Trimble 6248192 900 MHz FHSS Transceiver User Manual SPSx80 Smart GPS Antenna User Guide
Trimble Navigation Ltd 900 MHz FHSS Transceiver SPSx80 Smart GPS Antenna User Guide
Trimble >
User Manual
USER GUIDE Trimble SPSx80 Smart GPS Antenna ® Version 2.28 (SPS780 Smart GPS Antennas) Version 3.20 (SPS880 Smart GPS Antennas) Revision A August 2006 Corporate Office Trimble Navigation Limited 935 Stewart Drive Sunnyvale, CA 94085 USA www.trimble.com Construction Business Area Trimble Navigation Limited Construction Business Area 5475 Kellenburger Road Dayton, Ohio 45424-1099 USA 800-538-7800 (toll free in USA) +1-937-245-5600 Phone +1-937-233-9004 Fax www.trimble.com E-mail: trimble_support@trimble.com Legal Notices Copyright and Trademarks © 2006, Trimble Navigation Limited. All rights reserved. Trimble and the Globe & Triangle logo are trademarks of Trimble Navigation Limited, registered in the United States Patent and Trademark Office and in other countries. AutoBase, CMR, CMR+, HydroPro, Maxwell, TRIMMARK, Trimble Geomatics Office, Trimble Total Control, TSC2, TSCe, VRS, Zephyr, and Zephyr Geodetic are trademarks of Trimble Navigation Limited. The Bluetooth word mark and logos are owned by the Bluetooth SIG, Inc. and any use of such marks by Trimble Navigation Limited is under license. Microsoft, Windows, and Windows NT, are either registered trademarks or trademarks of Microsoft Corporation in the United States and/or other countries. All other trademarks are the property of their respective owners. Release Notice This is the August 2006 release (Revision A) of the SPSx80 Smart GPS Antenna User Guide. It applies to version 2.28 and 3.20 of the SPSx80 Smart GPS antennas. Product Limited Warranty Information LIMITED WARRANTY TERMS AND CONDITIONS Product Limited Warranty Subject to the following terms and conditions, Trimble Navigation Limited (“Trimble”) warrants that for a period of one (1) year from date of purchase this Trimble product (the “Product”) will substantially conform to Trimble's publicly available specifications for the Product and that the hardware and any storage media components of the Product will be substantially free from defects in materials and workmanship. Product Software Product software, whether built into hardware circuitry as firmware, provided as a standalone computer software product, embedded in flash memory, or stored on magnetic or other media, is licensed solely for use with or as an integral part of the Product and is not sold. If accompanied by a separate end user license agreement (“EULA”), use of any such software will be subject to the terms of such end user license agreement (including any differing limited warranty terms, exclusions, and limitations), which shall control over the terms and conditions set forth in this limited warranty. Software Fixes During the limited warranty period you will be entitled to receive such Fixes to the Product software that Trimble releases and makes commercially available and for which it does not charge separately, subject to the procedures for delivery to purchasers of Trimble products generally. If you have purchased the Product from an authorized Trimble dealer rather than from Trimble directly, Trimble may, at its option, forward the software Fix to the Trimble dealer for final distribution to you. Minor Updates, Major Upgrades, new products, or substantially new software releases, as identified by Trimble, are expressly excluded from this update process and limited warranty. Receipt of software Fixes or other enhancements shall not serve to extend the limited warranty period. For purposes of this warranty the following definitions shall apply: (1) “Fix(es)” means an error correction or other update created to fix a previous software version that does not substantially conform to its Trimble specifications; (2) “Minor Update” occurs when enhancements are made to current features in a software program; and (3) “Major Upgrade” occurs when significant new features are added to software, or when a new product containing new features replaces the further development of a current product line. Trimble reserves the right to determine, in its sole discretion, what constitutes a Fix, Minor Update, or Major Upgrade. Warranty Remedies If the Trimble Product fails during the warranty period for reasons covered by this limited warranty and you notify Trimble of such failure during the warranty period, Trimble will repair OR replace the nonconforming Product with new, equivalent to new, or reconditioned parts or Product, OR refund the Product purchase price paid by you, at Trimble’s option, upon your return of the Product in accordance with Trimble's product return procedures then in effect. How to Obtain Warranty Service To obtain warranty service for the Product, please contact your local Trimble authorized dealer. Alternatively, you may contact Trimble to request warranty service at +1-408-481-6940 (24 hours a day) or e-mail your request to trimble_support@trimble.com. Please be prepared to provide: – your name, address, and telephone numbers – proof of purchase – a copy of this Trimble warranty – a description of the nonconforming Product including the model number – an explanation of the problem The customer service representative may need additional information from you depending on the nature of the problem. Warranty Exclusions and Disclaimer This Product limited warranty shall only apply in the event and to the extent that (a) the Product is properly and correctly installed, configured, interfaced, maintained, stored, and operated in accordance with Trimble's applicable operator's manual and specifications, and; (b) the Product is not modified or misused. This Product limited warranty shall not apply to, and Trimble shall not be responsible for, defects or performance problems resulting from (i) the combination or utilization of the Product with hardware or software products, information, data, systems, interfaces, or devices not made, supplied, or specified by Trimble; (ii) the operation of the Product under any specification other than, or in addition to, Trimble's standard specifications for its products; (iii) the unauthorized installation, modification, or use of the Product; (iv) damage caused by: accident, lightning or other electrical discharge, fresh or salt water immersion or spray (outside of Product specifications); or exposure to environmental conditions for which the Product is not intended; (v) normal wear and tear on consumable parts (e.g., batteries); or (vi) cosmetic damage. Trimble does not warrant or guarantee the results obtained through the use of the Product, or that software components will operate error free. NOTICE REGARDING PRODUCTS EQUIPPED WITH TECHNOLOGY CAPABLE OF TRACKING SATELLITE SIGNALS FROM SATELLITE BASED AUGMENTATION SYSTEMS (SBAS) (WAAS/EGNOS, AND MSAS), OMNISTAR, GPS, MODERNIZED GPS OR GLONASS SATELLITES, OR FROM IALA BEACON SOURCES: TRIMBLE IS NOT RESPONSIBLE FOR THE OPERATION OR FAILURE OF OPERATION OF ANY SATELLITE BASED POSITIONING SYSTEM OR THE AVAILABILITY OF ANY SATELLITE BASED POSITIONING SIGNALS. THE FOREGOING LIMITED WARRANTY TERMS STATE TRIMBLE’S ENTIRE LIABILITY, AND YOUR EXCLUSIVE REMEDIES, RELATING TO THE TRIMBLE PRODUCT. EXCEPT AS OTHERWISE EXPRESSLY PROVIDED HEREIN, THE PRODUCT, AND ACCOMPANYING DOCUMENTATION AND MATERIALS ARE PROVIDED “AS-IS” AND WITHOUT EXPRESS OR IMPLIED WARRANTY OF ANY KIND, BY EITHER TRIMBLE OR ANYONE WHO HAS BEEN INVOLVED IN ITS CREATION, PRODUCTION, INSTALLATION , OR DISTRIBUTION, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE, TITLE, AND NONINFRINGEMENT. THE STATED EXPRESS WARRANTIES ARE IN LIEU OF ALL OBLIGATIONS OR LIABILITIES ON THE PART OF TRIMBLE ARISING OUT OF, OR IN CONNECTION WITH, ANY PRODUCT. BECAUSE SOME STATES AND JURISDICTIONS DO NOT ALLOW LIMITATIONS ON DURATION OR THE EXCLUSION OF AN IMPLIED WARRANTY, THE ABOVE LIMITATION MAY NOT APPLY OR FULLY APPLY TO YOU. Limitation of Liability TRIMBLE'S ENTIRE LIABILITY UNDER ANY PROVISION HEREIN SHALL BE LIMITED TO THE AMOUNT PAID BY YOU FOR THE PRODUCT. TO THE MAXIMUM EXTENT PERMITTED BY APPLICABLE LAW, IN NO EVENT SHALL TRIMBLE OR ITS SUPPLIERS BE LIABLE FOR ANY INDIRECT, SPECIAL, INCIDENTAL , OR CONSEQUENTIAL DAMAGE WHATSOEVER UNDER ANY CIRCUMSTANCE OR LEGAL THEORY RELATING IN ANYWAY TO THE PRODUCTS, SOFTWARE AND ACCOMPANYING DOCUMENTATION AND MATERIALS, (INCLUDING, WITHOUT LIMITATION, DAMAGES FOR LOSS OF BUSINESS PROFITS, BUSINESS INTERRUPTION, LOSS OF DATA, OR ANY OTHER PECUNIARY LOSS), REGARDLESS OF WHETHER TRIMBLE HAS BEEN ADVISED OF THE POSSIBILITY OF ANY SUCH LOSS AND REGARDLESS OF THE COURSE OF DEALING WHICH DEVELOPS OR HAS DEVELOPED BETWEEN YOU AND TRIMBLE. BECAUSE SOME STATES AND JURISDICTIONS DO NOT ALLOW THE EXCLUSION OR LIMITATION OF LIABILITY FOR CONSEQUENTIAL OR INCIDENTAL DAMAGES, THE ABOVE LIMITATION MAY NOT APPLY TO YOU. PLEASE NOTE: THE ABOVE TRIMBLE LIMITED WARRANTY PROVISIONS WILL NOT APPLY TO PRODUCTS PURCHASED IN THOSE JURISDICTIONS (E.G., MEMBER STATES OF THE EUROPEAN ECONOMIC AREA) IN WHICH PRODUCT WARRANTIES ARE THE RESPONSIBILITY OF THE LOCAL TRIMBLE AUTHORIZED DEALER FROM WHOM THE PRODUCTS ARE ACQUIRED . IN SUCH A CASE, PLEASE CONTACT YOUR LOCAL TRIMBLE AUTHORIZED DEALER FOR APPLICABLE WARRANTY INFORMATION. Official Language THE OFFICIAL LANGUAGE OF THESE TERMS AND CONDITIONS IS ENGLISH. IN THE EVENT OF A CONFLICT BETWEEN ENGLISH AND OTHER LANGUAGE VERSIONS, THE ENGLISH LANGUAGE SHALL CONTROL. Registration To receive information regarding updates and new products, please contact your local dealer or visit the Trimble website at www.trimble.com/register. Upon registration you may select the newsletter, upgrade, or new product information you desire. Notices Class B Statement – Notice to Users. This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to Part 15 of the FCC rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates, uses, and can radiate radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communication. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one or more of the following measures: – Reorient or relocate the receiving antenna. – Increase the separation between the equipment and the receiver. – Connect the equipment into an outlet on a circuit different from that to which the receiver is connected. – Consult the dealer or an experienced radio/TV technician for help. Changes and modifications not expressly approved by the manufacturer or registrant of this equipment can void your authority to operate this equipment under Federal Communications Commission rules. Canada This digital apparatus does not exceed the Class B limits for radio noise emissions from digital apparatus as set out in the radio interference regulations of the Canadian Department of Communications. Le présent appareil numérique n’émet pas de bruits radioélectriques dépassant les limites applicables aux appareils numériques de Classe B prescrites dans le règlement sur le brouillage radioélectrique édicté par le Ministère des Communications du Canada. Europe This product has been tested and found to comply with the requirements for a Class B device pursuant to European Council Directive 89/336/EEC on EMC, thereby satisfying the requirements for CE Marking and sale within the European Economic Area (EEA). Contains Infineon radio module ROK 104001. These requirements are designed to provide reasonable protection against harmful interference when the equipment is operated in a residential or commercial environment. Australia and New Zealand This product conforms with the regulatory requirements of the Australian Communications Authority (ACA) EMC framework, thus satisfying the requirements for C-Tick Marking and sale within Australia and New Zealand. Taiwan – Battery Recycling Requirements The product contains a removable Lithium-ion battery. Taiwanese regulations require that waste batteries are recycled. 廢電池請回收 Notice to Our European Union Customers For product recycling instructions and more information, please go to www.trimble.com/ev.shtml. Recycling in Europe: To recycle Trimble WEEE (Waste Electrical and Electronic Equipment, products that run on electrical power.), Call +31 497 53 24 30, and ask for the "WEEE Associate". Or, mail a request for recycling instructions to: Trimble Europe BV c/o Menlo Worldwide Logistics Meerheide 45 5521 DZ Eersel, NL iv SPSx80 Smart GPS Antenna User Guide Safety Information Before you use your Trimble® SPS GPS receiver, make sure that you have read and understood all safety requirements. Regulations and safety The receivers contain an internal radio-modem and can send signals through Bluetooth® wireless technology (SPSx50 Modular GPS receiver and the SPSx80 Smart GPS antenna only) or through an external data communications radio. Regulations regarding the use of the radio-modems vary greatly from country to country. In some countries, the unit can be used without obtaining an end-user license. Other countries require end-user licensing. For licensing information, consult your local Trimble dealer. Before operating an SPSx50 Modular GPS receiver or SPSx80 Smart GPS antenna, determine if authorization or a license to operate the unit is required in your country. It is the responsibility of the end user to obtain an operator’s permit or license for the receiver for the location or country of use. For FCC regulations, see Notices, page iii. Type approval Type approval, or acceptance, covers technical parameters of the equipment related to emissions that can cause interference. Type approval is granted to the manufacturer of the transmission equipment, independent from the operation or licensing of the units. Some countries have unique technical requirements for operation in particular radio-modem frequency bands. To comply with those requirements, Trimble may have modified your equipment to be granted Type approval. Unauthorized modification of the units voids the Type approval, the warranty, and the operational license of the equipment. Exposure to radio frequency radiation For 450 MHz radio Safety. Exposure to RF energy is an important safety consideration. The FCC has adopted a safety standard for human exposure to radio frequency electromagnetic energy emitted by FCC regulated equipment as a result of its actions in General Docket 79-144 on March 13, 1986. Proper use of this radio modem results in exposure below government limits. The following precautions are recommended: • • DO NOT operate the transmitter when someone is 20 cm (7.8 inches) of the antenna. DO NOT operate the transmitter unless all RF connectors are secure and any open connectors are properly terminated. SPSx80 Smart GPS Antenna User Guide Safety Information • DO NOT operate the equipment near electrical blasting caps or in an explosive atmosphere. • All equipment must be properly grounded according to Trimble installation instructions for safe operation. • All equipment should be serviced only by a qualified technician. For license-free 900 MHz radio1 CAUTION – For your own safety, and in terms of the RF Exposure requirements of the FCC, always observe the precautions listed here. • Always maintain a minimum separation distance of 20 cm (7.8 inches) between yourself and the radiating antenna on the SPSx50 radio-modem. • Do not co-locate the antenna with any other transmitting device. For Bluetooth radio The radiated output power of the internal Bluetooth wireless radio is far below the FCC radio frequency exposure limits. Nevertheless, the wireless radio shall be used in such a manner that the Trimble receiver is 20 cm or further from the human body. The internal wireless radio operates within guidelines found in radio frequency safety standards and recommendations, which reflect the consensus of the scientific community. Trimble therefore believes the internal wireless radio is safe for use by consumers. The level of energy emitted is far less than the electromagnetic energy emitted by wireless devices such as mobile phones. However, the use of wireless radios may be restricted in some situations or environments, such as on aircraft. If you are unsure of restrictions, you are encouraged to ask for authorization before turning on the wireless radio. Installing antennas CAUTION – For your own safety, and in terms of the RF Exposure requirements of the FCC, always observe these precautions: – Always maintain a minimum separation distance of 20 cm (7.8 inches) between yourself and the radiating antenna. – Do not co-locate the antenna with any other transmitting device. This device has been designed to operate with the antennas listed below, and having a maximum gain of 5 dBi. Antennas not included in this list, or having a gain greater than 5 dBi, are strictly prohibited for use with this device. The required antenna impedance is 50 ohms. The antennas to be used with the 450 MHz radio are 0 dBi and 5 dBi whip antennas. The antennas to be used with the 900 MHz radio are 0 dBi, 3 dBi, and 5 dBi whip antennas. 1. 900 Mhz radios are not used in Europe. vi SPSx80 Smart GPS Antenna User Guide Safety Information To reduce potential radio interference to other users, the antenna type and its gain should be so chosen that the equivalent isotropically radiated power (e.i.r.p.) is not more than that permitted for successful communication. Battery safety WARNING – Do not damage the rechargeable Lithium-ion battery. A damaged battery can cause an explosion or fire, and can result in personal injury and/or property damage. To prevent injury or damage: – Do not use or charge the battery if it appears to be damaged. Signs of damage include, but are not limited to, discoloration, warping, and leaking battery fluid. – Do not expose the battery to fire, high temperature, or direct sunlight. – Do not immerse the battery in water. – Do not use or store the battery inside a vehicle during hot weather. – Do not drop or puncture the battery. – Do not open the battery or short-circuit its contacts. WARNING – Avoid contact with the rechargeable Lithium-ion battery if it appears to be leaking. Battery fluid is corrosive, and contact with it can result in personal injury and/or property damage. To prevent injury or damage: – If the battery leaks, avoid contact with the battery fluid. – If battery fluid gets into your eyes, immediately rinse your eyes with clean water and seek medical attention. Do not rub your eyes! – If battery fluid gets onto your skin or clothing, immediately use clean water to wash off the battery fluid. WARNING – Charge and use the rechargeable Lithium-ion battery only in strict accordance with the instructions. Charging or using the battery in unauthorized equipment can cause an explosion or fire, and can result in personal injury and/or equipment damage. To prevent injury or damage: – Do not charge or use the battery if it appears to be damaged or leaking. – Charge the Lithium-ion battery only in a Trimble product that is specified to charge it. Be sure to follow all instructions that are provided with the battery charger. – Discontinue charging a battery that gives off extreme heat or a burning odor. – Use the battery only in Trimble equipment that is specified to use it. – Use the battery only for its intended use and according to the instructions in the product documentation. SPSx80 Smart GPS Antenna User Guide vii Safety Information viii SPSx80 Smart GPS Antenna User Guide Contents Safety Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . v Regulations and safety . . . . . . . . . . . Type approval . . . . . . . . . . . . . . . . Exposure to radio frequency radiation . For 450 MHz radio . . . . . . . . . For license-free 900 MHz radio . For Bluetooth radio . . . . . . . . Installing antennas . . . . . . . . . . . . . Battery safety. . . . . . . . . . . . . . . . . . v . v . v . v . vi . vi . vi vii 13 13 13 13 14 14 14 Features and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SPS780 Smart GPS antenna standard features . . . . . . . SPS780 Basic features . . . . . . . . . . . . . . . . . . SPS780 Max features . . . . . . . . . . . . . . . . . . . SPS880 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 . . . . . . . . . . . . . . . . . . . . Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 About the SPSx80 Smart GPS antenna. . . . SPS780 Basic Smart GPS antenna . . SPS780 Max Smart GPS antenna . . . SPS880 Extreme Smart GPS antenna Related Information . . . . . . . . . . . . . . . Technical Support. . . . . . . . . . . . . . . . . Your Comments . . . . . . . . . . . . . . . . . . 16 16 16 17 17 18 18 18 19 20 21 21 22 Batteries and Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23 External power . . . . . . . . . . . . . . . . . . . . . . . Battery safety. . . . . . . . . . . . . . . . . . . . . . . . . Battery performance . . . . . . . . . . . . . . . . . . . . Charging the Lithium-ion batteries . . . . . . . . . . . Storing the Lithium-ion battery . . . . . . . . . . . . . Disposing of the rechargeable Lithium-ion battery . Operating the receiver with a Trimble controller . . SPSx80 Smart GPS Antenna User Guide 24 24 24 25 26 26 26 ix Contents Setup Guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 Base station operation guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Base station components. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Base station setup guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Permanent installation antenna cabling for the SPSx50 Modular GPS receiver and SPS770 GPS receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Rover operation guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Rover receiver components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Rover receiver setup guidelines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cellular modem and external radio . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31 31 32 33 36 38 38 39 40 40 41 42 45 45 47 48 Configuring the Receiver Settings . . . . . . . . . . . . . . . . . . . . . . . 51 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 . . . . . . . . . . . . . . . . . . . . . . . . . . Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Special application files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Applying application files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Storing application files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Naming application files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Creating and editing the configuration files that control the receiver . . . . . . . . . . . . Installing the Configuration Toolbox software. . . . . . . . . . . . . . . . . . . . . . . Configuring the receiver using the Configuration Toolbox software . . . . . . . . . Transmitting the application file to the receiver . . . . . . . . . . . . . . . . . . . . . Setting up the Receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37 Connecting the receiver to external devices . . . . . . . . . . . . . . . . . . . . . . . Trimble controller with SCS900 Site Controller software . . . . . . . . . . . External radio-modems . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Common ways to set up a base station . . . . . . . . . . . . . . . . . . . . . . . . . . Setting up a base station for permanent or semi-permanent installation. Setting up a base station for daily site use: T-Bar . . . . . . . . . . . . . . . . Setting up a mobile base station: Tripod and fixed height tripod . . . . . . Common ways to set up a rover receiver . . . . . . . . . . . . . . . . . . . . . . . . . Setting up the rover receiver on a jobsite vehicle . . . . . . . . . . . . . . . . Setting up the rover receiver on a rod . . . . . . . . . . . . . . . . . . . . . . . Setting up a rover receiver on a belt or in a backpack . . . . . . . . . . . . . . . . 28 . . . 28 . . . 29 52 53 53 53 53 54 55 55 56 56 56 57 58 AutoBase Feature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59 Setting Up a Base Station . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60 Best practice . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60 Antenna type . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60 SPSx80 Smart GPS Antenna User Guide Contents Scenarios . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Scenario One: Base station setup on first visit to a site . . . . . . . . . . Scenario Two: Base station setup on a repeat visit to that site . . . . . Scenario Three: The stored base station position seems to be missing Flowchart showing the AutoBase process . . . . . . . . . . . . . . . . . . . . . . 61 61 61 62 63 66 66 67 67 67 67 70 70 71 72 NMEA-0183 Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73 NMEA-0183 message overview Common message elements . . Message values . . . . . . NMEA messages . . . . . . . . . Specifications. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 69 General specifications . . . . . . Physical specifications . . . . . . Electrical specifications . . . . . Communication specifications Default Settings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65 Default receiver settings . . . . . . . . . . . Resetting the receiver to factory defaults Default behavior. . . . . . . . . . . . . . . . Power up settings . . . . . . . . . . . . . . . Logging data . . . . . . . . . . . . . . . . . . Logging data after a power loss . . 74 75 75 75 GSOF Messages . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91 Supported message types . . . . . . . . GSOF message definitions . . . . . . . TIME . . . . . . . . . . . . . . . . LLH . . . . . . . . . . . . . . . . . ECEF. . . . . . . . . . . . . . . . . ECEF DELTA. . . . . . . . . . . . NEU DELTA . . . . . . . . . . . . Velocity . . . . . . . . . . . . . . . PDOP . . . . . . . . . . . . . . . . SIGMA . . . . . . . . . . . . . . . SV Brief . . . . . . . . . . . . . . . SV Detail . . . . . . . . . . . . . . UTC . . . . . . . . . . . . . . . . . Batt/Mem . . . . . . . . . . . . . Attitude . . . . . . . . . . . . . . . Flags . . . . . . . . . . . . . . . . . Data collector report structure . 92 . 92 . 92 . 93 . 93 . 94 . 94 . 95 . 95 . 95 . 96 . 97 . 98 . 98 . 99 .100 .102 SPSx80 Smart GPS Antenna User Guide xi Contents Adding Internal Radio Frequencies . . . . . . . . . . . . . . . . . . . . . 103 Adding receive frequencies for the 450 MHz internal radio. . . . . . . . . . . . . . . . . . . . . . .104 Upgrading the Receiver Firmware . . . . . . . . . . . . . . . . . . . . . . 105 The WinFlash utility . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .106 Installing the WinFlash utility . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .106 Upgrading the receiver firmware . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .106 Data Logging and Postprocessed Measurement Operations . . . . . . . 109 Connecting to the office computer . . . . . . . . . . . . Transferring files directly from a CompactFlash card Deleting files in the receiver . . . . . . . . . . . . . . . . Supported file types . . . . . . . . . . . . . . . . . . . . . .110 .110 .111 .111 Troubleshooting . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113 LED conditions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .114 Receiver issues. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .114 Base station setup and static measurement problems . . . . . . . . . . . . . . . . . . . . . . . . . .116 Glossary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119 xii SPSx80 Smart GPS Antenna User Guide CHAPTER Introduction SPS780 Basic Smart GPS antenna Welcome to the SPSx80 Smart GPS Antenna User Guide. This manual describes how to set up and use the Trimble® SPSx80 Smart GPS antennas. The SPS GPS receivers is a family of receivers that comprise the SPSx50 Modular GPS receivers, SPS770 GPS receivers, and the SPSx80 Smart GPS antennas. Where necessary, this manual contains references to specific receivers in the product family. When information is specific to a particular model, then the specific model name is used. Even if you have used other Global Positioning System (GPS) products before, Trimble recommends that you spend some time reading this manual to learn about the special features of this product. If you are not familiar with GPS, visit the Trimble website (www.trimble.com) for an interactive look at Trimble and GPS. About the SPSx80 Smart GPS antenna The SPSx80 Smart GPS antenna family comprises the following Smart GPS antennas: • SPS780 Basic • SPS780 Max • SPS880 Extreme The SPS780 Basic Smart GPS antenna is the entry level receiver in the SPSx80 Smart GPS antenna family. The SPS780 Basic is available as a base station only or rover only configuration. The receiver is optimized for use on small-to-midsize construction projects. SPS780 Max Smart GPS antenna The SPS780 Max Smart GPS antenna is available from new or as an upgrade to the SPS780 Basic Smart GPS antenna. The SPS780 Max configuration provides you with base and rover operation capability plus the ability to work at longer ranges from the base station, and to operate as a rover in a Trimble Virtual Reference Station (VRS™) network. SPS880 Extreme Smart GPS antenna The SPS880 Extreme Smart GPS antenna can track the existing GPS L1 and L2 satellite signals plus the future L2C and L5 signals as they become available. The new signals provide the ability to initialize faster, work in harsher GPS environments, and work at longer ranges from the base station. The SPS880 Extreme can also utilize signals from the Russian GLONASS satellites, providing increased satellite availability and fewer/shorter GPS outages. The Smart GPS antennas are designed for all on-the-rod rover operation and rapid daily base station setup operation. SPSx80 Smart GPS Antenna User Guide 13 1 Introduction Related Information Sources of related information include the following: • Help – The SCS900 Site Controller software has built-in, context-sensitive help that lets you quickly find the information you need. Access it from the Help menu. Alternatively, click the ? button in a dialog, or press [F1]. On a Microsoft® Windows® CE device, select Start / Help. • Release notes – The release notes describe new features of the product, information not included in the manuals, and any changes to the manuals. They are provided as a .pdf file on the Trimble SPS GPS Receiver CD. • Trimble training courses – Consider a training course to help you use your GPS system to its fullest potential. For more information, go to the Trimble website at www.trimble.com/training.html. Technical Support If you have a problem and cannot find the information you need in the product documentation, contact your local dealer. Alternatively, go to the Support area of the Trimble website (www.trimble.com/support.shtml). Select the product you need information on. Product updates, documentation, and any support issues are available for download. If you need to contact Trimble technical support, complete the online inquiry form at www.trimble.com/support_form.asp. Your Comments Your feedback about the supporting documentation helps us to improve it with each revision. E-mail your comments to ReaderFeedback@trimble.com. 14 SPSx80 Smart GPS Antenna User Guide CHAPTER Features and Functions In this chapter: SPS780 Smart GPS antenna standard features SPS880 Extreme Smart GPS antenna standard features Use and care COCOM limits Parts of the receiver Button functions LED behavior The SPSx80 Smart GPS antennas are designed to be used for the following infrastructure and site development applications: • Layout of structure foundations, caissons and piles • Earthworks, fine grading and finishing stakeout operations • Initial site measurements to verify design levels and regular subsequent measurements to determine progress volumes • Measurements and grade/thickness checks on laid materials The SPSx80 incorporates a GPS antenna, receiver, internal radio, and battery in a rugged light-weight unit that is ideally suited as an allon-the-pole RTK rover or quick setup/rapid mobilization base station. LEDs enable you to monitor satellite tracking, radio reception, data logging status, and power. Bluetooth® wireless technology provides cable-free communications between the receiver and controller. You can use the SPSx80 as part of an RTK GPS system with the Trimble SCS900 Site Controller software. All the receivers can optionally record GPS data to the receiver’s optional internal memory and download to a computer using the serial connection. SPSx80 Smart GPS Antenna User Guide 15 2 Features and Functions Overview The SPS780 and SPS880 Extreme Smart GPS antennas (see Figure 2.1) are very similar in setup, operational use, and controls. The SPS880 has a taller antenna dome to accommodate the larger GPS antenna and the circuitry required to track additional GPS signals and GLONASS satellites. Figure 2.1 SPS780 Smart GPS antenna (left), and the SPS880 Extreme Smart GPS antenna (right) SPS780 Smart GPS antenna standard features The SPS780 Smart GPS antenna provides the following features: • Small, lightweight design - 1.31 kg (2.89 lb) (integrated radio, GPS receiver, GPS antenna and battery) 3.7 kg (8.16 lb) complete system weight (rover including TSC2 controller and rod) • The quick setup, high mobility base and rover receiver system is ideal for small to mid-size jobsites and for working on multiple jobsites on a daily or weekly basis • 24-channel L1/L2 GPS receiver (SPS780 Basic and SPS780 Max) • Internal, removable, smart Lithium-ion battery provides up to 6.6 hrs GPS rover operation per battery • Bluetooth® wireless technology for cable free, no hassle base or rover operation • Simple keypad with on/off key and LED indicators for power, radio, and satellite tracking • Allows measurement from a moving platform, for example, mounted on a vehicle or marine vessel for increased efficiency on large jobsites SPS780 Basic features 16 • Rover or base configurations, not interchangeable • 2 Hz measurement rover receiver update rate • Rover operational range limited to 1.5 mile (2.4 km) from base station SPSx80 Smart GPS Antenna User Guide 2 Features and Functions • Base station operational range limited only by normal restrictions common to UHF radio transmissions • Integrated transmit radio (450 MHz Base configuration only) • Entry level price point for lower cost of base station or rover • Can be upgraded to the SPS780 Max SPS780 Max features • Base/Rover receiver interchangeability for ultimate GPS fleet flexibility • Rover option offers 10 Hz measurement update rate • Range limited only by normal restrictions common to UHF radio transmissions • Operates as a rover within a Virtual Reference Station (VRS) network for operation without a conventional base station • Integrated transmit/receive radio provides base station and rover operation capability (900 MHz variant contains receive only radio and utilizes the SNB900 radio at the base station for transmit capability) SPS880 Extreme Smart GPS antenna standard features • Small, lightweight design – 1.35 kg (2.97 lb) (integrated radio, GPS receiver, GPS antenna and battery) 3.71 kg (8.18 lb) complete system weight (rover including TSC2 controller and rod) • The quick setup, high mobility base or rover receiver, is ideal for any size jobsite as a rover and for working on multiple jobsites on a daily or weekly basis • 72-channel L1/L2/L2C/L5 GPS and L1/L2 GLONASS receiver • Performs all site measurement and stakeout operations within the operating range of the radio • Internal, removable, smart Lithium-ion battery provides up to 5.5 hrs GPS rover operation per battery • Bluetooth wireless technology for cable free, no hassle base or rover operation • Simple keypad with on/off key and LED indicators for power, radio and satellite tracking • 20 Hz update rate • Full base/rover interchangeability • Operates within a VRS network for conventional base station-free rover capability • Integrated transmit radio (450MHz version only) • Receives L2C code and L5 carrier signal for future GPS modernization capability • Tracks GLONASS L1/L2 signals for increased satellite availability and operation in harsh GPS environments SPSx80 Smart GPS Antenna User Guide 17 2 Features and Functions Use and care This product is designed to withstand the rough treatment and tough environment that typically occurs in construction applications. However, the receiver is a high-precision electronic instrument and should be treated with reasonable care. CAUTION – Operating or storing the receiver outside the specified temperature range can damage it. For more information, see Chapter 10, Specifications. COCOM limits The U.S. Department of Commerce requires that all exportable GPS products contain performance limitations so that they cannot be used in a manner that could threaten the security of the United States. The following limitations are implemented on this product: • Immediate access to satellite measurements and navigation results is disabled when the receiver velocity is computed to be greater than 1000 knots, or its altitude is computed to be above 18 000 meters. The receiver GPS subsystem resets until the COCOM situation clears. As a result, all logging and stream configurations stop until the GPS subsystem is cleared. Parts of the receiver All operating controls on the SPSx80 Smart GPS antenna are located on the front panel. Serial ports and connectors are located on the bottom of the unit. 18 SPSx80 Smart GPS Antenna User Guide 2 Features and Functions Front panel Figure 2.2 shows a front view of the SPSx80 Smart GPS antenna. The front panel contains the three indicator LEDs, and the power button. Power LED Radio LED Power button Satellite LED Figure 2.2 Front panel of the SPSx80 Smart GPS antenna The power button controls the receiver’s power on or off functions. The indicator LEDs show the status of power, satellite tracking, and radio reception. For more information, see LED behavior, page 21. SPSx80 Smart GPS Antenna User Guide 19 2 Features and Functions Lower housing Figure 2.3 shows the lower housing of the SPS780 Smart GPS antenna. The lower housing is the same for the SPS880, except for the identifying label. The housing contains the two serial ports, one TNC radio antenna connector, the removable battery compartment and the 5/8-11 threaded insert. Receiver identifying label TNC radio antenna connection Port 2 5/8-11" threaded insert Port 1 Figure 2.3 SPSx80 Smart GPS antenna lower housing Each port or connector on the Smart GPS antenna is marked with an icon to indicate its main function, as shown in Table 2.1. Table 2.1 Icon Receiver ports Name Connections Port 1 Device, computer, external radio, power in Port 2 Device, computer, external radio RADIO Radio communications antenna Port 1 is a 7-pin 0-shell Lemo connector that supports RS-232 communications and external power input. Port 1 has no power outputs. 20 SPSx80 Smart GPS Antenna User Guide 2 Features and Functions Port 2 is a DB-9 male connector that allows for full 9-pin RS-232 communications. Port 2 does not support power in or out. For more information on default port settings, see Default receiver settings, page 66. For more information on connector pinouts, see Communication specifications, page 72. The TNC port connector is for connecting a radio antenna to the receiver internal radio. A whip “rubber duck” antenna is supplied with the system for units with internal UHF or 900 MHz radios. This connector is not used if you are using an external radio receiver. For longer range operation (to provide higher gain and to raise the antenna higher above the ground), you can use a cable to connect an external radio antenna to the TNC port. For more information on connecting the SPSx80 Smart GPS antenna, see the Chapter 5, Setting up the Receiver. Button functions The receiver has only one button, the Power button, represented in this manual by E . Press E to switch the receiver on or off, and to perform other functions, as described as follows: Action Power button Turn on the receiver Press Turn off the receiver Hold for 2 seconds Delete the ephemeris file Hold for 15 seconds Reset the receiver to factory defaults Hold for 15 seconds Delete application files Hold for 30 seconds Note – The term “press” means to press the button and release it immediately. The term “hold” means to press the button and hold it down for the given time. LED behavior The three LEDs on the front panel of the receiver indicate various operating conditions. Generally, a lit or slowly flashing LED indicates normal operation, a LED that is flashing quickly indicates a condition that may require attention, and an unlit LED indicates that no operation is occurring. The following table defines each possible LED state: The term … means that the LED … Slow flash alternates on/off for 500 milliseconds. Fast flash alternates rapidly on/off for 100 milliseconds On is lit steady Off is unlit SPSx80 Smart GPS Antenna User Guide 21 2 Features and Functions LED flash patterns The following table details the possible flash patterns to indicate various states of receiver operation. Receiver mode Power LED Radio LED Satellite LED Green Green Amber Receiver OFF OFF OFF OFF Receiver ON Healthy power ON N/A N/A Low power Fast flash N/A N/A Tracking <4 SVs ON N/A Fast flash Tracking >4 SVs ON N/A Slow flash Logging data internally Flashes off every 3 seconds N/A N/A Receiving valid data packets ON Slow flash N/A No data packets ON OFF N/A Monitor mode ON Slow flash ON Note – If a column shows “N/A”, that specific LED may or may not be on, but it is not relevant to that particular mode. 22 SPSx80 Smart GPS Antenna User Guide CHAPTER Batteries and Power In this chapter: External power Battery safety Battery performance Charging the Lithium-ion batteries Storing the Lithium-ion battery Disposing of the rechargeable Lithium-ion battery Operating the receiver with a Trimble controller The GPS receiver is powered by an internal Lithium-ion battery, which can be detached from the receiver for charging. The receiver can also be connected to an external power source through Port 1. During measurement operations, each internal battery typically provides about 6.6 hours of power if using the internal RX (receive) radio and about 4.5 hours operating as a base station using the internal 450 MHz TX (transmit) radio. These times vary according to the type of measurement and the operating conditions. SPSx80 Smart GPS Antenna User Guide 23 3 Batteries and Power External power The GPS receiver uses an external power source in preference to its internal batteries. If the receiver is not connected to an external power source, or if the external power supply fails, the internal batteries are used. While carrying out static measurements for postprocessed computations using the internal memory, if no external power is supplied and the internal battery is drained, the receiver shuts down. No data is lost and when power is restored, the receiver restarts in the same status as it was when power was lost. Battery safety The receiver is powered by one rechargable Lithium-ion battery. Charge and use the battery only in strict accordance with the instructions in this chapter. WARNING – Do not damage the rechargeable Lithium-ion battery. A damaged battery can cause an explosion or fire, and can result in personal injury and/or property damage. To prevent injury or damage: – Do not use or charge the battery if it appears to be damaged. Signs of damage include, but are not limited to, discoloration, warping, and leaking battery fluid. – Do not expose the battery to fire, high temperature, or direct sunlight. – Do not immerse the battery in water. – Do not use or store the battery inside a vehicle during hot weather. – Do not drop or puncture the battery. – Do not open the battery or short-circuit its contacts. WARNING – Avoid contact with the rechargeable Lithium-ion battery if it appears to be leaking. Battery fluid is corrosive, and contact with it can result in personal injury and/or property damage. To prevent injury or damage: – If the battery leaks, avoid contact with the battery fluid. – If battery fluid gets into your eyes, immediately rinse your eyes with clean water and seek medical attention. Do not rub your eyes! – If battery fluid gets onto your skin or clothing, immediately use clean water to wash off the battery fluid. Battery performance To optimize battery performance and extend battery life: • • • 24 Fully charge all new batteries before use. Batteries perform best when they are not used at extreme temperatures. The receiver is designed to operate at –40 °C to +65 °C (–40 °F to +149 °F). However, operation at temperatures of less than 0 °C (32 °F) can cause a rapid drop in battery life. Do not allow a battery that is in storage to discharge to below 5 V. SPSx80 Smart GPS Antenna User Guide Batteries and Power Charging the Lithium-ion batteries WARNING – Charge and use the rechargeable Lithium-ion battery only in strict accordance with the instructions. Charging or using the battery in unauthorized equipment can cause an explosion or fire, and can result in personal injury and/or equipment damage. To prevent injury or damage: – Do not charge or use the battery if it appears to be damaged or leaking. – Charge the Lithium-ion battery only in a Trimble product that is specified to charge it. Be sure to follow all instructions that are provided with the battery charger. – Discontinue charging a battery that gives off extreme heat or a burning odor. – Use the battery only in Trimble equipment that is specified to use it. – Use the battery only for its