle automation" has identified, defined and consequently compiled different automation degrees beyond Driver Assistance Systems. These are partial-, high- and full automation. According to German regulatory law, i.e. the German Road Traffic Code, it has been identified that the distinctive feature of different degrees of automation is the permanent attention of the driver to the task of driving as well as the constant availability of control over the vehicle. Partial automation meets these requirements. The absence of the driver- concentration to the traffic situation and to execute control is in conflict with the use of higher degrees of vehicle automation (i.e. high and full automation). Their use is therefore presently not compatible with German law, as the human driver would violate his obligations stipulated in the Road Traffic Code when fully relying on the degree of automation these systems would offer. As far as higher degrees of automation imply free-hand driving, further research in terms of behavioural psychology is required to determine whether this hinders the driver in the execution of permanent caution as required by sec. 1 para. 1 StVO (German Road Traffic Code). As far as liabilities according to the StVG (German Road Traffic Act) are concerned, the presently reversed burden of proof on the driver within sec. 18 para. 1 S. 2 StVG might no longer be considered adequate in case of higher degrees of automation that allow the driver to draw attention from the task of driving (in case making such use of a system would be permitted by the German Road Traffic Code). The liability of the vehicle "keeper", according to the German Road Traffic Act, would remain applicable to all defined degrees of automation. In case of partial automation, the use of systems according to their limits is accentuated. The range of use that remains within the intended must be defined closely and unmistakeably. Affecting user expectations properly can immensely help to maintain safe use, in case design-measures that exclude overreliance are not available according to the current state of the art (otherwise such measures would have to be applied primarily). In case of the higher degrees of automation that no longer require the driver- permanent attention (under the presupposition their use would be permitted by the German Road Traffic Code), every accident potentially bears the risk to cause product liability on the side of the manufacturer. Liability of the manufacturer might only be excluded in case of a breach of traffic rules by a third party or in case of overriding/ oversteering by the driver. In so far aspects of German procedural law and the burden of proof are of great importance. The project group has identified the need for further continuative research not only to advance legal assessment but also to improve basic technical conditions for vehicle automation as well as product reliability.
Um die zukünftige Entwicklung von Fahrzeugen mit alternativem Antrieb in Deutschland verfolgen, analysieren und mögliche negative Auswirkungen auf die Verkehrssicherheit zeitnah identifizieren zu können, hat die Bundesanstalt für Straßenwesen (BASt) im Jahr 2010 die Einrichtung einer langfristigen Beobachtung des Fahrzeugmarktes und des Unfallgeschehens von Pkw mit alternativen Antriebsarten initiiert. Die Daten des vorliegenden Berichtes dokumentieren die Marktdurchdringung von Personenkraftwagen mit alternativen Antriebsarten und informieren über die Unfallbeteiligung von Fahrzeugen mit alternativem Antrieb bis 2011. Es hat sich gezeigt, dass Fahrzeuge mit Hybridantrieb nach wie vor ein starkes Marktwachstum aufweisen. Die Zuwachsrate ist nahezu auf dem gleichen hohen Niveau wie in den Vorjahren (ca. 28%, getypter Bestand). Bei den reinen Elektrofahrzeugen ist die Anzahl getypter Fahrzeuge sehr stark angestiegen, von 212 im Jahr 2010 auf 1880 im Jahr 2011. Der reale Bestand an Elektrofahrzeugen (inklusive ungetypter Fahrzeuge) hat sich demgegenüber von 2010 auf 2011 auf 4.541 Pkw verdoppelt. Dies deutet auf eine zunehmende Serienreife von Elektro-Kfz hin. Pkw mit alternativem Antrieb weisen 2011 (bis auf Gas) einen höheren Anteil an Unfällen innerorts auf als Pkw mit herkömmlichem Antrieb. Hybrid Fahrzeuge haben dabei eine erhöhte Beteiligungsquote innerorts von ca. 76%. Der relativ hohe Anteil von Innerortsunfällen von alternativ betriebenen Fahrzeugen ist vor allem vor dem Hintergrund der Nutzung der Fahrzeuge zu interpretieren.
