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- Abteilung Fahrzeugtechnik (162) (entfernen)
The objective was to develop and validate a crash trolley (reference vehicle) equipped with a compartment and a full restraint system for driver and front seat passenger which can be used in full scale crash testing. Furthermore, the crash trolley should have a suspension to show rotation and nick effects similar to real vehicles. Within the development phase the reference vehicle was build based on a European family car. Special attention was needed to provide appropriate strength to the trolley and its suspension. The reference vehicle is equipped with a restraint system consisting of airbags, pedals, seats, dashboard, and windscreen. On the front of the vehicle different crash barriers can be installed to provide miscellaneous deceleration pulses. For the validation phase a series of low and high speed crash tests with HIII dummies were conducted and compared with full scale tests. For the comparison deceleration pulse, dummy numbers and vehicle movement were analyzed. Validation tests with velocities up to 60 km/h showed promising results. The compartment and the suspension systems stayed stable. Rotation effects were comparable with full scale car crash tests. The airbags and seat belt system worked reasonable. The acceleration pulse compared to an Euro NCAP test had a similar characteristic but was in general slightly lower. After the successful validation the reference vehicle is already in use in different studies in the field of vehicle safety research at BASt.
In the European Project FIMCAR, a proposal for a frontal impact test configuration was developed which included an additional full width deformable barrier (FWDB) test. Motivation for the deformable element was partly to measure structural forces as well as to produce a severe crash pulse different from that in the offset test. The objective of this study was to analyze the safety performance of vehicles in the full width rigid barrier test (FWRB) and in the full width deformable barrier test (FWDB). In total, 12 vehicles were crashed in both configurations. Comparison of these tests to real world accident data was used to identify the crash barrier most representative of real world crashes. For all vehicles, the airbag visible times were later in the FWDB configuration. This was attributed to the attenuation of the initial acceleration peak, observed in FWRB tests, by the addition of the deformable element. These findings were in alignment with airbag triggering times seen in real world crash data. Also, the dummy loadings were slightly worse in FWDB compared to FWRB tests, which is possibly linked to the airbag firing and a more realistic loading of the vehicle crash structures in the FWDB configuration. Evaluations of the lower extremities have shown a general increasing of the tibia index with the crash pulse severity.
Frontal impact is still the most relevant impact direction in terms of injury causation amongst car occupants. Especially for car-to-car frontal impacts the mass ratio between the involved vehicles has a significant impact on the injury risk (the heavier the opponent car the higher the injury risk). In order to address this issue frontal Mobile Deformable Barrier test procedures have been developed world-wide (for example the MPDB procedure that was fully described during the FIMCAR Project). The objective of this study was to investigate how vehicles of different weight classes perform in a mobile barrier test procedure compared to a fixed barrier test procedure (the full width rigid and offset deformable barrier test). Beyond that, the influence of vehicle mass and vehicle deformation on injuries was evaluated based on real world accident data. Five vehicle types were selected and tested in a fixed offset test procedure (ODB), a full width rigid barrier test procedure (FWRB) and a mobile offset test procedure (MPDB). For the accident analyses data from the German In-Depth Accident Study (GIDAS) was evaluated with a focus on MAIS 2+ injured belted front row car (UN-R 94 compliant cars) occupants in frontal impact accidents. Test data indicates higher dummy loadings, in particular for the head acceleration and chest acceleration, in the MPDB test for the vehicles with a mass lighter than the trolley (1,500 kg) compared to the FWRB test. The trend of increased vehicle stiffness (especially illustrated by tests with the MPDB and small cars) shows the need of a further improvement of passive restraint systems to reduce the occupant loading and with it the injury risk. The analyzed GIDAS data confirm the higher injury risk for occupants in cars with an accident weight of less than 1,500 kg compared to those with a crash weight above 1,500 kg in car-to-car and car-to-object or car-to-HGV, respectively. Furthermore the injury risk increases with decreasing mass ratio (i.e., the opponent car is heavier) in car-to-car accidents. Independent from the higher injury risk, the risk for passenger compartment intrusion in frontal impact appears not to be independent on the crash weight of the car.
