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![Page 1: Geoscience data standards Establishing geological map and mineral occurrence data exchange standards Bruce Simons GeoScience Victoria.](https://reader035.fdocuments.net/reader035/viewer/2022062517/56649f1f5503460f94c377a1/html5/thumbnails/1.jpg)
Geoscience data standards
Establishing geological map and mineral occurrence data exchange standards
Bruce Simons
GeoScience Victoria
![Page 2: Geoscience data standards Establishing geological map and mineral occurrence data exchange standards Bruce Simons GeoScience Victoria.](https://reader035.fdocuments.net/reader035/viewer/2022062517/56649f1f5503460f94c377a1/html5/thumbnails/2.jpg)
Geoscience data standards
OutlineOutline
• Data exchange requirements (Interoperability)
• Exchange standard for geological data (GeoSciML)
• Testing the GeoSciML standard
• The Mineral Occurrence extension
• The Future
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Geoscience data standards
The problem• access to Government geoscience information is fragmented and inefficient
Delivering Government Digital Geoscience Data
Delivering Government Digital Geoscience Data
2004 Minerals Exploration Action Agenda …
• existing information is distributed across eight state and federal agencies
• each with its own information management systems and data formats
• up to 80% of time acquiring pre-competitive data is taken up by reformatting disparate data from government sources
• a disincentive to exploration
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Geoscience data standards
Why is it so hard?
• 8 Australian jurisdictions provide digital geoscience map data
• 8 data structures and delivery systems
• 2 (at least) proprietary software specific data formats
• cannot access more than one agency’s data at a time
The Solution is “Interoperability”• Establish a software-independent DATA TRANSFER STANDARD
“the ability of software and hardware on different machines from different vendors to
share data”
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Geoscience data standards
systems
syntax
schematic
semantic
interoperability
Data Structure (GeoSciML, MineralOccurrences, O&M)
Data Content (Ontologies, Vocabularies)
Data Language (GML, XML)
Data Services (WFS, WMS, WCS)
Interoperability RequirementsInteroperability Requirements
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Geoscience data standards
Agree to use Web Services (WFS, WMS, WCS)
Software capabilities are limited to simple data models
• Existing vendor and open source software aim to support OGC
web service specifications (e.g. GML and complex features)
• Ongoing collaborative work with software developers to serve the
complex feature model needed for geological information
Not all required OGC standards properly specified and
tested
• E.g. Registries, binding WFS to WMS, handling xpath/href links
Systems AgreementSystems Agreement
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Geoscience data standards
How do you convert standard representations of complex
data models (UML) to standard schema (GML)?
• Need to establish UML rules (single inheritance, associations
must have role names, etc)
• Need to establish conversion rules (what to do with Union,
interface classes etc)
• Establish name spaces
Need software to enable automatic generation of schema
Syntax AgreementSyntax Agreement
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Geoscience data standards
systems
syntax
schematic
semantic
interoperability
Data Structure (GeoSciML, MineralOccurrences, O&M)
Data Content (Ontologies, Vocabularies)
Data Language (GML, XML)
Data Services (WFS, WMS, WCS)
Interoperability RequirementsInteroperability Requirements
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Geoscience data standards
Victoria
South Australia
Schematic AgreementSchematic AgreementCompoundMaterial
«Type»
EarthMaterial::Rock
+ consolidationDegree: CGI_Term+ lithology: ControlledConcept [1..*]
lithology
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Geoscience data standards
systems
syntax
schematic
semantic
interoperability
Data Structure (GeoSciML, MineralOccurrences, O&M)
Data Content (Ontologies, Vocabularies)
Data Language (GML, XML)
Data Services (WFS, WMS, WCS)
Interoperability RequirementsInteroperability Requirements
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Geoscience data standards
Cainozoic?
Palaeozoic?
Archaean?
Bolindian?Eastonian?Gisbornian?
Late?Early?
Semantic Agreement Semantic Agreement • Select geologic features where age = “xxx”
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Geoscience data standards
• Geological data is largely text-based and interpretive. Simple
numerical data is rare.
