KR101871908B1 - Anti-jamming apparatus for global navigation satellite system and anti-jamming method for global navigation satellite system - Google Patents

Abstract

An apparatus for jamming a satellite navigation system including an array antenna and a satellite navigation receiver for detecting position information from RF satellite signals output from the array antenna, the apparatus comprising: The N digital down-conversion units and the N digital IF signals are directed in the direction of the tracking satellite to generate an anti-jamming signal, a replication signal corresponding to each tracking satellite is generated based on the anti-jamming signal, A jamming processing unit for generating a digital synthesized signal by synthesizing a corresponding replica signal, and a frequency up conversion unit for converting the digital synthesized signal into an analog RF signal and outputting the analog synthesized signal to a satellite navigation receiver.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus and method for jamming a satellite navigation system,

The present invention relates to a jam processing apparatus and a jam processing method for a satellite navigation system, and more particularly, to a jam processing apparatus and a jam processing method capable of interfacing with an existing navigation system.

 The Global Navigation Satellite System (GNSS) is a system that calculates the location of a user by triangulation using multiple satellites orbiting the earth.

Such a satellite navigation system can be used for a long time because there is no divergence according to the use time, and it has an advantage that accurate positioning can be performed all over the earth.

On the other hand, the GNSS signal emitted from the satellite above 20,000 km becomes a signal of about -128.5 dBm, which is lower than the thermal noise at room temperature when it reaches the receiver. In other words, since the GNSS signal is lower than the thermal noise, it may be easily influenced by unintentional ambient radio signals or intentional interference and jamming, which may lead to a large navigation error or a failure to perform navigation.

Thus, the GNSS signal has a direct band spread processing gain, but is particularly vulnerable to intentional or military jamming. In order to reduce the jamming of such GNSS signals, various jamming attenuation techniques such as anti-jamming antenna technology, front-end filtering anti-jamming technology, digital anti-jamming signal processing technology are applied to the satellite navigation system.

In particular, the anti-jamming antenna technology is a technique used in an adaptive array antenna. It uses a beam steered array technique to increase the gain by forming a beam with a very narrow width in the satellite signal direction, And a null steered array technique for suppressing the jamming signal.

In this case, the latter is a technique for converting a GNSS signal into a digital domain, forming a null in a jamming direction, and then recovering the RF signal, and has the advantage of adding an anti-jamming function to the existing satellite navigation system.

The former is a technique for amplifying the GNSS signal strength by increasing the signal gain in the satellite direction, and has the advantage of having better anti-jamming performance than the null steering technique.

However, since the beam steering jamming technique of the array antenna separates and processes the signals according to the direction of each satellite, there is a problem that the device for jamming must be manufactured integrally with the satellite receiving device.

In the beam steering jamming technique of the array antenna, the RF signal must be converted for every signal processing channel. To this end, a DAC and an IF / RF unit corresponding to the number of signal channels are provided to generate an RF signal in which jamming is suppressed for each channel It is inevitable to synthesize the signal with one RF signal or to synthesize a signal in which the jamming is suppressed in the digital domain.

At this time, if the signals of all the satellites are combined, there is a problem that the quality of the final output signal can not be guaranteed due to the interference between the satellite signals and the increase of the base low noise.

It is an object of the present invention to provide a jam processing apparatus and a jam processing method applicable to a pre-installed satellite navigation apparatus.

Another object of the present invention is to provide a jam processing apparatus and method for generating a replica signal of a tracking satellite based on an anti-jamming signal in a digital domain and synthesizing the replica signal in a digital domain to suppress signal degradation due to signal synthesis or low- Thereby providing a jamming processing method.

Another object of the present invention is to provide a jam processing apparatus and a jam processing method for selecting a duplicate signal to be synthesized according to the quality of a satellite signal or the possibility of jamming of a satellite signal to provide an RF signal having the best quality to a satellite navigation receiver will be.

According to an aspect of the present invention, there is provided an apparatus for jamming a satellite navigation system including an array antenna and a satellite navigation receiver for detecting position information from RF satellite signals output from the array antenna, An N-th frequency down-conversion unit for converting the digital IF signal into a digital IF signal and outputting the digital IF signal, and N digital IF signals to generate a anti-jamming signal by steering the N digital IF signals in the direction of the tracking satellite, And a frequency up-conversion unit for converting the digital composite signal into an analog RF signal and outputting the converted analog RF signal to a satellite navigation receiver, A jam processing apparatus of a satellite navigation system is provided.

