A new conceptual algorithm for adaptive route changing in urban environments

IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
__________________________________________________________________________________________
Volume: 02 Issue: 10 | Oct-2013, Available @ http://www.ijret.org 557
A NEW CONCEPTUAL ALGORITHM FOR ADAPTIVE ROUTE
CHANGING IN URBAN ENVIRONMENTS
Prasanna Puttaswamy1
, Pramod Srivatsa Krishna Murthy2
, Bindu Anil Thomas3
1, 2
Prospective Research Scholar, Mysore, Karnataka State, India, prasanna.p06@gmail.com, prmdsrivatsa@gmail.com
3
HOD, E&C Dept., VidyaVikas Institute of Engineering and Technology, Mysore, India, binduvviet@gmail.com
Abstract
In this paper an attempt is shown in a Mathematical Model of an alternating route adapting for large scale, which was previously
done in small scale. This evaluation is done considering 75 and above traffic junctions with a scale of 4 to 6 vehicular density per
second in each junction. The main objective of this paper is to show how an Adaptive Route Changing [ARC] application responds to
assumed scenario & also proposing effective software architecture to monitor traffic in all the junctions at real time to minimise
traffic congestion.
Keywords : ARC, Intelligent transport system, Traffic Monitoring.
------------------------------------------------------------------------***--------------------------------------------------------------------
1. INTRODUCTION
ITS is one of the most research happening fields in the modern
automobile industry. Its variety of challenges includes
avoiding traffic congestions, increasing fuel efficiency of the
vehicles and so on. A still more sophisticated systems with
profound algorithmic ideas on improving the present ITS is
needed as the traffic congestions being the most haunted
problems of urban hubs at present. Previously done works on
ITS addresses several problems such as GLOSA [1] which
intimates the vehicles to accelerate or decelerate so as to avoid
waiting at traffic signal at intersections. The extension to this
paper is Adaptive Routing technology which is done on a
small scale on 2*2 grid of road addressing an algorithm that
advises the drivers to change path as to avoid traffic
congestion on route. Yet another kind of paper „an adaptive
routing algorithm for two tier traffic information system‟
which mainly focuses on an algorithm that broadcasts
messages between vehicles also addresses on ITS. However,
the main objective of this paper is to develop an algorithm to
effectively manipulate the traffic density for higher number of
traffic junction (75+ assumed) connected to a base station
using V2I communication & vice versa is proposed in this
paper. The block diagram of the proposed system is shown in
Fig.1.
Fig-1 Block Diagram of proposed system
The rest of this paper organised as follows section2. Related
Work: Explains in brief of different papers previously
published on ITS along with their cons. Section3. Algorithm:
Explains in detail, how the proposed system operates along
with some assumption made also some mathematical
Equation, Graphs needed in support. Section4. Performance
Evaluation: Explains how evaluation can be conducted with
scenario considerations. Section5. Conclusion and Future
Work: This section explains predicted results and also Future
work that can be extended.
BAS
E
STA
TIO
N
(SER
VER)
ROA
D
SIDE
UNIT
(RSU
)
TRA
FFIC
SIGN
AL
VEH
ICLE
NOD
E

