DYNAMIC RESOURCE ALLOCATION IN ROAD TRANSPORT SECTOR USING MOBILE CLOUD COMPUTING TECHNIQUES

International Journal of Mechanical Engineering and Technology (IJMET), ISSN 0976 – 6340(Print),
ISSN 0976 – 6359(Online), Volume 5, Issue 11, November (2014), pp. 17-25 © IAEME
17
DYNAMIC RESOURCE ALLOCATION IN ROAD
TRANSPORT SECTOR USING MOBILE CLOUD
COMPUTING TECHNIQUES
*G. Sadasiva prasad1
, Dr. K. Rajagopal2
, Dr.K. Prahlada rao3
1
Associate Professor, Dept. of Mech. Engg., MITS, Madanapalle
2
Professor & Head, Dept. of Mech. Engg., KSRM, Kadapa
3
Professor, Dept. of Mech. Engg. JNTU, Anantapur
ABSTRACT
Literature review revealed application of various techniques for efficient use of existing
resources in road transport sector vehicles, operators and related facilities. This issue assumes bigger
dimensions in situations where there are multiple routes and the demand in the routes is highly
fluctuating over the day. The application of the existing techniques as reported in literature addresses
above issues to a considerable extent. However the main draw back in existing techniques is lack of
proper uninterrupted information about vehicles and demand available at a central place for
allocation of vehicles in different roads and huge computational times required for processing. Cloud
computing is a recently developed processing tool that is used in effective utilization of resources in
transport sector under dynamic resource allocation. Since the demand fluctuates at different times in
different routes, mobile cloud computing techniques are being used to address the issues related to
effective resource allocation. This paper attempts at, making a detailed study of application of
mobile cloud computing techniques in transport sector for dynamic resource allocation and to
identify the limitations there in, with a view to address the limitations. Creating identical clouds at
various strategic points and mobile feeding of information to each cloud, creation of a central
processing place called as traffic manager, releasing vehicle / driver allocation orders of the traffic
manager etc, are some of the essential features of the proposed mobile cloud computing. Simulation
studies are made by considering case studies and the results are compared with real time values. The
proposed mobile cloud computing makes use of JRE processing. The required algorithms along with
coding, flow diagram and the output are presented. It has been observed that the proposed mobile
cloud computing processing offers uninterrupted service with minimum preprocessing, processing
and post processing time. Further the proposed method can be used for handling large number of
vehicles / routes with case and hence is more efficient than the existing methods of dynamic resource
INTERNATIONAL JOURNAL OF MECHANICAL ENGINEERING AND
TECHNOLOGY (IJMET)
ISSN 0976 – 6340 (Print)
ISSN 0976 – 6359 (Online)
Volume 5, Issue 11, November (2014), pp. 17-25
© IAEME: www.iaeme.com/IJMET.asp
Journal Impact Factor (2014): 7.5377 (Calculated by GISI)
www.jifactor.com
IJMET
© I A E M E

