Article


 

  AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   14 (2021) 144–149 
 

   

       Contents lists available at http://qu.edu.iq 

 

Al-Qadisiyah Journal for Engineering Sciences 

  
Journal homepage: http://qu.edu.iq/journaleng/index.php/JQES  

  

 

* Corresponding author.  

E-mail address: rod.post05@qu.edu.iq(Zainab A. AL-kareawi ) 

 

https://doi.org/10.30772/qjes.v14i2.766  

2411-7773/© 2021 University of Al-Qadisiyah. All rights reserved.                                This work is licensed under a Creative Commons Attribution 4.0 International License. 

   

Alternatives to enhance traffic conditions at U-turn sites 

Zainab A. AL-kareawia* and Jalal T. Al-Obaedia 

a Road and transportation department, University of AL-Qadisiyah, Iraq. 

bAsst.Prof. ,University of Al-Qadisiyah, College of Engineering, Iraq. 

 

A R T I C L E  I N F O 

Article history:  

Received 18 July 2021 

Received in revised form 26 August 2021 

Accepted 26 August 2021 

 

Keywords: 

Traffic simulation,  

VISSIM,  

U-turn 

 

A B S T R A C T 

Traffic simulation models play a major role in allowing traffic engineers to assess complex traffic situations 

such as U-turn section. Such models help in proposing solutions and proposing alternative scenarios without 

committing too many expensive resources and this models are necessary to implement alternative strategies 

in the field. Simulation traffic models can significantly improve the quality of road network planning and 

design in urban areas.  According to filed observation, the U-turn movement cause traffic congestion at both 

origin and distention (opposite) roads. This study introduced many alternatives to enhance the movement at 

U-turn section. These alternatives have been tested by using simulation models. The PTV VISSIM software 

was used to development the models. This development model has been calibrated and validated by using 

filed data collected from Al-Diwaniyah city, Iraq. The results show from the simulation results are in good 

agreement with the real data. 

© 2021 University of Al-Qadisiyah. All rights reserved. 

    

1. Introduction 

The U-turn movement is defining as the turning movement that is 

implemented at u-shape and it aim to travel to the opposite side. This area 

represents unsafe and cases traffic congestion in both origin and destination 

(opposing) roads [1, 2].  

There are many types of U-turn section. The median U-turn is the most 

common type that allow traffic to make the left turn through the median by 

using special path in the multilane roads. The other types including the U-

turn at intersection, roundabout [3, 4].  

The U-turn movement is more dangerous and having high accident since 

this movement is not control by traffic signals and it is dependent on the 

gap acceptance from drivers[5, 6] . If the gap is not enough to make the U-

turn and turning to the opposite side, the accident accrues due to the conflict 

with the opposite traffic [4]. The turning vehicle should be reducing their 

speed near the U-turn section and stop at the U-turn section if the available 

gap is not enough to make the U-turn movement.  When the gap is enough, 

the vehicle is executing the turning process to the opposite side.  

The geometric layout of U-turn section may have the auxiliary lane (storage 

lane) used to story the traffic that waiting unite the enough gap is providing 

to turn to the opposite direction. The anther used of auxiliary lane as a 

deceleration lane to reduce speed of turning vehicles and not cause 

accidents. Figure 1 show the geometric layout of U-turn section with and 

without auxiliary lane. 

During the past two decades, the U-turn movement used a treatment in 

intersections by replacing the direct left turn by right plus U-turn.  The 

advantage of used this treatment including travel and delay could be less 

when the traffic volume in major street is high or Moderate, the capacity of 

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Zainab A. AL-Kareawi, Jalal T. Al-Obaedi  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   14 (2021) 144–149                                                                                      145 

 

a U-turn movement at the median opening is much higher than the capacity 

of a direct left turn movement, and right turns plus U-turns have fewer 

conflicts than direct left turns [7].  

Traffic simulation models play a major role in allowing traffic engineers to 

assess complex traffic situations. This models help in proposing solutions 

and proposing alternative scenarios without committing too many 

expensive resources that are necessary to implement alternative strategies 

in the field. Simulation traffic models can significantly improve the quality 

of road network planning and design in urban areas[8] 

There are little studies of the alternative to enhance the movement at U-turn 

section. The speed humps are being used in many countries in the world as 

a technique to calm the traffic and make the turning process is easy and 

reduce the accident  [9, 10]. Al-Obeadi (2019) studied the effect of speed 

hump on the (ATS) by the turning vehicles and the results show the used of 

speed hump can reduce the (ATS). AL-Jameel(2014) [11] suggested the 

new design for U-turn section and the result shown this design can increase 

the capacity of U-turn section. Rhaptyalyani H. Della and others (2015)[2], 

study the effect of used new design for U-turn section on the capacity, 

degree of saturation, and queue length and traffic delay. The new model 

including the use of roundabout and the second models used fly over U-

turn. The results showed the used of second models give best perforce and 

reduced the delay and queue length, and increased the capacity. 

