Improving Editorial Workflow and Metadata Quality at Springer Nature

Salatino, Angelo A.; Osborne, Francesco; Birukou, Aliaksandr; Motta, Enrico

doi:10.1007/978-3-030-30796-7_31

Cited by 19 publications

(26 citation statements)

References 25 publications

(55 reference statements)

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“…The main result of this collaboration are two applications which demonstrate the value of using CSO in the context of developing intelligent functionalities that take as input scholarly entities: Smart Topics Miner and Smart Book Recommender. [3,40] (STM)  21 is a tool developed for supporting the Springer Nature editorial team in classifying editorial products according to a taxonomy of research topics drawn both from CSO and the Product Market Codes (PMC), Springer Nature's own editorial classification system. This information is then used for: i) classifying proceedings in digital and physical libraries; ii) enhancing semantically the metadata associated with publications and consequently improving the discoverability of the proceedings; and iii) detecting promising emerging research areas that may deserve more attention from the publisher.…”

Section: Cso and Springer Naturementioning

confidence: 99%

The Computer Science Ontology: A Comprehensive Automatically-Generated Taxonomy of Research Areas

et al. 2020

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Ontologies of research areas are important tools for characterizing, exploring, and analyzing the research landscape. Some fields of research are comprehensively described by large-scale taxonomies, e.g., MeSH in Biology and PhySH in Physics. Conversely, current Computer Science taxonomies are coarse-grained and tend to evolve slowly. For instance, the ACM classification scheme contains only about 2K research topics and the last version dates back to 2012. In this paper, we introduce the Computer Science Ontology (CSO), a large-scale, automatically generated ontology of research areas, which includes about 14K topics and 162K semantic relationships. It was created by applying the Klink-2 algorithm on a very large data set of 16M scientific articles. CSO presents two main advantages over the alternatives: i) it includes a very large number of topics that do not appear in other classifications, and ii) it can be updated automatically by running Klink-2 on recent corpora of publications. CSO powers several tools adopted by the editorial team at Springer Nature and has been used to enable a variety of solutions, such as classifying research publications, detecting research communities, and predicting research trends. To facilitate the uptake of CSO, we have also released the CSO Classifier, a tool for automatically classifying research papers, and the CSO Portal, a Web application that enables users to download, explore, and provide granular feedback on CSO. Users can use the portal to navigate and visualize sections of the ontology, rate topics and relationships, and suggest missing ones. The portal will support the publication of and access to regular new releases of CSO, with the aim of providing a comprehensive resource to the various research communities engaged with scholarly data.

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Section: Cso and Springer Naturementioning

confidence: 99%

The Computer Science Ontology: A Comprehensive Automatically-Generated Taxonomy of Research Areas

et al. 2020

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“…We annotated publications and patents using the CSO Classifier 16 [33], an open-source Python tool for annotating documents with research topics from CSO. This is the same classifier that powers the Smart Topic Miner [34], which is the application used by Springer Nature for annotating Proceedings Book in Computer Science. The resulting set of topics was enriched by including all their super-topics in CSO.…”