The goal of the project FIMCAR (Frontal Impact and Compatibility Assessment Research) was to define an integrated set of test procedures and associated metrics to assess a vehicle's frontal impact protection, which includes self- and partner-protection. For the development of the set, two different full-width tests (full-width deformable barrier [FWDB] test, full-width rigid barrier test) and three different offset tests (offset deformable barrier [ODB] test, progressive deformable barrier [PDB] test, moveable deformable barrier with the PDB barrier face [MPDB] test) have been investigated. Different compatibility assessment procedures were analysed and metrics for assessing structural interaction (structural alignment, vertical and horizontal load spreading) as well as several promising metrics for the PDB/MPDB barrier were developed. The final assessment approach consists of a combination of the most suitable full-width and offset tests. For the full-width test (FWDB), a metric was developed to address structural alignment based on load cell wall information in the first 40 ms of the test. For the offset test (ODB), the existing ECE R94 was chosen. Within the paper, an overview of the final assessment approach for the frontal impact test procedures and their development is given.
Das Ziel der Untersuchung war, die Grenzen der Belastbarkeit eines Rollstuhl- und Personenrückhaltesystems mit Kraftknoten nach DIN 75078-2 zu ermitteln. Dazu wurden dynamische Schlittenversuche durchgeführt, bei denen die Verzögerungspulse sowie das Gesamtgewicht von Rollstuhl und Prüfpuppe variiert wurden. Für die Untersuchungen kamen ein Prüfrollstuhl, definiert nach ISO 10542, und Rückhaltesysteme mit Kraftknoten gemäß DIN 75078-2 zum Einsatz. Das Rückhaltesystem bestand aus einem Rollstuhl- und einem Personenrückhaltesystem, wobei das Rollstuhlrückhaltesystem (RRS) mit vier bzw. sechs Gurten und entsprechenden Retraktoren an einem dynamischen Schlittenaufbau befestigt wurde. Das Personenrückhaltesystem (PRS) bestand aus einem am Rollstuhl integrierten Beckengurt sowie einem Schulterschräggurt, der am Beckengurt und am Schlittenaufbau befestigt wurde. Ferner wurden bei den Versuchen Prüfpuppen verschiedener Alters- und Gewichtsklassen (P6, HIII 5 %, HIII 50 % und HIII 95 %) eingesetzt Die Belastungsanforderungen für das Rückhaltesystem wurden sukzessiv erweitert, indem einerseits das Gesamtgewicht (Rollstuhl und Prüfpuppe) und andererseits auch die Verzögerungspulse bis zur Versagensgrenze erhöht wurden. Das Vier-Gurt-Rückhaltesystem konnte bei einem Verzögerungspuls von 10 g einem Gesamtgewicht von bis zu 221 kg standhalten. Bei einem Verzögerungspuls von 20 g und einem Gesamtgewicht von 134 kg wurde das Vier-Gurt-System bis über die Grenzen belastet. Das Sechs-Gurt-Rückhaltesystem hat Belastungen bis 221 kg standgehalten. Infolgedessen ist bei einer Erhöhung der Verzögerungspulse auf 20 g und einem Gesamtgewicht von mehr als 109 kg ein Sechs-Gurt-System zu empfehlen.
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.
