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A [[Ground-Based Augmentation System (GBAS)]] is a civil-aviation safety-critical system that supports local augmentation –at airport level– of the primary GNSS constellation(s) by providing enhanced levels of service that support all phases of approach, landing, departure and surface operations. While the main goal of GBAS is to provide [[Integrity|integrity]] assurance, it also increases the [[Accuracy|accuracy]] with position errors below 1 m (1 sigma).<ref name="GNSS Aug">[[Wikipedia:GNSS augmentation|GNSS augmentation in Wikipedia]]</ref><ref name="Kaplan">E.D. Kaplan, C.J. Hegarty, ''Understanding GPS Principles and Applications”, 2nd Ed., Artch House, ISBN 1-58053-894-0, 2006.</ref>
The Ground Based Augmentation System (GBAS) is intended primarily to support precision approach operations. It consists of a GBAS Ground Subsystem and a GBAS Aircraft Subsystem.
==Introduction: How a GBAS works==
(The information in this section has been taken from [http://www.faa.gov/ FAA]  homepage.)
A Ground Based Augmentation System (GBAS) augments the Global Positioning System (GPS) to improve aircraft safety during airport approaches and landings. It is expected that the end-state configuration will pinpoint the aircraft's position to within one meter or less with a significant improvement in service flexibility and user operating costs. GBAS is comprised of ground equipment and avionics. The ground equipment includes 4 reference receivers, a GBAS ground facility, and a VHF data broadcast transmitter. This ground equipment is complemented by GBAS avionics installed on the aircraft.<ref>[http://www.faa.gov/about/office_org/headquarters_offices/ato/service_units/techops/navservices/gnss/laas/howitworks/ LAAS-How it works] by FAA.</ref>
Signals from GPS satellites are received by the GBAS GPS Reference Receivers at the GBAS-equipped airport. The reference receivers calculate their position using GPS. The GPS Reference Receivers and GBAS Ground Facility work together to measure errors in GPS-provided position. The GBAS Ground Facility produces a GBAS correction message based on the difference between actual and GPS-calculated position which includes as well integrity parameters and approach path information. This GBAS correction message is then sent to a VHF data broadcast (VDB) transmitter.
The VDB broadcasts the GBAS signal throughout the GBAS coverage area to avionics in GBAS-equipped aircraft. GBAS provides its service to a local area (approximately a 30 kilometer radius). The signal coverage is designed to support the aircraft's transition from en route airspace into and throughout the terminal area airspace.


A Ground-Based Augmentation System (GBAS) is a civil-aviation safety-critical system that supports local augmentation – at airport level – of the primary GNSS constellation(s) by providing enhanced levels of service that support all phases of approach, landing, departure and surface operations. While the main goal of GBAS is to provide [[Integrity|integrity]] assurance, it also increases the [[Accuracy|accuracy]] with position errors below 1 m (1 sigma).<ref name="GNSS Aug">[[Wikipedia:GNSS augmentation]]</ref><ref name="Kaplan">E.D. Kaplan, C.J. Hegarty, ''Understanding GPS Principles and Applications”, 2nd Ed., Artch House, ISBN 1-58053-894-0, 2006.</ref>
The GBAS equipment in the aircraft uses the corrections provided on position, velocity, and time to guide the aircraft safely to the runway. This signal provides ILS-look-alike guidance as low as 200 feet (60 m) above touchdown. GBAS will eventually support landings all the way to the runway surface.


The Ground Based Augmentation System (GBAS) is intended primarily to support
<gallery>
precision approach operations. It consists of a GBAS Ground Subsystem and a
Image:Laas_step1.jpg‎
GBAS Aircraft Subsystem.  
Image:Laas_step2.jpg‎
Image:Laas_step3.jpg‎
Image:Laas_step4.jpg‎
</gallery>


==GBAS Architecture==
==GBAS Architecture==
[[File:SBAS_architecture.png|SBAS architecture|300px|thumb|right]]
[[File:LAAS_Architecture.png|GBAS architecture|350px|thumb|right]]


A SBAS is a safety critical system designed to augment one or several satellite navigation systems. The main components of a general GBAS architecture are:
A GBAS is a safety critical system designed to augment one or several satellite navigation systems. The main components of a general GBAS architecture are:
* GBAS Ground Subsystem
* GBAS Ground Subsystem
* GBAS Aircraft Subsystem
* GBAS Aircraft Subsystem
Line 24: Line 39:
===GBAS Ground Subsystem===
===GBAS Ground Subsystem===


The main purposes of the GBAS Ground Subsystem are: signals-in-space receive and decode, carrier smoothed code and differential corrections and integrity computation, integrity monitoring, generation and broadcasting of GBAS messages.
The main purposes of the GBAS Ground Subsystem are:
*reception and decoding of signals-in-space;
*computation of the differential corrections to the carrier-smoothed codes;
*integrity monitoring;
*generation and broadcasting of GBAS messages.


