IRJET- IoT based Traffic Congestion Monitoring and Management System

International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 05 Issue: 09 | Sep 2018 www.irjet.net p-ISSN: 2395-0072
© 2019, IRJET | Impact Factor value: 7.211 | ISO 9001:2008 Certified Journal | Page 6701
IOT BASED TRAFFIC CONGESTION MONITORING AND MANAGEMENT
SYSTEM
Dr.D.Selvaraj1, Bharathiraja R2, Gokul Nath V3 , Immanuel E4, Jyothesvar GL5
1Professor, Department of Electronics and Communication Engineering
2345Student, Department of Electronic and Communication Engineering
12345Panimalar Engineering College, Poonamallee , Chennai, Tamil Nadu 600123.
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Abstract - In today’s world, traffic jams during rush
hours is one of the major concerns. During rush hours,
emergency vehicles like Ambulances, Police cars and Fire
Brigade trucks get stuck in traffic jams. Due to this, these
emergency vehicles are not able to reach their destinations
in time, resulting to loss of human lives. An IOT based system
has been developed to provide clearance to any emergency
vehicle with aid of employing RFID technology by turning all
the red lights to green on the path of the emergency vehicle.
In addition to the green wave path, the system will track a
stolen vehicle when it passes through a traffic light with
help of RFID. By the proposal of this system an decrease in
usage waiting time for traffic clearance is achieved. Drivers
have a less stress to handle vehicles and can reduce accident
rates to a greater extend. The proposed method can be a
great relief to the traffic control department to handle
traffic in a great way. This RFID & IOT employed detecting
system is economically effective and perform as a superior
system.
Key Words: RFID, IOT, Traffic, Emergency vehicles, Green
Wave.
1. INTRODUCTION
Traffic congestion is said to occur when the number of
vehicles on road is greater than the capacity of the road.
Traffic congestion on roads is the slower speed or halt of
vehicles causing longer trip times and increased queues.
Traffic congestion has become the newly generated
conundrum in metropolitan cities of India. IoT refers to a
system that involves all the physical objects around us and
their communication with each other over the internet.
The main motive of IoT is to simplify the day to day life of
human beings. The increase in vehicle usage per head also
leads to traffic congestion. Moreover, it has been seen that
the conventional ways of curbing traffic congestion by
signalling system with predefined set time for signals
using microcontrollers was not efficient and is failing to
achieve its objectives. Many researchers have come up
with a model to deal with traffic congestion in a real-time
scenario. The traffic management system is the only way
one can address the problem of traffic congestion in Indian
cities where the scope for augmenting road infrastructure
is very minimal. IoT can help in altering traffic signal
patterns, providing real-time traffic information and alerts
to the drivers. RFID technology has a minimal security risk
factor. The number of vehicles and their speeds is
provided by sensors to a backend server to alter the traffic
signal pattern as a traffic decongestion strategy. Hence, the
idea to make the traffic signalling system adaptive
depending upon vehicle density on the road was chosen to
enumerate these issues and take necessary remedies to
aid these serious problems.
1.1 Causes for Traffic Congestion
Most of the Indian cities still have poor public transport
systems. Increasing population density puts a giant
pressure on already existing transport infrastructure,
affecting its quality. People now a days use their own
transport due to the inconvenience of public buses or rails.
Improvement on public transport and extra schemes like
BRT. The Bus rapid Transport is enforced in some cities
like Pune and it can be very helpful if implemented
correctly. People ought to attempt to use carpooling and
bike pooling to a larger extent as possible. Use of bicycles
for smaller distances conjointly improves individual health
together with reducing pollution and road congestion.
2. INTERNET OF THINGS
The internet of things (IoT) is the network of physical
devices, vehicles, buildings and alternative things
embedded with physical science, software, sensors,
actuators, and network property that modify these objects
to collect and exchange data. In 2013 the world Standards
Initiative on internet of Things (IoT-GSI) outlined the IoT
as "the infrastructure of the data society. The IoT permits
objects to be detected and controlled remotely across
existing network infrastructure, creating opportunities for
heaps of direct integration of the physical world into
computer-based systems, and ensuing in improved
efficiency, accuracy and economic benefit. When IoT is
increased with sensors and actuators, the technology
becomes an instance of the a lot of general category of
cyber-physical systems, that conjointly encompasses
technologies like sensible grids, smart homes, intelligent
transportation and smart cities. Each factor is
unambiguously diagnosable through its embedded

