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Bringing Ontology Development and Maintenance to the MainstreamOntologies supply the structure for relating information to other information in the semantic Web or the linked data realm. Ontologies provide a similar role for the organization of data that is provided by relational data schema. Because of this structural role, ontologies are pivotal to the coherence and interoperability of interconnected data [1].
There are many ways to categorize ontologies. One dimension is between upper level and mid- and lower- (or domain-) level. Another is between reference or subject (domain) ontologies. Upper-level ontologies [2] tend to be encompassing, abstract and inclusive ways to split or organize all “things”. Reference ontologies tend to be cross-cutting such as ones that describe people and their interests (e.g., FOAF), reference subject concepts (e.g., UMBEL), bibliographies and citations (e.g., BIBO), projects (e.g., DOAP), simple knowledge structures (e.g., SKOS), social networks and activities (e.g., SIOC), and so forth.
The focus here is on domain ontologies, which are descriptions of particular subject or domain areas. Domain ontologies are the “world views” by which organizations, communities or enterprises describe the concepts in their domain, the relationships between those concepts, and the instances or individuals that are the actual things that populate that structure. Thus, domain ontologies are the basic bread-and-butter descriptive structures for real-world applications of ontologies.
According to Corcho et al. [3] “a domain ontology can be extracted from special purpose encyclopedias, dictionaries, nomenclatures, taxonomies, handbooks, scientific special languages (say, chemical formulas), specialized KBs, and from experts.” Another way of stating this is to say that a domain ontology — properly constructed — should also be a faithful representation of the language and relationships for those who interact with that domain. The form of the interaction can range from work to play to intellectual understanding or knowledge.
Another focus here is on lightweight ontologies. These are typically defined as more hierarchical or classificatory in nature. Like their better-known cousins of taxonomies, but with greater connectedness, lightweight ontologies are often designed to represent subsumption or other relationships between concepts. They have not too many or not too complicated predicates (relationships). As relationships are added and the complexities of the world get further captured, ontologies migrate from the lightweight to the “heavyweight” end of the spectrum.
The development of ontologies goes by the names of ontology engineering or ontology building, and can also be investigated under the rubric of ontology learning. For reasons as stated below, we prefer not to use the term ontology engineering, since it tends to convey a priesthood or specialized expertise in order to define or use them. As indicated, we see ontologies as being (largely) developed and maintained by the users or practitioners within a given domain. The tools and methodologies to be employed need to be geared to these same democratic (small “d”) objectives.
For the last twenty years there have been many methods put forward for how to develop ontologies. These methodological activities have diminished somewhat in recent years. Yet the research as separately discussed in Ontology Development Methodologies [1] seems to indicate this state of methodology development in the field:
While there is by no means unanimity in this community, some general consenses can be seen from these prior reviews, especially those that concentrate on practical or enterprise ontologies. In terms of design objectives, this general consensus suggests that ontologies should be [4]:
While laudable, and which represent design objectives to which we adhere, current ontology development methods do not meet these criteria. Furthermore, to be discussed in our next installment, there is also an inadequate slate of tools ready to support these objectives.
If you ask most knowledgeable enterprise IT executives what they understand ontologies to mean and how they are to be built, you would likely hear that ontologies are expensive, complicated and difficult to build. Reactions such as these (and not trying to set up strawmen) are a reflection of both the lack of methods to achieve the consensual objectives above and the lack of tools to do so.
The use of ontology design patterns is one helpful approach [5]. Such patterns help indicate best design practice for particular use cases and relationship patterns. However, while such patterns should be part of a general methodology, they do not themselves constitute a methodology.
Also, as Structured Dynamics has argued for some time, the future of the semantic enterprise resides in ontology-driven apps [6]. Yet, for that vision to be realized, clearly both methods and tools to build ontologies must improve. In part this series is a reflection of our commitment to plug these gaps.
What we see at present for ontology development is a highly technical, overly engineered environment. Methodologies are only sparsely or generally documented. They are not lightweight nor collaborative nor really incremental. While many tools exist, they do not interoperate and are pitched mostly at the professional ontologist, not the domain user. In order to achieve the vision of ontology-driven apps the methods to develop the fulcrum of that vision — namely, the ontologies themselves — need much additional attention. An adaptive methodology for ontology development is well past due.
We can thus combine the results of prior surveys and recommendations with our own unique approach to adaptive ontologies in order to derive design criteria. We believe this adaptive approach should be:
We discuss each of these design criteria below.
While we agree with the advisability of collaboration as a design condition — and therefore also believe that tools to support this methodology must also accommodate group involvement — collaboration per se is not a design requirement. It is an implementation best practice.
Effective ontology development is as much as anything a matter of mindset. This mindset is grounded in leveraging what already exists, “paying as one benefits” through an incremental approach, and starting simple and adding complexity as understanding and experience are gained. Inherently this approach requires domain users to be the driving force in ongoing development with appropriate tools to support that emphasis. Ontologists and ontology engineering are important backstops, but not in the lead design or development roles. The net result of this mindset is to develop pragmatic ontologies that are understood — and used by — actual domain practitioners.
By definition the methodology should be lightweight and oriented to particular domains. Ontologies built for the pragmatic purposes of setting context and aiding interoperability tend to be lightweight with only a few predicates, such as isAbout, narrowerThan or broaderThan. But, if done properly, these lighter weight ontologies can be surprisingly powerful in discovering connections and relationships. Moreover, they are a logical and doable intermediate step on the path to more demanding semantic analysis.
Context simply means there is a reference structure for guiding the assignment of what content ‘is about’ [7]. An ontology with proper context has a balanced and complete scope of the domain at hand. It generally uses fairly simple predicates; Structured Dynamics tends to use the UMBEL vocabulary for its predicates and class definitions, and to link to existing UMBEL concepts to help ensure interoperability [8]. A good gauge for whether the context is adequate is whether there are sufficient concept definitions to disambiguate common concepts in the domain.
The essence of coherence is that it is a state of consistent connections, a logical framework for integrating diverse elements in an intelligent way. So while context supplies a reference structure, coherence means that the structure makes sense. With relation to a content graph, this means that the right connections (edges or predicates) have been drawn between the object nodes (or content) in the graph [9].
