AGENT-BASED APPROACH FOR ELECTRICITY
DISTRIBUTION SYSTEMS
Kimmo Salmenjoki, Yaroslav Tsaruk
Department of Computer Science, University of Vaasa
P.O. Box 700, 65101 Vaasa, Finland
Vagan Terziyan
Department of Mathematical Information Technology, University of Jyväskylä
P.O. Box 35, 40014 Jyväskylä, Finland
Marko Viitala
ABB Oy, Distribution Automation
P.O.Box 699, 65101 Vaasa, Finland
Keywords: Power distribution system, agent, semantic web, GUN, dashboard, SmartResource.
Abstract: This paper describes how semantic web and agent technologies could be used in enhancing the electricity
distribution systems. The paper starts by a brief overview of functioning of electricity distribution systems.
The introduced approaches aim at improving functionality of electricity distribution network systems and
assisting the experts by supporting automating of routine tasks in daily operations. We focus on GUN
(Global Understanding Environment) framework proposed by IOG (Industrial Ontologies Group) for
intelligent services on industrial resources. The resources and infrastructure of the electricity power network
are distributed. The interoperability, automation and integration features of GUN allow us to joint and
arrange cooperation among heterogeneous resources in electricity network domain. The interaction and
cooperation among resources in GUN platform are realized via resource agents. Based on discussions held
with the domain experts we also decided to use agent approach for automated collection of additional
information from heterogeneous resources and integrate this information to the operator interface
(Dashboard). This context information supports expert in decision making processes.
1 INTRODUCTION
The power electricity network is a complicated
structure and control of the networks’ processes is a
highly complicated and dynamic task. The software
engineering systems that exist nowadays provide
facilities for management of the power network. In
order to manage the power network the operator
needs to use several software systems and use
appropriate system tools according to the case
specific needs. By case we mean here a practical
implementation of a power electricity network. As a
tool to enhance the functionality of the electricity
network management systems via cooperation
among case specific software we are going to use the
latest IT solutions, such as semantic web and agent
technologies.
In the last years agent technology has been an
area of active research on the wide range of
application domains. Agents have been used to solve
different problems (Jennings & Wooldridge, 1998).
Especially agent technology was used in industrial
applications, where conventional software systems
and teams of human experts are assisted and
supported by agents to cope with the demands of
continuously changing and complex industrial
environment. Agents are helping to perform the
work of the power network operators and arrange
cooperation and communication among different
software systems.
382
Salmenjoki K., Tsaruk Y., Terziyan V. and Viitala M. (2007).
AGENT-BASED APPROACH FOR ELECTRICITY DISTRIBUTION SYSTEMS.
In Proceedings of the Ninth International Conference on Enterprise Information Systems - AIDSS, pages 382-389
DOI: 10.5220/0002350003820389
Copyright
c
SciTePress
The overall topic of using agent technology in
electricity network domain was already analyzed by
different research groups (Hines et al., 2005;
Kezunovic & Latisko, 2005). One of the frameworks
that was proposed by Cockburn is CIDIM
(Cooperating Intelligent Systems for Distribution
Systems Management) (Cockburn et al., 1992).
Their solution proposes to use the agent layer to
arrange cooperation and sharing of information
among different electricity domain expert systems.
The usage of semantic web allows to structure the
information and to represent it in machine
understandable way. The framework proposed by
IOG is to create an environment, which could unite
different industrial resources. GUN environment
(Kaykova et al., 2005) allows linking different
resources and making them co-operate. The
producers of electrical equipment have come up with
there own frameworks. ABB proposed the AIP
framework (Garcia et al., 2003).
The usage of semantic web and agent technology
can help to enhance the functionality on such areas
as fault detection and fault location. In general the
fault detection and fault location functions are
complicated tasks. In order to get accurate result a
lot of parameters need to be taken into account. In
fault detection such information as status of each
node of the electricity network, network structure
and description of the electricity network
components should be taken into account.
