Arc Hydro Groundwater Data Model GIS in Water Resources Fall 2009 With contributions from Norm Jones (BYU), Gil Strassberg (Aquaveo), David Maidment (UT.

Arc Hydro Groundwater Data Model GIS in Water Resources Fall 2009 With contributions from Norm Jones (BYU), Gil Strassberg (Aquaveo), David Maidment (UT Austin), Tim Whiteaker (UT Austin), Steve Grise (ESRI), Steve Kopp (ESRI)

Learning Objectives: By the end of this class you should be able to: Understand how we describe subsurface features in GIS using the Arc Hydro Groundwater Data Model Understand the linkages from one subsurface feature to another, and to time series or hydrostratigraphic data

Outline Background Arc Hydro Framework Arc Hydro Groundwater Components

Linking GIS and Water Resources GIS Water Resources

Arc Hydro: GIS for Water Resources Arc Hydro – An ArcGIS data model for water resources – Arc Hydro toolset for implementation – Framework for linking hydrologic simulation models The Arc Hydro data model and application tools are in the public domain Published in 2002, now in revision for Arc Hydro II

Challenges in developing Arc Hydro ArcGIS is a very successful static, 2D or 2.5D system For surface water resources we need – Close connection between raster terrain and vector stream data – Linkage to time varying water data observations stored at gages – Access to precipitation and evaporation data “fields” For groundwater resources we need – 3D representation of boreholes and hydrogeologic units – Integration with groundwater models, especially MODFLOW, which has become the ArcInfo of groundwater

Arc Hydro Groundwater – Time Line Arc Hydro book and tools published - 2002 Initial groundwater data model discussions, initial designs at the Center for Research in Water Resources, UT Austin - 2003 First complete design of Arc Hydro Groundwater data model - 2006 Arc Hydro Groundwater presented at ESRI User Conference - 2007 ESRI and Aquaveo team to develop Arc Hydro Groundwater Tools - 2007 Arc Hydro Groundwater Tools released - 2009 Arc Hydro Groundwater book - 2009-2010

What is a hydrologic data model Booch et al. defined a model: “a simplification of reality created to better understand the system being created” Objects Aquifer Stream Well Volume R.M. Hirsch, USGS

Developing a groundwater data model Take a variety of spatial information and integrate into one geospatial database with a common terminology Better communicationBetter communication Integration of dataIntegration of data Base for applicationsBase for applications Groundwater data model (geospatial database) Time series observations Geologic maps Borehole data Geospatial vector layers Gridded data Numerical models Hydrostratigraphy

Framework and Components Network Framework Surface water components Drainage Hydrography Channel Groundwater components Components can be added to the framework to represent specific themes in more detail Borehole data Hydrostratigraphy Geology Simulation Temporal (enhanced)

Arc Hydro Framework Basic representation of surface water and groundwaterBasic representation of surface water and groundwater Components can be added to the framework to represent specific themes in more detailComponents can be added to the framework to represent specific themes in more detail

Well Wells are the most basic features in groundwater databases Attributes of wells describe the location, depth, water use, owner, etc.

Well Wells are defined as 2D point features Only some basic attributes are predefined to describe the well use, and geometry and relationship with aquifers Wells in the Edwards Aquifer

Aquifer features Polygon features for representing aquifer boundaries and zones within themPolygon features for representing aquifer boundaries and zones within them Representation of Aquifer mapsRepresentation of Aquifer maps

Aquifer features An aquifer is defined by one or a set of polygon features Aquifer features can be grouped by HGUID

Hydro Features Key attributes for feature identificationKey attributes for feature identification HydroID – Unique ID within the geodatabase (internal relationships)HydroID – Unique ID within the geodatabase (internal relationships) HydroCode – Public identifier (external relationships)HydroCode – Public identifier (external relationships)

HydroID A new ID assigned to features in a Arc Hydro geodatabase Uniquely identifies features within a geodatabase Is used to manage relationships between features and to relate features with tabular data (e.g. time series) Custom tool for managing HydroIDs