Relating content coherently itself demands a coherent framework. At the upper reference layer this begins with UMBEL, which itself is an extraction from the vetted and coherent Cyc common sense knowledge base. However, as domain specifics get added, these details, too, must be testable against a unified framework. Logic and coherence testing are thus an essential part of the ontology development methodology.
Much value can be realized by starting small, being simple, and emphasizing the pragmatic. It is OK to make those connections that are doable and defensible today, while delaying until later the full scope of semantic complexities associated with complete data alignment.
An open world approach [10] provides the logical basis for incremental growth and adoption of ontologies. This is also in keeping with the continuous and incremental deployment model that Structured Dynamics has adopted from MIKE2.0 [11]. When this model is applied to the process of ontology development, the basic implementation increments appear as follows:
The first two phases are devoted to scoping and prototyping. Then, the remaining phases of creating a working ontology, testing it, maintaining it, and then revising and extending it are repeated over multiple increments. In this manner the deployment proceeds incrementally and only as learning occurs. Importantly, too, this approach also means that complexity, sophistication and scope only grows consistent with demonstrable benefits.
Fundamental to the whole concept of coherence is the fact that domain experts and practitioners have been looking at the questions of relationships, structure, language and meaning for decades. Though perhaps today we now finally have a broad useful data and logic model in RDF, the fact remains that massive time and effort has already been expended to codify some of these understandings in various ways and at various levels of completeness and scope.
These are prior investments in structure that would be silly to ignore. Yet, today, most methodologies do ignore these resources. This ignorance of prior investments in information relationships is perplexing. Though unquestioned adoption of legacy structure is inappropriate to modern interoperable systems, that fact is no excuse for re-inventing prior effort and discoveries, many of which are the result of laborious consensus building or negotiations.
The most productive methodologies for modern ontology building are therefore those that re-use and reconcile prior investments in structural knowledge, not ignore them. These existing assets take the form of already proven external ontologies and internal and industry structures and vocabularies.
Nearly a year ago we undertook a major series on description logics [12], a key underpinning to Structured Dynamics’ conceptual and logic foundation to its ontology development. While we can not always adhere to strict and conforming description logics designs, our four-part series helped provide guidance for the separation of concerns and work that can also lead to more effective ontology designs [13].
Conscious separation of the so-called ABox (assertions or instance records) and TBox (conceptual structure) in ontology design provides some compelling benefits:
Maintaining identity relations and disambiguation as separate components also has the advantage of enabling different methodologies or algorithms to be determined or swapped out as better methods become available. A low-fidelity service, for example, could be applied for quick or free uses, with more rigorous methods reserved for paid or batch mode analysis. Similarly, maintaining full-text search as a separate component means that work can be done by optimized search engines with built-in faceting.
An essential design criteria is to have a methodology and work flow that explicitly accounts for simple and interoperable tools. By “simple” we mean targeted, task-specific tools and functionality that is also geared to domain users and practitioners.
Of all design areas, this one is perhaps the weakest in terms of current offerings. The next installment in this series [1] will address this topic directly.
Armed with these criteria, we are now ready to present the new methodology. In summary terms, we can describe the steps in the methodology as:
After the scoping and analysis phase, the effort is split into two tracks:
This split conforms to the separation of ABox and TBox noted above [15]. There are conceptual and workflow parallels between entities and data v. ontologies. However, the specific methodologies differ, and we only focus on the conceptual ontology side in the discussion below, shown as the upper part (blue) of Figure 3:
Two key aspects of the initial effort are to properly scope the size and purpose of the starting prototype and to inventory the existing assets (structure and data; internal and external) available to the project.
Most current ontology methodologies do not emphasize re-use of existing structure. Yet these resources are rich in content and meaning, and often represent years to decades of effort and expenditure in creation, assembly and consensus. Just a short list of these potential sources demonstrates the treasure trove of structure and vocabularies available for re-use: Web portals; databases; legacy schema; metadata; taxonomies; controlled vocabularies; ontologies; master data catalogs; industry standards; exchange formats, etc.
Metadata and available structure may have value no matter where or how it exists, and a fundamental aspect of the build methodology is to bring such candidate structure into a common tools environment for inspection and testing. Besides assembling and reviewing existing sources, those selected for re-use must be migrated and converted to proper ontological form (OWL in the case of those developed by Structured Dynamics). Some of these techniques have been demonstrated for prior patterns and schema [17]; in other instances various converters, RDFizers or scripts may need to be employed to effect the migration.
Many tools and options exist at this stage, even though as a formal step this conversion is often neglected.
The prototype structure is the first operating instance of the ontology. The creation of this initial structure follows quite closely the approach recommended in Ontology Development 101 [18], with some modifications to reflect current terminology:
The prototype structure is important since it communicates to the project sponsors the scope and basic operation of the starting structure. This stage often represents a decision point for proceeding; it may also trigger the next budgeting phase.
An essential aspect of a build methodology is to re-use “standard” ontologies as much as possible. Core ontologies are Dublin Core, DC Terms, Event, FOAF, GeoNames, SKOS, Timeline, and UMBEL. These core ontologies have been chosen because of universality, quality, community support and other factors [19]. Though less universal, there are also a number of secondary ontologies, namely BIBO, DOAP, and SIOC that may fit within the current scope.
These are then supplemented with quality domain-specific ontologies, if such exist. Only then are new name spaces assigned for any newly generated ontology(ies).
The working ontology is the first production-grade (deployable) version of the ontology. It conforms to all of the ontology building best practices and needs to be complete enough such that it can be loaded and managed in a fully conforming ontology editor or IDE [20].
By also using the OWL API, this working structure can also be the source for specialty tools and user maintenance functions, short of requiring a full-blown OWL editor. Many of these aspects are some of the poorest represented in the current tools inventory; we return to this topic in the next installment.
The working ontology is the complete, canonical form of the domain ontology(ies) [21]. These are the central structures that are the focus for ongoing maintenance and extension efforts over the ensuing phases. As such, the ontologies need to be managed by a version control system with comprehensive ontology and vocabulary management support and tools.
