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Cartography For Cooperative Manoeuvres With Autonomous Land Vehicles

Published online by Cambridge University Press:  26 November 2010

Javier Alonso ,
Vicente Milanés ,
Enrique Onieva ,
Joshué Pérez ,
Carlos González  and
Teresa de Pedro
Javier Alonso*
Affiliation:
(Centro de Automática y Robótica (CAR), UPM-CSIC, Madrid)
Vicente Milanés
Affiliation:
(Centro de Automática y Robótica (CAR), UPM-CSIC, Madrid)
Enrique Onieva
Affiliation:
(Centro de Automática y Robótica (CAR), UPM-CSIC, Madrid)
Joshué Pérez
Affiliation:
(Centro de Automática y Robótica (CAR), UPM-CSIC, Madrid)
Carlos González
Affiliation:
(Centro de Automática y Robótica (CAR), UPM-CSIC, Madrid)
*
(Email: [email protected])
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Abstract

This article presents a cartographic system to facilitate cooperative manoeuvres among autonomous vehicles in a well-known environment. The main objective is to design an extended cartographic system to help in the navigation of autonomous vehicles. This system has to allow the vehicles not only to access the reference points needed for navigation, but also noticeable information such as the location and type of traffic signals, the proximity to a crossing, the streets en route, etc. To do this, a hierarchical representation of the information has been chosen, where the information has been stored in two levels. The lower level contains the archives with the Universal Traverse Mercator (UTM) coordinates of the points that define the reference segments to follow. The upper level contains a directed graph with the relational database in which streets, crossings, roundabouts and other points of interest are represented. Using this new system it is possible to know when the vehicle approaches a crossing, what other paths arrive at that crossing, and, should there be other vehicles circulating on those paths and arriving at the crossing, which one has the highest priority. The data obtained from the cartographic system is used by the autonomous vehicles for cooperative manoeuvres.

Keywords

Cartographic SystemAutonomous VehiclesIntelligent Transportation Systems (ITS)
Type
Research Article
Information
The Journal of Navigation , Volume 64 , Issue 1 , January 2011 , pp. 141 - 155
Copyright
Copyright © The Royal Institute of Navigation 2010