According to another aspect of the present invention, there is provided a method of jamming a satellite navigation system including an array antenna and a satellite navigation receiver for detecting position information from RF satellite signals output from the array antenna, N digital down-conversion steps of converting the digital IF signal into a digital IF signal and outputting the digital IF signal, and generating an anti-jamming signal by steering the N digital IF signals in the direction of the tracking satellite, A jamming processing step of generating a digital synthesized signal by synthesizing replica signals corresponding to the respective tracking satellites, and a frequency up-conversion step of converting the digital synthesized signal into an analog RF signal and outputting the converted analog RF signal to a satellite navigation receiver .

The jamming processing apparatus and the jamming processing method of the present invention can suppress the jamming of the RF signal output from the array antenna in the digital domain and convert the RF signal into an RF signal and output the RF signal, Can be provided.

Further, according to the jamming processing apparatus and the jamming processing method of the present invention, it is possible to suppress deterioration of the quality of the satellite signal due to signal synthesis of the tracking satellite or base low noise.

In addition, the jamming processing apparatus and the jamming processing method of the present invention can improve the quality of an RF signal input to a satellite navigation receiver by selecting a replica signal to be synthesized according to the quality of a satellite signal or the possibility of jamming of a satellite signal.

1 is an internal configuration diagram of a satellite navigation system to which a jam processing apparatus according to an embodiment of the present invention is applied.
2 shows the overall configuration of a jam processing apparatus according to an embodiment of the present invention.
3 shows the overall configuration of a jam processing unit according to an embodiment of the present invention.
4 shows an example of the internal configuration of a K-channel beam steering unit used in the present invention.
5 shows an example of the internal configuration of a correlator used in the present invention.
6 shows a configuration of a jam processing unit of a jam processing apparatus according to another embodiment of the present invention.
7 is a flowchart showing a jamming processing method according to an embodiment of the present invention.
8 is a flowchart specifically showing an example of a digital composite signal generating method.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In the drawings, like reference numerals are used to denote like elements throughout the drawings, even if they are shown on different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In describing the components of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the components from other components, and the terms do not limit the nature, order, order, or number of the components. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; intervening "or that each component may be" connected, "" coupled, "or " connected" through other components.

 1 is an internal configuration diagram of a satellite navigation system to which a jam processing apparatus according to an embodiment of the present invention is applied.

The satellite navigation system 100 in this specification includes not only a GPS (Global Positioning System) in a narrow sense, which is a satellite navigation system 100 provided by the United States, but also GLONASS, a satellite navigation system of Russia, Including the GALILEO (Project) system, the COMPASS in China, the QZSS in Japan, and the IRNSS in India, including satellite navigation systems or satellite positioning systems. Hereinafter, the jam processing apparatus of the present invention will be described with reference to GPS for convenience of explanation.

In general, the satellite navigation system 100 may include an antenna 110 and a satellite navigation receiver 120.

In a general satellite navigation system 100, a satellite signal of the GPS navigation satellite 102 and a jamming signal of the GPS jamming transmitter 104 are received by the antenna 110, Signal and a jamming signal are output.

In this case, the jamming signal may be a jamming file for disturbing the positioning satellite information in order to disturb the positioning satellite information in a similar manner to the GPS signal. A jammer or jamming signal transmitter 104 for transmitting the jamming signal may be an RF (radio) Jammers, VHF / UHF jammers, GPS jammers, and the like.

The RF signal output from the antenna 110 is input to the navigation device 120. The navigation device 120 processes the RF signal output from the antenna 110 according to a predetermined protocol to generate data of a predetermined format .

In such a conventional satellite navigation system, an RF signal is processed according to a predetermined protocol and output as preset data, which makes it difficult to apply the anti-jamming function even when there is a request for anti-jamming.

According to an embodiment of the present invention, the antenna 110 is replaced with an array antenna 110 in which a plurality of antennas are combined, and the jamming apparatus 130 includes an array antenna 110 Satellite navigation receiver (120). More specifically, the input terminal of the jamming processing device 130 is connected to the output terminal of the array antenna 110, and the output terminal of the jamming processing device 130 is connected to the input terminal of the satellite navigation receiver 120.