The GBAS Ground Subsystems consist of  
The GBAS Ground Subsystem consists of:
*2 to 4 GNSS Reference Receivers and their respective geographically separated antennas
*2 to 4 GNSS Reference Receivers and their respective geographically separated antennas;
* A VHF data broadcast (VDB) transmitter
* A VHF data broadcast (VDB) transmitter;
*A monitor system
*A monitor system;
*Approach Database (FAS data)
*Approach Database (FAS data);
*Ground processing functions
*Ground processing functions.


===GBAS Aircraft Subsystem===


The main element of GBAS Aircraft Subsystem is the aircraft GBAS Receivers.


The SBAS space segment is composed by several geostationary satellites in charge of broadcasting, over the service area, the SBAS navigation message. Typically, the SBAS satellites are multi-purpose (commercial communication) satellites that carry out an additional navigation payload capable to generate a GPS-like signal that retransmits to the users the navigation message generated on-ground.
The primary functions of the GBAS aircraft subsystem are:
* receive and decode the GNSS satellite and GBAS signals;
* determine the aircraft position;
* provide availability of the service;
* compute deviations from the desired flight path calculated from the Final Approach Segment (FAS) data;
* provide guidance signals and integrity information.


The SBAS GEO navigation payload is a transponder that relays the on-ground generated signal (upload to the GEO in the C-band frequency) to a transmitted signal in the L-band frequency band. For most of the navigation payloads, a second C-band downlink channel is available in order to improve the adjustment of the signal delay due to atmospheric propagation. However, first generation of navigation payloads only included a single-channel frequency translating repeater.
The GBAS aircraft subsystem essential elements are:
* An Aircraft GNSS Receiver Function that receives, tracks, and decodes the GNSS satellite signals.
* A VHF Data Broadcast Receiver Function that receives and decodes the messages broadcast by the GBAS Ground Subsystem.
* An Aircraft Navigation Processing Function that receives the measurement of the pseudo-ranges from the GNSS Receiver Function, applies the differential corrections received from the VHF Data Broadcast Receiver Function and calculates the differentially corrected aircraft position. The Aircraft Navigation Processing Function extracts from the different FAS path construction data received, the one having the Reference Path Selector selected by the crew through the GLS Channel Number Selector. The Aircraft Navigation Processing Function also calculates deviations from the selected FAS path based on its differentially corrected position.


The new generation of SBAS navigation payload includes more advanced functionalities. Among them, it is worth noting:
===GNSS Satellites Subsystem===
* Increase of the emission bandwidth and broadcast power.
* Evolution to dual-frequency L1/L5 transponders.
* Evolution of payload from signal transponders to regenerative payloads in which the signal is entirely build up onboard (the GEO only receives from ground segment the navigation message to be modulated in the GEO signal).


===Ground Mission Segment===
The GBAS Satellites Subsystem is mainly the GNSS constellations declared operational for civil use. The minimum requirements of a GBAS system are limited for the use of GNSS satellites ranging sources, with additional ranging sources being supplied by SBAS as an option.
The main purpose of the Ground Mission Segment is to generate and uplink the augmentation signal that will be broadcast by the GEO satellite.


To achieve this objective, the Ground Mission Segment is typically broken down into the following subsystems:
==GBAS Signal==
*Monitoring Station Network: Its purpose is to collect data from the satellites that are to be augmented. This is performed by a network of GNSS receivers.
*Processing Facility Centre: It is in charge of processing the data provided by the Monitoring Station Network to generate the messages to be broadcasted to the satellites.
*GEO Satellite Control Centre: It is in charge of generating the signal with the message provided by the Processing Facility Centre and up-linking it to the GEO satellites.
*Communication Layer: It interconnects the different elements of the Ground Segment.


====Monitoring Station Network====
The GBAS Signal in Space is defined to be only the data broadcast from the ground to the aircraft subsystem. The Satellite Signals in Space are part of the basic GNSS satellite constellations.
[[File:egnos_rims.png|EGNOS reference station|thumb|right|100px]]
The Monitoring Station Network is carefully designed to monitor satellites and ionosphere with the required accuracy and availability in the SBAS service area. This usually implies a dense network of stations in the service area, with some additional stations outside. In addition, there must be redundancy to avoid single points of failure, or even different subsets of stations to feed parallel and independent processing chains.


