d2kg: An integrated ontology for knowledge graph-based representation of government decisions and acts

2.1.Governmental–public organizations ontologies/vocabularies

Several ontologies (and vocabularies in the fashion of LOV [23]) related to public organizations have been developed to reflect the specificities of national public organizations and institutions of a given country in terms of their structure and operation.

Nevertheless, the aforementioned ontologies are focused on the procedural aspect, legislative (cabinet or parliamentary), governmental or administrative (nomenclature of public documents) and the interactions between actors involved in terms of their positions and functions. They are also customized to the organization they are built for or developed solely in the native language (Spanish, French). They neglect or partly accommodate though important aspects such as the financial aspect related to public money/resources use, as well as transparency and accountability which are fundamental for implementing open governance. Their main deficiency is that they only partially re-use standard ontologies and vocabularies components and they mostly construct their own classes and properties which are frequently limited in scope to the requirements of a given organization and country. On the other hand, the best practice would be to focus instead on re-using commonly agreed widely adopted standards at EU level, towards interoperability, which is the main aim of our work, too. Next we delve into this aspect.

2.2.ISA² – core vocabularies

The “Interoperability solutions for public administrations, businesses and citizens (ISA²)” Programme, supporting the development of digital solutions enabling administrations, enterprises and citizens in Europe to benefit from interoperable cross-border and cross-sector public services,1515 developed the EU core vocabularies.1616 The core vocabularies can serve as the tool to harmonize data representation in a comprehensive manner. Core vocabularies are simplified, reusable and extensible data models that capture the fundamental characteristics of a web resource, an entity, such as a Person or a Public Organisation for instance, in a context-neutral manner, abiding by the Linked Data principles. Moreover, core vocabularies promote the use of common identifiers for organisations, people and locations in the form of Uniform Resource Identifiers (URIs), can be easily combined with other Linked Data vocabularies, and are extendable with new classes and attributes to fulfill new domain requirements.1717

The most important core vocabularies developed under ISA² so far are the following:

2.3.The organization ontology

The W3C Organization ontology1818 contributes as the main ontology for organizational structures, since it is designed to allow domain-specific extensions to add classification of organizations and roles. It is designed to enable publication of information on organizations and organizational structures including governmental organizations to provide a generic, re-usable core ontology that can be further extended or specialized. This proves fit for the purpose of information extraction from government decisions/acts to identify the main actors and contact persons.

2.4.E-procurement ontology

A significant part of documentation at EU level is related to financial transactions. In this context, the procurement process holds a prominent place (Public procurement represents around 20 % of GDP in Europe). Therefore, the EU is investing significantly on the digitisation of the public procurement process (e-procurement). The procurement procedure itself can be quite complex involving many actors and discrete phases end to end, i.e. from notification, through tendering to awarding, ordering, invoicing and payment. This in turn implies variable requirements to cater for different entities and their interrelationships. This triggered the effort to establish several procedures and standards at EU legislative level (indicatively Directives 2014/24/EU, 2014/25/EU and 2014/23/EU establish rules for public contracts, design contests and concessions, whereas Directive 2014/55/EU defines the requirement for a European standard for electronic invoices, and the Commission Implementing Regulation (EU) 2015/19866 specifies standard forms for the publication of notices in the EU Official Journal1919).

Given the increasing importance of data standards for e-procurement, there is a number of initiatives driven by the public sector, the industry and academia over the recent years, with a diversity in terms of the vocabularies and the semantics that they are introducing, the phases of public procurement they are covering, and the technologies they are using. These differences hamper data interoperability and thus its reuse. This creates the need for a common data standard for publishing procurement data, hence allowing data from different sources to be easily accessed and linked, and consequently re-used. Hence, an ontology of the Public e-Procurement (ePO)2020 was developed to act as the common standard on the conceptual level, based on the main stakeholders consensus and designed to encompass the major requirements of the e-procurement process complying with the aforementioned EU Directives. Its goal is to formally encode and make available in an open, structured and machine-readable format public procurement data, to unify existing practices to make it easier to share, access and re-use data.21212222