The jamming processing unit 130 converts the RF signal output from the array antenna 110 into a digital domain to suppress jamming and converts the RF signal into an RF signal and outputs the RF signal, .

In addition, it generates an anti-jamming signal in which the jamming signal is suppressed in the digital domain, and synthesizes the replica signal of the tracking satellite generated using the anti-jamming signal in the digital domain to synthesize the signal of the tracking satellite without degrading the signal quality due to signal synthesis or base noise. I want to.

In addition, it is desired to improve the quality of a signal input to the GPS receiver 120 by selecting a replica signal to be synthesized according to the signal quality or jamming probability transmitted from the satellite being tracked.

Hereinafter, the jam processing apparatus 130 will be described in more detail with reference to FIGS. 2 to 5. FIG.

2 shows the overall configuration of a jam processing apparatus according to an embodiment of the present invention.

The jam processing apparatus 130 according to an embodiment of the present invention may include N frequency down-converting units 210, a jamming processing unit 220, and a frequency up-converting unit 230. Here, N is a natural number and may correspond to the number of antennas constituting the array antenna 110.

That is, N frequency down converter 210 is provided so as to correspond to each channel of array antenna 110. Each frequency down converter 210 has its front end connected to one output terminal of the array antenna 110 and receives an RF signal output from the array antenna 110.

The frequency down converter 210 includes an RF / IF converter and an analog-to-digital converter (ADC). The frequency down converter 210 converts the input RF signal into an IF signal of an intermediate frequency band, Signal.

At this time, the frequency down converter 210 can keep the synchronization in the frequency conversion process by using the same clock as the frequency up converter 230, which will be described below.

The jamming processing unit 220 generates an anti-jamming signal in which the jamming signal is suppressed by steering the N digital IF signals output from the frequency down converter 210 in the direction of the tracking satellite, Generates a duplicate signal, and synthesizes the duplicated signal to generate a digital composite signal in which jamming is suppressed.

Thus, by composing the replica signal of the tracking satellite in the digital domain, it is possible to suppress the jamming signal without deteriorating the signal quality due to the signal interference between the tracking satellites or the increase of the base noise.

The frequency up converter 230 includes a digital-analog converter (DAC) and an IF / RF converter. The frequency up converter 230 converts the digital synthesized signal output from the jamming processor 130 into an analog signal, Converts it into an RF signal of a radio frequency band and outputs it.

That is, the frequency up converter 230 according to the present invention converts the digital composite signal with jamming suppression into an RF signal that can be processed by the satellite navigation receiver 120 and outputs the RF signal.

Hereinafter, the jam processing unit 220 of the jam processing apparatus 130, which is a feature of the present invention, will be described in detail with reference to FIG. 3 to FIG.

3 shows the overall configuration of a jam processing unit according to an embodiment of the present invention.

The jam processing unit 220 according to the embodiment of the present invention includes a K channel beam steering unit 310, a K channel correlator 500, a navigation calculation unit 320, and a replica signal synthesizer 330, Generates an anti-jamming signal in which jamming is suppressed, and outputs a digital composite signal in which jamming is suppressed by synthesizing the replica signal of the tracking satellite generated based on the anti-jamming signal.

Here, K denotes the maximum number of satellites that can be tracked by the jam processing unit 220, and K is a natural number greater than 3, which is the minimum number of satellite signals required for tracking the position.

The K-channel beam steering unit 310 generates K-number of tracking satellites, forms a null in the jamming direction, and forms a beam in the direction of each tracking satellite to generate an anti-jamming signal. Hereinafter, an example of the K-channel beam steering will be described in more detail with reference to FIG.

FIG. 4 shows an example of the internal configuration of a K-channel beam steering unit 310 used in the present invention.

The beam steering unit 310 according to an embodiment of the present invention includes K steering units 410 and a weight calculation unit 420.

The weight calculation unit 420 calculates weights to be applied to the N channels based on the satellite direction information output from the navigation calculation unit 320 and the digital IF signal output from the frequency down conversion unit 210. [ The weight is determined so that the signal corresponding to the satellite direction is enhanced and the signal corresponding to the jamming direction is suppressed.

At this time, since the satellite directions are different according to the tracking satellites, the weight calculator 420 calculates weights 11 to KN for each of the tracking satellites, and inputs the calculated weights to the K steering units 410.

