We introduce the rationale for, and architecture of, the European Space Agency Climate Change Initiative (CCI) Open Data Portal (http://cci.esa.int/data/). The Open Data Portal hosts a set of richly diverse datasets – 13 “Essential Climate Variables” – from the CCI programme in a consistent and harmonised form and to provides a single point of access for the (>100 TB) data for broad dissemination to an international user community. These data have been produced by a range of different institutions and vary across both scientific and spatio-temporal characteristics. This heterogeneity of the data together with the range of services to be supported presented significant technical challenges.
An iterative development methodology was key to tackling these challenges: the system developed exploits a workflow which takes data that conforms to the CCI data specification, ingests it into a managed archive and uses both manual and automatically generated metadata to support data discovery, browse, and delivery services. It utilises both Earth System Grid Federation (ESGF) data nodes and the Open Geospatial Consortium Catalogue Service for the Web (OGC-CSW) interface, serving data into both the ESGF and the Global Earth Observation System of Systems (GEOSS). A key part of the system is a new vocabulary server, populated with CCI specific terms and relationships which integrates OGC-CSW and ESGF search services together, developed as part of a dialogue between domain scientists and linked data specialists. These services have enabled the development of a unified user interface for graphical search and visualisation – the CCI Open Data Portal Web Presence.
The European Space Agency (ESA) Open Data Portal (http://cci.esa.int/data/) has been developed to meet the objective of disseminating data outputs from the ESA Climate Change Initiative (CCI) programme (Hollmann et al., 2013). The CCI programme was initiated as a contribution towards the goal of the United Nations Framework Convention on Climate Change to create a database of Essential Climate Variables (ECVs) and to more fully exploit the long-term global archives of earth observation data available from ESA and its member states. In particular, the programme aims to provide stable, long-term, satellite based data products for climate modellers and researchers. Much of the programme is devoted to the development and maintenance of the ECV data products, but a key activity is the archival and dissemination of those data via the CCI Open Data Portal (at the time of this project, hosting 13 ECVs from 130 datasets involving 40 institutions).
The main contribution of the work described in this paper is to provide a detailed description of how the portal software was architected to meet the dual challenges of heterogeneous data management at scale and delivering a prescribed set of services for discovery and open access. The former requires curating and hosting a complex and varied set of climate data products in a harmonised and consistent manner. The latter requires high performance dissemination to the international user community and the effective integration of independent technologies with different conceptual approaches to solve similar problems. Both data and service delivery depend on standards, yet begin with diversity leading to fundamental challenges associated with narrowing the scope and managing the expectations of both producers and consumers (Figure 1). The entire activity depends on the data management and curation workflow as will be seen.
In the remainder of this paper we introduce the ECVs, the CCI programme and context. We discuss the available technologies and relevant prior work. We then present the CCI portal architecture and the necessary workflow. We describe the services and the Web Presence itself. Finally in conclusion, we discuss the issues which arose and the lessons learned. There is much future work required.
The Open Data Portal delivers on the CCI programme goal to support modellers by providing ECV data in a format suitable for use in the development and evaluation of climate models, for example, in seasonal to decadal prediction (Goddard et al., 2013) or wider earth system model evaluation (Eyring et al., 2016). This section provides background information about the Essential Climate Variables and context for the Open Data Portal (requirements on interoperation, curation and deployment environment).
The Climate Change Initiative data collection consists of Essential Climate Variables derived from satellite observations, covering marine, terrestrial and atmospheric domains. The products are mostly global gridded fields, but also include points or profiles along satellite orbit tracks, Shapefiles1 (e.g. glacier outlines) and images. The datasets span time periods from a few years to multiple decades. The products have been generated using state of the art scientific algorithms developed by the project teams and are typically updated each year, as algorithms are improved and/or new satellite data are incorporated.