As new ontologies are generated, they should be tested for coherence against various reasoning, inference and other natural language processing tools. Gap testing is also used to discover key holes or missing links within the resulting ontology graph structure. Coherence testing may result in discovering missing or incorrect axioms. Gap testing helps identify internal graph nodes needed to establish the integrity or connectivity of the concept graph.
Though used for different purposes, mapping and alignment tools may also work to identify logical and other inconsistencies in definitions or labels within the graph structure. Mapping and alignment is also important in its own right in order to establish the links that help promote ontology and information interoperability.
External knowledge bases can also play essential roles in testing and mapping. Two prominent knowledge base examples are Cyc and Wikipedia, but many additional exist for any specific domain.
Of course, the whole purpose of the development methodology is to create practical, working ontologies. Such uses include search, discovery, information federation, data interoperability, analysis and reasoning, The general purposes to which ontologies may be put are described in the Executive Intro to Ontologies [22].
However, it is also in day-to-day use of the ontology that many enhancements and improvements may be discovered. Examples include improved definitions of concepts; expansions of synonyms, aliases and jargon for concepts; better, more intuitive preferred labels; better means to disambiguate between competing meanings; missing connections or excessive connections; and splitting or consolidating of the underlying structure.
Today, such maintenance enhancements are most often not pursued because existing tools do not support such actions. Reliance on IDEs and tools geared to ontology engineering are not well suited to users and practitioners being able to note or effect such changes. Yet ongoing ontology use and adaptation clearly suggest that users should be encouraged to do so. They are the ones in the front lines of identifying and potentially recording such improvements.
Ontology development is a process, not a static destination or event. This observation makes intuitive sense since we understand ontologies to be a means to capture our understanding of our domains, which is itself constantly changing due to new observations and insights. This factor alone suggests that ontology development methodologies must therefore give explicit attention to extension.
But there is another reason for this attention. Incremental, adaptive ontologies are also explicitly designed to expand their scope and coverage, bite by bite as benefits prove themselves and justify that expansion. A start small and expand strategy is of course lower risk and more affordable. But, for it to be effective, it also must be designed explicitly for extension and expansion. Ontology growth thus occurs both from learning and discovery and from expanding scope.
Versioning, version control and documentation (see below) thus assume more central importance than a more static view would suggest. The use of feedbacks and the continuous improvement design based on MIKE2.0 are therefore also central tenets of our ontology development methodology.
This perspective of the ontology as a way to capture the structure and relationships of a domain — which is also constantly changing and growing — carries over to the need to document the institutional memory and use of it. Both better tools — such as vocabulary management and versioning — and better work processes need to be instituted to properly capture and record use and applications of ontologies.
Some of these aspects are now handled with utilities such as OWLdoc or the TechWiki that Structured Dynamics has innovated to capture ontology knowledge bases on an ongoing basis. But these are still rudimentary steps that need to be enforced with management commitment and oversight.
One need merely begin to probe the ontology development literature to observe how sparse the pickings are. Very little information on methodologies, best practices, use cases, recipes, how to manuals, conversion and use steps and other documentation really exists at present. It is unfortunately the case that documentation even lags the inadequate state of tools development in the ontology space.
Once formalized, these constructs — the structured ontologies or the named entity dictionaries as shown in Figure 3 — are then used for processing input content. That processing can range from conversion to direct information extraction. Once extracted, the structure may be injected (via RDFa or other means) back into raw Web pages. The concepts and entities that occur within these structures help inform various tagging systems [23]. The information can also be converted and exported in various forms for direct use or for incorporation in third-party systems.
Visualization systems and specialized widgets (see next) can be driven by the structure and results sets obtained from querying the ontology structure and retrieving its related instance data. While these purposes are somewhat beyond the direct needs of the ontology development methodology, the ontology structures themselves must be designed to support these functions.
In our methodology we also provide for administrative ontologies whose purpose is to relate structural understandings of the underlying data and data types with applicable end-use and visualization tools (”widgets”). Thus the structural knowledge of the domain gets combined with an understanding of data types and what kinds of visualization or presentation widgets might be invoked. The phrase ontology-driven apps results from this design.
Amongst other utility ontologies, Structured Dynamics names its major tool-driver ontology the SCO (Semantic Component Ontology). The SCO works in intimate tandem with the domain ontologies, but is constructed and designed with quite different purposes. A description of the build methodology for the SCO (or its other complementary utility ontologies) is beyond the scope of this current document.
As sprinkled throughout the above commentary, this methodology is also intimately related to tools and best practices. The next chapter in this series is devoted to and will be archived on the TechWiki as the lightweight domain ontology methodology. Best practices will be handled in a similar way for the chapter after that one and in its ontology best practices document on the TechWiki.
Earlier reviews and the information in this document suggest a real need for ontology building methodologies that are integrated, easier to use, interoperate with a richer tools set and are geared to practitioners versus priests. The good news is that there are architectures and building blocks to achieve this vision. The bad news is that the first steps on this path are only now beginning.
The next two installments in this series add further detail for why it is time — and how — we can make a leap forward in methodology. Those critical remaining pieces are in tools and best practices.
The Recent Pace of Ontology Development Appears to Have WanedThe development of ontologies goes by the names of ontology engineering or ontology building, and can also be investigated under the rubric of ontology learning. This paper summarizes key papers and links to this topic [18].
For the last twenty years there have been many methods put forward for how to develop ontologies. These methodological activities have actually diminished somewhat in recent years.
The main thrust of the papers listed herein is on domain ontologies, which model particular domains or topic areas. (As opposed to reference, upper or theoretical ontologies, which are more general or encompassing.) Also, little commentary is offered on any of the individual methodologies; please see the referenced papers for more details.
One of the first comprehensive surveys was done by Jones et al. in 1998 [1]. This study began to elucidate common stages and noted there are typically separate stages to produce first an informal description of the ontology and then its formal embodiment in an ontology language. The existence of these two descriptions is an important characteristic of many ontologies, with the informal description often carrying through to the formal description.
The next major survey was done by Corcho et al. in 2003 [2]. This built on the earlier Jones survey and added more recent methods. The survey also characterized the methods by tools and tool readiness.
