Upper ontology

In information science, an upper ontology (also known as a top-level ontology or foundation ontology) is an ontology (in the sense used in information science) which consists of very general terms (such as "object", "property", "relation") that are common across all domains. An important function of an upper ontology is to support broad semantic interoperability among a large number of domain-specific ontologies by providing a common starting point for the formulation of definitions. Terms in the domain ontology are ranked "under" the terms in the upper ontology, and the former stand to the latter in subclass relations.

A number of upper ontologies have been proposed, each with its own proponents. Each upper ontology can be considered as a computational implementation of natural philosophy, which itself is a more empirical method for investigating the topics within the philosophical discipline of physical ontology.

Library classification systems predate upper ontology systems. Though library classifications organize and categorize knowledge using general concepts that are the same across all knowledge domains, neither system is a replacement for the other.

Development

Any standard foundational ontology is likely to be contested among different groups, each with their own idea of "what exists". One factor exacerbating the failure to arrive at a common approach has been the lack of open-source applications that would permit the testing of different ontologies in the same computational environment. The differences have thus been debated largely on theoretical grounds, or are merely the result of personal preferences. Foundational ontologies can however be compared on the basis of adoption for the purposes of supporting interoperability across domain ontologies.

No particular upper ontology has yet gained widespread acceptance as a de facto standard. Different organizations have attempted to define standards for specific domains. The 'Process Specification Language' (PSL) created by the National Institute for Standards and Technology (NIST) is one example.

Another important factor leading to the absence of wide adoption of any existing upper ontology is the complexity. Some upper ontologies -- Cyc is often cited as an example in this regard -- are very large, ranging up to thousands of elements (classes, relations), with complex interactions among them and with a complexity similar to that of a human natural language, and the learning process can be even longer than for a natural language because of the unfamiliar format and logical rules. The motivation to overcome this learning barrier is largely absent because of the paucity of publicly accessible examples of use. As a result, those building domain ontologies for local applications tend to create the simplest possible domain-specific ontology, not related to any upper ontology. Such domain ontologies may function adequately for the local purpose, but they are very time-consuming to relate accurately to other domain ontologies.

To solve this problem some genuinely top level ontologies have been developed, which are deliberately designed to have minimal overlap with any domain ontologies. Examples are Basic Formal Ontology and the DOLCE (see below).

Arguments for the infeasibility of an upper ontology

Historically, many attempts in many societies have been made to impose or define a single set of concepts as more primal, basic, foundational, authoritative, true or rational than all others. A common objection to such attempts points out that humans lack the sort of transcendent perspective - or God's eye view - that would be required to achieve this goal. Humans are bound by language or culture, and so lack the sort of objective perspective from which to observe the whole terrain of concepts and derive any one standard.

Another objection is the problem of formulating definitions. Top level ontologies are designed to maximize support for interoperability across a large number of terms. Such ontologies must therefore consist of terms expressing very general concepts, but such concepts are so basic to our understanding that there is no way in which they can be defined, since the very process of definition implies that a less basic (and less well understood) concept is defined in terms of concepts that are more basic and so (ideally) more well understood. Very general concepts can often only be elucidated, for example by means of examples, or paraphrase.

Those who doubt the feasibility of general purpose ontologies are more inclined to ask “what specific purpose do we have in mind for this conceptual map of entities and what practical difference will this ontology make?” This pragmatic philosophical position surrenders all hope of devising the encoded ontology version of “everything that is the case,” (Wittgenstein, Tractatus Logico-Philosophicus).

Finally there are objections similar to those against artificial intelligence. Technically, the complex concept acquisition and the social / linguistic interactions of human beings suggests any axiomatic foundation of "most basic" concepts must be cognitive, biological or otherwise difficult to characterize since we don't have axioms for such systems. Ethically, any general-purpose ontology could quickly become an actual tyranny by recruiting adherents into a political program designed to propagate it and its funding means, and possibly defend it by violence. Historically, inconsistent and irrational belief systems have proven capable of commanding obedience to the detriment or harm of persons both inside and outside a society that accepts them. How much more harmful would a consistent rational one be, were it to contain even one or two basic assumptions incompatible with human life?

