Sustainable Computing and Communications
Internet Broadband Network of Things Applied to Intelligent Education
Y. Iano
1
, I. T. Lima
2
, H. J. Loschi
1
, T. C. Lustosa
1
, O. S. Mesquita
1
and A. Moretti
1
1
Department of Communications, State University of Campinas, Av. Albert Einstein, 400. Campinas-SP, Brazil
2
Department of Electrical and Computer Engineering, North Dakota State University
1411 Centennial Blvd, ECE 101E, Fargo, ND, U.S.A.
Keywords: Smart Cities, Internet of Things, Intelligent Education and Broadband.
Abstract: Intelligent cities may be defined as territories characterized by a high capacity of learning and innovation,
comprising in its structure the “Internet of Things”, developing, therefore, the creativity of its population, its
institutions of knowledge generation and its digital infrastructures to communication and management of the
knowledge. This structure has a great performance in the role of digital inclusion, allowing the possibilities
to integration, social well-being promotion (e-inclusion), supplementary education (internet toward software
application with great capacity to education) or in distant (e-learning) and professional development.
Multimedia communication, it may reach the most remote points and be available full-time, benefiting, in
addition, students with deficiencies and walking limitation to go to school, or with special needs of
differentiate teaching to educational development, creating and promoting the intelligent education. The
main Target to develop this study is to present a solution to network service bandwidth, considers media
world speed and projects the implementation of GPON (Gigabyte-capable Passive Optical Networks)
technology in access optical networks in the Brazil. Presenting an outcome comparison analysis obtained
from the project performed to implement in Holambra city, São Paulo, Brazil, relating to the perspectives
and standards of connectivity in the use of broadband networks in the world, showing the viability in the use
of such modern technologies in the GPON broadband.
1 INTRODUCTION
The new forms of knowledge need a suitable
broadband network connection. Digital activism has
reached the streets in cities all over the world, and
much of its proliferation took place through social
networks disclosure (Gorshe et al. 2014) (Lekamge
& Marasinghe 2013). Recent past has revealed that
people have new forms of organizing themselves,
either in teaching institution, in clubs, in open
spaces, etc. Applications such as Facebook, Twitter,
YouTube and WhatsApp, collect and send data in
real time and help to improve considerably the
aspects of modalities (Saad & Khan 2013).
Public environment are entirely responsible for
the evolution of its citizen. As we understand better
the behavior of the citizen from the intellectuality
extracted from collected data, for example, through
social networks, public architecture shall become
more communicative and provides better conditions
of connectivity and intelligent education (Fortino &
Trunfio 2014) (Jin et al. 2014). In this context
motivating, intelligent education is characterized by
the change of the educational environment,
generating individualized, active, flexible and
collaborative learning, with frequents use of tables
and applications and digital contents, that is what we
can call them up school without walls (Imrattanatrai
et al. 2014) (Majumder & Saha 2014).
Technological advance has changed computational
capacity and expanded the possibilities to be use and
applications to a horizon of immeasurable
perspective when everything is connected properly
and efficiently (McEwen & Cassimally 2013)
(Guinard et al. 2011).
Intelligent city presents as one of its features the
connectivity and communication between the several
devices (Jin et al. 2014). This ability allows us to
understand the contents and behaviors of people,
process information and share data in real time,
allowing a better use of resources. The way the
350
Iano Y., T. Lima I., J. Loschi H., C. Lustosa T., S. Mesquita O. and Moretti A..
Sustainable Computing and Communications - Internet Broadband Network of Things Applied to Intelligent Education.
DOI: 10.5220/0005447303500356
In Proceedings of the 4th International Conference on Smart Cities and Green ICT Systems (SMARTGREENS-2015), pages 350-356
ISBN: 978-989-758-105-2
Copyright
c
2015 SCITEPRESS (Science and Technology Publications, Lda.)
distribution of digital content and education must go
through a revolution as profound as the industrial
revolution and the multimedia industry has recently
suffered (Pfister 2011) (Downton 2008).
In the context an example of this constant change
in network traffic management systems, the
evolution of new models of sensors (inductive,
position, capacitive, magnetic field, ultrasonic,
photoelectric, identification, positioning, vision,
security, etc.) and the network infrastructure
allowing a better quality of the connections as well
as their management through the routers that connect
networks in the cities (Gaglio & Re 2014). This
fulfills the need for adequate connectivity applied to
smart education in line with the changes in more
flexible structures (Perera & Zaslavsky 2014)
(Bessis et al. 2012).