More recently the work of Simperl and her colleagues has focused on empirical results of ontology costing and related topics. This series has been the richest source of methodology insight in recent years [3, 4, 5, 6]. More on this work is described below.
Though not a survey of methods, one of the more attainable descriptions of ontology building is Noy and McGuinness’ well-known Ontology Development 101 [7]. Also really helpful are Alan Rector’s various lecture slides on ontology building [8].
However, one general observation is that the pace of new methodology development seems to have waned in the past five years or so. This does not appear to be the result of an accepted methodology having emerged.
Some of the leading methodologies, presented in rough order from the oldest to newest, are as follows:
Please note that many individual projects also describe their specific methodologies; these are purposefully not included. In addition, Ensan and Du look at some specific ontology frameworks (e.g., PROMPT, OntoLearn, etc.) from a domain-specific perspective [17].
Here is the general methodology as presented in the various Simperl et al. papers [c.f., Fig. 1 in 3]:
The Corcho et al. survey also presented a general view of the tools plus framework necessary for a complete ontology engineering environment [Fig. 4 from 2]:
There are more examples that show ontology development workflows. Here is one again from the Simperl et al. efforts [Fig. 2 in 5]:
However, what is most striking about the review of the literature is the paucity of methodology figures and the generality of those that do exist. From this basis, it is unclear what the degree of use is for real, actionable methods.
The Simperl and Tempich paper [3], besides being a rich source of references, also provides some recommended best practices based on their comparative survey. These are:
This review has not set out to characterize specific methodologies, nor their strengths and weaknesses. Yet the research seems to indicate this state of methodology development in the field:
At the beginning of this year Structured Dynamics assembled a listing of ontology building tools at the request of a client. That listing was presented as The Sweet Compendium of Ontology Building Tools. Now, again because of some client and internal work, we have researched the space again and updated the listing [1].
All new tools are marked with <New> (new only means newly discovered; some had yet to be discovered in the prior listing). There are now a total of 185 tools in the listing, 31 of which are recently new, and 45 added at various times since the first release. <Newest> reflects updates — most from the developers themselves — since the original publication of this post.
Though all are not relevant, see my post from a couple of years back on large-scale RDF graph software.
At the SemTech conference earlier this summer there was a kind of vuvuzela-like buzzing in the background. And, like the World Cup games on television, in play at the same time as the conference, I found the droning to be just as irritating.
That droning was a combination of the sense of righteousness in the superiority of linked data matched with a reprise of the “chicken-and-egg” argument that plagued the early years of semantic Web advocacy [1]. I think both of these premises are misplaced. So, while I have been a fan and explicator of linked data for some time, I do not worship at its altar [2]. And, for those that do, this post argues for a greater sense of ecumenism.
My main points are not against linked data. I think it a very useful technique and good (if not best) practice in many circumstances. But my main points get at whether linked data is an objective in itself. By making it such, I argue our eye misses the ball. And, in so doing, we miss making the connection with meaningful, interoperable information, which should be our true objective. We need to look elsewhere than linked data for root causes.
When I began this blog more than five years ago — and when I left my career in population genetics nearly three decades before that — I did so because of my belief in the value of information to confer adaptive advantage. My perspective then, and my perspective now, was that adaptive information through genetics and evolution was being uniquely supplanted within the human species. This change has occurred because humanity is able to record and carry forward all information gained in its experiences.
Adaptive innovations from writing to bulk printing to now electronic form uniquely position the human species to both record its past and anticipate its future. We no longer are limited to evolution and genetic information encoded in surviving offspring to determine what information is retained and moves forward. Now, all information can be retained. Further, we can combine and connect that information in ways that break to smithereens the biological limits of other species.
Yet, despite the electronic volumes and the potentials, chaos and isolated content silos have characterized humanity’s first half century of experience with digital information. I have spoken before about how we have been steadily climbing the data federation pyramid, with Internet technologies and the Web being prime factors for doing so. Now, with a compelling data model in RDF and standards for how we can relate any type of information meaningfully, we also have the means for making sense of it. And connecting it. And learning and adapting from it.
And, so, there is the answer to the rhetorical question: The problem we are solving is to meaningfully connect information. For, without those meaningful connections and recombinations, none of that information confers adaptive advantage.
One of the “chicken-and-egg” premises in the linked data community is there needs to be more linked data exposed before some threshold to trigger the network effect occurs. This attitude, I suspect, is one of the reasons why hosannas are always forthcoming each time some outfit announces they have posted another chunk of triples to the Web.
Fred Giasson and I earlier tackled that issue with When Linked Data Rules Fail regarding some information published for data.gov and the New York Times. Our observations on the lack of standards for linked data quality proved to be quite controversial. Rehashing that piece is not my objective here.
What is my objective is to hammer home that we do not need linked data in order to have data available to consume. Far from it. Though linked data volumes have been growing, I actually suspect that its growth has been slower than data availability in toto. On the Web alone we have searchable deep Web databases, JSON, XML, microformats, RSS feeds, Google snippets, yada, yada, all in a veritable deluge of formats, contents and contexts. We are having a hard time inventing the next 1000-fold description beyond zettabyte and yottabyte to even describe this deluge [3].
There is absolutely no voice or observer anywhere that is saying, “We need linked data in order to have data to consume.” Quite the opposite. The reality is we are drowning in the stuff.
Furthermore, when one dissects what most of all of this data is about, it is about ways to describe things. Or, put another way, most all data is not schema nor descriptions of conceptual relationships, but making records available, with attributes and their values used to describe those records. Where is a business located? What political party does a politician belong to? How tall are you? What is the population of Hungary?
These are simple constructs with simple key-value pair ways to describe and convey them. This very simplicity is one reason why naïve data structs or simple data models like JSON or XML have proven so popular [4]. It is one of the reasons why the so-called NoSQL databases have also been growing in popularity. What we have are lots of atomic facts, located everywhere, and representable with very simple key-value structures.
While having such information available in linked data form makes it easier for agents to consume it, that extra publishing burden is by no means necessary. There are plenty of ways to consume that data — without loss of information — in non-linked data form. In fact, that is how the overwhelming percentage of such data is expressed today. This non-linked data is also often easy to understand.
