Generated entailment and validation results and serialisations

definitions/docs/docs.jsonld

@@ -44,6 +44,36 @@
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   },
   "@graph": [
+    {
+      "title": "OGC GGXF geodetic data grid exchange format",
+      "alternative": [
+        "OGC GGXF geodetic data grid exchange format",
+        "22-051r7"
+      ],
+      "URI": "https://www.opengis.net/doc/GGXF/1.0",
+      "identifier": "22-051r7",
+      "URL": "https://docs.ogc.org/is/22-051r7/22-051r7.pdf",
+      "type": "doctype:is",
+      "creator": "Roger Lott",
+      "contributor": null,
+      "description": "The Geodetic data Grid eXchange Format (GGXF) is designed to be a single file format that may be used\r\nfor a wide range of geodetic applications requiring interpolation of regularly gridded data, including (but\r\nnot limited to):\r\n\u2022 Transformation of latitude and longitude coordinates from one geodetic coordinate reference\r\nsystem to another;\r\n\u2022 Transformation of gravity-related heights from one vertical coordinate reference system to\r\nanother;\r\n\u2022 Reduction of ellipsoid heights to the geoid, quasi-geoid or a surface of a vertical reference frame;\r\nand\r\n\u2022 The description of coordinate changes due to deformation.\r\nThe GGXF format has been designed specifically for carrying gridded geodetic parameters supporting\r\ncoordinate transformations and point motion operations but has no restriction on the type of content\r\nthat may be included.",
+      "publisher": "Open Geospatial Consortium",
+      "language": "English",
+      "license": null,
+      "source": null,
+      "rights": "",
+      "isPartOf": null,
+      "date": "2024-04-29",
+      "dateAccepted": null,
+      "dateSubmitted": null,
+      "format": null,
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+      "@type": "skos:Concept",
+      "broader": "doctype:is",
+      "inScheme": "http://www.opengis.net/def/docs",
+      "notation": "22-051r7"
+    },
     {
       "title": "OGC Disaster Pilot: Provider Readiness Guide",
       "alternative": [
@@ -52,7 +82,7 @@
       ],
       "URI": "http://www.opengis.net/doc/PER/DP21-provider-readiness",
       "identifier": "21-074r2",
-      "URL": "https://docs.ogc.org/per/21-074r2/html",
+      "URL": "https://docs.ogc.org/per/21-074r2.html",
       "type": "doctype:per",
       "creator": "Samantha Lavender, Andrew Lavender",
       "contributor": null,
@@ -66,14 +96,74 @@
       "date": "2024-04-26",
       "dateAccepted": null,
       "dateSubmitted": null,
-      "format": null,
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       "notation": "21-074r2"
     },
+    {
+      "title": "Topic 24 - Functional Model for Crustal Deformation",
+      "alternative": [
+        "Topic 24 - Functional Model for Crustal Deformation",
+        "22-010r4"
+      ],
+      "URI": "http://www.opengis.net/doc/AS/Topic-24/1.0",
+      "identifier": "22-010r4",
+      "URL": "https://docs.ogc.org/as/22-010r4/22-010r4.html",
+      "type": "doctype:as",
+      "creator": "Chris Crook",
+      "contributor": null,
+      "description": "This OGC Abstract Specification (AS) defines a general parameterization of surface deformation models.\r\n\r\nAll objects on the surface of the Earth are moving. Apparently fixed features such as buildings are moving with the Earth\u2019s crust, being subject to ongoing plate tectonic movement and episodic deformation events such as earthquakes.\r\n\r\nIncreasingly, applications and users rely on global positioning methods, such as Global Navigation Satellite Systems (GNSS) observations, to precisely determine the coordinates of features. The resulting coordinates are then stored in databases and used in a wide range of applications, such as Geographic Information Systems (GIS). However, the coordinates from GNSS are referenced to global reference frames and coordinate reference systems (CRSs). In these reference frames the coordinates of apparently fixed objects are continually changing.\r\n\r\nThis creates a challenge for the geospatial and positioning community: How to account for this movement when comparing data sets observed at different times, or how to locate an object observed in the past.\r\n\r\nThis problem is generally addressed in one of two ways:\r\n\r\nDefining a reference epoch for the CRS of coordinates held in the GIS, often by defining a CRS with a reference epoch, or\r\nUsing a CRS which is fixed relative to the surface of the Earth.\r\nIn practice there is little difference between these two approaches. Neither the position at a reference epoch, nor the coordinates in a static CRS, can be directly measured by global positioning methods.\r\n\r\nPropagating the observed coordinates to a reference epoch, or transforming to a static CRS, requires a deformation model\u2009\u2014\u2009a mathematical model of the deformation of the Earth\u2019s surface.\r\n\r\nCommon uses of a deformation model include:\r\n\r\nDetermining the current location of an object based on historic measurement of its location,\r\nPropagation of the current observed location of an object to the reference epoch of a static CRS,\r\nDetermining the spatial relationship of data sets observed at different times, and\r\nPredicting the location of an object at some future time.\r\nCurrently, many national geodetic agencies have developed or are planning to develop regional deformation models. However, the current models generally use customized formats and software developed by each agency.\r\n\r\nThis AS describes a way of parameterizing a deformation model such that it can be encoded into a data set and used in software for coordinate operations. The AS defines how to calculate the displacement of a point between two different epochs. It provides a common understanding between producers of deformation models and developers of software about what the deformation is and how it will be used.\r\n\r\nThis AS will allow users of compliant software applying a compliant deformation model to be confident that the model is being used as intended by its producers.",