Since its beginning in 1999, the German In-Depth Accident Study (GIDAS) evolved into the presumably leading representative road traffic accident investigation in Europe, based on the work started in Hanover in 1973. The detailed and comprehensive description of traffic accidents forms an essential basis for vehicle safety research. Due to the ongoing extension of demands of researchers, there is a continuous progress in the techniques and systematic of accident investigation within GIDAS. This paper presents some of the most important developments over the last years. Primary vehicle safety systems are expected to have a significant and increasing influence on reducing accidents. GIDAS therefore began to include and collect active safety parameters as new variables from the year 2005 onwards. This will facilitate to assess the impact of present and future active safety measures. A new system to analyse causation factors of traffic accidents, called ACASS, was implemented in GIDAS in the year 2008. The whole process of data handling was optimised. Since 2005 the on-scene data acquisition is completely conducted with mobile tablet PCs. Comprehensive plausibility checks assure a high data quality. Multi-language codebooks are automatically generated from the database structure itself and interfaces ensure the connection to various database management systems. Members of the consortium can download database and codebook, and synchronize half a terabyte of photographic documentation through a secured online access. With the introduction of the AIS 2005 in the year 2006, some medical categorizations have been revised. To ensure the correct assignment of AIS codes to specific injuries an application based on a diagnostic dictionary was developed. Furthermore a coding tool for the AO classification was introduced. All these enhancements enable GIDAS to be up to date for future research questions.
A flexible pedestrian legform impactor (FlexPLI) with biofidelic characteristics is aimed to be implemented within global legislation on pedestrian protection. Therefore, it is being evaluated by a technical evaluation group (Flex-TEG) of GRSP with respect to its biofidelity, robustness, durability, usability and protection level (Zander, 2008). Previous studies at the Federal Highway Research Institute (BASt) and other laboratories already showed good progress concerning the general development, but also the need for further improvement and further research in various areas. An overview is provided of the different levels of development and all kinds of evaluation activities of the Flex-TEG, starting with the Polar II full scale pedestrian dummy as its origin and ending up with the latest legform impactor built level GTR that is expected to be finalized by the end of the year 2009. Using the latest built levels as a basis, gaps are revealed that should be closed by future developments, like the usage of an upper body mass (UBM), the validation of the femur loads, injury risk functions for the cruciate knee ligaments and an appropriate certification method. A recent study on an additional upper body mass being applied for the first time to the Flex-GT is used as means of validation of recently proposed modified impact conditions. Therefore, two test series on a modern vehicle front using an impactor with and without upper body mass are compared. A test series with the Flex-GTR will be used to study both the comparability of the impact behavior of the GT and GTR built level as well as the consistency of test results. Recommendations for implementation within legislation on pedestrian protection are made.
According to the German road traffic regulations children up to the age of 12 or a height below 150 cm have to use approved and appropriate child restraint systems (CRS). CRS must be approved according to UN-ECE Regulation No. 44. The regulation classifies CRS in 5 weight categories. The upper weight group is approved for children from 22 to 36 kg. However, studies show that already today many children weigh more than 36 kg although they have not reached a height of 150 cm. Therefore, no ECE R44 approved CRS is available for these overweight children. In conclusion, today's sizes and weights of children are no longer represented by the current version of the ECE R44. The heaviest used dummy (P10) weighs just 32.6 kg and has a height of 137.9 cm. Statistical data of German children show that already 5% of the children at a height of 137.9 cm have a weight above 45.3 kg. Regarding children at a height of 145 cm, the 95th percentile limit is at a weight of 53.3 kg. Based on these data 4 dummies with different heights and weights were defined and produced. Two of them are overweight. Up to now, there is no experience how current child restraint systems perform in a car crash if they are used by children with a weight above 36 kg and a height smaller than 150 cm. In the future, different child restraint systems will be tested with respect to the ECE R44 regulation using these overweight dummies.
