Presentation is loading. Please wait.

Presentation is loading. Please wait.

Space and Time By David R. Maidment with contributions from Steve Kopp, Steve Grise, and Tim Whiteaker.

Published byEdward Jennings Modified over 8 years ago

Similar presentations

Presentation on theme: "Space and Time By David R. Maidment with contributions from Steve Kopp, Steve Grise, and Tim Whiteaker."— Presentation transcript:

1 Space and Time By David R. Maidment with contributions from Steve Kopp, Steve Grise, and Tim Whiteaker

2 Space and Time Introductory concepts Discrete space-time model – Arc Hydro Temporal Geoprocessing Continuous space-time model – netCDF Tracking Analyst

3 Space and Time Introductory concepts Discrete space-time model – Arc Hydro Temporal Geoprocessing Continuous space-time model – netCDF Tracking Analyst

4 4 Linking GIS and Water Resources GIS Water Resources Water Environment (Watersheds, gages, streams) Water Conditions (Flow, head, concentration)

5 Data Cube Space, L Time, T Variables, V D “What” “Where” “When” A simple data model

6 6 Space, FeatureID Time, TSDateTime Variables, TSTypeID TSValue Discrete Space-Time Data Model ArcHydro

7 Continuous Space-Time Model – NetCDF (Unidata) Space, L Time, T Variables, V D Coordinate dimensions {X} Variable dimensions {Y}

8 CUAHSI Observations Data Model A relational database at the single observation level (atomic model) Stores observation data made at points Metadata for unambiguous interpretation Traceable heritage from raw measurements to usable information Streamflow Flux tower data Precipitation & Climate Groundwater levels Water Quality Soil moisture data

9 Pre Conference Seminar 9 ODM and HIS in an Observatory Setting e.g. http://www.bearriverinfo.org

10 Space, Time, Variables and Observations Variables (VariableID) Space (HydroID) Time Observations Data Model Data from sensors (regular time series) Data from sensors (regular time series) Data from field sampling (irregular time points) Data from field sampling (irregular time points) An observations data model archives values of variables at particular spatial locations and points in time

11 Space, Time, Variables and Visualization Variables (VariableID) Space (HydroID) Time Vizualization Map – Spatial distribution for a time point or interval Map – Spatial distribution for a time point or interval Graph – Temporal distribution for a space point or region Graph – Temporal distribution for a space point or region Animation – Time-sequenced maps Animation – Time-sequenced maps A visualization is a set of maps, graphs and animations that display the variation of a phenomenon in space and time

12 Space, Time, Variables and Simulation Variables (VariableID) Space (HydroID) Time Process Simulation Model A space-time point is unique A space-time point is unique At each point there is a set of variables At each point there is a set of variables A process simulaton model computes values of sets of variables at particular spatial locations at regular intervals of time

13 Space, Time, Variables and Geoprocessing Variables (VariableID) Space (HydroID) Time Geoprocessing Interpolation – Create a surface from point values Interpolation – Create a surface from point values Overlay – Values of a surface laid over discrete features Overlay – Values of a surface laid over discrete features Temporal – Geoprocessing with time steps Temporal – Geoprocessing with time steps Geoprocessing is the application of GIS tools to transform spatial data and create new data products

14 Space, Time, Variables and Statistics Variables (VariableID) Space (HydroID) Time Statistical distribution Represented as {probability, value} Represented as {probability, value} Summarized by statistics (mean, variance, standard deviation) Summarized by statistics (mean, variance, standard deviation) A statistical distribution is defined for a particular variable defined over a particular space and time domain

15 Space, Time, Variables and Statistical Analysis Variables (VariableID) Space (HydroID) Time Statistical analysis Multivariate analysis – correlation of a set of variables Multivariate analysis – correlation of a set of variables Geostatistics – correlation space Geostatistics – correlation space Time Series Analysis – correlation in time Time Series Analysis – correlation in time A statistical analysis summarizes the variation of a set of variables over a particular domain of space and time

