Semantic Analysis and Complex Networks as Conjugated Techniques

Supporting Decision Making

Pedro Ivo Lancellotta, Victor Ströele, Regina Braga, José Maria N. David and Fernanda Campos

Post-Graduate Program in Computer Science, Federal University of Juiz de Fora, Juiz de Fora, Brazil

Keywords: Business Intelligence, Complex Networks, Data Visualization, Decision Making, InfoVis, Ontology.

Abstract: The expansion scenario in information technology has led to the need for the analysis of huge amounts of data

to manage information for quick decision making. This paper presents an architecture for data visualization

that uses semantic and structural interpretation as conjugated techniques for data analysis in different domains,

through an interface which supports visualization strategies. A case study was carried out with a specialist in

makes manual analysis a complex activity. The main

objective of Business Intelligence (BI) is to support

decision making, reduce costs, optimize work

efficiency to improve process management (Popovič

et al., 2013). Among the techniques to support BI

decision-making are Data Mining, Panels, Reports

and Data Visualization (Ranjan, 2008).

The use of data visualization techniques, or

information visualization, helps the cognitive process

in data interpretation and knowledge discovery (Card

identification of more appropriate visualization

techniques for specific datasets, and the reduction in

the amount of information displayed for a greater

abstraction of information, assisting user perception

(Jonker et al., 2013).

Among the efforts for the interpretation and

semantic data analysis, we can highlight the use of

ontologies, which have been applied in several

domains (Miah et al., 2007) (Zillner et al., 2008) (da

Silva & Cavalcanti, 2014) (Liu et al., 2016).

When defining an ontology for a domain, the

relationships between the domain interest individuals

and their characteristics, or in a simplified way, the

actors that interact in the domain of application are

identified. Thus, it is possible to delineate this

ontology in the form of a network, representing

individuals and their relationships (Heim et al., 2010).

allow a more effective visualization of intrinsic

relationships of data, observing the connections

Several works use ontologies and complex

networks individually to provide interpretations of

the data, but few explore both together. This paper

explores the combination of ontology techniques and

complex networks using them together, to

complement the information on each one in an

automated or semi-automated form.

Ontologies are able to offer benefits to complex

networks, such as (i) Abstraction of network nodes

with the use of inferences (ii) Aggregation of

semantic values for the data network (iii)

Classification of individuals, identifying semantic

groups that can be analyzed separately. On the other

hand, the complex network can also benefit the

ontology, such as: (i) Identification of new groups of

individuals, based on the analysis of ontology entities,

enabling the creation of other groups with similar

The main objective of this paper is to present an

architecture that defines the necessary components

for the visualization of information and support for

decision making. The architecture uses ontologies

and complex networks in a conjugated form,

supporting visualization for decision-making.

To evaluate the technical feasibility of the

architecture, a visualization platform was developed

to support the components of the proposed

architecture. In addition, in order to evaluate whether

semantic and structural data analysis (ii) Use of

ontologies and complex networks as conjugated

techniques in order to improve the interpretation of

strategic data (iii) Development of an ontology in the

agricultural context, related to dairy control, and (iv)

Development of a visualization platform to support

decision making.

The paper is organized as follows: Section 2

details some related works. In section 3, we present

the architecture. Section 4 presents a use case with

of data visualization. We reviewed works that use

information visualization, such as Business

Intelligence techniques, to support decision making.

We filtered the works that mainly use semantic and

complex network analysis as an approach,

contributing to the interpretation of information and

strategic analyzes for datasets in any domain.

Analyzing huge volumes of data is a challenge in

many research areas. Some research works, focus on

reducing the amount of data that will be available in

the visualization (Gu and Wang, 2011).

Ontologies have the ability to aggregate semantic

creating a unified and consolidated concept of the

target domain (Jayaraman et al., 2013).

The use of complex networks allows a structural

investigation of the data, so that it is possible to

identify individuals who are more influential in the

network as well as their intrinsic relationships (Lopes

et al., 2010). Still according to (Lopes et al., 2010), in

order to identify important individuals within the

network, complex network metrics are used, such as

node degree, centrality, among others.

Some studies use ontologies and / or complex

network metrics to better visualize data and identify

important elements for analysis (Queiroz-Sousa et al.,

2013) (Ströele et al., 2017), and the creation of

visualization tools that behave in an automated or

semi-automated way (Sobral et al., 2016). However,

few studies use these techniques in conjunction with

data interpretation (Heim et al., 2010). Others only

use different views on data (Dörk et al., 2012) (Radics

et al., 2015) (Soklakova et al., 2016).

one complements the information of the other. This

enables the development of a visualization platform

capable of inferring new information and rules about

a set of data analyzed in an automatic or semi-

automatic way.

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managers in making strategic decisions that lead to

higher quality and productivity. A conceptual

architecture that supports decision-making is

proposed which can self-feed and produce new

information. The general objective of the architecture

is to enable data visualization and interpretation from

a specific data source from the semantic and

occurs according to the following steps. Initially, (i)

data is collected from one or more repositories of the

same domain (ii) these data are organized, translated

into the ETL layer and then imported into the

ontology, in which some domain rules are defined

(iii) from the defined domain ontology, it is translated

as a network, showing the main relationships between

the main actors that constitute the application domain

(iv) finally, a complex network is modeled with the

individuals of the domain. In this network, the

identify new rules or groupings.

The ETL layer is responsible for extracting,

transforming and loading data for later processing.