The head impact of pedestrians in the windscreen area shows a high relevance in real-world accidents. Nevertheless, there are neither biomechanical limits nor elaborated testing procedures available. Furthermore, the development of deployable protection systems like pop-up bonnets or external airbags has made faster progress than the corresponding testing methods. New requirements which are currently not considered are taken into account within a research project of BASt and the EC funded APROSYS (Advanced PROtection SYStems) integrated project relating to passive pedestrian protection. Testing procedures for head impact in the windscreen area should address these new boundary conditions. The presented modular procedure combines the advantages of virtual testing, including full-scale multi-body and finite element simulations, as well as hardware testing containing impactor tests based on the existing procedures of EEVC WG 17. To meet the efforts of harmonization in legislation, it refers to the Global Technical Regulation of UNECE (GTR No. 9). The basis for this combined hardware and virtual testing procedure is a robust categorization covering all passenger cars and light commercial vehicles and defining the testing zone including the related kinematics. The virtual testing part supports also the choice of the impact points for the hardware test and determines head impact timing for testing deployable systems. The assessment of the neck rotation angle and sharp edge contact in the rear gap of pop-up bonnets is included. For the demonstration of this procedure, a hardware sedan shaped vehicle was modified by integrating an airbag system. In addition, tests with the Honda Polar-II Dummy were performed for an evaluation of the new testing procedure. Comparing these results, it was concluded that a combination of simulation and updated subsystem tests forms an important step towards enhanced future pedestrian safety systems considering the windscreen area and the deployable systems.
Evaluation of the performance of competitive headforms as test tools for interior headform testing
(2009)
The European Research Project APROSYS has evaluated the interior headform test procedure developed by EEVC WG 13, representing the head contact in the car during a lateral impact. One important aspect within this test procedure was the selection of an appropriate impactor. The WG13 procedure currently uses the Free Motion Headform as used within the FMVSS 201. The ACEA 3.5 kg headform used in Phase 1 of the European Directive and the future European Regulation on Pedestrian Protection is still discussed as a possible alternative. This paper reports work performed by the Federal Highway Research Institute (BASt) as a part of the APROSYS Task 1.1.3. The study compares the two headform impactors according to FMVSS and ACEA, in a series of basic tests in order to evaluate their sensitivity towards different impact angles, impact accuracy, the effect of differences to impactors of the same type and the effects of the repeatability and reproducibility of the test results. The test surface consisted of a steel tube covered with PU foam and PVC, representing the car interior to be tested. Despite of the higher mass of the FMH the HIC values of this impactor were generally lower than those of the ACEA headform. The FMH showed a higher repeatability of test results but a high sensitivity on the angle of roll, the spherical ACEA impactor performed better with regards to the reproducibility. In case of the ACEA impactor-, the angle of roll had no influence.
