Design of Energy Saving Lighting System in University Classroom Based on Wireless Sensor Network

doi:10.4236/cn.2013.51B013

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Communications and Network, 2013, 5, 55-60

doi:10.4236/cn.2013.51B013 Published Online February 2013 (http://www.scirp.org/journal/cn)

Design of Energy Saving Lighting System in University

Classroom Based on Wireless Sensor Network

Yu Liang, Ruihua Zhang*, Wei Wang, Caiqing Xiao

School of Computer Science and Technology, Shandong University, Jinan, china

Email: *ruihua_zhang@sdu.edu.cn

Received 2012

ABSTRACT

In order to reach the objective of intellig ence and energy saving for university classroom lighting, energy saving light-

ing control system in university classroom based on wireless sensor network is designed, including design of sensor

node and sink, as well as corresponding development of control program and upper-computer software. The system sets

single-chip Ameg16 as control center, realizes communication between nodes via nRF24L01 wireless transceiver mod-

ule, and realizes communication between sink and upper computer via w5100 wireless internet module. It perceives

illumination intensity via photoconductor, detects the human body position via infrared pyroelectric sensor, and places

the sensor node on the lamp, so the light can be controlled according to position of human body and cu rre n t illumination

intensity, which can realize energy saving to a large extent on condition that lighting requirement is satisfied. The sys-

tem has low cost, and there is no need to change the original lighting circuit. The light can be turned off by hand, and

when multi-media are used for the class, light can keep off even it is dim. In addition, this system has the function of

automatic fault report, which is convenient for property maintenance.

Keywords: Wireless Sensor Network; Infrared Pyroelectric Sensor; Energy Saving; Lighting System in University

Classroom

1. Introduction

It is a common phenomenon that electricity is wasted in

traditional lighting system of university classroom. Ac-

cording to regulations of national standard, power den-

sity of classroom lightin g is about 10 W/m2. Suppose the

average area of the classroom is 100 m2, then the lighting

load is about 1 kW. If the normal service time is 15 hours

every day, then power consumption of every classroom

every day is 1 kW×15 h＝15 kWh. There are 270 days

when students are at school, so the annual power con-

sumption is about 4050kWh. If the classroom is counted

as 100 m2, then the school has 200 classrooms, so the

power consumption for lighting is about 810,000.00 kWh.

If energy saving rate is calculated as 30%, then

243,000.00 kWh can be saved every year, that is to say,

150,000.00～200,000.00 Yuan of electricity fee will be

saved, and the above estimate does not include line loss

and damaged part of lamps for long service [1]. In terms

of Shandong University, according to statistics, electric-

ity fee in 2005 is 10,470,000.00 Yuan, and it has been

increasing annually [2]. In which power consumption of

lighting accounts for 40% of total electric quantity [3],

and waste caused by delayed turning off or unnecessary

turning on accounts for 70% of power consumption of

lighting. Directed at such wasting phenomena, many

lighting systems have appeared in the market, in which

switch of the light can be controlled automatically ac-

cording to the lighting requirement, so as to avoid the

above energy waste, save expenditure and at the same

time save labor power. Some systems will identify the

indoor light intensity and number of people to control

number of turn-on lamps [4, 5]; some others control the

light according to the region [3,6]. All of these cannot

reach the optimum effect of energy saving, and they re-

quire the original lighting system to change greatly.

In order to make up for the shortcomings of present

technology, system designed by this paper automatically

controls switch of the single lamp according to human

body position and current illumination intensity, which

saves energy to a large extent on condition that lighting

requirements are satisfied.

2. Working Principles of the System

On condition that the original lighting system of the

classroom is not changed, install the sensor node on

every lamp, and adjust the perception range of the sensor

into the largest lamp distance of 2 (often distances

between lamps are not equal, so the largest distance will

*Corresponding author.

Y. LIANG ET AL.

be selected) according to the actual requirements, thus

sensor nodes will be placed in the classroom for redun-

dancy. Every sensor node perceives human signal and

current illumination inten sity, which directly controls the

light. There is communication between sensor node and

sink, so sensor and lamp state in the classroom can be

reflected to sink. There is one sink in every classroom,

which is connected into internet (LAN) via screen wire.