The results of fault location could be more
accurate, if further case related context information
could be taken into account (Tomita et al., 1998). An
example of context information could be physical
location of the network and objects nearby (forest,
lake, factory, etc.), weather conditions and other on-
going activities in the area, where the network fault
is to be located. The location of the power network
affects to fault diagnostics. In case if electricity
network has a fault and part of the network is
situated in the area nearby forest and recently there
was a forest fire, then there is a high probability that
the fault happened in that region. So, this kind of
context information provides the possibility to
enhance fault detection and fault location. The
supporting context information, which should be
used in the fault location and fault diagnosis, is
presently already available in the web, but need to
be extracted from distributed sources and converted
into semantically rich format.
The next chapter explains the basic principles of
operation in a power network. This section provides
basic information about the electricity network
management system and its operation. In the next
section we describe the set of technologies, which
should bring the added value to existing systems.
The next chapter demonstrates multi agent approach
and GUN framework in some detail. At the end of
this paper we make conclusions about the work and
point out the issues, which need to be addressed in
the future.
2 OPERATING ELECTRICITY
DISTRIBUTION SYSTEMS
The common operations for the operator of
distribution systems are: monitoring, control, fault
analysis, restoration and maintenance. In order to
access full network’s status information in existing
systems the operator requires to use several software
applications. One of the leaders in electrical
distribution field ABB company comes up with their
own tools, which may be used in other domains as
well. The monitoring and control operations are
performed mainly using MicroSCADA Pro Control
System SYS 600, whereas fault analysis and
restoration occur via MicroSCADA Pro Distribution
Management System DMS 600. In process of work
operator may need information from additional
systems. The composition of this information gives
to the user a more clear picture about the current
system status. The information from SYS and DMS
systems can be used by external application for other
purposes like energy or asset management of power
network.
Figure 1: The system and its network operator Control
Center.
The Figure 1 shows the structure of the typical
power management system and network operator’s
interface, which includes the following technical
elements: DMS 600 network diagram, Trends lines,
Event list and Process displays from the SYS 600.
SYS and DMS systems provide on-line information
about the power network status, i.e. switching state
information and network topology colored by
MicroSCADA
SYS 600
Electricity network nodes
I
DMS 600
Control Center
(Operator Dashboard)
AGENT-BASED APPROACH FOR ELECTRICITY DISTRIBUTION SYSTEMS
383
voltage level specific colors (ABB, 2003; ABB,
2005). When a fault occurs in the power network,
the situation will be indicated by these systems and
the related fault analysis can be made by the
operator.
Many of the faults in the power network are
however such faults, which do not result into a
persisting fault into the primary process. These
faults are recovered via protection algorithms of
Intelligent Electrical Devices (IEDs) in the
following way. When a fault is detected by the IED,
it performs the automatic recovery (high speed
automatic reclosing) of power network according to
the parameter setting values for protection and
control algorithm. This means that the opened circuit
breaker becomes reclosed after some hundred of
milliseconds since the original fault detected by the
IED. The trial will be used to stop the lightning in
the spark gap. If the reclosing is not successful, the
IED will try the reclosing once more, now after a
few minutes (delayed automatic reclosing). If this
second reclosing is not successful, the permanent
fault situation is indicated in the network
management systems. To analyze the occurred fault
situation from the IED point of view, requires that
the operator initiates the manual operation to extract
the disturbance recordings from the IEDs or then
they are triggered automatically by the SYS 600 file
system. The analysis of disturbance recording in a
graphical tool reveals the technical details of the
primary process at the fault time. Otherwise the
updated power network status will indicate those
areas of the power network, which have been
defected by the permanent fault.
Depending on what kind of equipment there appears
in the primary process, the exact fault location in the
power network may be calculated automatically or
then additional switching operations need to be
performed by the operator. The results of these
additional switching operations indicate the fault
location more accurately in the power network. This
iteration process is called fault isolation. When fault
isolation has been made it is time to apply
restoration operation towards the power network.
