1
@inproceedings{SUMO2018,
2
          title = {Microscopic Traffic Simulation using SUMO},
3
         author = {Pablo Alvarez Lopez and Michael Behrisch and Laura Bieker-Walz and Jakob Erdmann and Yun-Pang Fl{\"o}tter{\"o}d and Robert Hilbrich and Leonhard L{\"u}cken and Johannes Rummel and Peter Wagner and Evamarie Wie{\ss}ner},
4
      publisher = {IEEE},
5
      booktitle = {The 21st IEEE International Conference on Intelligent Transportation Systems},
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           year = {2018},
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        journal = {IEEE Intelligent Transportation Systems Conference (ITSC)},
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       keywords = {traffic simulation, modelling, optimization},
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            url = {https://elib.dlr.de/124092/}
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}
11

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@article{Heinrichs:2017,
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 abstract = {Microscopic travel demand models take the characteristics of every individual person of the modelled population into account for computing the travel demand for the modelled region. Car sharing is an old concept, but the combination of a car sharing fleet parked in a public space with smartphone services to find available cars nearby offers a new mobility service. It enables people to use a fleet operator's cars by providing individual mobility on demand. However, integrating this mobility option into microscopic travel demand models still is a difficult task due to a lack of data. This paper shows an integrated approach to model car sharing as a new mode for transport within a travel demand model using disaggregated car fleets with car-specific attributes. The necessary parameters for mode choice are estimated from various surveys and integrated into an existing multinominal logit model. The proposed work is used to simulate the travel demand of a synthetic population for the German capital of Berlin. A comparison with the survey results shows that the proposed integration of car sharing meets the real-world data. Furthermore, it is shown that the mode choice reacts well for access restrictions for specific car segments and local accessibility influencing the trip lengths.},
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 author = {Heinrichs, Matthias and Krajzewicz, Daniel and Cyganski, Rita and von Schmidt, Antje},
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 year = {2017},
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 title = {Introduction of car sharing into existing car fleets in microscopic travel demand modelling},
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 pages = {1055--1065},
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 volume = {21},
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 number = {6},
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 issn = {1617-4917},
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 journal = {Personal and Ubiquitous Computing},
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 doi = {10.1007/s00779-017-1031-3}
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}
24

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@article{Treiber:2010,
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   title={An Open-Source Microscopic Traffic Simulator},
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   volume={2},
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   ISSN={1939-1390},
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   url={http://dx.doi.org/10.1109/MITS.2010.939208},
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   DOI={10.1109/mits.2010.939208},
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   number={3},
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   journal={IEEE Intelligent Transportation Systems Magazine},
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   publisher={Institute of Electrical and Electronics Engineers (IEEE)},
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   author={Treiber, M and Kesting, A},
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   year={2010},
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   pages={6–13} }
37

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@Book{MATSim:2016,
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  editor    = {Horni, A. and Nagel, K. and Axhausen, K.W.},
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  publisher = {Ubiquity Press},
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  title     = {The Multi-Agent Transport Simulation MATSim},
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  year      = {2016},
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  doi       = {http://dx.doi.org/10.5334/baw},
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  timestamp = {2024-04-15},
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  url       = {https://matsim.org/the-book},
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}
47

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@Article{Wardrop:1952,
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  author  = {Wardrop, J G},
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  journal = {Proceedings of the Institution of Civil Engineers},
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  title   = {ROAD PAPER. SOME THEORETICAL ASPECTS OF ROAD TRAFFIC RESEARCH.},
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  year    = {1952},
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  number  = {3},
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  pages   = {325-362},
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  volume  = {1},
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  doi     = {10.1680/ipeds.1952.11259},
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  url     = {https://doi.org/10.1680/ipeds.1952.11259}
58
}
59

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@Book{BeckmannEtAl:1955,
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  author    = {Beckmann, Martin J. and C. B. McGuire and C. B. Winsten},
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  publisher = {RAND Corporation},
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  title     = {Studies in the Economics of Transportation},
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  year      = {1955},
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  address   = {Santa Monica, CA},
66
  url       = {https://www.rand.org/pubs/research_memoranda/RM1488.html},
67
}
68

69
@Article{Ortmann2022,
70
  author    = {Paul Ortmann and Chris M.j. Tampère},
71
  journal   = {Journal of Open Source Software},
72
  title     = {dyntapy: dynamic and static traffic assignment in Python},
73
  year      = {2022},
74
  number    = {77},
75
  pages     = {4593},
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  volume    = {7},
77
  doi       = {10.21105/joss.04593},
78
  publisher = {The Open Journal},
79
  url       = {https://doi.org/10.21105/joss.04593},
80
}
81

82
@article{DarzentasEtAl1980,
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	author = {J. Darzentas and Dale F. Cooper and P.A. Storr and M.R.C. McDowell},
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	title ={Simulation of road traffic conflicts at T-junctions},
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	journal = {SIMULATION},
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	volume = {34},
87
	number = {5},
88
	pages = {155-164},
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	year = {1980},
90
	doi = {10.1177/003754978003400505},
91
	URL = {https://doi.org/10.1177/003754978003400505},
92
	eprint = {https://doi.org/10.1177/003754978003400505}
93
}
94

95
@software{opentrafficsim,
96
	author = {Hans van Lint and Alexander Verbraeck and Peter Knoppers and Wouter Schakel},
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	title = {{OpenTrafficSim}},
98
  url = {https://github.com/averbraeck/opentrafficsim},
99
  version = {1.7.6},
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	year = {2025},
101
}
102

103
@inproceedings{Carla,
104
  title = { {CARLA}: {An} Open Urban Driving Simulator},
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  author = {Alexey Dosovitskiy and German Ros and Felipe Codevilla and Antonio Lopez and Vladlen Koltun},
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  booktitle = {Proceedings of the 1st Annual Conference on Robot Learning},
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  pages = {1--16},
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  year = {2017}
109
}
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