Planet RDF

I decided to follow the example of

Extract Structured Content, Tag Concepts & Entities

Cognonto is brand new. At its core, it uses a structure of nearly 40 000 concepts. It has about 138,000 links to external classes and concepts that defines huge public datasets such as Wikipedia, DBpedia and USPTO. Cognonto is not a children’s toy. It is huge and complex… but it is very usable. Before digging into the structure itself, before starting to write about all the use cases that Cognonto can support, I will first cover all of the tools that currently exist to help you understand Cognonto and its conceptual structure and linkages (called KBpedia).

The embodiment of Cognonto that people can see are the tools we created and that we made available on the cognonto.com web site. Their goal is to show the structure at work, what ties where, how the conceptual structure and its links to external schemas and datasets help discover new facts, how it can drive other services, etc.

This initial blog post will discuss the demo section of the web site. What we call the Cognonto demo is a web page crawler that analyzes web pages to tag concepts, to tag named entities, to extract structured data, to detect language, to identity topics, and so forth. The demo uses the KBpedia structure and its linkages to Wikipedia, Wikidata, Freebase and USPTO to tag content that appears in the analyzed web pages. But there is one thing to keep in mind: the purpose of Cognonto is to link public or private datasets to the structure to expand its knowledge and make these tools (like the demo) even more powerful. This means that a private organization could use Cognonto, add their own datasets and link their own schemas, to improve their own version of Cognonto or to tailor it for their own purpose.

Let’s see what the demo looks like, what is the information it extracts and analyzes from any web page, and how it ties into the KBpedia structure.

I am proud to announce the start of a new venture called Cognonto. I am particularly proud of it because even if it is just starting, it is in fact more than eight years old. It is the embodiment of eight years of research, of experimentation, of a big deal of frustration and of great joy with my long-time partner Mike.

Eight years ago, we set a 5-to-10-year vision for our work as partners. We defined an initial series of technological goals for which we outlined a series of yearly milestones. The goals were related to help solving decades old problems with data integration and interoperability using a completely new research field (at the time): the Semantic Web.

And there we are eight years later, after working for an endless number of hours to create all kinds of different projects and services to pay for the research and the pieces of technologies we develop for these purposes. Cognonto is the embodiment of that effort, but it also created a series of other purposeful projects such as the creation of Stuctured Dynamics, UMBEL, the Open Semantic Framework and a series of other open source collaterals.

We spent eight years to create, sanitize, to make coherent and consistent, to generate and regenerate a conceptual structure of now 38,930 reference concepts with 138,868 mapping links to 27 external schemas, vocabularies and datasets. This led to the creation of KBpedia, which is the knowledge graph that drives Cognonto. The full statistics are available here.

I can’t thank Mike enough for this long and wonderful journey that led to the creation of Cognonto. I sent him an endless number of concepts lists that he diligently screened, assessed and mapped. We spent hundred of hours to discuss the knots and bolts of the structure, to argue about its core concepts and how it should be defined and used. It was not without pain, but I believe that the result is truly astonishing.

I won’t copy/paste the Cognonto press release here, a link will suffice. I it is just not possible for me to write a better introduction than the two pagers that Mike wrote for the press release. I would also suggest that you read his Cognonto introduction blog post: Cognonto is on the Hunt for Big AI Game.

In the coming weeks, I will write a lot about Cognonto, what it is, how it can be used, what are its use cases, how the information that is presented in the demo and the knowledge graph sections should be interpreted and what these pages tell you.

I was really pleased to see that at the GODAN Summit last week

One of the recent projects we’ve done at

I’ve been interviewed a couple of times recently by people interested in understanding how best to publish data to make it useful for others.  Once by a startup and a couple of times by researchers. The core of the discussion has essentially been the same question: “how do you know if a dataset will be useful to you?”