intended use and according to the instructions in the product documentation. The rechargeable Lithium-ion batteries are supplied partially charged. Note – Charge the battery completely before using it for the first time. If the battery has been stored for longer than three months, charge it before use. To charge the battery, first remove the battery from the receiver, and then place it in one of the following battery chargers, which is connected to mains power: • The dual-slot GPS battery charger (P/N 41114-00) and power supply (P/N 48800-00): • The five slot multi charger (P/N 49499-00) and power supply (P/N 51694): SPSx80 Smart GPS Antenna User Guide 25 3 Batteries and Power Storing the Lithium-ion battery If you must store a Lithium-ion battery for long periods, make sure that it is fully charged before it is stored, and that you charge it at least once every three months while it is stored. Do not allow a battery that is in storage to discharge to below 5 V. A battery that reaches deep discharge level (5 V or less) cannot be recharged and must be replaced. (To protect a battery that is in use from deep discharge, the receiver switches power sources or stops drawing power when the battery pack discharges to 5.9 V.) All batteries discharge over time when not in use, and they discharge faster in colder temperatures. Do not store the receiver at temperatures outside the range –40 °C to +70 °C (–40 °F to +158 °F). Do not store the batteries in the receiver or in the external charger unless power is applied. Keep all batteries on continuous charge when not in use. You can keep batteries on charge indefinitely without damage to the batteries. Disposing of the rechargeable Lithium-ion battery Discharge a Lithium-ion battery before disposing of it. Dispose of batteries in an environmentally sensitive manner, and adhere to any local and national regulations concerning battery disposal or recycling. Operating the receiver with a Trimble controller You can operate an SPS GPS receiver with any Trimble controller, for example, a TSC2 or TCU controller, that is running the SCS900 software. Typically, the receiver and the controller operate from their own individual power sources. The receiver and controller can communicate through Bluetooth wireless technology and can be connected without a cable. However, if a cable is required, the following information indicates which cable to use with which controller: 26 Controller Cable Controller connector Receiver connector TSC2 P/N 18532 DSub9 DSub9 TCU P/N 5302007 6H (Marked “Com” on the controller GPS holder) DSub9 TCU (alternative connection) P/N 53004007 6H (Marked “Com” on the controller GPS holder) SPSx80 Smart GPS Antenna User Guide 7OS CHAPTER Setup Guidelines In this chapter: Base station operation guidelines Rover operation guidelines GPS Real-Time Kinematic (RTK) operation provides centimeter-level accuracy by eliminating errors that are present in the GPS system. For all RTK operations, you require both a base station and a rover receiver. This chapter introduces the concepts of base station and rover operation, provides information to help you identify good setup locations, describes best practices for setting up the equipment, and outlines the precautions that you need to take to protect the equipment. Note – This chapter provides setup information for all the receivers in the SPS GPS receiver family. SPSx80 Smart GPS Antenna User Guide 27 4 Setup Guidelines Base station operation guidelines A base station consists of a receiver that is placed at a known (and fixed) position. The receiver tracks the same satellites that are being tracked by the rover receiver, at the same time that the rover is tracking them. Errors in the GPS system are monitored at the fixed (and known) base station, and a series of position corrections are computed. The corrections are sent through a radio link to the rover receiver, where they are used to correct the real time positions of the rover. Base station components The base station has the following components: • GPS receiver • GPS antenna • Base station radio • Power supply GPS receiver and GPS antenna The base station GPS receiver can be one of following types: • A Smart GPS antenna, such as the SPSx80, which incorporates a GPS receiver, GPS antenna, power supply, and base station radio into a single compact unit. A Smart GPS antenna can be rapidly set up on a tripod, fixed height tripod, or T-Bar anywhere that is convenient on the jobsite. • A Modular GPS receiver, such as the SPSx50, which incorporates a GPS receiver, power supply, and base station radio in a single unit. The GPS antenna (and, optionally, the base station radio antenna) is separate from the receiver. Because the GPS antenna is separate, you can use the following optimized components: – a geodetic antenna with large ground plane, to eliminate multipath (the major source of GPS errors) at the base station – a high gain or directional radio antenna, to increase broadcast range and to provide maximum coverage You can also place a modular GPS receiver in an easily accessible and secure location, safe from theft and the weather, while the antennas are placed high on a tower or building, clear of obstructions and able to deliver maximum performance. You can use either type of receiver in a permanent, semi-permanent, or daily quick setup configuration. If semi-permanent or permanent operation is required, however, the modular receiver delivers significant advantages. 28 SPSx80 Smart GPS Antenna User Guide 4 Setup Guidelines Base station setup guidelines For good performance, observe the following base station setup guidelines: • Place the GPS receiver in a location on the jobsite where equal range in all directions provides full coverage of the site. This is more important on larger jobsites, where the broadcast range of the base station radio may limit the operations of the GPS system. • Place the GPS antenna in a location that has a clear line of sight to the sky in all directions. Do not place the GPS antenna near vertical obstructions such as buildings, deep cuttings, site vehicles, towers, or tree canopy. • Place the GPS and radio antennas as high as practical. This minimizes multipath from the surrounding area, and enables the radio to broadcast to the maximum distance. Note – The GPS antenna must have a clear line of sight to the sky at all times during operation. • Choose the most appropriate radio antenna for the size and footprint of the site. The higher the gain on the antenna, the longer the range. If there is more focus on the transmission signal, there is a reduced coverage area. A 3 db or 5 db gain antenna provides a mix of good range and reasonable directional coverage. • Make sure that the GPS receiver does not lose power. The GPS receiver has an integrated battery, which has to be charged. To operate for the full day without loss of power at the base station, provide external power. Sources of external power include: – AC power – 12 V car or truck battery – Trimble custom external battery pack – Generator power – Solar panel When you use an external power supply, the integrated battery provides a backup power supply, enabling you to maintain continuous operation through a mains power failure. When the GPS receiver is connected to a power source greater than 15 V, the integrated battery is continuously charged from the connected power source. This helps to ensure that the battery stays charged (SPS770 and SPSx50 only). • Do not locate a GPS receiver, GPS antenna, or radio antenna within 400 meters (about 1312 feet) of: – a powerful radar, television, or cellular communications tower – another transmitter – another GPS antenna SPSx80 Smart GPS Antenna User Guide 29 4 Setup Guidelines Cellular phone towers can interfere with the base station radio broadcast and can stop corrections from reaching the rover receiver. High-power signals from a nearby radio or radar transmitter can overwhelm the receiver circuits. This does not harm the receiver, but can prevent the receiver electronics from functioning correctly. Low-power transmitters, such as those in cellular phones and two-way radios, do not interfere with receiver operations. • Do not set up the base station directly beneath or close to overhead power lines or electrical generation facilities. The electromagnetic fields associated with these utilities can interfere with GPS receiver operation. Other sources of electromagnetic interference include: – Gasoline engines (spark plugs) – Televisions and computer monitors – Alternators and generators – Electric motors – Equipment with DC-to-AC converters – Fluorescent lights – Switching power supplies • Place the GPS receivers in a protected and secure location. If the base station is in the center of a jobsite where heavy machinery is operating, place flags around the base station to warn operators of its existence. • If you place the SPSx50 Modular GPS receiver or SPS770 GPS receiver in a lock box on the jobsite to protect the receiver from theft or from the weather, shield the lock box from direct sunlight and provide ventilation for the receiver through an inlet and extractor fan. A receiver that has a broadcast radio generates significant heat. Do not allow the temperature in the box to exceed 65 ºC (149 ºF). If working in a cold climate, you may need to provide heat to the receiver. Do not operate the receiver below –40 ºC (–40 ºF). • 30 Trimble recommends that, wherever possible, you keep GPS receiver equipment dry. The receivers are designed to withstand wet weather, but keeping them dry prolongs their life and reduces the effects of corrosion on ports and connectors. If the equipment gets wet, use a clean dry cloth to dry the equipment, and then leave the equipment open to the air to dry. Do not lock wet equipment in a transport case for prolonged periods. Avoid exposing the GPS receiver to corrosive liquids and salt water wherever possible. SPSx80 Smart GPS Antenna User Guide Setup Guidelines • Trimble recommends that you install lightning protection equipment at permanent base station locations. Equipment should include a gas capsule lightning protector in the GPS and radio antenna feed line and appropriate safety grounding. A static dissipater near the antennas can reduce the likelihood of a direct lightning strike. Also protect any communications and power lines at building entry points. For more information, contact your local Trimble dealer, or go to the Huber and Suhner website (www.hubersuhnerinc.com). • Trimble recommends that you use surge protection equipment on all permanently installed equipment. Permanent installation antenna cabling for the SPSx50 Modular GPS receiver and SPS770 GPS receiver Many permanent base station installations have unique cabling requirements. Depending on the available infrastructure, you may need to mount the antenna a considerable distance from the receiver. The SPSx50 and SPS770 can withstand a loss of 12 dB between the GPS antenna and the receiver. The degree of loss in a coaxial cable depends on the frequency of the signal passing through it. Table 4.1 lists some common cable types and the maximum length you can use before an inline amplifier for GPS frequencies is required. Table 4.1 Maximum cable lengths Cable type Maximum length (for use without an inline amplifier) RG-214 30 m (100 ft) LMR-400 70 m (230 ft) LMR-500 85 m (280 ft) LMR-600 106 m (350 ft) Heliax LDF4/50 165 m (540 ft) Heliax LDF4.5/40 225 m (740 ft) Rover operation guidelines The second part of the RTK GPS system is the rover receiver. The rover receiver is mounted on a pole, vehicle, marine vessel, or in a backpack, and is moved between the points that require measurement or stakeout. The rover receiver is connected to a base station or to a source of RTK corrections such as a Virtual Reference Station (VRS) system. The connection is provided by an integrated radio, a SPSx80 Smart GPS Antenna User Guide 31 4 Setup Guidelines cellular modem in the controller, or through an external cellular phone that is connected to the receiver either by Bluetooth wireless technology or by means of a cable. The correction stream for some other positioning solutions, such as SBAS (WAAS/EGNOS, and MSAS) and the OmniSTAR XP or HP service1, is broadcast through geostationary satellites, and detected by the GPS antenna itself. No integrated radio or base station is required. Rover receiver components The rover receiver has the following components: • GPS receiver • GPS antenna • Optional integrated radio receiver and antenna for RTK operations • Optional items for the different mounting options (see below) In most rover applications, the receiver operates entirely from its own integrated battery unit. On a vehicle or on a marine vessel, however, an external power supply can be used. Use an external power supply if one is provided. The internal battery then acts as a uninterruptible power supply, covering any external power failures. Choose a rover receiver according to the needs of the job: • A Smart GPS antenna, such as the SPSx80, incorporates the GPS receiver, GPS antenna, power supply, and receive radio into a single compact unit. A Smart GPS antenna can be rapidly set up on a pole, vehicle, or backpack. This makes it easy to carry when you are measuring around the jobsite. • A Modular GPS receiver, such as the SPSx50, incorporates the GPS receiver, receive radio, and power supply into a single unit. The GPS antenna and, optionally, the receive radio antenna, is separate from the receiver. When you use a modular GPS receiver as a rover, you can use optimized components placed in the best locations for your application. For example: – A small, lightweight rover antenna can be mounted on a pole or backpack; placed in a high, inaccessible location on a marine vessel mast or cabin; or placed on a site vehicle roof or truck bed. – A rubber duck radio antenna, or an external radio antenna, can be mounted on a vehicle or vessel roof to provide maximum coverage. A Modular GPS receiver can be placed in a location that is both easily accessible and safe from theft and the weather. The antennas can be placed high on a vehicle or vessel roof, clear of obstructions and able to deliver maximum performance. 1. OmniSTAR is only available with the SPSx50 Modular GPS receiver. 32 SPSx80 Smart GPS Antenna User Guide 4 Setup Guidelines Rover receiver setup guidelines For good rover operation, observe the following setup guidelines: • Place the GPS antenna in a location that has a clear line of sight to the sky in all directions. Do not place the antenna near vertical obstructions such as buildings, deep cuttings, site vehicles, towers, or tree canopy. GPS rovers and the base station receive the same satellite signals from the same satellites: if you obscure the signals at times, the system will be unable to provide RTK Fixed positions. • Place the GPS and radio antennas as high as possible to minimize multipath from the surrounding area. The receiver must have a clear line of sight to the sky at all times during operation. • GPS satellites are constantly moving. Because you cannot measure at a specific location now does not mean that you will not be able to measure there later, when satellite coverage or location improves. Use GPS planning software to identify the daily best and worst satellite coverage times for your location, and then choose measurement times that coincide with optimal GPS performance. This is especially important when operating in the worst GPS locations. • The SPS770 Extreme, the SPS850 Extreme, and SPS880 Extreme can track the GPS L2C modernization signal. Additionally, the SPS850 Extreme and SPS880 Extreme can track the GPS L5 modernization signal and the GLONASS satellite constellation. These signals help you to get positions at the worst times of the day and in the worst GPS locations, but do not guarantee that you will. • To get a fixed position solution with centimeter accuracy, initialize the rover receiver. For initialization to take place, the receiver must track at least five satellites that the base station is also tracking. In a dual-satellite constellation operation, for example, GPS and GLONASS, the receiver must track at least six satellites. • To maintain a fixed position solution, the rover must continuously track at least four satellites that the base station is also tracking. In a dual-satellite constellation operation, for example, GPS and GLONASS, the receiver must track at least five satellites.The radio link between the base and rover receivers must also be maintained. • Loss of the satellite signals or loss of the radio link results in a loss of centimeter position accuracy. From Fixed, the receiver changes to Float or Autonomous mode: – In Float mode, the rover has connection to the base station through a radio, but has not yet initialized. – In Autonomous mode, the rover has lost radio contact with the base station receiver, and is working by itself with the available GPS signals. SPSx80 Smart GPS Antenna User Guide 33 4 Setup Guidelines • On a vehicle or marine vessel, place the GPS antenna in a location as free from shock and vibration as possible. For the modular receivers, a single magnetic mount is normally sufficient to hold the antenna in a suitable location, whereas for the larger smart antenna, a triple magnetic mount is normally recommended. Good alternatives include a 5/8" thread bolt in a suitable location on the roof bars, or a door-mounted pole bracket. CAUTION – The SPS880 Extreme is not suited to on-vehicle operation where it will be subject to heavy vibration, that is, operation in rough ungraded terrain. Use in these conditions can damage the SPS880 Extreme. • To mount the modular receiver on a pole, use two pole mounting brackets and a second tripod clip (P/N 571 204 300). See Figure 4.1. Figure 4.1 Rod mount for modular receiver To mount the modular receiver on a marine vessel, use the receiver bracket (P/N 56830-00). For marine moving base and heading applications, use the receiver bracket to mount two receivers together. 34 SPSx80 Smart GPS Antenna User Guide Setup Guidelines • Make sure that the rover receiver does not lose power. An SPSx50 is typically powered by its internal battery. You cannot change the battery, but the charge typically lasts for longer than a working day. The batteries in the SPSx80 can be changed when flat. (See Chapter 3, Batteries and Power). If you do not use the rover receiver very often, ensure that it is charged at least every three months. For vehicle operation or marine vessel operation, Trimble recommends that you use an external power source so that the internal battery can be saved for times when the receiver is being used off the vehicle or vessel. • Do not locate the receiver or antenna within 400 meters (1312 ft) of powerful radar, television, cellular communications tower, or other transmitters or GPS antennas. Low-power transmitters, such as those in cellular phones and two-way radios, normally do not interfere with receiver operations. Cellular towers can interfere with the radio and can interfere with GPS signals entering the receiver. High-power signals from a nearby radio or radar transmitter can overwhelm the receiver circuits. This does not harm the receiver, but it can prevent the receiver electronics from functioning correctly. • Do not use the rover receiver directly beneath or close to overhead power lines or electrical generation facilities. The electromagnetic fields associated with these utilities can interfere with GPS receiver operation. Other sources of electromagnetic interference include: – gasoline engines (spark plugs) – televisions and computer monitors – alternators and generators – electric motors – equipment with DC-to-AC converters – fluorescent lights – switching power supplies • Trimble recommends that, wherever possible, all GPS receiver equipment is protected from rain or water. Although, the receivers are designed to withstand all wet weather conditions, keeping the receivers dry prolongs the life of the equipment and reduces the effects of corrosion on ports and connectors. If the equipment gets wet, use a clean dry cloth to dry the equipment, and then leave the equipment open to the air to dry. Do not lock wet equipment in a transport case for prolonged periods. Wherever possible, avoid exposing the GPS receiver to corrosive liquids and salt water. • If you are using the rover receiver in open spaces, Trimble recommends that you stop work during electrical storms where the risk of lightning strike is high. • Where cables are involved, Trimble recommends that you use cable ties to secure the cables to the rod or other equipment to avoid inadvertent snagging while moving about the jobsite. Be careful not to kink, twist, or unnecessarily extend cables, and avoid trapping them in vehicle doors or windows. Damage to cables can reduce the performance of GPS equipment. SPSx80 Smart GPS Antenna User Guide 35 4 Setup Guidelines Internal radio setup for rover operations The internal radio of the SPS GPS receiver is delivered with the transmit (Tx) radio frequencies preprogrammed into the receiver. To add receive (Rx) radio frequencies to 450 MHz radios, use the WinFlash utility (see Appendix C, Adding Internal Radio Frequencies). Radio frequences cannot be added to the 900 MHz radios. Once the radio frequencies are configured, use the controller or receiver to select channel frequencies during base station or rover setup operations. Cellular modem and external radio Instead of the internal radio, you can use a cellular modem or an external radio as your data communications link. To connect a cellular modem to an SPSx80 Smart GPS antenna, you need the following: • SPSx80 Smart GPS antenna. • One of the following: – TSC2 controller with CompactFlash card cellular modem, for example, a Audiovox modem card – Cellular modem or a cellular phone that can transmit data • Serial (cellphone to DB9) cable (supplied with the cellular modem or phone). • Port 2 of the SPSx80 supports full RS-232 protocol, and should function properly with most cellular phone cables. Some cellular units may require custom cabling. Alternatively, the receiver also supports a cable-free Bluetooth connection with Bluetooth-enabled cell phones. For more information on using a cellular modem as a data link, refer to the SCS900 Site Controller Software Getting Started Guide and SCS900 Site Controller Software Office Guide. 