Abstract
GNSS outages due to intentional jamming affecting the airspace over the Eastern Mediterranean have received significant attention in recent years. In an effort to better understand the phenomenon and its impact on aviation hardware, DLR sent a data collection flight to the area. The flight was conducted in an Airbus 320, which allowed a study of the behavior of regular avionics and aviation-grade GNSS receivers under jamming conditions. Part of the experimental instrumentation included a high-definition radio-frequency recording device, which allows in-depth pre-correlation analysis of the radio spectrum around the main GPS and Galileo carrier frequencies. The results confirm that the observed outages likely stem from man-made radio interference. They also provide an in-situ opportunity to study the behavior of commercial avionics under GNSS interference conditions.
1 INTRODUCTION
It is a well-known and documented problem within the aviation community that outages in satellite navigation services make performance-based navigation (PBN) operations, as defined by ICAO (2008), using low required navigation performance (RNP) values impossible in various parts of the world (Berz, 2016). In these areas, Global Navigation Satellite System (GNSS) receivers do not always function as desired. Radio-frequency interference (RFI) has long been touted as the main reason for such outages in GNSS-based services, not only for aviation users but also for maritime applications (Pérez Marcos, et al., 2018).
Here, we summarize the findings of a test flight conducted specifically to assess the impact of the RFI on operational GNSS avionics’ multimode receivers (MMR), such that the findings could be representative of a broader class of mainline passenger aircraft. The test flight included equipment to study the issue at different levels of abstraction: directly in the cockpit as observed by pilots in the operational environment, at the level of GNSS observables, and directly in the radio spectrum.
2 EXPERIMENT DESIGN
One location that has reported difficulties with GNSS outages is the Nicosia Flight Information Region. The Department of Civil Aviation of the Republic of Cyprus published a Notice to Airmen (NOTAM) stating, “GPS signal interruptions have been reported within Nicosia FIR. Pilots are requested to promptly report to Air Traffic Control (ATC) any GPS signal interruption experienced,” (NOTAM A0211/20, 2020; see Figure 1). Outages of GNSS-based services are a hindrance to the efficient operation of the airspace and may prevent the implementation of PBN operations with low RNP values that cannot be achieved by classical hybridization of inertial measurements with ground-based navigation facilities.
To gain a better understanding of the effect these disruptions in GNSS-based services have on passenger aircraft, the German Aerospace Center (DLR), with support of EUROCONTROL and the DCA of Cyprus, flew its Airbus 320 test aircraft (registration D-ATRA) in the Nicosia Flight Information Region (FIR). Although D-ATRA features experimental flight-test installations in what would normally be the passenger cabin, its avionics are standard equipment for an A320. Similar to most modern transport aircraft, D-ATRA features two integrated Collins GLU920 MMRs for VHF Omnidirectional Ranging (VOR), Instrument Landing System (ILS), Distance Measuring Equipment (DME), and GPS. Each one of these primary MMRs is connected to one of two Rockwell Collins GNA-910 GPS L1 antennas. The effects of RFI on this MMR are somewhat specific to the aircraft type and design philosophy, but typical for large passenger aircraft.
The experimental equipment in the cabin included a Collins GLU925 MMR and a Spirent GSS6450 I/Q radio frequency (RF) data recorder for inspection of the radio spectrum. The data recorder and the GLU925 were fed from an experimental ANTCOM 3GNSSA-XT-1 multiband GNSS antenna. This experimental antenna is a multi-band GNSS antenna installed on the upper side of the fuselage, behind the primary operational GNSS antennas as shown in Figure 2.
The signals at the L1 center frequency 1,575.42 MHz and the L5 center frequency 1,176.45 MHz were transformed to baseband and coherently sampled with 8-bit resolution and a 30.7-MHz sampling rate by the GSS6450. This allowed for a detailed analysis of the radio frequency spectrum in the frequency bands used by GNSS. The MMR in the experimental equipment granted access to more detailed measurements than the primary operational equipment allowed for. Most notably, this included quantities that potentially enable a detection capability of RFI events, such as readings of the carrier-to-noise density ratio (C/N0) and measurements of individual pseudoranges and Doppler shifts.