For this, different criteria for the decision making of
operator apply. As the above describes there are
evidently requirements to get the relevant
information out of the underlying devices and
different systems to assist the operator in performing
the correct actions in the different circumstances.
Next, these assistants of operator are briefly
described including their role in the electricity
distribution process. IEDs control and monitor the
primitive equipment of the power network, such as
circuit breakers, disconnectors, earth-switches and
measurements. Their primary task is to protect the
power network and perform the control operations
either launched from the IED panel or from the
electricity distribution management system.
Additionally these devices collect the information
from the power network related to the switching
states, measurements, faults and power quality
harmonics (Vattinen et al., 2005). These devices
operate and collect information on the high accuracy
level (in milliseconds). This information is then sent
to the electricity distribution system, such as SYS
600, based on the filtering definitions made during
the IED configuration. For the measurements it is
typical that only the values exceeding the configured
deadband value in device are sent to the system.
However, the switch position indications and other
process critical state changes (typically binary) are
always sent from the device to system level together
with accurate time stamps. This is because these are
also meaningful, when the changes in the process are
later on investigated from the system history
archives.
Additionally DMS contains the accurate information
on the physical power network (location of wooden
poles, cable types) and customers supplied by
specific feeders. This information is then utilized,
when DMS participates into fault location process
and provides the suggestion of restoration operations
to the operator. This functionality is based on the
SYS and DMS data exchange, and some information
is extracted from the IEDs, too. Next, the
applicability of semantic web and agent technologies
will be investigated in electricity distribution
systems.
3 ENHANCING THE
ELECTRICITY DISTRIBUTION
SYSTEMS
In the previous chapter we’ve discussed the practical
operation of the electricity network and electricity
network management systems. The present systems
provide functionality to monitor and partially detect
and locate the faults. To address the previously
described complexity in operation, we need to
exchange information and use external sources of
information, too.
ICEIS 2007 - International Conference on Enterprise Information Systems
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3.1 Software Components based
Approaches
A step towards integrating systems has already
previously been made by ABB company. The AIP
(Aspect Integrator Platform) framework provided by
ABB provides a mechanism for integration of
different layers of information systems and improves
interaction among them. The different hierarchical
levels of the enterprise processes and systems of AIP
can be seen in Figure 2 (Garcia et al., 2003).
Figure 2: The overall enterprise information systems with
its levels.
In our case enterprise here can be seen to be the
whole power distribution system with all its
automation applications. The first level contains
hardware devices, which need to be controlled (e.g.
feeders of the electricity network). The second level
includes hardware components, which collect data or
perform some actions on the process level hardware
(IEDs). IEDs contain embedded sensors and
actuators together with communication. The Group
control level includes components (hardware and
software), which provide interoperability for a set of
lower level hardware components. The Process
control level includes components for interaction
among the set of hardware components and allows
to monitor and to supervise the processes. The top
levels allow us to coordinate and integrate usability
of data between different technological and business
processes.
The AIP provides means for information
representation and navigation as well as interfaces to
connect to the actual processes. The main AIP
concepts that build up automation applications on
this platform are Aspect Objects and Object Types.
Aspects and Aspect Types are implemented as COM
components with the above hierarchical structure.
This architecture is however not fully applicable in
electricity distribution domain, but is extensively
used in the automation scenarios. At present the
interoperability between different system can be
provided by OPC (OLE for Process Control)
technology only. The main advantage of this
standard is that it already allows extraction of data
produced by various system devices. The OPC uses
XML/SOAP as a standard for communication, and
the other necessary open, web based approaches for
improving this hierarchical scheme will be
addressed next.
