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Introduction to Traffic Engineering

Introduction to Traffic Engineering. of roads, streets and highways, their networks and terminals , abutting lands, and relationships with other modes of transportation. 1.1 Definition, scope and goal

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Introduction to Traffic Engineering

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  1. Introduction to Traffic Engineering

  2. of roads, streets and highways, their networks andterminals, abutting lands, and relationships with other modes of transportation 1.1 Definition, scope and goal Definition of Traffic Engineering --- It is the phase of transportation engineering that deals with: • planning • geometric design and • traffic operations

  3. Transportation Engineering is defined as a discipline applying technology and scientific principles to the planning, functional design, operation, and management of facilities for all modes of transportation

  4. Scope of Traffic Engineering --- surface (land) transportation; relationships and connection with other modes of transportation • Major modes of surface transportation --- automobile, bus, truck and bike

  5. Goal of Traffic Engineering --- explore how to provide for the safe, rapid, comfortable, convenient, economical, and environmentally compatible movement of people and goods. • Safe --- public safety • Rapid --- time value and customer service • Comfortable/convenient --- level of service • Economical --- social cost • Environmental --- clean air and sustainability • Movement = mobility

  6. Basic Elements of Highway Traffic Analysis • In order to measure its level of effectiveness, certain parameters associated with the highway must be measured and analysed. These properties include: • The quantity of traffic • The type of vehicles within the traffic stream • The distribution of flow over a period of time (usually 24 hours) • The average speed of the traffic stream • The density of the traffic flow. • Analysis of these parameters will directly influence the scale and layout of the proposed highway, together with the type and quantity of materials used in its construction

  7. Speed, flow and density of a stream of traffic In general terms, q is expressed in vehicles per unit time. where the traffic density, k, is a measure of the number of vehicles, n, occupying a length of roadway, l. Where, q= traffic flow n=no. of vehicle l=a given length of roadway k= density or concentration of traffic

  8. It can be seen that if the expression for q is divided by the expression for k, the expression for u is obtained: thus, the three parameters u, k and q are directly related under stable traffic conditions: • This constitutes the basic relationship between traffic flow, space mean speed and density.

  9. Speed-density relationship • In a situation where only one car is travelling along a stretch of highway, densities (in vehicles per kilo-metre) will by definition be near to zero and the speed at which the car can be driven is determined solely by the geometric design and layout of the road; such a speed is termed free-flow speed as it is in no way hindered by the presence of other vehicles on the highway. As more vehicles use the section of highway, the density of the flow will increase and their speed will decrease from their maximum free-flow value (uf) as they are increasingly more inhibited by the driving manoeuvres of others. If traffic volumes continue to increase, a point is reached where traffic will be brought to a stop, thus speeds will equal zero (u=0), with the density at its maximum point as cars are jammed bumper to bumper (termed jam density, kj)

  10. Greenshields (1934) proposed the simplest representation between the two variables, assuming a linear relationship between the two (see Fig. Below) Thus, the limiting values of the relationship between speed and density are as follows: When k=0,u=uf and, When u =0,k=kj In mathematical terms, this linear relationship gives rise to the following equation: This assumption of linearity allows a direct mathematical linkage to be formed between the speed, flow and density of a stream of traffic.

  11. Flow-density relationship From the equation derived above, we have: • This is a parabolic relationship and is illustrated in the Figure

  12. In order to establish the density at which maximum flow occurs, is differentiated and set equal to zero as follows: the term within the brackets must equal zero, therefore: km, the density at maximum flow, is thus equal to half the jam density, kj. Its location is shown (see the slide above)

  13. Speed-flow relationship • In order to derive this relationship, rearrange the equation to and Combining it with You will get This relationship is again parabolic in nature.

  14. In order to find the speed at maximum flow, is differentiated and put equal to zero: the term within the brackets must equal zero, therefore: • um, the speed at maximum flow, is thus equal to half the free-flow speed, uf. Its location is shown in Fig. (see the above slide)

  15. Combining Equations: the following expression for maximum flow is derived:

  16. Capacity and level of service analyses The no. of vehicles on our highways increases every year ,and transportation engineers are often faced with the challenge of designing modifications to existing facilities that will service the increased demand.

  17. Capacity: is the maximum no. of vehicles that a given highway can accommodate. • LOS: is an operating condition under capacity. Traffic engineers use capacity & LOS analysis to: • Determine the no. and width of lanes needed • Assess service levels and operational characteristics of existing facilities. • Identify traffic and roadway changes needed for new dev’t.

  18. Levels of Service LOS concepts Highway capacity manual defines the LOS categories for freeways and multilane highways as follows: • LOS A • Free-flow operation • LOS B • Reasonably free flow • Ability to maneuver is only slightly restricted • Effects of minor incidents still easily absorbed From Highway Capacity Manual, 2000

  19. Levels of Service • LOS C • Speeds at or near FFS • Freedom to maneuver is noticeably restricted • Queues may form behind any significant blockage. • LOS D • Speeds decline slightly with increasing flows • Density increases more quickly • Freedom to maneuver is more noticeably limited • Minor incidents create queuing From Highway Capacity Manual, 2000

  20. Levels of Service • LOS E • Operation near or at capacity • No usable gaps in the traffic stream • Operations extremely volatile • Any disruption causes queuing • LOS F • Breakdown in flow • Queues form behind breakdown points • Demand > capacity From Highway Capacity Manual, 2000

  21. LOS determination Base condition: * lane width * terrain * lateral clearance * traffic condition stream * access frequency * driver population characteristics Steps: • Measure Free-flow speed from the field-is the mean speed of traffic as measured when flow rates are low to moderate • Analysis flow rate –the highest volume in a 24-hr (the peak-hr volume) is used for V in traffic analysis computation. • Determine LOS

  22. For further knowledge read Highway Engineering by Rogers M. THANK YOU QUESTIONS????

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