Michael Diepenbroek scite author profile

The 'Berlin Declaration' was published in 2003 as a guideline to policy makers to promote the Internet as a functional instrument for a global scientific knowledge base. Because knowledge is derived from data, the principles of the 'Berlin Declaration' should apply to data as well. Today, access to scientific data is hampered by structural deficits in the publication process. Data publication needs to offer authors an incentive to publish data through long-term repositories. Data publication also requires an adequate licence model that protects the intellectual property rights of the author while allowing further use of the data by the scientific community.

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PANGAEA—an information system for environmental sciences

Diepenbroek

Grobe

Reinke

et al. 2002

Computers & Geosciences

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PANGAEA is an information system for processing, long-term storage, and publication of georeferenced data related to earth science fields. Essential services supplied by PANGAEA are project data management and the distribution of visualization and analysis software. Organization of data management includes quality control and publication of data and the dissemination of metadata according to international standards. Data managers are responsible for acquisition and maintenance of data. The data model used reflect the information processing steps in the earth science fields and can handle any related analytical data. The basic technical structure corresponds to a three tiered client/server architecture with a number of comprehensive clients and middleware components controlling the information flow and quality. On the server side a relational database management system (RDBMS) is used for information storage. The web-based clients include a simple search engine (PangaVista) and a data mining tool (ART). The client used for maintenance of information contents is optimized for data management purposes. Analysis and visualization of metainformation and analytical data is supported by a number of software tools, which can either be used as 'plug-ins' of the PANGAEA clients or as standalone applications, distributed as freeware from the PANGAEA website. Established and well-documented software tools are the mini-GIS PanMap, the plotting tool PanPlot, and Ocean Data View (ODV) for the exploration of oceanographic data. PANGAEA operates on a long-term basis. The available resources are sufficient not only for the acquisition of new data and the maintenance of the system but also for further technical and organizational developments. r

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Towards a multisensor station for automated biodiversity monitoring

Wägele

Bodesheim

Bourlat

et al. 2022

Basic and Applied Ecology

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The Scholix Framework for Interoperability in Data-Literature Information Exchange

Burton¹,

Aryani²,

Koers³

et al. 2017

D-Lib Magazine

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DOI for geoscience data - how early practices shape present perceptions

2015

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The first minting of Digital Object Identifiers (DOI) for research data happened in 2004 in the context of the project "Publication and citation of primary scientific data" (STD-DOI). Some of the concepts and perceptions about DOI for data today have their roots in the way this project implemented DOI for research data and the decisions made in those early days still shape the discussion about the use of persistent identifiers for research data today. This project also laid the foundation for a tighter integration of journal publications and data. Promoted by early adopters, such as PANG AEA, DOI registration for data has reached a high level of maturity and has become an integral part of scientific publishing. This paper discusses the fundamental concepts applied in the identification of DOI for research data and how these can be interpreted for alternative and future applications of persistent identifiers for research data.

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How round is round? A new approach to the topic ‘roundness’by Fourier grain shape analysis

1992

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Numerous methods for roundness measurement have been developed. None, however, has been generally accepted, because of conceptual and practical deficiencies. Modern image processing and Fourier grain shape analysis have eliminated the practical shortcomings, but the conceptual ones remained. Single, higher harmonics of the Fourier series, for example, fail to serve as reliable equivalents for roundness evaluation. The concept outlined in this paper recognizes three criteria for the evaluation of roundness. (1) All curvatures, convex as well as concave or plane elements, must be considered. (2) The positions of morphological elements are significant because salient parts of a particle are more easily abraded than protected ones. Consequently, the curvatures have to be weighted by their relative position on the particle. (3) Positions and curvatures of morphological elements have to be compared with the particle's ultimate abraded shape, which is assumed to be an ellipsoid. The ellipsoid reflects the aspect of form or sphericity. The distinction between sphericity and roundness is retained because there is no evidence that sphericity changes significantly during transport. The measurement is based on the outline of a particle's maximum projection plane, which is transformed to a Fourier series. Roundness data are derived from the complete amplitude spectrum. The aspect of sphericity is eliminated by subtracting the amplitude spectrum of the best approximating ellipse from the spectrum of the empirical shape. The residual amplitudes are normalized and summed. In a final step the resulting values are rescaled. This guarantees reasonable boundaries and a normal distribution of roundness values. The procedure is automated and its efficiency permits the calculation of large samples. Tests on fluvial and coastal gravel populations demonstrate that the method is sensitive to abrasional wear during all stages of roundness.

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Business models for sustainable research data repositories

Dillo¹,

Treloar²,

Lusoli³

et al. 2017

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Data Management of Proxy Parameters with PANGAEA

Diepenbroek

Grobe

Reinke

et al. 1999

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Specific parameters detennined from marine sediments can be used as proxy data to calculate fonner ocean properties. To use this scientific resource effectively an infonnation system is needed which guarantees consistent longtime storage of the proxy data and provides easy access for the scientific community. An infonnation system to archive proxy data of paleoclimatic relevance, together with the related meta-infonnation, raw data and evaluated paleoclimatic data, is presented here. The system provides standardized import and export routines, easy access with unifonn retrieval functions, and tools for the visualization of data. The network is designed as a client/server system providing access through the Internet.

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