HydroCode links to external applications Web interface for groundwater data in TexasWeb interface for groundwater data in Texas Texas Water Information Integration & Dissemination (WIID)Texas Water Information Integration & Dissemination (WIID)

Aquifer and well Well features are related to Aquifers: The AquiferID of a well feature is equal to the HydroID of an aquifer featureWell features are related to Aquifers: The AquiferID of a well feature is equal to the HydroID of an aquifer feature An aquifer can be associated with one or more wells (1:M relationship)An aquifer can be associated with one or more wells (1:M relationship) Can take a different approach to support M:N relationshipCan take a different approach to support M:N relationship * HydroID HydroCode Name HGUID FType Aquifer HydroID HydroCode LandElev WellDepth AquiferID AqCode HGUID FType Well 1

Aquifer and well Well HydroID = 53

Wells and TimeSeries Well features are related with time series (water levels, water quality ) San Marcos springs Springs Sink Creek San Marcos Monitoring Well (295443097554201)

MonitoringPoint has time series Monitoring points are related with time series (streamflow, water quality, precipitation)

Integration of surface water and groundwater data Streamflow Gage at Comal Springs, New Braunfels Texas Well in the Edwards Aquifer) The common framework supports analysis of surface water and groundwater data together

Surface water - groundwater linkage Relationships between surface water and aquifer enable analysis based on spatial and hydrologic relationships Streams over the outcrop = recharge features

Implementing the Arc Hydro framework 1.Create the classes of the Arc Hydro Framework (manually using ArcCatalog or by importing from an xml schema) 2.Add project specific classes, attributes, relationships, and domains as necessary 3.Document datasets and changes made to the data model 4.Import data into the framework classes (e.g. streams, wells, aquifers, time series) 5.Assign key attributes to uniquely identify the features and establish relationships 6.Apply tools to create new features and calculate attributes 7.Visualize data and create products (maps, scenes, reports)

Components Geology - Representation of data from geologic maps Wells and Boreholes – Description of well attributes and borehole data Hydrostratigraphy – 2D and 3D description of hydrostratigraphy Temporal – Representation of time varying data Simulation – Representation of groundwater simulation models (focus on MODFLOW)

Geologic maps A geologic map is a cartographic product that portrays information about the geologic character of a specific geographic area Groundwater features are closely tied to geology Groundwater features are closely tied to geology Geologic maps vary in scale (continental, regional, local) Geologic maps vary in scale (continental, regional, local) Provide a simple data structure to support mapping Provide a simple data structure to support mapping Geology Aquifers Maps from the United States National Atlas (http://nationalatlas.gov/).http://nationalatlas.gov/

Geologic map databases Arc Geology: Arc Geology: generic geologic map data model implemented within ArcGIS (figure from Raines et al. 2007) Geodatabase design for storing data from the Geologic Atlas of Texas ( Geodatabase design for storing data from the Geologic Atlas of Texas (http://www.tnris.org/news.aspx?id=244 )http://www.tnris.org/news.aspx?id=244

Geology component Map modified from: Geologic map of the Edwards Aquifer recharge zone, south-central Texas. U.S. Geological Survey SIM 2873 GeologyPoint: Point feature (e.g. springs, caves, sinks, and observation points) GeologyLine: Line features (e.g. faults, contacts) GeologyArea: Areal features (e.g. rock units and alteration zones)

Well databases Wells are basic features in groundwater databases Attributes of wells describe its location, depth, water use, owner, etc. Data are collected from drilling/construction reports and permits

Well databases Well databases store information on wells and related data Data are related to wells such as construction, water levels, water quality, and stratigraphy Usually a central table is used to describe well features and other data are linked to it through key attributes (e.g. state well number) Relationships in the TWDB groundwater database

Well The Well location is defined as a 2D point in the Well feature class In the Arc Hydro model we only predefine a set of basic attributes Wells in the Edwards Aquifer

Borehole data 3D data (screens, completion intervals, stratigraphy) are referenced along the well3D data (screens, completion intervals, stratigraphy) are referenced along the well From depth (top) – To depth (bottom)From depth (top) – To depth (bottom)