The basic objective of the current research is to investigate the effect of 

using different scenarios to improve the movement at the median U-turn 

section by using PTV VISSIM 5.10 microsimulation software. The travel 

time is used to compares between the difference alternatives. These 

scenarios including studying the effect of using traffic control on the 

through, opposing, and merging traffic, the effect of using speed humps in 

the opposing direction, increasing number of lanes and finally applying 

“jack handle” configuration on the U-turn site.  

  

Figure 1:The geometric layout of median U-turn section. 

2. Methodology  

The methodology of this research including the site selection, data collected 

and analyze, model building, calibration and validation for the model 

building and testing different scenarios to enhance the movement at the U-

turn section. 

The site for the U-turn section is selected from Al-Diwaniyah city, Iraq. 

The video recording is used to collect data and the through, opposite, 

merge1, merge2 volumes and average queue length is excavation for data 

collected.  

Traffic simulation is applied using PTV VISSIM development the U-turn 

model. The model has been calibrated and validated based on real traffic 

data as published in the authors previous research work[12] .The developed 

model use to study the effect of applying the alternatives in order to enhance 

traffic conditions at U-turn sites.   

3. Data collection 

In order to achieve the objective of the research, the data should be                    

collected. There are many methods of data collected. According to the 

information required in this study the video recording is the properly 

method to collected data. 

As discussed above, the parameters extracted form the data collected 

including the through volumes “refers to the through traffic volumes in the 

direction of merge 1”, the opposing volume” refers to the traffic volumes 

opposing to traffic volumes at merge 1” while merge 1 “refers to the U-turn 

direction with higher volumes than the another direction merge 2”and the 

average queue length that generate prior the U-turn section. The speed is 

collected by using the radar speed gun. The speed is measurement at the 

three location. The location NO.1 at (100 m before the U-turn section) to 

investigate the behaviour of drivers near the U-turn sections. Location NO.2 

at the U-turn section and the location NO.3 at (100m before U-turn in the 

opposite direction) to investigate the behaviour of drivers near the U-turn 

sections. Table (1) illustration the range of traffic flow and average 

queue length for data collected and the mean for the measure speed. 

Table 1 - The range of traffic flow and average queue length for data 
collected and the mean for the measure speed 

Traffic volumes for each  

direction 

Avg. 

queue 

length 

veh 

Mean speed for each 

location 

Through 

veh/hr  

Opposite 

veh/hr  

Merg1 

veh/hr 

Merg2 

veh/hr  

NO.1 

km/hr 

NO.2 

km/hr 

NO.3 

km/hr 

780-

1080 

672-

1392 

372-

648 

96-

216 

2-5 51.31 27.96 47.53 

4. Model development 

This section describes the model development and the calibration and 

validation process for the development model. The VISSIM models were 

built by adding link (to draw the road) and connecter (to draw the u- turn), 

use “yield priority” to make the turning vehicle wait until enough gap is 

available. The hump speed is select by adding “reduce speed area”. The 

traffic volume for each direction is entered to the networks by using the” 

vehicle input tool” The priorities of movements were applied by 

introducing “conflict area” which give the priority of opposing traffic. After 

the model building, the calibration and validation process are done to 

represent the real data. The results show the development models are 

representing the real. 

5. Models applications 

As described above, the calibrated and validated simulation models using 

PTV VISSIM was used in this research work. Many scenarios have been 

examined including the use of traffic signal, the use of speed humps, 

increase the number of lane and finally applying the “Jack handle” shape 

as shown in Figure 2 below. The travel time is used to examine the effect 

of applying these scenarios for the nearby sections. The travel times is 

defining as the difference in time between the vehicles arriving at the 

beginning of the section and the time the vehicles leaving the same section.  

Figure 2 illustration the location of travel time section.  

 According to traffic volumes in the real situation, the traffic volumes are 

used in these application are similar to the real (1000 veh/hr for the through 

direction), (500 veh/hr for merge1 direction), (1200 veh/hr for opposite 

direction) and (100 veh/hr for the merge2 direction). 

A/ Median U-turn B/U-turn with auxiliary lane 



146 Zainab A. AL-Kareawi, Jalal T. Al-Obaedi  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   14 (2021) 144–149 

 

Figure 2: The location of travel time section 

5.1 The effect of using traffic control  

The traffic control was usually used in intersections if that was warranted 

and the use of such signals at other sites such as (U-turn sites) needs to be 

examined before been applied. Theoretically, the benefit of using traffic 

controls at U-turn section were to increase the safety by avoiding 

conflicting points.  However, the effect of using traffic signals at such sites 

on capacity or travel time should also examined.   

