---

Journal of Applied Nonlinear Dynamics 1(1) (2011) 29--50 | DOI:10.5890/JAND.2011.12.002

Jozsef K. Tar; Laszlo Nadai; Imre J. Rudas; Terez A. Varkonyi

Communication Informatics & Telematics Knowledge Centre, Obuda University Budapest, Becsi ut 96/B, H-1034 Budapest, Hungary

Download Full Text PDF

 

Abstract

Precise emission models are so complex that their details practically are not available. The “physics” of hydrodynamic traffic models provides only ambiguousmathematical formulae. Therefore adaptive controllers iteratively improving the forecasts of a rough initial model are required that work without tuning any particular model parameters. For this purpose a simple numerical technique is reported. The stable stationary solutions of a particular model are determined. Then a simple iterative adaptive emission control grasping only the main factors is developed. It is shown that small modification of the parameters of the dynamic model have drastic influence on the emission so the use of adaptive techniques is essential.

Acknowledgments

This research was supported by the National Development Agency and the Hungarian National Scientific Research Fund (OTKA CNK 78168).

References

1. [1]	Peden, M., Scurfield, R., Sleet, D., Mohan, D., Hyder A.A., Jarawan, E. and Mathers, C. (eds.) (2004), World report on road traffic injury prevention, World Health Organization, Geneva.

2. [2]	Dragos, C.-A., Preitl, S., Precup, R.-E., Pirlea, D., Nes, C.-S., Petriu, E.M. and Pozna, C. (2010), Modeling of a vehicle with continuously variable transmission, Proc of the 19th International Workshop on Robotics in Alpe-Adria-Danube Region, Budapest, Hungary, June 23-25, 2010, 441-446.

3. [3]	Transportation Research Board - Highway Capacity Manual 2000, Book Code: HCM2EC, Transportation Reserach Board of the National Academies, US.

4. [4]	Sturm P.J. and Hausberger S. (eds.) (2005), Emissions and fuel consumption from heavy duty vehicles, COST 346, Final Report, Graz University of Technology, http://www.transportresearch. info/Upload/Documents/200906/20090619_171904_26922_II_COST346_WGA_FinalReport.pdf

5. [5]

   Joumard, R., Andre, J.-M., Rapone, M., Zallinger, M., Kljun N., Andre, M., Samaras, Z., Roujol, S., Laurikko, J., Weilemann, M., Markewitz, K., Geivanidis, S., Ajtay, D. and Paturel, L. (2007), Emission factor modelling and database for light vehicles, Report no. LTE 0523, June 2007, Institut National de Recherche sur les Transports et leur Securite, France , http://inrets.fr/ur/lte/publiautresactions/ fichesresultats/ficheartemis/road3/database32/Artemis deliverable_3_LTE0523.pdf

6. [6]

   Hausberger, S., Rexeis, M., Zallinger, M. and Luz, R. (2009), Emission factors from the model PHEM for the HBEFA Version 3, Report Nr. I-20a/2009 Haus-Em 33a/08/679 from 07.12.2009, Graz University of Technology, http://www.tfeip-secretariat.org/assets/Transport/Ongoing-projects/TUGLCVHBEFAaktuell.pdf

7. [7]	Figueiredo, L., Tenreiro Machado, J.A. and Ferreira, J.R. (2004), Dynamical analysis of freeway traffic, IEEE Transactions On Intelligent Transportation Systems, 5(4), 259-266.

8. [8]	Hoogendoorn, S.P. and Bovy, P.H.L. (2001), State-of-the-art of vehicular traffic flow modelling, Proceedings of the Institution of Mechanical Engineers, Part I: Journal of Systems and Control Engineering, 215(4), 283-303.

9. [9]	Luspay, T., Kulcsar, B., Varga, I. and Bokor, J. (2010), Parameter-dependent modeling of freeway traffic flow, Transportation Research Part C: Emerging Technologies, 18(4), 471-488.

10. [10]	Tettamanti, T., Varga, I. and Peni, T. (2010),MPC in urban traffic management,Model Predictive Control, (ed.: Tao Zheng), InTech, 251-268.

11. [11]	Papageorgiou, M. (1998), Some remarks on macroscopic traffic flow modeling, Transportation Research, A 32(5), 323-329.

12. [12]	Diakaki, C., Papageorgiou, M. and Abodoulas K. (2002), A multivariable regulator approach to trafficresponsive network-wide signal control, Control Engineering Practice, 10, 183-195.

13. [13]	Nguyen, C.C., Antrazi, S.S., Zhou, Z.-L. and Campbell, C.E. Jr. (1993), Adaptive control of a Stewart platform-based manipulator, Journal of Robotic Systems, 10(5), 657-687.