18
allocation. The major contribution of present work is developing of a mobile cloud computing
processor offering uninterrupted services with minimum processing time capable of handling large
vehicles / driver facilities under severe demand fluctuating conditions.
Keywords: Dynamic Resource Allocation (DRA), Transport, Mobile, Cloud, Planning, Route,
Vehicles.
1.0 INTRODUCTION
With the enormous exponential growth of population all over the world in general and India
in particular, people have to heavily depend on public and private transport systems for their day to
day life [1]. A public transport system is normally maintained by government and is supposed to
provide regular and continuous transport services to the public. The major public transport is road
transport in countries like India. As the government could not provide adequate transport facilities
meeting the public demand, private transport undertakings have slowly come up providing transport
facilities [8]. Though the transport undertakings are supposed to provide high quality of service at
reasonably economic fares, due to improper planning of transport systems the above goal could not
be achieved and transport sectors are running under loss. This limitation can be mainly attributed to
the un organized scientific planning of transport system causing huge investments, vehicles count
not be used to fullest extent, high operating costs etc. This has resulted in high transport fares which
forced public to go in for unorganized transport means, which normally violate rules and regulation
resulting in unsafe [5] and uncomfortable travel by the public[1]. This situation arises when there are
heavy fluctuations in the demand for vehicles at different times in different routes over different
periods of time and lack of communication to a central point which distributes the fleet at hand
suiting the demand [6]. In this situation, there are no fixed vehicles or fixed routes and the vehicles
assignment over routes continuously changes based on the demand. The central point is the
allocation manager. This system can operate on manual basis [7]. However if we consider a heavy
fluctuation in demand over the day over multiple routes, especially in metro cities at peak hours,
manual operation by the manager at central point may not be practically feasible. In such cases it is
recommended that a computer programming may be used [2] which computes instantly and displays
the vehicle – route allocation details and consequent orders [3]. In this paper an attempt is made to
consider a real time problem, and to develop a computer programme and study the output. For this,
simulations models will be proposed and the results of the simulation will be evaluated against above
real time situations. To make the concepts and applications of dynamic resource planning clear [2] a
few cases are analyzed. Conventional computing for dynamic resource allocation may not be feasible
in cases of high density of vehicles, routes and traffic. Hence is this paper an attempt is also made to
use mobile cloud computing techniques for dynamic resource allocation using mobile devices for
communicating data to a central resource allocation point. Cloud computing consists of feeding
heavy data to a high capacity server, which has multi operating facilities to generate end user
information instantly. The principle of working of mobile cloud consists of installing mobile
communicating devices at different convenient places with the facility of communicating vehicle Vs
route requirement data to different cloud stations situated at different convenient points and also to a
central point called as allocation manager. The manager will select the nearest available cloud and
process the data instantly and compute the same to generate vehicle – route allocation orders and
communicate back, the same to respective mobile devices for execution [9]. Laboratory simulation
models will be developed for this case and algorithms and coding are written with flow diagrams.
Upto five convenient roots are considered with fluctuation in demand over the day. The simulation
results are compared with available real time situation values to assess [4] the validity of the
proposed method. Exhaustive literature survey on dynamic resource allocation in general and using

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mobile cloud computing in particular with limitations there in, especially dealing with very high
density vehicle – route situations are presented. The major contribution of the present work will be to
propose a computer based dynamic resource planning in transport sector for high density fluctuation
requirements using mobile cloud computing techniques, and to address the limitation in existing
methods. Attempt will also be made to develop laboratory simulation models to validate the
proposed method.
2.0 LITERATURE REVIEW
Sada siva Prasad etal [1], idenfied the issues and challenge related dynamic resource
allocation polices in road transport sectors. They have suggested the various steps to be taken for
improving the efficiency of functioning of road transport sector and suggested methods of road
transport sector and suffested methods for the same. They rouched upon mobile cloud computing
application for addressing above issues. B.Sai etal [2], applied cloud computing techniques in
dynamic resources allocation for solving scheduling problems on virtual machines. Their method
compared well with existing methods. Cobo etal [3], worked on the conceptual structures of
intelligent transport systems (ITS). They developed an automatic method for detecting hidden
themes and their effect over a period of time. This method combined performance analysis and
science mapping. Litman, T. etal [4], did extensive work on evaluating accessibility for
transportation planning and submitted his conclusions. Safe etal [5], worked on clean, and affordable
transport for development, with special reference to safety of the transport systems. ESCAP etal [6],
analysis emerging issues in transport sector and suggested transport and millennium development
goals. Keller, G. etal [7], worked on low volume roads engineering leading to best management
practices in transport sector. Yanfeng etal [8], developed a smart parking system based on dynamic
resource allocation. Their work was based on mixed integer linear program at each destination in a
time driven sequence. They conduced that this approach reduced traffic congestion in urban areas
and exploited technologies for searching parking space availability, resulting in performance
improvement over existing parking behavior. Sarkar, A etal [9], developed a sustainable rural roads
maintenance system in India.
3.0 ISSUES AND CHALLENGES IN DRA
The main challenges in transport sector are:
a. Providing scientifically organized planning for transport using mobile cloud computing,
b. Providing good quality of services,
c. Planning for new strategies,
d. Optimizing the fleet size, and
4.0 SCOPE AND OBJECTIVES OF PRESENT WORK
The main objectives of the present work are
a. Addressing various drawbacks of transport system,
b. Providing consistently high quality of service,
c. Strategic planning for transport sector using mobile cloud computing techniques,
d. Reshaping transport activities,
e. Matching the vehicles with service demand and
f. Targeting travel time variability.