36 SPSx80 Smart GPS Antenna User Guide CHAPTER Setting up the Receiver In this chapter: Connecting the receiver to external devices Common ways to set up a base station Common ways to set up a rover receiver In this chapter, recommendations for setting up the receiver as a base station or for rover operations are provided. The recommendations cover a variety of common use scenarios. Note – This chapter provides setup information for all the receivers in the SPS GPS receiver family. SPSx80 Smart GPS Antenna User Guide 37 5 Setting up the Receiver Connecting the receiver to external devices You can connect an SPSx80 to the following devices: • a Trimble controller running Trimble SCS900 Site Controller software • an external radio-modem Trimble controller with SCS900 Site Controller software To connect a Trimble controller that is running the SCS900 Site Controller software to an SPS GPS receiver, use Bluetooth wireless technology ( for all except the SPS770 GPS receiver) or a serial cable. Table 5.1 shows how to connect the cables for each combination of SPS GPS receiver and Trimble controller. Table 5.1 Connecting to a Trimble controller running the SCS900 Site Controller software Use this cable connector … and connect the Cable part number cable to … To connect a SPSx50 Modular GPS receiver to a … TSC2 DB9 TSC2 Lemo SPSx50 TCU 6-pin Hirose TCU Lemo SPSx50 TSCe™ Lemo TSCe 31288-xx Lemo SPSx50 This cable is available in different lengths. The -xx indicates the length of the cable, in meters. 4-pin Hirose ACU 44147 Lemo SPSx50 ACU 32960 53004007 To connect a SPS770 Modular GPS receiver to a … TSC2 DB9 Lemo (Port 1) SPS770 TCU 6-pin Hirose TCU Lemo (Port 1) SPS770 TSCe ACU TSC2 32960 53004007 Lemo TSCe 31288-xx Lemo (Port 1) SPS770 This cable is available in different lengths. The -xx indicates the length of the cable, in meters. 4-pin Hirose ACU 44147 Lemo SPS770 To connect a SPSx80 Smart GPS antenna to a … TSC2 TCU TSCe 38 DB9 TSC2 Lemo (Port 1) SPSx80 6-pin Hirose TCU Lemo (Port 1) SPSx80 Lemo TSCe 31288-xx Lemo (Port 1) SPSx80 This cable is available in different lengths. The -xx indicates the length of the cable, in meters. SPSx80 Smart GPS Antenna User Guide 32960 53004007 5 Setting up the Receiver Table 5.1 Connecting to a Trimble controller running the SCS900 Site Controller software (cont) ACU Use this cable connector … and connect the Cable part number cable to … 4-pin Hirose ACU Lemo SPSx80 44147 External radio-modems The most common data link for Real-Time Kinematic (RTK) operation is a radio. The SPSx80 is available with the following internal radios: • 410 – 430 MHz (Tx/Rx, Rx only, or Tx only) • 430 – 450 MHz (Tx/Rx, Rx only, or Tx only) • 450 – 470 MHz (Tx/Rx, Rx only, or Tx only) • 900 MHz (Rx only) Note – “Tx” indicates that the radio transmits corrections. “Rx” indicates that the receiver receives corrections. “Tx/Rx” indicates that the radio both transmits and receives corrections. If the SPSx80 does not have an internal transmit radio, or you want to connect to a higher powered external transmit radio or cellular modem, use the DB9 port, the Lemo port, or Bluetooth wireless technology. The SPS780 supports the following Trimble base radios: • TRIMMARK 3 • Trimble SNB900 • Trimble PDL450 • Trimble HPB450 The receiver also supports third-party transparent radios and third-party cellular modems. To use an external radio with the SPSx80, you need an external power source for the radio—except for the SNB900 radio, which contains an internal battery. To configure the radio modem separately, use the external radio’s configuration program, or display and keypad. SPSx80 Smart GPS Antenna User Guide 39 5 Setting up the Receiver Common ways to set up a base station You can set up a base station in different ways depending on the application, coverage area, degree of permanence versus mobility, and available infrastructure. Before you set up a base station, please read Chapter 4, Setup Guidelines. Setting up a base station for permanent or semi-permanent installation For construction applications, where machine and site positioning operations using GPS will be carried out over a long time (weeks, months, or years), ensure that you choose the base station location carefully. A semi-permanent or permanent base station helps to eliminate the types of error that can result from repeated daily setups, and ensures that you always use the GPS antenna at the exact original location. The requirement for a permanent base station setup increases as more receivers that use the base station as a source of corrections, increases the cost of any base station downtime. On the largest jobsites, and on those that remain operational for the longest time, a permanent or semi-permanent installation is a popular solution. An SPSx50 or SPS770 GPS receiver is typically used as the base station, located in a site office or trailer where it is easy to access (to check or configure), and where it is secure from theft and the weather. The GPS and radio antennas are normally mounted on a permanent structure on the roof of the building, where they are high and clear from obstructions and where the radio antenna can provide the maximum range of operation. The GPS antenna most commonly used is the Trimble Zephyr Geodetic™ Model 2. This antenna has a large ground plane that eliminates multipath, providing the best GPS performance at the base location. The antennas are connected to the receiver by high quality RF cables. The receiver is connected to a permanent power supply (mains or generator power). The internal battery of the receiver is always being charged, and acts as an uninterruptible power supply if there is a power failure. In some cases, the receiver may also be connected by an Ethernet cable to the Internet, so that it can be monitored and configured from a remote location, and can warn an administrator by e-mail or text message if there is a change to the configuration. In these situations, the receiver can transmit GPS RTK corrections to a remote radio or receiver over the Internet, for rebroadcast requirements, without using repeaters. 40 SPSx80 Smart GPS Antenna User Guide Setting up the Receiver Figure 5.1 SPSx50 receiver permanent installation Setting up a base station for daily site use: T-Bar For construction applications where a daily setup and takedown of equipment is required for security reasons, Trimble recommends that you use a T-Bar setup. The T-Bar consists of a post mounted in concrete (so it cannot move), which has a solid metal T-Bar mounted to it to provide lateral separation between the GPS antenna and radio antenna. The T piece of the T-Bar has a vertical rod at each end. Each end terminates in a 5/8"×11 thread to which the antennas can be mounted. Trimble recommends that one end is clearly marked GPS and the other end is clearly marked Radio so that at each daily setup, the GPS and radio antennas are mounted at the same location. Switching antennas by mistake introduces a position error in all resulting measurements. You can buy the parts you need to make a T-Bar from any reputable hardware store. Make certain that the T-Bar cannot rotate after construction. Rotation of the T-Bar can introduce a position error into all subsequent measurements. On the upright post, mount either a bracket (to which the GPS receiver can be mounted), or a well-ventilated lockbox (in which the GPS receiver itself can be secured). SPSx80 Smart GPS Antenna User Guide 41 5 Setting up the Receiver Each day, mount the GPS antenna on the GPS end of the T-Bar and the radio antenna on the Radio end of the T-Bar. Connect the antennas to the receiver using the appropriate cables.The receiver uses its own integrated battery, or an external 12 V battery through the 12 V crocodile clips cable that are provided with the receiver. If you choose to use AC power, remember that the heat generated by the charging process and the radio transmitter increases the need for good ventilation around the receiver. In such scenarios, an SPSx80 Smart GPS antenna is also often used. Simply mount the SPSx80 on the T-Bar, and optionally connect to an external battery or radio unit. Advantages Use of a T-Bar setup ensures that the base station is set up with exactly the same position and height every day. This helps eliminate the errors typically associated with daily tripod setup. For example, wrong antenna height, base not set up over the point, base set up in the wrong location. Radio GPS Figure 5.2 System set up on a T-bar showing an external radio antenna to gain longer range Setting up a mobile base station: Tripod and fixed height tripod If you are repeatedly moving between jobsites, or if you are visiting a jobsite for the first time before a T-Bar or similar setup can be established, Trimble recommends that you use either a tripod and tribrach setup, or a fixed height tripod. The fixed height tripod is quicker and easier to set up over a control point. Take great care to ensure that the GPS antenna is set up accurately over the control point, and that the GPS antenna height is measured accurately, in the right way (vertical or slope 42 SPSx80 Smart GPS Antenna User Guide 5 Setting up the Receiver height) to the right location on the antenna (base of antenna or to a specified location on the antenna). When you start the rover receiver, it is extremely important to check in, at one or more known locations, to check for possible position or height errors. Checking in at a known location is good practice and can avoid costly errors caused by a bad setup. Typically, the tripod and fixed height tripod methods do not give significant height clearance above the ground, and can reduce the range of operation caused by radio limitations. Tripod and tribrach setup In the tripod setup, the tripod is located over the control point, and the tribrach and tribrach adaptor is mounted on the tripod and centered over the point. 1. Mount the GPS antenna on the tribrach adaptor. – If you are using a SPSx80 Smart GPS antenna, use the 25 cm spacer rod provided with the SPSx80 base station accessory kit. This allows the radio antenna in the receiver to clear the head of the tripod. 2. Clip the GPS receiver to the tripod (SPSx50 and SPS770 only). 3. Connect the GPS antenna to the receiver using the appropriate cable (SPSx50 and SPS770 only). 4. If necessary, connect the GPS receiver to an external 12 V power supply. Use the crocodile clip cable or the Trimble custom power pack. SPSx50 with a low-gain “rubber duck” antenna Figure 5.3 SPSx50 with an external high-gain antenna SPSx80 with an internal 450 MHz TX radio Tripod and tribrach setup for the SPSx50 and the SPSx80 SPSx80 Smart GPS Antenna User Guide 43 5 Setting up the Receiver Fixed height tripod setup A fixed height tripod setup is similar to a tripod setup, but is simplified by the central leg of the tripod, that is placed directly on the control point. If the central leg is leveled accurately, the fixed height tripod is quick and easy to set up, and provides an accurate way to measure the true antenna height. 1. Set up the tripod over the control point. 2. Attach the GPS antenna to the head of the tripod. 3. If using an external high-gain radio antenna, mount the radio antenna to the radio antenna bracket that is attached to the head of the tripod (beneath the GPS antenna). See Figure 5.4. 4. If using the SPSx50 Modular GPS receiver, hook the receiver to the center leg of the tripod, using the tripod clip. 5. If using the SPSx80 Smart GPS antenna, you can mount the antenna using the 25 cm spacer rod (supplied with the SPSx80 Base Station Accessory kit) so that the radio antenna clears the head of the tripod. Radio antenna bracket SPSx50 with a low-gain “rubber duck” antenna Figure 5.4 44 SPSx50 with an external highgain radio antenna Fixed height tripod setup for the SPSx50 and SPSx80 SPSx80 Smart GPS Antenna User Guide SPSx80 with an internal 450 MHz TX radio on a fixed height tripod 5 Setting up the Receiver Common ways to set up a rover receiver You can set up a rover receiver in different ways depending on the application. The components that make up a rover receiver are: • GPS receiver • GPS antenna • controller/computer • rod mounting equipment, including a rod, receiver bracket, and controller bracket • vehicle mounting equipment, including a suction cup and ball joint, extension arm, controller bracket, magnetic antenna mount, and necessary cables. • backpack equipment, including backpack and antenna-mounting rod • marine vessel mounting equipment, including receiver bracket, cables, antenna, and radio antenna brackets. Setting up the rover receiver on a jobsite vehicle CAUTION – This following rover setup is suited only to offroad (jobsite) vehicle use. Do not use this method on a vehicle that is driven at speed or in traffic. 1. 2. Do one of the following, depending on your receiver: – SPSx50 or SPS770: Mount the GPS antenna for the receiver on the roof of the vehicle. Use a single magnetic mount or a 5/8"×11 thread bolt attached to the roof bars. Run the GPS antenna cable for the receiver into the vehicle either through a rubber grommet in the roof, or through the passenger door window, which needs to be left slightly open during operation. – SPSx80: Mount the receiver on the roof of the vehicle. Use a triple magnetic mount or a 5/8"×11 thread bolt attached to the roof bars. Place and secure the GPS receiver in a convenient location in the vehicle. The GPS receiver can be controlled through the controller connected using Bluetooth wireless technology (SPSx50 or SPSx80) or a cable connected to a port on the receiver (SPS770). The receiver needs to be accessed only to turn it on at the start of each measurement session. It may be more convenient if the SPSx50 is placed in a location where the vehicle operator can see the keypad and display, to monitor receiver status and to configure settings as required. Most receiver capability can be controlled using the SCS900 Site Controller software. 3. Attach the suction cup to the front windscreen, dashboard, or other convenient location in the vehicle, making sure that it does not obstruct the driver’s view. SPSx80 Smart GPS Antenna User Guide 45 5 Setting up the Receiver 4. Attach the RAM extension arm to the suction cup, and the controller bracket to the RAM extension arm. 5. Lock the controller into the controller bracket and then adjust the bracket until the controller is in the most convenient location. Make sure that the controller does not restrict visibility through the front windscreen during vehicle use. 6. Lock the brackets so that the controller is held securely. If required, connect either the GPS receiver or the controller to an in-vehicle power supply as needed. Figure 5.5 46 Configuring SPSx50 from the cab. A Zephyr Model 2 antenna is mounted on the roof SPSx80 Smart GPS Antenna User Guide Setting up the Receiver Setting up the rover receiver on a rod For rod-based operation, mount the SPSx50 Modular GPS receiver as follows: 1. Mount the two rod brackets on the rod. 2. Tighten the top bracket, making sure that it is at a convenient height for the receiver. 3. Place the receiver in the slot in the rod bracket, and secure with the tripod clip. 4. Move the lower rod bracket down until it is over the second tripod clip on the receiver, and then tighten the rod bracket onto the rod. The receiver is held in place between the two brackets. 5. Insert the controller into the controller bracket as shown opposite. 6. Use the 5/8" thread to attach the GPS antenna to the top of the rod. 7. Use the GPS antenna cable to connect GPS antenna to the receiver. For rod-based operation, mount the SPSx80 Smart GPS antenna as follows: 1. Mount the receiver on the top of the rod using the 5/8"×11 thread in the base of the SPSx80. 2. Insert the controller into the controller bracket. 3. The SPSx80 and controller communicates through Bluetooth wireless technology. However, if a cable is required, connect the cable between the controller and receiver (see Figure 5.6 through Figure 5.7). SPSx80 Smart GPS Antenna User Guide 47 5 Setting up the Receiver P/N 53002007 P/N 32960 Cabled connections Figure 5.6 Bluetooth connections Connections for a rover SPSx80 setup, a TSC2 or TCU controller, and a 450 Mhz base station P/N 53002007 <> P/N 312888-02 P/N 32960 Figure 5.7 P/N 46125-00 Cabled connections for an SPSx80 setup, a TSC2 or TCU controller, and a 900 Mhz base station (with external power) Setting up a rover receiver on a belt or in a backpack If you prefer to work free of the weight of a pole, you can mount the rover receiver on a belt (SPS770 or SPSx50 only) or carry it in/on a backpack (all receivers). When you wear the receiver on a belt, ensure that the display is always visible so that you can easily check the status of the receiver. If you carry the receiver in a backpack, use an external radio antenna mount to allow for optimal radio signal reception. If you use a low gain antenna mounted directly on the receiver in a backpack, it may affect the radio signal reception and reduce the likelihood of obtaining an RTK Fixed solution. 48 SPSx80 Smart GPS Antenna User Guide Setting up the Receiver SPSx80 Smart GPS Antenna User Guide 49 5 50 Setting up the Receiver SPSx80 Smart GPS Antenna User Guide CHAPTER Configuring the Receiver Settings In this chapter: You can configure the SPS GPS receiver family in a variety of ways. This chapter describes the different configuration methods, and explains when and why each method is used. Using the SCS900 Site Controller software to configure the base station, the rover, and the radios Configuring the receiver to log data for postprocessing The SPS770 and SPSx80 receivers have no controls for changing settings. To configure these receivers: Configuring the receiver in real time • In real time, use external software such as the HYDROpro™ software, or the GPS Configurator or WinFlash utility. • In an application file, use the Configuration Toolbox utility. Configuring the receiver using application files Creating and editing the configuration files that control the receiver The SCS900 Site Controller software is likely to be your main tool to set up and operate the receiver on a daily basis. All necessary field configurations are handled through the SCS900 software running on a TSC2 or TCU controller. For more information, refer to the Trimble SCS900 Site Controller Software Getting Started Guide or the Trimble SCS900 Site Controller Software Office Guide. The external software detailed in this chapter is primarily used to update the receiver firmware and to configure upgrades or radio channels. SPSx80 Smart GPS Antenna User Guide 51 6 Configuring the Receiver Settings Using the SCS900 Site Controller software to configure the base station, the rover, and the radios As part of a total system solution for construction applications, the SPS GPS receivers are operated by a TSCe, ACU, TCU, or TSC2 controller running the SCS900 Site Controller software. The SCS900 Site Controller software provides the tools to configure and start the GPS receiver in the modes used by the SCS900 system: Base Station, RTK Rover, DGPS Rover, OmniSTAR rover, SBAS Rover (using WAAS/EGNOS and MSAS). Wizards help you through the process and, where possible, assign suitable default operational parameters to the system. This eliminates the need for an operator to know how to configure the receiver with the right settings. The SCS900 Site Controller software manages: • the radio, whether internal or external • all cellular communications components, such as modems and cellphones • the use of the Bluetooth wireless technology The software also scans communication ports on the receiver to identify connected devices. If the software cannot automatically identify the connected component, for example, a GPS antenna, it offers options (often with graphics) to help you manually select the correct component. The SCS900 Site Controller software allows you to set operational tolerances and settings (such as those shown below), which must be achieved before measurements can be accepted. When outside of these tolerances, the SCS900 Site Controller software warns you through on-screen messages or indications, and the nonautomatic acceptance of recorded positions. To set operational tolerances, go to the the Settings menu in the SCS900 Site Controller software. Example 1: From the Sky Plot screen, press Ctrl+M to open this screen and change the angle below which the receiver will not track satellites 52 SPSx80 Smart GPS Antenna User Guide Example 2: Use the Sky Plot screen to set if the receiver will track GLONASS satellites Configuring the Receiver Settings Configuring the receiver to log data for postprocessing The SPS GPS receivers do not come equipped with the Data Logging option. The receivers can have this added either at the time of purchase, or at a later date as an option. With the Data Logging option enabled, the receiver has available memory that facilitates the collection of GPS observations over a period of time, and that can be used with GPS postprocessing software such as the Trimble Geomatics Office™ for the computation of control networks and baselines. Note – The SCS900 system does not support postprocessed applications. Trimble recommends that you use either the front panel keypad and display, the Web User Interface, or (SPS770, SPSx80 only) the GPS Configurator software to configure the receiver for postprocessed measurement sessions. Configuring the receiver in real time The SPS770 and SPSx80 receivers can be configured in real time by the GPS Configurator software. When you configure the receiver in real time, you use the software to specify which settings you want to change. When you apply the changes, the receiver settings change immediately. Any changes that you apply to the receiver are reflected in the current application file, which is always present in the receiver. The current application file always records the most recent configuration, so if you apply further changes (either in real time or using an application file) the current file is updated and there is no record of the changes that you applied originally. Configuring the receiver using application files An application file contains information for configuring a receiver. To configure a receiver using an application file, you need to create the application file, transfer it to the receiver and then apply the file’s settings. The GPS Configurator software does this automatically when you work with configuration files. Overview An application file is organized into records. Each record stores configuration information for a particular area of receiver operation. Application files can include the following records: • File Storage • General Controls • Serial Port Baud Rate/Format • Reference Position SPSx80 Smart GPS Antenna User Guide 53 6 Configuring the Receiver Settings • Logging Rate • SV Enable/Disable • Output Message • Antenna • Device Control • Static/Kinematic • Input Message An application file does not have to contain all of these records. When you apply