Aiming at the issue of influence of blanket jamming on performances of Beidou navigation signals, through studying Beidou signals based on the BOC modulation technology, establishing a blanket jamming mathematical model, and performing modeling and simulation on multiple jamming technologies, to attain the jamming curves of time domains and frequency domains of Beidou signals, and the correlation curve of the signal-to-jamming rate and the bit error rate under blanket jamming, and thus realizing evaluation on the jamming performance.
The binary offset carrier (BOC) technology, as a research hotspot in the field of navigation, has been experimented in navigation signals of the American GPS system and the European Galileo system [
BOC modulation referred to auxiliary modulation on code signals generated by a satellite by taking a square wave as the subcarrier, then modulating to the main carrier, that is, multiplying the signal
That is:
In which,
BOC (14, 2) is taken as an example.
In reference to promotion of the spectrum formula of BPSK modulation signals, the power spectral density of the normalization baseband of BOC (fs, fc) modulation can be attained as [
When
When
Generally, the autocorrelation function of BOC modulation cannot be easily explicitly expressed. Provided that signals take the complex bandwidth
The number of main lobes and side lobes between the main lobes on both sides on the BOC power spectrum is determined by two parameters, i.e.
In which, n represents the number of main lobes and side lobes between the main lobes on both sides, and also serves as the order of BOC modulation,
Jamming on navigation signals mainly referred to jamming countermeasure to a user receiver, and classified into blanket jamming and deception jamming in technology.
By launching certain types of jamming signals, masking the frequency spectrum of signals launched by the adverse party in a certain way, and blanketing satellite signals reaching the antenna terminal of a receiver, to cause a result that the adverse party cannot correctly receive satellite signals to carry out positioning, and thus the capability of the adverse party to conduct normal operation is degraded or completely destroyed [
Blanket jamming includes spot jamming, blocking jamming and correlation jamming. Spot jamming is conducted in a manner of mainly performing jamming to satellite signals in specific code types, to cause the signals to fail at a certain area by adopting the frequency spot technology, through perfectly aligning the jamming carrier frequency to the signal carrier frequency [
Referred to launching ghost signals having the same parameters (only with different information codes) with real satellite signals to jam a receiver, to cause the receiver to generate error location information, and functioning as a pseudo satellite.
Deception jamming to navigation signals can be conducted in two ways: providing false navigation information or increasing the signal propagation time delay, which correspond to two jamming systems, i.e. the “production” jamming system and “forwarding” jamming system [
Single-tone jamming referred to launching signals at one frequency, and therefore jamming signal is a single frequency continuous wave voice frequency. Single-tone jamming is also called dot frequency jamming [
A jammer can launch L (being greater than 1) audios, which can be randomly distributed, or positioned on specific frequency bands. Under the circumstances that a specific target anti-jamming communication system is very vulnerable to jamming by specific audios and the jammer recognizes the situation, audios should be used more cautiously at the specific frequencies, and should not be randomly distributed [
When the audios are at adjacent channels, independent multi-tone jamming is formed, that is comb jamming. Therefore, the following assumption is adopted in default no matter which audio jamming countermeasure is discussed, that is the audio is positioned at one frequency of a frequency spectrum accurately, thus the jamming audio can pass the filter of a receiver, and distortion or attenuation is not generated. Independent multi-tone jamming is formed in a manner of superposing n independent sine wave signals, A refers to the amplitude, Δf refers to the stepping frequency width, and the time-domain expression is as follows:
The generalized stationary random process:
Called noise frequency modulation jamming, in which modulation noise
Gaussian noise and sinusoidal signals are used for noise frequency modulation, and jamming signals are formed after filtering and power amplification. The effective bandwidth of signals subjected to noise frequency modulation is only correlated to the amplitude effective value of modulation noise, and the frequency modulation coefficient, and barely correlated to the bandwidth of modulation noise.