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5.0 FORMULATION OF PROBLEM
In view of the enormous increase in demand for transport, a scientifically organized and
planned transport system has become a must. Hence the present work is undertaken to study the
existing limitations in transport sector planning and to proposed dynamic resource allocation in
transport sector using mobile cloud computing techniques.
6.0 METHODOLOGY OF PRESENT WORK
The methodology of present work consists of the following steps.
6.1 Development of appropriate application software under mobile cloud computing,
6.2 Fixing the vehicle roots, number of vehicle in each route for normal vehicle demand, anticipated
fluctuation in demand in each root etc.
6.3 Fixing a simulation model and writing the required algorithm along with the flow diagram and
coding.
6.4 Running the programme for output.
6.5 Analyzing the output of the simulation model and comparing with real time values for validation
of the software used for simulation model.
6.6 Generalization of the proposed method, for large number of roots and vehicles with fluctuations
in demand.
7.0 PRESENT WORK
Before developing the dynamic resource allocation programme using the said mobile cloud
computing techniques, the following steps as listed below are identified.
7.1 Assumptions
a) For a given situation, the number of roots (R1,R2…Rn) is constant.
b) Let the demand (no. of passengers) in roots R1, R2...Rn be d1, d2….dn under normal conditions
without fluctuations is (c).
c) The total no. of passengers in all the roots over the day is constant meaning thereby an increase in
demand in a particular route results in a corresponding decrease in another route.
d) Based on the speed of the vehicles and distance to be covered in each route, the number of
vehicles moving at a given time under normal demand in the said route may be assumed suitably.
e) Let there be N number of clouds (C1, C2…..Cn).
f) The office of the traffic manager is located at a place equidistant from all the clouds.
g) Important busy places in each route are provided with a mobile communication device connecting
all the clouds and traffic manager.
h) All the vehicles in all the routes have the same seating capacity (c) including over loading of 10%.
i) The total time of travel in each route is one hour.
j) At any given point of time in any route the demand can vary from 0 to 2c.
k) A spare vehicle with capacity (c) is provides in each route.
7.2 Creation of a mathematical Simulation model based on select case studies
Consider the case of a traffic situation, where there are five routes (R1,……..R5). The no of
vehicles in each route is 2 and the capacity of each vehicle in all the roots is 50 (c=50). Let there be 4
clouds in each route with a total of 4X5=20 clouds (C1,C2….C20). the demand in route R1 is
expressed as DR1 which can be less than c=50 or equal to c=50 or greater than C=50, Similarly in

