WSEAS Transactions on Mathematics


Print ISSN: 1109-2769
E-ISSN: 2224-2880

Volume 18, 2019

Notice: As of 2014 and for the forthcoming years, the publication frequency/periodicity of WSEAS Journals is adapted to the 'continuously updated' model. What this means is that instead of being separated into issues, new papers will be added on a continuous basis, allowing a more regular flow and shorter publication times. The papers will appear in reverse order, therefore the most recent one will be on top.

Volume 18, 2019


Behavior of Continuous Two-contours System

AUTHORS: Alexander G. Tatashev, Marina V. Yashina

Download as PDF

A deterministic continuous dynamical system is considered. This system contains two contours. The length of the ith contour equals c_i, i=1,2. There is a moving segment (cluster) on each contour. The length of the cluster, located on the ith contour, equals l_i, i=1,2. If a cluster moves without delays, then the velocity of the cluster is equal to 1. There is a common point (node) of the contours. Clusters cannot cross the node simultaneously, and therefore delays of clusters occur. A set of repeating system states is called a spectral cycle. Spectral cycles and values of average velocities of clusters have been found. The system belongs to a class of contour networks. This class of dynamical systems has been introduced and studied by A.P. Buslaev.

KEYWORDS: - Dynamical system, Contour networks, Self-organization, Average velocity of particles

REFERENCES:

[1] K. Nagel and M. Schreckenberg, Cellular automation models for freeway traffic, J. Phys. I. 9, 1972, pp. 296–305.

[2] V. Belitzky and P.A. Ferrary. Invariant measures and convergence properties for cellular automation 184 and related processes, J. Stat. Phys. 118(3), 2005, pp. 589–623.

[3] S. Wolfram. Statistical mechanics of cellular automata, Rev. Mod. Phys., 55, 1983, pp. 601- 644.

[4] M.L. Blank, Exact analysis of dynamical systems arising in models of flow traffic, Russian Math Surveys, 55(5), 2000, pp. 562- 563

[5] L. Gray and D. Grefeath, Exact analysis of dynamical systems arising in models of flow traffic, The ergodic theory of traffic jams, 105(3/4), 2001, pp. 413–452. pp. 562-563

[6] M. Kanai, Exact solution of the zero range process Journal of Physics A. Mathematical and Theoretical, 40(19), 2007, pp. 7127–7138.

[7] M. Blank. Metric properties of discrete time exclusion type processes in continuum. M Journal of Statistical Physics, 140 (1), pp. 170- 197, 2010. M. Kanai M, Exact solution of the zero range process, Journal of Physics A. Mathematical and Theoretical, 40(19), 2007, pp. 7127–7138.

[8] Biham O., Middleton A.A., Levine D. (November 1992). Self-organization and a dynamical transition in traffic-flow models. Phys. Rev. A. American Physical Society. 46 (10): pp. R6124пїЅ-R6127.

[9] D’Souza R.M. (2005). Coexisting phases and lattice dependence of a cellular automaton model for traffic flow. Phys. Rev. E. The American Physical Society. 71 (6): 066112.

[10] Angel O., Horloyd A.E., Martin J.B. (12 August 2005). The jammed phase of the Biham-Middleton-Levine traffic model. Electronic Communication in Probability. 10: pp. 167-178.

[11] Austin T., Benjamini I. (2006). For what number of cars must self organization occur in the BihamпїЅMiddletonпїЅLevine traffic model from any possible starting configuration arXiv:math/0607759

[12] A.S. Bugaev, A.P. Buslaev, V.V. Kozlov, M.V. Yashina. Distributed problems of monitoring and modern approaches to traffic modeling, 14th International IEEE Conference on Intelligent Transactions Systems (ITSC 2011), Washington, USA, 5–7.10.2011, pp. 477–481.

[13] V.V. Kozlov, A.P. Buslaev and A.G. Tatashev. On synergy of totally connected flow on chainmails, CMMSE-2013, Cadis, Spain, 3, pp. 861–873.

[14] A.P. Buslaev, M.Yu. Fomina, A.G. Tatashev and M.V. Yashina, On discrete flow networks model spectra: statement, simulation, hypotheses. J. Phys.: Conf. Ser. 1053, 2018, 012034.

[15] A.P. Buslaev and A G. Tatashev. Flows on discrete traffic flower, Journal of Mathematics Research, 9(1), pp. 98–108

[16] A.P. Buslaev and A.G. Tatashev. Exact results for discrete dynamical systems on a pair of contours. Math Math. Appl. Sci., February, 2018.

[17] V.V. Kozlov, A.P. Buslaev and A.G. Tatashev. Monotonic walks on a necklace and coloured dynamic vector. Int. J Comput Math, 92(9), pp. 1910 – 1920.

[18] A.P. Buslaev, A.G. Tatashev, M.V. Yashina, Flows spectrum on closed trio of contours. Eur. J. Pure Appl. Math., 11(3), pp. 893-897.

[19] A.P. Buslaev, A.G. Tatashev. Spectra of local cluster flows on open chain of contours. Eur. J. Pure Appl. Math., 11(3), pp. 628–641.

[20] A.A. Buchshtab. Number theory, Procveshcheniye, Moscow 1966. (In Russian)

WSEAS Transactions on Mathematics, ISSN / E-ISSN: 1109-2769 / 2224-2880, Volume 18, 2019, Art. #4, pp. 28-36


Copyright Β© 2018 Author(s) retain the copyright of this article. This article is published under the terms of the Creative Commons Attribution License 4.0

Bulletin Board

Currently:

The editorial board is accepting papers.


WSEAS Main Site