Over 130 discrete datasets have been delivered to date, with some ECVs producing many variants (Hollmann et al., 2013) such as products using different satellite datasets, or different algorithms, or the resulting data projected onto different grids, or different spatial or temporal resolutions. The majority of data products are gridded but with the notable exceptions of glaciers and some of the icesheet data which are vector based. Products are available to a range of the standard earth observation processing levels: Level 2 – geophysical variables derived from measurements but in spatio-temporal scale of the original acquisition; Level 3 – variables mapped to a uniform spatio-temporal scale and Level 4 – datasets created from the analysis of lower level data that result in gridded, gap-free products. Depending on the ECV or product, individual dataset sizes are between a few gigabytes and tens of terabytes. The data are used widely in the Earth Observation and Climate community, alone or in combination with model data to increase understanding of the earth system. Satellite observations of climate variables are increasingly used to evaluate or initialise climate models, as well as provide a global view of key quantities and their spatial and temporal evolution.
ESA set the requirements for the Open Data Portal, following consultation with the climate science and earth observation communities, mandating a single repository and point of access for the data working in the context of a pre-existing system, the Earth System Grid Federation (ESGF) but also the adoption of a range of community standards in order to facilitate broad dissemination of the data. One such standard is the Open Geospatial Consortium (OGC) Catalog Services for the Web (CSW, Nebert et al., 2016), which defines a means for catalogue and search of geospatial data records. By providing such a service it would be possible to integrate the Open Data Portal with initiatives such as the Global Earth Observation System of Systems (GEOSS).
ESGF and GEOSS differ markedly: while both provide access to data, the former uses consistent software and a globally federated system of index and data nodes to provide discovery and download services respectively (WIlliams et al., 2011), the latter provides a brokerage service utilising high level discovery before passing users down to other portals which themselves deliver a range of services (Bai et al., 2012). Both are predicated on two key services: discovery and delivery, but the semantics and nature of those services differ substantially.
In ESGF, data discovery utilises faceted search using a customised metadata schema. Discovery metadata is replicated between nodes in the federation. This enables distributed download from multiple sites in the federation. The primary workflow is data discovery and bulk data download via wget2 or GridFTP (Allcock et al., 2005), although more sophisticated services such as the Live Access Server (LAS, Hankin et al., 2001) and OPeNDAP (Cornillon et al., 2003) are available for some datasets.
The GEOSS Portal3 leverages the CSW formalism to aggregate discovery metadata from multiple data repositories into a single web-hosted search interface. A brokering approach (Nativi et al., 2013) provides the bridge between heterogeneous underlying technologies, data standards and disciplines, albeit with fundamental limitations in the level of integration (whilst standardisation of discovery metadata allows search across multiple catalogues, the differences in access conditions, semantics and structure for file access limit what can be achieved). As a consequence, it is generally not possible to deliver federated data services from any of the constituent portals. However, most GEOSS portals support one or both of the core OGC protocols: Web Map Server (WMS, Beaujardiere 2006) and Web Coverage Service (WCS, Peter Baumann 2012) for some or all datasets.
In practice the requirement for the Open Data Portal working in the context of both the ESGF and GEOSS has meant the need to support both interfaces: the Open Data Portal needs to integrate into the Earth System Grid Federation and broker into the GEOSS via the OGC-CSW. ESGF conformance also required conforming to the requirements of the Obs4MIPS project (Teixeira et al., 2014).
Delivering a portal to data relies on having data available and conforming to the necessary formats and standards. This involves having an ingest process into a repository which deals with multiple versions of data sourced from the producers, validates formats and prepares any necessary additional metadata.
The Centre for Environmental Data Analysis (CEDA) provides the necessary archival and curation environment – archival provides reliable data availability including multiple copies of data and curation provides active management of the data, including format and metadata migration (if necessary). Systems have been built up over decades (Pepler and Callaghan, 2015) to deliver reliable data services and complex metadata systems are in place (Parton et al., 2015) which exploit a wide range of information categories from archive metadata, to the necessary browse and discovery metadata (Lawrence et al., 2009). These data systems are supported by data scientists who have expertise in the relevant science areas and can actively curate the metadata content to maximise utility as systems and target communities evolve.