16 Pre Conference Seminar 16 CUAHSI Observations Data Model Space-Time Datasets Sensor and laboratory databases From Robert Vertessy, CSIRO, Australia

17 Space and Time Introductory concepts Discrete space-time model – Arc Hydro Temporal Geoprocessing Continuous space-time model – netCDF Tracking Analyst

18 Space-Time Cube TSDateTime TSTypeID TSValue FeatureID Time Space Variable Data Value

19 Time Series Data

20 Time Series of a Particular Type

21 A time series for a particular feature

22 A particular time series for a particular feature

23 All values for a particular time

24 MonitoringPointHasTimeSeries Relationship

25 TSTypeHasTimeSeries

26 Arc Hydro TSType Table Type Index Variable Name Type Of Time Series Info Regular or Irregular Units of measure Time interval Recorded or Generated Arc Hydro has 6 Time Series DataTypes 1.Instantaneous 2.Cumulative 3.Incremental 4.Average 5.Maximum 6.Minimum

27 Instantaneous Cumulative Average Incremental Maximum Minimum Time Series Types

28 Space and Time Introductory concepts Discrete space-time model – Arc Hydro Temporal Geoprocessing Continuous space-time model – netCDF Tracking Analyst

29 Time Series {value, time} Attribute Series {featureID, value, time} Raster Series {raster, time} Feature Series {shape,value, time} Four Panel Diagram

30 Time series from gages in Kissimmee Flood Plain 21 gages measuring water surface elevation Data telemetered to central site using SCADA system Edited and compiled daily stage data stored in corporate time series database called dbHydro Each time series for each gage in dbHydro has a unique dbkey (e.g. ahrty, tyghj, ecdfw, ….)

31 Compile Gage Time Series into an Attribute Series table

32 Hydraulic head Hydraulic head is the water surface elevation in a standpipe anywhere in a water system, measured in feet above mean sea level h Land surface Mean sea level (datum)

33 Map of hydraulic head X Y Z Hydraulic head, h x y h(x, y) A map of hydraulic head specifies the continuous spatial distribution of hydraulic head at an instant of time

34 Time sequence of hydraulic head maps x y z Hydraulic head, h t1t1 t2t2 t3t3

35 Attribute Series to Raster Series

36 Time Series {value, time} Attribute Series {featureID, value, time} Raster Series {raster, time} Feature Series {shape,value, time} Four Panel Diagram

37 Inundation h L d Depth of inundation = d IF (h - L) > 0 then d = h – L IF (h – L) < 0 then d = 0

38 Inundation Time Series t h(x,y,t) L T (x,y) Time d(x,y,t) d(x,y,t) = h(x,y,t) – L T (x,y) DEMO: DHI Time Series

39 Ponded Water Depth Kissimmee River June 1, 2003

40 Time Series {value, time} Attribute Series {featureID, value, time} Raster Series {raster, time} Feature Series {shape,value, time} Four Panel Diagram

41 Depth Classification 0 5 4 3 2 1 DepthClass 11 9-10 7-8 5-6 3-4 1-2 0

42 Feature Series of Ponded Depth

43 Attribute Series for Habitat Zones

44 Space and Time Introductory concepts Discrete space-time model – Arc Hydro Temporal Geoprocessing Continuous space-time model – netCDF Tracking Analyst

45 Multidimensional Data Data cube (3D) or hypercube (4D,5D…) Temperature varying with time Temperature varying with time and altitude X Y T

46 Multidimensional Data Time = 1 Time = 2 Time = 3

47 Multidimensional Data Time = 1 Time = 2 Time = 3

48 Data Cube Time Slices Multidimensional Data Time = 1 Time = 2 Time = 3

49 Multidimensional Data Includes variation in (x,y,z,t)

50 What is NetCDF? NetCDF (network Common Data Form) A platform independent format for representing multi- dimensional array-orientated scientific data. Self Describing - a netCDF file includes information about the data it contains. Direct Access - a small subset of a large dataset may be accessed efficiently, without first reading through all the preceding data. Sharable - one writer and multiple readers may simultaneously access the same netCDF file. NetCDF is new to the GIS community but widely used by scientific communities for around many years