3.2 Web Technology based Approaches
As we showed in the previous section the growing
complexity of systems together with a wide array of
supporting web-based information calls for new
means of enabling information sharing between
applications. As has been recognized by the
technology approaches and solutions proposed
above, various interchangeable information
descriptions have to be used. XML technologies
have been widely accepted by the IT and software
vendors to be a unified information description
platform for any software. This has today been
realized in the two lower levels of Figure 2 only. In
communicating this information between
interchangeable components web services (with
SOAP, WSDL and UDDI) provide integration
means only requiring TCP/IP and HTTP/HTTPS
readiness in the interacting partners.
However to sufficiently manage and coordinate the
higher levels of Figure 2 we need to provide domain
specific metadata together with XML based lower
level description and web services. This is provided
by W3C’s open standards on semantic web. We only
note here that architecturally we can still work like
Figure 2 suggests, but by semantic web, web
services and their engineering standard counterparts
we improve the information exchangeability towards
intelligent industrial services. On the lower level of
Figure 2 semantic web proposes new knowledge
interchange standards like RDF(Resource
Description Framework), OWL(Ontology Web
Language) and their extensions that will be used
with domain specific ontologies alike IEC 61850 in
improving the integration and interoperability of
software service-type systems. In the GUN platform
these are extended to RSCDF, RGBDF and RPIDF
for generic industrial engineering processes and
service descriptions. These will enable the multi
agent solutions of GUN, which will be described in
section 4.2. More technical details for this will be
provided in next chapter and in reference (Terziyan,
2003).
To achieve this the existing distribution system
components need to be extended to expose their
information in a way that it becomes applicable for
these new modern technologies. Already now it can
AGENT-BASED APPROACH FOR ELECTRICITY DISTRIBUTION SYSTEMS
385
be seen that this improves the overall expandability
and ability to integrate overall system with other
third party add-ons and evolving industry standards
like IEC 61850. Hence the semantic web, web
services provide new added value and potential
benefits for the whole domain. In the next chapter
we show how agent-based systems can be readily
applied to provide the improved operating of a
power distribution network.
4 AGENT-BASED APPROACH
FOR ELECTRICITY
DISTRIBUTION DOMAIN
4.1 Agents in Multiagent Environment
We assume that the future electricity distribution
system uses the previous hierarchical architecture
together with open web service interfaces and a
structured and semantic description of information
contained in the engineering systems as discussed
above. A software agent in our case is any
component that can operate independently and
collaboratively with other components in the
electricity distribution system presented on Figure 1.
The IEDs discussed previously are not agents yet,
because they only work with binary data and do not
presently support the improved data standards like
XML or RDF with extensions. When several agents
exist in one system, they form a MAS(Multiagent
system). In general MAS can contain hundreds of
agents, but for our demonstration environment
(Tsaruk, 2006) we restrict only to three types of
agents, which allows us to enhance the fault
detection and detection mechanisms. The overall
goal of the agent approach is to provide automated
means to enhance the electricity distribution
systems. In the first stage agents should providing
the user additional, domain context aware
information. Later this approach can be developed
further to automate some of the operator processes
described in chapter 2.
The agent technology can bring added value to the
existing electricity network management systems.
The agent in the GUN platform is more generically a
software component, which has such features as:
reactivity, proactivity and communication. The
reactivity is a feature which allows software
components to react to the changes in the
environment. The proactivity feature makes it
possible to predict the future values of the
environment’s parameters. The agent needs to have
communication ability in order to share collected
experience and cooperate with other agents (Hines et
al., 2005). The agents collaborate and cooperate in
this multi agent environment. What these more
complicated features of agents are and how agents
can collaborate in MAS we will discuss more
precisely in follow up papers.
