As
reported by Inside GNSS: GNSS jammers are small portable devices able to broadcast
powerful disruptive signals in the GNSS bands. A jammer can overpower the much
weaker GNSS signals and disrupt GNSS-based services in a geographical
area with a radius of several kilometers. Despite the fact that the use
of such devices is illegal in most countries, jammers can be easily
purchased on the Internet and their rapid diffusion is becoming a
serious threat to satellite navigation.
Several studies have analyzed the characteristics of the signals emitted
by GNSS jammers. From the analyses, it emerges that jamming signals are
usually characterized by linear frequency modulations: the
instantaneous frequency of the signal sweeps a range of several
megahertz in a few microseconds, affecting the entire GNSS band targeted
by the device.
The fast variations of their instantaneous frequency make the design of
mitigation techniques particularly challenging. Mitigation algorithms
must track fast frequency variations and filter out the jamming signals
without introducing significant distortions on the useful GNSS
components. The design problem becomes even more challenging if only
limited computational resources are available.
We have analyzed the ability of an adaptive notch filter to track fast
frequency variations and mitigate a jamming signal. In this article, we
begin by briefly describing the structure of the selected adaptive notch
filter along with the adaptive criterion used to adjust the frequency
of the filter notch.
When the adaptation parameters are properly selected, the notch filter
can track the jamming signals and significantly extend the ability of a
GNSS receiver to operate in the presence of jamming. Moreover, the
frequency of the filter notch is an estimate of the instantaneous
frequency of the jamming signal. Such information can be used to
determine specific features of the jamming signal, which, in turn, can
be used for jammer location using a time difference of arrival (TDOA)
approach.
The capabilities of the notch filter are experimentally analyzed
through a series of experiments performed in a large anechoic chamber.
The experiments employ a hardware simulator to broadcast GPS and
Galileo signals and a real jammer to disrupt GNSS operations. The GNSS
and interfering signals were recorded using an RF signal analyzer and
analyzed in post-processing. We processed the collected samples using
the selected adaptive notch filter and a custom GNSS software receiver
developed in-house.
The use of mitigation techniques, such as notch filtering, significantly
improves the performance of GNSS receivers, even in the presence of
strong and fast-varying jamming signals. The presence of a pilot tone in
the Galileo E1 signal enables pure phase-locked loop (PLL) tracking and
makes the processing of Galileo signals more robust to jamming.
Adaptive Notch Filter
Several interference mitigation techniques have been described in the
technical literature and are generally based on the interference
cancellation principle. These techniques attempt to estimate the
interference signal, which is subsequently removed from the input
samples. For example, transform domain excision techniques at first
project the input signal onto a domain where the inference signal
assumes a sparse representation. (See the articles by J. Young
et alia and M. Paonni
et alia,
referenced in the Additional Resources section near the end of this
article.) The interference signal is then estimated from the most
powerful coefficients of the transformed domain representation. The
interfering signal is removed in the transformed domain, and the
original signal representation is restored.
When the interfering signal is narrow band, discrete Fourier transform
(DFT)-based frequency excision algorithms, described in the article by
J. Young and J. Lehnert, are particularly effective. Transform domain
excision techniques are, however, computationally demanding, and other
mitigation approaches have been explored. For example, notch filters are
particularly effective for removing continuous wave interference (CWI).
M. Paonni
et alia, cited in Additional Resources, considered
the use of a digital notch filter for removing CWI, the center frequency
of which was estimated using the fast Fourier transform (FFT)
algorithm. Despite the efficiency of the FFT algorithm, this approach
can result in a significant computational burden and alternative
solutions should be considered.
The article by M. Jones described a finite impulse response (FIR) notch
filter for removing unwanted CW components and highlighted the
limitations of this type of filter. Thus, we adopted an infinite impulse
response (IIR) structure and experimentally demonstrated its
suitability for interference removal. In particular we considered the
adaptive notch filter described in the article by D. Borio
et alia listed in Additional Resources and investigated its suitability for mitigating the impact of a jamming signal.
This technique has been selected for its reduced computational
requirements and for its good performance in the presence of CWI. Note
that the notch filter under consideration has been extensively tested in
the presence of CWI; however, its performance in the presence of
frequency-modulated signals has not been assessed. Also, note that
removing a jamming signal poses several challenges that derive from the
swept nature of this type of interference. (For details, see the paper
by R. H. Mitch
et alia.)
