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Automatic Street Light Control System Using Microcontroller
MUSTAFA SAAD, ABDALHALIM FARIJ, AHAMED SALAH and
ABDALROOF ABDALJALIL
Department of Control Engineering
College of Electronic Technology/ Baniwalid
Baniwalid- Libya
LIBYA
mustafasaad9@yahoo.com
Abstract: - This paper aims at designing and executing the advanced development in embedded systems for
energy saving of street lights. Nowadays, human has become too busy, and is unable to find time even to switch
the lights wherever not necessary. The present system is like, the street lights will be switched on in the evening
before the sun sets and they are switched off the next day morning after there is sufficient light on the roads.
this paper gives the best solution for electrical power wastage. Also the manual operation of the lighting system
is completely eliminated. In this paper the two sensors are used which are Light Dependent Resistor LDR
sensor to indicate a day/night time and the photoelectric sensors to detect the movement on the street. the
microcontroller PIC16F877A is used as brain to control the street light system, where the programming
language used for developing the software to the microcontroller is C-language. Finally, the system has been
successfully designed and implemented as prototype system.
Key-Words: - Street light, LDR, photoelectric sensor, microcontroller, energy saving and circuit design.
1 Introduction
The idea of designing a new system for the
streetlight that do not consume huge amount of
electricity and illuminate large areas with the
highest intensity of light is concerning each
engineer working in this field. Providing street
lighting is one of the most important and expensive
responsibilities of a city. Lighting can account for
10–38% of the total energy bill in typical cities
worldwide [1]. Street lighting is a particularly
critical concern for public authorities in developing
countries because of its strategic importance for
economic and social stability. Inefficient lighting
wastes significant financial resources every year,
and poor lighting creates unsafe conditions. Energy
efficient technologies and design mechanism can
reduce cost of the street lighting drastically.
Manual control is prone to errors and leads to
energy wastages and manually dimming during mid
night is impracticable. Also, dynamically tracking
the light level is manually impracticable. The
current trend is the introduction of automation and
remote management solutions to control street
lighting [2].
There are various numbers of control strategy
and methods in controlling the street light system
such as design and implementation of CPLD based
solar power saving system for street lights and
automatic traffic controller [1], design and
fabrication of automatic street light control
system[3], automatic street light intensity control
and road safety module using embedded system [4],
automatic street light control system [5], Intelligent
Street Lighting System Using Gsm [6], energy
consumption saving solutions based on intelligent
street lighting control system [7] and A Novel
Design of an Automatic Lighting Control System
for a Wireless Sensor Network with Increased
Sensor Lifetime and Reduced Sensor Numbers[8].
In this paper two kinds of sensors will be used
which are light sensor and photoelectric sensor. The
light sensor will detect darkness to activate the
ON/OFF switch, so the streetlights will be ready to
turn on and the photoelectric sensor will detect
movement to activate the streetlights. LDR, which
varies according to the amount of light falling on its
surface, this gives an inductions for whether it is a
day-night time, the photoelectric sensors are placed
on the side of the road, which can be controlled by
microcontroller PIC16f877A. The photoelectric will
be activated only on the night time. If any object
crosses the photoelectric beam, a particular light
will be automatically ON. By using this as a basic
principle, the intelligent system can be designed for
the perfect usage of streetlights in any place.
The block diagram of street light system as
shown in Fig. 1 consists of microcontroller, LDR,
and photoelectric sensor. By using the LDR we can
operate the lights, i.e. when the light is available
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then it will be in the OFF state and when it is dark
the light will be in ON state, it means LDR is
inversely proportional to light. When the light falls
on the LDR it sends the commands to the
microcontroller that it should be in the OFF state
then it switch OFF the light, the photoelectric sensor
will be used to turn ON or OFF the light according
to the presence or absent of the object. All these
commands are sent to the controller then according
to that the device operates. We use a relay to act as
an ON/OFF switch.