+      "publisher": "Open Geospatial Consortium",
+      "language": "English",
+      "license": null,
+      "source": null,
+      "rights": "",
+      "isPartOf": null,
+      "date": "2024-04-29",
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+      "inScheme": "http://www.opengis.net/def/docs",
+      "notation": "22-010r4"
+    },
+    {
+      "title": "OGC Disaster Pilot: User Readiness Guide",
+      "alternative": [
+        "OGC Disaster Pilot: User Readiness Guide",
+        "21-075r2"
+      ],
+      "URI": "http://www.opengis.net/doc/PER/DP21-user-readiness",
+      "identifier": "21-075r2",
+      "URL": "https://docs.ogc.org/per/21-075r2.html",
+      "type": "doctype:per",
+      "creator": "Andrew Lavender, Samantha Lavender",
+      "contributor": null,
+      "description": "Disasters are geographic events and therefore, geospatial information, tools and applications have the potential to support the management of, and response to, disaster scenarios.\r\n\r\nHowever, the use of geospatial data varies significantly across disaster and emergency communities. This can often make it difficult to share information between different organizations, and sometimes even within the same organization, involved in disaster response. This could mean that not everyone involved will have the same situational awareness information.\r\n\r\nThere are many reasons for why geospatial information is fully used and exploited, included a lack of awareness of what geospatial options are available, lack of geospatial technology and skills, lack of funding, etc. The Disaster Pilot User Guide aims to address some of these issues by providing a non-technical showcase of the workflows and tools developed by the Pilot participants demonstrating what opportunities there are for disaster and emergency management communities to use geospatial solutions in practice.\r\n\r\nFor over 20 years, the Open Geospatial Consortium (OGC) has been working on the challenges of information sharing for emergency and disaster planning, management, and response. In Disaster Pilot 23 (DP23) the aims were to:\r\n\r\nDevelop flexible, scalable, timely and resilient information data workflows to support critical disaster management decisions, enabling stakeholder collaboration, and\r\nProvide applications and visualization tools to promote the wider understanding of how geospatial data can support emergency and disaster communities.\r\nAs part of DP23, a trilogy of Guides were developed to improve knowledge and understanding of how geospatial data and tools and could support disaster and emergency communities. Alongside the User Guide is a Provider Guide giving all the detail technical details behind the work, and a companion Operational Capacity Guide describing the steps needed to develop geospatial readiness.\r\n\r\nThe User Guide contains a summary of the work undertaken in DP23, and Disaster Pilot 21 (DP21), where participants have worked on disaster scenarios relating to:\r\n\r\nDroughts\r\nWildland Fires\r\nFlooding\r\nLandslides\r\nHealth & Earth Observation Data for Pandemic Response\r\nCase Studies have focused on the hazards of drought in Manitoba, Canada; wildland fires in western United States; flooding in the Red River basin, Canada; landslides and flooding in Peru; and Pandemic response in Louisiana, United States. The participants have developed various data flows, alongside tools to support the collection, discovery, or visualization of data to support disaster management and response.\r\n\r\nAnnex A describes the tools and applications developed within the Pilots alongside the benefits these can offers. The Guide finishes with details of future possibilities, and where the Disaster Pilot initiative could focus next. Annexes B to E give descriptions of the data flows developed, including the aspects of disaster management or response the data flow relates to; together with the benefits it offers and the type of decisions it can support.\r\n\r\nThis document is for first responders, emergency managers, decision-makers, and anyone interested in encouraging disaster and emergency communities to realize the value of geospatial data to save lives and limit damage.",
+      "publisher": "Open Geospatial Consortium",
+      "language": "English",
+      "license": null,
+      "source": null,
+      "rights": "",
+      "isPartOf": null,
+      "date": "2024-04-29",
+      "dateAccepted": null,
+      "dateSubmitted": null,
+      "format": "text/html",
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+      "@type": "skos:Concept",
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+      "inScheme": "http://www.opengis.net/def/docs",
+      "notation": "21-075r2"
+    },
     {
       "title": "OGC Testbed 19 High Performance Geospatial Computing Engineering Report",
       "alternative": [