• Compliance to many controlled vocabularies is not a trivial exercise
• Compliance to vocabularies is crucial to be able to construct
standardised requests on distributed data
• Establish language independent identifiers that local terms and
languages can be mapped to
• GGIC Controlled Vocabularies Working Group and CGI
Geoscience Concepts Task Group
Semantic Agreement Semantic Agreement
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Geoscience data standards
availability of appropriate technologies
common data structure
software independence
common data content
commitment to these standards
Interoperability RequirementsInteroperability Requirements
- OGC, ISO, W3C
- CGI-IUGS
- INSPIRE, GGIC
Summary
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Geoscience data standards
• Open data standards
• Efficiencies for government
• Efficiencies for industry
• Benefits for the wider geoscience community
Interoperability BenefitsInteroperability Benefits
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Geoscience data standards
A Geological Data Model• based on real world concepts
• represents the complexity of geology (hierarchical, relational)
• tells users what geological information goes where
• developed by the scientific community
• internationally agreed
• builds on established standards such as GML (Geographic Markup
Language)
• uses the ISO ‘feature’ model
GeoScience Markup Language • the markup language delivers the model to web services
• is machine readable
What is GeoSciML?What is GeoSciML?
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Geoscience data standards
Committee for the Management and Application of
Geoscience Information
Committee for the Management and Application of
Geoscience Information
Australia
USA
Canada
France
UK
Sweden
Italy
Japan
Interoperability Working Group
GeoScience Markup LanguageGeoScience Markup Language
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Geoscience data standards
«FeatureType»GeologicFeature::MappedFeature
+ observationMethod: CGI_TermValue [1..*]+ positionalAccuracy: CGI_Value
«FeatureType»GeologicFeature::GeologicFeature
+ observationMethod: CGI_TermValue [1..*]+ purpose: DescriptionPurpose = instance
«FeatureType»GeologicUnit::GeologicUnit
«estimatedProperty»+ bodyMorphology: CGI_TermValue [0..*]+ compositionCategory: CGI_TermValue [0..1]+ exposureColor: CGI_TermValue [0..*]+ outcropCharacter: CGI_TermValue [0..*]+ rank: ScopedName [0..1]
«DataType»GeologicUnit::GeologicUnitPart
+ role: ScopedName
«estimatedProperty»+ proportion: CGI_Value
«DataType»GeologicUnit::MetamorphicDescription
«estimatedProperty»+ metamorphicFacies: CGI_TermValue [0..*]+ metamorphicGrade: CGI_TermValue [0..1]+ peakPressureValue: CGI_NumericValue [0..1]+ peakTemperatureValue: CGI_NumericValue [0..1]+ protolithLithology: EarthMaterial [0..*]
«FeatureType»GeologicUnit::ChronostratigraphicUnit
«estimatedProperty»+ beddingPattern: CGI_TermValue [0..*]+ beddingStyle: CGI_TermValue [0..*]+ beddingThickness: CGI_Value [0..*]+ definingAge: CGI_Value+ unitThickness: CGI_Numeric [0..*]
«FeatureType»GeologicUnit::LithologicUnit
«FeatureType»GeologicUnit::LithostratigraphicUnit
«estimatedProperty»+ beddingPattern: CGI_TermValue [0..*]+ beddingStyle: CGI_TermValue [0..*]+ beddingThickness: CGI_Value [0..*]+ unitThickness: CGI_Numeric [0..*]
«FeatureType»GeologicUnit::LithodemicUnit
«DataType»GeologicUnit::PhysicalDescription
«estimatedProperty»+ density: CGI_Numeric [0..1]+ magneticSusceptibility: CGI_Value [0..1]+ permeability: CGI_Value [0..1]+ porosity: CGI_Value [0..1]
«DataType»GeologicUnit::WeatheringDescription
«estimatedProperty»+ environment: CGI_Term [0..*]+ weatheringDegree: CGI_Term [0..1]+ weatheringProcess: CGI_Term [0..*]+ weatheringProduct: EarthMaterial [0..*]
«DataType»GeologicUnit::CompositionPart
+ role: ScopedName
«estimatedProperty»+ lithology: ControlledConcept [1..*]+ material: CompoundMaterial [0..1]+ proportion: CGI_Value
AnyDefinition
«Type»Vocabulary::ControlledConcept
+ identifier: ScopedName+ name: LocalizedGenericName [1..*]
Metadata entity set information::MD_Metadata
{n}
«FeatureType»GeologicAge::GeologicEvent
+ eventAge: CGI_Value+ eventEnvironment: CGI_TermValue [0..*]+ eventProcess: CGI_TermValue [1..*]
+specification 1
Description
+occurrence
0..*
+part
0..*
+containedUnit
1
+metamorphicCharacter
0..1
+physicalProperty
0..*
+weatheringCharacter
0..1
+composition«estimatedProperty»
0..*
0..*
+classifier
0..1
+metadata
0..1
+metadata0..1
+metadata
0..1
+preferredAge 0..1
+feature
+geologicHistory