BoreholeLog table Used to store 3D borehole data related with well featuresUsed to store 3D borehole data related with well features Each row in the table represents a point/interval along a boreholeEach row in the table represents a point/interval along a borehole Data are related with a Well feature through the WellID attributeData are related with a Well feature through the WellID attribute 3D geometry is defined by the TopElev and BottomElev attributes3D geometry is defined by the TopElev and BottomElev attributes

3D features (BorePoints and BoreLines) Can create 3D features representing data in the BoreholeLog table BorePoint is a 3D point feature class for representing point locations along a borehole (e.g. geologic contacts, samples) BoreLine is a 3D line feature class for representing intervals along a borehole

Hydrogeologic units “Hydrogeologic unit is any soil or rock unit or zone which by virtue of its hydraulic properties has a distinct influence on the storage or movement of ground water” (USGS glossary of hydrologic terms) Hydrogeology can be derived by classifying stratigraphic units Georgetown Fm. (GTOWN) Cyclic + Marine member (CYMRN) Upper confining unit Leached + collapsed member (LCCLP) Regional dense member (RGDNS) Grainstone member (GRNSTN) Kirschberg evaporite member (KSCH) Dolomitic member (DOLO) Upper Glen Rose (UGLRS) Stratigraphic units Hydrogeologic units Pearson Fm. Basal Nodular member (BSNOD) Kainer Fm. Georgetown Fm. Edwards Aquifer

Hydrogeologic unit table HydroGeologicUnit table provides a conceptual description of hydrogeologic units Hydrogeologic units can be attributed with an AquiferID such that they can be grouped to represent an aquifer Spatial features are indexed with a HGUID to relate to the conceptual representation of the units

Representations of hydrogeologic units Different spatial representations of hydrogeologic units with 2D and 3D objects Workflow for creating 3D hydrogeologic models

Hydrogeologic unit table Hydrogeologic units are described with different spatial instances (outcrops, borehole intervals, surfaces, cross sections, and volumes) HGUID is the key attribute HGUID Conceptual description Spatial description GeoArea Polygonfeature class HydrogeologicUnit Table SectionLine PointZfeature class GeoRasters Raster dataset GeoSection Multipatchfeature class GeoVolume Multipatchfeature class 1 *

GeoArea GeoArea feature representing the Kainer hydrogeologic unit GeologyArea features represent data from geologic maps GeologyArea 2D polygons defining boundaries of hydrogeologic units2D polygons defining boundaries of hydrogeologic units GeoArea (conceptual/interpolated boundary) ≠ GeologyArea (mapped outcrop)GeoArea (conceptual/interpolated boundary) ≠ GeologyArea (mapped outcrop) Data points representing top elevations of the Kainer formation

Representation of Cross Sections SectionLine SectionLine defines the 2D cross section GeoSection represent 3D sections as 3D features GeoSection represent 3D sections as 3D features SectionID of the polygon relates back to the section line SectionID of the polygon relates back to the section line A A’ BB’

GeoRasters Raster catalog for storing and indexing raster datasets Can store top and bottom of formations Each raster is related with a HGU in the hydrogeologic unit table Georgetown Glen Rose Kainer Person

GeoRasters GeoRasters also store hydraulic properties such as transmissivity, conductivity, and specific yield K (feet/day) Raster of hydraulic conductivity in the Edwards Aquifer

GeoVolume Objects for representing 3D volume objects Geometry is multipatch - Can create the volumes as a set of 3D triangles Not real volume – can’t do any 3D operations

Types of time varying datasets Single variable time series (time series) – A single variable recorded at a location, such as stream discharge or groundwater levels Multi-variable time series (attribute series) – Multiple variables recorded simultaneously at the same location, such as chemical analysis of a water sample Time varying surfaces (raster series) – Raster datasets indexed by time. Each rater is a “snapshot” of the environment at a certain time. Time varying features (feature series) – A collection of features indexed by time. Each feature in a feature series represents a variable at a single time period.

