Presentation is loading. Please wait.

Presentation is loading. Please wait.

Www.spatialanalysisonline.com Chapter 4 Part C: Queries, Computations & Map Algebra.

Published byThomas O'Donnell Modified over 11 years ago

Similar presentations

Presentation on theme: "Www.spatialanalysisonline.com Chapter 4 Part C: Queries, Computations & Map Algebra."— Presentation transcript:

1 www.spatialanalysisonline.com Chapter 4 Part C: Queries, Computations & Map Algebra

2 3 rd editionwww.spatialanalysisonline.com2 Queries, Computations & Map Algebra Queries Non-spatial queries Spatial queries SELECT queries/select by location Other SQL-like queries, e.g. Make table Spatial JOIN and RELATE operations OGC Spatial Relations (See next slide, from 4A)

3 3 rd editionwww.spatialanalysisonline.com3 MethodDescription Note: a and b are two geometries (one or more geometric objects or features points, line objects, polygons, surfaces including their boundaries); I(x) is the interior of x; dim(x) is the dimension of x, or maximum dimension if x is the result of a relational operation Spatial relations Equalsspatially equal to: a=b Disjoint spatial disjoint: equivalent to a b= Intersects spatially intersects: [a b] is equivalent to [not a disjoint(b)] Touches spatially touches: equivalent to [a b and I(a) I(b)= ]; does not apply if a and b are points Crosses spatially crosses: equivalent to [dim(I(a) I(b))<max{dim(I(a)),dim(I(b))} and a b a and a b b] Within spatially within: within(b) is equivalent to [a b=a and I(a) I(b) ] Containsspatially contains: [a contains(b)] is equivalent to [b within(a)] Overlaps spatially overlaps: equivalent to [dim(I(a) I(b))=dim(I(a))=dim(I(b)) and a b a and a b b] Relatespatially relates, tested by checking for intersections between the interior, boundary and exterior of the two components OGC OpenGIS Simple Features Specification: Spatial Relations Queries, Computations & Map Algebra

4 3 rd editionwww.spatialanalysisonline.com4 Queries, Computations & Map Algebra Simple computations Field level – attribute processing SQL/Query operations – e.g. Make Table Raster layer operations Basic Map Algebra Single layer operations: local, focal/neighbourhood, zonal, global Multi-layer operations Raster-vector combined operations Algebraic expressions – e.g. C=(A-B)/(A+B)

5 3 rd editionwww.spatialanalysisonline.com5 Queries, Computations & Map Algebra Map algebra – local operations, multi-grid

6 3 rd editionwww.spatialanalysisonline.com6 Queries, Computations & Map Algebra Map algebra operations – broader view Resolution, orientation and resampling Classification Algebraic and Statistical operations Proximity/landscape metric operations Surface and hydrological analysis operations Transformation and interpolation Filtering

7 3 rd editionwww.spatialanalysisonline.com7 Queries, Computations & Map Algebra Grid filtering – Linear (weighted average) Low pass filters, e.g. High pass filters, e.g. Kernels - example Weighted average as integer

8 3 rd editionwww.spatialanalysisonline.com8 Queries, Computations & Map Algebra Grid filtering – Linear – common image processing functions Sharpening Blurring Edge detection Embossing Gradient operations

9 3 rd editionwww.spatialanalysisonline.com9 Queries, Computations & Map Algebra Grid filtering – points to note Attribute data range Multi-band image processing Kernel size and shape Single or multi-pass Edge effects User-defined kernels Spatial vs frequency domain filtering

10 3 rd editionwww.spatialanalysisonline.com10 Queries, Computations & Map Algebra Grid filtering – Non-linear Non-linear local adjustment Local operation, not based on kernel (weighted average) Minimum, Maximum, Variance, IQR Median deviation and thresholding Noise reduction

11 3 rd editionwww.spatialanalysisonline.com11 Queries, Computations & Map Algebra Grid filtering – Erosion and dilation Erosion – pixel removal/alteration Dilation – pixel addition/alteration Kernels and structural elements Source DEM/image Dilation of source Erosion of source