The target environment for the system is the JASMIN data analysis facility (Lawrence et al., 2013), a collaborative environment for the environmental sciences community combining access to the archive with user-managed storage, a cloud and a batch processing system. JASMIN uses a tenancy model to allocate its computing resources to different projects and programmes. The CCI Open Data Portal was deployed using cloud and virtualisation services on JASMIN. The CCI data itself was integrated into CEDA’s curated data archive on JASMIN. This consists of a broad range of earth observation and atmospheric science datasets which CEDA provides access to as part of a wider service on behalf of NERC, the Natural Environment Research Council.
The baseline architecture consists of a central archive, metadata systems, data services, and a web front-end (hereafter referred to as the Web Presence) – with data and metadata services consistent with ESGF and GEOSS requirements. This is delivered with customised implementations of the two main ESGF components, the Index Node and the Data Node.
The Index Node includes an identity provider for user authentication, a metadata catalogue, a portal and search service. The Data Node provides a data publisher, and services for data download and access control, built on the Unidata THREDDS Data Server (TDS)4 augmented with GridFTP for bulk data download. The key innovation has been to integrate additional OGC services for download and visualisation and reconcile alternative strategies for data discovery with ESGF Search and CSW.
The architecture is summarised in Figure 2, there are two CCI user facing interfaces: the Open Data Portal Web Presence itself, and the CCI Toolbox user interface (section 5.4). Additional interfaces include data delivery services, the CEDA catalogue interface (all the data is ingested into the CEDA archive), and regular ESGF and GEOSS portal interfaces.
Alongside the primary consumers of the architecture (the Web Presence and the CCI Toolbox), the user facing data services fall into four categories:
As the project progressed it became clear that the range of data types precluded easy deployment of some services – those marked with a † above were deemed low priority and dropped.
The next section describes the data and metadata workflow necessary to support this architecture, and section 5 describes the services which it exposes.
The development of the metadata systems for supporting the workflow necessary to publish data into the portal and out to users formed a major component of the work. This architecture depends on several key underlying technologies: the ESGF Publisher which indexes key metadata from NetCDF source files into the Solr distributed search system;9 both the ESGF and the Web Presence utilise faceted search based on the Data Reference Syntax (DRS, Petrie et al., 2020); and the metadata systems depend on the CEDA catalogue system (which uses the Metadata Objects for Linking Environmental Sciences, MOLES, Parton et al., 2015).
The publishing workflow involves five key steps: data acquisition, initial metadata creation, metadata customisation, and support for the ESGF and OGC/GEOSS systems. These are summarised in Figure 3 alongside a depiction of the interaction of the Web Presence interacting with the metadata services. In the rest of this section we provide some detail of the publishing workflow, the service interactions is discussed section 5.
Data is first pulled into a staging area for quality control checks, checking conformance with the CCI data standards (ESA Climate Office, 2015) which had been introduced to make data as consistent as possible. It is then formally incorporated into the CEDA archive, exploiting existing CEDA systems which conform to the OAIS archiving standard for managing migration, ensuring fixity of data etc (Corney et al., 2004). This involved storage allocation and organisation into a directory hierarchy, with each CCI dataset mapping to a directory in a POSIX hierarchy.
Metadata is needed to support the CEDA, ESGF and CSW discovery services, as well as support management and data delivery services.
Dataset-level and dataset collection records are manually created in the CEDA data catalogue by data scientists at the granularity of whole datasets. Data products are organised into datasets divided up by the different characteristics (processing level, spatial resolution, instruments, algorithms or product type) of each ECV.