In this work, two signals were examined using traffic simulations, one for 

merging traffic and the second is for opposing traffic as shown in  Figure 

3. Figure 3: The traffic signal location. 

Different green times with 60 second cycle length have been examined as 

shown in Table 2 below. Figure (4) show the travel time for sec.1, sec.2, 

sec.3, sec.4, and sec.5 for all case of traffic signal. For sec.1 (before traffic 

signal in through direction) when the green time is high, the travel time is 

reducing. The travel time begin increase when the green time is decrease. 

For sec.3 (before traffic signal in opposite direction), the travel time for all 

cases (a, b, c, d) is higher than the normal case since the red time is higher 

than the green time. For sec.5, the travel time for all cases (a, b, c, d) is 

lower than the normal cases. For sec.2 and sec.4, the travel time is no effect 

when using the traffic signal.  

Table 2 - Traffic control times. 

 

Figure 4: The travel times with used of traffic control. 

5.2 The effect of using speed humps  

Speed humps is one of the most traffic calming that produce significant 

reduction for speeds of traffic.  In this study, the speed hump is placed in 

opposite direction to reduce the speed of vehicles that conflict with the 

turning vehicles to ease the turning process.  Such speed humps are usually 

located upstream of the U-turn sites as show in Figure (5). 

 

 

 

 

Figure 5: The speed humps location. 

Different speeds for opposing traffic have been tested to simulate the effect 

of humps on opposing traffic speeds and to examine the effect of that on 

merging traffic.  Table (4) shows the speed of vehicles at hump. Figure (6) 

  Traffic control data 

Case  Cycle 

length (s) 

For through traffic  For opposite traffic 

Green 

time(s) 

Red 

time (s) 

Green 

time (s) 

Red 

time (s) 

Case a 60 50 10 10 50 

Case b 60 45 15 15 45 

Case c 60 40 20 20 40 

Case d 60 35 25 25 35 

0

5

10

15

20

normal
case

case a caseb case c case d

T
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Traffic signal time (sec)

Sec.2

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50

100

150

200

250

normal case case a caseb case c case d

T
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Traffic signal time (sec)

Sec.3

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20

normal case case a caseb case c case d

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ti
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Traffic signal time (sec)

Sec.4

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normal case case a caseb case c case d

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normal case case a caseb case c case d

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Traffic signal time (sec)

Sec.1



Zainab A. AL-Kareawi, Jalal T. Al-Obaedi  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   14 (2021) 144–149                                                                                      147 

 

shows the travel time results for sec.1, sec.2, sec.3, sec.4, and sec.5 for all 

case of speed hump. 

The used of the speed humps can significantly effect to reduce the travel 

time for the turning vehicles and make the U-turn process is easy. For sec.1, 

the use of speed hump decreases the travel time and when the speed of 

vehicles at the hump increase the travel time also increase. For sec.3, the 

used of speed hump at the opposite direction increase the travel time since 

the speed in the section is lower due to the use of hump and when the speed 

of vehicles at hump increase the travel time is decrease. 

 For sec.5, when the speed of vehicles in humps increase the travel time 

also increase since the speed in main street (opposing direction) is increase 

and the turning vehicles should be waiting unite the enough gap is 

providing. For sec.2 and sec.4, the travel time is not effect when using the 

speed hump.  

Table 3 - The speed of traffic at humps 

 

 

 

 

 

 

 

 

Figure 6: The effect of speed hump on the travel time. 

5.3 The effect of increasing number of lanes 

In Al-Diwaniyah, most of multilane roads having three lanes for each 

direction but however, one of these lanes is usually utilized as on line 

parking. This section examines the effect of increasing the no. of lanes of 

the travel time of the through, opposing, merging directions by preventing 

such on line parking. Figure (7) shown the travel time for sec.1, sec.2, sec.3, 

sec.4, and sec.5 for using two lanes and three lanes. The results show that 
the increase the number of lanes have significantly reduced the travel time 

in (sec.1, 5) because the capacity of two lanes is lower than the capacity of 

the three lanes and (sec.2,3,4) are not effect. From that, it should be 

recommended to prevent vehicles to stop near the U-turn section for the 

purpose of reducing congestion and facilitating the turning process. 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Case NO. The speed of vehicles at hump 

Normal case 50 (km/hr) 

Case a 5 (km/hr) 

Case b 12 (km/hr) 

Case c 20 (km/hr)  

Case d 30 (km/hr) 

0

10

20

30

40

5 km/h 12 km/h 20 km/hr 30km/hr 50km/hr

T
r
a

v
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ti
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 (

se
c
)

Speed at ahump (km/hr)

Sec.1

0

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10

15

20

5 km/h 12 km/h 20 km/hr 30km/hr 50km/hr

T
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v
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Speed at ahump (km/hr)

Sec.2

0

50

100

150

200

5 km/h 12 km/h 20 km/hr 30km/hr 50km/hr

T
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ti
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Speed at ahump (km/hr)