2.5.Diavgeia Programme

At national level, in Greece, a good showcase is Diavgeia (“Diavgeia” (‘Διαυ´γεια’) is the Greek word for Transparency). Diavgeia is a Programme introduced by Law in 2010 obliging Public Organizations to post their decisions and acts on the Web. Each document is digitally signed and assigned a unique Internet Uploading Number (IUN) of primary importance, since it operates as a sole reference code certifying that the decision has been uploaded on the respective Diavgeia Portal. Moreover, what makes this effort valuable is that administrative acts and decisions are not considered valid unless published online [22]. This enhances significantly the usability, applicability and role of the Programme in the sphere of Public Administration, which is further exploited as source of data for privately developed applications. The Diavgeia Programme is considered an Open Government Best Practice, received very positively both at national and European level [10]. Overall, a significant number of acts and decisions have been published on the Portal, reaching 50 million during its operation to-date, whereas as the rate of uploads has reached 28 thousand decisions per working day.2323

3.1.Use cases

One should focus on real applicable use cases, independently whether this involves a Knowledge Graph or the respective ontology. The added value we try to bring in is to further elaborate on valuable practical Use Cases for the end user, be it a public servant or a citizen in a wider sense engaging in public policies, combining the deployment of standard ontologies and core vocabularies, following to a great extent the EU standardization so as to enable interoperability.

Use Case 1: Transparency/Accountability in public money/resources spending

Accountability for the allocation of public money or – in general resources – at national and EU level is the driving force to develop tools for monitoring the money flow. A characteristic use case is to identify the recipient organizations-economic operators of public money. Diavgeia, as the main repository for decisions related to the procurement procedures in Greece, is an important source of information. Related Diavgeia decisions/acts can help us identify the recipient contractors, the volume of awarded budget, the frequency of awarded contracts to specific economic operators so as to establish potential patterns in the awards or even suspicion of preferential treatment. The latter applies also for recruitment of personnel.

Use Case 2: Publicity in public spending

A use case focusing mostly on the publicity requirements related to the (pre)award procurement. It is necessary and legally binding in most cases through established procedures at EU and national level that contracting authorities-public organizations announce and publish the calls for tenders to economic operators, citizens and third parties. Essential piece of information consists of the type of procurement procedure, i.e. open/closed tender, selection and award criteria to be fulfilled by the candidates, a potential break down in tender lots, if applicable. It is also of primary importance that public organizations can be timely and effectively reached to provide feedback on procedural issues. Therefore, Contact Points’ information should be available in all possible means of communication (email/telephone/postal address/contact persons) and in this sense modelled by an underlying system (ontology).

Use Case 3: Efficiency of the decision-making processes

In decision-making processes knowledge is the foremost element that contributes to well-informed results. If we are interested in financial transactions, we could further orient our search accordingly. Thus, to obtain an overview of public resources allocation one could be oriented towards cumulative information. To elaborate on critical financial information, the available data can be further broken down to actual budget categories to identify where public money is spent, i.e. to which kind of goods, works, consumables, services etc. This can be done by retrieving related Diavgeia Award decisions in order to identify the different procurement types which are already classified base on the Common Procurement Vocabulary (CPV) values. In the same manner, one could be interested in specific information concerning personnel appointment/recruitment, such as the type/category of personnel appointed or the frequency of appointments. In terms of its internal functioning, an organization could collect data for statistical reasons (for instance, the average number or duration of public Contracts) to assess the efficiency of its organizational units.

In the Diavgeia platform knowledge extraction is currently performed in two ways: firstly, by a keyword search (either basic or more advanced using multiple criteria) based on the encoded metadata and secondly via an API to query over the metadata. In both cases metadata is encoded by public servants with no uniform approach. This fact leads to significant discrepancies between the decisions/acts textual and metadata information. Therefore, the platform does not allow the translation of use cases such as the above to inputs producing outputs suitable to the end user needs. In our work, we use Competency Questions (CQs) to translate use cases in ontology requirements.

3.2.Competency questions

Given a set of scenarios related to the application field, developers should be able to place a set of questions stated in natural language representing users demands and translated in SPARQL queries to support the development in:

- Enabling developers to identify the main entities and their relationships to create the ontology vocabulary;

- Providing developers with a simple means to verify requirements’ compliance by either knowledge retrieval or by entailment on its axioms and answers checking [3].

Therefore, we identify domains of interest and develop questions, as analysed in Section 5, that will drive the identification of the appropriate ontology components and facilitate their implementation into a new ontology.

Use Case 1: Transparency/Accountability in public money/resources spending

Use Case 2: Publicity in public spending

Use Case 3: Efficiency of the decision-making processes.

This list of CQs is built around the most characteristic thematic categories of decisions and acts. It represents a non-exhaustive list customized to the needs of the end user or the organization and thus drives the knowledge extraction process. One can further elaborate on combinations of the above queries to build additional competency questions.