The generalized stationary random process:
Called noise amplitude modulation jamming, in which
From the expression of noise amplitude modulation, it is observed that noise amplitude modulation jamming is generated due to generation of band-limited noise fundamentally. Firstly, a set of mutually-independent Gaussian white noise is generated, and then the Gaussian white noise passes a band-limited filter to produce required band-limited noise [
Noise amplitude modulation jamming can be defined as narrow-band jamming, as the frequency spectrum width thereof is only twice that of modulation noise. Requirement on a modulator is high with increase of the spectrum width of modulation noise, thereby leading to a too complicated circuit which is difficult to realize. In addition, the frequency spectrum width of noise amplitude modulation is also limited by the limited bandwidth of an oscillating tube.
The generalized stationary random process:
Called noise phase modulation jamming, in which modulation noise
The total power of phase modulation waves is equal to the carrier power. When the effective phase shift
The jamming analysis program is mainly conducted in a manner that a Beidou navigation signal generating module and a jamming signal generating module are integrated through a human-computer interaction interface, the parameters of different jamming modules can be adjusted according to requirements, the waveform characteristics of time domains and frequency domains of Beidou navigation signals generated by the Beidou navigation signal generating module, and the chosen jamming signals can be observed in real time, the two can be simulated into a signal reaching the receiver terminal through jamming analysis software in an integrating way, and the time domains and frequency domains of the signal are displayed. By integrating the Beidou navigation signal source with the jamming modules, bit error rates under different jamming conditions are attained through further simulation and the jamming effect is analyzed.
Blanket jamming has great jamming power, so the pseudorange measurement precision of a receiver can not only be reduced, even error decoding can be caused directly, thereby leading to incapability of positioning by the receiver. Multiple blanket jamming effects are analyzed and simulated mainly in the aspects of time domain and frequency domain simulation and bit error rate simulation.
Setting the information code rate to be 0.1 MHz, the BOC modulation subcarrier frequency to be 14 MHz, the spread spectrum code rate to be 2 MHz, the intermediate frequency carrier to be 100 MHz, the sampling frequency to be 1440 MHz, the signal-to-jamming rate to be 10 db, and the transmit information bit to be 100,000. When being free from jamming, time domain and frequency domain simulation of signals received by a receiver as shown in
Setting the Gaussian noise variance
Figures 6-11 are time domain and frequency domain graphs of signals received by the input terminal of a receiver under the effect of three types of noise, and the jamming effects of jamming signals on time domains and frequency domains can be observed visually. Figures 12-14 is a curve, of which bit error rates of three types of
jamming change along with signal-to-jamming rates. It is observed that jamming with uniform power density is formed in the passband of a filter after the receiver is jammed by noise, due to spread spectrum gain, and the receiver extends the jamming power while amplifying the signal power. The spread spectrum gain of Beidou system is great, and great power is required to complete jamming. No significant difference exists among the jamming effects, by contrast, the noise amplitude modulation is low in bit error rate when the signal-to-jamming rate is lower than 25 dB, and the bit error rate is high when the signal-to-jamming rate is greater than 25 dB. The effect of blanket jamming can be illustrated more obviously by noise modulation jamming, a jamming function is fulfilled, and however, great power is required to achieve certain jamming effects.
The paper mainly focuses on detailed description and simulation on how to jam the Beidou system (BOC modulation). The research keystone lies in the definition, characteristics and superiority in terms of anti-jamming of the BOC modulation method; signal source modeling, jamming modeling and BOC modulation jamming modeling are completed; multiple jamming methods are simulated and the jamming results are analyzed, and accordingly the validity of the jamming methods is demonstrated.
Pei Wang,Xiaochun Lu,Rui Wang, (2016) Research on Blanket Jamming to Beidou Navigation Signals Based on BOC Modulation. International Journal of Communications, Network and System Sciences,09,135-144. doi: 10.4236/ijcns.2016.95012