The ESGF discovery and CSW discovery metadata do not share the same semantics, schema, or API, although they are complementary (see Table 1). The most important distinction arises from both limitations and advantages of the existing ESGF technology: it only supports publishing gridded CF-NetCDF data, but it supports discovery down to the granularity of individual files. By contrast, the CSW is designed for general data, but discovery is at the level of entire datasets and collections.
|Catalogue and Search Technology||Granularity of content||Supported data types||Use of controlled vocabularies||Dataset metadata||Links to data access services|
|OGC CSW/ISO 19115 metadata for CEDA MOLES Metadata Catalogue||Supports collections and Datasets only||Any – dataset and dataset collection information input manually||Limited use of unbound keywords||Full scope of ISO 19115: including abstract, responsible party, licensing and other constraints on use.||Links at the granularity of datasets only. Links provided using OnlineResources. Links have name and description but not classified by service type.|
|ESGF Search||Datasets and file level metadata||ESGF publisher works with gridded netCDF data only||Per project DRS controlled vocabularies supports faceted search||Limited dataset metadata such as dataset variables information||Links provided at dataset and file level. Links categorised by type e.g. OPeNDAP, HTTPServer, GridFTP|
The limitation on datatypes in ESGF would be problematic for the CCI, were it not for the alternative CSW cataloguing, as the CCI includes different datatypes (e.g. glacier boundaries) and formats (Shapefiles). By supporting both interfaces, it is possible to both construct a complete catalogue of all CCI datasets for exposure using the CSW and ESGF search systems. The ESGF system complemented CSW by providing a more powerful faceted search interface for the gridded CF-NetCDF data. The two interfaces also support broad dissemination of the data via a) the ESGF distributed infrastructure and b) CSW harvesting of discovery records into, for example, the GEOSS Geoportal.
Much of the development effort was concerned with the evolution of a system to reconcile the two different approaches of the ESGF and the OGC-CSW. However, it was possible to exploit a data reference syntax, DRS, to provide a common logical organisation. A DRS consists of a set of controlled vocabularies which enable any given dataset to be uniquely identified and enables the development of faceted search capability. The first use of a DRS in this mode was for CMIP5 (Taylor et al., 2012), but a CCI specific version was developed, including terms such as the ECV name, the processing level, the instrument used for the retrieval and the sensor platform (Petrie et al., 2020).
The utility of DRS approaches is enhanced by exploiting SKOS10 to link vocabulary terms and serving the vocabularies and linked data definitions from a vocabulary server. The use of a vocabulary service provides a single canonical source for information for use by (multiple) search interfaces and any client applications consuming its content. These developments built on experience with the Climate Information Platform for Copernicus (CLIPC, Mihajlovski et al., 2016) and CHARMe (Blower et al., 2014), both of which had demonstrated the advantages of using independent systems to manage controlled vocabularies.
A data modelling exercise was conducted to generate the necessary content. Data scientists entered vocabulary terms and relationships into spreadsheets. Using a special Python script, the information from the sheet cells was converted into SKOS and OWL11 representations using the Turtle12 serialisation. The use of SKOS allowed the mapping of concept relationships between geophysical parameters (e.g. sea ice is broader than sea ice concentration, and conversely, sea ice concentration is narrower than sea ice). SKOS concept schemes were developed for the CCI DRS (Figure 4) and the full 50 ECVs defined by the Global Climate Observing System, GCOS.13 Where possible pre-existing definitions already available from the NERC Vocabulary Server (Leadbetter, 2012) were used. Once prepared, vocabularies were uploaded to an internal vocabulary server implemented using the open source Apache Jena14 Fuseki triple store.
The ESGF has its own publishing system which is predicated on gridded CF-NetCDF compliant data providing information for the THREDDS catalogue and the Solr distributed database. After consistency checking, the files can be automatically parsed for metadata extraction; information extracted includes variable detail, the necessary DRS terms and details about spatio-temporal extent. Dataset and file-level information were recorded in both databases along with service endpoint information for access methods such as standard HTTP data download and OPeNDAP.