The steering unit 410 includes a weight combining unit 412 for combining N weight applying units 411 for applying weights to the respective digital IF signals and N digital IF signals to which weights are applied, And an anti-jamming signal in which the beam is steered in the satellite direction.

Thus, an anti-jamming signal in which a jamming signal is suppressed can be obtained by forming a null in the jamming direction and steering it in the satellite direction.

4, the beam steering unit 310 is described as suppressing the jamming signal by using both the beam steered array technique and the null steered array technique. It is also possible to suppress the jamming signal using only the beam steering array technique.

Referring back to FIG. 3, the anti-jamming signal obtained by the K-channel beam steering unit 310 is input to the K-channel correlator 500.

The K-channel correlator 500 is allocated to each tracking satellite and performs a function of tracking the satellite signal. Specifically, the channel correlator 500 lowers the input anti-jamming signal to the baseband, reverses the input anti-jamming signal to restore the data of the tracking satellite, and integrates and dumps the restored data.

The navigation calculation unit 320 determines whether to track the satellite based on the integral-dump value output from the K-channel correlator 500, and calculates a code phase increase value and a carrier phase increase value of the tracking satellite Update the change, and output it to the correlator 500. At this time, determining whether to track the satellite through the integration-dump, and updating the code and the carrier wave for satellite tracking are obvious to those skilled in the art, and a detailed description thereof will be omitted.

In addition, the navigation calculation unit 320 corrects the error by calculating the error of the code phase information and the carrier phase error, and extracts the navigation data through the calculation of the navigation (for example, the current position, the moving speed, do.

In addition, the navigation calculation unit 320 may generate the satellite direction information by analyzing the direction of each tracking satellite through the navigation solution, and output it to the weight calculation unit 420.

In particular, the navigation calculation unit 320 may input the extracted navigation data to the K-channel correlator 500, and the K-channel correlator 500 generates the replica signal corresponding to each tracking satellite using the input navigation data can do.

5, the operation of the correlator 500 and the navigation calculation unit 320 for generating the replica signal of the tracking satellite will be described in detail.

5 shows an example of the internal configuration of a correlator used in the present invention.

5, a correlator 500 according to an embodiment of the present invention includes a carrier generator 510 for generating a carrier wave corresponding to a tracking satellite by reflecting an input carrier phase increase value, A code generator 530 for generating the codes of the tracking satellite by reflecting the code phase increase value, an integrating-dumper 550 for calculating the correlation, a multiplier 520, 540 for multiplying the anti-jamming signal, . ≪ / RTI >

The anti-jamming signal input to the correlator 500 is multiplied by the carrier of the tracking satellite and converted into baseband, and the anti-jamming signal converted into baseband is multiplied by the code of the tracking satellite to be inversely converted, And input to the navigation calculation unit 320. [

The navigation calculation unit 320 determines whether or not to track the satellite based on the data output from the integration-dump unit 550 and inputs the navigation data of the tracking satellite extracted through the navigation calculation to the replica signal generator 560 do.

The replica signal generator 560 includes a high-resolution carrier generator 561, a replica code multiplier 562, a data generator 564 and a data multiplier 563 to generate a replica signal corresponding to the tracking satellite in the digital domain.

The high-resolution carrier generator 561 generates a carrier wave of the tracking satellite corresponding to the carrier phase increase value.

The data generator 564 generates data corresponding to the tracking satellite based on the navigation data input by the navigation calculation unit 320 and the code phase information output from the code generator 510.

The carrier of the tracking satellite generated by the high-resolution carrier generator 561 and the code of the tracking satellite generated by the code generator 530 are multiplied by the replica code multiplier 562 and output. The output of the replica code multiplier 562 and the data The data generated by the generator 564 is multiplied by a data multiplier 563 to output a replica signal corresponding to the tracking satellite.

5, a separate high-resolution carrier generator 561 is provided in the replica signal generator 560. However, when a replica signal is generated using the carrier wave generated by the carrier generator 510, a high-resolution carrier generator 561 ) May be omitted.

5, the replica signal generator 560 may include a separate code generator.

In addition, although the copy signal generator 560 is described as being configured in the correlator 500 in FIG. 5, the present invention is not limited thereto, and may be implemented in another component or may be implemented as a separate component.

