GREEN AGH CAMPUS
Tomasz Szmuc
1
, Leszek Kotulski
1
, Bartosz Wojszczyk
2
and Adam Se¸dziwy
1
1
AGH University of Science and Technology, Department of Automatics, al. Mickiewicza 30, 30-059 Krak´ow, Poland
2
GE Energy, Atlanta, U.S.A.
Keywords:
Green AGH Campus, Smart Grid, Intelligent Lighting.
Abstract:
Smart grid systems are the response for the growing global energy demand and the environment protection
concerns. To obtain all profits from a smart grid solution, its development has to rely on technical issues
but also on an active participation of a system end users. In this paper we present an overview of the Green
AGH Campus project which is based on advanced technologies tested in other similar projects. Its innovation
is combining the role of a fully functional smart grid solution with educational features and the potential of
replicating obtained results in other environments. The intelligent lighting system is also discussed as the most
developed part of the Green AGH Campus.
1 INTRODUCTION
The Green AGH Campus smart grid project was
started by a consortium which initially consists of
AGH University of Science and Technology, General
Electric Energy and Marshal’s Office of the Malopol-
ska Region. Members of the consortium represent
academia, research, development, industry and mu-
nicipality.
AGH University of Science and Technology is
the leading Polish technical university (Webometrics,
2012) with 38,000 students of nearly 200 specialties
within 50 disciplines. Its graduates work in the elec-
tronics and telecommunications industry, companies
designing and installing systems and computer net-
works, making equipment for large corporations, e.g.
automatics and robotics systems or specialized mea-
suring and medical equipment, also in firms offering
new telecommunications services, such as multime-
dia communication systems. (AGH UST, 2012)
The profile of the University and careers of its
graduates make us expect that starting the Green AGH
Campus project for educational goals will propagate
positive attitudes toward energy usage and manage-
ment among professionals.
General Electric Energy being the part of GE com-
pany consists of the following divisions: Energy Ser-
vices, GE Oil & Gas and GE Power & Water. It is
active in such areas as energy production, distribution
and management, renewable energy sources or the re-
utilization of water. The GE Energy, which partici-
pated in numerous smart grid projects, ensures tech-
nological background of the project.
The Marshal’s Office of the Malopolska Region
being the third partner of the project, represents mu-
nicipal organizational units. Its experience will allow
to migrate the Green AGH Campus as a scalable solu-
tion to other communities interested in achieving eco-
nomic profits.
2 SMART GRID PROJECT
EXAMPLES
Growing global energy demand and associated
growth in energy prices but also planned reduction
of CO
2
emission stimulate development of the range
of methodologies and technologies related to energy
production and distribution.
Smart grids which are oriented for those goals al-
low achieving them by reducing energy usage, obtain-
ing energy from renewable sources, developing en-
ergy storage methods or linking small suppliers to the
energy grid. The following proof of concepts regard-
ing smart grid solutions should be presented here.
Amsterdam Smart City which includes multi-
ple initiatives like West Orange (400 households with
new energy management systems), Climate Street
(smart meters and plugs, energy saving lighting) or
ITO Tower (sensor-based lighting, heating, cooling,
smart plugs).
159
Szmuc T., Kotulski L., Wojszczyk B. and S˛edziwy A..
GREEN AGH CAMPUS.
DOI: 10.5220/0003979101590162
In Proceedings of the 1st International Conference on Smart Grids and Green IT Systems (SMARTGREENS-2012), pages 159-162
ISBN: 978-989-8565-09-9
Copyright
c
2012 SCITEPRESS (Science and Technology Publications, Lda.)
The GE smart grid demonstration project on Maui
Island, Hawaii, based on the U.S. Clean EnergyTech-
nologies Action Plan. Key objectives of the project
include effective management of renewable gener-
ation based on a distribution management system
(DMS) platform, demand response and integration of
energy storage.
BedZED in Hackbridge, London, England. The
general assumption underlying this housing develop-
ment was using renewable energy only, produced on
site by solar panels or co-generation plant. Addi-
tionally the energy efficient materials and technolo-
gies were applied. All energy saving steps reduced
the power usage by 25% compared to the average for
United Kingdom.
3 GREEN AGH CAMPUS
In the Green AGH Campus project we would like
to adopt best practices applied in developing exist-
ing smart grid projects. We will focus on developing
methods that will promote effectively smart grid solu-
tions in environments for cities or larger regions. Two
barriers may be identified here:
1. the lack of professionals who can create such so-
lutions,
2. the lack of a public demand for their implementa-
tion (mainly due to the weak awareness of poten-
tial benefits).