2.1 Flight Path
The test flight took place on February 13, 2020, taking off from Larnaca at 07:50 UTC and landing at 10:18 UTC back at Larnaca. The route of the flight, shown in Figure 3, initially went southeast towards waypoint APLON at Flight Level (FL) 300, turned east towards VELOX, then continued in northerly direction to DESPO and back to VELOX to enter a holding pattern there. After descending to FL210, we proceeded northeast towards ALSUS, then back westwards to enter holding at RUDER. In the hold, we descended to FL100 and, from there, continued toward Larnaca Airport (LCLK) conducting the VOR approach to Runway 04.
3 RESULTS
The two types of equipment, experimental and operational, yield completely different insights. The observations in the cockpit are of interest for operational considerations, as there are lessons to be learned for future generations of avionics. By contrast, the response of the experimental MMR provides a more detailed view of the effects of RFI on hardware that is widespread in aircraft that operate in the very area where this RFI is being measured. Finally, we show the characteristic of the RFI signal in the time and frequency domain, which supports the claim that the disruptions to GNSS-based services stem from a man-made signal.
3.1 Observations in the Cockpit
The loss of GPS navigation was not immediately apparent in the cockpit, as the aircraft coasted through GPS outages with its high-grade inertial reference systems. After approximately an hour of flying, which happened roughly at waypoint APLON (indicated in Figure 3) before turning toward waypoint VELOX to the East, both GPS receivers successively reported faults. These are shown in Figure 4 and indicate that the actual navigation performance (ANP) was greater than the RNP. At the same time, the primary flight display showed the message GPS Primary Lost.
For a pilot not explicitly looking for GPS interference, this would have been the first indication of a degraded navigation capability. A pilot actively looking out for RFI can have information displayed on the GPS status page of the multi-function control and display unit (MCDU), shown in Figure 5. This page is, however, not routinely monitored in regular commercial traffic.
3.2 Experimental Multimode Receiver
The experimental MMR in the experimental racks (GLU925) is a newer generation of the primary MMR in the avionics bay (GLU920). The fundamental results will not change significantly, as the limitation in performance stems directly from the RFI signals. The experimental MMR provides the number of satellites tracked by the MMR and the C/N0 estimate for each satellite.
In Figure 6, we show the number of GPS satellites tracked by the MMR for the entire flight. For most of the airborne time, fewer than four satellites were available to the MMR, making GPS unavailable. It should be noted, however, that the relatively short periods of GPS availability, visible in both graphs, were sufficient to recalibrate inertial systems, which in turn allowed the aircraft Flight Management System (FMS) to coast and continue providing navigation services.
The C/N0 provided by the experimental MMR is visualized in Figure 7. Under nominal conditions, when the RFI does not affect the MMR, there is a spread of about 10 dB in C/N0 between the best-received and the worst-received satellites. This is usually attributed to the fact that signals from satellites at different elevation angles experience different antenna gains and atmospheric effects. In Figure 7, it is evident that this condition is only given on the ground and at low altitudes, as it occurs only until shortly after take-off time (i.e., before 8:00 am) and before landing (i.e., after 10:00 am). Readers interested in the details of the antenna gain pattern on the experimental equipment may consult Caizzone et al. (2019).
Under RFI conditions, it is evident from Figure 7 that all satellites have degraded C/N0. For some legs of the flight, this degradation leads to a loss of lock condition. Notwithstanding, for some brief moments the experimental MMR is able to track satellite signals in flight and even compute GPS-based position solutions.
Overall, the experimental MMR was denied from computing a position solution for 80% of the experiment time; note that this includes taxiing, takeoff, and landing. The results in Figure 6 show the number of satellites available for a position solution for the entire flight route. At points with four or more available satellites, the MMR computed the corresponding positions and the avionics were able to recalibrate the inertial sensors.