The monitoring stations have the following characteristics:
The GBAS ground subsystem differential computed corrections (contained in Type 1 message), GBAS ground subsystem  related data (contained in Type 2 message) and Final Approach Segments (FAS) (contained in Type 4 message) are transmitted to the aircraft users via VHF Data Broadcast (VDB) Signal. The GBAS Messages are encoded in this signal. The specification of GBAS message data format is contained in the [http://www.icao.org ICAO] SARPS Appendix B for the aspects related with the signal in space, as well as in the RTCA MOPS DO-253C for the minimum operational performance requirements applicable to the airborne GBAS receiver equipment.  
* Dual frequency (L1/L2) receivers with geodetic quality.
* Atomic frequency standard (Caesium/Rubidium/H-Maser).
* Able to track all in view GPS and GEO satellites.
* Allocated in site conditions with good local environment condition in terms of multipath and radio frequency interference .
* Geo-referenced to WGS-84 (or ITRF) within a 1-3 cm accuracy.
* Compliant with some processing capabilities:
** 1 Hz data acquisition.
** Embedded data quality checks to remove misleading data.
** Data processing and broadcast within a few milliseconds.
** Integrated robustness against known threats (e.g. ''evil'' waveforms detection).


====Processing Facility Centre====
The VDB radio frequencies used shall be selected from the radio frequencies in the band 108-117.975 MHz. The lowest assignable frequency shall be 108.025 MHz and the highest frequency assignable shall be 117.950 MHz. The separation between assignable frequencies (channel spacing) shall be 25 kHz.
[[File:egnos_cpfps.png|CPFPS, component of the EGNOS Central Processing Facility|thumb|right|200px]]
The Processing Facility Centre is one of the critical elements of the SBAS system as it is charge of generating the augmentation information for the user, playing a major role in the achievement of the SBAS performance requirements.


The Processing Facility Centre is in charge of the following functions:
The GBAS message types are summarized in the following table:
* Process all input data from the Monitoring Station Network.
* Estimate the satellite corrections, ionospheric model and error variance terms.
* Perform a dedicated integrity assessment on the information provided by the system to the users.
* Format the outputs according to the SBAS standards.


The Processing Facility Centre has a very strong algorithmic load, as it has to solve the following challenges:
{| class="wikitable" align="center"
* Advanced models for satellite orbit determination (breaking frontiers in GEO orbit and clock determination).
!Message type identifier
* Determination of the SBAS reference time and satellite clock corrections with better than 2 ns accuracy.
!Message Name
* Real-time ionospheric estimation with a dense network of receivers. This estimation should be able to characterize local and rapid phenomena.
|-align="center"
* Integrity estimation valid for wide-areas with demanding performance requirements.
|0
 
| Spare
====GEO Satellite Control Centre====
|-align="center"
[[File:egnos_nles_test.png|Test diagram for EGNOS uplink station|thumb|right|200px]]
|1
GEO Satellite Control Centre function is to relay the SBAS messages computed by the Processing Facility Centre to the GEO satellites. Its functions include:
| GBAS Differential Corrections
* Codify the GPS-like signal encoding. In particular, the preparation of the signal generation as well as the PRN encoding.
|-align="center"
* Modulate the SBAS message information provided by the Processing Facility Centre into the signal.
|2
* Synchronize the timing of the signal to the SBAS reference time.
| GBAS Related Data
* Control de time synchronization between the carrier and code components of the uplink signal (core-carrier coherency).
|-align="center"
* Close the uplink-station/GEO-satellite control loop by receiving and processing the downlink SBAS satellite signals (both in L- and C- bands).
|3
 
| Reserved for ground–based ranging source
====Communication Layer====
|-align="center"
The Communication Layer ensures that all the SBAS Ground Segment elements are interconnected in real time. This connection should be performed with high performance standards in terms of reliable lines, sufficient bandwidth for a large exchange of data, and stringent redundancy and security requirements.
|4
| Final Approach Segment (FAS) data
|-align="center"
|5
| Predicted ranging source availability
|-align="center"
|6
| Reserved
|-align="center"
|7
| Reserved for national applications
|-align="center"
|8
| Reserved for test applications
|-align="center"
|9-255
| Spare
|}


===Support Mission Segment===
==GBAS Performances==
The SBAS Support Segment collects all the elements need to support the development and operation of a SBAS system. These elements are not related with the provision of the SBAS service but they are needed as external support facilities. They SBAS support needs can be listed as:
* The design, development and validation phases.
* The deployment and operation.
* The certification process.
* The maintenance and troubleshooting.
* The certification of applications.