12 3 rd editionwww.spatialanalysisonline.com12 Queries, Computations & Map Algebra Ratios, indices and normalisation Spatially extensive variables Spatially intensive variables Normalisation of count data e.g. cars/household, ethnic group counts/1000 population Common types: Averages Proportions/percentages Densities

13 3 rd editionwww.spatialanalysisonline.com13 Queries, Computations & Map Algebra Standardisation Direct standardisation Regional/national comparisons Indirect standardisation Expected values Excess rates Statistical standardisation Z-scores Range-based (basic or trimmed)

14 3 rd editionwww.spatialanalysisonline.com14 Queries, Computations & Map Algebra Ratio computations – some issues Division by 0 and missing data handling Normalisation of normalised data Variance instability Divisor selection Appropriateness Availability/accuracy/timeliness Rate selection Raw rates, expected rates, rate smoothing

15 3 rd editionwww.spatialanalysisonline.com15 Queries, Computations & Map Algebra Point density Density: counts/area (n/A) Occupancy: area/counts (A/n) Zone boundaries/area definition Grid counts (cell shape, size, orientation issues) … need for a boundary free approach … develop ideas from univariate statistics

16 3 rd editionwww.spatialanalysisonline.com16 Queries, Computations & Map Algebra Point density – kernel methods Uniform 50:50 Box kernel Box sum histogram

17 3 rd editionwww.spatialanalysisonline.com17 Queries, Computations & Map Algebra Kernel density – Normal kernel function

18 3 rd editionwww.spatialanalysisonline.com18 Queries, Computations & Map Algebra Kernel density – decisions Functions (finite or infinite) Bandwidth – key criterion (fixed/adaptive) Grid resolution Relative or absolute densities, or probabilities Comparison issues with other density datasets temporal mapped values

19 3 rd editionwww.spatialanalysisonline.com19 Queries, Computations & Map Algebra Kernel density estimation (KDE) – 2D approach Symmetric functions Finite (e.g. box) or infinite (e.g. Normal) Rotated 1D function 2D function Procedure: Select function and parameters Specify grid resolution (or extent and number of cols/rows) Apply 2D function to each data point and record value at every grid intersection Sum grid intersection values and normalise Map resulting grid

20 3 rd editionwww.spatialanalysisonline.com20 Queries, Computations & Map Algebra 2D kernels – single point Normal kernel (unbounded) Quartic kernel (bounded)

21 3 rd editionwww.spatialanalysisonline.com21 Queries, Computations & Map Algebra 2D mapped kernel density – Lung cancer cases, Quartic kernel and Normal kernel

22 3 rd editionwww.spatialanalysisonline.com22 Queries, Computations & Map Algebra 3D mapped kernel density – lung cancer cases

23 3 rd editionwww.spatialanalysisonline.com23 Queries, Computations & Map Algebra Kernel density – alternative functions Normal (or Gaussian), Quartic (spherical) (Negative) Exponential, Triangular (conic) Uniform (flat), Epanechnikov (paraboloid/quadratic) Applications Density/probability surface creation/comparisons Case/control analysis Spatio-temporal analysis Hot spot analysis Network analysis (see Okabe et al)

24 3 rd editionwww.spatialanalysisonline.com24 Queries, Computations & Map Algebra Cartograms Density adjustment – areas represent population

25 3 rd editionwww.spatialanalysisonline.com25 Queries, Computations & Map Algebra Cartograms Density adjustment – alternative approaches

26 3 rd editionwww.spatialanalysisonline.com26 Queries, Computations & Map Algebra Line and intersection density Kernel methods applied to linear forms Route systems (and intersections) Line frequency (number per unit area) Length density (length per unit area) Intersection density (intersections per unit of length, per unit area)

Download ppt "Www.spatialanalysisonline.com Chapter 4 Part C: Queries, Computations & Map Algebra."

Similar presentations

Methodological context

Methodological context
Www.spatialanalysisonline.com Chapter 7 Part B: Locational analysis.

Chapter 7 Part B: Locational analysis.
Www.spatialanalysisonline.com Chapter 2 Conceptual frameworks for spatial analysis.