Jamming signals are usually frequency modulated with a fast-varying
center frequency. The time-frequency evolution of the signal transmitted
by an in-car GPS jammer is provided as an example in
Figure 1.
The instantaneous center frequency of the jamming signal sweeps a
frequency range of more than 10 megahertz in less than 10 microseconds.
The adaptation criterion selected for estimating the center frequency of
the jamming signal has to be sufficiently fast to track these frequency
variations.
The notch filter considered in this work is characterized by the
following transfer function (illustrated on the opening page of this
article)
Equation 1 (for equations see inset photo, above right)
where
kα is the pole contraction factor and
z0[
n] is the filter zero.
kα controls the width of the notch introduced by the filter, whereas
z0[
n] determines the notch center frequency. Note that
z0[
n]
is progressively adapted using a stochastic gradient approach described
in the textbook by S. Haykin with the goal of minimizing the energy at
the output of the filter. A thorough description of the adaptation
algorithm can be found in the article by D. Borio
et alia.
The notch filter is able to place a deep null in correspondence with the
instantaneous frequency of narrow band interference and, if the zero
adaptation parameters are properly chosen, to track the interference
frequency variations. The energy of the filter output is minimized when
the filter zero is placed in correspondence with the jammer
instantaneous frequency
Equation 2
where Φ(
nTs) is the jammer instantaneous frequency and
fs = 1/
Ts is the sampling frequency.
This implies that
z0[
n] can be used to estimate the instantaneous frequency of the interfering signal. The magnitude of
z0[
n] also strongly depends on the amplitude of the interfering signal. Indeed, |
z0[
n]| approaches one as the amplitude of the jamming signal increases. Thus, |
z0[
n]| can be used to detect the presence of interference, and the notch filter activates only if |
z0[
n]| passes a predefined threshold,
Tz. A value of
Tz= 0.75 was empirically selected for the tests described in the following section.
Experimental Setup and Testing
To test the capability of the adaptive notch filter to mitigate against a
typical in-car jammer, we conducted several experiments in a large
anechoic chamber at the Joint Research Centre (JRC) of the European
Commission.
Figure 2
provides a view of the JRC anechoic chamber where the jamming tests
were conducted. The anechoic chamber offers a completely controlled
environment in which all sources of interference besides the jammer
under test can be eliminated.
The experimental setup is similar to that employed to test the impact of
LightSquared signals on GPS receivers (For details, see the article by
P. Boulton
et alia listed in Additional Resources). We used a
simulator to provide a controlled GPS and Galileo constellation, with a
static receiver operating under nominal open-sky conditions. The GNSS
signals were broadcast from a right hand circular polarization (RHCP)
antenna mounted on a movable sled on the ceiling of the chamber. A
survey grade GNSS antenna was mounted inside the chamber, and the sled
was positioned at a distance of approximately 10 meters from this
antenna. The GNSS receiving antenna was connected via a splitter to a
spectrum analyzer, an RF signal analyzer, and a commercial high
sensitivity GPS receiver.
Table 1 (see inset photo, above right) lists the RF signal analyzer parameters.
To provide the source of jamming signals a commercially available
(though illegal) in-car jammer was connected to a programmable power
supply. We removed the jammer’s antenna and connected the antenna port,
via a programmable attenuator with up to 81 decibels of attenuation, to a
calibrated standard gain horn antenna. This gain horn was positioned at
approximately two meters from the GNSS receiving antenna.
The goal of this configuration was to permit variation of the total
jammer power received at the antenna.
Unfortunately, the jammer itself
is very poorly shielded; so, a significant amount of the interfering
power seen by the receiver was found to come directly from the body of
the jammer, rather than through the antenna.
To minimize this effect, we exercised great care to shield the jammer as
much as possible from the GNSS antenna. We placed the jammer body in an
aluminum box, which was subsequently surrounded by RF absorbent
material. The jammer body and the receiving GNSS antenna were separated
by approximately 15 meters, thereby ensuring approximately 60 decibels
of free space path loss.