51 Why NetCDF? Most commonly used format in the oceanographic and atmospheric science for observational data and numerical modeling The National Center for Atmospheric Research (NCAR) University Corporation for Atmospheric Research (UCAR) NOAA's Climate Diagnostics Center (CDC) Los Alamos National Laboratory (LANL) The National Center for Supercomputing Applications US Air Force and Navy Atmospheric Research in Australia Australia Defense UK Hydrographic Office NATO...

52 What is a NetCDF file? NetCDF is a binary file A NetCDF file consists of: Global Attributes: Describe the contents of the file Dimensions:Define the structure of the data (e.g Time, Depth, Latitude, Longitude) Variables:Holds the data in arrays shaped by Dimensions Variable Attributes: Describes the contents of each variable CDL (network Common Data form Language) description takes the following form netCDF name { dimensions:... variables:... data:... }

53 Storing Data in a netCDF File

54 NetCDF Data Sources Community Climate Systems Model (CCSM) http://www.ccsm.ucar.edu, https://www.earthsystemgrid.org/ http://www.ccsm.ucar.eduhttps://www.earthsystemgrid.org/ The CCSM is fully-coupled, global climate model that provides state-of-the-art computer simulations of the Earth's past, present, and future climate states. 100 yrs of climate change forecast data (2000-2099) Control runs (1870-1999) and scenario runs Temperature, precipitation flux, surface snow thickness, snowfall flux, cloud water content, etc. Program for Climate Model Diagnosis and Intercomparison (PCMDI) http://www-pcmdi.llnl.gov/ http://www-pcmdi.llnl.gov/

55 NetCDF Data Sources Vegetation and Ecosystem Modeling and Analysis Project (VEMAP) http://dataportal.ucar.edu/vemap/main.html http://dataportal.ucar.edu/vemap/main.html VEMAP was a large, collaborative, multi-agency program to simulate and understand ecosystem dynamics for the continental United States. The VEMAP Data Portal is a central collection of files maintained and serviced by the NCAR Data Group Climate data interval: Annual, monthly, and daily. Data type: Historical and model results Data: Temperature, irradiance, precipitation, humidity, incident solar radiation, vapor pressure, elevation, land area, vegetation, water holding capacity of soil, etc.

56 NetCDF Data Sources British Atmospheric Data Center (BADC) http://badc.nerc.ac.uk/data/ http://badc.nerc.ac.uk/data/ The role of the BADC is to assist UK atmospheric researchers to locate, access and interpret atmospheric data. Many datasets are publicly available but datasets marked with key symbol have restricted access. Datasets are organized by projects or organizations. Climatology Interdisciplinary Data Collection (CIDC) has monthly means of over 70 Climate Parameters. Met Office - Historical Central England Temperature Data has the monthly series, which begins in 1659, is the longest available instrumental record of temperature in the world. The daily series begins in 1772.

57 NetCDF Data Sources National Oceanic & Atmospheric Administration (NOAA) National Digital Forecast Database (NDFD) http://www.nws.noaa.gov/ndfd/ http://www.nws.noaa.gov/ndfd/ Radar Integrated Display with Geospatial Element (RIDGE) http://www.srh.weather.gov/ridge/ http://www.srh.weather.gov/ridge/ Precipitation Analysis http://www.srh.noaa.gov/rfcshare/precip_download.php http://www.srh.noaa.gov/rfcshare/precip_download.php Climate Diagnostics Center http://www.cdc.noaa.gov/http://www.cdc.noaa.gov/ NCDC THREDDS Catalog http://www.ncdc.noaa.gov/thredds/catalog.html http://www.ncdc.noaa.gov/thredds/catalog.html NCDC NCEP Stage IV Radar Rainfall http://www.ncdc.noaa.gov/thredds/catalog/radar/StIV/catalog.html http://www.ncdc.noaa.gov/thredds/catalog/radar/StIV/catalog.html