4.2 GUN Platform
The Global Understanding Environment (GUN)
(Kaykova et al., 2005) enables interfacing of
heterogeneous resources and arranging interaction
among them. With GUN the heterogeneous
resources (devices, services, systems, human experts
and documents) become web-accessible, proactive
and cooperative. The web accessibility feature
allows the resource to use functionality of other
resources available in the web and provide it’s own
service facilities. The agent supported resources are
able to analyze their state independently from other
system components or to acquire such analysis from
remote experts or web services. The semantic web
technology allows us to realize the interoperability
among heterogeneous resources. The usage of agent
technologies allows us to monitor and control the
status of each node in a highly distributed manner
(Wong & Kalam, 1997).
In Figure 3 the agent layer of GUN environment
takes care about realization of intelligent, proactive
and collaborative behaviour of the resource. The
adapter layer performs transformation from and to
resource specific format. The proactive feature
allows it to monitor and plan its behavior towards
efficient functioning. The cooperative feature allows
agents to collaborate and share experience with other
Figure 3: Layers of the GUN architecture: resource,
adapter, agent.
ICEIS 2007 - International Conference on Enterprise Information Systems
386
resources. The functionality of the environment is
realized using agent technology as described above.
The whole set of resources within GUN are
divided into following types: service consumers,
service providers and expert (in our case the
operator). All these resources can be artificial
(material or abstract) or natural (human or other).
The service consumers will be able to proactively
monitor their own state over time within the
dynamic environment; share experiences and
knowledge among other resources; to discover and
to use appropriate service providers in order to get
some additional functionality or information.
Industrial resources (e.g. devices, experts, software
components, etc.) can be linked to above semantic
web-based environment via adapters (or interfaces),
which include (if necessary) sensors with digital
output, data structuring (e.g. XML) and semantic
adapter components. A specific agent is assigned to
each resource and it is able to monitor semantically
rich data about the state of the resource.
This generic GUN framework can be used in various
domains. In SmartResource project the GUN
concept was used for industrial device maintenance
domain see (Terziyan, 2006) for more details. There
the GUN platform is used for constant monitoring
providing necessary maintenance of the industrial
resources. In case if experience and knowledge of a
specific agent is not enough the agent discovers
other agents in the MAS environment, which
represent other components and exchange
information to act in the processes and collaborate
on further operations that are needed.
Implementation of agent technologies within GUN
framework allows later highly distributed operation
and further system dynamics (like mobility, self
configuration and dynamic life cycle) of intelligent
service components. These can act between various
platforms using decentralized service discovery,
FIPA communication protocols utilization, and other
advanced MAS-type integration/composition of
distributed services.
In software architecture the distributed and service
based architectures are beginning to replace the
previously popular component-based approaches of
section 3.1. Overall, the semantic web technologies
provide mechanisms, which allow us to realize
seamless integration of different systems. This
provides enormous potential for integration of
different levels of enterprise processes. It provides
possibility to integrate applications of monitoring
and controlling network with business and planning.
Instead of “reinventing the wheel” the GUN
platform proposes to interconnect and interact with
systems that exist nowadays. This solution should be
suitable for both customers and producers of
electricity network management systems. The
customer gets benefits of integrating different
already existing systems without big investments
like ERP systems. This is extremely important since
industrial processes are running 24 hours a day and
it is often not possible to interrupt the process due to
change or upgrade of software. The producer should
have a chance to smoothly adapt software systems
according to demand of the market.
4.3 Applying the Generic GUN
Framework in the Electricity
Distribution Domain
The previous section discussed the general concepts
of GUN MAS environment. The overall setup of the
GUN architecture was done in Figure 3. In the
electricity distribution domain the consumer of the
service is a Device with an attached GUN agent
component (see Figure 3 and previous section 4.1).
It is important to note that the Device means both
the physical industrial hardware and its
complementary agent software component residing
in the GUN platform that will supplement the
enhanced system functionalities that will be realized
in the future. At present, the Device during its life
time works and produces online data. This data need
to be carefully collected and will only be used in our
case if the network has some symptoms of the fault
as was discussed in chapter 2. These symptoms
should be recognized locally by the IED when ever
possible. The request of the Expert(human operator)
should be sent for detail description of Device status
in the fault detection cases described in chapter 2.