Between the different SBAS Support elements it is worth noting:
* End to End Simulators in charge of simulating data under controlled conditions (reference errors, emulated feared events) in order to simulate the real system behaviour (delays and communication problems, algorithm, broadcasting features, etc).
* Service Volume Simulators in charge of evaluating the overall SBAS performances over the service area under a set of controlled conditions.
* Performance Analysis Tools in charge of measuring all the performance concepts at:
** system level by analysing the Signal in Space information and checking the accuracy, integrity, continuity and availability features but using concepts based in the errors available at pseudorange domain.
** user point of view level, by analysing user data (including local conditions) and applying user-related algorithms (see [[SBAS Standards|SBAS standards]]).
* On-line monitoring tools for tracking the system behaviour in real time and collecting system failure and anomalies. These elements also support the system operation by predicting the expected behaviour of the system and provide warnings as system outages or degradations. They also provide warnings to external users.
* Archiving tools supporting the data archiving. The data comprises both all the internal information generated by the system as well as external data (satellite reference orbit and clock data, ionospheric information, outages, etc).
* Application test benches to support applications by generating test scenarios for their certification and performance verification. They are able to plug different application software or equipment for homologation purposes.


===User Segment===
The GBAS performances are defined with respect to the level of service that the system is designed to provide. The main source for GBAS performances comes from civil aviation navigation safety requirements and they are different for each civil aviation operation. <ref name="ICAO_SARPS">[http://www.icao.org ICAO] Standards and Recommended Practices, Annex 10, Volume 1 Radio Navigation Aids, July 2006</ref>
The SBAS user segment comprises all the user equipment that makes use of the SBAS Signal in Space (SIS). In fact, the SBAS User segment is not under the control of the SBAS service provider as it is driven by the SBAS application market.
 
In general, the SBAS service operator provides different services aiming at different market sectors, namely an [[EGNOS Open Service|Open Service]], a [[EGNOS Safety of Life Service|Safety of Life service]] (SoL) and even a [[EGNOS Commercial Data Distribution Service|Commercial Service]].
 
For the Safety-of-Life (SoL) service, the SBAS user equipment shall be compliant (certified) against several standards. For instance, civil aviation SBAS equipment shall demonstrate (see [[SBAS Standards|SBAS standards]]):
* Full compliance to  RTCA SBAS MOPS DO-229 (airborne equipment).
* Full compliance to the RTCA SBAS MOPS 228 and 301 (antenna requirements).
* Compliance to RTCA TSO (C190, C145b, C146b) for SBAS equipment.
* Compatibility to other avionics equipment, in particular Flight Management Systems (FMS).
 
The SoL civil aviation certified equipment is in the highest rank with respect its cost. There exist a large number of certified receivers manufacturers worldwide both in the US (GARMIN, Honeywell, Rockwell Collins, General Avionics, etc) and in Europe (see complete list in EASA homepage<ref>[http://www.easa.europa.eu/certification/docs/etso-authorisations/etsoa.pdf List of ETSO Authorisations (European Aviation Safety Agency)]</ref>).
 
The Open Service (OS) targets low cost, general purpose GNSS equipment that uses the SBAS SIS to provide the user with an enhanced accuracy performance in comparison with the one provided by a standalone GPS device. In comparison with the certification requirements of the user equipment above, user equipment is not necessarily compliant with the RTCA MOPS DO 229 processing rules, but might only make use of the processing algorithms that render the accuracy corrections provided by the SBAS SIS.
 
Finally, some SBAS service providers (see [[:Category:EGNOS|EGNOS]]) include the provision of the information computed by the SBAS ground element (input raw data, corrections, integrity information) by dissemination means different to the SBAS GEO link (generally, using terrestrial telecommunication networks). This constitutes the Commercial Service. This market sector comprises professional users (land and geodesy applications, maritime or terrestrial transport applications) that are not subject to the integrity and latency requirements needed in the SoL service.
 
==SBAS Signal==
 
Every SBAS provides ranging signals transmitted by GEO satellites, differential corrections on the wide area and additional parameters aimed to guarantee the integrity of the GNSS user:
* '''GEO Ranging''': transmission of GPS-like L1 signals from GEO satellites to augment the number of navigation satellites available to the users.
* '''Wide Area Differential (WAD)''': differential corrections to the existing GPS/GLONASS/GEO navigation services computed in a wide area to improve navigation services performance. This includes corrections to the satellite orbits and clocks, as well as information to estimate the delay suffered from the signal when it passes through the ionosphere.
* '''GNSS/Ground Integrity Channel (GIC)''': integrity information to inform about the availability of GPS/GLONASS/GEO safe navigation service.
 