Arguments for the feasibility of an upper ontology

Many of those who doubt the possibility of developing wide agreement on a common upper ontology fall into one of two traps:

  1. they assert that there is no possibility of universal agreement on any conceptual scheme; but they argue that a practical common ontology does not need to have universal agreement, it only needs a large enough user community (as is the case for human languages) to make it profitable for developers to use it as a means to general interoperability, and for third-party developer to develop utilities to make it easier to use; and
  2. they point out that developers of data schemes find different representations congenial for their local purposes; but they do not demonstrate that these different representation are in fact logically inconsistent.

In fact, different representations of assertions about the real world (though not philosophical models), if they accurately reflect the world, must be logically consistent, even if they focus on different aspects of the same physical object or phenomenon. If any two assertions about the real world are logically inconsistent, one or both must be wrong, and that is a topic for experimental investigation, not for ontological representation. In practice, representations of the real world are created as and known to be approximations to the basic reality, and their use is circumscribed by the limits of error of measurements in any given practical application. Ontologies are entirely capable of representing approximations, and are also capable of representing situations in which different approximations have different utility. Objections based on the different ways people perceive things attack a simplistic, impoverished view of ontology. The objection that there are logically incompatible models of the world are true, but in an upper ontology those different models can be represented as different theories, and the adherents of those theories can use them in preference to other theories, while preserving the logical consistency of the necessary assumptions of the upper ontology. The necessary assumptions provide the logical vocabulary with which to specify the meanings of all of the incompatible models. It has never been demonstrated that incompatible models cannot be properly specified with a common, more basic set of concepts, while there are examples of incompatible theories that can be logically specified with only a few basic concepts.

Many of the objections to upper ontology refer to the problems of life-critical decisions or non-axiomatized problem areas such as law or medicine or politics that are difficult even for humans to understand. Some of these objections do not apply to physical objects or standard abstractions that are defined into existence by human beings and closely controlled by them for mutual good, such as standards for electrical power system connections or the signals used in traffic lights. No single general metaphysics is required to agree that some such standards are desirable. For instance, while time and space can be represented many ways, some of these are already used in interoperable artifacts like maps or schedules.

Objections to the feasibility of a common upper ontology also do not take into account the possibility of forging agreement on an ontology that contains all of the primitive ontology elements that can be combined to create any number of more specialized concept representations. Adopting this tactic permits effort to be focused on agreement only on a limited number of ontology elements. By agreeing on the meanings of that inventory of basic concepts, it becomes possible to create and then accurately and automatically interpret an infinite number of concept representations as combinations of the basic ontology elements. Any domain ontology or database that uses the elements of such an upper ontology to specify the meanings of its terms will be automatically and accurately interoperable with other ontologies that use the upper ontology, even though they may each separately define a large number of domain elements not defined in other ontologies. In such a case, proper interpretation will require that the logical descriptions of domain-specific elements be transmitted along with any data that is communicated; the data will then be automatically interpretable because the domain element descriptions, based on the upper ontology, will be properly interpretable by any system that can properly use the upper ontology. In effect elements in different domain ontologies can be *translated* into each other using the common upper ontology. An upper ontology based on such a set of primitive elements can include alternative views, provided that they are logically compatible. Logically incompatible models can be represented as alternative theories, or represented in a specialized extension to the upper ontology. The proper use of alternative theories is a piece of knowledge that can itself be represented in an ontology. Users that develop new domain ontologies and find that there are semantic primitives needed for their domain but missing from the existing common upper ontology can add those new primitives by the accepted procedure, expanding the common upper ontology as necessary.

Most proponents of an upper ontology argue that several good ones may be created with perhaps different emphasis. Very few are actually arguing to discover just one within natural language or even an academic field. Most are simply standardizing some existing communication. Another view advanced is that there is almost total overlap of the different ways that upper ontologies have been formalized, in the sense that different ontologies focus on a different aspect of the same entities, but the different views are complementary and not contradictory to each other; as a result, an internally consistent ontology that contains all the views, with means of translating the different views into the other, is feasible. Such an ontology has not thus far been constructed, however, because it would require a large project to develop so as to include all of the alternative views in the separately developed upper ontologies, along with their translations. The main barrier to construction of such an ontology is not the technical issues, but the reluctance of funding agencies to provide the funds for a large enough consortium of developers and users.