All information gathers into the computer that acts as a

server via internet for information integration, gathering

and disposal as well as providing necessary Web service.

The director can lodge in Web server via any networking

PC or even mobile phone to inquire or control state of all

nodes in the classroom. The system structure is shown in

Figure 1.

The sensor is arranged acco rding to the lamp position.

Height of the classr oom is 3.4 m, perception ang le of in-

frared pyroelectric sensor is 120 degree, and adjust resis-

tance and lens to make radius of sensor coverage range

be the largest lamp distan ce of 2. In general situation,

one person can be detected by 1 or 2 sensors, such as the

white and grey part in Figure 2, and in special situations,

one person can be detected by 3 or 4 sensors, such as the

bend and dark part in Figure 2. Therefore, 4 lamps can

be turned on at most.

Figure 1. System structure diagram.

Figure 2. Human signal detection diagram.

Control of turning on and off the light by automatic

detection in the classroom: under the condition of insuf-

ficient light, when people walk in or past the classroom,

the light will not b e turned on. Only when p eople stay or

sit in a position, will 1 lamp above be turned on, and in

special situations, will 4 lamps be turned on at most.

When people are seated, as long as there is tiny move-

ment within 5 minu tes, the ligh t will keep on . When peo-

ple leave, 5 minutes later, the lamp at corresponding po-

sition will be turned off. Under the co nd ition of sufficien t

light, the light will not be turn ed on. In addition, the sys-

tem can automatically detect damaged lamp node and

sensor node, and report to upper computer, asking for

maintenance.

Control of turning off the light by hand in the class-

room: when multi-media are used for classes in the

classroom, the light may be insufficient, and when there

are people in the classroom, the light will be turned on

automatically, but actually, there is no need to turn on the

light. Therefore, switch of the original lighting system

can be used to turn of f the light by ha nd .

Overall working of the system: firstly, turn on the

original circuit switch to make the circuit unimpeded for

automatic control by the system. When people enter into

the perception range of the sensor, the sensor will detect

current light value. If the light is insufficient, lamp con-

trolled by the sensor node will be turned on, (after order

of turning on the light is given, the light value will be

detected again, and if the light is still insufficient, order

of turning on the light will be given again. If the light is

still insufficient after 3 times, then the node is judged to

be damaged). When people leave the perception range,

there is a delay time for the light to be turned off. In

terms of information that state of the sensor node storage

lamp changes, when sink checks this sensor node, the

current state will be sent to sink (if sink does not receive

the reply, the sensor node will be judged to be damaged).

Sink will make judgment after summarization, then pass

the updated information to the upper computer. Accord-

ingly, the upper computer can also actively issue inquiry

or control orders which will be passed to sensor node via

sink, to get corresponding information or control turning

on and off the light. Under special conditions, such as

multi-media are used, the light can be turned off by hand

via original switch of the circuit.

3. System Hardware Design

This system realizes two kinds of nodes: sensor node and

sink.

3.1. Sensor Node

The sensor node consists of the following components:

infrared pyroelectric sensor, photoresistance, wireless

Y. LIANG ET AL.

transceivers, center processing chip, 5v power converter

and relay. The hardware design circuit is shown in Fig-

ure 3.

with the 3.3v power. This module employs 2.4 GHz with

the distance about more than 10 meters. It can be pro-

grammed to set the location, only when receiving the

location of this single-chip, can the data be output (inter-

rupt indication is provided).

U1 is the central processing component unit. Both the

sensor node and sink employs ATMEGA16L-8PU AVR

single-chip. Eight-binary AVR microprocessors using the

same single-chip can avoid the complexities in the coor-

dination to develop various chips, reduce the system cost

and the difficulties in maintenance. And the pro- gram-

mers are familiar with Amega16, which is easy for de-

velopment.

P4 is the infrared pyroelectric sensor module

BISS0001 with three pins, among which the 1st pin con-

nects with the high level, the 2nd pin connects with the

single-chip PA0 as the output of the collected data, and

the 3rd pin connects with the low level. Its operation

principle is that when anyone enters its detection zone,

high level will be outputted, while anyone leaves its de-

tection zone, low level will be outpu tted automatically.

P2 is the wireless module nRF24L01, which employs

SPI serial communication to communicate with mega16.