To allow this kind of behavior, you need to
invest more in networks and high-performance
equipment, so in our study we use the GPON
technology, a concept of smart cities, enabling better
connectivity of users to a smart education
environment.
The motivation to develop this study is to present
a solution to network service higher bandwidth at
the best rate recorded worldwide (Thompson et al.
2014). This solution considers media world speed
and projects the implementation of GPON
technology in this scenario.
After analysis in previous studies (Mesquita et al.
2013) updated and expanded deployments recent
information these networks, comparing trends of
these technologies applied to Internet of Shings
Worldwide, focused on smart education (Oliveira
2014).
2 BROADBAND
TECHNOLOGIES IN BRAZIL
Current broadband technologies have impairments
regarding the features in its architecture. Finding
architecture with a suitable solution may be a
thorough engineering project, wherein we have to
take into account many interfaces and factors that
are engaged on the study. Decisions must be taken
with certain care so that the network cost is not out
of financial provisions and hinder its
implementation, being, thus, necessary to consider
characteristics of some network technologies
(Gorshe et al. 2014) (Mesquita et al. 2013).
We may mention PON (Passive Optical
Network) comprising the EPON (Ethernet Passive
Optical Network) or GPON network (Gorshe et al.
2014).
Such equipment technologies are
commercialized in a wide range with definite
parameters. Among the main manufactures and
researchers of such technologies, we can highlight:
CPQD (Centro de Pesquisas e Desenvolvimento em
Telecomunicações | Research Center and
Development in Telecommunication), Padtec
(Produtos de Alto Desafio Tecnológico | High
Technological Challenge Products) e CIANET
(Mesquita et al. 2013).
In GPON networks comparing to EPON, we
have:
Advantages
They are run in different rates of
downstream and upstream;
• They work in various transceivers systems
with low cost, low maintenance and a
network of easy operation and maintenance
together with competitive costs of
equipment;
Can take advantages from the laser ONT
decrease in the costs when asymmetrically
set.
Warranties of interoperability with ONT
(Optical Network termination) with a
management standard in the service level.
Disadvantages
Complexity in their encapsulation model
layers;
Ethernet / GEM / GTC have a very
complex management;
It is more expansive when compared in
comparable rates with EPON technologies.
Due to advances and evolutions of studies in
these technologies, it is possible to be found in
scientific documents enhanced parameters regarding
the aforementioned, that has been exceeded
continuously for academic experimental work
(Mesquita et al. 2013).
3 EVOLUTION OF THE SPEED
OF THE BROADBAND
NETWORKS
In the technological framework and broadband
services recent studies disclose the "State of the
Internet" report that lists the average speed of the
fixed Internet connections of each country in the
world in megabytes per second (Mbps). In 136
SustainableComputingandCommunications-InternetBroadbandNetworkofThingsAppliedtoIntelligentEducation
351
countries evaluated, the global average is 4,6Mbps,
so the global average connection speed had a
significant growth in the second quarter of 2014,
increasing 21% and passing well of 4Mbps the first
time (Thompson et al. 2014).
On a global scale, the fastest Internet in the
world is South Korea with an average speed of
24,6Mbps followed by Japan (14,9Mbps),
Netherlands (14,3Mbps), Hong Kong (15,7Mbps),
Switzerland (14,9Mbps), Czech Republic
(12,6Mbps), Sweden (13,6Mbps), Ireland
(12,6Mbps) and United States (11,4Mbps)
(Thompson et al. 2014). See the complete data in
Figure 1:
The numbers are disappointing in relation to
Brazil, which is in 84th position in the ranking. The
national average speed of the Internet in Brazil is
2,9Mbps, for the last three months of 2014. In the
analysis Brazil was the smallest country to increase
the average speed in the measured period, an
acceleration of only 0,2%. Reflecting a decrease of
four positions in the world ranking (Thompson et al.
2014).
The speed is constantly increasing among the ten
countries with the highest average speed of the
internet, however it is important to highlight the
Uruguay as the country with the highest annual
growth rate that consists of 197% thus reaching the
average speed 5,6Mbps (Thompson et al. 2014).