Several common arguments against upper ontology can be examined more clearly by separating issues of concept definition (ontology), language (lexicons), and facts (knowledge). For instance, people have different terms and phrases for the same concept. However, that does not necessarily mean that those people are referring to different concepts. They may simply be using different language or idiom. Formal ontologies typically use linguistic labels to refer to concepts, but the terms that label ontology elements mean no more and no less than what their axioms say they mean. Labels are similar to variable names in software, evocative rather than definitive. The proponents of a common upper ontology point out that the meanings of the elements (classes, relations, rules) in an ontology depend only on their logical form, and not on the labels, which are usually chosen merely to make the ontologies more easily usable by their human developers. In fact, the labels for elements in an ontology need not be words - they could be, for example, images of instances of a particular type, or videos of an action that is represented by a particular type. It cannot be emphasized too strongly that words are *not* what are represented in an ontology, but entities in the real world, or abstract entities (concepts) in the minds of people. Words are not equivalent to ontology elements, but words *label* ontology elements. There can be many words that label a single concept, even in a single language (synonymy), and there can be many concepts labeled by a single word (ambiguity). Creating the mappings between human language and the elements of an ontology is the province of Natural Language Understanding. But the ontology itself stands independently as a logical and computational structure. For this reason, finding agreement on the structure of an ontology is actually easier than developing a controlled vocabulary, because all different interpretations of a word can be included, each *mapped* to the same word in the different terminologies.

A second argument is that people believe different things, and therefore can't have the same ontology. However, people can assign different truth values to a particular assertion while accepting the validity of certain underlying claims, facts, or way of expressing an argument with which they disagree. (Using, for instance, the issue/position/argument form.) This objection to upper ontologies ignores the fact that a single ontology can represent different belief systems, representing them as different belief systems, without taking a position on the validity of either.

Even arguments about the existence of a thing require a certain sharing of a concept, even though its existence in the real world may be disputed. Separating belief from naming and definition also helps to clarify this issue, and show how concepts can be held in common, even in the face of differing belief. For instance, wiki as a medium may permit such confusion but disciplined users can apply dispute resolution methods to sort out their conflicts. It is also argued that most people share a common set of "semantic primitives", fundamental concepts, to which they refer when they are trying to explain unfamiliar terms to other people. An ontology that includes representations of those semantic primitives could in such a case be used to create logical descriptions of any term that a person may wish to define logically. That ontology would be one form of upper ontology, serving as a logical "interlingua" that can translate ideas in one terminology to its logical equivalent in another terminology.

Advocates argue that most disagreement about the viability of an upper ontology can be traced to the conflation of ontology, language and knowledge, or too-specialized areas of knowledge: many people, or agents or groups will have areas of their respective internal ontologies that do not overlap. If they can cooperate and share a conceptual map at all, this may be so very useful that it outweighs any disadvantages that accrue from sharing. To the degree it becomes harder to share concepts the deeper one probes, the more valuable such sharing tends to get. If the problem is as basic as opponents of upper ontologies claim, then, it also applies to a group of humans trying to cooperate, who might need machine assistance to communicate easily.

If nothing else, such ontologies are implied by machine translation, used when people cannot practically communicate. Whether "upper" or not, these seem likely to proliferate.

Available upper ontologies

Basic Formal Ontology (BFO)

The Basic Formal Ontology (BFO) framework developed by Barry Smith and his associates consists of a series of sub-ontologies at different levels of granularity. The ontologies are divided into two varieties: relating to continuant entities such as three-dimensional enduring objects, and occurrent entities (primarily) processes conceived as unfolding in successive phases through time. BFO thus incorporates both three-dimensionalist and four-dimensionalist perspectives on reality within a single framework. Interrelations are defined between the two types of ontologies in a way which gives BFO the facility to deal with both static/spatial and dynamic/temporal features of reality. A continuant domain ontology descending from BFO can be conceived as an inventory of entities existing at a time. Each occurrent ontology can be conceived as an inventory of processes unfolding through a given interval of time. Both BFO itself and each of its extension sub-ontologies can be conceived as a window on a certain portion of reality at a given level of granularity. More than 200 extension ontologies of BFO have been created, applying the BFO architecture to different domains through the strategy of downward population. The Cell Ontology, for example, populates downward from BFO by importing the BFO branch terminating with object, and defining a cell as a subkind of object. Other examples of ontologies extending BFO are the Ontology for Biomedical Investigations (OBI) and the ontologies of the Open Biomedical Ontologies Foundry. In addition to these examples, BFO and extensions are increasingly being use in defense and security domains, for example in the AIRS framework. BFO serves as the upper level of the Sustainable Development Goals (SDG) Interface Ontology developed by the United Nations Environment Programme. BFO has been documented in the textbook Building Ontologies with Basic Formal Ontology, published by MIT Press in 2015.