Given the constraint of gridded CF-NetCDF some datasets were not suitable for publishing through the ESGF system. Such datasets were those which did not conform to a coverage array describing values at a point in space and/or time, such as those describing the spatial extent of a feature (e.g. the Greenland and Antarctic Ice Sheets and Glaciers ECVs).
ESGF publishing was started when the first release of CCI datasets had already been made and the second release was underway. In many cases, datasets did not comply with the data standards. This impacted on ESGF publishing since specific metadata were expected in order to represent the different search facets set by the DRS. The ESGF publisher uses a system of map files to link information from the source files to these facets. In order to deal with the inconsistencies with the data, a special cci-tagger script was developed to extract vocabulary terms from the data and implement workarounds for problems such as inconsistent naming for a term, a term being absent completely or terms being defined in filenames, rather than file metadata. The cci-tagger script makes heavy use of the CCI vocabulary service.
The MOLES system underlying the CEDA catalogue supports the export of dataset records serialised as ISO 19115. This capability was used to populate a dedicated project specific OGC CSW interface with CCI metadata and construct a search interface supporting free text search and results at the granularity of individual datasets. Although project specific, this same interface allowed other systems (e.g. GEOSS) to harvest CCI metadata.
The OGC-CSW records were populated with DRS terms from an extension to the cci-tagger script. The resulting ISO 19115 records for the CSW specified the relevant vocabulary SKOS concept in each case and the URI for the source SKOS collection. Where possible these took advantage of a direct mapping between ISO 19115 records returned from the CSW and the related ESGF dataset search results. In practice, there was not always a one-to-one mapping between ISO records and the ESGF dataset records in all cases, with some ISO records containing multiple DRS dataset identifiers.
The data itself is hosted by CEDA using the core JASMIN storage, and exposed directly using existing CEDA services. Here we discuss the additional CCI specific services, hosted using a combination of JASMIN’s cloud and virtualisation services. We begin by describing the initial data services deployed as the system was developed, then the dashboard development, before describing the Open Data Portal production system as of September 2019.
The first development was to deploy data services. Standard FTP access to CCI data was directly available via the CEDA services, all that was necessary for the CCI was to ensure that FTP endpoints for the datasets were entered into the ISO19115 dataset records served from the OGC-CSW. Each ISO record linked to the FTP service by including an online resource link mapped to the FTP path of the equivalent dataset directory in the data archive.
The THREDDS Data server provided HTTP and OPeNDAP out of the box (for gridded datasets), and WMS and WCS were configured as non-standard options. Although built on organising, finding and delivering files, THREDDS also supports aggregation and the attachment of services at both the file and aggregation level. All the files in a dataset were served individually via HTTP, and as an aggregation – a single contiguous set of data combined along the time axis – via OPeNDAP, WMS and WCS.
The necessary configuration for the aggregations was created by an additional Python script which augmented the THREDDS catalogue and Solr search indexes created by the ESGF publisher by adding the aggregation endpoints using the NetCDF markup language (NcML, Nativi et al., 2005). The NcML specifies the variables to be aggregated and includes the time steps for each file as a measure to optimise load performance. Repeated queries benefit from significant performance improvement by virtue of caching by the HTTP server.
ESA required open access, so no access control was configured (eventually the Web Presence provided the capability for users to register in order to provide a mechanism for them to be kept informed about changes to data and services).
An early “dashboard” search interface was developed to provide a novel graphical overview of all the ECV data products available and the respective temporal coverage for each (Figure 5). In this interface the CSW content was exposed in such a way that the user could select by ECV to see specific ISO 19115 records. This interface now forms part of the larger Web Presence.
Following the publication of the first data into ESGF services, the CCI Open Data Portal had dual search interfaces. This served to underline the disparity between the two: the CSW provided complete coverage of all datasets but an only rudimentary interface for file access and manipulation through FTP; ESGF Search provided a comprehensive faceted search interface linking to individual file download via HTTP and OPeNDAP but was limited in its coverage since the ESGF Publisher is only capable of indexing NetCDF files into the search catalogue.