I’ve given essentially the same answer each time. When I’m sifting through dataset descriptions, either in a portal or via a web search, my first stage of filtering involves looking for:

1. A brief summary of the dataset: e.g. a title and a description
2. The licence
3. Some idea of its coverage, e.g. geographic coverage, scope of time series, level of aggregation, etc
4. Whether it’s in a usable format

Beyond, that there’s a lot more that I’m interested in: the provenance of the data, its timeliness and a variety of quality indicators. But those pieces of information are what I’m looking for right at the start. I’ll happily jump through hoops to massage some data into a better format. But if the licence or coverage isn’t right then its useless to me.

We can frame these as questions:

1. What is it? (Description)
2. Can I use it? (Licence)
3. Will it help answer my question? (in whole, or  part)
4. How difficult will it be to use? (format, technical characteristics)

It’s frustrating how often these essentials aren’t readily available.

Here’s an example of why this is important.

A weather data example

I’m currently working on a project that needs access to local weather observations. I want openly licensed temperature readings for my local area.

My initial port of call was the

On the upcoming Monday (05.09.2016), AKSW group will discuss topics related to Semantic Web and LOD Cloud Statistics. Also, we will have invited speaker from University of Leipzig Library (UBL) Dr. Astrid Vieler talking about OpenAccess at Leipzig University.

LODStats: The Data Web Census Dataset

by Ivan Ermilov et al.
Presented by: Ivan Ermilov

Abstract: Over the past years, the size of the Data Web has increased significantly, which makes obtaining general insights into its growth and structure both more challenging and more desirable. The lack of such insights hinders important data management tasks such as quality, privacy and coverage analysis. In this paper, we present the LODStats dataset, which provides a comprehensive picture of the current state of a significant part of the Data Web. LODStats is based on RDF datasets from data.gov, publicdata.eu and datahub.io data catalogs and at the time of writing lists over 9 000 RDF datasets. For each RDF dataset, LODStats collects comprehensive statistics and makes these available in adhering to the LDSO vocabulary. This analysis has been regularly published and enhanced over the past five years at the public platform lodstats.aksw.org. We give a comprehensive overview over the resulting dataset.

OpenAccess at Leipzig University

Invited talk by Dr. Astrid Vieler from Leipzig University Library (UBL). The talk will be about Open Access in general and the Open Access Policy of our University in special. She will tell us more about our right, which we have toward the publishers, and she gives us advice and hints on how we can increase the visibility of our publications.

After the talks, there is more time for discussion in smaller groups as well as coffee and cake. The colloquium starts at 3 p.m. and is located on 7th floor (Leipzig, Augustusplatz 10, Paulinum).

The Winnipeg City’s NOW (Neighbourhoods Of Winnipeg) Portal is an initiative to create a complete neighbourhood web portal for its citizens. At the core of the project we have a set of about 47 fully linked, integrated and structured datasets of things of interests to Winnipegers. The focal point of the portal is Winnipeg’s 236 neighbourhoods, which define the main structure of the portal. The portal has six main sections: topics of interests, maps, history, census, images and economic development. The portal is meant to be used by citizens to find things of interest in their neibourhood, to learn their history, to see the images of the things of interest, to find tools to help economic development, etc.

The NOW portal is not new; Structured Dynamics was also its main technical contractor for its first release in 2013. However we just finished to help Winnipeg City’s NOW team to migrate their older NOW portal from OSF 1.x to OSF 3.x and from Drupal 6 to Drupal 7; we also trained them on the new system. Major improvements accompany this upgrade, but the user interface design is essentially the same.

The first thing I will do is to introduce each major section of the portal and I will explain the main features of each. Then I will discuss the new improvements of the portal.

