Journal:Development and governance of FAIR thresholds for a data federation

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Full article title Development and governance of FAIR thresholds for a data federation
Journal Data Science Journal
Author(s) Wong, Megan; Levett, Kerry; Lee, Ashlin; Box, Paul; Simons, Bruce; David, Rakesh; MacLeod, Andrew; Taylor, Nicolas; Schneider, Derek; Thompson, Helen
Author affiliation(s) Federation University, Australian Research Data Commons, Commonwealth Scientific and Industrial Research Organisation, University of Adelaide, The University of Western Australia, University of New England
Primary contact Email: mr dot wong at federation dot edu dot au
Year published 2022
Volume and issue 21(1)
Article # 13
DOI 10.5334/dsj-2022-013
ISSN 1683-1470
Distribution license Creative Commons Attribution 4.0 International
Website https://datascience.codata.org/articles/10.5334/dsj-2022-013/
Download https://datascience.codata.org/articles/10.5334/dsj-2022-013/galley/1138/download/ (PDF)

Abstract

The FAIR (findable, accessible, interoperable, and re-usable) principles and practice recommendations provide high-level guidance and recommendations that are not research-domain specific in nature. There remains a gap in practice at the data provider and domain scientist level, demonstrating how the FAIR principles can be applied beyond a set of generalist guidelines to meet the needs of a specific domain community.

We present our insights developing FAIR thresholds in a domain-specific context for self-governance by a community (in this case, agricultural research). "Minimum thresholds" for FAIR data are required to align expectations for data delivered from providers’ distributed data stores through a community-governed federation (the Agricultural Research Federation, AgReFed).

Data providers were supported to make data holdings more FAIR. There was a range of different FAIR starting points, organizational goals, and end user needs, solutions, and capabilities. This informed the distilling of a set of FAIR criteria ranging from "Minimum thresholds" to "Stretch targets." These were operationalized through consensus into a framework for governance and implementation by the agricultural research domain community.

Improving the FAIR maturity of data took resourcing and incentive to do so, highlighting the challenge for data federations to generate value whilst reducing costs of participation. Our experience showed a role for supporting collective advocacy, relationship brokering, tailored support, and low-bar tooling access, particularly across the areas of data structure, access, and semantics that were challenging to domain researchers. Active democratic participation supported by a governance framework like AgReFed’s will ensure participants have a say in how federations can deliver individual and collective benefits for members.

Keywords: agriculture, AgReFed, FAIR data, community, governance, RM-ODP, data federation

Context and contribution

The agriculture data landscape is complex, comprising of a range of data types, standards, repositories, stakeholder needs, and commercial interests, creating data silos and potential "lock-ins" for consumers. (Kenney, Serhan & Trystram 2020; Ingram et al. 2022) There is an urgent need to work toward clear, ethical, efficient agricultural data sharing practices (Jakku et al. 2019; Wiseman & Sanderson 2018) that incorporate improvements to discoverability, accessibility, interoperability, and quality of data across the value chain. (Barry et al. 2017; Perrett et al. 2017; Sanderson, Reeson & Box 2017) A priority stakeholder question across the agri-tech sector is "how do we create systems whereby people feel confident in entering and sharing data, and in turn how do we create systems to govern data for the benefit of all?" (Ingram et al. 2022: 6)

Agricultural data stakeholders span the public and private sector, including farmers, traders, researchers, universities, consultants, and consumers. Their varied needs around data type, trustworthiness, timeliness, availability, and accuracy shape the many data capture, storage, delivery, and value-add products emerging across the public and private sector. (Allemang & Bobbin 2016; Kenney, Serhan & Trystram 2020) Data providers require confidence in data infrastructure governance before they share their data, in turn requiring ethics of ownership, access, and control. Strong value propositions are also key. This helps grow participants via a "network effect," increasing infrastructure value further. (Chiles et al. 2021; Ingram et al. 2022; Sanderson, Reeson & Box 2017)

Offerings of the many data infrastructures vary and may include a means for:

  • depositing data for persistence, citation, publisher, and funding requirements (Datacite, 2022);
  • increasing collaborative opportunities;
  • enhancing regulatory compliance;
  • improving on-farm operations;
  • leveraging standardization, quality assurance, and quality control pipelines and specialist analysis capacity (Harper et al. 2018; Wicquart et al. 2022);
  • running simulations through virtual research environments (VREs) (Knapen el al. 2020);
  • performing cross-domain data integration (Kruseman el al. 2020); and
  • linking data and models to knowledge products and decision support tooling (Antle et al. 2017).