Within the process of integrating passenger airbags in the vehicle fleet a problem of compatibility between the passenger airbag and rear-facing child restraint systems was recognised. Especially in the US several accidents with children killed by the passenger airbag were recorded. Taking into account these accidents the deactivation of a present passenger airbag is mandatory if a child is carried in a rear-facing child restraint system at the front passenger seat in all member states of the European Union. This rule is in force since the deadline of 2003/20/EC at the latest. In the past a passenger airbag either could not be disabled or could only be disabled by a garage. Today there are a lot of different possibilities for the car driver himself to disable the airbag. Solutions like an on/off-switch or the automatic detection of a child restraint system are mentioned as an example. Taking into account the need for the deactivation of front passenger airbags two types of misuse can occur: transportation of an infant while the airbag is (still) enabled and transportation of an adult, while the airbag is disabled, respectively. Within a research project funded by BASt both options of misuse were analysed utilising two different types of surveys amongst users (field observations and interviews, Internet-questionnaires). In addition both analysis of accident data and crash tests for an updated assessment of the injury risk caused by the front passenger airbag were conducted. Both surveys indicate a low risk of misuse. Most of the misuse cases were observed in older cars, which offer no easy way to disable the airbag. For systems, which detect a child seat automatically, no misuse could be found. The majority of misuses in cars equipped with a manual switch were caused by reasons of oblivion. Also the accident analysis indicates a minor risk of misuse. From more than 300 cases of the GIDAS accident sample that were analysed, only 24 children were using the front passenger seat in cars equipped with a front passenger airbag. In most of these cases the airbag was deactivated. When misuse occurred the injury severity was low. However, when analysing German single accidents the fatality risk caused by the front passenger airbag became obvious. From the technical point of view, there were important changes in the design of passenger airbags in recent years. Not only volume and shape were modified, but also the mounting position of the entire airbag module was changed fundamentally. Even if these findings do not allow obtaining general conclusions, a clear tendency of less danger by airbags could be identified. For future vehicle development a safe combination of airbags and rear faced baby seats seems to be possible in the long term. This would mean that both types of misuse could be eliminated. For parents an easier use of child seat and car would be the result.
In the last years there has been a decline in accident figures in Germany especially for four wheeled vehicles. At the same time, accident figures for motorcycles remained nearly constant. About 17 % of road traffic fatalities in the year 2006 were motorcyclists. 33 % of these riders were killed in single vehicle crashes. This leads to the conclusion that improving driving dynamics and driving stability of powered two wheelers would yield considerable safety gains. However, the well-known measures for cars and trucks with their proven effectiveness cannot be transferred easily to motorcycles. Therefore studies were carried out to examine the safety potential of Anti Lock Braking Systems (ABS) and Vehicle Stability Control (VSC) for motorcycles by means of accident analysis, driving tests and economical as well as technical assessment of the systems. With regard to ABS, test persons were assigned braking tasks (straight and in-curve) with five different brake systems with and without ABS. Stopping distances as well as stress and strain on the riders were measured for 9 test riders who completed 105 braking manoeuvres each. Knowing the ability of ABS to avoid falls during braking in advance of a crash and taking into account the system costs, a cost benefit analysis for ABS for motorcycles was carried out for different market penetration of ABS, i.e. equipment rates, and different time horizons. The potential of VSC for motorcycles was estimated in two steps. First the kinds of accidents that could be prevented by such a system at all have been analysed. For these accident configurations, simulations and driving tests were then performed to determine if a VSC was able to detect the critical driving situation and if it was technically possible to implement an actuator which would help to stabilise the critical situation.
A series of drop tests and vehicle tests with the adult head impactor according to Regulation (EC) 631/2009 and drop tests with the phantom head impactor according to UN Regulation No. 43 have been carried out by the German Federal Highway Research Institute (BASt) on behalf of the German Federal Ministry of Transport, Building and Urban Development (BMVBS). Aim of the test series was to study the injury risk for vulnerable road users, especially pedestrians, in case of being impacted by a motor vehicle in a way described within the European Regulations (EC) 78/2009 and (EC) 631/2009. Furthermore, the applicability of the phantom head drop test described in UN Regulation No. 43 for plastic glazing should be investigated. In total, 30 drop tests, thereof 18 with the adult head impactor and 12 with the phantom head impactor, and 49 vehicle tests with the adult head impactor were carried out on panes of laminated safety glass (VSG), polycarbonate (PC) and laminated polycarbonate (L-PC). The influence of parameters such as the particular material properties, test point locations, fixations, ambient conditions (temperature and impact angle) was investigated in detail. In general, higher values of the Head Injury Criterion (HIC) were observed in tests on polycarbonate glazing. As the HIC is the current criterion for the assessment of head injury risk, polycarbonate glazing has to be seen as more injurious in terms of vulnerable road user protection. In addition, the significantly higher rebound of the head observed in tests with polycarbonate glazing is suspected to lead to higher neck loads and may also cause higher injury risks in secondary impacts of vulnerable road users. However, as in all tests with PC glazing no damage of the panes was observed, the risk of skin cut injuries may be expected to be reduced significantly. The performed test series give no indication for the test procedure prescribed in UN Regulation No. 43 as a methodology to approve glass windscreen not being feasible for polycarbonate glazing, as all PC panes tested fulfilled the UN R 43 requirements. The performance of the windscreen area will not be relevant for vehicle type approval according to the upcoming UN Regulation for pedestrian protection. However, it is recommended that pedestrian protection being considered for plastic windscreens to ensure at least the same level of protection as glass windscreens.