Taking advantage of the controlled vocabularies and vocabulary service however, it was possible to combine ESGF and OGC-CSW to provide a single search interface in the Web Presence which integrated search results from both. (Figure 6).
Facets and the available terms for each facet are populated dynamically from the definitions of concepts and collections in the vocabulary service. It can display context-sensitive help text sourced from the ‘preferred label’ text of the vocabulary terms. When a query selection is made, these are translated into keyword items included in a given CSW query (e.g. Figure 7). Keyword items correspond to the URIs of concepts in the appropriate SKOS ConceptScheme. A drill down approach was implemented for the search logic in the user interface. This takes advantage of the fact that the ISO records returned from the CSW contain links to the corresponding ESGF search records:
The Open Data portal services can be consumed by third party clients. Figure 8 shows two such examples: a WMS client developed by Plymouth Marine Laboratory which pulls data from the CCI Open Data Portal, and the CCI ToolBox desktop client – Cate – developed as part of a separate ESA project. The latter provides more comprehensive functionality for data analysis and visualisation, using the Open Data Portal search and data services. In particular, it takes advantage of OPeNDAP sub-setting to selectively retrieve portions of data from the portal data archive to the user client’s host computer.
The final system was the result of iterative development with capability added via a set of discrete developments through the project. Four key phases were involved:
While the use of an iterative approach was partly to meet ESA requirements as they unfolded, it was also a result of the a priori recognition that trying to design upfront for all the data complexity issues would have been inefficient and impractical. The twofold challenges of a developing a single consistent set of services for a large and varied collection of datasets and managing a complex set of requirements for discovery and access services could have consumed endless design time with little practical outcome. Instead, by using existing technologies and a sequence of milestone deliveries, problems were addressed as they were encountered.
There were three main classes of problem: information mismatch between the tools, scale issues and content issues. We give three examples of each.
The task of integrating a varied set of data into the metadata catalogue and archiving services has demonstrated the intimate relationship between the metadata content and the services, with services dependent on particular information provision. Unfortunately, different service requirements had led to different metadata standards, and reconciling alternative metadata technologies and strategies to deliver a range of services was non-trivial. The development of vocabulary services based on linked data and a common data reference syntax made this possible. Equally important was the quality and extent of the primary content – services and usability benefitted from attention to detail by data providers and extra metadata information added by data scientists during data ingestion.
The sheer volume of files per dataset exposed performance limitations in the ESGF Publisher software. The Ocean Colour ECV for example, represents a large data collection which splits into 40 datasets along the lines of the geophysical parameter recorded, the co-ordinate system used and the temporal frequency. Even with this division, the number of files for individual datasets was large; for example, daily data involved in excess of 7000 files over the complete time range 1997–2016.
The ESGF Publisher was originally designed for managing CMIP5 data with a very different structure determined by the experiment design. The initial work-around in the case of Ocean Colour, involved splitting the data and reorganising it into smaller temporal chunks so that rather than publishing the dataset as a single 20-year time span, it was divided into smaller datasets. Similar hacks were initially applied to other ECVs. However, a patch was developed for the Publisher such that it was possible to create datasets spanning the full twenty years. In one publishing update in autumn 2018 over a quarter of a million data files were indexed organised into over 100 datasets.
For some datasets there were last-mile issues with the publication of the data: though ingestion, checks and metadata catalogue generation processes would succeed, minor formatting inconsistencies in NetCDF header file content (e.g. use of non-standards compliant names for the time dimension) would prevent services from operating correctly (e.g. THREDDS being unable to serve OPeNDAP and WMS queries).
In most cases it was possible to correct these by liaising with the respective ECV data producers to get new versions of the data, but these sorts of issues served to underline the need for rigorous checking and enforcement of data standards both by the data providers, and by the ingestion process.