3, when a plurality of replica signals corresponding to the respective tracking satellites are output from the K-channel correlator 500, the signal combiner 330 combines a plurality of replica signals to generate and output a digital synthesized signal .

The synthesized signal thus generated is converted into an analog RF signal by the frequency up converter 230 and input to the satellite navigation receiver 120, as described with reference to FIG. 1 and FIG.

That is, since the jammed RF signal is input to the satellite navigation receiver 120 in FIG. 1, the anti-jamming function can be implemented without modifying the satellite navigation receiver 120.

Also, by generating the replica signal of the tracking satellite and synthesizing it in the digital domain, it is possible to prevent noise due to signal interference between the tracking satellites, thereby improving the quality of the satellite signal.

In addition, by generating a duplicate signal using a high-resolution carrier wave, it is possible to prevent generation of background noise and improve the quality of the satellite signal.

6 shows a configuration of a jam processing unit of a jam processing apparatus according to another embodiment of the present invention.

Compared with FIG. 3, the jam processing apparatus 600 according to another embodiment may further include a signal selection unit 610. FIG. For the sake of convenience in the following description, the same reference numerals as in FIG. 3 are assigned to configurations that perform the same functions as those in FIG. 1 to FIG. 3, and a detailed description thereof will be omitted.

The signal selector 610 selects only the replica signals corresponding to the selection signals among the K replica signals output from the K channel correlator 500 and outputs the selected signals.

For this, the signal selector 610 may include K switches operating according to the selection signal, but it is not limited thereto, and may include various configurations capable of selectively outputting signals.

The navigation calculation unit 620 analyzes the signal quality of each tracking satellite according to the signal intensity of the tracking satellite and generates a selection signal according to the analyzed quality.

For example, the navigation calculation unit 620 may analyze the signal quality of each tracking satellite and generate a selection signal so that only the clone signal corresponding to the satellite having the signal quality higher than the preset reference is output.

However, if the number of satellites having a quality higher than a preset reference is smaller than a predetermined minimum number of tracking satellites, the navigation calculation unit 620 may select a replica signal corresponding to the minimum number of tracking satellites according to the priority of quality Can be generated.

In addition, the navigation calculation unit 620 analyzes the jamming probability of each tracking satellite and generates a selection signal so that a duplicate signal is not output when it is determined that the satellite is jamming.

Jamming probability can be analyzed by taking into account at least one of the absolute magnitude of the signal power received from the tracking satellite, the rate of change of the signal power, and the relative signal strength.

Specifically, since the signal power of the GPS is expected to not exceed the predetermined range, the navigation calculation unit 620 determines that there is a possibility of jamming if the signal power of the tracking satellite exceeds the predetermined range, A selection signal can be generated so that a signal of a tracking satellite outside the set range is not outputted.

In addition, the GPS satellite is 20,000 km above the ground, so that the signal power does not change suddenly according to the position change of the receiver. Therefore, the navigation calculation unit 620 monitors the rate of change of the signal power of each tracking satellite, judges that jamming is possible when the rate of change of the signal power is out of a predetermined range, and determines that the rate of change of the signal power is out of the predetermined range A selection signal can be generated so that the signal of the tracking satellite is not outputted.

In addition, since the GPS satellite signal has a relatively fixed fixed power ratio, the navigation calculation unit 620 compares the relative values of the signal powers of the plurality of tracking satellites, so that the tracking satellite, It is possible to generate a selection signal such that a replica signal corresponding to a tracking satellite different from a satellite having a relatively different signal power is not output.

Thus, by selecting the replica signal in consideration of the quality of the signal or the jamming possibility, it is possible to generate the anti-jamming RF signal of higher quality.

7 is a flowchart showing a jamming processing method according to an embodiment of the present invention.

7 may be executed by the jam processing device 130 provided between the array antenna 110 and the satellite navigation receiver 120 as described above.

Referring to FIG. 7, the jamming processing apparatus 130 receives N RF signals output through the array antenna 110 in operation S710 and converts the received RF signals into digital IF signals in operation S720.

Specifically, the digital IF signal is generated by down-converting the RF signal output through the N channels of the array antenna 110 to an IF frequency and converting it into a digital domain.

