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Preliminary Design of GBAS Onboard Test Equipment

  • Jeong, Myeong-Sook (CNS/ATM Team, CNS/ATM and Satellite Navigation Research Center, Korea Aerospace Research Institute) ;
  • Ko, Wan-Jin (CNS/ATM Team, CNS/ATM and Satellite Navigation Research Center, Korea Aerospace Research Institute) ;
  • Bae, Joong Won (CNS/ATM Team, CNS/ATM and Satellite Navigation Research Center, Korea Aerospace Research Institute) ;
  • Jun, Hyang Sig (CNS/ATM Team, CNS/ATM and Satellite Navigation Research Center, Korea Aerospace Research Institute)
  • Received : 2013.03.29
  • Accepted : 2013.04.30
  • Published : 2013.04.30

Abstract

When the ground subsystem of Ground Based Augmentation System(GBAS) is installed at the airport, the functions and performance of subsystem should be evaluated through ground and flight testing at the pre-commissioning phase. In the case of GBAS flight testing, it can be conducted by the existing flight check aircraft, but the GBAS ground testing requires the development of specially customized equipment to perform the ground testing. Therefore, this paper describes the preliminary design of GBAS onboard test equipment which can be independently used for the GBAS ground testing and flight testing on a car and an aircraft.

Keywords

1. INTRODUCTION

Recently, an aircraft landing service using the Instrument Landing System (ILS) is facing a number of limits in terms of landing efficiency and economical feasibility. Therefore, many countries pursue a strategy for providing a GNSS based aircraft landing service instead of the existing ground based navigation equipment (e.g., VOR, NDB, and ILS) (Jun et al. 2010). The Ground Based Augmentation System (GBAS), which was developed as part of this effort, is a system that provides the precision approach service and precision positioning service to guide the runway landing of aircraft located within a 20NM radius of airport. The actual development of GBAS has been conducted in the United States and Europe since the mid-1990s. As the SLS-4000 model, which is a GBAS ground subsystem of Honeywell Company from the United Sates, obtained the Category I (CAT-I) level product certification by the Federal Aviation Administration (FAA) in September 2009, the research on the applicability of GBAS is actively being carried out around the globe (Bea et al. 2011, Jeong et al. 2012).

The countries that are currently conducting research on the GBAS include the United States, Germany, Spain, Japan, Brazil, and Australia. Also, in Korea, the research on the development of GBAS operational technology has been performed from September 2010 to establish a domestic GBAS CAT-I certification system by the Korea Aerospace Research Institute. In the case of Germany, by installing the SLS-4000 of Honeywell Company at the Bremen Airport, the GBAS operational approval was obtained in February 2012 for the first time in the world, and it is currently in operational use by the Air Berlin (Dunkel 2012, Weber & Dunkel 2011, Weber 2011). The Newark Airport in the United States obtained the operational approval in September 2012 for the second time in the world, and additionally, the Houston Airport in the United States and the Malaga Airport in Spain are conducting research with the goal of obtaining the operational approval in 2013 (Alvarez & Callejo 2012).

In the case of Korea, construction is in progress from January 2013 to install the SLS-4000 of Honeywell Company from the United States at the Gimpo International Airport which was selected as the domestic GBAS testing airport, and the installation is expected to be completed by the end of June 2013. After the completion of SLS-4000 equipment installation at the airport, by sequentially performing the ground testing and evaluation and flight testing and evaluation, it will be evaluated whether the functions and performance of SLS-4000 at the Gimpo International Airport satisfy the CAT-I service requirements.

Therefore, in order to smoothly perform the ground and flight testing and evaluation that will be carried out from the latter half of this year to the first half of next year, customized equipment is required which can be loaded on a car and an aircraft and can evaluate the GBAS ground and flight testing and evaluation items stipulated by the International Civil Aviation Organization (ICAO) (ICAO Doc 8071 Vol. II 2007, ICAO Annex 10 Vol. I 2006, EUROCAE ED-114 2003, FAA-order-8200.1C 2005). In this paper, the hardware and software design of GBAS onboard test equipment is described which was specially customized for the GBAS ground and flight testing and evaluation.