What is important is that the data be available electronically with a description of what the records contain. But that hurdle is met in many, many different ways and from many, many sources without any reference whatsoever to linked data. I submit that any form of desirable data available on the Web can be readily consumed without recourse to linked data principles.
The real advantage of RDF is the simplicity of its data model, which can be extended and augmented to express vocabularies and relationships of any nature. As I have stated before, that makes RDF like a universal solvent for any extant data structure, form or schema.
What I find perplexing, however, is how this strength somehow gets translated into a parallel belief that such a flexible data model is also the best means for transmitting data. As noted, most transmitted data can be represented through simple key-value pairs. Sure, at some point one needs to model the structural assumptions of the data model from the supplying publisher, but that complexity need not burden the actual transmitted form. So long as schema can be captured and modeled at the receiving end, data record transmittal can be made quite a bit simpler.
Under this mindset RDF provides the internal (canonical) data model. Prior to that, format and other converters can be used to consume the source data in its native form. A generalized representation for how this can work is shown in this diagram using Structured Dynamics‘ structWSF Web services framework middleware as the mediating layer:
Of course, if the source data is already in linked data form with understood concepts, relationships and semantics, much of this conversion overhead can be bypassed. If available, that is a good thing.
But it is not a required or necessary thing. Insistence on publishing data in certain forms suffers from the same narrowness as cultural or religious zealotry. Why certain publishers or authors prefer different data formats has a diversity of answers. Reasons can range from what is tried and familiar to available toolsets or even what is trendy, as one might argue linked data is in some circles today.There are literally scores of off-the-shelf “RDFizers” for converting native and simple data structs into RDF form. New converters are readily written.
Adaptive systems, by definition, do not require wholesale changes to existing practices and do not require effort where none is warranted. By posing the challenge as a “chicken-and-egg” one where publishers themselves must undertake a change in their existing practices to conform, or else they fail the “linked data threshold”, advocates are ensuring failure. There is plenty of useful structured data to consume already.
Accessible structured data, properly characterized (see below), should be our root interest; not whether that data has been published as linked data per se.
Linked data is nothing more than some techniques for publishing Web-accessible data using the RDF data model. Some have tried to use the concept of linked data as a replacement for the idea of the semantic Web, and some have recently tried to re-define linked data as not requiring RDF [5]. Yet the real issue with all of these attempts — correct or not, and a fact of linked data since first formulated by Tim Berners-Lee — is that a technique alone can not carry the burden of usefulness or interoperability.
Despite billions of triples now available, we in fact see little actual use or consumption of linked data, except in the life science domain. Indeed, a new workshop by the research community called COLD (Consuming Linked Data) has been set up for the upcoming ISWC conference to look into the very reasons why this lack of usage may be occurring [6].
It will be interesting to monitor what comes out of that workshop, but I have my own views as to what might be going on here. A number of factors, applicable frankly to any data, must be layered on top of linked data techniques in order for it to be useful:
These requirements apply to any data ranging from Census CSV files to Google search results. But because relationships can also be more readily asserted with linked data, these requirements are even greater for it.
It is not surprising that the life sciences have seen more uptake of linked data. That community has keen experience with curation, and the quality and linkages asserted there are much superior to other areas of linked data [7].
In other linked data areas, it is really in limited pockets such as FactForge from Ontotext or curated forms of Wikipedia by the likes of Freebase that we see the most use and uptake. There is no substitute for consistency and quality control.
It is really in this area of “publish it and they will come” that we see one of the threads of parochialism in the linked data community. You can publish it and they still will not come. And, like any data, they will not come because the quality is poor or the linkages are wrong.
As a technique for making data available, linked data is thus nothing more than a foot soldier in the campaign to make information meaningful. Elevating it above its pay grade sets the wrong target and causes us to lose focus for what is really important.
There is another strange phenomenon in the linked data movement: the almost total disregard for the linking part. Sure data is getting published as triples with dereferencable URIs, but where are the links?
At most, what we are seeing is owl:sameAs assertions and a few others [8]. Not only does this miss the whole point of linked data, but one can question whether equivalence assertions are correct in many instances [9].
For a couple of years now I have been arguing that the central gap in linked data has been the absence of context and coherence. By context I mean the use of reference structures to help place and frame what content is about. By coherence I mean that those contextual references make internal and logical sense, that they represent a consistent world view. Both require a richer use of links to concepts and subjects describing the semantics of the content.
It is precisely through these kinds of links that data from disparate sources and with different frames of reference can be meaningfully related to other data. This is the essence of the semantic Web and the purported purpose of linked data. And it is exactly these areas in which linked data is presently found most lacking.
Of course, these questions are not the sole challenge of linked data. They are the essential challenge in any attempt to connect or interoperate structured data within information systems. So, while linked data is ostensibly designed from the get-go to fulfill these aims, any data that can find meaning outside of its native silo must also be placed into context in a coherent manner. The unique disappointment for much linked data is its failure to provide these contexts despite its design.
Yet, having said all of this, Structured Dynamics is still committed to linked data. We present our information as such, and provide great tools for producing and consuming it. We have made it one of the seven foundations to our technology stack and methodology.
But we live in a pluralistic data world. There are reasons and roles for the multitude of popular structured data formats that presently exist. This inherent diversity is a fact in any real-world data context. Thus, we have not met a form of structured data that we didn’t like, especially if it is accompanied with metadata that puts the data into coherent context. It is a major reason why we developed the irON (instance record and object notation) non-RDF vocabulary to provide a bridge from such forms to RDF. irON clearly shows that entities can be usefully described and consumed in either RDF or non-RDF serialized forms.
Attitudes that dismiss non-linked data forms or arrogantly insist that publishers adhere to linked data practices are anything but pluralistic. They are parochial and short-sighted and are contributing, in part, to keeping the semantic Web from going mainstream.
Adoption requires simplicity. The simplest way to encourage the greater interoperability of data is to leverage existing assets in their native form, with encouragement for minor enhancements to add descriptive metadata for what the content is about. Embracing such an ecumenical attitude makes all publishers potentially valuable contributors to a better information future. It will also nearly instantaneously widen the tools base available for the common objective of interoperability.