As data to the Expert resource Device sends the
historical values of relevant Device’s parameters.
The process of interaction among Device and Expert
is combined by the Service component. This
component is a processing unit. Based on the
information about the network parameters and
previous decision made by the Expert the Service
via its agent is also gradually learning the inherent
logic of fault detection. When the Service is fully
learned it is able to perform similar, routine like
tasks as the Expert did originally. The scenario of
interaction among resources is presented in the
Figure 4.
Using this setting GUN framework can be used in
electricity distribution field to address a variety of
real world cases in the advanced control and
management of the power distribution networks.
The experience and diagnosis about fault detection
AGENT-BASED APPROACH FOR ELECTRICITY DISTRIBUTION SYSTEMS
387
could be shared among agents. In future, the
heterogeneous network hardware and software
systems allow us to demonstrate the interoperability
and added functionality among heterogeneous
electricity power network resources and systems.
The automation of the operator’s routine tasks will
also be later done via the previously described MAS
system using agent collaboration and learning
behaviors.
Figure 4: The scenario of interaction among resources
according to GUN framework.
According to the GUN platform interaction among
resources is organized via adapters and agents
realize the behavioral functionality of the resource
(proactive, cooperative resources’ behavior). In the
pilot demo environment the part of electricity
network (feeder) represents a device to be monitored
and maintained (against system failures and faults)
as was described in Figure 4. The architecture and
scenario of interaction among components
combining Figures 1 and 4 can be found in Figure 5.
The agent of the Expert resource interacts, collects
and integrates information from other agents. One
more function of the Expert agents will be
automation of operator’s routine work. In case if
Expert agent detects that the network operator does
the same operation when he gets a specified set of
events, next time operator gets the same set of
events the agent is going to support the user in
performing this operation in a semi automated
manner.
The additional case based information is provided by
Context Information Providers (CIP). The CIP
resources are provide context information about the
network (e.g. geographical location of the network,
weather conditions, activities in the area of the
electricity network, etc.). The CIP resource is a
subtype of Service resource. One of the examples of
such service could be a shared algorithm for fault
detection and location as a web service. Nowadays
this functionality is provided by the DMS 600
software system.
Figure 5: Architecture of multiagent electrical distribution controlling environment.
Device with
online data
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Electricity network data
exchange
ICEIS 2007 - International Conference on Enterprise Information Systems
388
5 CONCLUSIONS
In this paper we have improved electricity power
network management and control with semantic and
agent approaches. We used the general GUN
platform in establishing a future test bed for building
highly distributed and intelligent industrial control
systems for the demanding needs of the distributed
energy systems. The device agent deployed on each
node could enhance the local diagnosis done today
by the IEDs based on the shared status of the overall
electricity network(current, voltage on the power
line). The information should be provided in both
directions: import from external sources to
electricity distribution systems and export
information or functionality of electricity network
systems to systems from other domains.
Thanks to agents learning capabilities new types of
faults could be detected. The knowledge about new
type of faults and their solution could be shared
among agents because of agents’ communication
feature. The information and functionality could be
exported to the other systems using SOA (Service
Oriented Architecture). The usage of SOA allows
simplifying the integration of heterogeneous
software systems. The GUN platform used provides
a superior platform for developing next generation
engineering solutions that transform the
heterogeneous industrial resources into smart
components that enhance both the engineering and
business needs of the distributed energy domain.
ACKNOWLEDGEMENTS
The material presented in this paper was results of
SmartResource project. The authors of this paper are
grateful to all contributors of the project: TEKES,
ABB, Metso Automation, TeliaSonera. We would
like to thank for all members of Industrial Ontology
Group for their ideas, consultation and continual
support. The test bed of this project was installed in
Technobothnia research lab premises. We appreciate
the lab personnel for their assistance and support.
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