This module has 8 pins, among which the 2nd pin con-

nects with the single-chip MISO as the SPI output pin,

the 3rd pin connects with single-chip MOSI as the SPI

input pin, the 4th pin connects with the single-chip SCK

as the SPI clock signal pin, the 5th pin connects CSN as

the SPI enable pin, the sixth pin connects with the single-

chip SCK as the mode selection pin, the 7th pin connects

3.2. Sink

Sink consists of the following components: wireless tran-

sceivers, central processing chip mega16 and Ethernet

communication module. The hardware design circuit is

shown in Figure 4.

Figure 3. Hardware co nne ction chart for sensor node.

Figure 4. Hardware connection chart for sink.

Y. LIANG ET AL.

P6 is SW5100 module with 10 pins, among which the

1st pin connects with the single-chip MISO as the

SW5100 module SPI output pin, the 2nd pin connects

with the single-chip MOSI as the SW5100 module input

pin, the 3rd pin connects with the single-chip SCS as the

low-efficient chip selecting signal, the 4th pin connects

with the single-chip SCLK as the SPI clock signal pin.

W5100 Ethernet communication module realizes the

connection with the internet and sinks through the cable.

Since there are network ports in the classrooms, this

module can be selected to reduce the changes in the

original lighting system.

4. System Software Design

4.1. Sensor Node

The followings are the functions of the sensor node.

1) The values of the infrared pyroelectric sensor and

photo resistance are collected periodically to maintain the

delay_3s_open_lam and delay_max_5min_close_lamp.

The condition of the switch can be judged through the

two values to turn on or off the light.

2) When the commands for turning on or off the lights

are given, the illumination values would be collected

again to judge if the nodes are damaged.

3) According to the commands from the sink, the

lights will be controlled or messages will be sent to sink.

The control process for the sensor node is shown in

Figure 5.

Figure 5. Control process chart for the sensor node.

Illumination intensity and the positions of the person-

nel are regarded as the basis for the system control. The

sensor nodes in the classroom are coded uniformly. Each

sensor node will detect the values of the infrared py-

roelectric sensor and photo resistance to maintain the two

delay values, namely delay_3s_open_lamp and delay_

max_5min_close_lamp. The sensor node will determine

the status of the switch from the two values to control the

switch. If the sensor node receives the commands from

sink, it will judge the command type, and the control

command will control the switch according to the com-

mand, while the query command will return to the cur-

rent status.

Among which, three problems should be solved when

employing the infrared pyroelectric sensor to detect the

position of human.

1) The perception scop e of the sensor is too large, and

the radius of the sensor which has not been treated is 4 m

(following the above designed height for the classroom).

It cannot be used to confirm the specific location , but the

perception radius can be decreased to the largest lamp

distance of 2 through adjusting the resistance value

of the module and optical lens.

2) According to the perception principle of the infrared

pyroelectric sensor, the testing basis for the human signal

is the relative movement, namely, if the human keeps

motionless, even in the perception scope, the sensor

cannot perceive, which is quite inapplicable in the class-

room. The students in the classroom cannot stay still at

any time. During the control procedure design process,

delay_max_5min_close_lamp is introduced to avoid the

misjudgment because of the stillness. If no signals for

human are detected, it will turn down five minutes later.

If the delay exhausts but there is still ex istence of human,

the delay will be updated. Then when there is a tiny

movement in the five minutes, it can be detected.

3) If nothing has been done and th ere is on e passing by,

a light will turn off after being turned on, which is un-

necessary. The twinkle of lights will be harmful to the

human body. Delay_3s_open_lamp has been introduced,

namely in 3 s continuous test, there are signals for human,

it can be confirmed that someone has stopped at some-

where instead of passing by.

4.2. Sink

The followings are the major functions of th e sink:

1) Take turns to check the sensor node, achieve the

switch status of the sensor node, photo resistance vale,

and infrared pyroelectric sensor value, update the status

information of the sensor for the maintenance on sink.

After a cycle, if there are changes in the status of the

light, it will send messages to the upper-computer. If the

query demand from the upper-computer is received, in-

formation about the status of the light and current sensor

Y. LIANG ET AL. 59

node will be sent to the upper-computer.

2) If the control command has been received from the

upper-computer, it will be sent to th e corresponding sen-

sor.