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 the final report to the steering committee on frontal impact [Faerber 2007] and the FP5 VC-COMPAT[Edwards 2007] project activities, two test approaches were 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 will be performed. In the FIMCAR Deliverable D 3.1 [Adolph 2013] the development and assessment of criteria and associated performance limits for the full width test procedure were reported. In this Deliverable D3.2 analyses of the test data (full width tests, car-to-car tests and component tests), further development and validation of the full width assessment protocol and development of the load cell and load cell wall specification are reported. The FIMCAR full-width assessment procedure consists of a 50 km/h test against the Full Width Deformable Barrier (FWDB). The Load Cell Wall behind the deformable element assesses whether or not important Energy Absorbing Structures are within the Common Interaction Zone as defined based on the US part 581 zone. The metric evaluates the row forces and requires that the forces directly above and below the centre line of the Common Interaction Zone exceed a minimum threshold. Analysis of the load spreading showed that metrics that rely on sum forces of rows and columns are within acceptable tolerances. Furthermore it was concluded that the Repeatability and Reproducibility of the FWDB test is acceptable. The FWDB test was shown to be capable to detect lower load paths that are beneficial in car-to-car impacts.
In general the passive safety capability is much greater in newer versus older cars due to the stiff compartment preventing intrusion in severe collisions. However, the stiffer structure which increases the deceleration can lead to a change in injury patterns. In order to analyse possible injury mechanisms for thoracic and lumbar spine injuries, data from the German Inâ€Depth Accident Study (GIDAS) were used in this study. A twoâ€step approach of statistical and caseâ€byâ€case analysis was applied for this investigation. In total 4,289 collisions were selected involving 8,844 vehicles, 5,765 injured persons and 9,468 coded injuries. Thoracic and lumbar spine injuries such as burst, compression or dislocation fractures as well as soft tissue injuries were found to occur in frontal impacts even without intrusion to the passenger compartment. If a MAIS 2+ injury occurred, in 15% of the cases a thoracic and/or lumbar spine injury is included. Considering AIS 2+ thoracic and lumbar spine, most injuries were fractures and occurred in the lumbar spine area. From the case by case analyses it can be concluded that lumbar spine fractures occur in accidents without the engagement of longitudinals, lateral loading to the occupant and/or very severe accidents with MAIS being much higher than the spine AIS.
Advancing active safety towards the protection of vulnerable road users: the PROSPECT project
(2017)
Accidents involving Vulnerable Road Users (VRU) are still a very significant issue for road safety. According to the World Health Organisation, pedestrian and cyclist deaths account for more than 25% of all road traffic deaths worldwide. Autonomous Emergency Braking Systems have the potential to improve safety for these VRU groups. The PROSPECT project (Proactive Safety for Pedestrians and Cyclists) aims to significantly improve the effectiveness of active VRU safety systems compared to those currently on the market by expanding the scope of scenarios addressed by the systems and improving the overall system performance. The project pursues an integrated approach: Newest available accident data combined with naturalistic observations and HMI guidelines represent key inputs for the system specifications, which form the basis for the system development. For system development, two main aspects are considered: advanced sensor processing with situation analysis, and intervention strategies including braking and steering. All these concepts are implemented in several vehicle prototypes. Special emphasis is put on balancing system performance in critical scenarios and avoiding undesired system activations. For system validation, testing in realistic scenarios will be done. Results will allow the performance assessment of the developed concepts and a cost-benefit analysis. The findings within the PROSPECT project will contribute to the generation of state -of-the-art knowledge, technical innovations, assessment methodologies and tools for advancing Advanced Driver Assistance Systems towards the protection of VRUs. The introduction of a new generation safety system in the market will enhance VRU road safety in 2020-2025, contributing to the "Vision Zero" objective of no fatalities or serious injuries in road traffic set out in the Transport White Paper. Furthermore, the test methodologies and tools developed within the project shall be considered for the New Car Assessment Programme (Euro NCAP) future roadmaps, supporting the European Commission goal of halving the road toll in the 2011-2020 timeframe.