The jamming processing device 130 generates a digital composite signal by synthesizing the replica signal of the tracking satellite in the digital domain (S730).

At this time, the replica signal of the tracking satellite corresponds to the satellite signal transmitted by each tracking satellite, and is generated based on the navigation data extracted from the anti-jamming signal generated using at least one of the beam steering array technique and the null steering technique . Since the replica signals corresponding to each of the generated tracking satellites are synthesized in the digital domain, mutual interference due to the signal synthesis of the tracking satellite is suppressed. Further, a high-resolution carrier wave is used for generation of the replica signal, thereby suppressing the generation of the base noise due to the replica signal synthesis. A method of generating such a digital composite signal will be described in detail below with reference to FIG.

The jamming processing device 130 frequency-ups the digital synthesized signal to an RF signal and outputs it (S740). That is, the digital composite signal generated through the synthesis of a plurality of replica signals is converted into an analog signal, frequency-up-converted into an RF signal of a radio frequency band, and then output.

In this way, the jamming signal is suppressed by converting the RF signal into the digital domain, and the jamming signal is changed to the RF signal again, and the anti-jamming function can be added without changing the structure of the existing satellite navigation receiver 120.

8 is a flowchart specifically showing an example of a digital composite signal generating method.

Referring to FIG. 8, the jamming processing device 130 generates a signal for each tracking satellite by steering a digital IF signal.

A signal corresponding to the satellite direction is enhanced with respect to the generated signal, and a null is formed in the signal corresponding to the jamming direction to weaken the signal to generate an anti-jamming signal (S810).

At this time, the N weights determined for the null formation may be applied to each of the N digital IF signals, and the anti-jamming digital IF signal may be generated by combining the weighted digital IF signals.

At this time, the weight value can be determined based on the satellite direction information and the digital IF signal.

The jamming processing device 130 extracts the navigation data from the anti-jamming digital IF signal (S820). The navigation data can be obtained through a navigation algorithm operation.

On the other hand, prior to the extraction of the navigation data, as described above, whether or not to track the satellite is determined based on the result of integration-dump processing of the carrier wave of the tracking satellite and the tracking satellite code applied to the anti-jamming signal, The increment value and the carrier phase increment value are updated to track the satellite signal.

The jamming processing unit 130 applies a carrier wave and a code of the tracking satellite to the legitimate data to generate a replica signal of the tracking satellite (S830).

Specifically, a carrier of the tracking satellite is generated according to the carrier phase increase value. At this time, the carrier wave generated by the jamming processing device 130 may be a high-resolution transfer file.

Then, a code corresponding to the tracking satellite is generated, and data corresponding to the tracking satellite is generated based on the navigation data and the phase information of the tracking satellite.

At this time, the carrier wave, the code, and the data may be sequentially generated, but may be generated in synchronization with a predetermined clock.

The jamming processing device 130 selects and outputs the satellite replica signal to be synthesized (S840). The selection of the satellite replica signal can be processed according to the above-described selection signal, and a selection signal can be generated according to the signal quality of the tracking satellite or the jamming possibility of the tracking satellite. Since the selection signal generation method is the same as the selection signal generation method of the navigation calculation section 320 described above, detailed description is omitted in order to avoid redundancy.

The jamming processing device 130 combines the output plurality of satellite replica signals to generate a digital synthesized signal (S850).

The signal processing described in Fig. 8 is performed in the digital domain. Particularly, since the replication signal synthesis of the tracking satellite based on the anti-jamming signal is also performed in the digital domain, quality deterioration due to signal interference between a plurality of tracking satellite signals can be prevented, and base noise can be prevented .

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. , Separation, substitution, and alteration of the invention will be apparent to those skilled in the art.

Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: satellite navigation system 110: array antenna
120: satellite navigation receiver 130: jam processing device
210 frequency down conversion unit 220 jam processing unit
230: frequency up-conversion unit 310: beam steering unit
320: navigation calculation unit 330: signal synthesis unit
410: Steering section 420: Weight calculation section
500: Correlator 510: Carrier generator
520: Carrier multiplier 530: Code generator
540: Code multiplier 550: Integral-dump
560: Replication Signal Generator

Claims (12)