3.3 Radio Spectrum
The graphic in Figure 8 is a spectrogram around the L1 and L5 center frequencies over a time period of 1.5 hours during the flight. The sampling time of the spectromgram was 10 s, in the sense that every 10 s, we computed the power spectral density over a Hamming window of 0.1 ms, for a total of over three million signal samples per epoch. In the L1 spectrum, we observed interference around the L1 center frequency, as well as 15 MHz above. The bandwidth of the interference at the center of the L1 frequency was 1 MHz. The averaged power ratio between the signal interference and the noise floor was 10 dB.
To better understand the time behavior of the RFI signal, we analyzed the signal in the L1 band over a shorter time. We computed the frequency with the maximum power spectral density over a few ms to better visualize the triangular frequency chirp, a telltale sign of intentional RFI. The excerpt in Figure 9 shows a section of 30 ms, starting at 09:00. The shape of the signal corresponds to a frequeny sweep with 1-MHz bandwidth and a period of approximately 1 ms. These parameters are very much in line with what can be expected from intentional, high-power RFI (Fernández Hernández, et al., 2019).
Another useful result of Figure 8 is that the interference signal shown has a peak power of at least 30 dB above the noise floor upon reception at the aircraft. This signal characteristic leads us to conclude that the RFI source could be a high-power interferer or J2, in the nomenclature of Fernández Hernández et al. (2019). This interpretation is also consistent with the observations reported in Murrian et al. (2019); the authors also provide a 95% confidence interval for the position of a J2 jammer that is consistent with the observations in this paper. Note that no significant interference signal appears in the L5 band.
4 DISCUSSION
An immediate consequence of RFI in the Nicosia FIR is that GPS-based services are unavailable to aviation users. In particular, this applies to performance-based navigation (PBN), a class of services that aims to modernize air-traffic operations. While some PBN service types can continue operating during RFI by resorting to ground-based navigation infrastructure and inertial sensors, PBN operations with low RNP values can suffer timeouts if inertial sensor data are fused with GPS measurements. PBN operations that rely entirely on GPS (Localizer Performance with Vertical Guidance GPS Landing System) become unavailable. Furthermore, the Automatic Dependent Surveillance – Broadcast (ADS-B) functionality may be limited when integrity on the transmitted position information cannot be guaranteed, which is the case if GNSS is unavailable.
In practice, this means that aircraft need to accommodate greater safety margins, thus forcing greater separation between aircraft on adjacent routes. The lack of low RNP impacts the capacity of the airspace, as well as its operational efficiency (Aviation Intelligence Unit, 2021).
From an operational perspective, it is, of course, desirable to continue providing navigation services during GNSS outages. This type of service is commonly referred to as alternative position, navigation, and timing (APNT). The conventional view that APNT services are to bridge short-term outages is consistent with sparse, infrequent events of low-power, local RFI as described by Pullen and Gao (2012). Instead, our results show that APNT systems will likely be required to provide long-term, or even permanent, services to aviation users in some parts of the world.
HOW TO CITE THIS ARTICLE
Osechas, O., Fohlmeister, F., Dautermann, T., & Felux, M. (2022) Impact of GNSS-band radio interference on operational avionics. NAVIGATION, 69(2). https://doi.org/10.33012/navi.516
ACKNOWLEDGMENTS
The authors want to thank Gerhard Berz and Valeriu Vitan, of EUROCONTROL, for their unwavering support in setting up contacts with the DCA and DEC in Nicosia. We are also thankful to Nicos Nicolaou from the DCA and Andronikos Kakkouras from DEC for their valuable support, interfacing with Larnaca Airport and with the Nicosia FIR.
Also, we would like to thank the DLR program office LAO for funding the flight tests. Furthermore, test pilots Jens Heider and Peter Baumann, FTI Specialists Hayung Becker and Andreas Buschbaum, aircraft engineer Silvio Heyne, flight test engineers Malte Kreienfeld and Robert Geister, and senior scientist facilitator Thomas Ludwig.
This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.