Fig. 1 Block diagram of street light system
2 Automatic street light system
circuit design
The system basically consists of a LDR,
Photoelectric sensor, Power supply, Relays and
Micro controller.
2.1 LDR
The theoretical concept of the light sensor lies
behind, which is used in this circuit as a darkness
detector. The LDR is a resistor as shown in Fig. 2,
and its resistance varies according to the amount of
light falling on its surface. When the LDR detect
light its resistance will get decreased, thus if it
detects darkness its resistance will increase.
Fig. 2 LDR
2.2 Photoelectric Sensor
To detect the movement in the street, the
photoelectric sensors have been used in this paper,
where emitter and receiver are in one unit as shown
in Fig 3. Light from the emitter strikes the target and
the reflected light is diffused from the surface at all
angles. If the receiver receives enough reflected
light the output will switch states. When no light is
reflected back to the receiver the output returns to
its original state. In diffuse scanning the emitter is
placed perpendicular to the target. The receiver will
be at some angle in order to receive some of the
scattered (diffuse) reflection. The photoelectric
sensor specifications are illustrated in Table 1.
Fig. 3 Photoelectric sensor
Table 1 Photoelectric sensor specifications
Photoelectric Sensors (MC005)
Sensing range
3-80 cm
Sensing object
Translucency, opaque
Supply voltage,
current
DC 5V, 100mA
Output operation
Normally open
Output
DC three-wire system
(NPN)
Diameter, Length
18mm, 45mm
Ambient temperature
-25_70
2.3 Regulated Power Supply
Usually, we start with an unregulated power supply
ranging from 9volt to 12volt DC. To make a 5volt
power supply, KA8705 voltage regulator IC as
shown in Fig. 4 has been used.
Fig. 4 Power supply regulator
The KA8705 is simple to use. Simply connect
the positive lead form unregulated DC power supply
(anything from 9VDC to 24VDC) to the input pin,
connect the negative lead to the common pin and
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then turn on the power, a 5 volt supply from the
output pin will be gotten.
2.4 Relays
Relays are remote control electrical switches that
are controlled by another switch, such as a horn
switch or a computer as in a power train control
module. Relays allow a small current flow circuit to
control a higher current circuit. Several designs of
relays are in use today, 3-pin, 4-pin, 5-pin, and 6-
pin, single switch or dual switches. Relays which
come in various sizes, ratings, and applications, are
used as remote control switches. Fig. 5 shows
different types of relays. In this paper, the 4-pin
relay will be used.
Fig. 5 Different types of relays
2.5 PIC16F877A Microcontroller
A microcontroller is a computer control system on a
single chip. It has many electronic circuits built into
it, which can decode written instructions and
convert them to electrical signals. The
microcontroller will then step through these
instructions and execute them one by one. As an
example of this a microcontroller we can use it to
controller the lighting of a street by using the exact
procedures.
Microcontrollers are now changing electronic
designs. Instead of hard wiring a number of logic
gates together to perform some function we now use
instructions to wire the gates electronically. The list
of these instructions given to the microcontroller is
called a program. There are different types of
microcontroller, this project focus only on the
PIC16F877A Microcontroller where it's pins as
shown in Fig. 6.
Fig. 6 Pin diagram of PIC16F877A microcontroller
3 Automatic street light control
Circuit Design
The inputs in the streets lighting system are LDR
and photoelectric sensors, after dusk the light sensor
will activate the system, to be ready to detect any
object by photoelectric sensors, on the road to turn
ON the streetlights. Lamps will be used as
streetlights in this paper.
In this section each circuit, which has been
designed will be discussed. Firstly the LDR circuit
as shown in Fig. 7, the LDR and RV1 form one arm
of the bridge, and R1-R2 form the other arm. These
arms can actually be regarded as potential dividers,
with the R1-R2 arm applying a fixed half-supply
voltage to the non-inverting input of the op-amp,
and with the LDR-RV1 divider applying a light-
dependent variable voltage to the inverting terminal
of the op-amp.
