Development of Ontologies for Reasoning and Communication in

Multi-Agent Systems

Sebastian Törsleff, Constantin Hildebrandt and Alexander Fay

Institute of Automation Technology, Helmut-Schmidt University, Hamburg, Germany

Keywords: Ontology Development, Ontology Engineering, Model-driven Engineering, Multi-Agent Systems,

Cyber-physical Systems.

Abstract: In future cyber-physical systems, such as smart factories and energy grids, ontologies can serve as the enabler

for semantically precise communication as well as for knowledge representation and reasoning. Multi-agent

systems have shown to be a suitable software development paradigm for cyber-physical systems and may

play a key role in enabling future cyber-physical

systems for smart factories and energy grids (Leitao

et al., 2016; Vrba et al., 2014). Major benefits of

MASs are modularity, flexibility and robustness.

Ontologies can provide value to MAS, in terms of

serving as the foundation for inter-agent

communication on the one hand (Souza et al., 2016),

and knowledge bases that agents can use for

reasoning on the other hand (Laclavik et al., 2006;

Subercaze and Maret, 2011).

ontologies for reasoning and communication in MAS

remains an open issue as the ontological needs in

industrial applications cannot be met with existing

ontologies or even existing standardards,

notwithstanding their lack of formalization (Hodges

et al., 2017). Therefore, the authors developed the

Ontologies for Reasoning and Communication in

Multi-Agent Systems methodology (OReCo). It is not

designed to act as a standalone MAS development

2018). Key features of OReCo are the integration

model-driven engineering artefacts, the utilization of

existing ontologies to reduce engineering effort, and

the integration into the popular MAS development

environment JADE

ontology development and ontology utilization. The

former is the subject of this paper. The latter deals

with actual implementation tasks related to the

utilization of developed ontologies in MASs and will

more specifically the OWL 2 DL profile. Note, that

this deviates from prominent definitions of the term,

which do not imply a representation language or

degree of formality, e.g. (Uschold and Gruninger,

1996). Only in some cases we use the term “ontology

in the broadest sense” to refer to the full spectrum of

conceptualisations as defined in (Lassila and

McGuinness, 2001). Occasionally, we use the terms

“lightweight ontoloy” and “heavyweight ontology” to

differentiate between human-centred UML class

diagram representation and machine-readable

representation based on OWL 2 DL, respectively. The

communication and reasoning in MASs for cyber-

physical systems that are developed using model-

driven engineering methodologies will be referred to

as the “application domain” of the methodology from

here on. Specific desired solutions, e.g. a distribution

grid automation solution, we refer to as “use cases”.

follows. In section 2 we present requirements

regarding the development of ontologies in the

application domain that have been gathered from

industry. Afterwards, in section 3, we provide an

analysis of related research and discuss in how far it

withstands the requirements we identified. The

methodology itself is presented in section 4 and

preliminary evaluation results regarding its

application in a smart energy grid-related research

project in section 5. Conclusions and an outlook on

with involvement from industry partners in the

research project CrESt

3

(Collaborative Embedded

Systems), some of which originally were presented in

(Hildebrandt et al., 2018b), others were added in the

meantime.

Identifying requirements is the first step in ontology

development. As in software engineering in general,

requirements are a key determinant for successful

is the model-driven engineering of MASs. Thus,

diagrams that specify the message exchange and

internal program logic of agents are available. These

are valuable artefacts with regard to the ontology

requirements and implicitly contain all intended uses

of the ontology under development. Accordingly, we

define the utilization of such artefacts as a

requirement.

ontologies for a specific use case, it is desirable to

Accordingly, ontology modularity represents another

requirement.

rooted in the fact that ontology experts usually do not

have the necessary knowledge to model the required

domain knowledge for a specific use case. Therefore,

domain experts who possess the necessary domain

knowledge have to take an active and central role in

ontology development.

class diagrams are not as expressive as heavyweight

ontologies, they help to conceptualize domain

knowledge transparently. This facilitates the

integration of domain experts in ontology

development (see R4). For this reason, we define the

of existing ontologies (in the broadest sense)

whenever reasonable. This ranges from industry

standards as the basis for concept definitions to

integrating existing heavyweight ontologies. The

utilization of ontologies with varying degrees of

expressiveness requires their integration at different

stages of the development cycle.

for reusable, modular ontologies necessitates a

defined ontology bridging procedure to connect

decision to develop a new ontology development

methodology.

scope is determined by the design of the system under

development. That is, if the system design poses

specific requirements, the ontology has to satisfy

these requirements. An iterative-incremental

approach for the ontology development would thus be

inappropriate. This does of course not inhibit an

iterative-incremental approach being applied to the

overall system under development. In such cases,

multiple iterations of the OReCo methodology would

be driven by the enclosing development methodology

and decidability (Hitzler et al., 2010), the OWL 2 DL

profile can be considered the default implementation

language for ontologies developed using OReCo.

The specification of ontology requirements is partly

based on the NeON methodology (Suárez-Figueroa et

al., 2009). Some of the tasks in the ontology

requirements specification according to NeON can be

omitted, since their results are the same for any use

case in OReCo’s application domain.

in Table 2. Further tasks of the ontology requirements

specification according to NeON have been modified

the requirements discussed in section 2.

processes artefacts from model-driven engineering,

i.e. the system design comprising UML diagrams

such as sequence diagrams (covering the message

exchange between agents) and activity diagrams

(covering the internal application logic of agents).