The main objective of EC CASPER research project is to reduce fatalities and injuries of children travelling in cars. Accidents involving children were investigated, modelling of human being and tools for dummies were advanced, a survey for the diagnosis of child safety was carried out and demands and applications were analysed. From the many research tasks of the CASPER project, the intention of this paper is to address the following: • In-depth investigation of accidents and accident reconstruction. These will provide important points for the injury risk curve, in order to improve it. Different accident investigation teams collected data from real road accidents, involving child car passengers, in five different European countries. Then, a selection of the most appropriate cases for the injury risk curve and the purposes of the project was made for an in-depth analysis. The final stage of this analysis was to conduct an accident reconstruction to validate the results obtained. The in-depth analysis included on-scene accident investigation, creating virtual simulations of the accident/possible reconstruction, and conducting the reconstruction. In the cases of successful reconstructions, new points were introduced to the injury risk curves. Accident reconstructions of selected cases were carried out in test laboratories as the next step following in-depth road accident investigation. These cases were reconstructed using similar child restraint systems (CRS) and the same type make and model as in the real accidents. Reconstructing real cases has several limitations, such as crash angle, cars" approximation paths and crash speed. However, a few changes and applications on the testing conditions were applied to reduce the limitations and improved the representations of the real accidents. After conducting the reconstructions, a comparison between the deformations of the cars on the real accident and the vehicles from the reconstructions was made. Additionally, a correlation between the data captured from the dummies and the injury data from the real accident was sought. This finalises an in-depth analysis of the accident, which will provide new relevant points to the injury risk curve. The CASPER project conducted a large research programme on child safety. On technical points, a promising research area is the developing injury risk curves as a result of in-depth accident investigations and reconstructions. This abstract was written whilst the project was not yet finished and final results are not yet known, but they will be available by the time of the conference. All the works and findings will not necessarily be integrated in the industrial versions of evaluation tools as the CASPER project is a research program.
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.
Aufgrund des demografischen Wandels werden in der Zukunft immer mehr ältere Menschen ein Kraftfahrzeug führen. Das vorliegende Projekt soll Erkenntnisse dazu liefern, wie unter Berücksichtigung der Verkehrssicherheit die Mobilität der älteren Fahrer so lange wie möglich erhalten werden kann. Unfallanalysen zeigen, dass ältere Kraftfahrer typische Fahrfehler bzw. Unfälle begehen. Unklar ist derzeit die genaue Ursache hierfür, vor allem vor dem Hintergrund der langjährigen Erfahrung älterer Kraftfahrer, welche eher eine äußerst geringe Unfallrate vermuten ließe. Ziel der vorliegenden Untersuchung war es, tiefere Erkenntnisse äber die Ursache von Fahrfehlern älterer Kraftfahrer zu gewinnen, um daraus Anforderungen an die technische Weiterentwicklung von Fahrerassistenzsystemen ableiten zu können. Diese Fahrerassistenzsysteme sollen speziell älteren Autofahrern Hilfestellung