The THREDDS Data Server (TDS) was selected early in the project to satisfy the requirements to provide HTTP, data download, OPeNDAP, WMS and WCS. This has the added benefit of delivering a powerful aggregation capability (via OPeNDAP), effectively creating a data cube across spatial and temporal dimensions important for analysis of climate datasets. However, the TDS has limited support for the OGC services and future developments may need to exploit other technology such as Geoserver.15 In addition, whilst it is possible to create large aggregations, the large temporal range (20–30 years in some cases) is at the limit of what the technology can support – at all layers, from the TDS down through the web application server and underlying host capability. Work at CEDA as part of the ESiWACE16 project is exploring alternatives for scalable systems for data access.
Like the CCI portal activity, the Copernicus Climate Change Service (C3S, Raoult et al., 2017) is a system to provide an authoritative source of quality-assured data to support adaptation and mitigation strategies for climate change. Datasets include climate models, re-analyses as well as ECVs. Rather than collating data together in a single repository, C3S uses a distributed architecture. There is a central web interface and toolbox for server-side analysis of data but the data itself is hosted at remote data providers. A broker and a system of adaptors for the different data sources and computational resources mediate access through to the toolbox and web front end. The use of agreed standards for the adaptor interfaces was important taking advantage of OGC web services, ESGF and OPeNDAP as used in the CCI Open Data Portal.
There is clearly a large overlap between the system developed for C3S and the Open Data Portal. The C3S use of an adaptor in its architecture has provided an abstraction between the data source and data consumer. Such a model could have provided some benefits in managing the heterogeneity between the different datasets in CCI. Equally however, CCI has evolved a comprehensive system for managing controlled vocabularies and integrating distinct services for data discovery and access. The decision to host the data in a single repository has benefits for the future evolution of the CCI system to support hosted processing and analysis since with all the data in one place, computing resources can be colocated eliminating the need to move and stage data between infrastructures.
The use of OpenSearch in the earth observation community (CEOS, 2015) shows promise as a means to combine content from multiple categories of metadata into a single search interface. The challenge of granularity of data is explicitly addressed with a drill-down approach to search from Collection (dataset or dataset collection) to granule (individual file/data product) level. This is achieved by establishing a hierarchy of search endpoints from Collection down to granule search. Dataset metadata can be attached at the collection level in the search hierarchy serialised for example as O & M (ISO 19156 and OGC 10025) observations or using ISO 19139. OpenSearch itself is a simple open standard for data discovery which defines a response based on syndication formats such as Atom and RSS, extending these with search metadata. Search endpoints include a description document which enables clients to introspect the given service and determine the semantics for search queries. Initiatives such as CWIC17 and FedEO18 are taking advantage of OpenSearch to create federated search infrastructures linking data repositories from multiple agencies (Miura, 2016).
For discovery, ESGF itself could migrate to the OpenSearch standard. This has been implemented for the CEDA archive ESA Sentinel data products and clearly it could address the problems encountered in the project with the differing semantics and content for OGC CSW and ESGF Search. A future system could provide an OpenSearch service that would serve dataset and file-level response content. Dataset metadata could be represented using the O & M observations or as ISO 19115 records. OpenSearch is being considered for adoption for ESGF in its technical roadmap.
We have built the CCI Open Data Portal ecosystem consisting of a Web Presence exploiting standard APIs for data discovery and access integrated together with standardised vocabulary services exposing new vocabularies developed for the project. The development methodology involved:
The system depends on a workflow which takes data that conforms to the CCI data specification, ingests it into the CEDA Archive, and uses both manual and automatically generated metadata to support data discovery, browse and delivery services based on the deployment of both Earth System Grid Federation nodes and OGC-CSW metadata catalogues. An integral part of the system is a new vocabulary server, populated with CCI specific terms and relationships developed as part of an iterative dialogue between domain scientists and linked data specialists. Third party applications, including GEOSS and the CCI ToolBox are able to consume the CCI Open Data Portal services.