an application file, any option that is not included in the records in the file remains at its current setting. For example, if you apply an application file that only specifies the elevation mask to use, all other settings remain as they were before the application file was applied. You can store up to twenty different application files in the receiver. You can apply an application file’s settings at the time it is transferred to the receiver, or at any time afterwards. Special application files The receiver has three special application files, which control important aspects of the receiver’s configuration. Default application file The default application file (Default.cfg) contains the original receiver configuration, and cannot be changed. This file configures the receiver after it is reset. You can reset the receiver by pressing E for at least 15 seconds, or by using the reset option in the GPS Configurator software. For more information, see Chapter 8, Default Settings. Although you cannot change or delete the default application file, you can use a power up application file to override any or all of the default settings. Current application file The current application file (Current.cfg) reflects the current receiver configuration. Whenever you change the receiver’s configuration, either in real time or by applying an application file, the current file changes to match the new configuration. You cannot delete the current file or change it directly, but every change to the receiver’s current configuration is applied to the current file as well. When you switch off the receiver then turn it on again, all the settings from the current application file are applied, so you do not lose any changes that you have made. The only exceptions are the following logging parameters: • 54 Logging rate SPSx80 Smart GPS Antenna User Guide 6 Configuring the Receiver Settings • Position rate • Elevation mask These parameters are always reset to the factory default values whenever the receiver is switched off. Power Up application file The power up application file (Power_up.cfg) is used to set the receiver to a specific configuration any time the unit is powered up. In this file, you can specify that the receiver is reset to defaults before the power up settings are applied. This ensures that restarting the receiver always resets it to factory defaults prior to applying the power up application file. Alternatively, you can specify that the power up settings are applied immediately after the current application file’s settings have been applied. Restarting the receiver results in a configuration that uses your default settings for the options you define in the power up file, but the current settings for all other options. By default, there is no power_up application file on the receiver. To use a power up application file, you must create and save a power_up application file in the GPS Configurator software. If you save this file to disk, the file is called power_up.cfg. The extension .cfg is used, by convention, to identify application files on the office computer. When you transfer this file to the receiver, the file is saved on the receiver as power_up, and becomes the new power up file. The power up file is the only special application file that you can overwrite or delete from the receiver. Applying application files An application file’s settings do not affect the receiver’s configuration until you apply the application file. You can do this at the same time that you save the file. Alternatively, you can save the file on the computer or in the receiver, then open it later and apply its settings. Storing application files You can store application files that you create in the GPS Configurator software on the receiver and on the computer. For example, each file can represent a different user sharing the same receiver, or a particular mode of operation. Saving application files on your computer as well as in your receiver is optional, but it is useful because: • it gives you a permanent copy of the settings you have sent to a receiver, for audit or your own reference. • you can use the same file to configure multiple receivers identically. • you can use an existing application file as a template to create other application files with similar settings. SPSx80 Smart GPS Antenna User Guide 55 6 Configuring the Receiver Settings Naming application files The application filename in the office computer and in the receiver are always the same. This makes it easier to recognize and keep track of your application files. When you change the name of the application file in the receiver, this changes the application filename on your computer. When you transfer an application file from the receiver and save it to the computer, the system renames the file to match the internal receiver file. However, if you use Windows Explorer, for example, to change the .cfg filename on the computer, this does not change the internal receiver filename. This means that the GPS receiver does not recognize the change to the filename on the computer. Creating and editing the configuration files that control the receiver The Configuration Toolbox software enables you to create and edit GPS receiver configuration files. The settings in these files control the operation of the GPS receiver. The GPS receiver configuration file can then be copied and sent to the receiver. You can also create a file, called an application file or appfile, (*.cfg), which contains all the receiver settings necessary for a particular job or application. Application files can be stored on both the receiver and computer. Multiple files can be maintained to represent multiple users sharing a device and/or multiple modes of operation. You can also save files to audit the operating settings of a receiver. For applications requiring real-time positions in any coordinate system other than WGS-84, you need the Configuration Toolbox software to define and transfer the necessary coordinate system and transformation parameters. A maximum of ten files can be stored in the receiver. This includes the files default.cfg and current.cfg, which always reside in the receiver. Note – If you use the SCS900 Site Controller software in the field, you do not need to use the Configuration Toolbox software to set up the transformation parameters. This is done through the Site Calibration process in the SCS900 software. Installing the Configuration Toolbox software You can install the Configuration Toolbox software from the Trimble SPS GPS Receiver CD that is shipped with your receiver, or download it from the Trimble website. The Configuration Toolbox software requires one serial port dedicated to receiver communications. Installing new versions of the Configuration Toolbox software updates the Coordinate System Library. If you have calibrated sites stored on your computer, save them as receiver configuration files. This ensures that the coordinate system information for particular sites are not overwritten. 56 SPSx80 Smart GPS Antenna User Guide 6 Configuring the Receiver Settings Installing new versions of the Configuration Toolbox software into a directory containing a previous version overwrites the older program and data files. By default, application files located in the root installation folder, C:\TOOLBOX, are moved to the APPFILE\ subfolder. The installation program creates the subfolders shown in Table 6.1 within the installation folder. Table 6.1 Subfolders within the installation folder Subfolder Description bin\ Contains the Configuration Toolbox executable file (ctoolbox.exe) and dynamic link libraries (*.dll). appfiles\ This is the preferred directory for storing application files. Existing application files from earlier versions of Configuration Toolbox are moved here during the installation. cseditor\ Contains the Coordinate System Editor executable file (cseditor.exe), dynamic link libraries (*.dll), and help files. geolib\ Contains the geodetic database files used by the Configuration Toolbox software and the Coordinate System Editor software. Configuring the receiver using the Configuration Toolbox software 1. Select Start / Programs / Trimble / Configuration Toolbox. 2. Select File / New / SPSx80 or SPS770. 3. Make the appropriate selections for your receiver settings. For more information, see the Help and the Configuration Toolbox User Guide. 4. To save the application file, select File / Save As. Make sure that you specify the same 8-character file name when you save the file both in the computer and on the receiver, as shown in the Configuration File dialog: SPSx80 Smart GPS Antenna User Guide 57 6 Configuring the Receiver Settings Transmitting the application file to the receiver 1. Connect the data/power cable (part number 32345) to the receiver and the computer. 2. Connect the O-shell Lemo connector to the receiver port. 3. Connect the female DB9 connector to the computer. 4. Connect the power leads of the data/power cable to the power supply. 5. To open the application file you require, select File / Open. 6. With the file open and the Configuration File dialog open, select Communications / Transmit File. A message appears when the application file is successfully transmitted. If an error occurs, select Communications / Transmit File again. This overrides any incompatibility in baud rates and enables successful communication. To check the successful transmission, close the Configuration File dialog and then select Communications / Get File. A list of all application files in the receiver appears. If you clicked Apply Immediately in the application file, the new file will be the current file. To change files, select the required file from the list and then select Communications / Activate File. 58 SPSx80 Smart GPS Antenna User Guide CHAPTER AutoBase Feature In this chapter: Setting Up a Base Station Best practice Antenna type Scenarios Scenario One: Base station setup on first visit to a site Scenario Two: Base station setup on a repeat visit to that site Scenario Three: The stored base station position seems to be missing Flowchart showing the AutoBase process The Trimble SPS880 Extreme Smart GPS antenna features AutoBase™ technology, which provides the following advantages: • Reduced risk of a setup that uses incorrect base station coordinates. • Reduced daily setup times for a mobile base station. When you use an SPS880 Extreme Smart GPS antenna as a base station receiver, you do not need to reconfigure the receiver at the start of each day. The AutoBase feature is a function of the version 3.x receiver firmware, which supports both GPS modernization (L2C and L5 signals) and GLONASS signals. You cannot turn off the AutoBase warning feature in the SPS880 Extreme Smart GPS antenna. Note – With the SPS880 Extreme Smart GPS antenna, always start a base station setup by using the SCS900 Site Controller software to initialize the SPS880 Extreme Smart GPS antenna on a new point. See page 60. Please read this chapter even if you have used the AutoBase feature in other Trimble receivers. New functions now provide even greater benefits. SPSx80 Smart GPS Antenna User Guide 59 7 AutoBase Feature Setting Up a Base Station The AutoBase feature influences how you set up an SPS880 Extreme Smart GPS antenna as a base station. Before the receiver can transmit RTK corrections (that is, operate as an RTK base station), the current position of the receiver must correspond to a previous base station position. The base station position—latitude, longitude, and height—must be part of the GPS site calibration. Note – There is no need to configure the base station receiver settings manually. 1. To perform the first base station setup at a new location, always use the SCS900 Site Controller software to initialize the SPS880 Extreme Smart GPS antenna on a new point. You generally do this only once, the first time that you occupy the point, but see the Caution below. When the base station setup is complete, the receiver generates and stores an application file that contains the parameters for that location. CAUTION – When you perform a future base station setup at the same location, the receiver assumes that there has been no change to either the antenna height or the antenna height measurement method used previously. It is therefore essential that you keep the antenna height constant between setups. If there is any risk that the antenna height might have changed, you must use the SCS900 Site Controller software to start (and so reset) the SPS880 Extreme Smart GPS antenna. From the SCS900 Site Controller software, select Start Base Station. 2. To perform a future base station setup at the same location, simply press the Power key on the receiver. The receiver turns on, determines its location, finds the appropriate application file, initializes the settings, and starts to broadcast RTK CMR+ corrections through the internal radio or through the external radio (whichever radio was used the previous time). If the receiver uses an external radio, such as an SNB900 radio, the AutoBase feature raises the Bluetooth® wireless connection to the radio. If a Bluetooth connection is not used, the AutoBase feature searches the receiver communications ports for the external radio. When the receiver finds the external radio, the receiver transmits RTK CMR+ corrections to the radio. Best practice After each new base station setup, and at the start of every measurement session, Trimble recommends that you measure one known point to verify that the position and height errors are within tolerance. The measurement takes only a few seconds, but can eliminate the gross errors typically associated with daily base station setup. Antenna type The selected antenna type determines which options are available for determining the antenna height. The AutoBase feature uses an antenna type of “R8 Model 2 /SPS880 Internal.” 60 SPSx80 Smart GPS Antenna User Guide 7 AutoBase Feature Scenarios These scenarios describe what you may experience when using AutoBase technology. Note – The AutoBase Warning feature is always turned on in an SPS880 Extreme Smart GPS antenna. Scenario One: Base station setup on first visit to a site • You set up the base station receiver on a point that you have not previously used as a base station with that receiver. 1. The receiver is powered on. 2. The receiver begins tracking satellites. 3. The receiver determines the current position. 4. The receiver reviews the base positions stored in the receiver. 5. The receiver does not find any base station that corresponds to the current position. 6. The receiver will not begin transmitting RTK corrections and the radio LED will not flash. No RTK corrections will be streamed until the base station is set up using the SCS900 Site Controller software. Scenario Two: Base station setup on a repeat visit to that site • You set up the base station receiver on a point that you have previously used as a base station with that receiver. 1. The receiver is powered on. 2. The receiver begins tracking satellites. 3. The receiver determines the current position. 4. The receiver reviews the base station positions stored in the receiver. 5. The receiver finds a base station position that corresponds to the current position. A base station position is found, so the AutoBase warning is not displayed. 6. The receiver loads the previous base information. 7. The antenna type, antenna height, and measurement method used in the previous setup of this base station are applied. SPSx80 Smart GPS Antenna User Guide 61 7 AutoBase Feature CAUTION – When you perform a future setup at the same location, the receiver assumes that there has been no change to either the antenna height or the antenna height measurement method used previously. It is therefore essential that you keep the antenna height constant between setups. If there is any risk that the antenna height might have changed, you must use the SCS900 Site Controller software to start (and so reset) the SPS880 Extreme Smart GPS antenna. From the SCS900 Site Controller software, select Start Base Station. 8. The receiver begins generating RTK CMR+ corrections. 9. The RTK corrections begin streaming on the radio or port defined in the previous setup of this base station. Scenario Three: The stored base station position seems to be missing • You set up the base station receiver on a point that you have previously used as a base station, as in Scenario Two. But for some reason, the stored base station position is not found in the receiver. Someone has inadvertently deleted the data, or perhaps a different receiver ( for example, the other receiver in a pair) was used on the previous occasion. 1. The base station receiver is set up on a point that you have previously used as a base station. 2. The receiver is powered on. 3. The receiver begins tracking satellites. 4. The receiver determines the current position. 5. The receiver reviews the base station positions stored in the receiver. 6. The receiver does not find any base station that corresponds to the current position. 7. The receiver will not begin transmitting RTK corrections and the radio LED will not flash. No RTK corrections will be streamed until you do one of the following things: 62 • Use the SCS900 Site Controller software to set up the base station. • Change to the receiver that was previously used as the base station at this location. SPSx80 Smart GPS Antenna User Guide AutoBase Feature Flowchart showing the AutoBase process Power on receiver Receiver looks for application files No Do application files exist? Yes AutoBase warning is displayed Use SCS900 to reset and restart the receiver or Change to the receiver that was previously used as the base station at this location No Any application file that corresponds with the current position? No Make corresponding application file active Figure 7.1 Yes Is there more than one acceptable application file? Yes Make most recent created application active AutoBase feature SPSx80 Smart GPS Antenna User Guide 63 7 64 AutoBase Feature SPSx80 Smart GPS Antenna User Guide CHAPTER Default Settings In this chapter: Default receiver settings Resetting the receiver to factory defaults Default behavior Power up settings Logging data All SPSx80 Smart GPS antenna settings are stored in application files. The default application file, Default.cfg, is stored permanently in the receiver, and contains the factory default settings for the SPSx80 Smart GPS antenna. Whenever the receiver is reset to its factory defaults, the current settings (stored in the current application file, Current.cfg) are reset to the values in the default application file. You cannot modify the default application file. However, you can create a power-up application file so that the settings in this file can be applied immediately after the default application file, overriding the factory defaults. For more information, see Configuring the receiver using application files, page 53. SPSx80 Smart GPS Antenna User Guide 65 8 Default Settings Default receiver settings These settings are defined in the default application file. Function Factory default SV Enable All SVs enabled General Controls: Serial Port 1: Serial Port 2: Input Setup: Elevation mask 13° PDOP mask RTK positioning mode Low Latency Motion Kinematic Baud rate 115,200 Format 8-None-1 Flow control None Baud rate 115,200 Format 8-None-1 Flow control None Station Any NMEA/ASCII (all supported messages) All ports Off Streamed output All Types Off Offset = 00 RT17/Binary All ports Off Reference position: Antenna: Latitude 0° Longitude 0° Altitude 0.00 m HAE Type Trimble SPS780, SPS880, Internal Height (true vertical) 0.00 m Group All Measurement method Bottom of mount Resetting the receiver to factory defaults To reset the receiver to its factory defaults, do one of the following: • On the receiver, press E for 15 seconds. • In the GPS Configurator software, select Connect to Receiver and then click Reset receiver in the General tab. • In the Configuration Toolbox software, select the General tab and then click Reset Receiver. Note – For more information on the GPS Configurator and Configuration Toolbox software which are supplied on the Trimble SPS GPS Receiver CD , see Chapter 6, Configuring the Receiver Settings. 