Linked data is a good thing, but not an ultimate thing. By making linked data an objective in itself we unduly raise publishing thresholds; we set our sights below the real problem to be solved; and we risk diluting the understanding of RDF from its natural role as a flexible and adaptive data model. Paradoxically, too much parochial insistence on linked data may undercut its adoption and the realization of the overall semantic objective.
Root cause analysis for what it takes to achieve meaningful, interoperable information suggests that describing source content in terms of what it is about is the pivotal factor. Moreover, those contexts should be shared to aid interoperability. Whichever organizations do an excellent job of providing context and coherent linkages will be the go-to ones for data consumers. As we have seen to date, merely publishing linked data triples does not meet this test.
I have heard some state that first you celebrate linked data and its growing quantity, and then hope that the quality improves. This sentiment holds if indeed the community moves on to the questions of quality and relevance. The time for that transition is now. And, oh, by the way, as long as we are broadening our horizons, let’s also celebrate properly characterized structured data no matter what its form. Pluralism is part of the tao to the meaning of information.
Ontologies are the structural frameworks for organizing information on the semantic Web and within semantic enterprises. They provide unique benefits in discovery, flexible access, and information integration due to their inherent connectedness; that is, their ability to represent conceptual relationships. Ontologies can be layered on top of existing information assets, which means they are an enhancement and not a displacement for prior investments. And ontologies may be developed and matured incrementally, which means their adoption may be cost-effective as benefits become evident [1].
Ontology may be one of the more daunting terms for those exposed for the first time to semantic technologies. Not only is the word long and without common antecedents, but it is also a term that has widely divergent use and understanding within the community. It can be argued that this not-so-little word is one of the barriers to mainstream understanding of the semantic Web.
The root of the term is the Greek ontos, or being or the nature of things. Literally — and in classical philosophy — ontology was used in relation to the study of the nature of being or the world, the nature of existence. Tom Gruber, among others, made the term popular in relation to computer science and artificial intelligence about 15 years ago when he defined ontology as a “formal specification of a conceptualization.”
Much like taxonomies or relational database schema, ontologies work to organize information. No matter what the domain or scope, an ontology is a description of a world view. That view might be limited and miniscule, or it might be global and expansive. However, unlike those alternative hierarchical views of concepts such as taxonomies, ontologies often have a linked or networked “graph” structure. Multiple things can be related to other things, all in a potentially multi-way series of relationships.
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| A distinguishing characteristic of ontologies compared to conventional hierarchical structures is their degree of connectedness, their ability to model coherent, linked relationships |
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Ontologies supply the structure for relating information to other information in the semantic Web or the linked data realm. Ontologies thus provide a similar role for the organization of data that is provided by relational data schema. Because of this structural role, ontologies are pivotal to the coherence and interoperability of interconnected data.
When one uses the idea of “world view” as synonomous with an ontology, it is not meant to be cosmic, but simply a way to convey how a given domain or problem area can be described. One group might choose to describe and organize, say, automobiles, by color; another might choose body styles such as pick-ups or sedans; or still another might use brands such as Honda and Ford. None of these views is inherently “right” (indeed multiples might be combined in a given ontology), but each represents a particular way — a “world view” — of looking at the domain.
Though there is much latitude in how a given domain might be described, there are both good ontology practices and bad ones. We offer some views as to what constitutes good ontology design and practice in the concluding section.
A good ontology offers a composite suite of benefits not available to taxonomies, relational database schema, or other standard ways to structure information. Among these benefits are:
The relationship structure underlying an ontology provides an excellent vehicle for discovery and linkages. “Swimming through” this relationship graph is the basis of the Concept Explorer (also known as the Relation Browser) and similar widgets.
The most prevalent use of ontologies at present is in semantic search. Semantic search has benefits over conventional search in terms of being able to make inferences and matches not available to standard keyword retrieval.
The relationship structure also is a powerful and more general and more nuanced way to organize information. Concepts can relate to other concepts through a richness of vocabulary. Such predicates might capture subsumption, precedence, parts of relationships (mereology), preferences, or importances along virtually any metric. This richness of expression and relationships can also be built incrementally over time, allowing ontologies to grow and develop in sophistication and use as desired.
The pinnacle application for ontologies, therefore, is as coherent reference structures whose purpose is to help map and integrate other structures and information. Given the huge heterogeneity of information both within and without organizations, the use of ontologies as integration frameworks will likely emerge as their most valuable use.
Good ontology practice has aspects both in terms of scope and in terms of construction.
Here are some scoping and design questions that we believe should be answered in the positive in order for an ontology to meet good practice standards:
If these questions can be answered affirmatively, then we would deem the ontology ready for production-grade use.
Fundamental to the whole concept of coherence is the fact that experts and practitioners within domains have been looking at the questions of relationships, structure, language and meaning for decades. Though perhaps today we now finally have a broad useful data and logic model in RDF, the fact remains that massive time and effort has already been expended to codify some of these understandings in various ways and at various levels of completeness and scope. Good practice also means, therefore, that maximum leverage is made to springboard ontologies from existing structural and vocabulary assets.
And, because good ontologies also embrace the open world approach, working toward these desired end states can also be incremental. Thus, in the face of common budget or deadline constraints, it is possible initially to scope domains as smaller or to provide less coverage in depth or to use a small set of predicates, all the while still achieving productive use of the ontology. Then, over time, the scope can be expanded incrementally.
To achieve their purposes, ontologies must be both human-readable and machine-processable. Also, because they represent conceptual structures, they must be built with a certain composition.
Good ontologies therefore are constructed such that they have:
In the case of ontology-driven applications using adaptive ontologies, there are also additional instructions contained in the system (often via administrative ontologies) that tell the system which types of widgets need to be invoked for different data types and attributes. This is different than the standard conceptual schema, but is nonetheless essential to how such applications are designed.
Today, Structured Dynamics is pleased to make its Citizen Dan application available for public viewing, play and downloading for the first time.
Citizen Dan is a free, open source system available to any community and its citizens to measure and track indicators of local well being. It can be branded and themed for local needs. It is under active development by Structured Dynamics with support from a number of innovative cities.