The SBAS delivers to the user the corrections and integrity data as well as some ancillary information (timing, degradation parameters, etc.) through messages encoded in the signal. The specification of the SBAS message data format is contained in the [http://www.icao.org ICAO] SARPS Appendix B for the aspects related with the signal in space, as well as in the RTCA MOPS DO-229D for the minimum performance requirements applicable to the airborne SBAS receiver equipment.  The format of the messages is thoroughly explained in the article [[The EGNOS SBAS Message Format Explained]].
 
The SBAS satellite shall transmit a GPS-like L1 (1574.42 MHz) signal, modulated with a Coarse/Acquisition Pseudo-Random Noise (PRN) code. The SBAS L1 radiofrequency characteristics are:<ref name="ICAO_SARPS">[http://www.icao.org ICAO] Standards and Recommended Practices, Annex 10, Volume 1 Radio Navigation Aids, July 2006</ref>


{| class="wikitable"
{| class="wikitable"
|-
|-
!|Parameter||Description
!Typical Operation
!Horizontal Accuracy (95%)
!Vertical Accuracy (95%)
!Integrity
!Time-To-Alert (TTA)
!Continuity
!Availability
|-
|-
|Modulation || Bi-phase shift key (BPSK) modulated by a bit train comprising the PRN code and the SBAS data (modulo-2 sum).
|Initial approach, Intermediate approach, Non-precision approach (NPA), Departure
|align="center"|220m (720ft)
|align="center"|N/A
|align="center"|1–1×10<sup>-7</sup>/h
|align="center"|10s
|align="center"|1–1×10<sup>-4</sup>/h to 1–1×10<sup>-8</sup>/h
|align="center"|0.99 to 0.99999
|-
|-
|Bandwidth || L1 ±30.69 MHz. At least 95% of the broadcast power will be contained within the L1 ±12 MHz band.
|Non Precision Approach with vertical guidance (NPV-I)
|align="center"| 220m (720ft)
|align="center"| 20m (66ft)
|align="center"| 1–2×10<sup>-7</sup> per approach
|align="center"| 10s
|align="center"| 1–8×10<sup>-6</sup> in any 15s
|align="center"| 0.99 to 0.99999
|-
|-
|Ranging Codes || A PRN Code (Gold code) of 1 millisecond in length at a chipping rate of 1023 Kbps.
|Non Precision Approach with vertical guidance (NPV-II)
|align="center"| 16m (52ft)
|align="center"| 8m (26ft)
|align="center"| 1–2×10<sup>-7</sup> per approach
|align="center"| 6s
|align="center"| 1–8×10<sup>-6</sup> in any 15s
|align="center"| 0.99 to 0.99999
|-
|-
|SBAS Data || 500 symbols per second, module-2 modulated (250 effective bits per second)
|Category I (CAT-I) Precision Approach
|-
|align="center"| 16m (52ft)
|Power || Minimum power –131 dBm at 5 degrees elevation Maximum power –119,5 dBm
|align="center"| 6.0m to 4.0m (20ft to 13ft)
|align="center"| 1–2×10<sup>-7</sup> per approach
|align="center"| 6s
|align="center"| 1–8×10<sup>-6</sup> in any 15s
|align="center"| 0.99 to 0.99999
|}
|}


A convolutional encoding of the bits is performed with the following parameters:
Usually a GBAS system is designed to fulfil CAT-I Precision Approach.
{| class="wikitable"
|-
!|Code Parameter||Value
|-
|Coding Rate || 1/2
|-
|Coding Scheme || Convolutional
|-
|Constraint Length || 7
|-
|Generator Polynomials || G1 = 171(oct); G2 = 133(oct)
|-
|Encoding Sequence || G1 then G2
|-
|Flush || No
|}
 