The 12th edition of the SEMANTiCS, which is a well known platform for professionals and researchers who make semantic computing work, will be held in the city of Leipzig from September 12th till 15th. We are proud to announce the final program of the SEMANTiCS conference. The program will cover 6 keynote speakers, 40 industry presentations, 30 scientific paper presentations, 40 poster & demo presentations and a huge number of satellite events. Special talks will given by Thomas Vavra from IDC and Sören Auer, who will feature the LEDS track. On top of that there will be a fishbowl session ‘Knowledge Graphs – A Status Update’ with lightning talks from Hans Uszkoreit (DFKI) and Andreas Blumenauer (SWC). This week, the set of our distinguished keynote speakers has been fixed and we are quite excited to have them at this years’ edition of SEMANTiCS. Please join us to listen to talks from representatives from IBM, Siemens, Springer Nature, Wikidata, International Data Corporation (IDC), Fraunhofer IAIS, Oxford University Press and the Hasso-Plattner-Institut, who will share their latest insights on applications of Semantic technologies with us. To register and be part of the SEMANTiCS 2016 in Leipzig, please go to: http://2016.semantics.cc/registration.

Share your ideas, tools and ontologies, last minute submissions
Meetup: Big Data & Linked Data – The Best of Both Worlds  

On the first eve of the SEMANTiCS conference we will discuss how Big Data & Linked Data technologies could become a perfect match. This meetup gathers experts on Big and Linked Data to discuss the future agenda on research and implementation of a joint technology development.

• Register (free)

• If you are interested to present your idea, approach or project which links Semantic technologies with Big Data in an ad-hoc lightning talk, please get in touch with Thomas Thurner (t.thurner@semantic-web.at).

WORKSHOPS/TUTORIALS

This year’s SEMANTiCS is starting on September 12th with a full day of exciting and interesting satellite events. In 6 parallel tracks scientific and industrial workshops and tutorials are scheduled to provide a forum for groups of researchers and practitioners to discuss and learn about hot topics in Semantic Web research.

• Registration (free)

How to find users and feedback for your vocabulary or ontology?

The Vocabulary Carnival is a unique opportunity for vocabulary publishers to showcase and share their work in form of a poster and a short presentation, meet the growing community of vocabulary publishers and users to build useful semantic, technical and social links. You can join the Carnival Minute Madness on the 13th of September.

• Submit your vocabulary to the VOCARNIVAL here: http://2016.semantics.cc/vocarnival/submission

• More info: http://2016.semantics.cc/vocarnival

How to submit to ELDC?

The European Linked Data Contest awards prizes to stories, products, projects or persons presenting novel and innovative projects, products and industry implementations involving linked data. The ELDC is more than yet another competition. We envisage to build a directory of the best European projects in the domain of Linked Data and the Semantic Web. This year the ELDC is awarded in the categories Linked Enterprise Data and Linked Open Data, with €1.500,- for each of the winners. Submission deadline is August 31, 2016.

• Submit your product, story or project here: http://2016.semantics.cc/eldc

7th DBpedia Community Meeting in Leipzig 2016

Co-located with SEMANTiCS, the next DBpedia meeting will be held at Leipzig on September 15th. Experts will speak about topics such as Wikidata: bringing structured data to Wikipedia with 16.000 volunteers. The 7th edition of this event covers a DBpedia showcase session, breakout sessions and a DBpedia Association meeting where we will discuss new strategies and which direction is important for DBpedia. If you like to become part of the DBpedia community and present your ideas, please submit your proposal or check our meeting website: http://wiki.dbpedia.org/meetings/Leipzig2016

Sponsorship  opportunities

We would be delighted to welcome new sponsors for SEMANTiCS 2016. You will find a number of sponsorship packages with an indication of benefits and prices here: http://semantics.cc/sponsorship-packages.

Special offer: You can buy a special SEMANTiCS industry ticket for €400 which includes a poster presentation at our marketplace. So take the opportunity to increase the visibility of your company, organisation or project among an international and high impact community. If you are interested, please contact us via email to semantics2016@fu-confirm.de.  

Things, not Strings
Entity-centric views on enterprise information and all kinds of data sources provide means to get a more meaningful picture about all sorts of business objects. This method of information processing is as relevant to customers, citizens, or patients as it is to knowledge workers like lawyers, doctors, or researchers. People actually do not search for documents, but rather for facts and other chunks of information to bundle them up to provide answers to concrete questions.