3.3.Diavgeia documents analysis

This section presents a Diavgeia sample document analysis. For instance, if we are interested in the appointment (recruitment) in public organizations in terms of transparency this relates to UC1/CQ5 and in terms of efficiency to UC3/CQ3. A reference document, as published on the platform related to the appointment (recruitment) of personnel to a Greek Ministry, is presented in Fig. 1. The document is depicted below annotated to describe both the extraction of critical information from Diavgeia docs (highlighted in color) and subsequently the mapping of this information data to the actual classes and properties (in boxes) from standard ontologies and vocabularies or new ones created in d2kg for the purpose of responding to the UCs/CQs developed.

Fig. 1.

Diavgeia sample doc in focus.

3.4.Ontology built-up

Based on a typical document we can practically fit the corresponding entities to the appropriate pieces of information within the document. We perform the translation of the main document elements in ontology terms, i.e. via their classes and the object and data properties used to interrelate and describe them. That means identifying which components of standard ontologies can be integrated to map them to the information included in the Diavgeia documents. This is the common approach followed for a set of documents through the new integrated ontology built-up.

For instance, the document selected (Fig. 1) is broken down in three main Parts (A, B, C) according to a typical document layout. We highlighted the main document elements (in Greek) representing valuable knowledge and provided next to them the corresponding actual related classes/properties from standard ontologies with their prefixes (in English) or the prefix d2kg: for our new ontology. We can extract Organization’s related data from Part A/upper left corner. It is issued by a m8g: Public Organization (class), the ‘HELLENIC MINISTRY OF DEVELOPMENT AND INVESTMENTS’ (‘ϒΠΟϒΡΓΕΙΟ ΑΝΑΠΤϒΞΗΣ ΚΑΙ ΕΠΕΝΔϒΣΕΩΝ’ in Greek). We identify the internal hierarchical structure of the Ministry comprising a GENERAL DIRECTORATE (‘ΓΕΝ. Δ/ΝΣΗ ΔΙΟΙΚΗΤΙΚΩΝ ϒΠΗΡΕΣΙΩΝ’), a DIRECTORATE (‘ΔΙΕϒΘϒΝΣΗ ΔΙΑΧΕΙΡΙΣΗΣ & ΑΝΑΠΤϒΞΗΣ ΑΝΘΡΩΠΙΝΟϒ ΔϒΝΑΜΙΚΟϒ’) and a DEPARTMENT (‘ΤΜΗΜΑ ΚΙΝΗΤΙΚΟΤΗΤΑΣ ϒΠΑΛΛΗΛΩΝ’) and we see how these are interrelated via appropriate object properties (org:hasUnit/org:unitOf of the Organization ontology). Further down within Part A, we can extract data for the Contact Point (class epo:ContactPoint) ‘Πληροφορι´ες’ in Greek and how this is reached via the appropriate object properties such as epo:hasPostalAddress, and data properties epo:postCode, epo:hasTelephone, epo:hasEmail, eli:date_document, dvg:protocol_number, etc. It is interesting to note that in most cases the classes and properties are self-explained in the sense that their naming is quite straightforward.

Part B constitutes the main part of the document comprising the vital information. For this appointment decision, for the term identifying the appointment (‘προσλαµβα´νεται’ in Greek) we needed to create a new object property d2kg:appointedIn, and for the Rank (‘Βαθµο´ Β’ in Greek) the data property d2kg:staffRank, etc.

In the concluding part C, the classes org:Post, org:Person are necessary to identify the Signer, while object properties such as epo:isSignedBy, epo:heldBy and data properties such as epo:hasFullName, epo:hasGivenName, epo:hasBirthFamilyName are used to retrieve a variety of RDF triples. The document also includes on the right upper corner its unique Identifier assigned by the platform Diavgeia mapped to the data property dvg:iun.

In summary, we followed the aforementioned approach for a set of documents. To construct our integrated ontology, we started off from the directly competing Diavgeia ontology as the basis, trying to re-use on the one hand existing classes, object and data properties, and on the other hand enrich it with others from widely used standard ontologies and vocabularies already conforming to commonly agreed standards at EU level, with the objective to significantly enhance its functionality and re-usability. The object properties have been extended by 2.85% and datatype properties by 2.46% (ratio of sum of new and existing to existing properties). These rather low ratios indicate the high re-usability of existing standards, which was the primary objective of this work. To this end, we applied the basic principles of linked open data development according to the W3C guidelines2828 for establishing the framework for high quality linked open data, we developed our integrated ontology and subsequently built a Knowledge Graph in the domain of interest, government decisions/acts encoded in Diavgeia Platform.

