As air transport continues to grow, the use of Global Satellite Navigation Systems (GNSS) for Flight Navigation
is increasing. So too is the move towards using systems that support Required Navigation Performance
(RNP). Augmentation Systems to GNSS, both Satellite-Based Augmentation Systems (SBAS), such as Wide
Area Augmentation System (WAAS) and European Geostationary Navigation Overlay System (EGNOS) are
already in use but the adoption of the Local Area systems such as the Ground-Based Augmentation Landing
System (GBAS Landing System) for airport precision approach and category I, II, and III landing operations is
on the rise. A critical system such as this must meet stringent performance indicators for RNP and be sure to
maintain accuracy and stability under the full range of real-world conditions.
In order to help developers and integrators to test the airborne GNSS receiver in their GBAS Landing System,
Spirent has developed the GSS4150 solution. The GSS4150 GBAS Landing System VDB Simulator has been
designed to add a single, integrated source of the VHF Data Broadcast (VDB) augmentation signal to Spirent’s
range of GNSS RF constellation simulators - in a rack-mountable chassis.
GSS4150
The integrated solution to
GNSS + GBAS functional testing
GSS4150
The integrated solution to GNSS + GBAS functional testing
No. 1
The rst source is the error modelling
applied to a simulated GNSS reference
receiver, the location for which is user-
specied. The various simulated system
effects are calculated and the resulting
errors are compiled into the differential
corrections for message type 1 of
GBAS.
The GSS4150 varies the
signal level in response to
the distance of separation
from the dened simulated
transmitter location and
the simulated aircraft
position, and in response
to the simulated VHF
antenna reception pattern.
No. 2
The second source is the xed data entered by the user
via detailed on-screen forms that is required by message
types 2 and 4, and for some elds associated with
message type 1. The GSS4150 varies the signal level in
response to the distance of separation from the dened
simulated transmitter location and the simulated aircraft
position, and in response to the simulated VHF antenna
reception pattern.
GSS4150B
Data messages are constructed in real time from two sources associated with the host GNSS Simulator:
Airport
Authorities
Airline
Operators
Avionics
Manufacturers
Airframe
Manufacturers
GSS4150
GBAS Test
Solution
GBAS
System
Developers
GBAS
System
Integrators
Other Aircraft
Systems
GSS4150
VDB Signal
Generator
GSS7000
GSS9000
& GSS6700
Synchronisation Signals
GNSS RF
VDB RF LOC RF (option)
Host Control
Ethernet
(Optional remote control)
Synchronisation
Signals
SimGEN
Controller
Airborne
GPS/DGPS
Equipment
under test
Specications
The GSS4150 comprises a VHF signal source generator and software extensions contained within Spirent’s
SimGEN software. It supports message types:
Signal Capability
Parameter Comment Value
Number of VHF Signal Sources 1 channel
Carrier Frequency Minimum
Maximum
Resolution
108.000MHz
117.975MHz
0.025MHz
Symbol Rate Fixed 10.500 symbols/s
Modulation D8PSK
TDMA Timing Reference RTCA DO-246 As ICD
Maximum Signal Level At RF port
(represents modelled received power at VHF antenna)
-50dBm
Signal Level Control Range 40dB
0.5dB
Signal Level Accuracy 1-sigma calibration uncertainty 1dB (RSS)
Adjacent channel suppression First Channel
Second Channel
-40dBc
-65dBc
Message Types 1 2 3 Differential Corrections 100 second smoothed pseudoranges
Message Type 2 GBAS related data
Message Type 4 FAS and TAP construction data
Message Types 5 2 3 Ranging Source Availability
Message Types 11 2 3 Differential Corrections 30 second smoothed pseudoranges
Specied Accuracy
Parameter Comment Value
Uncertainty in calibrated simulated power at
maximum power power level
±0.7dB (RSS)
±1.0dB (Max)
Signal Level Run-to-Run variance under same environmental
conditions
<0.2dB
Linearity <±0.5dB
Carrier Frequency The unit will normally be frequency locked to
an external reference from the simulator, and is
dependent on its calibrated accuracy.
Master clock may be manually adjusted to < 0.02Hz
error at calibration interval (1 year).
<±5Hz at
108MHz
after one year
(absolute)
Contact Us
For more information, call your Spirent sales representative or
visit us on the web at www.spirent.com/ContactSpirent.
www.spirent.com
© 2019 Spirent Communications, Inc. All of the company names and/or brand names
and/or product names and/or logos referred to in this document, in particular the
name “Spirent” and its logo device, are either registered trademarks or trademarks
pending registration in accordance with relevant national laws. All rights reserved.
Specications subject to change without notice.
Americas 1-800-SPIRENT
+1-800-774-7368 | sales@spirent.com
US Government & Defense
info@spirentfederal.com | spirentfederal.com
Europe and the Middle East
+44 (0) 1293 767979 | emeainfo@spirent.com
Asia and the Pacic
+86-10-8518-2539 | salesasia@spirent.com
MCD00388 Issue 1-03 | RevC | 03/19
GSS4150
The integrated solution to GNSS + GBAS functional testing
Signal Capability
Port In/Out Type Characteristics
RF OUT COAXIAL
Type ‘N’ Female
Front Panel
Provides the primary RF GPS signal
output at specied levels.
50 ohm
VSWR <1.2:1 (band)
DC isolated
EXT REF
External reference
IN COAXIAL BNC socket
Rear Panel
Allows locking to external simulator
references
10MHz
Internal Reference Oscillator
OUT COAXIAL BNC socket
Rear Panel
10MHz Sine
0 dBm normal
50 ohm
1PPS OUT
(1 pulse per second)
OUT 25-Way D-Type
Rear Panel
TTL level compatible
Normal width 100ms
50 ohm
HOST PC IN/OUT USB downstream connector Control interface
110/240V ac IN International Standard
Rear Panel