BORO

Business Objects Reference Ontology is an upper ontology designed for developing ontological or semantic models for large complex operational applications that consists of a top ontology as well as a process for constructing the ontology. It is built upon a series of clear metaphysical choices to provide a solid (metaphysical) foundation. A key choice was for an extensional (and hence, four-dimensional) ontology which provides it a simple criteria of identity. Elements of it have appeared in a number of standards. For example, the ISO standard, ISO 15926 – Industrial automation systems and integration – was heavily influenced by an early version. The IDEAS (International Defence Enterprise Architecture Specification for exchange) standard is based upon BORO, which in turn was used to develop DODAF 2.0.

CIDOC Conceptual Reference Model

Although "CIDOC object-oriented Conceptual Reference Model" (CRM) is a domain ontology, specialised to the purposes of representing cultural heritage, a subset called CRM Core is a generic upper ontology, including:[1][2]

A persistent item is a physical or conceptional item that has a persistent identity recognized within the duration of its existence by its identification rather than by its continuity or by observation. A persistent item is comparable to an endurant.
A propositional object is a set of statements about real or imaginary things.
A symbolic object is a sign/symbol or an aggregation of signs or symbols.

COSMO

COSMO (COmmon Semantic MOdel, available at http://micra.com/COSMO/COSMO.owl) is an ontology that was initiated as a project of the COSMO working group of the Ontology and taxonomy Coordinating Working Group, with the goal of developing a foundation ontology that can serve to enable broad general Semantic Interoperability. The current version is an OWL ontology, but a Common-Logic compliant version is anticipated in the future. The ontology and explanatory files are available at the COSMO site. The goal of the COSMO working group was to develop a foundation ontology by a collaborative process that will allow it to represent all of the basic ontology elements that all members feel are needed for their applications. The development of COSMO is fully open, and any comments or suggestions from any sources are welcome. After some discussion and input from members in 2006, the development of the COSMO has been continued primarily by Patrick Cassidy, the chairman of the COSMO Working Group. Contributions and suggestions from any interested party are still welcome and encouraged. Many of the types (OWL classes) in the current COSMO have been taken from the OpenCyc OWL version 0.78, and from the SUMO. Other elements were taken from other ontologies (such as BFO and DOLCE), or developed specifically for COSMO. Development of the COSMO initially focused on including representations of all of the words in the Longman Dictionary of Contemporary English (LDOCE) controlled defining vocabulary (2148 words). These words are sufficient to define (linguistically) all of the entries in the LDOCE. It is hypothesized that the ontological representations of the concepts represented by those terms will be sufficient to specify the meanings of any specialized ontology element, thereby serving as a basis for general Semantic Interoperability. Interoperability via COSMO is enabled by using the COSMO (or an ontology derived from it) as an interlingua by which other domain ontologies can be translated into each other's terms and thereby accurately communicate. As new domains are linked into COSMO, additional semantic primitives may be recognized and added to its structure. The current (January 2016) OWL version of COSMO has over 8000 types (OWL classes), over 1000 relations, and over 3000 restrictions. The COSMO itself (COSMO.owl) and other related and explanatory files can be obtained at http://micra.com/COSMO.

Cyc

A well-known and quite comprehensive ontology available today is Cyc, a proprietary system under development since 1986, consisting of a foundation ontology and several domain-specific ontologies (called microtheories). A subset of that ontology has been released for free under the name OpenCyc, and a more or less unabridged version is made available for free non-commercial use under the name ResearchCyc.

