A traffic bottleneck is a localized disruption of vehicular traffic on a street, road, or highway. As opposed to a

traffic jam Traffic congestion is a condition in transport that is characterized by slower speeds, longer trip times, and increased vehicular queueing. Traffic congestion on urban road networks has increased substantially since the 1950s. When traffic de ...

, a bottleneck is a result of a specific physical condition, often the design of the road, badly timed

traffic light Traffic lights, traffic signals, or stoplights – known also as robots in South Africa are signalling devices positioned at road intersections, pedestrian crossings, and other locations in order to control flows of traffic. Traffic light ...

s, or sharp curves. They can also be caused by temporary situations, such as vehicular accidents. Bottlenecks can also occur in other methods of transportation. Capacity bottlenecks are the most vulnerable points in a network and are very often the subject of offensive or defensive military actions. Capacity bottlenecks of strategic importance - such as the

Panama Canal The Panama Canal ( es, Canal de Panamá, link=no) is an artificial waterway in Panama that connects the Atlantic Ocean with the Pacific Ocean and divides North and South America. The canal cuts across the Isthmus of Panama and is a condui ...

where traffic is limited by the infrastructure - are normally referred to as

choke point In military strategy, a choke point (or chokepoint) is a geographical feature on land such as a valley, defile or bridge, or maritime passage through a critical waterway such as a strait, which an armed force is forced to pass through in order ...

s; capacity bottlenecks of tactical value are referred to as mobility corridors.

Causes

Traffic bottlenecks are caused by a wide variety of things: * Construction zones where one or more existing lanes become unavailable (as depicted in the diagram on the right) * Accident sites that temporarily close lanes * Narrowing a low-capacity highway road * Terrain (e.g., uphill sections, very sharp curves) * Poorly timed

s * Slow vehicles that disrupt upstream traffic flow upstream (also known as a " moving bottleneck") *

Rubbernecking Rubbernecking is a derogatory term primarily used to refer to bystanders staring at accidents. More generally, it can refer to anyone staring at something of everyday interest compulsively (especially tourists). The term ''rubbernecking'' derive ...

Rubbernecking is an example of how bottlenecks can be induced by psychological factors; for example, vehicles safely pulled to the

shoulder The human shoulder is made up of three bones: the clavicle (collarbone), the scapula (shoulder blade), and the humerus (upper arm bone) as well as associated muscles, ligaments and tendons. The articulations between the bones of the shoulder mak ...

by a police car often result in passing drivers to slow down to "get a better look" at the situation.

Graphical and theoretical representation

Traffic flow In mathematics and transportation engineering, traffic flow is the study of interactions between travellers (including pedestrians, cyclists, drivers, and their vehicles) and infrastructure (including highways, signage, and traffic control dev ...

theory can be used to model and represent bottlenecks.

Stationary bottleneck

Consider a stretch of highway with two lanes in one direction. Suppose that 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 ...

is modeled as shown here. The highway has a peak capacity of Q vehicles per hour, corresponding to a density of ''k_c'' vehicles per mile. The highway normally becomes jammed at ''k_j'' vehicles per mile. Before capacity is reached, traffic may flow at ''A'' vehicles per hour, or a higher ''B'' vehicles per hour. In either case, the speed of vehicles is ''v_f'' (or "free flow"), because the roadway is under capacity. Now, suppose that at a certain location ''x₀'', the highway narrows to one lane. The maximum capacity is now limited to ''D''’, or half of ''Q'', since only one lane of the two is available. State ''D'' shares the same flow rate as state ''D, but its vehicular density is higher. Using a time-space diagram, we may model the bottleneck event. Suppose that at time ''t₀'', traffic begins to flow at rate ''B'' and speed ''v_f''. After time ''t₁'', vehicles arrive at the lighter flowrate ''A''. Before the first vehicles reach location ''x₀'', the traffic flow is unimpeded. However, downstream of ''x₀'', the roadway narrows, reducing the capacity by half—and to below that of state ''B''. Due to this, vehicles will begin queuing upstream of ''x₀''. This is represented by high-density state ''D''. The vehicle speed in this state is the slower ''v_d'', as taken from the fundamental diagram. Downstream of the bottleneck, vehicles transition to state ''D, where they again travel at free-flow speed ''v_f''. Once vehicles arrive at rate ''A'' starting at time ''t₁'', the queue will begin to clear and eventually dissipate. State ''A'' has a flowrate below the one-lane capacity of states ''D'' and ''D. On the time-space diagram, a sample vehicle trajectory is represented with a dotted arrow line. The diagram can readily represent vehicular delay and queue length. It's a simple matter of taking horizontal and vertical measurements within the region of state ''D''.

Dynamic bottleneck

For this example, consider three lanes of traffic in one direction. Assume that a truck starts traveling at speed ''v'', more slowly than at the free-flow speed ''v_f''. As shown on the

below, speed ''q_u'' represents the reduced capacity (two-thirds of ''Q'', i.e., 2 out of 3 lanes available) around the truck. State ''A'' represents normal approaching traffic flow, again at speed ''v_f''. State ''U'', with flowrate ''q_u'', corresponds to the queuing upstream of the truck. On the fundamental diagram, vehicle speed ''v_u'' is slower than speed ''v_f''. But once drivers have navigated around the truck, they can again speed up and transition to downstream state ''D''. While this state travels at free flow, the vehicle density is less because fewer vehicles get around the bottleneck. Suppose that, at time ''t'', the truck slows from the free-flow rate to ''v''. A queue builds behind the truck, represented by state ''U''. Within the region of state ''U'', vehicles more slowly, as indicated by the sample trajectory. Because state ''U'' limits to a smaller flow than state ''A'', the queue will back up behind the truck and eventually crowd out the entire highway (slope ''s'' is negative). If state ''U'' had the higher flow, there would still be a growing queue. However, it would not back up because the slope ''s'' would be positive.Daganzo, Robert, ed. (1997). ''Fundamentals of Transportation and Transportation Operations''. Pergamon-Elsevier, Oxford, UK

References

{{DEFAULTSORT:Traffic Bottleneck Road transport Road traffic management

Causes

Graphical and theoretical representation

Stationary bottleneck

Dynamic bottleneck

See also

References