4.1.The d2kg ontology

Fig. 2.

Representation of the d2kg ontology.

A graphical UML like representation of the main entities and their relationships of the integrated ontology d2kg is provided in Fig. 2. This representation gives an outlook of the developed ontology highlighting characteristic components of the current implementation, that is several of the most frequently used classes, data and object properties.

At the level of the main ontologies and vocabularies, the ISA core vocabularies are shown in green, the ePO in orange and the Diavgeia ontology in grey, whereas the controlled vocabularies in blue. The blue continuous lines show existing object properties representing domain-range classes relationships, whereas the purple dashed lines indicate new domain-range relationships between classes established locally with the re-use of existing or new object properties and black dashed indicate inferred sub-classes. Data type properties are represented via the preceding + symbol inside a class box. The class sub-class relationship is typically depicted via a black one-directional arrow connecting the two entities, but occasionally sub-classes are contained under the class within the same box (like in the case of a characteristic one: Document). The reason for the latter is to include as much information as possible in this representation, since the ontology includes numerous entities and relationships. For instance, the property ‘hasProcurementValue’ indicates a domain-range relationship between a Diavgeia decision of class type dvg:Award and the class type epo:Value, whereas we can infer that m8g:Public Organization is also a sub-class of an org:Organization. It is evident that the focus is on the re-use of existing classes, object and data properties from standard ontologies, along with additional ones for the purpose of extracting valuable information from Diavgeia decisions and acts. The majority of data and object properties derives from the ePO and the Diavgeia ontology.

In practice, the d2kg ontology is built in OWL by integrating components from various ontologies and vocabularies – by importing them via their URIs – released in OWL too, as well as limited components from SKOS used for notation/labeling, together with controlled vocabularies incorporated as instances to enable re-using their set of values to address use cases (end user) requirements. In this respect the respective different naming conventions according to their origin for entities representations are adopted in the d2kg ontology. Characteristic entities imported in d2kg per originating ontology are detailed in the next sections. We describe the re-used entities per ontology, introducing the most characteristic new ones we developed in separate distinct sub-sections.

The d2kg ontology, in this respect, is a unique integration of existing ontologies combined with core and controlled vocabularies developed based on EU standards. It provides a customized solution to abide by the requirements of the Greek platform Diavgeia, re-engineering the respective Diavgeia ontology and binding it with standard ontologies, proposing a solution to encode government and administrative decisions/acts that could be universally adopted to integrate public documents produced by other EU Member States, with certain adjustments content-wise.

4.2.d2kg controlled vocabularies

Apart from the appropriate classes, object and data properties, it is significant to introduce re-usability with regards to the terms used by the actual data incorporated via instances. This is possible through controlled vocabularies ensuring a standardized approach concerning the terms that correspond to predefined values for these properties. This is the point where the EU vocabularies are introduced.3333

4.3.URIs

The format of the URIs is differentiated depending on the actual usage of the entity. Concerning the main entity Legal Resource, we adopted the Persistent URIs approach of the Diavgeia ontology to comply as much as possible with common requirements.4646 The decisions/acts are structured according to the ELI rationale template: http://www.diavgeia.gov.gr/eli/<iun>/<version>. Modifications of a decision result to a new URI with the same <iun> and a new <version> number. Regarding other types of entities, though, the Greek government Diavgeia platform has determined a way to uniquely represent them according to an XML schema4747including the most important data and providing an available HTTP URL to look it up. The templates of the most important entities are:

Fig. 3.

Greek government Diavgeia XML representation of a URI for an organization.

5.1.Debugging

To assess the d2kg ontology we deploy initially Protégé, the tool used to develop it. We assess the possible faults in the ontology via the ‘Pellet’ reasoner and the installed ‘Debugger’ plug-in. The debugging shows that no faults occur during this validation process and no repairs are suggested for the ontology. The ontology proved to be both consistent and coherent. The default configuration for the debugger was selected delivering an error-free ontology.

OOPS! also provides an indicator for each pitfall, according to the classification of possible negative consequences (critical, important, minor) [17]. In the case of d2kg, OOPS! detected several pitfalls; however, all critical or important ones derived from the imported ontologies implementation (for instance, missing domain or range in properties, missing annotations, defining wrong inverse relationships etc) and not related to our implementation.