DOLCE

Descriptive Ontology for Linguistic and Cognitive Engineering (DOLCE) is the first module of the WonderWeb foundational ontologies library,[3] developed by Nicola Guarino and his associates at the Laboratory for Applied Ontology (LOA). As implied by its acronym, DOLCE has a clear cognitive bias, in that it aims at capturing the ontological categories underlying natural language and human common sense. DOLCE, however, does not commit to a strictly referentialist metaphysics related to the intrinsic nature of the world. Rather, the categories it introduces are thought of as cognitive artifacts, which are ultimately depending on human perception, cultural imprints and social conventions. In this sense, they intend to be just descriptive (vs prescriptive) notions, that assist in making already formed conceptualizations explicit.

General Formal Ontology (GFO)

The general formal ontology (GFO), developed by Heinrich Herre and his colleagues of the research group Onto-Med in Leipzig, is a realistic ontology integrating processes and objects. It attempts to include many aspects of recent philosophy, which is reflected both in its taxonomic tree and its axiomatizations. GFO allows for different axiomatizations of its categories (such as the existence of atomic time-intervals vs. dense time). The basic principles of GFO are published in the Onto-Med Report Nr. 8 and in "General Formal Ontology (GFO): A Foundational Ontology for Conceptual Modelling".[4][5]

Two GFO specialties, among others, are its account of persistence and its time model. Regarding persistence, the distinction between endurants (objects) and perdurants (processes) is made explicit within GFO by the introduction of a special category, a persistent.[6] A persistant is a special category with the intention that its instances "remain identical" (over time). With respect to time, time intervals are taken as primitive in GFO, and time-points (called "time boundaries") as derived. Moreover, time-points may coincide, which is convenient for modelling instantaneous changes.

gist

gist is developed and supported by Semantic Arts. gist (not an acronym – it means to get the essence of) is a “minimalist upper ontology”. gist is targeted at enterprise information systems, although it has been applied to healthcare delivery applications. The major attributes of gist are:

  1. it is small (there are 140 classes and 127 properties)
  2. it is comprehensive (most enterprises will not find the need to create additional primitive classes, but will find that most of their classes can be defined and derived from gist)
  3. it is robust – all the classes descend from 12 primitive classes, which are mostly mutually disjoint. This aids a great deal in subsequent error detection. There are 1342 axioms, and it uses almost all of the DL constructs (it is SROIQ(D) )
  4. it is concrete – most upper ontologies start with abstract philosophical concepts that users must commit to in order to use the ontology. Gist starts with concrete classes that most people already do, or reasonably could agree with, such as Person, Organization, Document, Time, UnitOfMeasure and the like)
  5. it is unambiguous – ambiguous terms (such as “term”) have been removed as they are often overloaded and confused. Also terms that frequently have different definitions at different enterprises (such as customer and order) have been removed, also to reduce ambiguity.
  6. it is understandable – in addition to being built on concrete, generally understood primitives, it is extremely modular. The 140 classes are implemented in 18 modular ontologies, each can easily be understood in its entirety, and each imports only the other modules that it needs.

gist has been used to build Enterprise Ontologies for a number of major commercial and governmental agencies including: Procter & Gamble, Sentara Healthcare, Washington State Department of Labor & Industries, LexisNexis, Sallie Mae and two major Financial Services firms. gist is freely available with a Creative Commons share alike license. There are 18 small ontologies that make up gist. Gist can be downloaded all at once by loading or importing gistCore at gist7. gist is actively maintained, and has been in use for 10 years. As of May 2015 it is at version 7.1.1.[7]

gist was the subject of a paper exploring how to bridge modeling differences between ontologies [8] In a paper describing the OQuaRE methodology for evaluating ontologies, the gist unit of measure ontology scored the highest in the manual evaluation against 10 other unit of measure ontologies, and scored above average in the automated evaluation. The authors stated "This ontology could easily be tested and validated, its knowledge could be effectively reused and adapted for different specified environments" [9]

IDEAS

The upper ontology developed by the IDEAS Group is higher-order, extensional and 4D. It was developed using the BORO Method. The IDEAS ontology is not intended for reasoning and inference purposes; its purpose is to be a precise model of business.