1. An apparatus for jamming a satellite navigation system including an array antenna and a satellite navigation receiver for detecting position information from an RF satellite signal output from the array antenna,
N frequency downconverters for converting RF signals output from the array antenna into digital IF signals and outputting the digital IF signals;
Generating an anti-jamming signal by steering the N digital IF signals in the direction of the tracking satellite, generating a replica signal corresponding to each of the tracking satellites based on the anti-jamming signal, A jamming processing unit for generating a digital synthesized signal; And
And a frequency up-conversion unit for converting the digital composite signal into an analog RF signal and outputting the converted analog RF signal to the satellite navigation receiver,
The jam processing unit,
K beam steering units that steer each of the N IF signals in a tracking satellite direction based on direction information of the tracking satellite and form a null in a jamming direction to generate the anti-jamming signal; And
And a correlator for extracting the navigation data of each of the tracking satellites from the anti-jamming signal and generating a replica signal corresponding to each of the tracking satellites based on the navigation data. delete The method according to claim 1,
The jam processing unit,
A navigation calculation unit for analyzing the signal quality of each of the tracking satellites based on the navigation data, determining a satellite to be used for position detection according to an analysis result, and generating a selection signal;
A duplicate signal selector for selecting and outputting P replica signals among the K replica signals according to the selection signal; And
A signal synthesizer for synthesizing P replica signals output from the replica signal selector to generate the digital synthesized signal;
Wherein the jam processing unit further comprises: The method of claim 3,
Wherein the navigation calculation unit analyzes jamability of each of the tracking satellites using at least one of an absolute magnitude of signal power received from the tracking satellite, a rate of change in signal power, and a relative signal strength, And the jamming processing apparatus of the satellite navigation system generates the selection signal. The method according to claim 1,
The correlator comprises:
A carrier generator for generating a carrier of the tracking satellite in accordance with the carrier phase increase value;
A code generator for generating a code corresponding to the tracking satellite;
A data generator for generating data corresponding to the tracking satellite based on the navigation data and the phase information of the tracking satellite; And
At least one multiplier for synthesizing the carrier, the code, and the data to generate a replica signal of the tracking satellite;
And a jam processing unit of the satellite navigation system. 6. The method of claim 5,
Wherein the carrier generator is a high-resolution carrier generator for generating a high-resolution carrier wave. 1. A jamming method for a satellite navigation system including an array antenna and a satellite navigation receiver for detecting position information from an RF satellite signal output from the array antenna,
An N frequency down conversion step of converting the RF signal output from the array antenna into a digital IF signal and outputting the digital IF signal;
Generating an anti-jamming signal by steering the N digital IF signals in the direction of the tracking satellite, generating a replica signal corresponding to each of the tracking satellite based on the anti-jamming signal, A jamming processing step of generating a digital synthesized signal;
Converting the digital synthesized signal into an analog RF signal and outputting the converted analog RF signal to the satellite navigation receiver,
The jam processing step may include:
A K beam steering step of steering each of the N IF signals in a tracking satellite direction based on direction information of the tracking satellite and forming a null in a jamming direction to generate the anti-jamming signal; And
A step of extracting navigation data of each tracking satellite from the anti-jamming signal to track the satellite, and generating a replica signal corresponding to each of the tracking satellite based on the navigation data. delete 8. The method of claim 7,
The jam processing step may include:
Analyzing the signal quality of each of the tracking satellites based on the navigation data, determining a satellite to be used for position detection according to an analysis result, and generating a selection signal;
Selecting and outputting P replica signals among the K replica signals according to the selection signal; And
Synthesizing the output P replica signals to generate the digital synthesized signal;
Further comprising the step of: 10. The method of claim 9,
Wherein the step of generating the selection signal comprises:
Analyzing the jamability of each of the tracking satellites using at least one of an absolute magnitude of the signal power received from the tracking satellite, a rate of change of the signal power, and a relative signal strength to generate the selection signal based on the jamming probability A method for jamming a satellite navigation system. 8. The method of claim 7,
The step of generating the replica signal comprises:
Generating a carrier of the tracking satellite in accordance with the carrier phase increase value;
Generating a code corresponding to the tracking satellite;
Generating data corresponding to the tracking satellite based on the navigation data and the phase information of the tracking satellite; And
Generating a replica signal of the tracking satellite by combining the carrier, the code, and the data;
Of the satellite navigation system. 12. The method of claim 11,
And the carrier wave is a high-resolution carrier wave.

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