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 UN Regulation No. 79 is going to be amended to allow automatically commanded steering functions (ACSF) at speeds above 10 km/h. Hence, requirements concerning the approval of automatically performed steering manoeuvres have to be set in order to allow safe use of automatic steering on public roads as well as improve overall road safety for the driver and the surroundings. By order of the German Federal Ministry of Transport and Digital Infrastructure (BMVI), BASt developed and verified physical test procedures for automatic steering to be implemented in UN Regulation No. 79. The usability of currently available test tools was examined. The paper at hand describes these test procedures and presents results from verification tests. The designated tests are divided in three sections: functionality tests, verifications for the transition of control and emergency tests. System functionality tests are auto matic lane keeping, automatic lane change and an automatic abort of an initiated lane change due to traffic. Those tests check if the vehicle remains in its lane (under normal operating conditions), is able to perform safe automatic lane change manoeuvres and if it considers other road users during its manoeuvres. Transition tests examine the vehicle's behaviour when the driver fails to monitor the system and in situations when the system has to hand over the steering control back to the driver. For instance these tests provoke driver-in-the-loop requests by approaching system boundary limitations, like missing lane markings, surpassing maximum lateral acceleration in a bend or even a major system failure. Even further the driver and his inputs are monitored and if the system detects that he is overriding system actions or contrary want to quit the driving task and unfastens the seat belt, it has to shut down and put the human back into manually control and the responsibility of driving. The last series of test consists of two emergency situations in which the system has to react to a time critical event: A hard decelerating vehicle and a stationary vehicle in front both with no lane change possibility for the ACSF vehicle. Some of the tests, especially the emergency manoeuvres, require special target vehicles and propulsion systems. Since no fully automatic steering vehicles are available, a current Mercedes E-Class with Mercedes' "drive pilot" system was used. It was shown that the vehicle is automatically able to brake to a full stop towards a static Euro NCAP target from partial-automatic driving at 90 km/h, that it could brake towards a rapidly decelerating lead vehicle when travelling at 70 km/h, that it was able during partially automatic driving to remain in its lane in normal operation conditions and to perform a automatic (driver initiated) lane change while surveilling the driver- activities.
In den vergangenen 20 Jahren hat der Verkehrslärm an Autobahnen um durchschnittlich 2,5 dB(A), an Bundesstraßen um 1,5 dB(A) zugenommen. Die Absenkung der Geräuschgrenzwerte durch technische Maßnahmen an den Fahrzeugantrieben brachte nicht den gewünschten Erfolg, da außerorts das Reifen-Fahrbahn-Geräusch überwiegt und die Verkehrsmenge generell stark gewachsen ist. Eine Stagnation des Verkehrsaufkommens ist nicht erkennbar, sodass auch in Zukunft neue Straßen in der dicht besiedelten Bundesrepublik nur noch zusammen mit sehr kostenintensiven Lärmschutzmaßnahmen geplant und gebaut werden können. Mit dieser Ausgangslage wurde, als Teil des Forschungsnetzwerkes "Leiser Verkehr", das Verbundprojekt "Reduzierte Reifen-Fahrbahn-Geräusche" konzipiert. In dem Projekt arbeiten 16 Partner aus Verwaltung, Industrie und Forschung zusammen, um zum einen die theoretischen Grundlagen bei der Entstehung und Messung von Reifen-Fahrbahn-Geräuschen zu erarbeiten, zum anderen die Komponenten des Systems "Reifen-Fahrbahn" zu optimieren. Dieses System setzt sich aus den Teilen Reifen, Fahrzeug, Straße (Asphalt-, Betonbauweise) und den Fahrbahnübergängen der Brücken zusammen. Im Rahmen der Projektlaufzeit sollen 1 bis 3 dB(A) leisere Komponenten des geräuscherzeugenden Gesamtsystems entwickelt, erprobt und gebaut werden. Mittelfristig soll durch die Entwicklung von Reifen-Fahrbahn-Geräusch-Modellen ein mindestens 5 dB(A) leiseres Gesamtsystern konzipiert werden. Nach Beginn im Sommer 2001 befindet sich das Projekt momentan in der Arbeitsphase und mit ersten Ergebnissen ist Ende des laufenden Jahres zu rechnen.