ISO 15926

ISO 15926 is an International Standard for the representation of process plant life-cycle information. This representation is specified by a generic, conceptual data model that is suitable as the basis for implementation in a shared database or data warehouse. The data model is designed to be used in conjunction with reference data: standard instances that represent information common to a number of users, process plants, or both. The support for a specific life-cycle activity depends on the use of appropriate reference data in conjunction with the data model. To enable integration of life-cycle information the model excludes all information constraints that are appropriate only to particular applications within the scope. ISO 15926-2 defines a generic model with 201 entity types. It has been prepared by Technical Committee ISO/TC 184, Industrial automation systems and integration, Subcommittee SC 4, Industrial data.

MarineTLO

MarineTLO is an upperontology for the marine domain (also applicable to the terrestrial domain), developed by the Information Systems Laboratory at the Institute of Computer Science, Foundation for Research and Technology - Hellas (FORTH-ICS). Its purpose is to tackle the need for having integrated sets of facts about marine species, and thus to assist research about species and biodiversity. It provides a unified and coherent core model for schema mapping which enables formulating and answering queries which cannot be answered by any individual source.[10][11]

PROTON

PROTON (PROTo ONtology) is a basic subsumption hierarchy which provides coverage of most of the upper-level concepts necessary for semantic annotation, indexing, and retrieval.

SUMO (Suggested Upper Merged Ontology)

The Suggested Upper Merged Ontology (SUMO) is another comprehensive ontology project. It includes an upper ontology, created by the IEEE working group P1600.1 (originally by Ian Niles and Adam Pease). It is extended with many domain ontologies and a complete set of links to WordNet. It is open source.

UMBEL

Upper Mapping and Binding Exchange Layer (UMBEL) is an ontology of 28,000 reference concepts that maps to a simplified subset of the OpenCyc ontology, that is intended to provide a way of linking the precise OpenCyc ontology with less formal ontologies.[12] It also has formal mappings to Wikipedia, DBpedia, PROTON and GeoNames. It has been developed and maintained as open source by Structured Dynamics.

UFO (Unified Foundational Ontology)

The Unified Foundational Ontology (UFO), developed by Giancarlo Guizzardi and associates, incorporating developments from GFO, DOLCE and the Ontology of Universals underlying OntoClean in a single coherent foundational ontology. The core categories of UFO (UFO-A) have been completely formally characterized in Giancarlo Guizzardi's Ph.D. thesis and further extended at the Ontology and Conceptual Modelling Research Group (NEMO) in Brazil with cooperators from Brandenburg University of Technology (Gerd Wagner) and Laboratory for Applied Ontology (LOA). UFO-A has been employed to analyze structural conceptual modeling constructs such as object types and taxonomic relations, associations and relations between associations, roles, properties, datatypes and weak entities, and parthood relations among objects. More recent developments incorporate an ontology of events in UFO (UFO-B), as well as an ontology of social and intentional aspects (UFO-C). The combination of UFO-A, B and C has been used to analyze, redesign and integrate reference conceptual models in a number of complex domains such as, for instance, Enterprise Modeling, Software Engineering, Service Science, Petroleum and Gas, Telecommunications, and Bioinformatics. Another recent development aimed towards a clear account of services and service-related concepts, and provided for a commitment-based account of the notion of service (UFO-S),[13] UFO is the foundational ontology for OntoUML, an ontology modeling language.

WordNet

WordNet, a freely available database originally designed as a semantic network based on psycholinguistic principles, was expanded by addition of definitions and is now also viewed as a dictionary. It qualifies as an upper ontology by including the most general concepts as well as more specialized concepts, related to each other not only by the subsumption relations, but by other semantic relations as well, such as part-of and cause. However, unlike Cyc, it has not been formally axiomatized so as to make the logical relations between the concepts precise. It has been widely used in Natural language processing research.

YAMATO (Yet Another More Advanced Top Ontology)

YAMATO is developed by Riichiro Mizoguchi, formerly at the Institute of Scientific and Industrial Research of the University of Osaka, and now at the Japan Advanced Institute of Science and Technology. Major features of YAMATO are:

  1. an advanced description of quality, attribute, property, and quantity,[14]
  2. an ontology of representation,[15]
  3. an advanced description of processes and events,[16]
  4. the use of a theory of roles.[17]

YAMATO has been extensively used for developing other, more applied, ontologies such as a medical ontology,[18] an ontology of gene,[19] an ontology of learning/instructional theories,[20] an ontology of sustainability science,[21] and an ontology of the cultural domain.