automatic data processing system however is in a position
to interoperate among the present internet infrastructure.
Experts estimate that the IoT can incorporate virtually fifty
billion objects by 2020.
3. EXISTING SYSTEM
The previous and existing system tend to offer a higher
traffic congestion due to traditional methods. As of now
only timing based traffic clearance is being followed
regardless of high traffic areas. Due to this clearance
becomes a tedious process. So to maintain a highly
innovative and enhanced mode of transport, it is
necessary to adopt a different method. As of now we knew
maintaining a seamless traffic route is impossible without
changes. Taking over bridges, subways and alternate
routes may be effective in only some cases, but it doesn’t
work in a regular daily life. This issue not only affects an
individual routine but creates a overall delay in entire
activities. So upgrading and enhancing the present traffic
clearance is a very necessary need.
3.1 Drawbacks of Existing System
 In existing method, automatic traffic management
based upon vehicle type is difficult.
 There is no wireless technology available for
monitoring.
 There is no support for detection of theft vehicle.
 Clearance of traffic is tedious.
4. LITERATURE SURVEY
Road Traffic Congestion Management Based On A Search-
Allocation Approach By Al Qasemi Academic College
Baqa El Ghabia, Israel published in the year 2017
Implementation of On road sensors were used to detect
the density of traffic. In this way, the vehicles passing on
the road over the sensors creates a change in inductance.
This change in inductance creates a count of vehicle, but
during peak hours the vehicles pass on a much faster rate
and the interval of change in inductance cannot be
recorded precisely. Creating the use of such sensor based
environment needs a lot of investment and much manual
works.
4. PROPOSED WORK
In the proposed system we are going to monitor the traffic
system, emergency and theft vehicles easily by using cloud
database by the combination of RFID and IoT technology.
This system can deal with the improved monitoring of
theft vehicle and traffic clearance in emergency conditions
which is detected using the RFID reader and monitored
using IoT.
In the proposed system to improve the existing
system a new Green wave system is developed ,in which
the traffic signal management for emergency vehicle is
included. To make the proposed system to work, each and
every vehicle going for registration is provided with a
RFID tag. In which information like vehicle’s unique
registration number and vehicle type is stored. The vehicle
type is mentioned as E (For Emergency) and N (For
Normal) in the tag. These data are stored in the database
in the Transport office. To read the information in tag a
RFID reader is installed in the Traffic control unit.
Whenever the vehicle passes through ,the signal reader
gets the vehicle type and gives it to the controller unit. In
which if any E (Emergency) type vehicle is found, that lane
is made green with respect to the other lanes. To upgrade
further more theft vehicle detection method is used. To
find a theft vehicle, the user has to contact the Transport
office to update the database of the vehicle with T (for
Theft). So whenever a vehicle is passed through the traffic
signal, the Control unit picks up the tag details and sent to
the Transport office via IoT unit. From the obtained value
the PC in the Transport office has to check with the
database. If any theft vehicle is found, the control unit in
the Transport office will send to Police station about the
vehicle passing through the particular signal. Thus the
police able to intercept the vehicle in the next possible
path.

4.1 Block Diagram
Fig 4.1 Block Diagram of Proposed Model
In the proposed system The Mega 2560 is a
microcontroller board based on the ATmega2560 which
acts as the brain of the model. This controls the entire
functioning of the model. This receives the input from the
IR sensors and RFID module to calculate the traffic rate.
Fig 4.2 Arduino Mega 2560
A 16x2 LCD display is very basic module and is
very commonly used in various devices and circuits. These
modules are preferred over seven segments and other
multi segment LEDs which displays the rate of traffic level
to the public which has the minimum Vs maximum traffic.
A Light Emitting Diode (LED) is one of the latest
inventions and is extensively used these days. From your
cell phone to the large advertising display boards, the
wide range of applications of these magical light bulbs can
be witnessed almost everywhere.
An infrared sensor is an electronic device, that
emits in order to sense some aspects of the surroundings.
An IR sensor can measure the heat of an object as well as
detects the motion. These types of sensors measures only
infrared radiation, rather than emitting it that is called as a
passive IR sensor. Usually in the infrared spectrum, all the
objects radiate some form of thermal radiations.
Fig 4.3 Working of IR sensor
4.2 Flow Chart
Fig 4.3 Flow of IR and switching of traffic signals

