User's Manual

ManualsBrandsTrimble ManualsElectronicsGNSS RX with Bluetooth and Spread Spectrum Radio

129

130

131

132

133

134

135

136

137

138

Table Of Contents

USER GUIDE
Legal Notices
Safety Information
- Regulations and safety
- Type approval
- Exposure to radio frequency radiation
- Installing antennas
- Battery safety
Contents
Introduction
- About the SPSx80 Smart GPS antenna
- About the SPSx81 Smart GPS antenna
- Related Information
- Technical Support
- Your Comments
Features and Functions
- Overview
- SPS780 Smart GPS antenna features
- SPS781 Smart GPS antenna standard features
- SPS880 Extreme Smart GPS antenna standard features
- SPS881 Extreme Smart GPS antenna standard features
- Use and care
- COCOM limits
- Parts of the receiver
  - Front panel
  - Lower housing
- Button functions
- LED behavior
  - LED flash patterns
Batteries and Power
- External power
- Battery safety
- Battery performance
- Charging the Lithium-ion batteries
- Storing the Lithium-ion battery
- Disposing of the rechargeable Lithium-ion battery
Setup Guidelines
- Base station operation guidelines
  - Base station components
  - Base station setup guidelines
- Rover operation guidelines
  - Rover receiver components
  - Rover receiver setup guidelines
- Cellular modem and external radio
Setting up the Receiver
- Connecting the receiver to external devices
  - Trimble controller with SCS900 Site Controller software
  - External radio-modems
- Common ways to set up a base station
- Common ways to set up a rover receiver
Configuring the Receiver Settings
- Using the SCS900 Site Controller software to configure the base station, the rover, and the radios
- Configuring the receiver to log data for postprocessing
- Configuring the receiver in real time
- Configuring the receiver using application files
- Creating and editing the configuration files that control the receiver
AutoBase Feature
- Setting Up a Base Station
  - Best practice
  - Antenna type
- Scenarios
- AutoBase process
Default Settings
- Default receiver settings
- Resetting the receiver to factory defaults
- Default behavior
- Power up settings
- Logging data
  - Logging data after a power loss
Specifications
- General specifications
- Physical specifications
- Electrical specifications
- Communication specifications
- GPS satellite signal tracking
- Integrated radio options
- Variable configuration options
NMEA-0183 Output
- NMEA-0183 message overview
- Common message elements
  - Message values
- NMEA messages
- ADV
- GGA
- GSA
- GST
- GSV
- HDT
- PTNL,AVR
- PTNL,GGK
- PTNL,PJK
- PTNL,VGK
- PTNL,VHD
- RMC
- ROT
- VTG
- ZDA
GSOF Messages
- Supported message types
- General Serial Output Format
- Reading binary values
  - INTEGER data types
- GSOF message definitions
Adding Internal Radio Frequencies
- Adding receive frequencies for the 450 MHz internal radio
Real-Time Data and Services
- RT17 Streamed Data service
- Login authentication
Upgrading the Receiver Firmware
- The WinFlash utility
  - Installing the WinFlash utility
- Upgrading the receiver firmware
Data Logging and Postprocessed Measurement Operations
- Connecting to the office computer
- Transferring files directly from a CompactFlash card
- Deleting files in the receiver
- Supported file types
Troubleshooting
- LED conditions
- Receiver issues
- Base station setup and static measurement problems
Glossary

SPSx80 and SPSx81 Smart GPS Antennas User Guide 133

Glossary

SNR See

signal-to-noise ratio.

triple frequency GPS A type of receiver that uses three carrier phase measurements (

L1, L2, and L5).

UTC Universal Time Coordinated. A time standard based on local solar mean time at the

Greenwich meridian.

VRS Virtual Reference Station. A VRS system consists of GPS hardware, software, and

communication links. It uses data from a network of

base stations to provide

corrections to each rover that are more accurate than corrections from a single base

station.

To start using VRS corrections, the rover sends its position to the VRS server. The VRS

server uses the base station data to model systematic errors (such as ionospheric

noise) at the rover position. It then sends

RTCM correction messages back to the rover.

WAAS Wide Area Augmentation System. WAAS was established by the Federal Aviation

Administration (FAA) for flight and approach navigation for civil aviation. WAAS

improves the accuracy and availability of the basic GPS signals over its coverage area,

which includes the continental United States and outlying parts of Canada and

Mexico.

The WAAS system provides correction data for visible satellites. Corrections are

computed from ground station observations and then uploaded to two geostationary

satellites. This data is then broadcast on the L1 frequency, and is tracked using a

channel on the GPS receiver, exactly like a GPS satellite.

Use WAAS when other correction sources are unavailable, to obtain greater accuracy

than autonomous positions. For more information on WAAS, refer to the FAA website

http://gps.faa.gov.

The EGNOS service is the European equivalent and MSAS is the Japanese equivalent of

WAAS.

WGS-84 World Geodetic System 1984. Since January 1987, WGS-84 has superseded WGS-72 as

the

datum used by GPS.

The WGS-84 datum is based on the

ellipsoid of the same name.