 
==SBAS Performances==
The SBAS performances are defined with respect to the level of service that the system is designed to provide. The main source for SBAS performances comes from civil aviation navigation safety requirements and they are different for each civil aviation operation.<ref name="ICAO_SARPS"/>
{| class="wikitable"
|-
!|Typical Operation||Horizontal Accuracy (95%)||Vertical Accuracy (95%)||Integrity||Time-To-Alert (TTA)||Continuity||Availability
|-
|En-route || 3.7 km (2.0 NM) || N/A || 1 – 1 × 10-7/h || 5 min || 1 – 1 × 10-4/h to 1 – 1 × 10-8/h || 0.99 to 0.99999
|-
|En-route Terminal || 0.74 km (0.4 NM) || N/A || 1 – 1 × 10-7/h || 15 s || 1 – 1 × 10-4/h to 1 – 1 × 10-8/h || 0.99 to 0.99999
|-
|Initial approach, Intermediate approach, Non-precision approach (NPA), Departure ||220 m (720 ft)||N/A||1 –1x10-7/h||10 s ||1 – 1x10-4/h to 1 – 1x10-8/h||0.99 to 0.99999
|-
|Approach operations with vertical guidance (APV-I) || 16 m (52 ft) || 20 m (66 ft) || 1 – 2 × 10-7 per approach || 10 s || 1 – 8 × 10-6 in any 15 s || 0.99 to 0.99999
|-
|Approach operations with vertical guidance (APV-II) || 16 m (52 ft)  || 8 m (26 ft) || 1 – 2 × 10-7 per approach || 6 s || 1 – 8 × 10-6 in any 15 s || 0.99 to 0.99999
|-
|Category I precision Approach  || 16 m (52 ft) || 6.0 m to 4.0 m (20 ft to 13 ft) || 1 – 2 × 10-7 per approach || 6 s || 1 – 8 × 10-6 in any 15 s || 0.99 to 0.99999
|}


As indicated in the table above, the performance requirements are expressed in terms of four quantitative concepts, many of them to be interpreted as probabilistic figures:
As indicated in the table above, the performance requirements are expressed in terms of four quantitative concepts, many of them to be interpreted as probabilistic figures:
* '''Accuracy''': is expressed in terms of Navigation System Error (NSE) as the difference between the real position of the aircraft and the position provided by the airborne equipment. A SBAS assures the compliance with respect the accuracy requirements by providing to the user corrections to the satellite orbit and clock errors as well as to the ionospheric residual propagation error.
* '''Accuracy''': is expressed in terms of Navigation System Error (NSE) as the difference between the real position of the aircraft and the position provided by the airborne equipment.
* '''Integrity''': is defined by [http://www.icao.org ICAO] as a measure of the trust that can be placed in the correctness of the information supplied by the system. This general statement is expressed at the SBAS system level as the maximum allowable probability that the navigation position error exceeds alarm limit and the navigation system does not alert the pilot in a time less than the time to alert. The SBAS assures the integrity requirements by:
* '''Integrity''': is defined by [http://www.icao.org ICAO] as a measure of the trust that can be placed in the correctness of the information supplied by the system.
** Providing to the user satellite and/or ionospheric alarms in order to inform the user to reject the corresponding satellite/ionospheric corrections in its positioning computation.
** Providing to the user Horizontal and Vertical Protection Level information (HPL, VPL) in order to assess the availability of the system, by comparing these PLs with the corresponding Alarm Limits (AL) for a given phase of flight (see next tabel). The SBAS computes and broadcasts integrity bounds to the satellite orbit and clock (UDRE) corrections as well as to the ionospheric corrections errors (GIVE) so that the user is able to compute a PL that over bounds the navigation system error experienced by the user with the integrity risk requirement.
 
{| class="wikitable"
|-
!Operation || Horizontal AL || Vertical AL
|-
|En-route (oceanic/continental) || 7.4 Km (4 NM) || N/A
|-
|En-route (continental) || 3.7 Km (2 NM) || N/A
|-
|En-route, Terminal || 1.85 Km (1 NM) || N/A
|-
|NPA || 556 m (0.3 NM) || N/A
|-
|APV-I || 40 m (130 ft) || 50 m (164 ft)
|-
|LPV200 || 40 m (130 ft) || 35 m (200 ft)
|-
|APV-II || 40 m (130 ft) || 20 m (66 ft)
|-
|Category I || 40 m (130 ft) || 15 to 10 m (50 ft to 33 ft)
|}


* '''Continuity''': is the probability that the specified system performance will be maintained for the duration of a phase of operation, presuming that the system was available at the beginning of that phase of operation and was predicted to operate throughout the operation. Lack of continuity means that the operation must be aborted (with the associated risk).  
* '''Continuity''': is the probability that the specified system performance will be maintained for the duration of a phase of operation, presuming that the system was available at the beginning of that phase of operation and was predicted to operate throughout the operation. Lack of continuity means that the operation must be aborted (with the associated risk).  
* '''Availability''': is the probability that the navigation service is available at the beginning of the planned operation. A SBAS is considered available when the accuracy, integrity and continuity requirements are met and it is measured in terms of probability of the system being available for any given user at any given time. In practice, the availability is computed by measuring the probability of a protrection level being below its corresponding alarm limit. It should be noted that a lack of availability is not a safety concern but prevents the nominal operation of the system, and implies an associated impact on the service operation status.
* '''Availability''': is the probability that the navigation service is available at the beginning of the planned operation. A GBAS system is considered available when the accuracy, integrity and continuity requirements are met throughout the coverage region.
 