5.2.Reasoning

Pellet and Hermit reasoners were used to retrieve additional knowledge through inference. The default configuration for both reasoners was selected with all available checks enabled, which computes inferences on class (checks for equivalent, disjoint classes, super-classes, classes instances), object properties (checks for equivalent, inverse properties, super-properties, domains and ranges) and data properties (checks for domains, equivalent properties) along with individual inferences (object and data property assertions). Notice that the inferences are used merely for the verification of the ontology. In the actual application, only inferences related to triplestores (i.e. rule-based OWL 2 RL) are relevant for the completeness of answers to SPARQL queries. Inferences provide an insight of the data encapsulated in Diavgeia documents. A concrete example of a Declaration Summary document (iun:‘Ψϒ1ϒ46ΜΤΛ6-ΛΩ3’) is used. Apart from the predefined classification of the document as Declaration Summary, we infer the following class types based on domain/range constraints.

- Award Criterion: derived from the object property “hasAwardCriterion” present in the doc text and related to the value ‘Cost’. Therefore, the Reasoner yields the corresponding class type ‘Award Criterion’ for this property.

- Contract: implying the assignment of a Contract as a result of the object property: “hasContractNature type” and its corresponding value ‘Supplies’, revealing the class type ‘Contract’.

- Procedure Type: The procurement procedure type is identified as ‘Open’ through the use of the respective object property: “hasProcedureType” encoded in the document.

- Opening Term: the information on the Opening date and time is provided via the respective data property: “hasOpeningDateTime” and its corresponding value ‘2022-01-2022T15:00:00’, helping us to identify this class type.

The inferred concepts (types) produced after Reasoning proved to be sound, complete and meaningful, since it is anticipated that for this type of act to retrieve relevant information for the type of contract that is going to be assigned, its award criterion, the type of the procurement procedure deployed to award the contract etc.

5.3.Ontology metrics

In terms of the main ontology metrics we initially proceed with Protégé metrics. A summary is depicted in Table 1(a) below, with the figures being representative of the d2kg ontology’s size. These figures show the collection of a significant number of classes, properties and a high number of axioms (since it includes the combined logical and non-logical axiom count) as a result of the integration of numerous standard ontologies and vocabularies and the high number of populated instances. In the d2kg namespace we have defined 13 object proporties, 8 datatype properties and 148 instances.

To evaluate also the domain coverage we deployed the online platform OntoMetrics [15]. An overview of the main metrics is presented in Table 1(b). The assessment is based on ontology’s accuracy and conciseness. The first three metrics refer to the ontology’s accuracy, while the other two refer to its conciseness. We note the following:

- A high attribute richness value (the average number of attributes per class, giving an indication of both the ontology design quality and the amount of information pertaining to instance data). The high value is anticipated due to the integration of numerous ontologies in a single schema;

- A good coverage in the range of concepts illustrated via the inheritance richness value (the average number of sub-classes per class describing the distribution of information across different levels of the ontology’s inheritance tree). This measure can differentiate a horizontal ontology (where classes have a large number of direct sub-classes) from a vertical ontology (where classes have a small number of direct sub-classes). In our case, a balance is achieved to cover on the one hand good range of concepts without, on the other hand, going into a highly detailed analysis of their sub-traits;

- A balanced relationship richness close to 50% (the ratio/percentage of the number of (non-inheritance) relationships divided by the total number of relationships which reflects the diversity of the types of relations). An ontology containing only inheritance relationships conveys less information than an ontology that contains a diverse set of relationships;

- A satisfactory value for the average population. Formally, the average population is defined as the number of instances of the knowledge base divided by the number of classes defined in the ontology schema, providing an indication of the ontology population quality.

The DL expressivity is classified as SROIN(D), derived via both Ontometrics and Protégé, which indicates the support of Transitivity, Role chains, Nominals, InverseOf and Cardinality restrictions. The d2kg ontology corresponds to the OWL 2 DL profile.

6.1.A knowledge graph representation for the Greek Programme Diavgeia

The Diavgeia typical appointment document we used already in Section 3.4. can be visualized in the form of a Knowledge Graph via Ontotext GraphDB.4848

Fig. 4.

GraphDB visualization for the Diavgeia sample in focus.