Upper/foundational ontology tools

ONSET

ONSET, the foundational ontology selection and explanation tool, assists the domain ontology developer in selecting the most appropriate foundational ontology. The domain ontology developer provides the requirements/answers one or more questions, and ONSET computes the selection of the appropriate foundational ontology and explains why. The current version (v2 of 24 April 2013) includes DOLCE, BFO, GFO, SUMO, YAMATO and GIST.

ROMULUS

ROMULUS is a foundational ontology repository aimed at improving semantic interoperability. Currently there are three foundational ontologies in the repository: DOLCE, BFO and GFO. Features of ROMULUS include:

  1. It provides a high-level view of the foundational ontologies with only the most general concepts common to all implemented foundational ontologies.
  2. Foundational ontologies in ROMULUS are modularised.
  3. Foundational ontology mediation has been performed. This includes alignment, mapping, merging, searchable metadata and an interchangeability method for foundational ontologies.
  4. ROMULUS provides detailed taxonomies of each foundational ontology to allow easy browsing of foundational ontologies.
  5. ROMULUS allows you to download each foundational ontology module including the integrated foundational ontologies.
  6. Searchable metadata of each foundational ontology is available.
  7. A comparison of the included foundational ontologies is available.

See also

References

  1. "Graphical Representation of core CRM form". CIDOC.
  2. "Definition of the CIDOC Conceptual Reference Model, Version 5.0.4". CIDOC. November 2011.
  3. http://www.loa-cnr.it/old/Papers/D18.pdf
  4. http://www.onto-med.de/Archiv/ontomed2002/en/publications/scientific-reports/om-report-no8.pdf
  5. http://www.onto-med.de/publications/2010/gfo-basic-principles.pdf
  6. http://www.onto-med.de/en/theories/gfo/part1/node20.html
  7. Semantic Arts. "gist home page".
  8. Chiara Ghidini; Luciano Serafini; Segio Tessaris. "Complexity of Reasoning with Expressive Ontology Mappings" (PDF).
  9. Astrid Duque-Ramos & Jesualdo Tomas Fernandez-Breis. "OQuaRE: A SQuaRE-based Approach for Evaluating the Quality of Ontologies" (PDF).
  10. "MarineTLO - A Top Level Ontology for the Marine/Biodiversity Domain". forth.gr. Retrieved 22 April 2015.
  11. Tzitzikas, Y. and Alloca, C. and Bekiari, C. and Marketakis, Y. and Fafalios, P. and Doerr, M. and Minadakis, N. and Patkos, T. and Candela, L. (2013). "Integrating Heterogeneous and Distributed Information about Marine Species through a Top Level Ontology". Communications in Computer and Information Science. Institute of Computer Science, FORTH-ICS, Greece: Springer: 289–301. doi:10.1007/978-3-319-03437-9_29.
  12. Mike Bergman. "The Role of UMBEL: Stuck in the Middle with You . . .". Retrieved 2010-10-26.
  13. Nardi, J. C., Falbo, R. D. A., Almeida, J. P. A., Guizzardi, G., Pires, L. F., van Sinderen, M. J., & Guarino, N. (2013, September). "Towards a commitment-based reference ontology for services". In Enterprise Distributed Object Computing Conference (EDOC), 2013 17th IEEE International (pp. 175-184). IEEE.
  14. http://www.ei.sanken.osaka-u.ac.jp/hozo/onto_library/YAMATO101216.pdf
  15. "Part 3: Advanced course of ontological engineering". springer.com. 22: 193–220. doi:10.1007/BF03040960. Retrieved 22 April 2015.
  16. . doi:10.3233/AO-2009-0067. Missing or empty |title= (help)
  17. Mizoguchi, R.; Sunagawa, E.; Kozaki, K.; Kitamura, Y. "A Model of Roles within an Ontology Development Tool: Hozo". J. of Applied Ontology. 2 (2): 159–179.
  18. http://ceur-ws.org/Vol-833/paper9.pdf
  19. http://ceur-ws.org/Vol-897/session1-paper05.pdf
  20. "start [OMNIBUS project]". qee.jp. 6 December 2014. Retrieved 22 April 2015.
  21. "Toward knowledge structuring of sustainability science based on ontology engineering". springer.com. Retrieved 22 April 2015.
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