1. The Global Positioning System. GPS antenna GPS receiver and batteries! Windows CE handheld computer Paper Map with targets Matt Evans of Abe591a and Aaron Pierce of the Biology Department; mapping the Purdue University Ross Reserve. Sample Location Flag/Pin ASM 215 April 2009

2. How does GPS work In a “nutshell”, time equals distance. If the time signal is delayed by bounces, then the receiver will think the satellite is in the wrong place, and the location is calculated wrong. Our discussion is VERY simplified

3. GPS Basics GPS = Global Positioning System (uses satellites) GPS has significantly changed surveying, navigation, shipping, airline, transportation GPS has become the most common method for field data collection in GIS http://classic.mountainzone.com/everest/98/photos/4-27/gps-receiver.html

4. Three components of the Global Positioning System

5. US Satellite Component 4 to 8 satellites are typically visible from any unobstructed viewing location on earth

6. Control component Master control station in Colorado Springs Collects: Satellite health and status information Satellite tracking information from each tracking station Timing data from the U.S. Naval Observatory Earth data from the U.S. Defense Mapping Agency Signals course corrections, changes in operation, etc.

7. User component Individuals with GPS receivers

8. GPS systems around the world NAVSTAR – U.S. (Department of Defense) GLONASS – Russia Galileo – Consortium of European governments and industries http://europa.eu.int/comm/dgs/energy_transport/galileo/video/index_en.htm

9. GPS Range Distance Range = speed of light * travel time

10. Combining range measurements

11. GPS Signals – Coded and Carrier Two carrier signals Modulated to produce two coded signals –Also called pseudo-random code, because it appears similar to random noise Positions based on carrier signal measurement are more accurate than those based on the code signal measurements

12. Range measurement from coded signal

13. Uncertainty in position Atmospheric and ionospheric delays –(speed of light is only constant in a vaccuum) –No analytical method to remove errors System operation and delays (smaller error) Receiver errors –Clocks may use algorithms that do not precisely calculate position –Multipath signals from reflections off buildings

14. Satellite geometry and Positional Dilution of Precision

15. Time sat 1 Time sat 2 Time sat 3 Your location

16. Accuracy without differential correction Code phase receivers typically provide –3 to 30 meter accuracy for single reading –2 to 15 meters for multiple fixes Carrier phase: a few centimeters but need differential

17. Time sat 1 Time sat 2 Trees Time sat 3 Pavement Multipath error.

18. These represent locations collected by a fixed GPS antenna on our roof. In 24 hours the points scatter around a 4.0 meter circle. In Tippecanoe county a second of a degree is about 30 meters.

19. Reducing positional error 1. Collect many position fixes while remaining stationary –Also provides an estimate of variation (standard deviation) –Cannot be used in moving vehicle, for example 2. Use differential correction

20. Differential Correction Two receivers are used to greatly improve the accuracy of GPS positional measurements Base station at known location

21. Differential correction Post- processed Real-time

22. Sources of real-time differential correction Radio transmitter from a private base station U.S. Coast Guard has established GPS radio beacons –Concentrated near the oceans, Great Lakes, and Mississippi River –Need to purchase beacon receiver package that supports real time correction using the Coast Guard beacon signal

23. Sources of real-time differential correction - Wide Area Augmentation System (WAAS ) Administered by the U.S. Federal Aviation Administration for dependable aircraft navigation Based on a network of ground reference stations scattered about North America. Correction transmitted to a satellite. Individual errors are less than 7 m 95% of the time; errors for multiple readings (30 minutes) are 1 to 3 meters

24. Source of real-time differential correction – Commercial satellites Omnistar and Landstar have a set of base stations distributed across a region Available on a subscription or license basis

25. Carrier phase GPS (RTK) Real Time Kinematic GPS, or RTK can accuracy needed for surveying Uses the carrier phase of the GPS signal Accuracies of around ½ inch horizontal and 1 inch in the vertical direction.

26. Topographic assessment at Davis Purdue Ag Center

27. Applications of GPS

28. Lab Tomorrow We will use low precision Garmin 12XL GPS units from Forestry and Natural Resources. You may use your own if you are familiar with it.

29. Push the “Page” button until you get the screen which displays location. They will be set to display degrees, minutes and decimal seconds.

30. Lab Exercise Collect readings at six locations. Each location you collect 5 readings over 5 to 10 minutes. Do some calculations GIS lab will use this data

33. What if it rains? Umbrella Raincoat Solid shoes Calculator fieldbook Work in teams of 2. Outside maybe 40 minutes. Wait till it clears or work through the rain.

34. Latitude - Longitude GPS measures where you are on the planet, not where you are on a map, so it uses DEGREES: 40 0 25 ‘ 19.1” 40 degrees 25 minutes 19.1 seconds –60 seconds in a minute, 60 minutes in a degree LatitudeLongitude Meets at the polesGoes on around the world

35. Geographic coordinate system Latitude varies from north to south Longitude varies from east to west Measurements in degrees minutes and seconds, or “decimal degrees”

36. Not sphere but spheroid Newton and others in the 17 th and 18 th century proposed that the Earth is flattened due to rotational forces. Complex, repeated, highly accurate measurements established that the curvature of the Earth was greater at the equator than the poles Image from ESRI online course

37. Projected coordinate systems Map projections: The transformation of coordinate locations from the curved Earth surface onto flat maps Point to remember: Distortions are unavoidable when making flat maps Image from ESRI online course

38. Representing locations with coordinates: Two types of coordinate systems 1. Geographic coordinate system –Locates objects on the curved surface of the earth 2. Projected coordinate system –Locates objects on a flat surface such as a paper map or a computer screen Each has advantages and disadvantages for various applications.

39. Some map projections

40. Understanding distortion: Four spatial properties Shape –Conformal maps: shapes are the same as they are on earth Area –Equal area map: Sizes are the same relative to earth, and if you move a shape around on the map its size will be the same Distance –Equidistant map preserves true scale for all straight lines passing through a specified location Direction –Azimuthal map: Directions from one location to all other points on themap are shown correctly

41. Universal Transverse Mercator Coordinate System Divides the Earth into 6°longitude zones. Extends from 80° S to 80° N

42. Universal Transverse Mercator Coordinate System Indiana is UTM Zone 16 in meters

43. State Plane Coordinate System Defined for each state in the US. Often used by local governments In Indiana, based on Transverse Mercator projection and Feet

44. Coordinate systems in Indiana Federal and state Government use UTM Meters, Indiana county government uses State Plane Feet Google uses degrees, mins, secs

45. Good tutorials on GPS http://www.aero.org/education/primers/gps/GPS-Primer.pdf http://www.trimble.com/gps/ To really learn more, take the GPS course in Civil Engineering Very nicely done "What is GPS" video from US Air Force: http://www.youtube.com/watch?v=fpPwMu 3foGghttp://www.youtube.com/watch?v=fpPwMu 3foGg