Sec.3

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20

5 km/h 12 km/h 20 km/hr 30km/hr 50km/hr

T
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a

v
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ti
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Speed at ahump (km/hr)

Sec.4

0

10

20

30

40

Two- lanes Three-lanes

T
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Number of lanes per direction

Sec.1

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Two- lanes Three-lanes

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Number of lanes per direction

Sec.2

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Sec.3

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Number of lanes per direction

Sec.4

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60

70

5 km/h 12 km/h 20 km/hr 30km/hr 50km/hr

T
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c)

Speed at ahump (km/hr)

Sec.5



148 Zainab A. AL-Kareawi, Jalal T. Al-Obaedi  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   14 (2021) 144–149 

 

 

 

 

 

 

Figure 7: The effect of increase NO. of lanes of the travel time. 

5.4 The effect of using jack handles 

The geometric design of jack handle is required a spacious place on the side 

of the road near the U-Turn section.  No lane uses nearby the site selection. 

The jack handle treatment cannot use in crowded cities with urban buildings 

on the sides of road.  It might be effective on external roads that contain 

empty spaces on the sides of the road. Figure (2) shows the U-turn model 

with jack handle. Figure (8) shown the result of using jack handle.  

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 8: The effect of using jack handle on the travel time. 

In this study, the gap is take (2.5 sec.).This  gap take from the calibration 

and validation processes . 

For sec.1 (before jack handle in through direction), the used of jack handle 

increase the travel time for this section as compared to the normal section. 

For sec.5 (turning direction), the travel time for normal section is lower than 

the travel time when using jack handle because the turning vehicles in jack 

handle should wait unit the enough gap is providing in the through and 

opposite direction. On the other hand, the turning vehicles in normal case 

wait unite the enough gap is providing in opposite direction only. For sec.2, 

sec.3, and sec.4, the travel time is not effect when using the jack handle 

treatment. Finally, the used of jack handle is not effective to enhance the 

movement at the U-turn section. 

5.5 The effect of using special lanes for turning vehicles 

The used of special lane (see Figure 2) for the turning vehicles is an 

effective way to increase the capacity of U-turn section as well as making 

the U-turn movement safer as a result of eliminating conflict points during 

the turning process. This section examines the effect of allocating of a 

special U-turn path through both directions.  Figure (9) shows the results of 

the effect of using special lane for turning vehicles on the travel time. 

The use of special lane for the turning vehicles has a significant effect to 

reduce the travel time for the turning vehicles. For sec.3,4, the travel time 

is not effect. For sec.5, the travel time is reducing when using the special 

lane for turning vehicles since the turning vehicles are not effect by the 

opposite volume and turn directly without waited to provide the enough 

gap. As well as, the (500 veh/hr) is the input turning volumes and the output 

volumes after the run is (400 veh/hr) in normal case and (528 veh /hr) in 

used of special lane for turning veh case. This result lead to the capacity of 

U-turn also increase. 

 

 

 

 

 

 

 

 

 

 

 

 

0

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40

50

60

70

Two- lanes Three-lanes

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Number of lanes per direction

Sec.5

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normal case jack handle case

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sec.1 

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Zainab A. AL-Kareawi, Jalal T. Al-Obaedi  /AL-QADISIYAH JOURNAL FOR ENGINEERING SCIENCES   14 (2021) 144–149                                                                                      149 

 

 

 

 

 

 

 

Figure 9: The effect of using special lane for turning vehicle on the 

travel time. 

6. Conclusions  

This paper used VISSIM microsimulation software to development model 

for the U-turn section and test different scenarios to enhance the movement 

at U-turn section. The video recording was used to collect data for Al-

Diwaniyah city, Iraq. The calibration and validation process were done for 

model development to represent the real data. After this stage, the models 

used to test different alternatives and the result shown the ability of use 

VISSIM software to model the complicated section such as U-turn section.  

The following conclusions could be highlighted. 

• The use of traffic signal at U-turn section may enhance traffic 

conditions at U-turn sites if appropriate signal timings is used.    

• The use of speed hump in the opposite direction causes the 

reduction of travel time for the turning vehicles since the driver 

at the speed hump should reduce their speed. In addition, when 

the speed of the vehicles at a hump is increased, the average 

travel time for turning is increase but the average travel time for 

opposing traffic also decrease.  

• The increase the number of lanes have significantly reduced the 

travel time in turning vehicles. Therefore, it should be 

recommended to prevent vehicles to stop near the U-turn section 

for the purpose of reducing congestion and facilitating the 

turning process. 

• The use of Jack handle layout has increased the travel time for 

sections and therefore, such layout has not recommended based 

on this study results.  

• The used of special lane for the turning vehicles has 

significantly reduced the travel time for the turning vehicles.  

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0

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vehicles case

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Sec.5