Data repositories can come from several different

sources, but all of them refer to the same application

domain, or at least have data related to the domain.

load the ontology with the individuals, according to

the domain rules. The main functionality of the ETL

layer is the ability to interpret data from different

repositories to a consolidated and well-defined data

This section presents an initial evaluation of the

proposed architecture, which was made from the first

version of the information system for decision-

making support. The objective of this evaluation is to

answer the research question considering the use of

the proposed solution in a real-world context.

The evaluation method adopted in this paper is

based on a case study carried out in the context of an

agricultural research company with real data

extracted from dairy cattle production. A case study

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A survey reported by MilkPoint (https://

www.milkpoint.com.br) highlights the managerial

aspect as the major limiting factor in milk production.

There is a lack of approaches that assist the managers

in the visualization of data on this field (Miah et al.,

2007).

The evaluation scope was defined based on the

GQM method (Basili et al., 1994) with the "purpose

of characterizing the effect of semantic and structural

as aggregated techniques, combined with

visualization techniques support decision-making?

To collect evidence and respond to the proposed

research question, direct observations and interviews

were used as data sources.

This section describes the semantic and complex

network analysis obtained from the analyzes

performed in the developed system. The interpretable

elements, observed from the use of ontologies and

found that used ontologies that represent the process

of milk control and quality from dairy cattle.

Therefore, an ontology was created using Protégé

(protege.stanford.edu). The creation of this ontology

was done with the help of specialists in the area of

agricultural research to better detail the process and

their needs. The ontology created has a total of 30

classes and 41 logical rules. The classes of Institution,

RegionalCenter, Coordinator, Consultant and

Producer represent managerial aspects and classes,

context, it is possible to associate semantic analysis

with managerial processes.

Initially, a comparative analysis was performed

through tables in relation to managerial data. The

domain specialists observed the hierarchical

relationship between some entities (Regional Center,

Coordinators and Consultants). Without the use of

ontologies, only the inter-relationships between

individuals was identified. Due to the data set

volume, it is costly to perform joins between these

data in order to identify the attributes and their

associations, allowing specialists to analyze only

the production values of all properties served by

management entities were associated. As a result, it

was possible to make previously complex

observations, such as identifying the production of

properties served by a specific Regional Center.

For the definition of levels of abstraction and

structural analysis a complex network was modeled

considering the relationships between the individuals.

The management network aims to visualize the mean,

total or other aggregations on the values related to the

With the help of this network, the specialist was

able to analyze which farms produce more milk for a

Regional Center chosen by him/her according to

his/her needs of analysis and decision making

used, there are two main networks that make up the

system: management and milk production. The

analyzes made by the specialist which focused on the

study of the managerial network (Figure 2) were

composed of the following entities: Institution,

institutions, the visualization of the network is

compromised according to the volume of data

presented to the user. The objective is to highlight the

entities that serve farms with a higher milk yield.

For this, the complex network metrics defined

above are used. It was observed that nodes with

greater closeness centrality are related to more Farms

or with more Entities. Thus, comparing the entities of

the greatest influence on entity and / or property

management. Thus, when measuring the minimum

paths between regional centers and farms, it was

possible to identify which entities are present in these

paths, showing that this entity manages a greater

range of other entities and properties.

in the abstraction of the managerial network. With

this abstraction, the manager is able to briefly

visualize the measures identified with the total

influence more, considering the productivity of a

certain regional center or any other entity that one

wishes to take as the central element of the network.

The reduction in the number of nodes represented on

the screen (Figure 2) facilitates the visualization by

the business managers without compromising the

information contained in the complex network.

Finally, this case study demonstrated the use of

the first version of the system for visualization and

decision making that covers semantic and structural

aspects of the data. All the actions carried out in the

can be highlighted.

helping in the decision-making process?

“These charts enabled me to do an immediate

analysis of the production of specific farms

comparing to a national scenario, presenting

information that supported me in the decision-making

process with the milk producers”.

(II) How do you evaluate the use of different visual

(III) Is it possible to analyze data from different

institutions and their contribution to national cattle

production?

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us to identify and to compare the different entities in

relation to its productivity. This is a good

contribution of the system for data analysis”.

the information presented in the visualization artifacts

provides better awareness, so that dairy institutions

can help milk producers in the administration of their

herds and farms. According to the second answer,

there is evidence that the components used helped

decision making. However, it is still necessary to

integrate these components. The third answer showed

that the use of semantic analysis and complex

networks as conjugated techniques can help in

decision-making process.

observed (i) the specialists' interactions with the

Considering these points, it is possible to affirm

that there is evidence that the semantic and structural

analysis of the data, together with visualization

techniques are able to aid in the decision making,

adding more information to the data. However,

further case studies should be carried out for a wider

evaluation of the proposal.

As threats to the validity of this case study we

can cite the reduced number of participants. Through

the evaluation it was possible to state that these results

ontologies as conjugated techniques to support the

decision-making process for business managers. The

networks provides a semantic and structural analysis

of the data, so that the visualization strategy brings

forward additional information from the data used. A

classical problem in analyzing complex networks is

the amount of information presented to users. In this

abstractions in the network, so that it is possible to

omit some nodes without the loss of important

information for decision-making. Complex networks

also collaborate in the creation of new logical rules

for the previously defined ontology.

A first version of the system was developed, and

a case study was carried out with the purpose of

evaluating the architecture. The use of ontologies and

addition, adopt new metrics to support the analyzes

related to the complex networks and identification of

new logical rules.

REFERENCES

and Computer Graphics, 17(12):2015–2024.

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