Realizing an Effective and Flexible ITS Evaluation Strategy Through Modular and Multi-Scaled Traffic Simulation

The next generation of transportation systems employing advanced ITS and vehicular inter-networking are difficult to evaluate because of their inherent complexity. Advanced control algorithms, sensor setups, multiple communication media, and the varying driver reactions require new planning and evaluation strategies. While simulation tools are often used to study the likely effects of such systems in advance, we do not fully know what to expect as the outcome of a given implementation, making it difficult to validate a simulation's output. Data collection from a variety of field-tests is beginning to provide this data, but simulation definition, implementation and validation tools are all in need of improvement in order to keep up. Here we propose a new simulation framework that can translate a single ITS use case to different simulation tools with multiple traffic networks and/or data sets. This allows simulation tools to be compared and combined as appropri-ate for the given use case in order to improve both the validity and scalability of the simulation, and to facilitate better coop-eration between those working in this rapidly developing field.

[1]  Larry Head,et al.  Surrogate Safety Measures from Traffic Simulation Models , 2003 .

[2]  Valentin Cristea,et al.  AN INTEGRATED VEHICULAR AND NETWORK SIMULATOR FOR VEHICULAR AD-HOC NETWORKS , 2006 .

[3]  Javier Gozalvez iTETRIS : the framework for large-scale research on the impact of cooperative wireless vehicular communications systems in traffic efficiency , 2009 .

[4]  Frank Kargl,et al.  Simulation of ad hoc networks: ns-2 compared to JiST/SWANS , 2008, Simutools 2008.

[5]  Moritz Killat,et al.  Enabling efficient and accurate large-scale simulations of VANETs for vehicular traffic management , 2007, VANET '07.

[6]  Fritz Busch,et al.  Greener Roads By Talking Traffic Lights: Knowledge about Queue Length and Upcoming Traffic Light Signal , 2010 .

[7]  C.M. Clark,et al.  Distributed platoon assignment and lane selection for traffic flow optimization , 2008, 2008 IEEE Intelligent Vehicles Symposium.

[8]  Xabiel G. Pañeda,et al.  Limitations of network emulation with single-machine and distributed ns-3 , 2010, SimuTools.

[9]  Daniel Krajzewicz,et al.  SUMO (Simulation of Urban MObility) - an open-source traffic simulation , 2002 .

[10]  Christoph Schroth,et al.  Simulation of car-to-car messaging: analyzing the impact on road traffic , 2005, 13th IEEE International Symposium on Modeling, Analysis, and Simulation of Computer and Telecommunication Systems.

[11]  Patrick Weber,et al.  OpenStreetMap: User-Generated Street Maps , 2008, IEEE Pervasive Computing.

[12]  Christian Maag,et al.  Modeling cooperative on-road-systems , 2010 .

[13]  Martin Mauve,et al.  Multiple simulator interlinking environment for IVC , 2005, VANET '05.

[14]  Christoph Meinel,et al.  Efficient traffic simulator coupling in a distributed V2X simulation environment , 2010, SimuTools.

[15]  Fritz Busch,et al.  Greener roads by talking traffic lights - Knowledge about queue length and next traffic light signalling , 2010 .

[16]  J. George Shanthikumar,et al.  A Unifying View of Hybrid Simulation/Analytic Models and Modeling , 1983, Oper. Res..

[17]  Elmar Schoch,et al.  Simulation of ad hoc networks: ns-2 compared to JiST/SWANS , 2008, SimuTools.

[18]  Robbert van Renesse,et al.  JiST: an efficient approach to simulation using virtual machines , 2005, Softw. Pract. Exp..