66 SPSx80 Smart GPS Antenna User Guide 8 Default Settings Default behavior The factory defaults specified on page 66 are applied whenever you start the receiver. If a power up application file is present in the receiver, its settings are applied immediately after the default settings, so you can use a power up file to define your own set of defaults. The factory defaults are also applied when you perform a full reset of the receiver because resetting the receiver deletes the power up files. When starting any of the SPS GPS receivers as a base station or rover receiver using the Trimble SCS900 site controller software or the HYDROpro™ software, the settings as required for those operations are automatically set and configured in that software. To change the receiver settings for special applications or for use with third-party software, use the GPS Configurator software or the Configuration Toolbox software. Power up settings When you turn off the receiver, any changes that you have made to logging settings are lost and these settings are returned to the factory defaults. Other settings remain as defined in the current file. The next time you turn on the receiver, the receiver checks for a power up file and, if one is present, applies the settings in this file. Logging data Logging data with the SPS GPS receivers is available as an option. By default, the data logging option is turned off. For information on how to enable the data logging option, and the necessary postprocessing software options, please contact your Trimble dealer. Data logging using GPS receivers requires you to have access to suitable GPS postprocessing software such as Trimble Geomatics Office™ or Trimble Total Control™. Data logging involves the collection of GPS measurement data over a period of time at a static point or points, and subsequent postprocessing of the information to accurately compute baseline information. Postprocessed GPS data is typically used for control network measurement applications and precise monitoring. The following information only applies if you have the Data Logging options enabled in the receiver, and that you intend to carry out GPS postprocessed measurement operations. Logging data after a power loss If the receiver loses power unexpectedly, when power is restored the receiver tries to return to the state it was in immediately before the power loss. The receiver does not reset itself to default settings. If the receiver was logging data when power was lost unexpectedly, it resumes logging data when power is restored. SPSx80 Smart GPS Antenna User Guide 67 8 68 Default Settings SPSx80 Smart GPS Antenna User Guide CHAPTER Specifications In this chapter: General specifications Physical specifications Electrical specifications Communication specifications This chapter details the specifications for the SPSx80 Smart GPS antenna. Specifications are subject to change without notice. SPSx80 Smart GPS Antenna User Guide 69 9 Specifications General specifications Feature Specification Keyboard and display On/Off key for one button startup using AutoBase technology LED indicators For satellite tracking, radio link reception, and power monitoring Receiver type Fully integrated “Smart” GPS antenna Physical specifications Feature Specification Dimensions (LxWxH) 19 cm (7.5 in) x 10 cm (3.9 in) including connectors Weight 1.28 kg (2.88 lb) receiver only, with internal battery 3.70 kg (8.16 lbs) complete system weight, including controller and pole (when used as a rover) Temperature1 Operating Storage –40 °C to +65 °C (–40 °F to +149 °F) –40 °C to +75 °C (–40 °F to +167 °F) Humidity 100%, condensing Waterproof IP67 for submersion to depth of 1 m (3.28 ft) Shock and vibration Shock, non operating Tested and meets the following environmental standards: Designed to survive a 2 m (6.6 ft) pole drop onto concrete MIL-STD-810F, Fig.514.5C-17 To 40 G, 10 msec, saw-tooth MIL-STD-810F, FIG.514.5C-1 Shock, operating Vibration Measurements • • • • • • • • • • Code differential GPS positioning3 Horizontal accuracy Vertical accuracy 70 Advanced Trimble Maxwell™ Custom GPS chip High-precision multiple correlator for L1 and L2 pseudo-range measurements Unfiltered, unsmoothed pseudo range measurements data for low noise, low multipath error, low time domain correlation and high dynamic response Very low noise L1 and L22 carrier phase measurements with <1 mm precision in a 1 Hz bandwidth Proven Trimble low elevation tracking technology 24 Channels (SPS780 only) L1/L2 full cycle carrier (SPS780 only) L1 and L2 Signal-to-Noise ratios reported in dB-Hz 72 Channels L1/L2/L2C/L5 GPS and L1/L2 GLONASS (SPS880 Extreme only) WAAS / EGNOS support ±(0.25 m + 1 ppm) RMS, ± (9.84 in + 1 ppm) RMS ±(0.50 m + 1 ppm) RMS, ± (19.68 in + 1 ppm) RMS SPSx80 Smart GPS Antenna User Guide 9 Specifications Feature Specification WAAS differential positioning accuracy4 Typically <5 m (16.40 ft) 3D RMS Real Time Kinematic (RTK) positioning3 Horizontal Vertical Initialization time Regular RTK operation with base station RTK operation with Scalable GPS infrastructure Initialization reliability5 ±(10 mm + 1 ppm) RMS, ± (0.38 in +1 ppm) RMS ±(20 mm + 1 ppm) RMS, ± (0.78 in +1 ppm) RMS Single/Multi-base minimum 10 sec + 0.5 times baseline length in km, <30 km <30 seconds typical anywhere within coverage area (SPS780 Max and SPS880 Extreme only). Typically >99.9% Receiver will operate normally to –40 °C. Bluetooth module and internal batteries are rated to –20 °C. The availability of the L2C code GPS signal is dependent on the US government. Accuracy and reliability may be subject to anomalies such as multipath, obstructions, satellite geometry, and atmospheric conditions. Always follow recommended practices. Depends on WAAS/EGNOS system performance. May be affected by atmospheric conditions, signal multipath, and satellite geometry. Initialization reliability is continuously monitored to ensure highest quality Electrical specifications Feature Specification Power, internal 11 to 28 V DC external power input with over-voltage protection on Port 1 (7-pin Lemo) Battery Rechargeable, removable 7.4 V, 2.4 Ah Lithium-ion battery in internal battery compartment Power consumption <2.5 W, in RTK rover mode with internal radio Rover operation time on internal battery 450 MHz 900 MHz 5.5 hours; varies with temperature (Rx only) 5.5 hours; varies with temperature (Rx only) Base station operation times on internal battery 450 MHz 4.2 hours; varies with temperature (Tx/Rx) 900 MHz 5.5 hours; varies with temperature (External Tx radio) Certification Class B Part 15, 22, 24FCC certification Canada FCC CE mark approval C-tick approval WEEE SPSx80 Smart GPS Antenna User Guide 71 9 Specifications Communication specifications Feature Specification Communications Port 1 (7-pin 0S Lemo) Port 2 (DSub 9-pin) Bluetooth 3-wire RS-232 Full RS-232 Fully integrated, fully sealed 2.4 GHz Bluetooth1 Integrated radios Fully integrated, fully sealed internal 450 MHz, TX, RX, or Tx/Rx2 Fully integrated, fully sealed internal 900 MHz, Rx3 450 MHz transmitter radio power output 0.5 W External GSM/GPRS, cellular phone support Supported for direct dial and Internet-based VRS correction streams Cellular phone or GSM/GPRS modem inside TSC2 controller Receiver position update rate SPS780 Basic SPS780 Max SPS880 Extreme 1 Hz and 2 Hz positioning 1 Hz, 2 Hz, 5 Hz, and 10 Hz positioning 1 Hz, 2 Hz, 5 Hz, 10 Hz, and 20 Hz positioning Data Input and Output CMR, CMR+, RTCM 2.1, RTCM 2.2, RTCM 2.3, RTCM 3.0 Outputs NMEA, GSOF, and RT17 Carrier Supports BINEX and smoothed carrier (SPS880 Extreme only) Bluetooth type approvals are country specific. Contact your local Trimble office or representative for more information. 72 Tx only or Rx only with SPS780 Basic; Tx/Rx with SPS780 Max. 900 MHz is Rx only with SPS780, external transmit radio must be used when configured as a base. SPSx80 Smart GPS Antenna User Guide APPENDIX NMEA-0183 Output In this appendix: NMEA-0183 message overview Common message elements NMEA messages This appendix describes the formats of the subset of NMEA-0183 messages that are available for output by the receivers. For a copy of the NMEA-0183 Standard, go to the National Marine Electronics Association website at www.nmea.org. SPSx80 Smart GPS Antenna User Guide 73 A NMEA-0183 Output NMEA-0183 message overview When NMEA-0183 output is enabled, a subset of NMEA-0183 messages can be output to external instruments and equipment connected to the receiver serial ports. These NMEA-0183 messages let external devices use selected data collected or computed by the GPS receiver. All messages conform to the NMEA-0183 version 3.01 format. All begin with $ and end with a carriage return and a line feed. Data fields follow comma (,) delimiters and are variable in length. Null fields still follow comma (,) delimiters but contain no information. An asterisk (*) delimiter and checksum value follow the last field of data contained in an NMEA-0183 message. The checksum is the 8-bit exclusive of all characters in the message, including the commas between fields, but not including the $ and asterisk delimiters. The hexadecimal result is converted to two ASCII characters (0–9, A–F). The most significant character appears first. The following table summarizes the set of NMEA messages supported by the receiver, and shows the page that contains detailed information about each message. Message Function Page ADV Position and Satellite information for RTK network operations 76 GGA Time, position, and fix related data 77 GSA GPS DOP and active satellites 78 GST Position error statistics 79 GSV Number of SVs in view, PRN, elevation, azimuth, and SNR 80 HDT Heading from True North 81 PTNL,AVR Time, yaw, tilt, range, mode, PDOP, and number of SVs for Moving Baseline RTK 82 PTNL,GGK Time, position, position type and DOP values 83 PTNL,PJK Local coordinate position output 84 PTNL,VGK Time, locator vector, type and DOP values 85 PTNL,VHD Heading Information 86 RMC Position, Velocity, and Time 87 ROT Rate of turn 88 VTG Actual track made good and speed over ground 89 ZDA UTC day, month, and year, and local time zone offset 90 To enable or disable the output of individual NMEA messages, do one of the following: 74 • Create an application file in the GPS Configurator software that contains NMEA output settings and then send the file to the receiver. • Add NMEA outputs in the Serial outputs tab of the GPS Configurator software and then apply the settings. (You cannot use the GPS Configuration software to load application files to the SPSx50 Modular GPS receivers.) • For SPSx50 Modular GPS receivers, set up the NMEA output using the keypad and display or a web browser. SPSx80 Smart GPS Antenna User Guide NMEA-0183 Output Common message elements Each message contains: • a message ID consisting of $GP followed by the message type. For example, the message ID of the GGA message is $GPGGA. • a comma • a number of fields, depending on the message type, separated by commas • an asterisk • a checksum value Below is an example of a simple message with a message ID ($GPGGA), followed by 13 fields and a checksum value: $GPGGA,172814.0,3723.46587704,N,12202.26957864,W,2,6,1.2,18.893,M,25.669,M,2.0,0031*4F Message values NMEA messages that the receiver generates contains the following values. Latitude and longitude Latitude is represented as ddmm.mmmm and longitude is represented as dddmm.mmmm, where: • dd or ddd is degrees • mm.mmmm is minutes and decimal fractions of minutes Direction Direction (north, south, east, or west) is represented by a single character: N, S, E, or W. Time Time values are presented in Universal Time Coordinated (UTC) and are represented as hhmmss.cc, where: • hh is hours, from 00 through 23 • mm is minutes • ss is seconds • cc is hundredths of seconds NMEA messages When NMEA-0183 output is enabled, the following messages can be generated. SPSx80 Smart GPS Antenna User Guide 75 A NMEA-0183 Output ADV Position and Satellite information for RTK network operations An example of the ADV message string is shown below. Table A.1 and Table A.2 describe the message fields. The messages alternate between subtype 110 and 120. $PGPPADV,110,39.88113582,-105.07838455,1614.125*1M Table A.1 ADV subtype 110 message fields Field Meaning message ID $PPGPADV Message sub-type 110 Latitude Longitude Ellipsoid height Elevation of second satellite, in degrees, 90° maximum Azimuth of second satellite, degrees from True North, 000° through 359° The checksum data, always begins with * $PGPPADV,120,21,76.82,68.51,29,20.66,317.47,28,52.38,276.81,22,42.26,198.96*5D Table A.2 76 ADV subtype 120 message fields Field Meaning message ID $PPGPADV Message sub-type 120 First SV PRN number Elevation of first satellite, in degrees, 90° maximum Azimuth of first satellite, degrees from True North, 000° through 359° Second SV PRN number Elevation of second satellite, in degrees, 90° maximum Azimuth of second satellite, degrees from True North, 000° through 359° The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide A NMEA-0183 Output GGA Time, Position, and Fix Related Data An example of the GGA message string is shown below. Table A.3 describes the message fields. $GPGGA,172814.0,3723.46587704,N,12202.26957864,W, 2,6,1.2,18.893,M,-25.669,M,2.0,0031*4F Table A.3 GGA message fields Field Meaning message ID $GPGGA UTC of position fix Latitude Direction of latitude: N: North S: South Longitude Direction of longitude: E: East W: West GPS Quality indicator: 0: Fix not valid 1: GPS fix 2: Differential GPS fix 4: Real Time Kinematic, fixed integers 5: Real Time Kinematic, float integers Number of SVs in use, range from 00 through 12 HDOP Orthometric height (MSL reference) 10 M: unit of measure for orthometric height is meters 11 Geoid separation 12 M: geoid separation is measured in meters 13 Age of differential GPS data record, Type 1 or Type 9. Null field when DGPS is not used. 14 Reference station ID, ranging from 0000 through 1023. A null field when any reference station ID is selected and no corrections are received. 15 The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide 77 A NMEA-0183 Output GSA GPS DOP and active satellites An example of the GSA message string is shown below. Table A.4 describes the message fields. $GPGSA,<1>,<2>,<3>,<3>,,,,,<3>,<3>,<3>,<4>,<5>,<6>*<7> Table A.4 78 GSA message fields Field Meaning message ID $GPGSA Mode 1, M = manual, A = automatic Mode 2, Fix type, 1 = not available, 2 = 2D, 3 = 3D PRN number, 01 through 32, of satellite used in solution, up to 12 transmitted PDOP-Position dilution of precision, 0.5 through 99.9 HDOP-Horizontal dilution of precision, 0.5 through 99.9 VDOP-Vertical dilution of precision, 0.5 through 99.9 The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide NMEA-0183 Output GST Position Error Statistics An example of the GST message string is shown below. Table A.5 describes the message fields. $GPGST,172814.0,0.006,0.023,0.020,273.6,0.023,0.020,0.031*6A Table A.5 GST message fields Field Meaning message ID $GPGST UTC of position fix RMS value of the pseudorange residuals; includes carrier phase residuals during periods of RTK(float) and RTK(fixed) processing Error ellipse semi-major axis 1 sigma error, in meters Error ellipse semi-minor axis 1 sigma error, in meters Error ellipse orientation, degrees from true north Latitude 1 sigma error, in meters Longitude 1 sigma error, in meters Height 1 sigma error, in meters The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide 79 A NMEA-0183 Output GSV Satellite Information The GSV message string identifies the number of SVs in view, the PRN numbers, elevations, azimuths, and SNR values. An example of the GSV message string is shown below. Table A.6 describes the message fields. $GPGSV,4,1,13,02,02,213,,03,-3,000,,11,00,121,,14,13,172,05*67 Table A.6 80 GSV message fields Field Meaning message ID $GPGSV Total number of messages of this type in this cycle Message number Total number of SVs visible SV PRN number Elevation, in degrees, 90° maximum Azimuth, degrees from True North, 000° through 359° SNR, 00–99 dB (null when not tracking) 8–11 Information about second SV, same format as fields 4 through 7 12–15 Information about third SV, same format as fields 4 through 7 16–19 Information about fourth SV, same format as fields 4 through 7 20 The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide NMEA-0183 Output HDT Heading from True North The HDT string is shown below, and Table A.7 describes the message fields. $GPHDT,123.456,T*00 Table A.7 Field Heading from true north fields Meaning message ID $GPHDT Heading in degrees T: Indicates heading relative to True North The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide 81 A NMEA-0183 Output PTNL,AVR Time, Yaw, Tilt, Range for Moving Baseline RTK The PTNL,AVR message string is shown below, and Table A.8 describes the message fields. $PTNL,AVR,181059.6,+149.4688,Yaw,+0.0134,Tilt,,,60.191,3,2.5,6*00 Table A.8 82 AVR message fields Field Meaning message ID $PTNL,AVR UTC of vector fix Yaw angle in degrees Yaw Tilt angle in degrees Tilt Reserved Reserved Range in meters GPS quality indicator: 0: Fix not available or invalid 1: Autonomous GPS fix 2: Differential carrier phase solution RTK (Float) 3: Differential carrier phase solution RTK (Fix) 4: Differential code-based solution, DGPS 10 PDOP 11 Number of satellites used in solution 12 The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide NMEA-0183 Output PTNL,GGK Time, Position, Position Type, DOP An example of the PTNL,GGK message string is shown below. Table A.9 describes the message fields. $PTNL,GGK,172814.00,071296,3723.46587704,N,12202.26957864,W,3,06,1.7,EHT6.777,M*48 Table A.9 PTNL,GGK message fields Field Meaning message ID $PTNL,GGA UTC of position fix Date Latitude Direction of latitude: N: North S: South Longitude Direction of Longitude: E: East W: West GPS Quality indicator: 0: Fix not available or invalid 1: Autonomous GPS fix 2: Differential, floating carrier phase integer-based solution, RTK(float) 3: Differential, fixed carrier phase integer-based solution, RTK(fixed) 4: Differential, code phase only solution (DGPS). Also, OmniSTAR XP/HP converging 5: SBAS solution – WAAS, EGNOS 6: RTK Float 3D in a VRS/Network. Also OmniSTAR XP/HP converged 7: RTK Fixed 3D in a VRS/Network 8: RTK Float 2D in a VRS/Network Number of satellites in fix DOP of fix 10 Ellipsoidal height of fix 11 M: ellipsoidal height is measured in meters 12 The checksum data, always begins with * Note – The PTNL,GGK message is longer than the NMEA-0183 standard of 80 characters. SPSx80 Smart GPS Antenna User Guide 83 A NMEA-0183 Output PTNL,PJK Local Coordinate Position Output An example of the PTNL,PJK message string is shown below. Table A.10 describes the message fields. $PTNL,PJK,010717.00,081796,+732646.511,N,+1731051.091,E,1,05,2.7,EHT28.345,M*7C Table A.10 PTNL,PJK message fields Field Meaning message ID $PTNL,PJK UTC of position fix Date Northing, in meters Direction of Northing will always be N (North) Easting, in meters Direction of Easting will always be E (East) GPS Quality indicator: 0: Fix not available or invalid 1: Autonomous GPS fix 2: Differential, floating carrier phase integer-based solution, RTK(float) 3: Differential, fixed carrier phase integer-based solution, RTK(fixed) 4: Differential, code phase only solution (DGPS). Also, OmniSTAR XP/HP converging 5: SBAS solution – WAAS, EGNOS 6: RTK Float 3D in a VRS/Network. Also OmniSTAR XP/HP converged 7: RTK Fixed 3D in a VRS/Network 8: RTK Float 2D in a VRS/Network Number of satellites in fix DOP of fix 10 Ellipsoidal height of fix 11 M: ellipsoidal height is measured in meters 12 The checksum data, always begins with * Note – The PTNL,PJK message is longer than the NMEA-0183 standard of 80 characters. 84 SPSx80 Smart GPS Antenna User Guide NMEA-0183 Output PTNL,VGK Vector Information An example of the PTNL,VGK message string is shown below. Table A.11 describes the message fields. $PTNL,VGK,160159.00,010997,-0000.161,00009.985,-0000.002,3,07,1,4,M*0B Table A.11 PTNL,VGK message fields Field Meaning message ID $PTNL,VGK UTC of vector in hhmmss.ss format Date in mmddyy format East component of vector, in meters North component of vector, in meters Up component of vector, in meters GPS Quality indicator: 0: Fix not available or invalid 1: Autonomous GPS fix 2: Differential, floating carrier phase integer-based solution, RTK(float) 3: Differential, fixed carrier phase integer-based solution, RTK(fixed) 4: Differential, code phase only solution (DGPS). Also, OmniSTAR XP/HP converging 5: SBAS solution – WAAS, EGNOS 6: RTK Float 3D in a VRS/Network. Also OmniSTAR XP/HP converged 7: RTK Fixed 3D in a VRS/Network 8: RTK Float 2D in a VRS/Network Number of satellites if fix solution DOP of fix M: Vector components are in meters 10 The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide 85 A NMEA-0183 Output PTNL,VHD Heading Information An example of the PTNL,VHD message string is shown below. Table A.12 describes the message fields. $PTNL,VHD,030556.00,093098,187.718,-22.138,-76.929,5.015,0.033,0.006,3,07,2.4,M*22 Table A.12 86 PTNL,VHD message fields Field Meaning message ID $PTNL,VHD UTC of position in hhmmss.ss format Date in mmddyy format Azimuth ΔAzimuth/ΔTime Vertical Angle ΔVertical/ΔTime Range ΔRange/ΔTime GPS Quality indicator: 0: Fix not available or invalid 1: Autonomous GPS fix 2: Differential, floating carrier phase integer-based solution, RTK(float) 3: Differential, fixed carrier phase integer-based solution, RTK(fixed) 4: Differential, code phase only solution (DGPS). Also, OmniSTAR XP/HP converging 5: SBAS solution – WAAS, EGNOS 6: RTK Float 3D in a VRS/Network. Also OmniSTAR XP/HP converged 7: RTK Fixed 3D in a VRS/Network 8: RTK Float 2D in a VRS/Network 10 Number of satellites used in solution 11 PDOP 12 The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide NMEA-0183 Output RMC Position, Velocity, and Time The RMC string is shown below, and Table A.13 describes the message fields. $GPRMC,123519,A,4807.038,N,01131.000,E,022.4,084.4,230394,003.1,W*6A Table A.13 Field GPRMC message fields Meaning message ID $GPRMC UTC of position fix Status A=active or V=void Latitude Longitude Speed over the ground in knots Track angle in degrees (True) Date Magnetic variation in degrees The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide 87 A NMEA-0183 Output ROT Rate and Direction of Turn The ROT string is shown below, and Table A.14 describes the message fields. $GPROT,35.6,A*4E Table A.14 88 ROT message fields Field Meaning message ID $GPROT Rate of turn, degrees/minutes, "–" indicates bow turns to port A: V: The checksum data, always begins with * Valid data Invalid data SPSx80 Smart GPS Antenna User Guide NMEA-0183 Output VTG Track Made Good and Speed Over Ground An example of the VTG message string is shown below. Table A.15 describes the message fields. $GPVTG,,T,,M,0.00,N,0.00,K*4E Table A.15 VTG message fields Field Meaning message ID $GPVTG Track made good (degrees true) T: track made good is relative to true north Track made good (degrees magnetic) M: track made good is relative to magnetic north Speed, in knots N: speed is measured in knots Speed over ground in kilometers/hour (kph) K: speed over ground is measured in kph The checksum data, always begins with * SPSx80 Smart GPS Antenna User Guide 89 A NMEA-0183 Output ZDA UTC Day, Month, And Year, and Local Time Zone Offset An example of the ZDA message string is shown below. Table A.16 describes the message fields. $GPZDA,172809,12,07,1996,00,00*45 Table A.16 ZDA message fields Field Meaning message ID $GPZDA UTC Day, ranging between 01 and 31 Month, ranging between 01 and 12 Year Local time zone offset from GMT, ranging from 00 through ±13 hours Local time zone offset from GMT, ranging from 00 through 59 minutes The checksum data, always begins with * Fields 5 and 6 together yield the total offset. For example, if field 5 is –5 and field 6 is +15, local time is 5 hours and 15 minutes earlier than GMT. 90 SPSx80 Smart GPS Antenna User Guide APPENDIX GSOF Messages In this appendix: Supported message types GSOF message definitions This appendix provides information on the General Serial Output Format (GSOF) messages that the SPS GPS receivers support. GSOF messages are a Trimble proprietary format and can be used to send information such as position and status to a third-party device. For information on how to output GSOF messages from the SPSx50 Modular GPS receiver, refer to Chapter 6, Configuring the SPSx50 Using the Keypad and Display and Chapter 7, Configuring the Receiver Settings in the SPSx50 Modular GPS Receiver User Guide. SPSx80 Smart GPS Antenna User Guide 91 B GSOF Messages Supported message types This table summarizes the GSOF messages that are supported by the receiver, and shows the page that contains detailed information about each message. Message Description Page TIME Position time 92 LLH Latitude, longitude, height 93 ECEF Earth-Centered, Earth-Fixed position 93 ECEF DELTA Earth-Centered, Earth-Fixed Delta position 94 NEU DELTA Tangent Plane Delta 94 Velocity Velocity data 95 PDOP PDOP info 95 SIGMA Position Sigma info 95 SV Brief SV Brief info 96 SV Detail SV Detailed info 97 UTC Current UTC time 98 BATT/MEM