==Notes==
==Notes==
Line 234: Line 181:


[[Category:Fundamentals]]
[[Category:Fundamentals]]
[[Category:GBAS]]

Latest revision as of 14:43, 24 July 2018


FundamentalsFundamentals
Title GBAS Fundamentals
Edited by GMV
Level Basic
Year of Publication 2011
Logo GMV.png

A Ground-Based Augmentation System (GBAS) is a civil-aviation safety-critical system that supports local augmentation –at airport level– of the primary GNSS constellation(s) by providing enhanced levels of service that support all phases of approach, landing, departure and surface operations. While the main goal of GBAS is to provide integrity assurance, it also increases the accuracy with position errors below 1 m (1 sigma).[1][2]

The Ground Based Augmentation System (GBAS) is intended primarily to support precision approach operations. It consists of a GBAS Ground Subsystem and a GBAS Aircraft Subsystem.

Introduction: How a GBAS works

(The information in this section has been taken from FAA homepage.)

A Ground Based Augmentation System (GBAS) augments the Global Positioning System (GPS) to improve aircraft safety during airport approaches and landings. It is expected that the end-state configuration will pinpoint the aircraft's position to within one meter or less with a significant improvement in service flexibility and user operating costs. GBAS is comprised of ground equipment and avionics. The ground equipment includes 4 reference receivers, a GBAS ground facility, and a VHF data broadcast transmitter. This ground equipment is complemented by GBAS avionics installed on the aircraft.[3]

Signals from GPS satellites are received by the GBAS GPS Reference Receivers at the GBAS-equipped airport. The reference receivers calculate their position using GPS. The GPS Reference Receivers and GBAS Ground Facility work together to measure errors in GPS-provided position. The GBAS Ground Facility produces a GBAS correction message based on the difference between actual and GPS-calculated position which includes as well integrity parameters and approach path information. This GBAS correction message is then sent to a VHF data broadcast (VDB) transmitter.

The VDB broadcasts the GBAS signal throughout the GBAS coverage area to avionics in GBAS-equipped aircraft. GBAS provides its service to a local area (approximately a 30 kilometer radius). The signal coverage is designed to support the aircraft's transition from en route airspace into and throughout the terminal area airspace.

The GBAS equipment in the aircraft uses the corrections provided on position, velocity, and time to guide the aircraft safely to the runway. This signal provides ILS-look-alike guidance as low as 200 feet (60 m) above touchdown. GBAS will eventually support landings all the way to the runway surface.

GBAS Architecture

GBAS architecture

A GBAS is a safety critical system designed to augment one or several satellite navigation systems. The main components of a general GBAS architecture are:

  • GBAS Ground Subsystem
  • GBAS Aircraft Subsystem
  • GNSS Satellites Subsystem

GBAS Ground Subsystem

The main purposes of the GBAS Ground Subsystem are:

  • reception and decoding of signals-in-space;
  • computation of the differential corrections to the carrier-smoothed codes;
  • integrity monitoring;
  • generation and broadcasting of GBAS messages.

The GBAS Ground Subsystem consists of:

  • 2 to 4 GNSS Reference Receivers and their respective geographically separated antennas;
  • A VHF data broadcast (VDB) transmitter;
  • A monitor system;
  • Approach Database (FAS data);
  • Ground processing functions.

GBAS Aircraft Subsystem

The main element of GBAS Aircraft Subsystem is the aircraft GBAS Receivers.

The primary functions of the GBAS aircraft subsystem are:

  • receive and decode the GNSS satellite and GBAS signals;
  • determine the aircraft position;
  • provide availability of the service;
  • compute deviations from the desired flight path calculated from the Final Approach Segment (FAS) data;
  • provide guidance signals and integrity information.

