Introduction to Spatial Database System

1. Introduction to Spatial Database System Presented by Xiaozhi Yu

2. Outline • What is spatial database system? • What need to be presented? • Organizing the underlying space. • Spatial data types. • Spatial relationships. • Integrating geometry into DBMS data model. • Spatial indexing. • Spatial join. • System architecture.

3. What is spatial database system? • Spatial database is a database system • It offers spatial data types in its data model and query language • It supports spatial data types in its implementation , providing at least spatial indexing and efficient algorithms for spatial join

4. Modeling: What need to be presented? • Single object Points, Lines and Regions

5. Modeling: What need to be presented? • Spatially related collections of objects Partitions-----a set of regions Networks-----points and lines

6. Modeling: Organizing the Underlying Space-Discrete Geometric Bases • Simplex and simplicial complex: • Simplex :For each dimension d, a d-simplex is a minimal object in that dimension. Any d-simplex is composed of (d+1) simplicies of dimension d-1. • Simplicial complex: A finite set of simplices such that the intersection of any two simplices in the set is a face (simplex of d-1 dimension)

7. Modeling: Organizing the Underlying Space-Discrete Geometric Bases • Realm: Conceptually represents the complete underlying geometry of one particular application space. A realm is a finite set of points and lines over discrete grid.

8. Modeling: Spatial data types Example : Rose algebra • Three data types • Points ---a set of R-points • lines ----a set of disjointed R-blocks • regions ---- a set of edge disjoint R-faces Values are realm based, composed from elements from realm. • Kind : type sets • EXT = {lines, regions} • GEO= {points, line, regions} • =A kind for all partitions

9. Four classes of operations in ROSE

10. Four classes of operations in ROSE

11. Spatial Relationships • Several classes of relationships: • Topological relationships • Adjacent, Disjoint, Inside, etc. • Direction relationships • Above, below, north-of, southwest-of, etc. • Metric relationships • Distance < 100 , etc.

12. Relationships of simple regions

13. Integrating geometry into DBMS data model • DBMS data model is extended by SDTs at the level of atomic data types. • The central idea for integrating geometric modeling into DBMS data model is to present “spatial objects ” by objects with at least one attribute of spatial data type.

14. Querying---fundamental operators • Spatial selection • Exp : cities select[center inside Bavaris] • Spatial join • Exp : cities rivers join[dist (center, route) < 50] • Spatial function application • Exp : • Other set operators • Overlay , fusion, Voronoi

15. Spatial indexing • Two ways: • Dedicated external spatial data structures are added to the system, offering for spatial attributes. Like B-tree does for standard attributes. • Spatial objects are mapped into a one-dimensional space so that they can be stored within a standard one-dimensional index such as a B-tree.

16. Spatial indexing : approximations • Spatial keys are much simpler geometric objects than the SDT value itself.

17. Spatial indexing : grid approximation • An example : grid approximation. Space is divided into cells by grid and SDT value is represented by a set of cells that it intersect.

18. Spatial indexing : grid approximation • Any shape(a set of cells) can be represented by a set of bit strings called z-elements. • For a spatial object, use its corresponding set of z-elements as a set of spatial keys.

19. Spatial index structures for points • Grid file : partition data space by irregular grid into cells. • Scales : split line position, one scale per dimension. • Directory: entries are pointers to buckets.

20. Spatial index structures for rectangles • There are three approaches: • Approach 1 Transformation : a rectangle represented by four points can be regarded as one point in four dimensions.

21. Spatial index structures for rectangles • There are three approaches: • Approach 2 Overlapping regions:

22. Spatial index structures for rectangles • There are three approaches: • Approach 3 Clipping:

23. Supporting spatial join • Central ideas for computing spatial join are the filter and refine strategy and use of spatial index structures. • Strategies classification criteria: • Grid approximation/bounding box • None/one/both operands are represented in a spatial index structure.

24. Supporting spatial join : Grid approximation/bounding box • Grid approximation: • A parallel scan of the two sets of z-elements corresponding to the two sets of spatial objects is performed, similar to a merge join for a “<=” predicate. • When using the bounding box : • For each object , the bounding box of its SDT attribute is used as a search argument. The problem is to determine for two sets of rectangles R,S, all pairs (r, s) , r intersects s.

25. Supporting spatial join • None indexes • Algorithms such as bb_join, an external divided-and conquer algorithm, similar to external merge join. • Use seeded tree to build an index for one operand on the fly. • One index • Index join or repeated search join can be used. Inner operand is represented in an index. Scan the outer operand set and for each object, the bounding box of its SDT attribute is used as a search argument on the index.

26. Supporting spatial join • Both operand have indexes • Perform synchronized traversal of the two index structure so that pairs of cells of their respective partitions covering the same part of space are encountered together.

27. System architecture • Layered architecture: spatial functionality is built on top of a given DBMS.

28. System architecture • Dual architecture:

29. Integrated spatial DBMS architecture- using an extensible DBMS

30. Thank You