These diagrams are annotated with competency

questions (CQs) and answers using a custom UML

profile, which facilitates their automated export into

a tabular representation including a reference to the

methodology has been omitted. This is due to the fact

that the intended uses are already given by the system

design.

deals with aspects that are not covered by CQs, e.g. a

specific ontology naming convention or the

mandatory use of industrial standards. The latter

could result from the system design, e.g. if a agent

interacts with a technical system that requires the use

of a specific protocol. Non-functional requirements

Group Requirements. Useful groups are subdomains

such as technical properties of a battery storage or

generic concepts such as units of measure. Further

grouping may be performed in case of agents

requiring very specialized knowledge. Such groups,

by facilitating ontology segmentation, can help

reduce the TBox size (and thus inprove the reasoning

performance) of agents with distinct knowledge

verifiable, understandable, unambiguous, concise and

modifiable. Guidance on how to evaluate these

criteria are provided in (Suárez-Figueroa et al., 2009).

An additional criterion is wether a requirement is

implementable, e.g.. if a CQ can be answered with an

ontology. This characteristic has been added since

non-ontology experts might add CQs that cannot be

covered by an ontology with reasonable effort. In case

of invalid requirements, step 1.1 and/or 1.2 of the

methodology have to be revisited (not depicted in

as per the NeON methodology has been omitted. This

is based on the rationale that the ontology under

development serves as an enabler for reasoning and

communication in the system under development as

prescribed by the system design. This means that any

determined in step 1.3.

In step 1.5 Extract Glossary and Synonyms, the

foundation is laid for the subsequent analysis of

existing ontologies. The glossary comprises three

parts. The first part shows terms and frequency based

on the CQs, the second one based on the related

answers, and the third part identifies objects that can

be seen as instances of other classes. Additionally,

synonyms are recorded for each glossary term to

facilitate the survey of existing ontologies. The final

The conceptualization stage begins with step 2.1

Analyse Existing Ontologies. In this step, the

ontology and domain experts first perform a survey to

identify suitable ontologies (in the broadest sense)

based on the glossary developed in step 1.5. This will

result in a pool of ontologies (in the broadest sense)

potentially ranging from plain dictionaries to

heavyweight ontologies. Ideally, the survey yields a

set of heavyweight ontologies that satisfy all

requirement (CQs and non-functional). In that case

Ontologies. Here, domain experts, supported by

ontology experts, conceptualize an ontology

addressing the remaining CQs as a UML class

diagram. We recommend performing this step with

the concept of so-called content ontology design

patterns in mind (Hitzler et al., 2016). These are small

modular and extendible ontologies which can be used

in multiple use cases. This approach is specifically

useful for industry standards that have a high

likelihood of being reused, but also in cases where

instance, consider a network topology ontology for

energy grids that can be extended for the domain gas,

electricity etc. Further orientation marks with regard

to the segmentation of the lightweight ontology

implementation task are given by the requirement

The last stage of the development begins with step 3.1

Implement Heavyweight Ontologies. Inputs for this

step are the pre-selected and newly implemented

lightweight ontologies as well as the ontology

requirements specification. The latter provides

information not included in the lightweight

modelling in OWL can be found in (Pinto et al.,

2004).

Figure 2 shows an exemplary scenario in which the

overall ontology under development comprises three

TBoxes that are being used by two distinct agents. In

this scenario, Agent1’s knowledge base imports

TBox1 and TBox2. Accordingly, “TBox bridges”, i.e.

TBox statements that connect existing TBoxes, are

required between TBox1 and TBox2 as well as

between TBox2 and TBox3. These statements are

symbolized by the white lines within the agent’s

knowledge bases. Technical alternatives and

guidance on how to bridge ontologies can be found in

(Hodges et al., 2017).

Figure 2: Exemplary utilization and bridging of TBoxes in

different agents.

Step 3.2 Bridge Heavyweight Ontologies deals with

integrating the resulting heavyweight ontologies. A

key determinant of this step is the utilization of these

ontologies by the agents, which is captured in the

the CQs identified earlier. The results of the query

need to be consistent with the respective answers of

each CQ in order for this step to succeed. Otherwise,

step 3.1 or 3.2 have to be revisited.

5 EVALUATION

This section deals with a preliminary evaluation of

the proposed methodology and its satisfaction of the

requirements presented in section 2. The use case for

the evaluation was a MAS-based low-voltage

distribution grid automation solution that had been

developed in Agent.HyGrid

possible to group the identified CQs based on their

attribution to agents. For instance, one group

comprised CQs focussing the grid topology and was

only relevant to one agent, while another group

adressed the flexibility of distributed energy

resources, which multiple agents exchange

information about. This provided the foundation for

the concurrent execution of subsequent

conceptualisations and underlines the methodology’s

flexibilities could be identified by the domain experts

in step 2.1, they modelled a lightweight ontology

flexibility ontology is now used by all agents, the grid

topology is only used by one agent, which

demonstrates the advantageuousness of the ontology

6 CONCLUSIONS AND

Ontologies have the potential to significantly reduce

the engineering effort required in MAS development.

the first part, which is unique in addressing

requirements specific to this application domain.

While providing significant value in its current state

already, additional research is required to improve

a systematic survey of existing ontologies in the smart

grid space. The results of this survey will serve as the

foundation for a software tool that supports ontology

and domain experts in the development process by

providing recommendations for reuse of existing

ontologies based on the glossary in step 2.1 Analyse

Existing Ontologies.

also result from ongoing and planned evaluation

Sturm, A., Shehory, O., 2014. The Landscape of Agent-