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Spatial Databases - Topology

Spatial Databases - Topology. Spring, 2008 Ki-Joune Li. Spaghetti Model. The Most Simple Representation by Vector Model Point Table Line Table. P1 (30,70). L1. P4 (20,60). L5. L4. L3. P3 (20,50). P2 (40,50). L2. Spaghetti Model. Example: DXF

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Spatial Databases - Topology

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  1. Spatial Databases- Topology Spring, 2008 Ki-Joune Li

  2. Spaghetti Model • The Most Simple Representation by Vector Model • Point Table Line Table P1 (30,70) L1 P4 (20,60) L5 L4 L3 P3 (20,50) P2 (40,50) L2

  3. Spaghetti Model • Example: DXF • A CAD Data Format by Spaghetti Model • Representation of geometric properties not spatial or geographic ones • Program Assignment #1 • Decode given data file in DXF • Define schema of Oracle spatial DB • Insert objects into DB • Programming Environment: JDBC + Oracle SDO • Due data: by April 23th

  4. Problem of Spaghetti Model: Example • When P1 moves to (40,80), Ambiguity P1 (40,80) P1 (30,70) L4 L1 P4 (20,60) L5 ? L3 40, 80 P3 (20,50) P2 (40,50) L2 40, 80

  5. P5 (30,70) P1 (40,80) L4 P4 (20,60) L1 L5 L3 P3 (20,50) P2 (40,50) L2 Problem of Spaghetti Model: Example • To make it clear • Relationship betweenPoint and Line 40, 80 No change of line table

  6. Problem of Spaghetti Model: Example • No clear information about the connection without additional data • L1:L3 ? or L1:L2 P2 L1 : 3,300V L2 : 220V P1 P3 P5 L4 : 220V L3 : 3,300V P4  Need Topological Information

  7. l1 l2 l3 l1 l2 l3 l4 l5 l5 l4 Topology • Topology • Invariant properties during elastic transformation (rubber sheeting) • Relationship between Spatial Objects • Topological Equivalence (Homeomorphism)

  8. Some Definitions of Topology • Mathematical Definition based on Point Set Theory • An area: Defined as an infinite set of points • Neighbor of p: set of all points within a unit disc of p • Boundary: Set of all points that have neighbors within A and neighbors within AC at the same time • Interior and Exterior Neighbor of p p Boundary of A neighbors in A, neighborsin AC AC A

  9. B A B A B B A A, B Examples of Topologies B A Disjoint(A,B) Meet(A,B) Overlap(A,B) A Some complicated cases ? Cover(A,B) or CoveredBy(B,A) Contain(A,B) or Inside(B,A) Equal(A,B) A 8 Relationships B Topology between Lines ?

  10. A B Representation of Topology by 9-IM • 9-Intersection Model • Example • Extensions of 9-IM R(A,B)= R(A,B)=

  11. Built-In Topology: Topology Levels • By VPF (Vector Product Format): A Military Standard • VPF  NATO Standard  CEN/TC287  ISO/TC211 • Level 0: No topology (Spaghetti Model) • Level 1 • Level 2 • Level 3: Face topology Less Topology More Topology

  12. p3 p2 p1 l2 l3 l1 Topology Level 1: Connectivity • Description of connectivity between lines • l1 is connected with l2. • Example • Pipeline network • No Planarity restriction

  13. Topology Level 2: Connectivity + Planarity • Topology Level 1 + Planarity Condition • Planarity • Only ONE object at a position • No overlapping is allowed • Example: ? p3 p3 p2 l21 l12 p2 l11 p5 l1 p1 p1 l2 l22 p4 p4 Level 2 Level 1 (not Level 2)

  14. B B A A C C B A C Topology Level 3: Face Topology • Topology Level 2 + Face Topology • Adjacency between faces • Left / Right Face of a line • Example Original Boundary With Face Topology Without Face Topology

  15. How to maintain the Planarity of Faces • Example 1 • Example 2 Original Faces F2 New Face to respect the planarity F1 F3 F2 F1 New Inserted Line

  16. Point (Node) • (X,Y) • Line (Edge) • Point String Face Simple Data Modeling of Topology Starting Pt 1..1 Connected Line 1..* Ending Pt 1..1 Connected Line 1..* Topology Level 1, 2 Left Face 1..1 Right Face 1..1 Boundary 1..* Boundary 1..* Topology Level 3 • Face with Holes ? Outer Ring Inner Ring

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