14. [14]	Kamnik, R., Matko, D. and Bajd, T. (1998), Application of Model Reference Adaptive Control to industrial robot impedance control, Journal of Intelligent and Robotic Systems, 22, 153-163.

15. [15]	Somlo, J., Lantos, B. and Cat, P.T. (2002), Advanced robot control, Akademiai Kiado, Budapest, Hungary.

16. [16]	Hosseini-Suny, K., Momeni, H. and Janabi-Sharifi, F. (2010), Model Reference Adaptive Control design for a teleoperation system with output prediction, J Intell Robot Syst, DOI 10.1007/s10846-010-9400-4, 1-21.

17. [17]	Lyapunov, A.M. (1892), A general task about the stability of motion (in Russian), PhD Thesis, University of Kazan, Russia.

18. [18]	Lyapunov, A.M. (1966), Stability of motion, Academic Press, New-York and London.

19. [19]

    Tar, J.K., Bito, J.F., Rudas, I.J., Kozlowski, K.R. and Tenreiro Machado, J.A. (2008), Possible adaptive control by tangent hyperbolic fixed point transformations used for controlling the φ6-type Van der Pol oscillator, Proc. of the 6th IEEE International Conference on Computational Cybernetics (ICCC 2008), November 27-29, 2008, Stara Lesna, Slovakia, 15-20.

20. [20]	Tar, J.K., Bito, J.F., Nadai, L. and Tenreiro Machado, J.A. (2009), Robust Fixed Point Transformations in adaptive control using local basin of attraction, Acta Polytechnica Hungarica, 6(1), 21-37.

21. [21]

    Rudas, I.J., Tar, J.K. and Varkonyi, T.A. (2011), Novel adaptive synchronization of different chaotic Chua circuits, Proc. of the ETAI COSY 2011, Special International Conference on Complex Systems: Synergy, of Control, Communications and Computing, COSY 2011, 16-20 September 2011, Ohrid, Macedonia, 109-114.

22. [22]

    Tar, J.K., Bito, J.F. and Rudas, I.J. (2010), Replacement of Lyapunov's direct method in Model Reference Adaptive Control with Robust Fixed Point Transformations, Proc. of the 14th IEEE International Conference on Intelligent Engineering Systems 2010, Las Palmas of Gran Canaria, Spain, May 5-7, 231-235.

23. [23]

    Tar, J.K., Bito, J.F., Rudas, I.J. and Eredics, K. (2010), Comparative analysis of a traditional and a novel approach to model reference adaptive control, Proc. of the 11th International Symposium of Hungarian Researchers on Computational Intelligence and Informatics, Budapest, November 18-20, 2010, 93-98

24. [24]	Greenshields, B.D. (1935), A study of traffic capacity, Proc. of the Highway Research Board, 14, 448-477.

25. [25]	Callen, H.B. (1985), Thermodynamics and an Introduction to Thermostatistics, 2nd Edition, JohnWiley & Sons Inc.

26. [26]	Kondepudi, D. and Prigogine, I. (1998),Modern Thermodynamics, John Wiley & Sons, Chichester.

27. [27]	Dalla Man, C., Rizza, R. and Cobelli, C. (2007), Meal simulation model of the glucose-insulin system, IEEE Transactions in Biomedical Engineering, 54(10), 1740-1749.

28. [28]	Magni, L., Raimondo, D.M., Dalla Man, C., De Nicolao, G., Kovatchev, B. and Cobelli, C. (2009), Model predictive control of glucose concentration in type I diabetic patients: An in silico trial, Biomedical Signal Processing and Control, 4(4), 338-346.

29. [29]	Baudin ,M., Couvert, V. and Steer, S. (2010), Optimization in SCILAB, Scilab Consortium & INRIA Paris - Rocquencourt, www.scilab.org

30. [30]	http://www.scilab.org/education/higher_education

31. [31]	http://www.scilab.org/communities/international/china

32. [32]	http://www.scilab.org/communities/international/india

33. [33]	http://www.scilab.org/communities/international/japan

34. [34]	Papageorgiou, M. and Kotsialos, A. (2000), Freeway ramp metering: an overview, IEEE Transactions on Intelligent Transportation Systems, 3(4), 271-281.

35. [35]	Traffic Detector Handbook: Third Edition Volume I. Research, Development, and Technology, Publication No. FHWA-HRT-06-108 October 2006, U.S. Department of Transportation, Federal Highway Administration, Turner-Fairbank Highway Research Center