<strong>GPS Aircraft Installation and Operation</strong>
<strong>1. GPS Installation</strong>
</strong>Present-day Aircraft GPS receivers are embedded (as a modular part or card) in the Multi-Mode Receiver also housing ILS-, MLS-, VOR-receivers. While physically integrated with the MMR, the GPS receiver is a standalone sensor complying with ARINC 743B characteristics providing an ARINC 429 Data Bus (DITS) output to interface with the applicable aircraft systems requiring a GPS-pvt input. For system isolation, the GPS data bus is triplicated each carrying the same data. Data buses may typically be interfaced with:
− FMC’s for FMS present position updates
− EGPWS as PPOS input for terrain avoidance
− Clocks to synchronize time with GPS derived UTC
− Emergency Locator Transmitter (ELT) beacon for crash site reporting
</strong>The GPS antenna will be located on top of the fuselage and comprises a very small antenna hardly visible between the many other antenna’s. The antenna is active (Low Noise Amplifier (LNA) included) to compensate for the coax cable run to the MMR. The LNA will be powered through the coaxial centre conductor also carrying the rf-signal to the receiver.
</strong>Early GPS installations consisted of a self-contained GPS receiver located in the crown/ceiling of the aircraft close to a passive GPS antenna on top of the fuselage. This type of installations is referred to as the Global Navigation Satellite Sensor Unit (GNSSU). This type of installations has been terminated.
Unique architectures may locate a GPS receiver as an integral part of a Flight Management Computer System (e.g. B747-300 FMCS) or the Enhanced Ground Proximity Warning System (EGPWS) in retrofit installations without an MMR.
<strong>2. GPS Operation</strong>
With electrical power available and the circuit breaker closed, the GPS receiver is operational and will provide output without further controls. Time-To-First-Fix (TTFF) may be reduced by supplying present position as an initialisation input to the GPS receiver. This PPOS may be derived from the aircraft IRS or memorized by the GPS from the previous flight. The same IRS input may assist the GPS receiver to coast through short periods of GPS signal loss speeding up re-acquisition.
Once available, the GPS position may be used as an IRS alignment PPOS input to accurately align the IRS’s without reference to gate positions or equivalent.
The GPS receiver has the regular Built-In Test Equipment (BITE) and will annunciate receiver failures through amber annunciator(s) and/or messages on the applicable aircraft warning and caution systems. Faults may also be indicated when GPS navigation is lost for 6 seconds.
There are hardly any normal or abnormal procedures for the pilot to mention. GPS operation basically is fully automatic. The only control provided may be a GPS manual inhibit prompt on the applicable FMS CDU page (NAV OPTIONS) to disable the system e.g. if the behaviour is unacceptable or when NOTAM’s indicate unreliable GPS signals part of the route. Even then, the FMS navigation sensor logic should be able to automatically deselect GPS data if it no longer fulfils the FMS specific requirements for primary use and FMS reverts to DME/DME, VOR/DME or IRS only navigation, whatever is available.
To observe GPS position calculations in relation to IRS position computations there are two possible places to observe:
− The applicable FMS CDU pages (POS REF) displaying the GPS data
− The EFIS MAP display showing GPS and IRS position around the origin when desired
GPS will prove to be the most accurate latitude/longitude position sensor and the number of so-called MAP-shifts will reduce significantly. In combination with the EGPWS terrain database, the accurate GPS position will reduce the CFIT risk. Accurate UTC derived from GPS will aid the increasing demand for Required Time of Arrival (RTA) operations leading to reduced separation minima.
More specific information related to specific aircraft installations can be found in the applicable Aircraft Operations Manual (AOM) including procedures for use and limitations.
The schematic shows a typical aircraft installation (B737-800).
<a href="http://flightcrewguide.com/wp-content/uploads/2013/11/GPS-Interface-Schematic-simplified-B737-800.jpg"><img class="aligncenter size-large wp-image-1920" src="http://flightcrewguide.com/wp-content/uploads/2013/11/GPS-Interface-Schematic-simplified-B737-800-685×1024.jpg" alt="GPS Interface Schematic simplified B737-800" width="580" height="867" /></a>
<a title="GPS Description" href="http://flightcrewguide.com/wiki/gps/gps-general/">GPS Description</a>
<a title="GPS Introduction" href="http://flightcrewguide.com/wiki/gps/gps-introduction/">GPS Introduction</a>
<a title="GPS Operating Principles" href="http://flightcrewguide.com/wiki/gps/gps-operating-principles/">GPS Operating Principles</a>
<a title="GPS Segments" href="http://flightcrewguide.com/wiki/gps/gps-segments/">GPS Segments</a>
<a title="GPS Aircraft Installation and Operation" href="http://flightcrewguide.com/wiki/gps/gps-aircraft-installation-operation/">GPS Aircraft Installation and Operation</a>
<a title="GPS Signals" href="http://flightcrewguide.com/wiki/gps/gps-signals/">GPS Signals</a>
<a title="GPS Position & Time" href="http://flightcrewguide.com/wiki/gps/gps-position-time/">GPS Position & Time</a>
<a title="GPS Augmentations" href="http://flightcrewguide.com/wiki/gps/gps-augmentations/">GPS Augmentations</a>
<a title="GPS Abbreviations" href="http://flightcrewguide.com/wiki/gps/gps-abbreviations/">GPS Abbreviations</a>