Citizen Dan is an exemplar instance of Structured Dynamics’ open semantic framework (OSF), a generalized framework for deploying semantic platforms for any domain. By changing its guiding ontologies and source content and data, what appears for Citizen Dan can be adopted for virtually any subject area.
As configured, the Citizen Dan OSF instance is a:
Citizen Dan’s information sources may include Census data, the Web, real-time feeds, government datasets, municipal government information systems, or crowdsourced data. Information can range from standard structured data to local narratives, including from minutes and reports, contributed stories, blogs or news outlets. The ‘raw’ input data can come in essentially any format, which is then converted to a standard form with consistent semantics.
Text and narratives and the concepts and entities they describe are integrally linked into the system via information extraction and tagging. All ingested information, whether structured or text sources, with their semantics, can be exported in multiple formats. A standard organizing schema, also open source and extensible or modifiable by all users, is provided via the optional MUNI ontology (with vocabulary details in development here), being developed expressly for Citizen Dan and its community indicator system purposes.
All of the community information contained within a Citizen Dan instance is available as linked data.
Here are the main components or widgets to this Citizen Dan demo:
the exporter component appears in multiple locations across the appliance, either as a tab option (e.g., Filter component) or as a dropdown list to the lower right of many screens. A variety (and growing!) number of export formats are available. When it appears as a dropdown list, the export is limited to the currently active slice. When invoked via tab, more export selection options are available. See further the technical documentation for this componentA number of other tools are available to admins in the actual appliance, but are not exposed in the demo:
In addition, it is not possible in the demo to save persistent dashboard views or submit stories or documents for tagging, nor to register as a user or view the admin portions of the Drupal instance.
The sample data and content in the demo is for the Iowa City (IA) metropolitan statistical area. This area embraces two counties (Johnson and Washington) and the census tracts and townships that comprise them, and about two dozen cities. Two of the notable cities are Iowa City itself, home of the University of Iowa, and Coralville, where Structured Dynamics, the developer of Citizen Dan and the open semantic framework (OSF), is headquartered.
The text content on this site is drawn from Wikipedia articles dealing with this area. About 30 stories are included.
The data content on the site is drawn from US Census Bureau data. Shape files for the various geographic areas were obtained from here, and the actual datasets by geographic area can be obtained from here.
Citizen Dan is an exemplar instance of Structured Dynamics’ open semantic framework (OSF), a generalized framework for deploying semantic platforms for specific domains.
OSF is a combination of a layered architecture and modular software. Most of the individual open source software products developed by Structured Dynamics and available on the OpenStructs site are components within the open semantic framework. These include:
The software that makes up the Citizen Dan appliance is one of the four legs that provide a stable, open source solution. These four legs are software, structure, methods and documentation. When all four are provided, we can term this a total open solution.
For Citizen Dan, the complements to this software are:
In its entirety, the total open solution amounts to a form of capacity building for the enterprise.
Inherent in the design and architecture of Citizen Dan is the potential for each instance (single installation) to act as a node in a distributed network of nodes across the Web. Via the structWSF Web service endpoints and appropriate dataset permissions, it is possible for any city in the Citizen Dan network to share (or not) any or all of its data with other cities.
This collaboration aspect has been “baked into the cake” from Day One. The system also supports differential access, rights and roles by dataset and Web service. Thus, city staffs across multiple communities could share data differently than what is provided to the general public.
Since all data management aspects of each Citizen Dan instance is also oriented around datasets, expansion to a network mode is quite straightforward.
The Citizen Dan appliance is based on the Drupal content management system, which means any community can easily theme or add to the functionality of the system with any of the available 6500 open source modules that extend the basic Drupal functionality.
All other components, including the multiple third-party ones, are also open source.
To install Citizen Dan for your own use, you need to:
(Note: there will also be some more updates in August, including the MUNI release.)
For questions and additional info, please consult the TechWiki or the OpenStructs community site.
Finally, please contact us if you’d like to learn more about the project, investigate funding or sponsorship opportunities, or contribute to development. We’d welcome your involvement!
A few weeks back I completed a three-part introductory series to what Structured Dynamics calls a ‘total open solution‘. A total open solution as we defined it is comprised of software, structure, methods and documentation. When provided in toto, these components provide all of the necessary parts for an organization to adopt new open source solutions on its own (or with the choice of its own consultants and contractors). A total open solution fulfills SD’s mantra that, “We’re successful when we’re not needed.”
Two of the four legs to this total open solution are provided by documentation and methods. These two parts can be seen as a knowledge base that instructs users on how to select, install, maintain and manage the solution at hand.
Today, SD is releasing publicly for the first time two complementary knowledge bases for these purposes: TechWiki, which is the technical and software documentation complement, in this case based around SD’s Open Semantic Framework and its associated open source software projects; and DocWiki, the process methodology and project management complement that extends this basis, in this case based around the Citizen Dan local community open data appliance.
All of the software supporting these initiatives is open source. And, all of the content in the knowledge bases is freely available under a Creative Commons 3.0 license with attribution.
In setting out the design of these knowledge bases, our mindset was to enable single-point authoring of document content, while promoting easy collaboration and rollback of versions. Thus, the design objectives became:
Assuming these objectives could be met, we then had three other objectives on our wish list:
Our initial investigations looked at conventional content and document management systems, matched with version control systems or SVNs. Somewhat surprisingly, though, we found the Mediawiki platform to fulfill all of our objectives. Mediawiki, as detailed below, has evolved to become a very mature and capable documentation platform.
While most of us know Mediawiki as a kind of organic authoring and content platform — as it is used on Wikipedia and many other leading wikis — we also found it perfect for our specific knowledge base purposes. To our knowledge, no one has yet set up and deployed Mediawiki in the specific pre-packaged knowledge base manner as described herein.
TechWiki is a Mediawiki instance designed to support the collaborative creation of technical knowledge bases. The TechWiki design is specifically geared to produce high-quality, comprehensive technical documentation associated with the OpenStructs open source software. This knowledge base is meant to be the go-to source for any and all documentation for the codes, and includes information regarding:
As of today, TechWiki contains 187 articles under 56 categories, with a further 293 images. The knowledge base is growing daily.
