Newell's Car-following Model
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In traffic flow theory, Newell’s car-following model is a method used to determine how vehicles follow one another on a roadway. The main idea of this model is that a vehicle will maintain a minimum space and time gap between it and the vehicle that precedes it. Thus, under congested conditions, if the leading car changes its speed, the following vehicle will also change speed at a point in time-space along the
traffic wave Traffic waves, also called stop waves, ghost jams, traffic snakes or traffic shocks, are traveling disturbances in the distribution of cars on a highway. Traffic waves travel backwards relative to the cars themselves. Relative to a fixed spot on t ...
speed, ''-w''.Newell G.F. (2002) A simplified car-following theory: a lower order model. Institute of Transportation Studies, University of California, Berkeley.


Overview

Assuming the
fundamental diagram The fundamental diagram of traffic flow is a diagram that gives a relation between road traffic flux (vehicles/hour) and the traffic density (vehicles/km). A macroscopic traffic model involving traffic flux, traffic density and velocity forms the ...
(flow-density) is a triangular function, a traffic state ''A'' with speed ''vA'' and density ''kA'' can be assumed in the congestion region. The density on the roadway can be determined using the spacing between vehicles and is computed simply the equation: ''kA = 1/sA'' Geometric relations from the
fundamental diagram The fundamental diagram of traffic flow is a diagram that gives a relation between road traffic flux (vehicles/hour) and the traffic density (vehicles/km). A macroscopic traffic model involving traffic flux, traffic density and velocity forms the ...
can be used to calculate the density as well, given by the equation: ''kA ='' (''kj w'')/(''vA+w'') In the time-space diagram, the trajectories of the leading (top) and following (bottom) vehicle are separated by the distance ''δ'' and time ''τ''. The spacing between vehicles at traffic state A can be found using a geometric relationship found in the time-space diagram: ''sA = vA''(''τ'')''+δ'' Using relationships between the previous equations, variables ''τ'' and ''δ'' can be solved for: ''τ = 1''/(''wkj'') ''δ'' = ''1''/''kj'' Thus, ''τ'' and ''δ'' are constants defined by the wave speed and jam density, independent of the speed of the leading vehicle and the traffic state. The path of vehicle ''i'', a function of time, can be determined using the equation: ''xi''(''t'')'' = ''min(''xAF''(''t''),'' xAC''(''t'')) Position of vehicle ''i'' under free-flow conditions: ''xiF''(''t'')'' = xi''(''t-τ'') +'' v''f * τ Position of vehicle ''i'' under congested conditions: ''xiC''(''t'')'' = xi-1''(''t-τ'')'' - δ''


Driver aggressiveness

Under real-world conditions, a hypothetical following driver may drive improperly, resulting in deviations from the time-space trajectories proposed under Newell’s model. Time-space trajectories from data collected on roads and highways can be compared to its respective Newell’s car-following model trajectory to determine whether a driver is cautious or aggressive. The following figures show the trajectories of two vehicles (black) and the trajectory predicted by Newell’s car-following Model for the following vehicle (blue). Time-space trajectory for a normal driver: Time-space trajectory for a cautious driver: Time-space trajectory for an aggressive driver: When the following driver reacts early when decelerating or reacts late when accelerating, the time and distance gap between the leader and the follower increases. The follower can be described as a cautious driver. In the other situation, the follower reacts later when decelerating or earlier when accelerating decreasing the time and distance gap between the leader and follower. The follower can be described as an aggressive driver.


See also

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Annual average daily traffic Annual average daily traffic, abbreviated AADT, is a measure used primarily in transportation planning, transportation engineering and retail location selection. Traditionally, it is the total volume of vehicle traffic of a highway or road for a y ...
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Gipps' model Gipps' model is a mathematical model for describing car-following behaviour by motorists in the United Kingdom. The model is named after Peter G. Gipps who developed it in the late-1970s under S.R.C. grants at the Transport Operations Research Gr ...
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Intelligent driver model In traffic flow modeling, the intelligent driver model (IDM) is a time-continuous car-following model for the simulation of freeway and urban traffic. It was developed by Treiber, Hennecke and Helbing in 2000 to improve upon results provided wit ...
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Traffic simulation Traffic simulation or the simulation of transportation systems is the computer simulation, mathematical modeling of transportation systems (e.g., freeway junctions, arterial routes, roundabouts, downtown grid systems, etc.) through the application o ...


References

Road traffic management