Strings, or names for things are not the same as the things they refer to. Still, those two aspects of an entity get mixed up regularly to nurture the Babylonian language confusion. Any search term can refer to different things, therefore also Google has rolled out its own knowledge graph to help organizing information on the web at a large scale.

Semantic graphs can build the backbone of any information architecture, not only on the web. They can enable entity-centric views also on enterprise information and data. Such graphs of things contain information about business objects (such as products, suppliers, employees, locations, research topics, …), their different names, and relations to each other. Information about entities can be found in structured (relational databases), semi-structured (XML), and unstructured (text) data objects. Nevertheless, people are not interested in containers but in entities themselves, so they need to be extracted and organized in a reasonable way.

Machines and algorithms make use of semantic graphs to retrieve not only simply the objects themselves but also the relations that can be found between the business objects, even if they are not explicitly stated. As a result, ‘knowledge lenses’ are delivered that help users to better understand the underlying meaning of business objects when put into a specific context.

Personalization of information
The ability to take a view on entities or business objects in different ways when put into various contexts is key for many knowledge workers. For example, drugs have regulatory aspects, a therapeutical character, and some other meaning to product managers or sales people. One can benefit quickly when only confronted with those aspects of an entity that are really relevant in a given situation. This rather personalized information processing has heavy demand for a semantic layer on top of the data layer, especially when information is stored in various forms and when scattered around different repositories.

Understanding and modelling the meaning of content assets and of interest profiles of users are based on the very same methodology. In both cases, semantic graphs are used, and also the linking of various types of business objects works the same way.

Recommender engines based on semantic graphs can link similar contents or documents that are related to each other in a highly precise manner. The same algorithms help to link users to content assets or products. This approach is the basis for ‘push-services’ that try to ‘understand’ users’ needs in a highly sophisticated way.

‘Not only MetaData’ Architecture
Together with the data and content layer and its corresponding metadata, this approach unfolds into a four-layered information architecture as depicted here.

Following the NoSQL paradigm, which is about ‘Not only SQL’, one could call this content architecture ‘Not only Metadata’, thus ‘NoMeDa’ architecture. It stresses the importance of the semantic layer on top of all kinds of data. Semantics is no longer buried in data silos but rather linked to the metadata of the underlying data assets. Therefore it helps to ‘harmonize’ different metadata schemes and various vocabularies. It makes the semantics of metadata, and of data in general, explicitly available. While metadata most often is stored per data source, and therefore not linked to each other, the semantic layer is no longer embedded in databases. It reflects the common sense of a certain domain and through its graph-like structure it can serve directly to fulfill several complex tasks in information management:

• Knowledge discovery, search and analytics
• Information and data linking
• Recommendation and personalization of information
• Data visualization

Graph-based Data Modelling
Graph-based semantic models resemble the way how human beings tend to build their own models of the world. Any person, not only subject matter experts, organize information by at least the following six principles:

1. Draw a distinction between all kinds of things: ‘This thing is not that thing’
2. Give things names: ‘This thing is my dog Goofy’ (some might call it Dippy Dawg, but it’s still the same thing)
3. Categorize things: ‘This thing is a dog but not a cat’
4. Create general facts and relate categories to each other: ‘Dogs don’t like cats’
5. Create specific facts and relate things to each other: ‘Goofy is a friend of Donald’, ‘Donald is the uncle of Huey, Dewey, and Louie’, etc.
6. Use various languages for this; e.g. the above mentioned fact in German is ‘Donald ist der Onkel von Tick, Trick und Track’ (remember: the thing called ‘Huey’ is the same thing as the thing called ‘Tick’ – it’s just that the name or label for this thing that is different in different languages).