0..*
Presented as a series of class diagrams which show the properties of, and relationships between, geological features
The GeoSciML Data ModelThe GeoSciML Data Model
Geological unit features
• composition (earth materials)
• metamorphism
• weathering character
• physical properties
• spatial representation
• unit types (lithostratigraphic, chronostratigraphic)
• age and geological history (events)
• unit parts (child/parent relations)
• vocabularies• metadata
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Geoscience data standards
Geological Data Model BenefitsGeological Data Model Benefits
• data providers need only “map” their own local data
structures to the data transfer structure
• data providers don’t need to change their local
database structures to use the transfer standard
• allows language independent terminology to be used
(i.e. controlled vocabularies)
• is open source
• software vendor independent
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Geoscience data standards
GeoSciML BenefitsGeoSciML Benefits
GML
Client
WMS WFS
WMSWFS
WMSWFS
WMS WFS
GeoSciML
GeoSciML
GeoSciML
GeoSciML
GA
GSV
BGS
USGS
BGS
schema
GSV
schema
GA
schema
USGS
schema
a standard GML schema for geological data
WMS WFS
GeoSciML
GSCGSC
schema
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Geoscience data standards
Testing the GeoSciML standardTesting the GeoSciML standard
Testbed 1 2005 - A borehole demonstrator between UK and France
Testbed 2 2006 – A six nation demonstrator delivering geological
map data from globally distributed sources using GeoSciML v1.1
Testbed 2 Use cases
display map, query one feature, return attributes in GeoSciML
query several map features, return GeoSciML file for download
reclassify map features based on Age or Lithology
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Geoscience data standards
GeoSciML
Vancouver, CAVancouver, CAUppsala, SVUppsala, SV
Canberra, AUCanberra, AU
Ottawa, CAOttawa, CA
Reston, VAReston, VA
Keyworth, UKKeyworth, UK
Portland, ORPortland, OR
Orleans, FROrleans, FR
Accessing GeoSciML data using a web client in CanadaAccessing GeoSciML data using a web client in Canada
GeoSciML Testbed2GeoSciML Testbed2
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Geoscience data standards
• Successfully demonstrated WMS/WFS delivery, display and download of distributed data sources and simple query functions
• Not previously attempted with such a complex model
• Identified capabilities and limitations of WFS and OGC
standards
• Highlighted technical challenges to be able to deliver and
consume complex features using WFS• Highlighted the need to establish well-defined limits for any
web data services • Reinforced the importance of documentation of the data model
to guide participants
Lessons Learnt from Testbed2Lessons Learnt from Testbed2
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Geoscience data standards
Wide ranging and ambitious use cases
• Use Case 1 – Render a geological map from multiple data sources
• symbols based on age or lithology• language dependent legend
• Use Case 2 – Return GML for mapped features in bounding box
• service profiles may vary to deliver sampling features, mapped features of geologic structures, links to composition or a stratigraphic lexicon
• Use Case 3 – User defined query (eg “all GeologicUnits of Silurian age”)
• Use Case 4 – Data transport for import/export from applications
• GSI3D, GeoModeller, ESRI, dB to dB
• Use Case 5 – Register of Web, Vocabulary, Symbology services
Delivery at IGC33, August 2008 – Oslo, Norway
Testbed 3 (in progress)Testbed 3 (in progress)
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Geoscience data standards
• GGIC established standard
• Extension of GeoSciML
• Data exchange model for mineral occurrences
• Develop a standard model that includes
reserves and resources
• Standardised vocabularies
The Mineral Occurrences extensionThe Mineral Occurrences extension
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Geoscience data standards
Mineral SystemMineral Deposit Model
Earth Resource
Mapped Feature
Earth Resource Material
MineMining Activity
Commodity
Product
Resource
Reserve
Endowment
«FeatureType»GeologicFeature::GeologicFeature
+ observationMethod: CGI_TermValue [1..*]+ purpose: DescriptionPurpose = instance
«FeatureType»GeologicFeature::MappedFeature
+ observationMethod: CGI_TermValue [1..*]+ positionalAccuracy: CGI_Value
«FeatureType»EarthResource
+ sourceReference: CI_Citation [0..*]