Es wird über das Ende 2002 abgeschlossene EU-Projekt ADVISORS berichtet. Ziel dieses Projektes, an dem sich 16 Organisationen aus 10 europäischen Ländern beteiligten, war es, die Entwicklung, Testung und Implementierung von Fahrerassistenzsystemen (FAS) zu unterstützen. Es wurde eine umfassende Methodik zur Bewertung von FAS entwickelt und auf dieser Basis wurden eine Reihe von Evaluationsstudien zu ausgewählten FAS durchgeführt. Des Weiteren wurden Implementierungsstrategien für bestimmte FAS entwickelt und mit Experten verschiedener Länder diskutiert.
Abschluss des deutsch-französischen Verbundprojekts "Inter-Vehicle Hazard Warning" (DEUFRAKO-IVWH)
(2004)
Im Rahmen der Deutsch-Französischen Kooperation im Verbundprojekt "Inter-Vehicle Hazard Warning" (DEUFRAKO-IVWH) wurde ein auf Fahrzeug-Fahrzeug-Kommunikation basierendes Warnsystem konzipiert und bewertet. Die im Rahmen des Projekts durchgeführten Arbeiten haben gezeigt, dass ein auf Fahrzeug-Fahrzeug-Kommunikation basierendes Warnsystem prinzipiell geeignet ist, einen Beitrag zur Erhöhung der Verkehrssicherheit zu leisten. Das Ausmaß der zu erwartenden positiven Effekte ist allerdings ganz wesentlich abhängig vom Ausstattungsgrad der Fahrzeugflotte mit einem solchen System.
Falltests zur Untersuchung der Belastungen von Dummys beim Aufprall auf den Boden, Teil 1 und 2
(2010)
Beim Zusammenprall eines Motorrads mit einem Pkw unterscheidet man in der Unfallforschung sowohl den Erstanprall des Motorradfahrers an den Pkw als auch den Sekundäraufprall des Motorradfahrers auf dem Boden. So genannte Full-Scale-Crashtests mit Dummys haben beim Erstanprall gezeigt, dass Motorradfahrer durch Airbags potenziell geschützt werden können. Bei den entsprechenden Unfallsimulationen wurde jedoch im weiteren Bewegungsablauf beim nachfolgenden Sekundäraufprall auf dem Boden festgestellt, dass relativ hohe Belastungen auf den Dummy einwirken. Es stellt sich hierbei jedoch die Frage, ob die üblicherweise für Lasteinwirkungen im Falle eines Erstanpralls entwickelten und validierten Dummys die bei einem Sekundäraufprall auf einen Motorradfahrer einwirkenden Belastungen hinreichend genau wiedergeben können. Dazu wurden die Belastungen eines Dummys beim Aufprall auf den Boden untersucht, um das Verletzungsrisiko eines menschlichen Motorradfahrers einschätzen zu können. Im Dekra-Crash-Test-Center wurden vier verschiedene Aufprallsituationen mit einem Hybrid III Dummy durchgeführt, wobei diese Tests an eine andere Testreihe angelehnt sind, die bereits am US-amerikanischen Institut "Dynamic Research International" (DRI) durchgeführt worden waren. Nach der Erläuterung des Testaufbaus und seiner Durchführung wird detailliert auf die gemessenen Verzögerungsbelastungen des Dummys eingegangen. Hierbei geben zum einen Tabellen eine Übersicht über charakteristische Messwerte zur Quantifizierung der maximalen Belastung des Dummys, zum anderen veranschaulichen Bilder die zugehörigen zeitlichen Verzögerungsverläufe in Becken, Brust und Kopf des Dummys. Der Artikel schließt mit einer Interpretation der Versuchsergebnisse und gibt einen Ausblick auf den weiteren Untersuchungsbedarf.