The experiment was controlled via a PXI controller, which generated
synchronous triggers for the RF data collection and simulator signal
generation, controlled the power supplied to the jammer, and updated the
attenuation settings according to a desired profile. All events
(trigger generation, jammer power on/off, attenuation setting) were time
stamped using an on-board timing module. The commercial receiver was
configured to log raw GPS measurements including carrier-to-noise (C/N
0) values.
The experimental procedure involved two trials, each lasting
approximately 40 minutes. In the first trial, the simulator and data
collection equipment were both enabled, but the jammer remained powered
off. In the second trial, the same scenario was generated in the
simulator, the data collection equipment was enabled and, after a period
of three minutes, the jammer was powered on.
We initially set the attenuation to its maximum value of 81 decibels. We
subsequently reduced this in two-decibel decrements to a minimum value
of 45 decibels. We maintained each level for a period of 60 seconds.
Finally, we again increased the attenuation in two-decibel increments to
its maximum value.
Figure 3 presents this attenuation profile.
We performed a calibration procedure whereby the total received jammer
power at the output of the active GNSS receiving antenna was measured
using a calibrated spectrum analyzer while the attenuation level was
varied. Further, the total noise power was measured in the same
12-megahertz bandwidth with the jammer switched off. This permitted the
computation of the received jammer-to-noise density power ratio (J/N
0) as a function of the attenuator setting.
Figure 3 also shows the calibrated J/N
0 at the output of the
active GNSS antenna as a function of time. The analysis provided in the
next section is conducted as a function of the J/N
0.
Sample Results
This section provides sample results obtained using the adaptive notch filter described earlier. In particular, the loss in C/N
0 experienced by the GPS and Galileo software receivers used for analysis is experimentally determined as a function of the J/N
0.
The adaptive notch filter is used to reduce the C/N
0 loss.
Figure 4 shows the loss in C/N
0 experienced in the presence of the jammer as a function of J/N
0.
The first curve arises from software receiver processing of the GPS
signals, the second plot from software receiver processing of the
Galileo signals, and the third from the commercial high sensitivity
receiver that processed only the GPS signals.
Note the small difference between the GPS and Galileo results. This is
to be expected due to the wideband nature of the jammer. In fact, for
both GPS and Galileo processing the jammer is effectively averaged over
many chirp periods, thereby giving it the appearance of a broadband
(white) noise source. The one difference between the GPS and Galileo
signals is that the tracking threshold of the Galileo signals is
approximately six decibels lower than that for the GPS signals. This is
due to the use of a pure PLL processing strategy using only the E1C
(pilot) component of the Galileo signal.
The other interesting point to note from Figure 4 is that the commercial
receiver exhibits better resilience against the jammer. This is most
likely due to a narrower front-end bandwidth in the commercial receiver,
although this cannot be confirmed because the receiver manufacturer
does not provide this information.
From the time-frequency evolution of the jamming signal used for the
experiment and shown in Figure 1, it emerges that the bandwidth of the
jamming component is approximately 10 megahertz. If the commercial
receiver had a smaller bandwidth, then it would effectively filter out
some of the jammer power, thereby improving its performance with respect
to the software receiver results.
Figure 4 provides an indication of the performance degradation caused by
a jamming signal when no mitigation technique is employed. The notch
filter is expected to improve the receiver performance. The improvement
depends on the filter parameters and their ability to track the jammer’s
rapid frequency variation.
Two configurations of the adaptive notch filter were tested:
kα = 0.8 and
kα = 0.9. The first case has a smaller contraction factor and, hence, a wider notch than the latter.
The adaptive step size of the stochastic gradient algorithm was tuned
for the jammer under consideration. (The adaptation of the filter zero
must be fast to track the frequency variations of the jammer’s chirp
signal.) In each case the magnitude of the zero of the notch filter was
used as a detector for interference. We chose a threshold of 0.75 so
that when the amplitude of the zero was greater than this threshold, the
notch filter was enabled and the receiver processed this filtered data.
Otherwise the receiver processed the raw data collected from the
antenna.
Figure 5 and
Figure 6
illustrate the results of the filtering for the two cases. In these
plots, the upper portion shows the time evolution of the frequency
content of the raw data, with the frequency estimate of the notch filter
superimposed as a dashed red line. The lower plots show the time
evolution of the frequency content of the filtered data. From these
lower plots the wider notch appears to do a better job of removing the
jammer signal. On the other hand, this will also result in a greater
reduction of the useful signal power.