Localization of the project at the university campus
solves both problems as it is explained later on.
Our basic goal is to prepare the environment
which allows both researching (in terms of using
modern energy technologies) and demonstrating it to
students in the real micro-world.
So-called control room enables us to research
modern solutions including integrated approaches to:
• energy efficiency and application of low emis-
sion technologies (e.g. renewable energy sources,
electric vehicles, etc.),
• optimal management of an integrated system and
technologies for creating NegaWatt zones,
• combining technical/economic value and the end
user,
• transforming managed data into information ap-
plicable in an effective management of advanced
NegaWatt functions and moving clients from
the consumer role to the prosumer (producer-
consumer) one,
• cooperation with DSO’s for the active participa-
tion in the energy market,
• knowledge exchange, testing modern solutions
and optimizing-operational processes,
• broadly defined intelligent networks (creating
sand-boxes), and the work management and op-
timization,
• power grids with active (controllable) generation
and customer load.
The overall architecture concept will be based on
scalability, interoperability and availability through
open-standard design and common information
model (CIM) based integration.
The control room is an essential element of the
teaching process at our university. The idea of this
system is based on two optimization subsystems. The
first one, incorporating the concept of DMS-based
shadow environment (Fig.1), will optimize costs of
energy consumed while keeping the maximum level
of the energy reliability and security. The second sub-
system is focused on the optimization of the energy
consumption by local entities like student dormito-
ries, didactic buildings or outdoor lighting.
The data gathered from the system will be used
as an input for simulations which, will allow students
who explore smart grid solutions, to discover conse-
quences of control decisions made by them.
The solution development will rely on intelligent
management systems (DMS), monitoring (smart me-
ters) and automatics which cover smart buildings, in-
telligent lighting systems, energy storage, control-
lable energy receivers and so on. Besides the con-
ventional energy sources, combined heat and power
(CHP) and photovoltaic (PV) technologies will be
used. Green AGH Campus components will be in-
tegrated using electrical grid and computer network
(HAN/LAN) which enable remote monitoring, con-
trol, securing and other tasks.
Initially six buildings are designed to be cov-
ered by the project: four dormitories, one smart grid
compliant university building and the swimming pool
complex. Additionally the outdoor lighting is as-
sumed to be the component of the smart grid as well.
Each dormitory will be equipped with a building
management system (BMS) supporting both energy
service and detailed accounting of energy consumers.
The new idea is to develop the dedicated customer
relations management (CRM) system that will teach
users how to save the energy and/or decrease a hous-
ing fee. Learning the economic energy management
generates not only temporary effects (i.e. current sav-
ings), but also long term ones. Let us notice that dor-
mitory residents leave it after a few years, and next
they may become natural ambassadors of the smart
grid technology. This perspective gives the hope to
SMARTGREENS2012-1stInternationalConferenceonSmartGridsandGreenITSystems
160
break the mentioned second barrier of the smart grid
technology development.
It should be remarked that the swimming pool
may play yet another role in the project besides being
the next building incorporated into the Green AGH
Campus, namely it may be used as an energy storage.
The lighting system of Green AGH Campus will
be designed to meet the following two requirements:
improving public safety and decrease the operational
costs. This part of the project as the most matured
part of the solution will be discussed in more detail in
the next section.
In this project we have paid the special attention
to computer systems which are used to both intelli-
gently control system’s behavior and gather data con-
cerning processes being performed. Obtained infor-
mation will be stored in data repositories which allow
data mining. That will help improving quality of the
smart grid system control. Selected parts of those data
will be distributed to third parties which can simulate
and verify the possibility of applying some smart grid
sub-solutions in their environments. Thus the second
goal of the Green AGH Campus project, i.e. establish-
ing scalable, interoperable platform enabling energy
suppliers integration, will be achieved. The system
scalability allows future Green AGH Campus growth
and, on the other side, adapting it to other environ-
ments. The important feature is the system accessi-
bility which will be accomplished by minimizing in-
vestment costs, making the solution be within reach
of potential investors. It is planned to replicate the
solutions tested in the project in other local govern-
ment units. The main objective is to optimize energy
management.
Expected added values of the Green AGH Campus
solution are:
• improved safety of the system and the people,
achieved by implementing intelligent, reactive
systems of control and monitoring,
• effectiveness and lower exploitation costs
achieved by intelligent power control, energy
saving technologies but also by changing users
attitudes,
• environmental protection achieved by using envi-
ronment friendly technologies (e.g. LED lamps)
and renewable energy sources and by decreasing
the power consumption.