«estimatedProperty»+ dimension: EarthResourceDimension [0..1]+ expression: CGI_TermValue [0..*]+ form: CGI_TermValue [0..*]+ linearOrientation: CGI_LinearOrientation [0..*]+ planarOrientation: CGI_PlanarOrientation [0..*]+ shape: CGI_TermValue [0..*]
«DataType»SupergeneProcesses
+ depth: CGI_Numeric [0..1]+ material: EarthMaterial [0..*]+ type: CGI_TermValue [0..1]
«FeatureType»MineralOccurrence
«estimatedProperty»+ type: MineralOccurrenceTypeCode
«DataType»MineralSystem
+ associationType: CGI_TermValue
«DataType»MineralDepositModel
«estimatedProperty»+ mineralDepositGroup: ScopedName [1..*]+ mineralDepositType: ScopedName [0..*]
«DataType»EarthResourceMaterial
+ earthResourceMaterialRole: ERMaterialRoleCode+ material: EarthMaterial
«FeatureType»MiningActivity
+ activityDuration: TM_Period+ activityType: MiningActivityTypeCode+ oreProcessed: CGI_Numeric [0..1]
«FeatureType»Mine
+ endDate: TM_Instant [0..1]+ mineName: MineNamePreference [1..*]+ sourceReference: CI_Citation+ startDate: TM_Instant [0..1]+ status: MineStatusCode
«FeatureType»Product
+ productName: CGI_TermValue+ sourceReference: CI_Citation [1..*]
«estimatedProperty»+ grade: CGI_Numeric [0..1]+ production: CGI_Numeric [0..1]+ recovery: CGI_Numeric [0..1]
«FeatureType»Commodity
+ commodityGroup: ScopedName [0..*]+ commodityName: ScopedName
«estimatedProperty»+ commodityImportance: ImportanceCode [0..1]+ commodityRank: Integer [0..1]
«DataType»OreMeasure
+ calculationMethod: CharacterString+ date: TM_GeometricPrimitive+ dimension: EarthResourceDimension [0..1]+ proposedExtractionMethod: CGI_TermValue [0..1]+ sourceReference: CI_Citation [1..*]
«estimatedProperty»+ ore: CGI_Numeric
«DataType»Endowment
+ includesReserves: Boolean+ includesResources: Boolean
«DataType»Reserve
+ category: ReserveCategoryCode
«DataType»Resource
+ category: ResourceCategoryCode+ includesReserves: Boolean
«FeatureType»GeologicAge::GeologicEvent
+ eventAge: CGI_Value+ eventEnvironment: CGI_TermValue [0..*]+ eventProcess: CGI_TermValue [1..*]
«DataType»CommodityMeasure
«estimatedProperty»+ commodityAmount: CGI_Numeric [0..1]+ cutOffGrade: CGI_Numeric [0..1]+ grade: CGI_Numeric [0..1]
«DataType»RawMaterial
+ material: EarthMaterial+ rawMaterialRole: RawMaterialRoleCode
1
+producedMaterial
1..*
1
+measureDetails
1..*
+feature+geologicHistory
0..*
+preferredAge
0..1
1
+oreAmount
0..*
0..*
+commodityOfInterest 1..*
0..*
+composition 0..*
0..*
+sourceCommodity
1
+relatedActivity1..*
+associatedMine0..1
0..*
+relatedMine0..1
1
+composition
0..*
0..*
+classification
0..1
0..*
+geneticDescription
0..1
1+supergeneModification
0..*
+child0..*
+parent0..1
+resourceExtraction 0..*
+deposit1
+specification
1 Description
+occurrence
0..*
+source1
+commodityDescription
1..*
Mineral System
Mineral Deposit Model
Earth Resource
Mapped Feature
Earth Resource Material
Mine
Mining Activity
Commodity
Product
Resource Reserve
Endowment
Mineral Occurrences ModelMineral Occurrences Model
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Geoscience data standards
• Describes Earth Resources independent of associated human activities
• Caters for descriptions of Earth Resources• Utilises GeoSciML MappedFeature to describe
spatial representation• Utilises GeoSciML EarthMaterial to describe host
and associated materials• Deliver mineral occurrence data through the
Australian Geoscience Portal• Real time access to the latest data
Mineral OccurrencesMineral Occurrences
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Geoscience data standards
Where to from here?Where to from here?
Within Australia…
An Australian Geoscience Portal
• All government geoscience map data
• Data served from distributed state and
federal sites to a single portal
• Using the GeoSciML, Mineral
Occurrence and Observation &
Measurements data transfer standards
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Geoscience data standards
OneGeology1:1 million digital world geology of 87 nationsAustralia – 1:2.5M and 1.1M (east)
Other Geoscience “ML’s” currently under development
• Landslides
• Geochronology
• Geochemistry
• Water
• Hydrogeology
• Earthquakes
Where to from here?Where to from here?
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Geoscience data standards
Questions?
Web sites CGI Home
http://www.cgi-iugs.org/
GeoSciML Data Model Working Group home
http://www.cgi-iugs.org/tech_collaboration/data_model/downloads.html
CGI Data Model Collaboration twiki
https://www.seegrid.csiro.au/twiki/bin/view/CGIModel/
Testbed 3 Use Cases
https://www.seegrid.csiro.au/twiki/bin/view/CGIModel/TestBed3UseCases