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Hybrid electric vehicles (HEVs) with a power-split system offer a variety of possibilities in reduction of CO2 emissions and fuel consumption. Power-split systems use a planetary gear sets to create a strong mechanical coupling between the internal combustion engine, the generator and the electric motor. This concept offers rather low oscillations and therefore passive damping components are not needed. Nevertheless, during acceleration or because of external disturbances, oscillations which are mostly influenced by the ICE, can still occur which leads to a drivability and performance downgrade. This paper proposes a design of an active damping control system which uses the electric motor to suppress those oscillations instead of handling them within the ICE control unit. The control algorithm is implemented as part of an existing hybrid controller without any additional hardware introduced.

Typical co-simulation platforms cannot handle co-simulations under hard real-time conditions. The most important issue is the coupling of simulation tools together with real-time systems. To solve this problem a real-time coupling mechanism has to be developed which ensures the required hard real-time conditions. This coupling technology has to solve additional problems compared to non-real-time coupling mechanisms. First the most important aspect is a time-correct coupling with the involved real-time systems. Another important task is to keep the round trip time between the coupled systems as small as possible. This is relevant for stability aspects of the coupled simulation. Furthermore sensor signals of such real-time systems are typically corrupted by noise so the real-time coupling technology must be able to handle these noisy coupling signals.

In the automotive industry a strong trend towards electrification is determined. It offers the possibility of a more flexible actuation of the vehicle systems and can therefore reduce the fuel consumption and CO₂ emissions for modern vehicles. This is not only valid for typical drive train components, e.g., for hybrid or pure electric vehicles, but also for chassis components and auxiliaries like power-steering pump or air-conditioning compressor. However, a further electrification is limited by the 14V power net of conventional passenger cars. The high electric currents required by new/additional electrical components may lead to increased line losses and instability in the vehicle electrical system. With the introduction of a medium voltage level (≺60V) these problems can be circumvented.

In the virtual development process validated simulation models are requested to accurately predict power train vibration and comfort phenomena. Conclusions from refined parameter studies enable to avoid costly tests on rigs and on the road. Thereby, an appropriate modeling approach for specific phenomena has to be chosen to ensure high quality results. But then, parameters for characterizing the dynamic properties of components are often insufficient and have to be roughly estimated in this development stage. This results in a imprecise prediction of power train resonances and in a less conclusive understanding of the considered phenomena. Conclusions for improvements remain uncertain. This paper deals with the two different aspects of model refinement and parameter updating. First an existing power train model (predecessor power train) is analyzed whether the underlying modeling approach can reproduce the physical behavior of the power train dynamics adequately.

Cost- and time-efficient vehicle development is increasingly depending on the usage of adequate software tools to enhance effectiveness. The aim is a continuous integration of simulation tools and test environments within the vehicle development process in order to save time and costs. This paper introduces a procedure to reveal the cause of low-frequency powertrain vibrations and the influences on the dynamic behavior of a vehicle on a roller test bench. The affected longitudinal acceleration signal is an arbitrative criterion for the driveability assessment with AVL-DRIVE™, a well-known driveability analysis and development tool for the objective assessment concerning NVH and driveability aspects of full vehicles. These experimental studies are embedded into an approach, which describes the functional assembly of three applied test environments "road," "roller test bench" and "simulation" with according tools in order to facilitate an integrated driveability development process.

In this article a new approach for a combined optimization of performance, emissions, fuel consumption and driveability is presented. Traditionally the development of performance, emissions and consumption takes place on drivetrain testbeds and on chassis dynos. The development of driveability is done in vehicle tests very late in the development phase for which AVL-DRIVE™ is used by many OEMs for the objective evaluation of driveability. The so-called “Vehicle Simulation Model” VSM is a framework for the simulation of driveability in real time. Its flexible model structure as well as the tight connection to AVL-DRIVE™ offers the possibility to integrate the optimization of driveability in earlier development steps and therefore neglect repeating loops in the development caused by e.g. not fulfilled driveability targets.