The GBAS aircraft subsystem essential elements are:

  • An Aircraft GNSS Receiver Function that receives, tracks, and decodes the GNSS satellite signals.
  • A VHF Data Broadcast Receiver Function that receives and decodes the messages broadcast by the GBAS Ground Subsystem.
  • An Aircraft Navigation Processing Function that receives the measurement of the pseudo-ranges from the GNSS Receiver Function, applies the differential corrections received from the VHF Data Broadcast Receiver Function and calculates the differentially corrected aircraft position. The Aircraft Navigation Processing Function extracts from the different FAS path construction data received, the one having the Reference Path Selector selected by the crew through the GLS Channel Number Selector. The Aircraft Navigation Processing Function also calculates deviations from the selected FAS path based on its differentially corrected position.

GNSS Satellites Subsystem

The GBAS Satellites Subsystem is mainly the GNSS constellations declared operational for civil use. The minimum requirements of a GBAS system are limited for the use of GNSS satellites ranging sources, with additional ranging sources being supplied by SBAS as an option.

GBAS Signal

The GBAS Signal in Space is defined to be only the data broadcast from the ground to the aircraft subsystem. The Satellite Signals in Space are part of the basic GNSS satellite constellations.

The GBAS ground subsystem differential computed corrections (contained in Type 1 message), GBAS ground subsystem related data (contained in Type 2 message) and Final Approach Segments (FAS) (contained in Type 4 message) are transmitted to the aircraft users via VHF Data Broadcast (VDB) Signal. The GBAS Messages are encoded in this signal. The specification of GBAS message data format is contained in the ICAO SARPS Appendix B for the aspects related with the signal in space, as well as in the RTCA MOPS DO-253C for the minimum operational performance requirements applicable to the airborne GBAS receiver equipment.

The VDB radio frequencies used shall be selected from the radio frequencies in the band 108-117.975 MHz. The lowest assignable frequency shall be 108.025 MHz and the highest frequency assignable shall be 117.950 MHz. The separation between assignable frequencies (channel spacing) shall be 25 kHz.

The GBAS message types are summarized in the following table:

Message type identifier Message Name
0 Spare
1 GBAS Differential Corrections
2 GBAS Related Data
3 Reserved for ground–based ranging source
4 Final Approach Segment (FAS) data
5 Predicted ranging source availability
6 Reserved
7 Reserved for national applications
8 Reserved for test applications
9-255 Spare

GBAS Performances

The GBAS performances are defined with respect to the level of service that the system is designed to provide. The main source for GBAS performances comes from civil aviation navigation safety requirements and they are different for each civil aviation operation. [4]

Typical Operation Horizontal Accuracy (95%) Vertical Accuracy (95%) Integrity Time-To-Alert (TTA) Continuity Availability
Initial approach, Intermediate approach, Non-precision approach (NPA), Departure 220m (720ft) N/A 1–1×10-7/h 10s 1–1×10-4/h to 1–1×10-8/h 0.99 to 0.99999
Non Precision Approach with vertical guidance (NPV-I) 220m (720ft) 20m (66ft) 1–2×10-7 per approach 10s 1–8×10-6 in any 15s 0.99 to 0.99999
Non Precision Approach with vertical guidance (NPV-II) 16m (52ft) 8m (26ft) 1–2×10-7 per approach 6s 1–8×10-6 in any 15s 0.99 to 0.99999
Category I (CAT-I) Precision Approach 16m (52ft) 6.0m to 4.0m (20ft to 13ft) 1–2×10-7 per approach 6s 1–8×10-6 in any 15s 0.99 to 0.99999

Usually a GBAS system is designed to fulfil CAT-I Precision Approach.

As indicated in the table above, the performance requirements are expressed in terms of four quantitative concepts, many of them to be interpreted as probabilistic figures:

  • Accuracy: is expressed in terms of Navigation System Error (NSE) as the difference between the real position of the aircraft and the position provided by the airborne equipment.
  • Integrity: is defined by ICAO as a measure of the trust that can be placed in the correctness of the information supplied by the system.
  • Continuity: is the probability that the specified system performance will be maintained for the duration of a phase of operation, presuming that the system was available at the beginning of that phase of operation and was predicted to operate throughout the operation. Lack of continuity means that the operation must be aborted (with the associated risk).
  • Availability: is the probability that the navigation service is available at the beginning of the planned operation. A GBAS system is considered available when the accuracy, integrity and continuity requirements are met throughout the coverage region.

Notes


References

  1. ^ GNSS augmentation in Wikipedia
  2. ^ E.D. Kaplan, C.J. Hegarty, Understanding GPS Principles and Applications”, 2nd Ed., Artch House, ISBN 1-58053-894-0, 2006.
  3. ^ LAAS-How it works by FAA.
  4. ^ ICAO Standards and Recommended Practices, Annex 10, Volume 1 Radio Navigation Aids, July 2006