4 LIGHTING
The intelligent lighting system (ILS) is the important
element of the Green AGH Campus. The ILS aim
is twofold: increasing the quality of public spaces in
particular by improving the personal safety and de-
creasing exploitation costs related to the illumination.
The first goal may be accomplished by analysis of
a behavior of inhabitants e.g. using models describ-
ing the dynamics of pedestrians (Wa¸s, 2010). Re-
sults of such an analysis allow for correlating ILS per-
formance with expected behaviors of pedestrians and
preparing predefined lighting profiles suited for vari-
ous environment states. Decreased illumination costs,
being the second objective, is achieved by using en-
ergy saving technologies (e.g. light emitting diode -
LED) and intelligent control adapting the system per-
formance to actual needs.
The LED technology creates possibility for
preparing lighting solutions satisfying design require-
ments and standards (Institution of Lighting Engi-
neers, 2005) and on the other side capable of adapting
to changing conditions of an environment. Taking the
advantage of the second property may impact an en-
ergy consumption and related costs.
Managing the intelligent lighting system includes
two aspects: 1) preparing a suitable distribution of
lamps and 2) providing an intelligent control of a sys-
tem. Both questions addressed below.
A primary objective of a light designer is secur-
ing the illumination of public spaces at the night time
as well as preserving the energy efficiency and econ-
omy of solutions so that staying and moving in these
spaces could be safe and comfortable. The basic goal
of an artificial illumination in the urban area is to
guarantee its safe usage and supporting the space ori-
entation.
A lighting design process is constrained by ar-
chitectural assumptions related either to aesthetic or
functional demands, compulsory standards like EN
13201 or CIE 115:2008 and implied energy con-
sumption (e.g. see (Institution of Lighting Engineers,
2005)). The first constraint takes into account such is-
sues as the safety of the people or enhancing the ori-
entation ability in an urban space. The second one
defines requested properties of an illuminated area. It
should be remarked that such a characteristic is given
by a set of lighting profiles corresponding to vari-
ant validations of predefined configurations of such
parameters as daylight level, actual traffic intensity,
weather conditions and so on (Fig. 2).
The ILS control acts based on data received from
sensors and on a selected lighting profile.
The common issue related to both the design and
the control of the ILS is their high computational
complexity. The simple example illustrating the prob-
lem’s order of magnitude is the number of possible
GREENAGHCAMPUS
161
Figure 1: Example of localized control system ”Shadow Environment”.
Figure 2: Exemplary city area with corresponding lighting
profiles.
states for a row of ten LED luminaries when each
lamp may work at ten luminosity levels. Such a sys-
tem may take 10
10
states.
To overcome the computational complexity re-
lated problems a formal representation of a system
has to be introduced. A graph model of an urban
space coupled with distributed, agent-based compu-
tations paradigm are applied (see (Se¸dziwy and Ko-
tulski, 2011)). The control system is supported by
distributed rule based Artificial Intelligence systems.
5 CONCLUSIONS
The Green AGH Campus combines the most inno-
vative smart grid solutions tested in other existing
implementations with the educational features of the
university. The preliminary analysis of the first phase
of the project (in particular development of the light-
ing system) shows that the system complexity forces
using advanced computer science technology based
on Artificial Intelligence. On the other side these
AI-based methods support scalability of the system.
Scalability and open-standard design of the solution
will enable its replication to other environments.
REFERENCES
AGH UST (2012). AGH UST - facts and figures.
http://www.agh.edu.pl/en/university/about-us/agh-ust-
facts-and-figures.html.
Institution of Lighting Engineers (2005). Outdoor Lighting
Guide. Routledge, 1st edition.
Se¸dziwy, A. and Kotulski, L. (2011). Solving large-scale
multipoint lighting design problem using multi-agent
environment. Key Engineering Materials, 486:197–
182.
Wa¸s, J. (2010). Crowd dynamics modeling in the light of
proxemic theories. In Proceedings of the 10th in-
ternational conference on Artifical intelligence and
soft computing: Part II, ICAISC’10, pages 683–688,
Berlin, Heidelberg. Springer-Verlag.
Webometrics (2012). Ranking of World Universities, Jan-
uary 2012. http://www.webometrics.info.
SMARTGREENS2012-1stInternationalConferenceonSmartGridsandGreenITSystems
162