Sink will take turns to check each sensor node regu-

larly, which will avoid the collision with th e sensor node

for active uploading. There are th ree major objectives for

taking turns to check:

1) Send message to the sensor node to check if there

are any changes in the status of the lights.

2) To see if the sensor node is broken (if there is no

respond, the sensor node has been broken).

3) If commands for controlling the switch are received

from the upper-computer, then turning to check this node,

control command should be sent to the sensor node. Af-

ter receiving the command, the sensor node will send

messages for turning on or off the switch to the sink.

The sink would maintain the information for the sen-

sor node and status of the light through taking turns to

check, and changes will be updated after the check. If

there is any change in the status of the switch of the light

(including whether it’s broken), then messages will be

sent to the upper-computer, which would calculate the

lighting time according to the information. Meanwhile

the upper-machine can also check the state values of each

sensor node through these messages. The control process

chart is shown in Figure 6.

Function design for upper-computer PC serving as the

upper-c o mputer, realize the following ma j or functions:

1) Show the serial number of the sensor nodes and

sinks in the classroom.

2) Check the current status of the lights and sensor

nodes in the classroom.

3) Control the switch of the lights in the classroom.

4) Keep a record for the historical information of the

switch and calculate the electricity consumption.

Realization interface is shown in Figure 7.

Figure 6. Control process chart for the sink.

5. System Testing

System testing follows the following procedure:

1) Firstly design and realize the sensor node and sink,

and achieve success within the stated communication

scope.

2) Allocate the sensor node on each light in an expe-

rimental classroom, transform the circuit to make the

sensor node control the switch, the transmission of the

test data and test for success of the incident.

3) Arrange the sinks in a place in which all the sensor

nodes can be covered within the communication distance

of the wireless module, the sensor nodes and sinks can

work.

4) Test the communications between the sink and the

upper-computer.

5) Test the control over the switch of th e light, and test

if the upper-computer can control the switch of the light

by sending commands.

6) Overall test of the system: a person walks a distance

and sits at somewhere. In the test result, the roadside

lights passed do not turn on, while the one above the

place where the person sits turns on. When he leaves, the

light will turn down automatically. The result of the up-

per-computers is shown in Figure 8.

Suppose that the average acreage of the classroom is

100m2 and there are 15 lights. Accord ing to this calcula-

tion method, in most cases, when one enters the class-

room, he would turn on one or two lights, maybe in spe-

cial conditions he would turn on 4 lights. If several stu-

dents sit closely in the classroom, the number of the

lights would not increase. Under such condition, the

Figure 7. Display Interface for the power consumption in

each classroom.

Figure 8. Real time display of the information of the class-

room.

Y. LIANG ET AL.

illumination scope of the two lights is about 15 m2. Ac-

cording to the national standards, the illumination power

density of the classroom is about 10 W/ m2, then the il-

lumination load power about (100 m2-15 m2)×10 W/ m2

= 850W can be saved. If the normal service time is 15

hours every day (it is the worst situation, generally we

can turn off the lights in the daytime), then about 0.85

kW×15 h＝12.75 kWh power consumption can be saved

for each classroom in one day. The students will be at

school for 270 days in each year, and then the annual

saved power is about 3442 kWh. If the school has 200

classrooms, so the predicated annual saved power is

about 690000 kWh.

6. Conclusions

Compared with the tradition al energy saving control sys-

tem for the lights in the classroom, allocating sensor

nodes on the corresponding lights can help get the gen-

eral position of the human body, and then turn on the

corre- sponding lights to save the energy substantially on

the premise of satisfying illumination demand. Besides,

this design based on wireless sensor network can not

only decrease the changes in the original lighting system,

but also get prepared for the expansion of the intelligent

classroom. By adopting B-S structure, the upper-com-

puter can check the current status of the classroom online

freely. It can also know if there are broken lights or sen-

sor node in the classroom at any ti me, which would br ing

convenienc e for the maintenance work. In today’s avoca-

tion of energy saving, such low-cost and convenient en-

ergy saving system would certainly be widely used.

7. Acknowledgements

This work was partially sponsored by the Natural Sci-

ence Foundation of China (NSFC) under grant No.

60903031 and 61070022, the Teaching Reform of Shan-

dong University under grant No. 11480071188178.

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