Fig. 7 LDR circuit
In use, RV1 is adjusted so that the LDR-RV1
voltage rises fractionally above that of R1-R2 as the
light intensity rises to the desired trigger lever, and
under this condition the op-amp output switches to
negative saturation and thus drives the relay on via
Q1 and biasing resistors R3-R4 when the light
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intensity falls below this level, the op-amp output
switches to positive saturation. The circuit is very
sensitive, being able to detect light-level changes
too small to be seen by the human eye, the circuit
can be modified to act as a precision dark-activated
switch by either transposing the inverting and non-
inverting input terminals of the op-amp, or by
transposing RV1 and the LDR.
Further, the Reset circuit is used to put the
microcontroller into known state. Normally when a
PIC microcontroller is reset, execution starts from
address 0 of the program memory. Also, the
oscillator circuit has been used to provide a
microcontroller with a clock, so that the
microcontroller can execute a program.
Four photoelectric sensors are used in this paper.
Their function to sense the objective that will pass
through the street, at the same time give a signal to
the microcontroller to turn on the lamp. The idea to
save the energy, where the system have been
designed to light ON the lamp in the night only and
only if there is any object passes through the street.
Except to that the light will be OFF. First
photoelectric sensor is used to turn ON the first
lighting column via microcontroller automatically
when any object passes in front of it. Meanwhile the
second photoelectric sensor will turn ON the second
lighting column and turn OFF the first one after few
delay when the object passes in front of it. The third
sensor will activate the third lighting column when
the object passes in front of it, and will turn OFF the
second lighting column after few delays.
Fig. 8 Schematic circuit of the street light system
Finally the last sensor which will be used to turn
OFF the third lighting column after the object passes
in front of it. Fig. 8 shows the overall system
schematic circuit that has been designed in this
paper to control the street lights using PIC
microcontroller.
The details of this circuit can be summarized as
follow:
1. Pins 13 & 14 of the PIC are connected to
the Oscillator circuit and Crystal which
consisting of 4 MHz crystal connected to
two 33 Pf capacitors.
2. Pin 1 is connected to VCC +5V through
10KΩ resistor, connected to reset bottom
for resetting the circuit.
3. Pin 5 is connected to the LDR Circuit.
4. Pins 16, 17, 18, and 19 connected to the
photoelectric sensors through 10KΩ
resistor.
5. Pins 29, 30 and33 connected to the lamp1,
lamp2 and lamp3, through 2.2KΩ resistance
and transistor and Relay.
4 RESULTS AND DISCUSSIONS
The project aims were to reduce the side effects of
the current street lighting system, and find a solution
to save power. In this project the first thing to do, is
to prepare the inputs and outputs of the system to
control the lights of the street. The prototype as
shown in Fig. 9 has been implemented and works as
expected and will prove to be very useful and will
fulfill all the present constraints if implemented on a
large scale.
Fig.9 Prototype of street light system
Fig. 9 shows the street light system, from the
figure it can be seen that, all lighting column are
OFF, because there is no any object passes through
the street, even though the weather is night. This is
the idea of using the microcontroller to control each
lighting column alone. When any object passes in
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front specific photoelectric sensor the lighting
column which connected to it will be turn ON
automatically.
5 Conclusion
This paper elaborates the design and construction of
automatic street control system circuit. Circuit
works properly to turn street lamp ON/OFF. After
designing the circuit which controls the light of the
street as illustrated in the previous sections. LDR
sensor and the photoelectric sensors are the two
main conditions in working the circuit. If the two
conditions have been satisfied the circuit will do the
desired work according to specific program. Each
sensor controls the turning ON or OFF the lighting
column. The street lights has been successfully
controlled by microcontroller. With commands from
the controller the lights will be ON in the places of
the movement when it's dark. furthermore the
drawback of the street light system using timer
controller has been overcome, where the system
depends on photoelectric sensor. Finally this control
circuit can be used in a long roadways between the
cities.
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