__________________________________________________________________________________________
2. RELATED WORKS
Several works suggesting various algorithms to reduce traffic
congestions have been previously made. Such as, the one from
TU Berlin [2] which uses GPS to acquire digital maps & live
traffic data in real time further used for optimal route guiding
system. The results obtained from the simulation of this
system showed a decrease in the overall trip time & also
predicts a decrease in these benefits as equipped vehicle
penetration increases. This is because the system does not
include the effect of their recommendation to the
measurements causing furthermore congestion. This system
also alerts minority of driver to take longer routes, making
way for majority of driver‟s to shorter routes, which makes
this system being avoided by certain driver‟s who are
instructed to longer routes. In contrast with the said system,
PRE-DRIVE C2X project [3] proposes a new algorithm in
which each vehicle has ability to exchange data between each
other regarding traffic conditions around them. This helps
other vehicles to decide whether to alter its pre fixed route,
thus provides an advantage of knowing nearby traffic
congestions. Simulation results of this systems shows benefits
of vehicle 2 vehicle (V2V) application penetration applicable
even to non V2V equipped vehicles.
The implemented research on GLOSA [1] from Surrey
University, suggests an algorithm that effectively impacts on
fuel & traffic efficiency through a constant communication
between the vehicle & the road side unit [1] to know for the
present traffic light status. This information is further used to
calculate the speed & time required to cross the traffic signal
without being stuck on red at individual junction either by
accelerating or decelerating. The fuel efficiency reduces as the
traffic density decreases. On the other hand traffic density
effects inversely to traffic efficiency. GLOSA also assumes
that No vehicle waiting at traffic light which is not always the
case [1]. The further extension to the said paper (GLOSA) in
ARC [4] addresses & effectively increases fuel efficiency also
decreasing the average trip time considering only a small
segment of 2-by-2 grid area with traffic signals which has a
control of 4 intersections of bidirectional roads as scenario. In
the ARC algorithm method the efficiency is increased by
alerting the drivers to alter their path at the time of congestion,
thus reducing the average trip time. This algorithm alerts the
drivers to take shorter routes thus overcoming the limitations
in the project done by TU of Berlin. The con as of the referred
paper includes its scalability issue as it is considered only for a
shorter grid with traffic flow in one direction. In the present
proposed paper these said cons are addressed with
improvements.
3. ALGORITHM
Following assumptions are made for the present scenario:
more than 75 Intersections with 4 roads intersecting & having
two lanes for each direction with each intersection have a
Road Side Unit (RSU) & considering a threshold limit of 4-6
vehicles per second per junction as vehicular density.
To implement effective routing Algorithm three independent
applications are proposed, namely:
Vehicle node: This forms the least form of a node that updates
its id, acceleration, and location to nearest junction to which it
is approaching to the RSU. Vehicle node also receives the
information from RSU in order to alert drivers about the traffic
scenario on way to their destination. The CGGC [5] protocol
is used for the communication between Vehicle Node & RSU.
It receives the message from RSU to adapt a new route during
congestions.
Road Side Unit: it is the actual nodes present at traffic
junctions which collects all the information‟s that are required
to be updated to the base station like individual id‟s, traffic
density in their vicinity, id‟s of all roads that meets at its point.
These units play important role, once the base station detects
any congestion & informs individual RCU‟s around the
congested junction to reduce traffic flow through congested
one. It is possible because each junction knows the exact
vehicle counts in each road intersecting. Thus with the
command from base station previous RSU changes waiting
time & passing time of the vehicular traffic according to data
from the Base station, thus avoiding further block out.
One more advantage of such RSU is that its capability to alter
the signal lights according to the priority basis during
congestions. This is done as follows, when the queue length of
vehicles at any road at any individual intersection reaches
threshold limit, then the corresponding RSU responds to this
by sparing extra time with green signal to that road taken from
those roads with minimum queue limit, providing high priority
to the longer queue length roads. Additional time provided for
congested road can be calculated as
Addition time for congested road is given by
𝑇𝑎 − 𝑇𝑟𝑞𝑎 + 𝑇𝑏 − 𝑇𝑟𝑞𝑏 + [𝑇𝑐 − 𝑇𝑟𝑞𝑐]
Where,
Ta = Time allocated for green light for Road A
Trqa = Time required to clear the queue length at road A
Assuming 1 mtr traffic clears in 1 sec (Qm)
Then the threshold queue length can be calculated using the
expression 2
Qth = 1.5 ∗ 𝑇𝑔𝑙 ∗ 𝑄𝑚
Where Tgl = Green Light Time