2. OVERVIEW ON GBAS ONBOARD TEST EQUIPMENT

The purpose of GBAS onboard test equipment development is to evaluate the functions and performance required for the equipment, prior to commissioning, after the installation of GBAS ground subsystem at the airport. At the pre-commissioning phase, the functions and performance required for the GBAS ground subsystem should be evaluated through the ground and flight testing and evaluation items stipulated by the ICAO 8071 Vol. II as shown in Table 1. Therefore, for the hardware and software design of GBAS onboard test equipment, the hardware components and software functional requirements necessary for the test were obtained by examining the testing and evaluation items stipulated by the ICAO 8071 Vol. II.

Table 1. GBAS functional requirements (ICAO Doc 8071 Vol. II 2007).

Parameter Annex 10 vol. I Testing
Position domain accuracy (functional test)
Pseudorange domain accuracy
Continuity (GBAS ground system)
Ground Pseudorange Uncertainty
Tropospheric delay and residual tropospheric
Uncertainty
GCID indication
Residual ionospheric uncertainty
Reference antenna phase centre position accuracy
FAS data points accuracy
Integrity monitoring for GNSS ranging sources
Resistance to interference (range signal)
Procedure validation
Runway surface coverage
Message block header
Data content
VDB coverage
Carrier frequency /Carrier frequency stability
Monitering
TDMA slot monitoring
VDB transmitter power monitor
Power in adjacent channels
3.7.2.4.1 & Table 3.7.2.4-1
App. B 3.6.7.1.1
App. B 3.6.7.1.3
App. B 3.6.7.2.2.4
App. B 3.6.7.2.3.1
 
App. B 3.6.7.2.3.2
App. B 3.6.7.2.3.5
App. B 3.6.7.2.3.3
App. B 3.6.7.2.4.1
App. B 3.6.7.2.6
App. B 3.7
-
3.7.3.5.3.2
App. B 3.6.3.4.1
App. B 3.6.4
 
3.7.3.5.4.1
App. B 3.6.7.3
App. B 3.6.7.3.1.2
App. B 3.6.7.3.1.3
3.7.3.5.4.5
F/G
G
G
G
G
 
F/G
G
G
G
F
F/G
F
G
G
F/G
 
G
 
G
G
G

 

As for the GBAS ground and flight testing and evaluation items shown in Table 1, the testing and evaluation is broadly divided into GBAS position accuracy evaluation, continuity evaluation, consistency evaluation of VHF Data Broadcast (VDB) message, VDB field strength evaluation, signal interference evaluation of VDB and Global Positioning System (GPS), and validity evaluation of approach procedure. Therefore, the major functional requirements for the GBAS onboard test equipment to perform the test are as follows.

◦ Reception of GPS satellite signal, GBAS VDB signal, and DGPS correction signal◦ Generation of aircraft navigation data, landing guidance data, and flight trajectory data◦ Gathering and analysis of VDB and GPS radio wave output◦ Simple performance monitoring for GBAS navigation and landing guidance data◦ Display and storage for the input/output data of measuring devices

On the other hand, as the GBAS onboard test equipment will be used for both the ground testing and evaluation and flight testing and evaluation, the equipment was designed to be operated independently on a car and an aircraft by constructing a customized independent system as shown in Fig. 1. Also, based on the previously obtained functional requirements, the onboard test equipment was designed so that it can output and display aircraft navigation data(position, velocity, and time), approach guidance data, and VDB field strength and signal interference data by receiving the VDB signal transmitted from GBAS ground subsystem and the GPS satellite signal, and that it can store all the collected data for post processing. Moreover, the equipment was designed to have a monitoring function for its own GBAS navigation and approach data so that it can perform simple performance evaluation in real time.

Fig. 1. Concept of GBAS onboard test equipment operation.