Receiver battery and memory status 98 ATTITUDE Attitude info 99 GSOF message definitions When GSOF output is enabled, the following messages can be generated. TIME This message describes position time information. It contains the following data: Table B.1 92 • GPS time, in milliseconds of GPS week • GPS week number • Number of satellites used • Initialization counter Time (Type 1 record) Field Item Type Value Meaning Output record type Char 01h Position time output record Record length Char 0Ah Bytes in record 2–5 GPS time (ms) Long msecs GPS time, in milliseconds of GPS week 6–7 GPS week number Short number GPS week count since January 1980 Number of SVs used Char 00h-0Ch Number of satellites used to determine the position (0-12) Position flags 1 Char See Table B.14 Reports first set of position attribute flag values SPSx80 Smart GPS Antenna User Guide B GSOF Messages Table B.1 Time (Type 1 record) Field Item Type Value Meaning 10 Position flags 2 Char See Table B.15 Reports second set of position attribute flag values 11 Initialized number Char 00h-FFh Increments with each initialization (modulo 256) LLH This message describes latitude, longitude, and height. It contains the following data: Table B.2 • WGS-84 latitude and longitude, in radians • WGS-84 height, in meters Latitude, longitude, height (Type 2 record) Field Item Type Value Meaning Output record type Char 02h Latitude, longitude, and height output record Record length Char 18h 2–9 Latitude Double Radians Latitude from WGS-84 datum 10–17 Longitude Double Radians Longitude from WGS-84 datum 18–25 Height Double Meters Height from WGS-84 datum Bytes in record ECEF This message describes the ECEF position. It contains the following data: • Table B.3 Earth-Centered, Earth-Fixed X, Y, Z coordinates, in meters ECEF position (Type 3 record) Field Item Type Value Meaning Output record type Char 03h Earth-Centered, Earth-Fixed (ECEF) position output record Record length Char 18h Bytes in record 2–9 Double Meters WGS-84 ECEF X-axis coordinate 10–17 Double Meters WGS-84 ECEF Y-axis coordinate 18–25 Double Meters WGS-84 ECEF Z-axis coordinate SPSx80 Smart GPS Antenna User Guide 93 B GSOF Messages ECEF DELTA This message describes the ECEF Delta position. It contains the following data: • Table B.4 Field Earth-Centered, Earth-Fixed X, Y, Z deltas between the rover and base position, in meters. ECEF Delta (Type 6 record) Item Type Value Meaning Output record type Char 06h Earth-Centered, Earth-Fixed (ECEF) Delta output record Record length Char 18h Bytes in record 2–9 Delta X Double Meters ECEF X-axis delta between rover and base station positions 10–17 Delta Y Double Meters ECEF Y-axis delta between rover and base station positions 18–25 Delta Z Double Meters ECEF Z-axis delta between rover and base station positions NEU DELTA This message contains Tangent Plane Delta information. It contains the following data: • North, East, and Up deltas of the vector from the base to the rover (in meters) projected onto a plane tangent to the WGS-84 ellipsoid at the base receiver. Note – These records are only output if a valid DGPS/RTK solution is computed. Table B.5 94 NEU Delta (Type 7 record) Field Item Type Value Meaning Output record type Char 07h Tangent Plane Delta output record Record length Char 18h Bytes in record 2–9 Delta east Double meters East component of vector from base station to rover, projected onto a plane tangent to the WGS-84 ellipsoid at the base station 10–17 Delta north Double meters North component of tangent plane vector 18–25 Delta up Double meters Difference between ellipsoidal height of tangent plane at base station and a parallel plane passing through rover point SPSx80 Smart GPS Antenna User Guide GSOF Messages Velocity This message provides velocity information. It contains the following data: Table B.6 • Horizontal velocity, in meters per second • Vertical velocity, in meters per second • Heading, in radians, referenced to WGS-84 True North Velocity (Type 8 record) Field Item Type Value Meaning Output record type Char 08h Velocity data output record Record length Char 0Dh Bytes in record Velocity flags Char See Table B.17 Velocity status flags 3–6 Speed Float Meters per second Horizontal speed 7–10 Heading Float Radians True north heading in the WGS-84 datum 11–14 Vertical velocity Float Meters per second Vertical velocity PDOP This message describes the PDOP information. It contains the following data: Table B.7 • PDOP • HDOP • VDOP • TDOP PDOP (Type 9 record) Field Item Value Meaning Output record type Char Type 09h PDOP information output record Record length 10h Bytes in record Char 2–5 PDOP Float Positional Dilution of Precision 6–9 HDOP Float Horizontal Dilution of Precision 10–13 VDOP Float Vertical Dilution of Precision 14–17 TDOP Float Time Dilution of Precision SIGMA This message describes the Position Sigma information. It contains the following data: • Position RMS • Sigma east, in meters • Sigma north, in meters • Sigma up, in meters SPSx80 Smart GPS Antenna User Guide 95 B GSOF Messages Table B.8 Field • Covariance east-north • Error Ellipse Semi-major axis, in meters • Error Ellipse Semi-minor axis, in meters • Orientation of Semi-major axis in degrees from True North • Unit variance • Number of epochs Sigma (Type 12 record) Item Type Value Meaning Output record type Char 0Ch Position sigma information output record Record length Char 26h Bytes in record 2–5 Position RMS Float 6–9 Sigma east Float Meters 10–13 Sigma north Float Meters 14–17 Covar. east-north Float number 18–21 Sigma up Float Meters 22–25 Semi-major axis Float Meters Semi-major axis of error ellipse 26–29 Semi-minor axis Float Meters Semi-minor axis of error ellipse 30–33 Orientation Float degrees Orientation of semi-minor axis, clockwise from True North 34–37 Unit variance Float 30–39 Number of epochs short Root means square of position error calculated for overdetermined positions Covariance east-north (dimensionless) Valid only for over-determined solutions. Unit variance should approach 1.0 value. A value of less than 1.0 indicates that apriori variances are too pessimistic. count Number of measurement epochs used to compute the position. Could be greater than 1 for positions subjected to static constraint. Always 1 for kinematic. SV Brief This message provides brief satellite information. It contains the following data: Table B.9 • Number of satellites tracked • The PRN number of each satellite • Flags indicating satellite status SV brief (Type 13 record) Field Item 96 Type Output record type Char Record length Char Number of SVs Char SPSx80 Smart GPS Antenna User Guide Value Meaning 0Dh Brief satellite information output record Bytes in record 00h-18h Number of satellites included in record1 GSOF Messages Table B.9 SV brief (Type 13 record) Field Item Type Value Meaning The following bytes are repeated for Number of SVs PRN Char 01h-20h Pseudorandom number of satellites (1-32) SV Flags1 Char See Table B.18 First set of satellite status bits SV Flags2 Char See Table B.19 Second set of satellite status bits Includes all tracked satellites, all satellites used in the position solution, and all satellites in view. SV Detail This message provides detailed satellite information. It contains the following data: Table B.10 • Number of satellites tracked • The PRN number of each satellite • Flags indicating satellite status • Elevation above horizon, in degrees • Azimuth from True North, in degrees • Signal-to-noise ratio (SNR) of L1 signal • Signal-to-noise ratio (SNR) of L2 signal SV detail (Type 14 record) Field Item Type Value Meaning Output record type Char 0Eh Detailed satellite information output record Record length Char 1 + 8×(number of SVs) Bytes in record 2–9 Number of SVs Char 00h-18h Number of satellites included in record1 The following bytes are repeated for Number of SVs PRN Char 01h-20h Pseudorandom number of satellites (1–32) Flags1 Char See Table B.18 First set of satellite status bits Flags2 Char See Table B.19 Second set of satellite status bits Elevation Char Degrees Angle of satellite above the horizon Azimuth Short Degrees Azimuth of satellite from True North SNR L1 Char dB * 4 Signal-to-noise ratio of L1 signal (multiplied by 4)2 SNR L2 Char dB * 4 Signal-to-noise ratio of L2 signal (multiplied by 4)2 Includes all tracked satellites, all satellites used in the position solution, and all satellites in view. THe SNR L1 and SNR L2 items are set to zero for satellites that are not tracked on the current frequency. SPSx80 Smart GPS Antenna User Guide 97 B GSOF Messages UTC This message describes current time information. It contains the following data: Table B.11 • GPS time, in milliseconds of GPS week • GPS week number • GPS to UTC time offset, in seconds UTC (Type 16 record) Field Item Type Value Meaning Output record type Char 10h Record length Char 09h Bytes in record 2–5 GPS millisecond of week Long msecs Time when packet is sent from the receiver, in GPS milliseconds of week 6–7 GPS week number Short number Week number since start of GPS time 8–9 UTC offset Short seconds GPS to UTC time offset 10 Flags Char See Table B.16 Flag bits indicating validity of Time and UTC offsets Batt/Mem This message provides information relating to the receiver battery and memory. It contains the following data: Table B.12 98 • Remaining battery power • Remaining memory Batt/Mem (Type 37 record) Field Item Type Output record type Char 25h Record length Char 0Ah 2–3 Battery capacity Unsigned short percentage 4–11 Remaining memory Double SPSx80 Smart GPS Antenna User Guide Value hours Meaning Bytes in record Remaining battery capacity in percentage Estimated remaining data logging time in hours B GSOF Messages Attitude This message provides attitude information relating to the vector between the Heading antenna and the Moving Base antenna. It contains the following data: Table B.13 Field • Tilt or vertical angle, in radians, from the Heading antenna to the Moving Base antenna relative to a horizontal plane through the Heading antenna • Heading or yaw, in radians, relative to True North • Range or slope distance between the Heading antenna and the Moving Base antenna Attitude (Type 27 record) Item Type Value Meaning Output record type Char 1Bh Attitude information Record length Char 2Ah Bytes in record 2–5 GPS time Long msecs GPS time in milliseconds of GPS week Flags Char See Table B.20 Flag bits indicating validity of attitude components Number of SVs used Char 00h-0Ch Calculation mode Char See Table B.21 Positioning mode Reserved 10–17 Tilt Double radians Tilt relative to horizontal plane 18–25 Yaw Double radians Rotation about the vertical axis relative to True North 26–33 Reserved Number of satellites used to calculate attitude Reserved Reserved 34–41 Range Double meters Distance between antennas 42–43 PDOP Short Position Dilution of Precision 0.1 SPSx80 Smart GPS Antenna User Guide 99 B GSOF Messages Flags Table B.14 Bit Meaning New position 0: No. 1: Yes. Clock fix calculated for current position 0: No. 1: Yes. Horizontal coordinates calculated this position 0: No. 1: Yes. Height calculated this position 0: No. 1: Yes. Weighted position 0: No. 1: Yes. Overdetermined position 0: No. 1: Yes. Ionosphere-free position 0: No. 1: Yes. Position uses filtered L1 pseudoranges 0: No. 1: Yes. Table B.15 1 00 Position flags 1: bit values Position flags 2: bit values Bit Meaning Differential position 0: No. 1: Yes. Differential position method 0: RTCM (Code) 1: RTK, OmniSTAR HP (Phase) Differential position method 0: Differential position is code (RTCM) or a float position (RTK) 1: Differential position is a fixed integer phase position (RTK if Bit-0 = 1, WAAS if Bit-0=0) OmniSTAR HP 0: Not active 1: OmniSTAR HP differential solution Position determined with static as a constant 0: No. 1: Yes. Position is network RTK solution 0: No. 1: Yes. 6–7 Reserved (set to zero) SPSx80 Smart GPS Antenna User Guide GSOF Messages Table B.16 Flags: Bit values Bit Meaning Time information (week and millisecond of week) validity 0: Not valid 1: Valid UTC offset validity 0: Not valid 1: Valid Table B.17 Velocity flags: Bit values Bit Meaning Velocity data validity 0: Not valid 1: Valid Velocity computation 0: Computed from doppler 1: Computed from consecutive measurements 2–7 Reserved (set to zero) Table B.18 SV flags: 1 bit values Bit Meaning Satellite Above Horizon 0: No. 1: Yes. Satellite Currently Assigned to a Channel (trying to track) 0: No. 1: Yes. Satellite Currently Tracked on L1 Frequency 0: No. 1: Yes. Satellite Currently Tracked on L2 Frequency 0: No. 1: Yes. Satellite Reported at Base on L1 Frequency 0: No. 1: Yes. Satellite Reported at Base on L2 Frequency 0: No. 1: Yes. Satellite Used in Position 0: No. 1: Yes. Satellite Used in Current RTK Process (Search, Propagate, Fix Solution) 0: No. 1: Yes. Table B.19 SV flags: 2 bit value Bit Meaning Satellite Tracking P-Code on L1 Band 0: No. 1: Yes. Satellite Tracking P-Code on L2 Band 0: No. 1: Yes. 2–7 Reserved. Set to zero. SPSx80 Smart GPS Antenna User Guide 101 B GSOF Messages Table B.20 Attitude flags Bit Meaning Calibrated 0: No. 1: Yes. Tilt valid 0: No. 1: Yes. Yaw valid 0: No. 1: Yes. Reserved Range valid 0: No. 1: Yes. 5–7 Reserved Data collector report structure Table B.21 Bit Meaning 0: No position 1: Autonomous position 2: RTK/Float position 3: RTK/Fix position 4: DGPS position Table B.22 Report packet 40h structure Byte Item Type Value Meaning STX CHAR 02h Start transmission. STATUS CHAR See Table B.23 Receiver status code. PACKET TYPE CHAR 40h Report Packet 40h. LENGTH CHAR 00h–FAh Data byte count. TRANSMISSION NUMBER CHAR PAGE INDEX CHAR 00h–FFh Index of current packet page. MAX PAGE INDEX CHAR 00h–FFh Maximum index of last packet in one group of records. Table B.23 1 02 Attitude calculation flags Unique number assigned to a group of record packet pages. Prevents page mismatches when multiple sets of record packets exist in output stream. Receiver Status code Byte number Message Description Bit 0 Reserved Bit 1 Low battery Bit 2–7 0–63 Reserved SPSx80 Smart GPS Antenna User Guide APPENDIX Adding Internal Radio Frequencies In this appendix: Adding receive frequencies for the 450 MHz internal radio If you have installed the optional internal 450 MHz radio in your GPS receiver, use the WinFlash utility to add the relevant receive frequencies to the default list of frequencies. To install the WinFlash utility, see Installing the WinFlash utility, page 140. If you have also purchased the transmit option (SPSx50 and SPSx80 only), Trimble must specify and configure the (FCC-approved) transmit broadcast frequencies at the factory. You cannot configure these yourself. SPSx80 Smart GPS Antenna User Guide 103 C Adding Internal Radio Frequencies Adding receive frequencies for the 450 MHz internal radio 1. Start the WinFlash utility. The Device Configuration screen appears. 2. From the Device type list, select the appropriate receiver. 3. From the PC serial port field, select the serial (COM) port on the computer that the receiver is connected to. 4. Click Next. The Operation Selection dialog appears. The Operations list shows all of the supported operations for the selected device. A description of the selected operation is shown in the Description field. 5. Select Configure Radio and then click Next. The Frequency Selection dialog appears: 6. In the Wireless Format group, select the appropriate channel and wireless mode. The Wireless mode must be the same for all radios in your network. 7. In the Specify Frequency field, enter the frequency you want to add. 8. Click Add. The new frequency appears in the Selected Frequencies list. Note – The programmed frequencies must conform to the channel spacing and minimum tuning requirements for the radio. To view this information, click Radio Info. You can select 12.5 kHz or 25 kHz channel spacing. All radios in your network must use the same channel spacing. 9. Once you have configured all the frequencies that you require, click OK. The WinFlash utility updates the receiver radio frequencies and then restarts the receiver. 1 04 SPSx80 Smart GPS Antenna User Guide APPENDIX Upgrading the Receiver Firmware In this appendix: The WinFlash utility Upgrading the receiver firmware Your receiver is supplied with the latest version of receiver firmware installed. If a later version becomes available, upgrade the firmware installed on your receiver using the WinFlash utility. You can also upgrade the SPSx50 receiver through the web interface. SPSx80 Smart GPS Antenna User Guide 105 D Upgrading the Receiver Firmware The WinFlash utility The WinFlash utility communicates with Trimble products to perform various functions including: • installing software, firmware, and option upgrades • running diagnostics ( for example, retrieving configuration information) • configuring radios For more information, online help is also available when using the WinFlash utility. Note – The WinFlash utility runs on Microsoft Windows 95, 98, Windows NT®, 2000, Me, or XP operating systems. Installing the WinFlash utility You can install the WinFlash utility from the Trimble SPS GPS Receiver CD, or from the Trimble website. To install the WinFlash utility from the CD: 1. Insert the disk into the CD drive on your computer. 2. From the main menu select Install individual software packages. 3. Select Install WinFlash. 4. Follow the on-screen instructions. The WinFlash utility guides you through the firmware upgrade process, as described below. For more information, refer to the WinFlash Help. Upgrading the receiver firmware 1. Start the WinFlash utility. The Device Configuration screen appears. 2. From the Device type list, select your receiver. 3. From the PC serial port field, select the serial (COM) port on the computer that the receiver is connected to. 4. Click Next. The Operation Selection screen appears. The Operations list shows all of the supported operations for the selected device. A description of the selected operation is shown in the Description field. 5. Select Load GPS software and then click Next. The GPS Software Selection window appears. This screen prompts you to select the software that you want to install on the receiver. 6. 1 06 From the Available Software list, select the latest version and then click Next. SPSx80 Smart GPS Antenna User Guide Upgrading the Receiver Firmware The Settings Review window appears. This screen prompts you to connect the receiver, suggests a connection method, and then lists the receiver configuration and selected operation. 7. If all is correct, click Finish. Based on the selections shown above, the Software Upgrade window appears and shows the status of the operation ( for example, Establishing communication with . Please wait.). 8. Click OK. The Software Upgrade window appears again and states that the operation was completed successfully. 9. To select another operation, click Menu; to quit, click Exit. If you click Exit, the system prompts you to confirm. 10. Click OK. SPSx80 Smart GPS Antenna User Guide 107 D 1 08 Upgrading the Receiver Firmware SPSx80 Smart GPS Antenna User Guide APPENDIX Data Logging and Postprocessed Measurement Operations In this appendix: Connecting to the office computer Transferring files directly from a CompactFlash card Deleting files in the receiver Supported file types By default, the SPS GPS receivers cannot log data unless you purchase the Data Logging option. For more information, see Configuring the receiver to log data for postprocessing, page 38. The SPS770 GPS receiver keeps satellite measurements and other data in files stored on a CompactFlash card when the data has been used for static measurement. An SPSx80 Smart GPS antenna uses the internal memory of the receiver to store this data. The data files cannot be processed until you transfer them to your office computer. Note – The SPS770 GPS receiver supports a maximum of 512 files on the CompactFlash cards. Note – The SPS780 has an available memory of 2 MB. The SPS880 Extreme has an available memory of 6 MB. The SPS750 Basic has an available memory of 2 MB when the Data Logging option is enabled. The SPS750 Max has an available memory of 27 MB when the option is enabled. The SPS850 Extreme has an available memory of 27 MB when the option is enabled. None of the receivers have a maximum file quantity limit. SPSx80 Smart GPS Antenna User Guide 109 E Data Logging and Postprocessed Measurement Operations Connecting to the office computer The SPSx80 Smart GPS antenna can communicate with the office computer using a serial connection from the DB9 connector on the receiver to a DB9 connector on the computer (see Figure E.1). To do this, use cable P/N 18532 that is supplied with the receiver. Before you connect to the office computer, ensure that the receiver battery is fully charged. Serial cable Serial (COM) port Figure E.1 Connecting the SPSx80 to a computer for serial data transfer Transferring files directly from a CompactFlash card In an SPS770 GPS receiver, all data is stored on an internal CompactFlash card. With a SPSx80 Smart GPS antenna or SPSx50 Modular GPS receiver, data is stored in the internal flash memory. There are two ways to transfer files between the receiver and your office computer: • Connect the receiver to the office computer and use the Data Transfer utility to transfer files. • With a SPS770 GPS receiver, remove the CompactFlash card from the receiver and insert it into the CompactFlash card slot in your office computer, where it functions like a normal disk drive. Use Windows Explorer to transfer files. When you use the Data Transfer utility to transfer data files from the receiver, the Data Transfer utility converts the raw receiver data (.T01) files you select into the Trimble DAT file format. 