Section: Generation Of Aida Knowledge Graphmentioning

confidence: 99%

ResearchFlow: Understanding the Knowledge Flow Between Academia and Industry

Salatino

Osborne

Motta

2020

Lecture Notes in Computer Science

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Understanding, monitoring, and predicting the flow of knowledge between academia and industry is of critical importance for a variety of stakeholders, including governments, funding bodies, researchers, investors, and companies. To this purpose, we introduce ResearchFlow, an approach that integrates semantic technologies and machine learning to quantifying the diachronic behaviour of research topics across academia and industry. ResearchFlow exploits the novel Academia/Industry DynAmics (AIDA) Knowledge Graph in order to characterize each topic according to the frequency in time of the related i) publications from academia, ii) publications from industry, iii) patents from academia, and iv) patents from industry. This representation is then used to produce several analytics regarding the academia/industry knowledge flow and to forecast the impact of research topics on industry. We applied ResearchFlow to a dataset of 3.5M papers and 2M patents in Computer Science and highlighted several interesting patterns. We found that 89.8% of the topics first emerge in academic publications, which typically precede industrial publications by about 5.6 years and industrial patents by about 6.6 years. However this does not mean that academia always dictates the research agenda. In fact, our analysis also shows that industrial trends tend to influence academia more than academic trends affect industry. We evaluated ResearchFlow on the task of forecasting the impact of research topics on the industrial sector and found that its granular characterization of topics improves significantly the performance with respect to alternative solutions.

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“…An alternative vision, that is gaining traction in the last few years, is to generate a semantically rich and interlinked description of the content of research publications [13,29,7,24]. Integrating this data would ultimately allow us to produce large scale knowledge graphs describing the state of the art in a field and all the relevant entities, e.g., tasks, methods, metrics, materials, experiments, and so on.…”

Section: Introductionmentioning

confidence: 99%

“…The research community has been working for several years on different solutions to enable a machine-readable representations of research, e.g., by creating bibliographic repositories in the Linked Data Cloud [19], generating knowledge bases of biological data [5], encouraging the Semantic Publishing paradigm [27], formalising research workflows [31], implementing systems for managing nanopublications [14] and micropublications [26], , automatically annotating research publications [24], developing a variety of ontologies to describe scholarly data, e.g., SWRC 6 , BIBO 7 , BiDO 8 , SPAR [21], CSO 9 [25], and generating large-scale knowledge graphs, e.g., OpenCitation 10 , Open Academic Graph 11 , Open Research Knowledge Graph 12 [13], Academia/Industry DynAmics (AIDA) Knowledge Graph 13 [3]. Most knowledge graphs in the scholarly domain typically contain metadata describing entities, such as authors, venues, organizations, research topics, and citations.…”

Section: Introductionmentioning

confidence: 99%

AI-KG: An Automatically Generated Knowledge Graph of Artificial Intelligence

Dessı̀

Osborne

Recupero

et al. 2020

Lecture Notes in Computer Science

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Scientific knowledge has been traditionally disseminated and preserved through research articles published in journals, conference proceedings, and online archives. However, this article-centric paradigm has been often criticized for not allowing to automatically process, categorize, and reason on this knowledge. An alternative vision is to generate a semantically rich and interlinked description of the content of research publications. In this paper, we present the Artificial Intelligence Knowledge Graph (AI-KG), a large-scale automatically generated knowledge graph that describes 820K research entities. AI-KG includes about 14M RDF triples and 1.2M reified statements extracted from 333K research publications in the field of AI, and describes 5 types of entities (tasks, methods, metrics, materials, others) linked by 27 relations. AI-KG has been designed to support a variety of intelligent services for analyzing and making sense of research dynamics, supporting researchers in their daily job, and helping to inform decision-making in funding bodies and research policymakers. AI-KG has been generated by applying an automatic pipeline that extracts entities and relationships using three tools: DyGIE++, Stanford CoreNLP, and the CSO Classifier. It then integrates and filters the resulting triples using a combination of deep learning and semantic technologies in order to produce a high-quality knowledge graph. This pipeline was evaluated on a manually crafted gold standard, yielding competitive results. AI-KG is available under CC BY 4.0 and can be downloaded as a dump or queried via a SPARQL endpoint.

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Improving Editorial Workflow and Metadata Quality at Springer Nature

Cited by 19 publications

References 25 publications

The Computer Science Ontology: A Comprehensive Automatically-Generated Taxonomy of Research Areas

The Computer Science Ontology: A Comprehensive Automatically-Generated Taxonomy of Research Areas

ResearchFlow: Understanding the Knowledge Flow Between Academia and Industry

AI-KG: An Automatically Generated Knowledge Graph of Artificial Intelligence

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