21
other routes the demands are DR2, DR3, DR4 and DR5. A fluctuation in demand means the values
of DR1,….DR5 are either more than or less than c.
7.3 Algorithm, flow diagram and coding for dynamic resource allocation using mobile cloud
computing techniques
7.3.1 Algorithm
a) Choose the routes (R1, or R2…..R5)
b) Based on the mobile communication information the demand DR1 or DR2….DR5 in each
root is noted down.
c) If the demand is normal, let the vehicles move normally.
d) The central traffic manager selects the nearest cloud and processes the vehicles allocation
based on the demand and releases the orders to the respective mobile stations.
e) If a particular cloud fails, the traffic manager shifts to another nearest cloud for information.
The orders may be in the form shown in next step.
f) If the demand in a route is more than normal, divert a vehicle from the less demand root to
above route etc.
7.3.2 Flow diagram
7.3.3 Coding
Sample coding based on java language is given below.
import java.awt.*;
import java.applet.*;
import java.awt.event.*;
Start – choose the routes (R1…R5)
Obtain demand DR1….DR5
Normal demand (c) - vehicles run
normally
Shift to another cloud if required
Processing by central traffic manager
Releasing of vehicle allocation orders
End

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import java.util.*;
import java.awt.geom.*;
import java.awt.Graphics.*;
//<applet code=s4 width=780 height=500></applet>
public class s4 extends Applet
{int bbb=0,aaa=0,ddd,op=0,as=0;
Button bb1=new Button("click");
Button bb2=new Button("DR1=");
Button bb7=new Button("c=");
TextField t1=new TextField("65");
public void init()
{
add(bb1);
add(bb2);add(t1);
add(bb3);add(t2);
add(bb4);add(t3);
add(bb5);add(t4);
add(bb6);add(t5);
add(bb7);add(t6);
add(bb8);add(t7);
}
if ((DR1<=c) && (DR2>c) && (DR2<=2*c) && (DR3<=c))
{
bbb=0;
}
else if ((DR1>c) && (DR1<=2*c) && (DR2<c) && (DR3==c) && (DR4==c))
{
bbb=1;
}
else if ((DR1>c) && (DR1<=2*c) && (DR2>c) && (DR2<=2*c) && (DR3>c) && (DR3<=2*c)
&& (DR4>c) && (DR4<=2*c) && (DR5<c))
{
bbb=2;
}
op=1;
aaa=0;
repaint();
}
if (bbb==0)
{
g.setColor(Color.red);

23
g.drawString ("Release one vehicle from route R1 and divert to route R2",50,100);
}
else if (bbb==1)
{
g.drawString ("Release one vehicle from route R2 and divert to route R1",50,100);
}
else if (bbb==2) {
g.drawString ("Release one vehicle from route R5 and divert to route R1.",50,100);
g.drawString ("Further borrow 3 vehicles from near by traffic network",50,120);
g.drawString ("and divert one each for routes R2, R3 and R4",50,140);
}
7.4 Output and orders of the traffic manager
The following refers to outputs for different cases.
7.4.1 Case :1
3 routes with DR1 < c and DR2 > c and DR3 = c.
No. of routes 3 (R1, R2, and R3)
No. of vehicles in each route (normal) = 2.
Normal capacity of vehile = c =50 (including overloading).
Actual demand in route 1 = DR1 = 35 (< c)
Actual demand in route 2 = DR2 = 65 (> c)
Actual demand in route 3 = DR3 = 50 (= c)
Output:
7.4.2 Case :2
4 routes with DR1 > c, DR2 <c, DR3 =c and DR4 = c.
No. of routes 4 (R1, R2, R3 and R4)
Normal capacity of vehicle = c =50 (including overloading).

24
Output:
7.4.3 Case: 3
5 routes with DR1 > c, DR2 > c, DR3 > c DR4 > c and DR5 < c.
No. of routes 5 (R1, R2, R3, R4 and R5)
Normal capacity of vehicle = c =50 (including overloading).
Output:
7.5 Validation of simulation results with real time actual values
The mathematical simulation models with 5 routes is considered and different combination of
demands (more than 500) in different routes are tried and the outputs are compared with the
corresponding requirements of real time situations. It has been observed that the results of simulation
in totality agree with the actual real time values. Hence by suitable modifications in assumptions as
shown in section 7.1, the developed algorithms and coding can be extended for any desired real time
situations.
8.0 RESULTS AND DISCUSSIONS
1. Since the traffic manger chooses the nearest cloud from among the identical clouds simulated
at different strategic places, the time of computation is reduced to a considerable extent
compared to existing methods.