DocWiki is a sibling Mediawiki instance that contains all TechWiki material, but has a broader purpose. Its role is to be a complete knowledge base for a given installation of an Open Semantic Framework (in the current case, Citizen Dan). As such, it needs to include much of the technical information in the TechWiki, but also extends that in the following areas:
The methodology portions of the DocWiki are drawn from the broader MIKE2.0 (Method for Integrated Knowledge Environments) approach. I have previously written about this open source methodology championed by Bearing Point and Deloitte.
As of today, DocWiki contains 357 articles and 394 structured tasks in 70 activity areas under 77 categories. Another 115 images support this content. This knowledge base, too, is growing daily.
Both of these knowledge bases are open source and may be exported and installed locally. Then, users may revise and modify and extend that pre-packaged information in any way they see fit.
The basic design of these systems is geared to collaboration and embeds what we think are really responsive work flows. These extend from supporting initial idea noodling to full-blown public documentation. The inherent design of the system also supports single-source publishing and book or PDF creation from the material that is there. Here is the basic overview of the design:
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Mediawiki provides the standard authoring and collaboration environment. There are a choice of editing methods. As content is created, it is organized in a standard way and stored in the knowledge base. The Mediawiki API supports the export of information in either XHTML or XML, which in turn allows the information to be used in external apps (including other Mediawiki instances) or for various single-source publication purposes. The Collection extension is one means by which PDFs or even entire books (that is, multi-page documents with potentially chapters, etc.) may be created. Use of a well-designed CSS ensures that outputs can be readily styled and themed for different purposes or audiences.
As wikis designed from the get-go to be reusable, and then downloaded and installed locally, it is important that we maintain quality and consistency across content. (After download, users are free to do with it as they wish, but it is important the initial database be clean and coherent.) The overall interaction with the content thus occurs via one of three levels: 1) simple reading, which is publicly available without limitation to any visitor, including source inspection and export; 2) editing and authoring, which is limited to approved contributors; and 3) draft authoring and noodling, which is limited to the group in #2 but for which the in-progress content is not publicly viewable. Built-in access rights in the system enable these distinctions.
Besides meeting all of the objectives noted at the opening of this post, these wikis (knowledge bases) also have these specific features:
Many of these features come from the standard extensions in the TechWiki/DocWiki packages.
The net benefits from this design are easily shared and modified knowledge bases that users and organizations may either contribute to for the broader benefit of the OpenStructs community, or download and install with simple modifications for local use and extension. There is actually no new software in this approach, just proper attention to packaging, design, standardization and workflow.
Via the sharing of extensions, categories and CSS, it is quite easy to have multiple instances or authoring environments in this design. For Structured Dynamics, that begins with our own internal wiki. Many notes are taken and collected there, some of a proprietary nature and the majority not intended or suitable for seeing public release.
Content that has developed to the point of release, however, can be simply tagged using conventions in the workflow. Then, with a single Export command, the relevant content is then sent to an XML file. (This document can itself be edited, such as for example changing all ‘TechWiki’ references to something like ‘My Content Site’; see further here.)
Depending on the nature of the content, this exported content may then be imported with a single Import command to either the TechWiki or DocWiki sites. (Note: Import does require admin rights.) A simple migration may also occur from the TechWiki to the DocWiki. Also, of course, initial authoring may begin at any of the sites, with collaborators an explicit feature of the TechWiki or DocWiki versions.
Any DocWiki can also be specifically configured for different domains and instance types. In terms of our current example, we are using Citizen Dan, but that could be any such Open Semantic Framework instance type:
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Under this design, then, the workflow suggests that technical content authoring and revision take place within the TechWiki, process and methodology revision in the DocWiki. Moreover, most DocWikis are likely to be installed locally, such that once installed, their own content would likely morph into local methods and steps.
So long as page titles are kept the same, newer information can be updated on any target wiki at any time. Prior versions are kept in the version history and can be reinstated. Alternatively, if local content is clearly diverging yet updates of initial source material is still desired, the local content need only be saved under a new title to preserve it from import overwrites.
We are really excited by this design and have already seen benefits in our own internal work and documentation. We see, for example, easier management of documentation and content, permanent (canonical) URLs for specific content items, and greater consistency and common language across all projects and documentation. Also, when all documentation is consolidated into one point with a coherent organizational and category structure, documentation gaps and inconsistencies also become apparent and can readily be fixed.
Now, with the release of these systems to the OpenStructs (Open Semantic Framework) and Citizen Dan communities, we hope to see broader contributions and expansion of the content. We encourage you to check on these two sites periodically to see how the content volume continues to grow! And, we welcome all project contributors to join in and help expand these knowledge bases!
We think this general design and approach — especially in relation to a total open solution mindset — has much to recommend it for other open source projects. We think these systems, now that we have designed and worked out the workflows, are amazingly simple to set up and maintain. We welcome other projects to adopt this approach for their own. Let us know if we can be of assistance, and we welcome ideas for improvement!
Like the seminal linked data publication by PricewaterhouseCoopers of about a year ago (see “PWC Dedicates Quarterly Technology Forecast to Linked Data“, May 29, 2009), a video released by Cisco yesterday is another signal of the emergence of the semantic enterprise.
The Cisco tech brief on The Semantic Enterprise is a quite accessible — but a bit eerie — seven-minute introduction. The video was prepared by Cisco’s Internet Business Solutions Group (IBSG), with Shaun Kirby, its Director of Innovations Architectures, as the narrator:
| YouTube: http://www.youtube.com/watch?v=3lUzs2I8BKI |
Well, as for being eerie, when the video first came up, I thought I was looking at an advanced, next generation avatar, perhaps a reincarnation of Douglas Adams’ Hyperland. Maybe this semantic stuff was closer at hand than we thought!
But, as it turned out, that first blush was only a reaction to how the video was shot. As it gets rolling, the Cisco video is extremely well done and informative. It is a great intro for sharing with management when contemplating your own moves to becoming a semantic enterprise.
I suggest you first view — and then bookmark — this one.