Figure 1: Average internet speed fixed broadband world (Thompson et al. 2014)
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4 DEVELOPMENTS OF THE
GPON PROJECT
Project was based on a Telecommunication
infrastructure consisting in a mixed network of
optical fiber and radio projected to an urban area that
has a relief differentiation, i.e., straight part and high
part that will be integrated by GPON technologies to
attend ten (10) points. 80% of the network will be
attended by optical fiber and 20% with radio
network in Wifi technology. The remote points will
be attended with a transferring rate of 300 Mbps,
aiming to attend close to 100% of the project
(Gorshe et al. 2014) (Mesquita et al. 2013).
The infrastructure of these technological
solutions is the next-generation to attend the
educational institutions who want to use
technologies such as: Broadband Internet, Video
Conferencing, VoIP (Voice over IP), CCTV (Closed
Circuit of TV), IPTV, distance learning through an
integrated solution of high capacity based on
innovative technology of networks that is the focus
of this work. In this project, we have a distribution
of network to attend clients of the chosen test bed
(Gorshe et al. 2014) (Mesquita et al. 2013).
From a financial point of view we have to take
into account equipment costs and physical facilities
to be carried out, for this investment Capex concept
was used that joints the cost of capital, also known
as fixed assets; and for the installation operations,
network maintenance and skilled labor, used the
Opex concept, which includes variable expenses,
unfixed, called passive (Mesquita et al. 2013).
To the ROI (Return of Investment) we will use
further the Payback calculations. The total
investment of this project is composed of the
network infrastructure of optical fiber and radio,
included the civil works and the acquisition of all
Epon or GPON equipment, since these devices are
not equivalent in terms of performance and cost
(Gorshe et al. 2014) (Mesquita et al. 2013).
We also take into account the need to carry
equipment inventory to be sold to customers to
receive the signal of the technologies under study. In
every project we have to have a preparation of an
investment proposal, where our goal is to seek
product innovation to pent-up demand solutions for
broadband in the whole country (Gorshe et al. 2014)
(Mesquita et al. 2013).
To the investment project assessment Method:
The value of a company depends on its future cash
flow. Thinking about this matter, we elaborated the
Figure 2 with comparison of the initial investment of
the technologies in study (Gorshe et al. 2014)
(Mesquita et al. 2013).
Figure 2: Sales estimate for project implementation.
Making analysis of GPON solution, we found that
the GPON network solutions can integrate a
complete architecture of broadband services, which
can be designed to meet the fixed-mobile network
convergence requirements, thus offering resources
that can support the broadband access and, in this
item, we have the next-generation services and
connections, allocating resources through OLT
(Optical Line Termination), network converters,
posts for receiving switch, splitter, network cables
(fiber, coaxial network cable RG11, cat network
cable. 5) splitters and ONU (Optical Network
Unit)performance functions of multimedia
conversion (Gorshe et al. 2014).
The data that makes up the prices are relative:
the optical network to GPON equipment and the
funding for project implementation.
It was planned to carry out the deployment Pops
10 (Points of Presence), each of which is composed
of Pop central and terminal equipment. The amounts
used are hypothetical, close to reality. The project
composition also had to estimate indirect costs
consist of expenses: the need to contract for labor
(vendors, operators, attendants), product marketing,
advertising and media. These expenses are necessary
to start the operation of the network when deploying
on call service (Mesquita et al. 2013).
For a real analysis, it is necessary to obtain the
values of each equipment performing a RFP
(Request For Proposal), which is the RFP performed
through a process executed by the contracting
company, so that potential suppliers can tender
business with at least three (3) equipment suppliers
(Mesquita et al. 2013).
It is important to highlight that for the technological
development of the country, both the private sector
and the government should be aligned in the search
for digital inclusion as well as the industry's
innovation. In the project, we elaborated a table of
the total value of the network where the investor can
immediately view the disbursement of Capex and
Opex for both active and passive systems. The total
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353
value of the investment addressed in the composition
of the initial investment Figure 2 presented the
following data for analysis: Capex for investment
and Opex for equipment maintenance, (we use
standard 10% value). The table 1 shows an
investment analysis considering the values for
decision making using the concept of PAYBACK
and VPL (Net Present Value). (Gorshe et al. 2014)
(Mesquita et al. 2013).
The Figures 3 and 4, respectively present a
comparison between the costs involving revenue
generated and fixed expenses of EPON and GPON
projects (Mesquita et al. 2013).
Figure 3: EPON_Receipts x Expenses.