__________________________________________________________________________________________
Queue length 
𝐷𝑖−𝐷𝑜
𝐿
Where, Di = Distance of its own Location
Do = First stooped vehicle at the traffic light
L = length of vehicle (Usually L remains constant) [4]
Here the aspect queue length varies in a wide range, as the
considered scenario is for city limits, this queue length which
forms an important constrain deciding the traffic light
ON/OFF period is in direct correlation with traffic density.
Traffic density is nothing but number of vehicles occupying a
given length of a lane, usually measured in vehicles per
kilometre per lane [8].
𝐷 = 𝑣/𝑠
Where, D is density,
V is rate of flow in vehicles per hour (vph),
S is space mean speed (kmph) considered as 40 kmph as
present scenario is for city.
In urban areas, traffic density varies according to the time i.e.
the traffic density at mornings will not be same as traffic at
noon, so green light time has to be changed according to the
traffic density. If the traffic signal (Green) is kept constant for
various traffic density flows, traffic congestion are frequently
observed i.e. say Green light period is set to 10 seconds at the
peak traffic hour, then traffic congestion is a more obvious.
Conversely if the green light period is more at early morning
(off peak time) then drivers must wait longer time even with
lesser traffic density. RSU’s will change the Green light time
according to the traffic‟s peak & off peak at real time. The
graph in the fig 2 shows the Traffic density v/s Time in
general.
Fig-2 Graph of Traffic density v/s Time
Base station: It is the tool to store information‟s from the
RSU & passes the same to the latter if required. The
communication established is a 2-way between base station &
RSU.
RSU to Base station communication: The entire RSU‟s
updates all the information obtained at its nodes to the base
station, such information includes road id, junction id, traffic
density & average vehicle entry at real time at a rate of 5 to 10
seconds on average.
Base station to RSU: this communication is only established
when a traffic congestion is observed. During traffic
congestion at any junction the following tasks are
accomplished by the base station in order to reduce it.
 Updates junction id where traffic congestion has
occurred to other junctions as to avoid further vehicle
flows to congested junction.
 Passes all required information‟s to congestion occurred
junction to reduce the traffic flow into it without
affecting other junction causing further congestion
down the line.
4. PERFORMANCE EVALUATION
The performance evaluation can either be done by simulation
or by actual hardware implementation. Due to high installation
cost it is recommended to go with simulation approach. In the
referred papers following tools are used: Fraunhofer VSimRTI
[6] to model vehicle traffic, data communication between
vehicles & signal lights. SUMO [7] tool is used for wireless
network & to connect all the RSU a virtual Base station is
maintained.
It is strictly recommended to consider the following scenario‟s
at the time of simulation:
Scenario 1:
Considering an intersection with id #1 & with four roads
connecting, named as 1a,1b,1c and 1d. Assuming 1a has the
more traffic flow than other lanes. Traffic flow from the cross
road to 1a is 1:3 to the main road traffic flow rate.
Scenario 2:
Since we are assuming the 75 Junction consider the scenario 1
for more than 4 Junction at once in different location. This
scenario results show‟s system scalability.
Scenario 3:
In this case consider the full traffic congestion in a complete
road. i.e. all the junction in that road are completely congested.
0
10
20
30
40
50
60
70
0 10 20 30
Density