Here the density of the traffic is compared with the lanes
in the priority of ‘LOW’, ‘MEDIUM’ & ‘HIGH’ using the IR
sensor and the lane with high traffic is cleared first
according to the algorithm.
For instance if lane 1 is of High Traffic IR detects
and sends the information to the microcontroller and this
information is processed and that particular lane is made
green to clear the traffic by the priority.
As the lane with high traffic is made green the low
traffic lane is made to wait with a RED signal and the
vehicles are stalled.
When an emergency vehicle is about to enter the
traffic ,the lane is cleared stalling other lanes to give way
for the emergency vehicle.
Controversy to the emergency vehicle when an
theft vehicle enters the lane in the same way the RFID
reads the tag and sends the information to the
microcontroller, the microcontrollers detects the Theft
vehicle immediately the lane is made to stall using RED
signal so the Theft vehicle can be easily recovered.
Fig 4.4 RFID Detection for Theft & Emergency Vehicle in
Lane
Here the vehicle on entering the lane is readily scanned by
the RFID reader in the junction.
When the vehicle ID is identified as either Theft or
Emergency Vehicle the Following Cases are Applied
CASE 1: Theft Vehicle entering the Lane
Here when there is an entry of Theft vehicle the
Predefined ID given to the Vehicle is readily scanned by
the reader and given to the micro controller. The
Microcontroller readily which has an active scan for the
vehicle ,Controls the traffic signal and turns the signal to
RED which halts the signal and displays the theft vehicle
presence which can be easily retrieved. Here this helps in
a faster recovery of the theft vehicle.
CASE 2: Emergency Case or Ambulance entry in the Lane
Incase when there is an emergency to clear the
traffic or if suppose when an ambulance enters the high
densely traffic routes the RFID tag given to those vehicles
is similarly scanned in the same way and informed to the
microcontroller and in turn the microcontroller takes
necessary action to clear the traffic as soon as possible.
The microcontroller changes the respective lane to GREEN
and the vehicle can pass the traffic with less waiting time.
5. RESULTS
These are the results obtained from the proposed
system.
5.1. High Traffic
In high traffic conditions the three IR sensors
placed are on HIGH state condition and as per the priority
the lane with highest traffic density is cleared first
whereas the other lanes are stalled with a GREEN signal.
Fig 5.1 High Traffic Congestion Management

5.2. Emergency Vehicle
Here the Emergency vehicle which is given an
identity tag of 12 digit numbers On reaching the traffic can
be easily detected by the RFID tag which is indicated in the
above figure. The information from the RFID is given to
the AT-MEGA microcontroller which clears the traffic.
Fig 5.2 Emergency Vehicle Management
5.3. Theft Vehicle
As in the case of the Theft Vehicle the lane is
stopped to identify the theft vehicle. Here the aim of the
microcontroller is to recognize and stall the theft vehicle.
So once the theft vehicle enters the RFID containing lane in
the way which emergency vehicle was recognized the theft
vehicle with unique ID is also recognized ad given to the
microcontroller. Once the microcontroller recognizes the
vehicle as a theft vehicle, the lane is turned to RED signal
and the lane is stalled. This stops the passage of theft
vehicle and can be retrieved.
Fig 5.3 Theft Vehicle Detection
5.4. IOT Monitoring section
Integration of IOT information on density of
traffic gives a great hand to public. So by the information
from the cloud server the details of information on density
of the traffic can be easily informed to the users so public
could take alternate routes and avoid traffic. This not only
helps individual to escape traffic but also entry of new
vehicles in an already dense traffic routes.
Fig 5.4 IOT Live Monitoring
6. CONCLUSION
Thus the vehicular assistance with sensors and
advanced IoT tracking can be helpful in creating a safer
experience for the travelers. By implementation of this
method many lives could be saved in an efficient manner.
On time medication failure is the main cause for the loss of
many lives, so such a negative case could be avoided. Loss
of vehicles can be a serious loss to a common man,

Tracking and retrieval of such vehicles can avoid a great
economical loss.
Such vehicular information can also be useful for
Legal cases and investigation to the Police department as
easy steps can be made with ready information available
from the cloud server and the rate of crime can also be
reduced to a greater extend.
7. REFERENCES
[1] Jamal Raiyn, “Road traffic congestion management
based on search allocation approach” Transport and
Telecommunication, 2017, volume 18, no. 1, 25-33
Transport and Telecommunication Institute, Lomonosova
1, Riga, LV-1019, Latvia
DOI 10.1515/ttj-2017-0003
[2] Da Xu. L, W. He, and S. Li, “Internet of things in
industries: A survey,” IEEE Transactions on industrial
informatics, vol. 10, no. 4, pp. 2233– 2243, 2014.
[3] Ramkumar Eswaraprasad , Linesh Raja,Nu “ Transport
Improved Intelligent System for Reliable Traffic Control
Management by Adapting Internet of Things”, IEEE,2017.
[4] Weihai Chen, Zheng Zhao, “A Novel Assistive On-ramp
Merging Control System for Dense Traffic Management”,
IEEE, 2017

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