GIS Lecture 5 Importing Spatial and Attribute Data

1. GIS Lecture 5 Importing Spatial and Attribute Data

2. Outline • GIS Data Sets • Map Projections • Coordinate Systems • GIS Data Sources

3. GIS Data Sets

4. GIS Data Sets • ArcInfo Coverages • ArcView Shapefiles • CAD Files • Aerial Photos • Event Files

5. ArcInfo

6. AAT Arc Attribute Table ARC Arc coordinates and topology BND Coverage minimum and maximum coordinates CNT Polygon centroid table PAL Polygon topology PAT Polygon/Point Attribute Table TIC Tic coordinates and Ids DBF Database Table ArcInfo Coverages

7. ArcINFO Coverages in ArcMap

8. Polygon Coverages • Area and perimeter automatically calculated

9. B E 1 2 Pine St. 733 A 734 F C Oak St. 3 4 D G Polygon Coverages Polygons share borders

10. Line Coverages • Length automatically calculated

11. Point Coverages

12. ArcInfo Coverages • Advantages • Many feature types • Shared borders • Automatic Area/Perimeter/Length fields • Disadvantages • Cannot edit in ArcMap

13. ArcInfo Export files • .e00 export exchange file • ArcCatalog translates into ArcGIS • Creates coverages

14. ArcView Shape Files • Advantages • heads-up digitizing and editing • less storage/rapid display • can export to CAD • Disadvantages • one feature type • no area or perimeter with new shapefiles

15. ArcView Shape Files • From 3 to 5 Files • .shp - stores feature geometry • .shx - stores index of features • .dbf - stores attribute data • .sbn and .sbx - store additional indices

16. ArcView Shapefiles

17. CAD Files • Why CAD Drawings? • Better Precision for Digitizing • .DWG / .DXF

18. Adding CAD Files

19. CAD Files in ArcMap

20. Aerial Images • Combining Grid and Vector Maps

21. Event Files X,Y Coordinates

22. Event Files

23. Event Files

24. Map Projections

25. Map Projections and Distortion • Map projections produce distortion in one or more spatial properties: • Shape, area, distance, and direction • Specific projections eliminate or minimize distortion

26. Distortion Examples

27. Mercator Projection: Distortion

28. Robinson Projection: Distortion

29. Projection Important • Measurements used to make important decisions • Comparing shapes, areas, distances, or directions of map features • Feature and image themes are aligned New York New York Los Angeles Los Angeles Projection: MercatorDistance: 3,124.67 miles Projection: Albers Equal AreaDistance: 2,455.03 miles Actual distance: 2,451 miles

30. Projection not Important • Business applications • Not of critical importance. • Concerned with the relative location of different features • On large scale maps - street maps • Distortion may be negligible • Map covers only a small part of the Earth's surface.

31. Coordinate Systems

32. Coordinate Systems • Spherical/Polar • Geographic Coordinate System • Rectangular • State Plane • UTM

33. Geographic Coordinate System • Latitude and Longitude • Census Bureau TIGER files • Geographic • Coordinate • System Grid

34. Longitude: Meridians

35. Latitude: Parallels

36. Origin • Longitude (prime meridian) 0 • Latitude (equator) 0

37. Coordinates Pittsburgh 40 -80

38. Pittsburgh’s Point • Degrees, Minutes, and Seconds (DMS): • 40°26’2”N latitude • -80°0’58”W longitude • Decimal Degrees (DD) • 1 degree = 60 minutes, • 1 minute = 60 seconds • 40°26’2” = • 40 + 26/60 + 2/3600 = 40 + .43333 + .00055 = • 40.434°

39. Translated to Distance • World circumference through • the poles is 24,859.82 miles, • so for latitude: • 1° = 24,859.82/360 = 69.1 miles • 1’ = 24,859.82/(360*60) = 1.15 miles • 1” = 24,859.82*5,280/(360*3600) = 101 feet • Length of the equator is 24,901.55 miles

40. Rectangular Coordinate Systems State Plane Coordinates • Local Governments UTM • US Military

41. State Plane Coordinate System • Established by the U.S. Coast and Geodetic Survey (now the National Ocean Survey) • At least one for each state • Rectangular (x,y) coordinates • 125 zones, following state and county boundaries each with its own projection: • Lambert conformal projection for zones with east-west extent • Transverse Mercatorprojection for zones with north-south extent • Cannot have zones joined to make larger regions

42. 400 (400, 300) North (Feet) 200 (100, 200) 0 0 200 400 East (Feet) Rectangular Coordinates • Has all positive Cartesian coordinates in feet, called false eastings and false northings

43. State Plane Coordinate Zones

44. State Plane Coordinate Zones

45. City of Pittsburgh as Geographic Coordinates

46. City of Pittsburgh as State Plane Coordinates

47. State Plane Coordinate Names • North American Datum of 1927 (NAD27) • American Datum of 1983 (NAD83) • "High Accuracy Reference Network" (HARN) • "High Precision GPS Network" (HPGN)

48. Universal Transverse Mercator System (UTM) • Developed by the NATO in 1947 • Military grid system • Based on transverse Mercator projection • Applied to maps of the Earth's surface extending from the Equator to 84 Degrees north and 80 degrees south latitudes

49. UTM Zones World is divided into 60 north-south zones, each covering a strip 6° wide in longitude

50. UTM Zones in the Contiguous USA