25
2. If a particular cloud breaks down, the traffic manager can immediately choose another nearest
cloud, there by rendering uninterrupted resource allocation service, which is not the case with
existing cloud computing methods.
3. It has been established that the results of the mathematical simulation model very well agree
with real time solutions, paving way for application of the proposed application software with
suitable modifications for any real time dynamic resource allocation problems.
4. Considering above, it has been established that the proposed mobile cloud computing
technique for dynamic resource allocations in road transport sector is reliable, fault free and
quick compared to existing mobile cloud computing techniques.
9.0 CONCLUSIONS
The major contribution of present work is developing of a mobile cloud computing processor
offering uninterrupted services with minimum processing time capable of handling large vehicles
driver facilities under severe demand fluctuating conditions.
REFERENCES
[1] G.Sada siva Prasad, “Issues and challenges related to dynamic resource allocation policies in
road transport sector”, IJRRSET, Vol-2, Issue 9, October 2014.
[2] B.Sai etal, “Virtual machines and cloud in dynamic resources”, IJRRSET, Vol-2, Issue 2, Feb
2014.
[3] M. J. Cobo, “A Bibliometric Analysis of the Intelligent Transportation Systems Research
Based on Science Mapping”, 1524-9050 © 2013 IEEE. Personal use is permitted, but
republication/redistribution requires IEEE permission.
[4] Litman, T. Evaluating Accessibility for Transportation Planning. Victoria Transport Policy
Institute, Victoria, Canada, 2008. www.vtpi.org/access.pdf. Accessed April 18, 2012.
[5] Safe, Clean, and Affordable Transport for Development. The World Bank Group’s Transport
Business Strategy for 2008–2012, Transport Sector Board, The World Bank, Washington,
D.C., 2008.
[6] ESCAP. Emerging Issues in Transport: Transport and Millennium Development Goals.
Expert Group Meeting on Preparation for the Ministerial Conference on Transport, U.N.
Economic and Social Commission for Asia and the Pacific, Bangkok, July 6, 2011.
http://www.unescap.org/ttdw/MCT2011/EGM/EGM1-10E.pdf. Accessed Feb. 11, 2012.
[7] Keller, G., and J.Sherar. Low Volume Roads Engineering-Best Management Practices Field
Guide. USAID and Forest Service, USDA, Washington, D.C., 2003.
http://www.fs.fed.us/global/topic/welcome.htm#12. Accessed April 18, 2012.
[8] Yanfeng Geng, “Dynamic Resource Allocation in Urban Settings: A “Smart Parking”
[9] Approach”, 2011 IEEE International Symposium on Computer-Aided Control System Design
(CACSD).
[10] Sarkar, A. K. Development of a Sustainable Rural Roads Maintenance System in India: Key
Issues. Planning for Accessibility and Rural Roads, Transport and Communications Bulletin
for Asia and the Pacific, No. 81, ESCAP, United Nations, Bangkok, 2011, pp. 36–51.
[11] Gurudatt Kulkarni, Jayant Gambhir and Amruta Dongare, “Security in Cloud Computing”,
International Journal of Computer Engineering & Technology (IJCET), Volume 3, Issue 1,
2012, pp. 258 - 265, ISSN Print: 0976 – 6367, ISSN Online: 0976 – 6375.
[12] Monal Mehta, Ishitva Ajmera and Rakesh Jondhale, “Mobile Cloud Computing”,
International Journal of Electronics and Communication Engineering & Technology
(IJECET), Volume 4, Issue 5, 2013, pp. 152 - 160, ISSN Print: 0976- 6464, ISSN Online:
0976 –6472.

DYNAMIC RESOURCE ALLOCATION IN ROAD TRANSPORT SECTOR USING MOBILE CLOUD COMPUTING TECHNIQUES

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