Time series The most basic case is a monitoring device recording values over time (e.g. monitoring well, streamflow gage) San Marcos springs Springs San Marcos River Sink Creek San Marcos Monitoring Well (295443097554201 )

Time series TimeSeries table is the basic table for storing time series data Need to support: what, where, and when VariableDefinition table describes variables Time (TsTime) Space (FeatureID) Variables (VarID)

Time series By querying the table we can create different data views 2791 TsTime FeatureID VarID 2 FeatureID VarID 2791FeatureID VarID 2 (a)(b)(c)TsTime

Time series views – create time series graph Well HydroID = 2791 FeatureID of the time series = HydroID of the spatial feature (e.g. Well)FeatureID of the time series = HydroID of the spatial feature (e.g. Well)

Time series views – map a variable at a given time Map a certain variable (e.g. water levels) at a given time (e.g. February 2004) FeatureID VarID 2 TsTime 2/2004 Feet above mean sea level

Multi-variable time series Data are indexed by space (FeatureID) and by time (TsTime) but instead of one variable we store multiple variables.Data are indexed by space (FeatureID) and by time (TsTime) but instead of one variable we store multiple variables. The column heading is the variable key (VarKey)The column heading is the variable key (VarKey) Variables (VarKey)

RasterSeries Raster datasets indexed by time Each raster represents a continuous surface describing a variable for a given time over an area of interest January 1991 January 1992 January 1993

Feature Series A collection of features indexed by time (e.g. particle tracks) Features are indexed by VarID, TsTime. Features can also be indexed with a GroupID. Each group of features creates a track over time

Representing simulation models Georeference model inputs and outputs (in space and time)Georeference model inputs and outputs (in space and time) Focus on MODFLOW, block centered finite difference grid (nodes are in the center of the cells)Focus on MODFLOW, block centered finite difference grid (nodes are in the center of the cells) Represent 2D and 3D modelsRepresent 2D and 3D models Block-centered finite difference grid

Simulation component Features for representing data from simulation models

Boundary Polygon feature class for representing the extent and orientation of a simulation model

Cell2D and Node Cell2D: polygon feature class that represents cells or elements associated with a two-dimensional simulation model or a single layer of a three-dimensional model Node: point feature class used in combination with Cell2D to represent the model’s mesh/grid. a)Finite element mesh b)Mesh centered finite difference grid c)Cell centered finite difference grid

Cell2D and Node Used to create maps of model data

Node3D and Cell3D Node3D – a Z enabled point feature class Cell3D - Multipatch feature class Represent three-dimensional cells and Nodes Used mostly for visualization of 3D modelsUsed mostly for visualization of 3D models

Summary Concepts Arc Hydro Groundwater… – extends Arc Hydro to represent groundwater datasets in GIS – includes components for aquifers, wells, hydrogeologic features, time series, and simulation model output – links features to hydrogeologic layers via HGUID, and to aquifers via AquiferID

Websites ESRI Data Model Website: www.esri.com/datamodelswww.esri.com/datamodels Arc Hydro Groundwater Websites: www.archydrogw.comwww.archydrogw.com www.aquaveo.com/archydro Contact: Norm Jones (njones@aquaveo.com)njones@aquaveo.com Gil Strassberg (gstrassberg@aquaveo.com)gstrassberg@aquaveo.com Steve Grisé (sgrise@esri.com)sgrise@esri.com

Arc Hydro Groundwater Data Model GIS in Water Resources Fall 2009 With contributions from Norm Jones (BYU), Gil Strassberg (Aquaveo), David Maidment (UT.

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Arc Hydro Groundwater Data Model GIS in Water Resources Fall 2009 With contributions from Norm Jones (BYU), Gil Strassberg (Aquaveo), David Maidment (UT.

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Presentation on theme: "Arc Hydro Groundwater Data Model GIS in Water Resources Fall 2009 With contributions from Norm Jones (BYU), Gil Strassberg (Aquaveo), David Maidment (UT."— Presentation transcript:

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