In Fig. 4 we can identify all core elements of this sample decision (properties with their labels). Indicatively:

- the corresponding decision ID (IUN): ‘6ΤΚΕ46ΜΤΛΡ-ΙΓΕ’ in the center;

- the decision type: ‘Appointment’ – in purple on the left hand side;

- the Organization which creates/issues the decision and appoints the Person, right next to the decision ID in red: the ‘HELLENIC MINISTRY OF DEVELOPMENT AND INVESTMENTS’(ϒΠΟϒΡΓΕΙΟ ΑΝΑΠΤϒΞΗΣ ΚΑΙ ΕΠΕΝ. in Greek). The object property labeled ‘is created by’ is used to identify the issuing Organization;

- the Organizational Units with their hierarchical structural relationship of the Ministry in the right hand side in red: ΓΕΝ. Δ/ΝΣΗ ΔΙΟΙΚΗΤΙΚΩΝ ϒΠΗΡΕ., ΔΙΕϒΘϒΝΣΗ ΔΙΑΧΕΙΡΙΣΗΣ & ΑΝΑΠΤ., ΤΜΗΜΑ ΚΙΝΗΤΙΚΟΤΗΤΑΣ ϒΠΑΛΛ in Greek;

- the Person appointed Andrikopoulou Charikleia (Ανδρικοπου´λου_Χαρι´κλεια in Greek) in red just below the decision ID on the left side.

6.2.SPARQL queries

We deploy SPARQL for a systematic and targeted extraction of knowledge, for certain characteristic Competency Questions for the Use Cases we have identified.

Use Case 1: Transparency/Accountability in public money/resources spending

CQ1: For a given organization, which are the top x economic operators/organizations that are recipients of awarded contracts (within a given time period)

The query provides the list of operators/contractors ranked according to the highest number of contracts awarded by the HELLENIC MINISTRY OF INTERIOR (id: 100054492) after 01.01.2017 (publication date). We identify the integration of different ontologies (epo: for E-procurement, dvg: for Diavgeia, eli: for ELI ontology).

The output (Table 2) comprises the name of the Contractors and the number of contracts they received.

Use Case 2: Publicity in public spending

CQ3: Which is the full information for the Contact Point for a decision/act (the designated organizational units/person)?

To enhance accountability it is necessary to have data related to the issuing organization of a decision/act. The focus is on the Core Public Organization ontology via its main entity ‘Contact Point’ to retrieve data of the Responsible agent issuing the act (output is illustrated in (Table 3).

Use Case 3: Efficiency of the decision-making process

CQ3: For a given organization, which are the persons (and their staff category, rank, post) appointed/recruited (within a given period of time))?

The following query retrieves specific data on the persons(employees) appointed/recruited and their Staff Category, Rank, Post that might be of interest to know for Human Resources Management within a (Public) Organization. This query uses the properties of Diavgeia ontology combined with ePO, eli and d2kg ontologies to provide a targeted view on a specific organization appointments procedure. For demonstration purposes we selected a Public Organization-Greek General Hospital of Corinth (id:99221922).

The output (Table 4) is that Mrs EVANGELIA KARKOYLA (ΕϒΑΓΓΕΛΙΑ ΚΑΡΚΟϒΛΑ in Greek) has been appointed as PHARMACIST (ΠΕ_ΦΑΡΜΑΚΟΠΟΙΩΝ in Greek) in a vacant post (κενη´_οργανικη´_θε´ση in Greek) and the appointment of this specific person has taken place once since 01-01-2015.

6.3.Added value of the d2kg ontology

It is imperative to stress the added value of the d2kg ontology with reference to the directly competing Diavgeia ontology with respect to the implementation of the Use Cases described in Section 3.1. Using the Diavgeia ontology Use Cases (UC) can either be partly or not implemented at all via the provided Competency questions (CQ). Concretely,

More specifically, from the characteristic UC/CQs presented, the UC3/CQ3 cannot be implemented to deliver required information on the recruitment procedure via the Diavgeia ontology. The Diavgeia ontology does not include core properties such as epo:appointedBy, d2kg:appointedIn/staffRank/staffCategory concerning the type of position, the staff category and the staff rank for the person recruited/appointed. An effort to model this type of decisions is provided in the ontology repository.4949 However, it cannot discriminate the essential data, merely providing it in a string via the property dvg:has_text.

In any case, the added value of the d2kg resides in our orientation to systematically re-use properties of the EU standard ontologies and vocabularies such as epo:isCreatedBy in UC1/CQ1, and epo:hasEmail/hasTelephone in UC2/CQ3, which is not the case for the Diavgeia ontology that constructs from scratch its own respective properties: government_institution_name, government_institution_email, government_institution_phone. Moreover, EU Core Vocabularies are being deployed to provide the set of required values. This highlights the benefit of the d2kg ontology to effectively implement a firm re-use strategy following the dynamic evolution/update of the standard ontologies and their corresponding properties. All SPARQL queries and their results can be found at the respective thesis.5050