58 NetCDF in ArcGIS NetCDF data is accessed as Raster Feature Table Direct read (no scratch file) Exports GIS data to netCDF

59 Gridded Data Raster Point Features

60 NetCDF Tools Toolbox: Multidimension Tools Make NetCDF Raster Layer Make NetCDF Feature Layer Make NetCDF Table View Raster to NetCDF Feature to NetCDF Table to NetCDF Select by Dimension

61 Space and Time Introductory concepts Discrete space-time model – Arc Hydro Temporal Geoprocessing Continuous space-time model – netCDF Tracking Analyst

62 Simple Events –1 feature class that describes What, When, Where Complex Event –1 feature class and 1 table that describe What, When, Where Arc Hydro

63 Simple Event IDTimeGeometryValue 1T1X1,Y10.1 2T2X2,Y20.3 1T3X3,Y30.7 2T4X4,Y40.4 3T5X5,Y50.5 2T6X6,Y60.2 4T7X7,Y70.1 1T8X8,Y80.8 1T9X9,Y90.3 Unique Identifier for objects being tracked through time Time of observation (in order)Geometry of observation Observation

64 Complex Event (stationary version) IDGeometry 1X1,Y1 2X2,Y2 3X3,Y3 4X4,Y4 IDTimeValue 1T10.1 2T20.3 1T30.7 2T40.4 3T50.5 2T60.2 4T70.1 1T80.8 1T90.3 The object maintains its geometry (i.e. it is stationary) Cases 1, 2, 3, 4, 5

65 Complex Event (dynamic version) IDGage Number 11001 21002 31003 41004 IDGeometryTimeValue 1X1,Y1T10.1 2X2,Y2T20.3 1X3,Y3T30.7 2X4,Y4T40.4 3X5,Y5T50.5 2X6,Y6T60.2 4X7,Y7T70.1 1X8,Y8T80.8 1X9,Y9T90.3 The object’s geometry can vary with time (i.e. it is dynamic) Cases 6 and 7

66 Tracking Analyst Display

67 Feature Class and Time Series Table

68 Temporal Layer Shape from feature class is joined to time series value from Time Series table

69 Summary Concepts Hydrologic variables are defined as a function of space and time Although space and time seem alike as independent dimensions they are not: –Space can be discrete or continuous and is multidimensional –Time is one-dimensional This leads to idea of spatially-referenced time series of data

70 Summary Concepts (II) In Arc Hydro, discrete spatial features are associated with time series values through a HydroID-FeatureID relationship Time series associated with individual features become Attribute Series associated with a Feature class Attribute series can be transformed to Raster Series and Feature Series by temporal geoprocessing (Four panel diagram)

71 Summary Concepts (III) ArcGIS explicitly supports time representations through –By allowing operations on netCDF files for spatially continuous fields –By allowing visualization of moving features using Tracking Analyst

Download ppt "Space and Time By David R. Maidment with contributions from Steve Kopp, Steve Grise, and Tim Whiteaker."

Similar presentations

Space-Time The ESRI Time Project – Comments by Steve Kopp

Space-Time The ESRI Time Project – Comments by Steve Kopp
HydroServer A Platform for Publishing Space- Time Hydrologic Datasets Support EAR 0622374 CUAHSI HIS Sharing hydrologic data Jeffery.

HydroServer A Platform for Publishing Space- Time Hydrologic Datasets Support EAR CUAHSI HIS Sharing hydrologic data Jeffery.
A Community Data Model for Hydrologic Observations Observations Data Model Schema ODM Data Source and Network SitesVariables ValuesMetadata Depth of snow.

A Community Data Model for Hydrologic Observations Observations Data Model Schema ODM Data Source and Network SitesVariables ValuesMetadata Depth of snow.
Reading NetCDF Files in Matlab and analyzing the data.