The effect of the notch filter on the reception of GNSS signals in terms of the C/N
0 degradation is illustrated in
Figure 7 and
Figure 8
for Galileo and GPS signals, respectively. Again, the difference
between the impact on GPS and Galileo signals is slight, due to the
wideband nature of the interferer. On the other hand, the benefit of the
notch filter is clear in both figures. The sidebar, “Track the Jamming
Signal,”
(at the end of this article) provides access to data and tools with which readers can test different configurations of the notch filters themselves.
Interestingly, it appears that two limiting curves exist, one for the
case of no filtering and one for the case where a notch filter is
applied. The variation in the contraction factor (over the range
considered) has little effect on the C/N
0 effectively measured by the GPS and Galileo software receivers.
The separation between the two curves is approximately five decibels,
i.e., the receiver that applies the notch filter experiences
approximately five decibels less C/N
0 loss than an unprotected receiver for the same J/N
0.
Of course, we must remember that this result applies for the data
collection system considered in this test, which consists of a 14-bit
analog-to-digital converter (ADC) with no automatic gain control (AGC).
In commercially available receivers with a limited number of bits for
signal quantization the non-linear losses due to the combination of
these two front-end components will likely lead to additional losses.
Conclusion
We have proposed an IIR adaptive notch filter as an easy means to
implement mitigation technique for chirp signals typical of the type of
commercially available jammers that have become ever more present in
recent years. A simple stochastic gradient adaptation algorithm was
implemented, with an associated simple interference detection scheme.
Our analysis showed that, for a receiver with sufficient dynamic range,
the proposed technique leads to an improvement of approximately five
decibels in terms of effective C/N
0.
We tested the proposed scheme on data collected from a low-cost
commercial jammer in a large anechoic chamber. We used a software
receiver to process both GPS and Galileo signals. The broadband nature
of the chirp signal means that its effect on GNSS signal processing is
similar to an increase in the thermal noise floor. Hence, the impact is
very similar on both GPS and Galileo receivers. On the other hand, the
chirp signal is instantaneously narrowband, a feature that is exploited
by the use of a notch filter with a highly dynamic response to
variations in the frequency of the interferer.
Acknowledgment
This study is mainly based on the paper “GNSS Jammers: Effects and
Countermeasures” presented by the authors at the Satellite Navigation
Technologies and European Workshop on GNSS Signals and Signal
Processing, (NAVITEC), December 2012.
Additional Resources
[1] Borio, D., Camoriano, L., and Lo Presti, L.,
“Two-pole and Multi-pole Notch Filters: A Computationally Effective
Solution for GNSS Interference Detection and Mitigation,”
IEEE Systems Journal, Vol. 2, No. 1, pp. 38–47, March 2008
[2] Boulton, P., Borsato, R., and Judge, K., “
GPS Interference Testing, Lab, Live, and LightSquared,”
Inside GNSS, pp. 32-45, July/August 2011
[3] Haykin, S.,
Adaptive Filter Theory, 4th ed., Prentice Hall, September 2001
[4] Jones, M.,
“The Civilian Battlefield, Protecting GNSS Receivers from Interference and Jamming,” Inside GNSS, pp. 40-49, March/April 2011
[5] Mitch, R. H., Dougherty, R. C., Psiaki, M. L.,
Powell, S. P., O’Hanlon, B. W., Bhatti, J. A., and Humphreys, T. E.,
“Signal Characteristics of Civil GPS Jammers,”
Proceedings of the 24th International Technical Meeting of the Satellite Division of The Institute of Navigation (ION GNSS 2011), Portland, OR, pp. 1907–1919, September 2011
[6] Paonni, M., Jang, J., Eissfeller, B., Wallner, S., Avila-Rodriguez, J. A., Samson, J., and Amarillo- Fernandez, F.,
“Wavelets and Notch Filtering, Innovative Techniques for Mitigating RF Interference,” Inside GNSS, pp. 54 – 62, January/February 2011
[7] Young, J. and Lehnert, J., “Analysis of DFTbased
Frequency Excision Algorithms for Direct Sequence Spread-Spectrum
Communications,”
IEEE Transactions on Communications, Vol. 46, No. 8, pp. 1076 –1087, August 1998