3. HARDWARE DESIGN

3.1 Hardware Components and Functions

As shown in Table 2, the hardware of GBAS onboard test equipment is composed of controller, measuring devices, power supply, display unit, antennas, and rack. The measuring devices are again composed of Multi-Mode Receiver (MMR), RF power meter, Differential GPS(DGPS) receiver, and spectrum analyzer. The controller controls and stores the input/output data of MMR, RF power meter, spectrum analyzer, and DGPS receiver which are the measuring devices, the display unit displays the data outputted from the controller for user, and the power supply provides the power necessary for the controller, measuring devices, and display unit. The measuring devices generate various measurement data needed for GBAS performance evaluation by receiving the GPS signal, VDB signal, and DGPS correction signal. The antennas consist of 1 GPS antenna, 1 VHF antenna, and 1 DGPS modem antenna, and provide a signal to each measuring device via each splitter. The rack fastens each component, and protects from external shock.

Table 2. Equipment component list.

Level 1 Level 2 Level 3
GBAS
onboard test 
equipment
Controller Computer
ARINC 429 interface card
Analog/Digital interface card
Chassis
Measuring devices MMR
RF power meter
DGPS receiver (equipped DGPS modem)
Spectrum analyzer
Power supply Power distributor
DC to AC converter
Battery
Display unit Monitor/Keyboard
Notebook
Antennas GPS antenna
DGPS modem antenna
VHF antenna
Splitter
Rack  

 

As for the detailed function of each measuring device, the MMR generates the aircraft navigation data and landing guidance data by receiving the GPS signal and GBAS VDB signal which are received via the GPS antenna and VHF antenna. The RF power meter measures the VDB field strength, the spectrum analyzer measures the GPS and VDB signal interference, and the DGPS receiver generates the precision navigation data using a Real Time Kinematic (RTK) survey technique. The position data, which is outputted from the DGPS receiver, is used as the reference trajectory of an aircraft and a car, and will be utilized for the accuracy of GBAS position data outputted from the MMR and the various performance monitoring functions.

3.2 Hardware Interface

Fig. 2 shows the interface among each component of GBAS onboard test equipment, and the controller was designed to transmit and receive the control command and output data for each measuring device. The controller uses the ARINC 429 communication to transmit and receive the input/output data for the MMR, the USB communication for the RF power meter and spectrum analyzer, and the RS232 communication for the DGPS receiver.

Fig. 2. Hardware interface of the GBAS onboard test equipment.

4. SOFTWARE DESIGN

4.1 Software Functional Requirements

The functional requirements of GBAS onboard test equipment software for performing the ground and flight testing and evaluation on the GBAS ground subsystem were designed so that they are broadly divided into system control function, output data display function, simple performance monitoring function for the GBAS navigation and approach data, and input/output data storage function for each component of measuring device as shown in Fig. 3, and the detailed design decisions for the functional requirements were defined as shown in Table 3.

Fig. 3. Software functional requirements.

Table 3. Design decisions for software functional requirements.