zum sicheren Führen von Kraftfahrzeugen bieten. In dem folgenden Laborexperiment wurde ein Doppeltätigkeits-Paradigma verwendet, indem eine Spurhalteaufgabe mit einer peripheren Lichtreizaufgabe kombiniert wurde. Die peripheren Lichtreize wurden den Probanden bilateral in zwei verschiedenen Abständen vom zentralen Punkt des Sehens (20 Grad und 60 Grad) präsentiert. Die Aufgaben wurden von älteren (65+) und jüngeren Kraftfahrern (22-45) zuerst einzeln, dann in Kombination durchgeführt. Um Aufschluss über mögliche Ursachen von Leistungsbeeinträchtigungen erhalten zu können, wurde neben der Erfassung von Verhaltensdaten (Spurabweichungen, Reaktionszeit, Anzahl der Auslassungen) ein Elektroenzephalogramm abgeleitet, welches Einblicke in die zugrunde liegenden neuronalen Verarbeitungsmechanismen ermöglicht. Wie erwartet, zeigten Ältere in der Spurhalteaufgabe schlechtere Leistungen als Jüngere, besonders bei gleichzeitiger Durchführung der Lichtreizaufgabe (Doppel-Aufgabe). In der Lichtreizaufgabe unterschieden sich die Leistungen der Altersgruppen nur bei Lichtreizen, die im 60 Grad Sehwinkel auftraten. Die Älteren reagierten hier langsamer und zeigten mehr Auslassungen als die Jüngeren. Überraschenderweise zeigten alle Versuchspersonen weniger Auslassungen in der Doppel-Aufgabe. Mittels Elektroenzephalogramm wurde anhand der ereigniskorrelierten Potenziale (EKP) deutlich, dass die Defizite Älterer nicht in einer Einschränkung der frühen Verarbeitung peripherer Reize (P1) liegen, da die P1 Amplitude bei Älteren sogar höher war als bei Jüngeren. Die N2 Amplitude, welche Hinweise auf die Verschiebung der Aufmerksamkeit gibt, war bei Jüngeren hingegen bei weiter peripher liegenden Reizen (60 Grad Sehwinkel) erhöht, was einen fronto-zentral fokussierten Kontrollprozess widerspiegelt. Die Orientierung auf den peripheren Reiz (P3a) war bei Älteren geringer ausgeprägt sowie auch die Zuordnung von Verarbeitungsressourcen (P3b) vor allem bei peripheren Lichtreizen. Es liegen zudem Hinweise darauf vor, dass Ältere verlängerte Reaktionszeiten aufgrund einer verzögerten Reaktionsaktivierung aufweisen. Mit dem vorliegenden Experiment konnte also gezeigt werden, dass die schlechteren Leistungen der älteren Versuchspersonen nicht auf periphere Sehleistungsmängel zurückzuführen sind, sondern einem späteren kognitiven Verarbeitungsprozess zuzuschreiben sind. Die Ergebnisse werden vor dem Hintergrund der Literatur und der Erfordernisse technischer Unterstützungen älterer Kraftfahrer diskutiert.
This report presents the results of a stakeholder analysis which has been performed by the EasyWay Cooperative Systems Task Force. The stakeholder analysis aims at identifying potential roles of the road operator in the operation process of selected cooperative services and describing expectations and aspirations related to the future roles and responsibilities from a European road operator- point of view. The following cooperative services have been considered in the stakeholder analysis: Hazardous location notification, Traffic jam ahead warning, Road works warning, Automatic access control and Parking management. The stakeholder analysis used findings from previous projects and performed own studies based on desk research and expert assessments which were carried out by the task partners. The approach includes the development of high-level descriptions showing functional schemes of the operational process chains and potential roles / responsibilities related to the road operator. A deepened analysis was performed by assessing the functional schemes / role profiles and collecting opportunities, concerns, and success factors from a road operator- perspective.