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References

REFERENCES

Alonso, J. (2009). Cooperative Driving Manouvres among Autonomous Vehicles. PhD thesis. Facultad de Informática, Universidad Politécnica de Madrid.Google Scholar
Bouraoui, L., Petti, S., Laouiti, A., Fraichard, T. and Parent, M. (2006). Cybercar cooperation for safe intersections. In: Proc. IEEE Intelligent Transportation Systems Conference ITSC ’06. 456461.Google Scholar
Drane, C. and Rizos, C. (1997). Positioning Systems in Intelligent Transportation. Artech House ITS Series. Artech House Publishers.Google Scholar
García, R. and de Pedro, T. (1998). Modeling a fuzzy coprocessor and its programming language. Mathware and Soft Computing 5(2–3), 167174.Google Scholar
García, R. and de Pedro, T. (2000). First application of the orbex coprocessor: Control of unmanned vehicles. EUSFLAT-ESTYLF Joint Conference. Mathware and Soft Computing 7(2–3), 265273.Google Scholar
Garcia-Garrido, M. A., Sotelo, M. A. and Martm-Gorostiza, E. (2006). Fast trafic sign detection and recognition under changing lighting conditions. In: Proc. IEEE Intelligent Transportation Systems Conference ITSC ’06. 811816.Google Scholar
Garcia, R., de Pedro, T., Naranjo, J. E., Reviejo, J. and Gonzalez, C. (2002). Frontal and lateral control for unmanned vehicles in urban tracks. In: Proc. IEEE Intelligent Vehicle Symposium. Vol. 2. 583588.Google Scholar
Knowles, D. (2006). Real time continuous curvature path planner for an autonomous vehicle in an urban environment. Technical report. California Institute of Technology.Google Scholar
Leonard, J., How, J., Teller, S., Berger, M., Campbell, S., Fiore, G., Fletcher, L., Frazzoli, E., Huang, A., Karaman, S., Koch, O., Kuwata, Y., Moore, D., Olson, E., Peters, S., Teo, J., Truax, R., Walter, M., Barrett, D., Epstein, A., Maheloni, K., Moyer, K., Jones, T., Buckley, R., Antone, M., Galejs, R., Krishnamurthy, S. and Williams, J. (2009). A perception-driven autonomous urban vehicle. In: The DARPA Urban Challenge (Springer Berlin/Heidelberg, Ed.). Vol. 56 of Springer Tracts in Ad-vanced Robotics. 163230. Springer-Verlag.CrossRefGoogle Scholar
Macek, K., Vasquez, D., Fraichard, T. and Siegwart, R. (2008). Safe vehicle navigation in dynamic urban scenarios. In: Proc. 11th International IEEE Conference on Intelligent Transportation Systems ITSC 2008. 482489.Google Scholar
Mamdani, E. H. (1976). Application of fuzzy logic to approximate reasoning using linguistic synthesis. In: Proceedings of the sixth international symposium on Multiple-valued logic. IEEE Computer Society Press. 196202.Google Scholar
Milanés, V., Onieva, E., Vinagre, B., González, C., Pérez, J. and Alonso, J. (2010). Sistema de asistencia a la conducción basado en una red de comunicaciones de bajo coste. DYNA.CrossRefGoogle Scholar
Milanés, V., Naranjo, J. E., Gonzalez, C., Alonso, J. and de Pedro, T. (2008). Autonomous vehicle based in cooperative GPS and inertial systems. Robotica 26(5), 627633.CrossRefGoogle Scholar
Naranjo, J. E., Bouraoui, L., Garcia, R., Parent, M. and Sotelo, M. A. (2009). Interoperable control architecture for cybercars and dual-mode cars. IEEE Transactions on Intelligent Transportation Systems 10(1), 146154.CrossRefGoogle Scholar
Naranjo, J. E., Sotelo, M. A., Gonzalez, C., Garcia, R. and de Pedro, T. (2007). Using fuzzy logic in automated vehicle control. IEEE Intelligent Systems 22(1), 3645.CrossRefGoogle Scholar
Onieva, E., Alonso, J., Pérez, J., Milanés, V. and de Pedro, T. (2009). Autonomous car fuzzy control modeled by iterative genetic algorithms. In: Proc. 2009 IEEE International Conference on Fuzzy Systems. Korea. 16151620.CrossRefGoogle Scholar
Perez, J., Gonzalez, C., Milanes, V., Onieva, E., Godoy, J. and de Pedro, T. (2009). Modularity, adaptability and evolution in the autopia architecture for control of autonomous vehicles. In: Proc. IEEE International Conference on Mechatronics ICM 2009. 15.Google Scholar
Rowell, J. M. (2001). Applying map databases to advanced navigation and driver assistance systems. The Journal of Navigation 54, 355363.CrossRefGoogle Scholar
Seo, Y. W. and Urmson, C. (2008). A perception mechanism for supporting autonomous intersection handling in urban driving. In: Proc. IEEE/RSJ International Conference on Intelligent Robots and Systems IROS 2008. 18301835.Google Scholar
Thrun, S. (2006). Winning the darpa grand challenge: A robot race through the mojave desert. In: Proc. 21st IEEE/ACM International Conference on Automated Software Engineering ASE ’06. 11–11.Google Scholar
Thrun, S., Montemerlo, M., Dahlkamp, H., Stavens, D., Aron, A., Diebel, J., Fong, P., Gale, J., Halpenny, M., Lau, K., Oakley, C., Palatucci, M., Pratt, V., Stang, P., Strohb, S., Dupont, C. and etc. (2006). The robot that won the darpa grand challenge. Journal of Field Robotics 23, 661692.CrossRefGoogle Scholar
Urmson, C., Duggins, D., Jochem, T., Pomerleau, D. and Thorpe, C. (2008a). From automated highways to urban challenges. In: Proc. IEEE International Conference on Vehicular Electronics and Safety ICVES 2008 610.CrossRefGoogle Scholar
Urmson, C., Anhalt, J., Bae, H., Bagnell, J., Baker, C., Bittner, R. E., Brown, T., Clark, M. N., Darms, M., Demitrish, D., Dolan, J., Duggins, D., Ferguson, D., Galatali, T., Geyer, C. M., Gittleman, M., Harbaugh, S., Hebert, M., Howard, T., Kolski, S., Likhachev, M., Litkouhi, B., Kelly, A., McNaughton, M., Miller, N., Nickolaou, J., Peterson, K., Pilnick, B., Rajkumar, R., Rybski, P., Sadekar, V., Salesky, B., Seo, Y., Singh, S., Snider, J. M., Struble, J. C., Stentz, A., Taylor, M., Whittaker, W. L., Wolkowicki, Z., Zhang, W. and Ziglar, J. (2008b). Autonomous driving in urban environments: Boss and the urban challenge. Journal of Field Robotics 25(8), 425466.CrossRefGoogle Scholar
White, M. (1993). Digital maps – a fundamental element of ivhs. Journal of Intelligent Transportation Systems 1(2), 135150.Google Scholar
Zhao, Y. (2001). Vehicle Location and Navigation Systems. Artech House ITS Series. Artech House Publishers.Google Scholar