Figure 4: GPON_Receipts x Expenses.
5 ASSESSMENT OF THE
OUTCOMES
Total costs of an fixed Internet service available by
an International provider involves three shares
related to the following stages (
Oliveira, Á., 2014):
GPON access network;
Main trunk link that connects the access
network to the router at the nearest
providing international station;
Table 1: Investment analysis of technology EPON and GPON.
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Interconnection of the international
provider to the router linked to the
backbone of the global Internet.
The price for the service mentioned above is
USD 7.115,00 monthly for a real and constant
transfer rate of 10Gbps. It is worth saying that the
approximate price per Mbps is USD 0,7115 monthly
(
Oliveira, Á., 2014).
Given the growing interest in video streaming 4k
("Ultra HD") it becomes important reference it with
a metric. It is known that the ultra HD video content
has adaptive bit rate, thus requiring the transmission
of your data in a broadband service that provides
enough bandwidth for the actual speed between 10
and 20Mbps (Thompson et al. 2014).
6 FUTURE CONTRIBUTIONS
It is being developed an analysis proposal to the
implementation of a new architecture of intelligent
cities with a network to support the demand of
around 30.000 users. The study will be based on the
project developed and planned by VIVO mobile
phone company in the city of Águas de São Pedro,
State of São Paulo, and by the city hall of the city of
Rio de Janeiro where there is an integration project
of the Marvelous City. At first in our analysis
proposal, we chose UNICAMP (Figure 6, included
in the appendix) (Federal University of Campinas).
7 CONCLUSIONS
The available real transfer rate of 40Mbps (Mesquita
et al. 2013) has a purchasing value of USD 30,12
monthly since the 1Mbps speed matches the monthly
fee of US$ 0,7115, so there is the viability of the
broadband Internet service in these parameters
(
Oliveira, Á., 2014)..
The highest average speed of the world
broadband fixed Internet consists of 24,6Mbps
referring to the country of South Korea, thus we
overcome in capacity and quality the
aforementioned speed with the proposal made viable
at constant rate, i.e., not shared at 40Mbps. This last
case study enables, among other 100% guaranteed
flow of data with video content 4k emerging interest
which is not necessarily the case with Internet South
Korea that has world supremacy as the average
speed of Internet as to fully the ultra hd video traffic
requires a broadband Internet service that provides at
least a constant rate of 20Mbps. It is important to
remember that only our case study made possible
offers constant speed against the other only
guarantee the average rate of data transfer. See the
Figure 5 showing comparative analysis of the case
study with Akamai data (Thompson et al. 2014).
Figure 5: Comparison analysis.
Internet of things allows multimedia resources,
classes and conferences on distance, turning this
way the learning easier, including in a more
interactive and didactic way. Expenditures for
transporting the student and the teachers are
considerably reduced this way.
Students’ safety is intensified. Time saving is
sharp. These are some of the resources and
advantages that an intelligent city provided thought a
broadband network with more capacity and quality,
suitable for the connectivity for the internet of
things.
In this context, this innovative form of rational
use that takes hold of all the resources of the
available technology aiming to improve teaching,
characterizes what we can define as intelligent
education.
Digital inclusion brings numerous possibilities
for integration, promotion of social well-being (e-
inclusion), supplementary education (internet toward
software application with great capacity to education
and to e-learning) and professional development of
the students. The new educational trends include
digital technology to provide better training and
more appropriate qualifications for education.
The former view of teacher on the board or only
textbook, no longer meets the expectations and the
new way of learning in this generation, totally
dependent on the use of multimedia and the ability
to access to the internet of things. With the evolution
of telecommunications networks and the
implementation of optical fiber networks in urban
and rural access, we can improve education.
SustainableComputingandCommunications-InternetBroadbandNetworkofThingsAppliedtoIntelligentEducation
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The effective application of these technologies
depends on techno-economic factors where often the
financial interests go beyond the actual demand.
We conclude that a scenario of the best
investments and costs of broadband network
implementation becomes more convenient to the use
of the GPON equipment due to investment values
and more attractive costs.
The applications of broadband current
technologies are essential and necessary for the
citizens, especially the distance education. This
work aims to contribute to the discussion the
creation of new mechanisms and methods to be
developed in order to facilitate access to quality and
speed to broadband services.
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APPENDIX
Figure 6: Unicamp University City Area.
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