Reading NetCDF Files in Matlab and analyzing the data.
Linking HIS and GIS How to support the objective, transparent and robust calculation and publication of SWSI? Jeffery S. Horsburgh CUAHSI HIS Sharing hydrologic.

Linking HIS and GIS How to support the objective, transparent and robust calculation and publication of SWSI? Jeffery S. Horsburgh CUAHSI HIS Sharing hydrologic.
Components of an Integrated Environmental Observatory Information System Cyberinfrastructure to Support Publication of Water Resources Data Jeffery S.

Components of an Integrated Environmental Observatory Information System Cyberinfrastructure to Support Publication of Water Resources Data Jeffery S.
This work was funded by the U.S. National Science Foundation under grant EAR 0622374. Any opinions, findings and conclusions or recommendations expressed.

This work was funded by the U.S. National Science Foundation under grant EAR Any opinions, findings and conclusions or recommendations expressed.
Crossing the Digital Divide

Crossing the Digital Divide
NCAR GIS Program : Bridging Gaps

NCAR GIS Program : Bridging Gaps
2014 ESIP Summer Meeting July 8–11, 2014 | Frisco, Colorado Advancing Scientific Data Support in ArcGIS Nawajish Noman.

2014 ESIP Summer Meeting July 8–11, 2014 | Frisco, Colorado Advancing Scientific Data Support in ArcGIS Nawajish Noman.
Development of a Community Hydrologic Information System Jeffery S. Horsburgh Utah State University David G. Tarboton Utah State University.

Development of a Community Hydrologic Information System Jeffery S. Horsburgh Utah State University David G. Tarboton Utah State University.
GIS Modeling Venkatesh Merwade, University of Texas at Austin Interdisciplinary aquatic modeling workshop, July 21, 2005.

GIS Modeling Venkatesh Merwade, University of Texas at Austin Interdisciplinary aquatic modeling workshop, July 21, 2005.
Geographic Information Systems : Data Types, Sources and the ArcView Program.

Geographic Information Systems : Data Types, Sources and the ArcView Program.
Deployment and Evaluation of an Observations Data Model Jeffery S Horsburgh David G Tarboton Ilya Zaslavsky David R. Maidment David Valentine

Deployment and Evaluation of an Observations Data Model Jeffery S Horsburgh David G Tarboton Ilya Zaslavsky David R. Maidment David Valentine
CUAHSI Hydrologic Information Systems and Web Services By David R. Maidment With support from many collaborators: Ilya Zaslavsky, David Valentine, Reza.

CUAHSI Hydrologic Information Systems and Web Services By David R. Maidment With support from many collaborators: Ilya Zaslavsky, David Valentine, Reza.
1 CEE 795 Water Resources Modeling and GIS Session #1 (some material from Dr. David Maidment, University of Texas) January 18, 2006 Learning Objectives:

1 CEE 795 Water Resources Modeling and GIS Session #1 (some material from Dr. David Maidment, University of Texas) January 18, 2006 Learning Objectives:
Marine GIS Applications using ArcGIS Global Classroom training course Marine GIS Applications using ArcGIS Global Classroom training course By T.Hemasundar.

Marine GIS Applications using ArcGIS Global Classroom training course Marine GIS Applications using ArcGIS Global Classroom training course By T.Hemasundar.
Geographical Information System GIS By: Yahia Dahash.

Geographical Information System GIS By: Yahia Dahash.
1 Space-Time Datasets in Arc Hydro II by Steve Grise (ESRI), David Maidment, Ernest To, Clark Siler (CRWR)

1 Space-Time Datasets in Arc Hydro II by Steve Grise (ESRI), David Maidment, Ernest To, Clark Siler (CRWR)
Rebecca Boger Earth and Environmental Sciences Brooklyn College.

Rebecca Boger Earth and Environmental Sciences Brooklyn College.

Similar presentations

Ads by Google