__________________________________________________________________________________________
5. EXPECTED CONCLUSION & FUTURE WORK:
In this paper a concept on algorithm for adaptive route
changing is effectively proposed along with large scale
scenario. Based on several referred papers efficient ways to
evaluate the performance of the proposed system is also
highlighted. Through a general view over this paper & a broad
search it can be revealed that this system can be opted for a
highly congested urban metropolis. Although a near to said
system has been suggested & implemented through
simulations, a systems with a separate Base Station (Server) to
maintain all the regarding data‟s with more precise operative
environment has never been proposed on such large scale. On
contrast to referred papers & their results, one can expect
much better result once the simulation is done for the proposed
concept.
The proposed algorithm can be simulated considering the
assumptions made, furthermore, improvements in gathering
the exact vehicular counts & all the other required data‟s with
more precision should be researched for betterment of the
present system.
REFERENCES
[1]. K Katasaros, R. Kernchen, M. Dianati, and D. Rieck,
“Performance study of a Green Light Optimized Speed
Advisory (GLOSA) application using an integrated
cooperative ITS simulation platform,” in International
Wireless Communication and Mobile Computing Conference,
2011, pp. 918-923.
[2]. “Research projects of TU Berlin on Traffic Control,”
Online, http://www4.math.tu-
berlin.de/coga/projects/traffic/routeguidance//,
[3]. PRE-DRIVE C2X Deliverable D2.3, “Description of
Communication, Traffic and Environment Models and their
Integration and Validation,” Tech. Rep., 2010
[4]. K Katasaros, R. Kernchen, M. Dianati, and D. Rieck,
“Performance Evaluation of an Adaptive Route Change
Application Using an Integrated Cooperative ITS Simulation
Platform” in International Wireless Communication and
Mobile Computing Conference, 2012, pp 377-382, (accessed
10/4/2013)
[5]. C. Maihofer, R. Eberhardt, and E. Schoch, “CGGC:
Cached Greedy Geocast,” in Wired/wireless Internet
Communication, 2004, pp.
[6]. T. Quech, B. Schunemann, I. Radusch, and C. Meinel,
“Realistic Simulation of V2X Communication Scenarios,” in
IEEE Asia-Pacific Services Computing Conference, 2008,
1623 -1627
[7]. D. Krajzewicz, G. Hertkorn, C. Rossel, and P . Wagner,
“SUMO (simulation of urban mobilty ) an open-source traffic
simulation,” in Middle East Symposium on Simulation and
Modelling, 2002, pp 183-187.
[8]. Anon “Volume, Density & Speed Studies and
Characteristic” Online,
http://211.71.86.13/web/jp/09sb/jtgcdl/PDF2/chapter%203.pdf
, (accessed 25/04/2013).
[9]. Anon “Traffic Flow” Online,
http://en.wikipedia.org/wiki/Traffic_flow, (accessed
27/042013).
ACKNOWLEDGEMENTS
We take this opportunity to express our profound gratitude and
deep regards to Dr. Bindu Anil Thomas HOD Electronic and
Communication Department VVIET, Mysore for her
exemplary guidance, monitoring and constant encouragement
throughout the course of this paper. The blessing, help and
guidance given by her time to time shall carry us a long way in
the journey of life on which we are about to embark.
We also take this opportunity to express a deep sense of
gratitude to Mr Narayanaswamy, Associate Prof. E&C Dept.
VVIET, Mysore for his cordial support, valuable information
and guidance.
We are obliged to Mr Kiran Kumar S, Mr. Mohan T N and
Mr. Abhilash V Illur, Students of VII Semester E&C Dept.
VVIET, Mysore. For the valuable information provided by
them in their respective fields We are grateful for their
cooperation and Assistance during the period of our
assignment.
BIOGRAPHIES
Mr. Prasanna Puttaswamy obtained his BE
(Electricals & Electronics) from VTU in
2010 and M.Sc Honours (Embedded
Microelectronics and Wireless System) from
Coventry University UK, in 2012. He
presently involved in experiment on sound
wave and publication. His area of interest: Antenna,
Embedded System, Radar and Microwave Engineering.
Mr. Pramod Srivatsa Krishna Murthy,
born in 1988, India, graduated with B.E in
Electricals & Electronics Engineering in
2010 & obtained MSc honours in Embedded
Microelectronics & Wireless Systems from
Coventry University of UK in 2012.
Currently working in a local embedded firm with alongside
involvement in technical experiments & publications and
ambitious to be a Research Scholar. Areas of interest are:
Embedded Systems, Microwave Engineering, Antennas &
Radar systems with few publications in the mentioned areas.

A new conceptual algorithm for adaptive route changing in urban environments

More Related Content

What's hot (20)

Similar to A new conceptual algorithm for adaptive route changing in urban environments (20)

More from eSAT Journals (20)

Recently uploaded (20)

A new conceptual algorithm for adaptive route changing in urban environments