Introduction to Global Positioning Systems (GPS) Mark Smith, Assistant Professor/Wildlife Extension Specialist
GPS Basics ► Satellite navigation system ► Maintained by the US Government All weather 24 hour Worldwide ► Available free to the public
Global Position “System” ► Space segment 24 satellites emitting radio signals ► Control Segment US DOD ► User Segment Your receiver
GPS Basics ► Radio signals sent from orbiting satellites to earth ► Measures receiver-to-satellite distance How long the signal took to get to your receiver Speed of light (186,000 m/s) Atomic clocks ► GPS units receive and convert signals to position, velocity, and time information
GPS Basics ► What’s in a radio signal? Psuedorandom code – identifies the satellite Ephemeris data – tells where the satellite should be Almanac data – tells the health of the satellite ► Constellation of 24 NAVSTAR earth-orbiting satellites ► Need to receive a signal from: 3 satellites for a 2D position 4 satellites for a 3D position
Sources of GPS Error ► Satellite availability ► Satellite geometry ► Ionosphere/troposphere conditions ► Signal blockage (i.e., forest canopy, tall buildings) ► Multi-path (signal bounce) ► Clock error (timing) ► Intentional degradation (the old Selective Availability)
Overcoming some forms of GPS error ► Differential correction Real time Post-processing “Base” station at a known location recording satellite signals simultaneously Differences in timing are then applied to the signals you recorded with your receiver ► WAAS enable units Wide Area Augmentation System Modified GPS signal---with error correction factor North America only 25 ground reference stations that collect signals and then send correction info to satellites which gets sent to your receiver
Measures of Position Accuracry ► DOP – Dilution of Precision Indicator of the quality of the satellite constellation Lower is better Types of DOP PDOP – Position Dilution of Precision VDOP – Vertical Dilution of Precision HDOP – Horizontal Dilution of Precision
Coordinate Systems ► Latitude/Longitude Degrees, minutes, seconds (33 o 14’ 32”) Decimal degrees ( o ) ► Projections How “3D” objects are converted to “2D” objects Cylindrical, Conical, and Planar ► Datums How the earth is shaped Based on mathematical models of the earth’s shape and dimensions ► Universal Transverse Mercator (UTM) Cylindrical 60 6-degree slices Meters ► Example: UTM, Zone 16N, NAD-27
UTM Zones
Which GPS Receiver is Best? ► Deluxe Survey grade units ► Used for highway and engineering projects ► Horizontal accuracy within a centimeter ► Costs up to $40,000 Mapping/resource grade units ► Used for mapping roads, stand boundaries, and point data ► Relocating data that is not flagged or marked ► 1-5 meter accuracy with good signal ► Usually requires formal training to use ► Download data to Geographic Information System ► Costs begin around $2,000
Which GPS Receiver is Best? ► Economical Recreational grade units ► General navigation ► Relocating plots, trees, etc. that have been flagged ► Estimating acreage of forest stands ► 3-5 meter accuracy with good signal ► Easy to learn using manual ► Costs $100 - $500
Which GPS Receiver is Best? ► Grade GPS you choose depends on field work and data collection needs Recreational grade – most forest inventory tasks Resource/mapping grade- determining harvest boundaries Recreational grade are good for first-time GPS users
GPS in Forestry ► Navigation ► Pre-harvest and post-harvest stand delineation ► Road and landing layout ► Acre control ► Equipment tracking ► Wildlife uses
Stand Delineation ► Estimating acreages Tree planting Herbicide application Slope/aspect
Wildlife ► GPS collars Large mammals Waterfowl 155 gm 760 gm 350 gm 1,100 gm
Questions/Discussion