Die Kommunikation zwischen Fahrzeugen und Infrastrukturkomponenten steht vor der Einführung in Europa. Dieser Beitrag stellt zunächst die grundlegende Technologie zum Austausch von Nachrichten und ein Pilotprojekt vor, innerhalb dessen eine sichere Fahrzeug-zu-Infrastruktur Kommunikation konzipiert und praktisch erprobt wird. Darauf aufbauend werden Sicherheitsfragestellungen von Infrastrukturkomponenten beleuchtet und ein Einblick in das Schlüsselmanagement sowohl für Fahrzeuge als auch Infrastrukturkomponenten gegeben.
Regarding to the German road traffic licensing regulations it is mandatory to have a light system using a bicycle in public traffic. All attached components must be approved. The admission requires additional restrictions such as a dynamo as energy source with a nominal voltage of 6 V. Batteries are only allowed in addition to this. To adopt the German bicycle regulation to the state of art of an energy efficient lighting, additional power sources such as a battery respectively rechargeable batterie should be evaluated. The project will propose amendments for German Road Traffic Regulations and technical requirements.
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.
Anforderungen, Zielkonflikte
(2019)
Um Sicherheit und Umweltverträglichkeit von Straßen- bzw. Kraftfahrzeugen zu gewährleisten, werden an die Gestaltung der Fahrzeuge technische Anforderungen gestellt. Es gibt Anforderungen durch den Gesetzgeber, die erfüllt werden müssen, um ein Fahrzeug in den Verkehr bringen zu dürfen. Darüber hinaus bestehen herstellerinterne Anforderungen an das Produkt, die über das vom Gesetzgeber geforderte Maß hinausgehen, um den Kundenwünschen und der Firmenphilosophie zu genügen. Und als dritter Punkt stellen auch Verbraucherschutz-Organisationen Kriterien auf, anhand derer sie die Eigenschaften der auf dem Markt befindlichen Fahrzeuge bewerten und die Fahrzeuge eingruppieren, was dann der Kundeninformation dient. Auch diese Anforderungen gehen über die des Gesetzgebers hinaus. Das Setzen der gesetzlichen Mindestanforderungen ist für die Fahrzeugtechnik mittlerweile jedoch nicht mehr einzelnen Staaten überlassen. Vielmehr sind die für die Genehmigung von Fahrzeugtypen einzuhaltenden Bedingungen international harmonisiert: Für die EU sind dies EU-Richtlinien oder EU-Verordnungen, die von der Europäischen Kommission in Brüssel vorgeschlagen werden. Für über die EU hinausgehende Staaten bzw. Regionen sind dies unter anderem Regelungen der UN, erstellt von der UN-Wirtschaftskommission für Europa (UNECE) in Genf.
Bicyclists and pedestrians belong to the most endangered groups in urban traffic. The EU-funded collaborative research project PROSPECT (‘PROactive Safety for PEdestrians and CyclisTs´) aims to significantly improve safety of those unprotected traffic participants by expanding the scope of scenarios covered by future active safety systems in passenger cars. Concepts for sensor control systems are built into three prototypes covering emergency interventions such as Autonomous Emergency Braking (AEB) as well as Autonomous Emergency Steering (AES). These systems tackle the well-known challenges of currently available systems including limited field-of-view by sensors, fuzzy path prediction, unreliable intent reaction times and slow reaction times. These highly innovative functions call for extensive validation methodologies based on already established consumer testing procedures. Since these functions are developed towards the prevention of intersection accidents in urban areas, a key aspect of the advanced testing methodology is the valid approximation of naturalistic trajectories using driving robots. Eventually, several simulator studies complemented a user acceptance and benefit analysis to evaluate the expected overall impact of the PROSPECT systems. The results achieved within the PROSPECT project are highly relevant for upcoming test protocols regarding the most critical situations with Vulnerable Road Users (VRU). With introducing the new methods in Euro NCAP (European New Car Assessment Programme) a significant increase in road safety is expected.