Rechtsfolgen zunehmender Fahrzeugautomatisierung : gemeinsamer Schlussbericht der Projektgruppe
(2012)
Die BASt-Projektgruppe "Rechtsfolgen zunehmender Fahrzeugautomatisierung" hat über die heute verfügbaren Fahrerassistenzsysteme hinaus drei verschiedene Automatisierungsgrade identifiziert und begrifflich definiert: Teil-, Hoch- und Vollautomatisierung. Aus verhaltensrechtlicher Sicht haben sich als wesentliche Unterscheidungsmerkmale verschiedener Automatisierungsgrade die auf das Verkehrsgeschehen fokussierte Aufmerksamkeit des Fahrers und seine ständige Möglichkeit zur Fahrzeugsteuerung herausgestellt. Im Fall der "Teilautomatisierung" ist die Aufmerksamkeit des Fahrers ständig auf das Verkehrsgeschehen gerichtet und er hat aufgrund der permanent von ihm durchzuführenden Systemüberwachung die Möglichkeit zur Fahrzeugsteuerung, so dass dieser Automatisierungsgrad den aktuellen verhaltensrechtlichen Anforderungen entspricht. Die verhaltensrechtlich geforderte Aufmerksamkeitskonzentration auf das Verkehrsgeschehen und die möglicherweise fehlende Möglichkeit zur Fahrzeugsteuerung stehen jedoch der Nutzung höherer Automatisierungsgrade (Hoch- und Vollautomatisierung) derzeit entgegen. Ihre Nutzung ist gegenwärtig nicht mit dem Verhaltensrecht vereinbar, da der menschliche Fahrzeugführer gegen seine Pflichten verstieße, wenn er sich vollständig auf das System verlassen würde. Soweit ein Automatisierungsgrad zugleich eine freihändige Fahrzeugsteuerung vorsieht, bedürfte es der verhaltenspsychologischen Untersuchung, inwieweit dies den Fahrer in der Ausübung ständiger Vorsicht im Sinne von -§ 1 Abs. 1 StVO zu beeinträchtigen vermag. Hinsichtlich der Haftung nach dem Straßenverkehrsgesetz erscheint die Beweislastverteilung im Rahmen von -§ 18 Abs. 1 S. 2 StVG in den Fällen höherer Automatisierungsgrade (Hoch- und Vollautomatisierung) nicht mehr sachgerecht, soweit dem Fahrer in verhaltensrechtlicher Hinsicht die Ausrichtung seiner Aufmerksamkeit auf andere Tätigkeiten als die konventionelle Fahraufgabe ermöglicht wird. Die Regelungen zur Haftung des Fahrzeughalters bleiben bei allen Automatisierungsgraden weiterhin anwendbar. In Bezug auf die Produkthaftung zeigt sich im Fall der vollständig fahrerüberwachten Teilautomatisierung die Bedeutung der Systemgrenzen. Produkthaftungsrechtlich gewinnt hier die Einordnung des bestimmungsgemäßen Gebrauchs wesentlich an Bedeutung. Zur Absicherung dieses bestimmungsgemäßen Gebrauchs ist die nachhaltige Beeinflussung der Verkehrserwartung beim Benutzerkreis entscheidend, soweit nicht primär konstruktive Möglichkeiten nach dem Stand von Wissenschaft und Technik zur Verfügung stehen, um unberechtigtes Systemvertrauen auszuschließen. Bei den höheren Automatisierungsgraden, die nicht mehr der Fahrerüberwachung bedürfen (unter der Annahme, ihre Nutzung wäre verhaltensrechtlich möglich), wäre jeder Schaden, der nicht auf ein Fehlverhalten Dritter oder eine Übersteuerung des Fahrers zurückzuführen ist, geeignet, Herstellerhaftung auszulösen. Diesbezüglich spielt die Darlegungs- und Beweislast eine wesentliche Rolle. Sowohl auf Grund der offenen Fragen in der rechtlichen Bewertung als auch übergreifend zur Verbesserung technischer Ausgangsbedingungen sowie der Gebrauchssicherheit wird von der Projektgruppe weiterer Forschungsbedarf zur Fahrzeugautomatisierung formuliert.