Chapter 2 Conceptual frameworks for spatial analysis.
Www.spatialanalysisonline.com Chapter 7 Part A: Network analysis.

Chapter 7 Part A: Network analysis.
Www.spatialanalysisonline.com Chapter 5 Part A: Spatial data exploration.

Chapter 5 Part A: Spatial data exploration.
Www.spatialanalysisonline.com Chapter 4 Part A: Geometric & related operations.

Chapter 4 Part A: Geometric & related operations.
Www.spatialanalysisonline.com Chapter 4 Part B: Distance and directional operations.

Chapter 4 Part B: Distance and directional operations.
Chapter 4 Joining Multiple Tables

Chapter 4 Joining Multiple Tables
1 Computational Geometry Chapter 12. 2 Range queries How do you efficiently find points that are inside of a rectangle? –Orthogonal range query ([x 1,

1 Computational Geometry Chapter Range queries How do you efficiently find points that are inside of a rectangle? –Orthogonal range query ([x 1,
Introdução to Geoinformatics: Geometries. Vector Model Lines: fundamental spatial data model Lines start and end at nodes line #1 goes from node #2 to.

Introdução to Geoinformatics: Geometries. Vector Model Lines: fundamental spatial data model Lines start and end at nodes line #1 goes from node #2 to.
Department of Geoinformation Science Technische Universität Berlin Geo-Databases: lecture 8 Management of Spatial Data Prof. Dr. Thomas H. Kolbe Institute.

Department of Geoinformation Science Technische Universität Berlin Geo-Databases: lecture 8 Management of Spatial Data Prof. Dr. Thomas H. Kolbe Institute.
Copyright © 2004 Pearson Education, Inc.. Chapter 15 Algorithms for Query Processing and Optimization.

Copyright © 2004 Pearson Education, Inc.. Chapter 15 Algorithms for Query Processing and Optimization.
Spatial Join Queries. Spatial Queries Given a collection of geometric objects (points, lines, polygons,...) organize them on disk, to answer point queries.

Spatial Join Queries. Spatial Queries Given a collection of geometric objects (points, lines, polygons,...) organize them on disk, to answer point queries.
Database System Concepts, 5th Ed. ©Silberschatz, Korth and Sudarshan See www.db-book.com for conditions on re-usewww.db-book.com ICOM 5016 – Database Systems.

Database System Concepts, 5th Ed. ©Silberschatz, Korth and Sudarshan See for conditions on re-usewww.db-book.com ICOM 5016 – Database Systems.
Murach's MySQL, C3© 2012, Mike Murach & Associates, Inc.Slide 1.

Murach's MySQL, C3© 2012, Mike Murach & Associates, Inc.Slide 1.
Object Relational Model Spatial Queries. Query Model Spatial Layer Data Table where coordinates are stored Primary Filter Spatial Index Index retrieves.

Object Relational Model Spatial Queries. Query Model Spatial Layer Data Table where coordinates are stored Primary Filter Spatial Index Index retrieves.
Chapter 12 and Chapter 3 Geometry Terms.

Chapter 12 and Chapter 3 Geometry Terms.
Geometry Chapter 10 -1 Polygons. Convex Polygon – a polygon with a line containing a side with a point in the interior of the polygon.

Geometry Chapter Polygons. Convex Polygon – a polygon with a line containing a side with a point in the interior of the polygon.
Spatial Data Mining. 2 Introduction Spatial data mining is the process of discovering interesting, useful, non-trivial patterns from large spatial datasets.

Spatial Data Mining. 2 Introduction Spatial data mining is the process of discovering interesting, useful, non-trivial patterns from large spatial datasets.
Oracle8i Spatial Concepts. Concepts Geometric data types Oracle8i Spatial data model Spatial Layers Spatial query model Spatial indexing «Window» queries.

Oracle8i Spatial Concepts. Concepts Geometric data types Oracle8i Spatial data model Spatial Layers Spatial query model Spatial indexing «Window» queries.

Similar presentations

Ads by Google