These fundamental principles for the organization of information are well reflected by semantic knowledge graphs. The same information could be stored as XML, or in a relational database, but it’s more efficient to use graph databases instead for the following reasons:

• The way people think fits well with information that is modelled and stored when using graphs; little or no translation is necessary.
• Graphs serve as a universal meta-language to link information from structured and unstructured data.
• Graphs open up doors to a better aligned data management throughout larger organizations.
• Graph-based semantic models can also be understood by subject matter experts, who are actually the experts in a certain domain.
• The search capabilities provided by graphs let you find out unknown linkages or even non-obvious patterns to give you new insights into your data.
• For semantic graph databases, there is a standardized query language called SPARQL that allows you to explore data.
• In contrast to traditional ways to query databases where knowledge about the database schema/content is necessary, SPARQL allows you to ask “tell me what is there”.

Standards-based Semantics
Making the semantics of data and metadata explicit is even more powerful when based on standards. A framework for this purpose has evolved over the past 15 years at W3C, the World Wide Web Consortium. Initially designed to be used on the World Wide Web, many enterprises have been adopting this stack of standards for Enterprise Information Management. They now benefit from being able to integrate and link data from internal and external sources with relatively low costs.

At the base of all those standards, the Resource Description Framework (RDF) serves as a ‘lingua franca’ to express all kinds of facts that can involve virtually any kind of category or entity, and also all kinds of relations. RDF can be used to describe the semantics of unstructured text, XML documents, or even relational databases. The Simple Knowledge Organization System (SKOS) is based on RDF. SKOS is widely used to describe taxonomies and other types of controlled vocabularies. SPARQL can be used to traverse and make queries over graphs based on RDF or standard schemes like SKOS.

With SPARQL, far more complex queries can be executed than with most other database query languages. For instance, hierarchies can be traversed and aggregated recursively: a geographical taxonomy can then be used to find all documents containing places in a certain region although the region itself is not mentioned explicitly.

Standards-based semantics also helps to make use of already existing knowledge graphs. Many government organisations have made available high-quality taxonomies and semantic graphs by using semantic web standards. These can be picked up easily to extend them with own data and specific knowledge.

Semantic Knowledge Graphs will grow with your needs!
Standards-based semantics provide yet another advantage: it is becoming increasingly simpler to hire skilled people who have been working with standards like RDF, SKOS or SPARQL before. Even so, experienced knowledge engineers and data scientists are a comparatively rare species. Therefore it’s crucial to grow graphs and modelling skills over time. Starting with SKOS and extending an enterprise knowledge graph over time by introducing more schemes and by mapping to other vocabularies and datasets over time is a well established agile procedure model.

A graph-based semantic layer in enterprises can be expanded step-by-step, just like any other network. Analogous to a street network, start first with the main roads, introduce more and more connecting roads, classify streets, places, and intersections by a more and more distinguished classification system. It all comes down to an evolving semantic graph that will serve more and more as a map of your data, content and knowledge assets.

Semantic Knowledge Graphs and your Content Architecture
It’s a matter of fact that semantics serves as a kind of glue between unstructured and structured information and as a foundation layer for data integration efforts. But even for enterprises dealing mainly with documents and text-based assets, semantic knowledge graphs will do a great job.

Semantic graphs extend the functionality of a traditional search index. They don’t simply annotate documents and store occurrences of terms and phrases, they introduce concept-based indexing in contrast to term based approaches. Remember: semantics helps to identify the things behind the strings. The same applies to concept-based search over content repositories: documents get linked to the semantic layer, and therefore the knowledge graph can be used not only for typical retrieval but to classify, aggregate, filter, and traverse the content of documents.

PoolParty combines Machine Learning with Human Intelligence

Semantic knowledge graphs have the potential to innovate data and information management in any organisation. Besides questions around integrability, it is crucial to develop strategies to create and sustain the semantic layer efficiently.

Looking at the broad spectrum of semantic technologies that can be used for this endeavour, they range from manual to fully automated approaches. The promise to derive high-quality semantic graphs from documents fully automatically has not been fulfilled to date. On the other side, handcrafted semantics is error-prone, incomplete, and too expensive. The best solution often lies in a combination of different approaches. PoolParty combines Machine Learning with Human Intelligence: extensive corpus analysis and corpus learning support taxonomists, knowledge engineers and subject matter experts with the maintenance and quality assurance of semantic knowledge graphs and controlled vocabularies. As a result, enterprise knowledge graphs are more complete, up to date, and consistently used.