|CEDA||Centre for Environmental Data Analysis|
|CF-NetCDF||denotes data formatted using the Network Common Data Form (NetCDF) from|
|Unidata which complies with the Climate and Forecast Conventions for describing and naming data variables.|
|CCI||The ESA Climate Change Initiative|
|CMIP5||5th Coupled Model Intercomparison Project|
|CSW||Catalogue Service for the Web – standard from the Open Geospatial Consortium defining a web service interface for discovery of catalogue records that describe geospatial data.|
|CWIC||CEOS (Committee on Earth Observation Satellites) WGISS (Working Group on Information Systems and Services) Integrated Catalogue|
|DRS||Data Reference Syntax – a system of controlled vocabularies for describing data defined for datasets hosted in the Earth System Grid Federation.|
|ECV||Essential Climate Variable (within the ESA CCI).|
|ESA||European Space Agency|
|ESGF||Earth System Grid Federation|
|GEOSS||Global Earth Observation System of Systems|
|HTTP||Hypertext Transfer Protocol|
|JASMIN||The UK Joint Analysis supercomputer|
|MOLES||Metadata Objects for Linking Environmental Sciences – a metadata information model developed for CEDA.|
|NCML||NetCDF Markup Language|
|NetCDF||Network Common Data Form – data format and software libraries from Unidata for array-based scientific data|
|NOSQL||Not-only SQL – Collective name for database technologies which do not follow the strict rules governing traditional relational databases.|
|NVS||NERC (Natural Environment Research Council) Vocabulary Service.|
|OBS4MIPS||The Project for Observations for Model Intercomparison Projects|
|OGC||Open Geospatial Consortium|
|OPeNDAP||Open-source Project for a Network Data Access Protocol – initiative focussed on the development of services for remote access of gridded data through the DAP (Data Access Protocol) specification.|
|OWL||Web Ontology Language|
|SKOS||Simple Knowledge Organisation System|
|THREDDS||Thematic Real-time Environmental Distributed Data Services – project from Unidata to develop middleware to bridge between data providers and users|
|WMS||Web Map Service – Open Geospatial Consortium standard defines a web service interface for accessing geo-referenced map images|
|WCS||Web Coverage Service – Open Geospatial Consortium standard defines a web service interface for service data coverages defined by geo-temporal query parameters.|
|WCPS||Web Coverage and Processing Service – Open Geospatial Consortium standard which defines a query language for filtering and processing multi-dimensional coverage data.|
2GNU Wget, https://www.gnu.org/software/wget/.
3GEOSS Portal http://www.geoportal.org/.
4THREDDS Data Server https://www.unidata.ucar.edu/software/thredds/current/tds/.
5ESGF Search API https://www.earthsystemcog.org/projects/cog/esgf_search_restful_api.
6GrADS Data Server, http://cola.gmu.edu/grads/gds.php.
7Live Access Server https://ferret.pmel.noaa.gov/LAS/.
8Web Coverage and Process Service http://www.opengeospatial.org/standards/wcps.
9Apache Solr: https://lucene.apache.org/solr.
10Simple Knowledge Organisation System https://www.w3.org/2004/02/skos/.
11Web Ontology Language https://www.w3.org/OWL/.
13Global Climate Observing System https://gcos.wmo.int/.
14Apache Jena https://jena.apache.org/.
The authors would like to acknowledge the funding and support for the project from the European Space Agency, inputs from members of the ESA Climate Office and the contribution of the CCI Open Data Portal project partners Brockmann Consult, CGI, University of Reading and Telespazio-Vega UK. In addition, we would like to thank Antonio Cofiño, University of Cantabria, Spain, for his technical assistance in configuring and optimising THREDDS Data Server to serve the ECV data products.
The authors have no competing interests to declare.
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