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There exists a need for traffic flow modeling in developing countries on account of the growth in personalized traffic. Traffic problems on highways and in urban areas attract considerable attention. Many scientists have tried to develop various Mathematical models.Cellular Automata (CA) approach has recently gained a lot of interest in traffic flow modeling due to its simplicity and computational efficiency. The model developed in the paper is based on Nagal and Schreckenberg (NaSch) model. We proposed a new stochastic one dimensional CA model for single lane with modified cell size and variable acceleration rate. Slow to start rule and anticipation rule has been introduced by extending NaSch model in Lagrange‟s form. The new extended CA model for traffic flow appear to have metastable branches near the critical density from steady state flow to jamming flow due to the presence of anticipation parameter and slow to start effect. Simulation results with fundamental diagrams for various values of p (braking probability), q (slow to start probability) and r (anticipation probability) show the ability of this modeling paradigm to capture the most important features of the traffic flow phenomena.

Traffic Flow Modeling, Cellular Automata, NaSch Model, Rule 184, Lagrange‟s Form, Stochastic CA, Heterogeneous Traffic, Slow to Start Rule and Anticipation Rule.

Arasan, V. T. and Koshy, R. Z. 2005. Methodology for Modeling Highly Heterogeneous Traffic Flow, Journal of Transportation Engineering, ASCE 131 (7):544-551.

Barlovic R, Santen L, Schadschneider A, and Schrekenberg M (1998). Metastable States in Cellular Automata for traffic flow. European Physical Journal B, 5(3), pp. 793-800.

Benjamin S, Jhonson N, and Hui P (1996). Cellular Automata models of traffic flow along a highway containing junction. Journal of Physics A: Mathematical and General, 29(12), pp.3119-3127.

Chowdhery D, Santen, and Schadschneider A (2000). Statistical Physics of vehicular traffic and some related systems. Physics Report, 329(4-6), pp. 199-329.

Helbing D, Herman HJ, Schrekenberg M, and Wolfe DE (2000). Traffic and Granular Flow. Berlin: Springer.

Krauss S, Wagner P, and Gawron C (2000). Metastable States in a microscopic model of traffic flow. Physics Report E, 55 (5), pp. 5597-5602.

Larrga,M.,del Rao. J.A, (2002) Two effective temperatures in traffic flow models: analogies with granular flow Physica A 307, 527-547.

Li-Yun D, Yu X, and Shi-Qiang D (2001) .One dimensional Cellular Automata Model for traffic flow based on car following idea. Journal of Applied Mathematics and Mechanics, 23 (4), pp. 363- 370.

Mallikarjuna C and Rao K (2007). Identification of a suitable Cellular Automata model for mixed traffic. Journal of Eastern Asia Society for Transportation Studies, 7, pp. 2454 - 2468.

Matsukidaira J and Nishinari K (2003). Euler-Lagrange correspondence of Cellular Automata for traffic flow model. Physical Review Letters, 90 (8), pp. 088701-1-4.

Nagel K and Schrekenberg M (1992). A Cellular Automata for freeway traffic.Journal of Physics I France, 2, pp. 2221-2229.

Nagal, K (1996) Particle hopping models and traffic flow theory, Physical Review E 3, 4655-4672.

Nishinari K (2001). A Lagrange representation of Cellular Automaton traffic flow models. Journal of Physics A: Mathematical and General, 34(48), pp. 10727-10736.

Nishinari K, Fukui M, and Schadschneider A (2004). A stochastic Cellular Automata model for traffic flow with multiple metastable states. Journal of Physics A: Mathematical and General, 37 (9), pp. 3101-3110.

Sakai S, Nishinari K, and Iida S (2006). A new stochastic Cellular Automata model and its jamming phase transition.Journal of Physics A: Mathematical and General, 16(4), pp.15327-15339.

Schadschneider A and Schrekenberg M (1997). Traffic flow models with slow to start rules.Journal of Annalen der Physik, 509(7), pp. 541-551.

Simon, P. M. and Nagel, K. 1998. Simplified cellular automaton model for city traffic, Physical Review E 58(2): 1286-1295.

Spyropoula I (2007) .Modeling a signal controlled traffic stream using Cellular Automata. Transportation Research Part C, 15(3), pp. 175-190.

Wolfram S (1986). Theory and application of Cellular Automata. World Scientific Singapore.