Detailed function Design decisions
Integrated system control The integrated system control comprehensively controls the architecture and algorithm of GBAS onboard test equipment software.
MMR control The MMR is broadly divided into navigation mode and approach mode depending on operation type. The navigation mode is divided into GPS navigation mode and GBAS navigation mode, and the approach mode is divided into ILS mode and GLS mode. The GBAS onboard test equipment generates and controls the function necessary for each operation mode of MMR.
RF power meter control Generates and controls the functions necessary for the RF power meter operation.
DGPS receiver control Generates and controls the functions necessary for performing the RTK navigation mode of DGPS receiver.
Spectrum analyzer control Generates and controls the functions necessary for the GPS and VDB signal interference analysis.
Status display Displays the result of self test for each measuring device.
Approach guidance display Displays the approach guidance data such as course deviation, runway azimuth, and airport ID which are outputted for each approach mode of MMR.
MMR navigation data display Displays the navigation data such as position, velocity, time, and satellite status which are outputted for each navigation mode of MMR.
VDB message display Displays the GBAS VDB message outputted from the MMR.
VDB field strength display Displays the VDB field strength outputted from the RF power meter.
DGPS navigation data display Displays the time and satellite status along with the precision position and velocity data outputted from the DGPS receiver.
Signal interference display Displays the GPS and VDB signal interference data outputted from the spectrum analyzer.
Protection level monitoring When the MMR is in GLS mode, it monitors the approach service protection level data outputted from the MMR by comparing with the alarm limit standard depending on GLS grade.
Position error monitoring When the RTK is available, it monitors the accuracy of navigation data outputted from the MMR based on the precision position data obtained from the RTK.
Course deviation monitoring When the RTK is available and the MMR is in GLS mode, it monitors the accuracy of aircraft vertical/lateral course deviation data outputted from the MMR.
LTP/FTP distance monitoring When the RTK is available and the MMR is in GLS mode, it monitors the accuracy of the distance data from aircraft to Landing Threshold Point/Fictitious Threshold Point (LTP/FTP) outputted from the MMR.
Input/Output data storage Separates and stores the input data and output data of each measuring device.

 

4.2 Design of Software Architecture

The onboard test equipment software operates on the controller of onboard test equipment as shown in Fig. 4. The software controls each measuring device and outputs the navigation and landing guidance data, the VDB message and VDB field strength data, and the status of GPS satellite in real time. The software was designed to have a separate control module for each measuring device to enable independent control and operation of each measuring device. When the RTK is available, the software performs the comparison operation for the two navigation data outputted from the MMR and DGPS receiver, and through this process, performs the simple performance monitoring function for the GBAS navigation data. Also, the onboard test equipment software is able to check the status of each measuring device with the self test function, and immediately outputs the fault data to operator when there is a problem. For each measuring device, the control input data and output data are separated and stored.

Fig. 4. Connection architecture of hardware and software.

4.3 Software CSCI

For the GBAS onboard test equipment software, an architectural analysis/design technique was applied which performs the modular design by matching the function and characteristic for each Computer Software Unit (CSU) of Computer Software Configuration Item (CSCI) considering the scalability and maintainability. The CSCI of GBAS onboard test equipment software was designed as shown in Fig. 5 based on the detailed software functional requirements defined in Fig. 3.

Fig. 5. CSCI of GBAS onboard test equipment.

4.4 Execution Concept of Software

Fig. 6 shows the execution concept diagram of onboard test equipment software. When the onboard test equipment CSCI execution file is performed after applying the power to the onboard test equipment, an integrity system control program controls each measuring device by calling the self test function, MMR control function, RF power meter control function, DGPS receiver control function, and spectrum analyzer control function, and simultaneously stores the input and output data of each measuring device by calling the input/output data storage function. The self test function and each measuring device control function, which were called, again display the output data by calling the status display function, MMR navigation data display function, approach guidance data display function, VDB message display function, VDB field strength display function, DGPS navigation data display function, and signal interference display function. And when the MMR and DGPS receiver are available, the protection level monitoring function, position error monitoring function, course deviation monitoring function, and LTP/FTP distance monitoring function are also called.

Fig. 6. Execution concept of software.

5. CONCLUSIONS

When the GBAS ground subsystem is installed at the airport, the functions and performance of the system should be evaluated at the pre-commissioning phase. Therefore, this paper examined the GBAS onboard test equipment which was designed to independently perform the GBAS ground testing and flight testing on a car and an aircraft. In this paper, the hardware components necessary for the GBAS onboard test equipment were presented, and the function of each component and the hardware interface among each component were described. Regarding the software, the software functions required for the testing and evaluation were summarized, and the software CSCI and execution concept which were designed based on the functional requirements were described. The GBAS onboard test equipment is currently being manufactured based on the design described in this paper, and the ground testing and evaluation for the Honeywell SLS-4000 installed at the Gimpo International Airport will be carried out using the equipment in the latter half of this year.

References

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