If the goal is to make data trusted, discoverable, and re-usable across the sector (Peason et al. 2021; Ernst & Young 2019), then a single platform is unlikely to meet all (public, private, commercial) needs. (Pearson et al. 2021; Ingram et al. 2022) Sector concerns include among others vendor lock-ins and a tendency towards stifling innovation. (Ingram et al. 2022) As such, a grand challenge is found in how data can be discovered and made interoperable among so many different databases and infrastructures. One solution is a decentralized federated approach where there is no single master data repository or registry (Harper et al. 2018) but rather a network of independent databases and infrastructures that can deliver data through a shared platform using standard transfer protocols via application programming interface (API). The data still remains with providers, as can access controls.

Preferring a single front-end source of data, as found in data federation, is not novel, and many of the FAIR (findable, accessible, interoperable, and re-usable) principles (Wilkinson et al. 2016) underpin data federations’ functions. Some examples include the Earth System Grid Federation (Petrie et al. 2021), materials science data discovery (Plante et al. 2021), and OneGeology (One Geology 2020). In the case of agriculture, there is the AgDataCommons (USDA 2021), the proposed U.K. Food Data Trust (Pearson et al. 2021), AgINFRA (Drakos et al. 2015), and CGIAR Platform for Big Data In Agriculture. (CGIAR 2021) Many of these data federation initiatives specify standards for the description and exchange of data, focusing on a particular data type of provider and/or providing a central intermediate space to standardize data. However, we believe agriculture requires a different approach given the diversity of data stores, one that addresses the ways data is structured, described, and delivered; differences in organizational and research requirements and norms; and economic, trust, and intellectual property concerns connected to agricultural data in general.

Since 2018, we have piloted a community-governed federation approach via the Agricultural Research Federation (AgReFed). (Box et al. 2019a) Participants provisioned their data holdings from their own choice of data repository aligned to their organization's capabilities and requirements of their research field. Concurrently, they aligned with collective expectations for FAIR data. This required developing acceptable levels of FAIR data to be implemented and governed by AgReFed participants. Current practices adopt FAIR as a high-level set of guiding principles (Wilkinson et al. 2016) or a set of generalist practice recommendations. (Bahim et al. 2020) This case study addressed this gap in an agricultural-specific implementation of FAIR in practice. As part of this study, we co-developed FAIR threshold criteria for participants to deliver data through a federation, and, through a consensus process, we integrated these FAIR thresholds into a framework for ongoing governance by a research domain community, for generating individual and collective benefit and growth of a data federation.

Use cases

The datasets of the pilot included point observations, as well as spatial, temporal, on-ground, sensor, and remote sensed data. The data described plants (yield, crop rotation, metabolomic, proteomic, hyperspectral), soil, and climatic variables from across Australia (Table 1).

Table 1. The data providers and their data products. An * indicates both data provider and user of the dataset or collection.
In-text abbreviation Data product name Data product type Data provider to AgReFed
SH (Soil Health) Corangamite Soil Health Monitoring Program Data (Corangamite Catchment Management Authority, 2019) Dataset and service Federation University, Centre for eResearch and Innovation (CeRDI)
SMN-1 (Soil Moisture Network 1) Southern Farming Systems Moisture Probe Network Data (Southern Farming Systems, 2011) Dataset Federation University, CeRDI
WT (Wheat Trials) Waite Permanent Rotation Trial (Sanderman et al. 2015) Dataset * University of Adelaide, School of Agriculture, Food and Wine
NS (NatSoils) CSIRO National Soil Site Database (CSIRO 2013) Dataset and service Commonwealth Scientific and Industrial Research Organisation (CSIRO)
SLG (Soil and Landscape Grid) Soil and Landscape Grid National Soil Attribute Maps - Available Water Capacity (3" resolution) - Release 1 (Rossel et al. 2014) Data product (maps), collection, and service CSIRO
FT (Frost Trials) UWA/DPIRD Frost Nursery Trial 2018 (Taylor et al. 2019) Dataset and collection * University of Western Australia (UWA) and Department of Primary Industries and Regional Development (DPIRD)
SMN-2 (Soil Moisture Network 2) SensorNets - SMART Farms Soil Moisture Network (Schneider et al. 2018) Dataset * University of New England (UNE)


References

Notes

This presentation is faithful to the original, with only a few minor changes to presentation, grammar, and punctuation. In some cases important information was missing from the references, and that information was added.