1 10 SPSx80 Smart GPS Antenna User Guide Data Logging and Postprocessed Measurement Operations However, if you connect the CompactFlash card/USB memory device to your computer and then copy or move files to your computer, it treats the card like any other disk drive, and transfers the files without converting them. You need to convert these raw receiver files to DAT format files before you can use them on your office computer. You can convert receiver data files by using a Windows Explorer extension which is installed on your computer when you install the Data Transfer utility. Deleting files in the receiver You can delete files stored in the receiver at any time. Do one of the following: • Press E for 30 seconds after the receiver is turned on. (When you use this method, all data is deleted, and for a SPS770, the CompactFlash card is reformatted.) • Use the Data Transfer utility • With the SPSx50 Modular GPS receiver, use the Web interface. Supported file types Table E.1 shows the file types that you can transfer to or from a SPS GPS receiver, and the software or utility that you must use to transfer each file type. Table E.1 Supported file types File Type Extensions Transfer from receiver Transfer to Software receiver Ephemeris .eph Yes No Data Transfer Raw observations .T01, .dat Yes No Data Transfer Web interface (SPSx50) Receiver firmware files .elf No Yes WinFlash utility Application files (SPS770 GPS receiver/SPSx80 Smart GPS antenna) .cfg Yes Yes GPS Configurator Configuration Toolbox Note – The SPS770 supports a maximum of 512 files on the CompactFlash card. Files stored on the CompactFlash card must be named using the 8.3 character format. The receiver does not support extended file names. SPSx80 Smart GPS Antenna User Guide 111 E 1 12 Data Logging and Postprocessed Measurement Operations SPSx80 Smart GPS Antenna User Guide APPENDIX Troubleshooting In this appendix: LED conditions Receiver issues Use this appendix to identify and solve common problems that may occur with the receiver. Please read this section before you contact technical support. SPSx80 Smart GPS Antenna User Guide 113 F Troubleshooting LED conditions The SPS770 GPS receiver and SPSx80 Smart GPS antenna have a simple display panel with LEDs to indicate the current status of the receiver. If you need more detailed information about what the receiver is doing, use a Trimble controller or laptop computer running the SCS900, GPS Configurator, or Configuration Toolbox software. The following section describes how the LED lights are used on the receiver to indicate current status. An LED that is flashing quickly indicates a condition that may require attention, and an unlit LED indicates that no operation is occurring. This section describes some LED conditions, possible causes, and how to solve them. Condition Possible cause Solution The SV Tracking LED is lit solidly and the Logging/Memory LED is flashing slowly. The receiver is in Monitor mode, ready for new firmware to be loaded or new options to be added. Turn on or turn off the receiver. The SV Tracking LED is not flashing. The receiver is tracking fewer Wait until the SV Tracking LED is flashing slowly. than four satellites. (SPS770 and SPS780 Smart GPS antenna only) Load the latest version of the firmware, which you can download from the Trimble website (www.trimble.com/sps770.shtml or www.trimble.com/sps780.shtml / Support / Downloads). The radio antenna cable and Make sure that the GPS antenna GPS antenna cable are mixed cable (with the yellow over-mould) is connected between the yellow TNC up. (SPS770 only) connector marked GPS and the GPS antenna. Receiver issues This section describes some possible receiver issues, possible causes, and how to solve them. Issue Possible cause Solution The receiver does not turn on. External power is too low. Check the charge on the external battery, and check the fuse if applicable. If necessary, replace the battery. Internal power is too low. • • External power is not properly • connected. • 1 14 SPSx80 Smart GPS Antenna User Guide Check the charge on the internal batteries and replace if necessary. Ensure battery contacts are clean. Check that the Lemo connection is seated properly. Check for broken or bent pins in the connector. Troubleshooting Issue Receiver does not log data. Possible cause Solution Faulty external power cable. • • Try a different cable. Check pinouts with multimeter to ensure internal wiring is intact. Insufficient memory on either Delete old files using the GPS Configurator software, or press E internal memory or the CompactFlash card. for 30 seconds. No CompactFlash card is inserted. (SPS770 only) Insert a CompactFlash card in the receiver. The CompactFlash card is not seated properly. Remove the Compact Flash card and reinsert it. Ensure that it slides into the housing easily and seats into the connector. The CompactFlash card is not formatted, or has been corrupted. Format the CompactFlash card using the GPS Configurator software, or press E for 30 seconds. If the problem persists, use the GPS Configurator software to perform a full format. The receiver is tracking fewer than four satellites. • • The data logging option is not enabled. Wait until the SV Tracking LED is flashing slowly. Use the SCS900 software. Go to the SkyPlot screen and press [Ctrl]+[M] to access the current elevation mask settings. Reduce the mask value to make more satellites available. The default mask setting for receiver is 13° above the horizon. Change the value to a lower setting temporarily while you are waiting for a better constellation availability. Check the original purchase order or the receiver configuration using WinFlash. If data logging is not enabled on the receiver, you can order the option from your local Trimble Site Positioning Systems dealer, and upgrade the receiver using the WinFlash utility. Receiver is not tracking GPS antenna does not have any satellites clear line of sight to the sky. Ensure that the antenna has a clear line of sight. The cable between receiver and the GPS antenna is damaged. Replace the cable. Cable connections at receiver or antenna are not tightly seated, or are connected incorrectly. Check all cable connections. SPSx80 Smart GPS Antenna User Guide 115 F Troubleshooting Issue Possible cause Solution The receiver is not responding. Receiver needs a soft reset. Turn off the receiver and then turn it back on again. Receiver needs a full reset. Press E for 30 seconds. Note – To retain data files, remove the CompactFlash card (SPS770) or download the files (SPS780) first. Base station setup and static measurement problems This section describes some possible station setup and static measurement issues, possible causes, and how to solve them. Trimble recommends that you use the SCS900 software to restart or configure base and rover receivers. The SCS900 software sets up all radio and receiver operating parameters, and is the most likely route to a successful problem resolution once you have checked all connections, cables, and batteries. Issue Possible cause Base station is not broadcasting. Port settings between base receiver and external radio are incorrect. Solution Using the Trimble SCS900 Site Controller software connect to the radio through the receiver. If no connection is made, connect directly Note – The SPS770 has an integrated RX only radio. For to the radio and change the port settings. Try to connect through the use as a base station, the receiver must be connected to receiver again to ensure that they are communicating. an external radio, such as a Note – The SCS900 software does TRIMMARK™ 3. not support direct connection to the Note – The SPSx80 has the external radio; it only allows option for an integrated TX radio that allows it to be used configuration through the receiver. The TRIMMARK 3 and SNB900 radios without an external radio at can be configured directly using the the base and rover location. keypad and display. The Trimble PDL The SPSx80 can also be connected to an external high or Trimble HPB radios can be configured using the accompanying power radio in certain configuration software through a countries. laptop computer. Faulty cable between receiver • and external radio • • 1 16 SPSx80 Smart GPS Antenna User Guide Try a different cable Examine the ports for missing pins Use a multimeter to check the pins No power to radio If the radio has its own power supply, check the charge and connections. No Bluetooth connections (SPS780 / SNB900) Make sure that the radio and receiver are within Bluetooth range of each other and that the Bluetooth antennae are visible to each other. Troubleshooting Issue Possible cause Solution Roving receiver is not receiving radio from the base station. The base station is not broadcasting. See Base station is not broadcasting. Incorrect over air baud rates between base station and rover. Connect to the roving receiver’s radio and make sure that it has the same setting as the base station receiver. Mismatched channel or network number selection. Match the base station and rover radio channels/network number and try again. Incorrect port settings between the rover external radio and receiver. If the radio is receiving data (the Radio LED is flashing) and the receiver is not receiving data, check the port settings of the receiver and radio using the Trimble SCS900 Site Controller software; match the settings and try again. The radio antenna cable and GPS antenna cable are mixed up. Make sure that the radio antenna cable (with the blue over-mould) is connected between the blue TNC connector marked RADIO and the radio antenna. SPSx80 Smart GPS Antenna User Guide 117 F 1 18 Troubleshooting SPSx80 Smart GPS Antenna User Guide Glossary almanac A file that contains orbit information on all the satellites, clock corrections, and atmospheric delay parameters. The almanac is transmitted by a GPS satellite to a GPS receiver, where it facilitates rapid acquisition of GPS signals when you start collecting data, or when you have lost track of satellites and are trying to regain GPS signals. The orbit information is a subset of the emphemeris / ephemerides data. AutoBase AutoBase technology uses the position of the receiver to automatically select the correct base station; allowing for one button press operation of a base station. It shortens setup time associated with repeated daily base station setups at the same location on jobsites. base station Also called reference station. A base station in construction, is a receiver placed at a known point on a jobsite that tracks the same satellites as an RTK rover, and provides a real-time differential correction message stream through radio to the rover, to obtain centimeter level positions on a continuous real-time basis. A base station can also be a part of a virtual reference station network, or a location at which GPS observations are collected over a period of time, for subsequent postprocessing to obtain the most accurate position for the location. BINEX BInary EXchange format. BINEX is an operational binary format standard for GPS/GLONASS/SBAS research purposes. It has been designed to grow and allow encapsulation of all (or most) of the information currently allowed for in a range of other formats. broadcast server An Internet server that manages authentication and password control for a network of VRS servers, and relays VRS corrections from the VRS server that you select. carrier A radio wave having at least one characteristic (such as frequency, amplitude, or phase) that can be varied from a known reference value by modulation. carrier frequency The frequency of the unmodulated fundamental output of a radio transmitter. The GPS L1 carrier frequency is 1575.42 MHz. carrier phase The time taken for the L1 or L2 carrier signal generated by the satellite to reach the GPS receiver. Measuring the number of carrier waves between the satellite and receiver is a very accurate method of calculating the distance between them. cellular modems A wireless adaptor that connects a laptop computer to a cellular phone system for data transfer. Cellular modems, which contain their own antennas, plug into a PC Card slot or into the USB port of the computer and are available for a variety of wireless data services such as GPRS. CMR CMR+ Compact Measurement Record. A real-time message format developed by Trimble for broadcasting corrections to other Trimble receivers. CMR is a more efficient alternative to RTCM. covanance The mean value. SPSx80 Smart GPS Antenna User Guide 1 19 Glossary datum Also called geodetic datum. A mathematical model designed to best fit the geoid, defined by the relationship between an ellipsoid and, a point on the topographic surface, established as the origin of the datum. World geodetic datums are typically defined by the size and shape of an ellipsoid and the relationship between the center of the ellipsoid and the center of the earth. Because the earth is not a perfect ellipsoid, any single datum will provide a better model in some locations than in others. Therefore, various datums have been established to suit particular regions. For example, maps in Europe are often based on the European datum of 1950 (ED-50). Maps in the United States are often based on the North American datum of 1927 (NAD-27) or 1983 (NAD-83). All GPS coordinates are based on the WGS-84 datum surface. deep discharge Withdrawal of all electrical energy to the end-point voltage before the cell or battery is recharged. DGPS See real-time differential GPS. differential correction Differential correction is the process of correcting GPS data collected on a rover with data collected simultaneously at a base station. Because the base station is on a known location, any errors in data collected at the base station can be measured, and the necessary corrections applied to the rover data. Differential correction can be done in real-time, or after the data has been collected by postprocessing. differential GPS See real-time differential GPS. DOP Dilution of Precision. A measure of the quality of GPS positions, based on the geometry of the satellites used to compute the positions. When satellites are widely spaced relative to each other, the DOP value is lower, and position accuracy is greater. When satellites are close together in the sky, the DOP is higher and GPS positions may contain a greater level of error. PDOP (Position DOP) indicates the three-dimensional geometry of the satellites. Other DOP values include HDOP (Horizontal DOP) and VDOP (Vertical DOP), which indicate the accuracy of horizontal measurements (latitude and longitude) and vertical measurements respectively. PDOP is related to HDOP and VDOP as follows: PDOP2 = HDOP2 + VDOP2 dual-frequency GPS A type of receiver that uses both L1 and L2 signals from GPS satellites. A dual-frequency receiver can compute more precise position fixes over longer distances and under more adverse conditions because it compensates for ionospheric delays. EGNOS European Geostationary Navigation Overlay Service. A satellite-based augmentation system (SBAS) that provides a free-to-air differential correction service for GPS. EGNOS is the European equivalent of WAAS, which is available in the United States. elevation mask The angle below which the receiver will not track satellites. Normally set to 10 degrees to avoid interference problems caused by buildings and trees, and multipath errors. ellipsoid An ellipsoid is the three-dimensional shape that is used as the basis for mathematically modeling the earth’s surface. The ellipsoid is defined by the lengths of the minor and major axes. The earth’s minor axis is the polar axis and the major axis is the equatorial axis. emphemeris / ephemerides A list of predicted (accurate) positions or locations of satellites as a function of time. A set of numerical parameters that can be used to determine a satellite’s position. Available as broadcast ephemeris or as postprocessed precise ephemeris. 1 20 SPSx80 Smart GPS Antenna User Guide Glossary epoch The measurement interval of a GPS receiver. The epoch varies according to the measurement type: for real-time measurement it is set at one second; for postprocessed measurement it can be set to a rate of between one second and one minute. For example, if data is measured every 15 seconds, loading data using 30-second epochs means loading every alternate measurement. feature A feature is a physical object or event that has a location in the real world, which you want to collect position and/or descriptive information (attributes) about. Features can be classified as surface or non-surface features, and again as points, lines/breaklines, or boundaries/areas. firmware The program inside the receiver that controls receiver operations and hardware. GLONASS Global Orbiting Navigation Satellite System. GLONASS is a Soviet space-based navigation system comparable to the American GPS system. The operational system consists of 21 operational and 3 non-operational satellites in 3 orbit planes. GNSS Global Navigation Satellite System. GSOF General Serial Output Format. A Trimble proprietary message format. HDOP Horizontal Dilution of Precision. HDOP is a DOP value that indicates the accuracy of horizontal measurements. Other DOP values include VDOP (vertical DOP) and PDOP (Position DOP). Using a maximum HDOP is ideal for situations where vertical precision is not particularly important, and your position yield would be decreased by the vertical component of the PDOP ( for example, if you are collecting data under canopy). L1 The primary L-band carrier used by GPS satellites to transmit satellite data. L2 The secondary L-band carrier used by GPS satellites to transmit satellite data. L5 The third L-band carrier used by GPS satellites to transmit satellite data. L5 will provide a higher power level than the other carriers. As a result, acquiring and tracking weak signals will be easier. Moving Base Moving Base is an RTK positioning technique in which both reference and rover receivers are mobile. Corrections are sent from a “base” receiver to a “rover” receiver and the resultant baseline (vector) has centimeter-level accuracy. MSAS MTSAT Satellite-Based Augmentation System. A satellite-based augmentation system (SBAS) that provides a free-to-air differential correction service for GPS. MSAS is the Japanese equivalent of WAAS, which is available in the United States. multipath Interference, similar to ghosts on a television screen, that occurs when GPS signals arrive at an antenna having traversed different paths. The signal traversing the longer path yields a larger pseudorange estimate and increases the error. Multiple paths can arise from reflections off the ground or off structures near the antenna. NMEA National Marine Electronics Association. NMEA 0183 defines the standard for interfacing marine electronic navigational devices. This standard defines a number of 'strings' referred to as NMEA strings that contain navigational details such as positions. Most Trimble GPS receivers can output positions as NMEA strings. OmniSTAR The OmniSTAR HP/XP service allows the use of new generation dual-frequency receivers with the OmniSTAR service. The HP/XP service does not rely on local reference stations for its signal, but utilizes a global satellite monitoring network. Additionally, while most current dual-frequency GPS systems are accurate to within a meter or so, OmniSTAR with XP is accurate in 3D to better than 30 cm. SPSx80 Smart GPS Antenna User Guide 1 21 Glossary Position Dilution of Precision. PDOP is a DOP value that indicates the accuracy of three-dimensional measurements. Other DOP values include VDOP (vertical DOP) and HDOP (Horizontal Dilution of Precision). PDOP Using a maximum PDOP value is ideal for situations where both vertical and horizontal precision are important. postprocessing Postprocessing is the processing of satellite data after it has been collected, in order to eliminate error. This involves using computer software to compare data from the rover with data collected at the base station. real-time differential Also known as real-time differential correction or DGPS. Real-time differential GPS is the GPS process of correcting GPS data as you collect it. Corrections are calculated at a base station and then sent to the receiver through a radio link. As the rover receives the position it applies the corrections to give you a very accurate position in the field. Most real-time differential correction methods apply corrections to code phase positions. RTK uses carrier phase measurements. While DGPS is a generic term, its common interpretation is that it entails the use of single-frequency code phase data sent from a GPS base station to a rover GPS receiver to provide sub-meter position accuracy. The rover receiver can be at a long range (greater than 100 kms (62 miles)) from the base station. rover A rover is any mobile GPS receiver that is used to collect or update data in the field, typically at an unknown location. Roving mode Roving mode applies to the use of a rover receiver to collect data, stakeout, or control earthmoving machinery in real time using RTK techniques. RTCM Radio Technical Commission for Maritime Services. A commission established to define a differential data link for the real-time differential correction of roving GPS receivers. There are three versions of RTCM correction messages. All Trimble GPS receivers use Version 2 protocol for single-frequency DGPS type corrections. Carrier phase corrections are available on Version 2, or on the newer Version 3 RTCM protocol, which is available on certain Trimble dual-frequency receivers. The Version 3 RTCM protocol is more compact but is not as widely supported as Version 2. RTK real-time kinematic. A real-time differential GPS method that uses carrier phase measurements for greater accuracy. SBAS Satellite-Based Augmentation System. SBAS is based on differential GPS, but applies to wide area (WAAS/EGNOS and MSAS) networks of reference stations. Corrections and additional information are broadcast via geostationary satellites. signal-to-noise ratio SNR. The signal strength of a satellite is a measure of the information content of the signal, relative to the signal’s noise. The typical SNR of a satellite at 30° elevation is between 47 and 50 dBHz. The quality of a GPS position is degraded if the SNR of one or more satellites in the constellation falls below 39. skyplot The satellite skyplot confirms reception of a differentially corrected GPS signal and displays the number of satellites tracked by the GPS receiver, as well as their relative positions. 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. 1 22 SPSx80 Smart GPS Antenna User Guide Glossary 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 at 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. SPSx80 Smart GPS Antenna User Guide 1 23 Glossary 1 24 SPSx80 Smart GPS Antenna User Guide
Source Exif Data:
File Type : PDF File Type Extension : pdf MIME Type : application/pdf PDF Version : 1.6 Linearized : No Encryption : Standard V1.2 (40-bit) User Access : Print, Copy, Fill forms, Extract, Assemble, Print high-res Page Mode : UseOutlines XMP Toolkit : 3.1-702 Producer : Acrobat Distiller 7.0 (Windows) Creator Tool : FrameMaker 7.0 Modify Date : 2006:08:02 14:33:11+12:00 Create Date : 2006:08:02 13:11:35Z Metadata Date : 2006:08:02 14:33:11+12:00 Format : application/pdf Title : SPSx80 Smart GPS Antenna User Guide Creator : Trimble Navigation Limited - Technical Publications Group Description : SPSx80 Document ID : uuid:eaf46ba0-d128-41bb-87d8-d56348afbe2d Instance ID : uuid:22fb176a-e02a-427f-bef6-0f1d89be0f40 Page Count : 124 Subject : SPSx80 Author : Trimble Navigation Limited - Technical Publications GroupEXIF Metadata provided by EXIF.tools