“An Enterprise without a Semantic Layer is like a Country without a Map.

On the 15th of August at 3 PM, Michael Röder will present the paper “RDF Query Relaxation Strategies Based on Failure Causes” of Fokou et al. in P702.

Abstract

Recent advances in Web-information extraction have led to the creation of several large Knowledge Bases (KBs). Querying these KBs often results in empty answers that do not serve the users’ needs. Relaxation of the failing queries is one of the cooperative techniques used to retrieve alternative results. Most of the previous work on RDF query relaxation compute a set of relaxed queries and execute them in a similarity-based ranking order. Thus, these approaches relax an RDF query without knowing its failure causes (FCs). In this paper, we study the idea of identifying these FCs to speed up the query relaxation process. We propose three relaxation strategies based on various information levels about the FCs of the user query and of its relaxed queries as well. A set of experiments conducted on the LUBM benchmark show the impact of our proposal in comparison with a state-of-the-art algorithm.

The paper is available at researchgate.

About the AKSW Colloquium

This event is part of a series of events about Semantic Web technology. Please see http://wiki.aksw.org/Colloquium for further information about previous and future events. As always, Bachelor and Master students are able to get points for attendance and there is complimentary coffee and cake after the session.

PoolParty Academy offers three E-Learning tracks that enable customers, partners and individual professionals to learn Semantic Web technologies and PoolParty Semantic Suite in particular.

You can pre-register for the PoolParty Academy training tracks at the academy’s website or join our live class-room at the biggest European industrial Semantic Web conference – SEMANTiCS 2016.

read more

We are happy to announce that the article “DL-Learner – A Framework for Inductive Learning on the Semantic Web” by Lorenz Bühmann, Jens Lehmann and Patrick Westphal was accepted for publication in the Journal of Web Semantics: Science, Services and Agents on the World Wide Web.

Abstract:

In this system paper, we describe the DL-Learner framework, which supports supervised machine learning using OWL and RDF for background knowledge representation. It can be beneficial in various data and schema analysis tasks with applications in different standard machine learning scenarios, e.g. in the life sciences, as well as Semantic Web specific applications such as ontology learning and enrichment. Since its creation in 2007, it has become the main OWL and RDF-based software framework for supervised structured machine learning and includes several algorithm implementations, usage examples and has applications building on top of the framework. The article gives an overview of the framework with a focus on algorithms and use cases.

Yesterday I went to the

On Monday 18.07.2016, Kleanthi Georgala will give her Colloquium presentation for her paper “An Efficient Approach for the Generation of Allen Relations”, that was accepted at the European Conference on Artificial Intelligence (ECAI) 2016.

Abstract

Event data is increasingly being represented according to the Linked Data principles. The need for large-scale machine learning on data represented in this format has thus led to the need for efficient approaches to compute RDF links between resources based on their temporal properties. Time-efficient approaches for computing links between RDF resources have been developed over the last years. However, dedicated approaches for linking resources based on temporal relations have been paid little attention to. In this paper, we address this research gap by presenting AEGLE, a novel approach for the efficient computation of links between events according to Allen’s interval algebra. We study Allen’s relations and show that we can reduce all thirteen relations to eight simpler relations. We then present an efficient algorithm with a complexity of O(n log n) for computing these eight relations. Our evaluation of the runtime of our algorithms shows that we outperform the state of the art by up to 4 orders of magnitude while maintaining a precision and a recall of 1.

Afterwards, Tommaso Soru will present a paper considered the latest chapter of the Everything-2-Vec saga, which encompasses outstanding works such as Word2Vec and Doc2Vec. The paper title is “node2vec: Scalable Feature Learning for Networks” [PDF] by Aditya Grover and Jure Leskovec, accepted for publication at the International Conference on Knowledge Discovery and Data Mining (KDD), 2016 edition.