KR101643283B1 - System and method for processing jamming signal using threat signal - Google Patents

Abstract

The present invention suggests a system and a method for processing a jamming signal using a threat signal, which output a threat signal and then verify an algorithm for generating the jamming signal by receiving and analyzing the jamming signal for the threat signal. The system according to the present invention includes: a threat signal processor that outputs a threat signal; a jamming signal reception determiner that determines whether a jamming signal for the threat signal is received; and a jamming signal generation determiner that compares, if it is determined that the jamming signal is received, information obtained by analyzing the jamming signal with information stored in a library to determine whether the jamming signal is normally generated.

Description

[0001] The present invention relates to a jamming signal processing system and method using a threat signal,

The present invention relates to a system and method for determining whether a jamming signal is normally generated. And more particularly, to a system and method for determining whether a jamming signal is normally generated using a threat signal.

The threat signal generator is a device that generates and outputs a threat signal based on a library. However, the conventional threat signal generating apparatus does not receive the jamming signal for the threat signal after outputting the threat signal. Therefore, since the conventional threat signal generating apparatus can not analyze the jamming signal, it can not verify whether or not the algorithm for generating the jamming signal is normally operating.

Korean Patent Publication No. 2010-0081623 proposes a device for generating a threat signal. However, since this device generates a plurality of threat signals at the same time, but does not receive a jamming signal for a threat signal, the above problem can not be solved.

SUMMARY OF THE INVENTION The present invention is conceived to solve the problems described above and provides a jamming signal processing system and method using a threat signal for verifying an algorithm for generating a jamming signal by receiving and analyzing a jamming signal for a threat signal after outputting a threat signal And the like.

However, the objects of the present invention are not limited to those mentioned above, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a threat detection apparatus comprising: a threat signal processing unit for outputting a threat signal; A jamming signal reception judging unit for judging whether or not a jamming signal for the threat signal is received; And a jamming signal generation determining unit for determining whether the jamming signal is normally generated by comparing the information obtained by analyzing the jamming signal with the information stored in the library if it is determined that the jamming signal has been received. We propose a jamming signal processing system.

Preferably, the threat signal processor outputs the threat signal again when it is determined that the jamming signal has not been received for a predetermined time.

Preferably, the threat signal processing unit generates an unknown signal not defined in the library as the threat signal and outputs the threat signal.

Preferably, the jamming signal generation determination unit acquires the jamming technique from information obtained by analyzing the jamming signal, and determines whether or not the jamming signal is normally generated based on whether the jamming technique is stored in the library .

Preferably, the threat signal processing unit controls the threat signal to no longer be output if it is determined that the jamming signal is normally generated, and controls the threat signal to be output again if it is determined that the jamming signal is not normally generated .

Preferably, the jamming signal processing system includes: a signal identification determiner for determining whether the first signal is identifiable based on information stored in the library; A jamming technique determination unit for determining a jamming technique for the first signal based on information about a pulse of the first signal when it is determined that the first signal is not identifiable; A jamming signal generator for generating a jamming signal based on the determined jamming technique; And a jamming signal output unit for outputting the jamming signal to the outside.

Preferably, the jamming technique determination unit uses at least one of a frequency characteristic of the first signal, a pulse width of the first signal, and a pulse repetition period of the first signal as information on the pulse.

Preferably, when the jamming signal is output to the outside, the signal identification determination unit determines whether or not a subsequent second signal is identifiable. If the jamming signal processing system determines that the second signal is identifiable, And a jamming technique processing unit for storing the technique in the library.

Preferably, when the determined jamming scheme is stored in the library, the jamming scheme processing unit may apply the determined jamming scheme to generate the jamming signal whenever a signal having the same pattern as the first signal is received. .

Preferably, the jamming scheme determination unit sequentially determines at least two jamming schemes based on a result of analyzing the characteristics of the first signal, and the jamming signal output unit outputs the jamming scheme to the at least two jamming schemes, And sequentially outputs signals.

Preferably, the jamming signal processing system further includes a jamming technique number determination unit that determines the number of jamming techniques based on a result of analyzing the characteristics of the first signal, and the jamming technique determination unit determines the number of the jamming techniques Jamming techniques are determined sequentially on a basis.

Preferably, the jamming signal output control device is mounted on a flying object, and the jamming technique determining section further uses the position information of the flying object when determining the jamming technique.

The present invention further provides a method of detecting a threat, comprising: outputting a threat signal; Determining whether a jamming signal for the threat signal is received; And determining whether the jamming signal is normally generated by comparing the information obtained by analyzing the jamming signal with the information stored in the library if it is determined that the jamming signal has been received. We propose a signal processing method.

Preferably, the method further includes outputting the threat signal again if it is determined that the jamming signal is not received for a predetermined period of time between the step of determining whether the signal is received and the step of determining whether the signal is received .

Preferably, the outputting step generates an unknown signal not defined in the library as the threat signal and outputs the generated threat signal.

Preferably, the step of determining whether the generated jamming signal is generated may include acquiring a jamming technique by analyzing the jamming signal, determining whether the jamming signal is normally generated based on whether the jamming technique is stored in the library, .

Preferably, if the jamming signal is normally generated, it is determined whether the jamming signal is generated. If it is determined that the jamming signal is normally generated, To be output again.

Determining whether the first signal is identifiable based on information stored in the library, after the step of determining whether the first signal is generated; Determining a jamming scheme for the first signal based on information about a pulse of the first signal if it is determined that the first signal is not identifiable; Generating a jamming signal based on the determined jamming technique; And outputting the jamming signal to the outside.

Preferably, the determining step uses at least one of a frequency characteristic of the first signal, a pulse width of the first signal, and a pulse repetition period of the first signal as information on the pulse.

Preferably, when the jamming signal is output to the outside after the step of outputting to the outside, it is determined whether a second signal to be received subsequently is identifiable or not; And storing the determined jamming scheme in the library if the second signal is determined to be identifiable.

Preferably, after the storing step, if the determined jamming technique is stored in the library, the determined jamming technique may be used to generate the jamming signal whenever a signal having the same pattern as the first signal is received And controlling the application to be applied.

Preferably, the determining step sequentially determines at least two jamming techniques based on a result of analyzing the characteristics of the first signal, and the step of outputting the at least two jamming techniques may include: And sequentially outputs the jamming signals.

Preferably, the method further comprises determining a number of jamming techniques based on a result of analyzing the characteristics of the first signal, between determining whether the jamming technique is possible and determining the jamming technique, Wherein the determining step sequentially determines the jamming techniques based on the number of the jamming techniques.

Preferably, the jamming signal output control method is performed by an apparatus mounted on a flying object, and the determining further uses position information of the flying object when determining the jamming technique.

The present invention can achieve the following effects through the above-described configurations.

First, it becomes possible to verify an algorithm for generating a jamming signal in a device generating a threat signal.

Second, break-lock can be simulated through jamming signal analysis.

1 is a reference diagram for explaining the operation principle of a jamming signal processing system according to an embodiment of the present invention.
2 is a flowchart schematically illustrating a method of operating a jamming signal processing system according to an embodiment of the present invention.
3 is a reference diagram for explaining a process of verifying an algorithm for generating a jamming signal in the jamming signal processing system according to an embodiment of the present invention.
4 is a reference diagram for explaining the operation principle of a conventional jamming system.
5 is a flowchart illustrating an operation method of a jamming signal processing system according to another embodiment of the present invention.
6 is a reference diagram for explaining a process of generating a jamming signal by the jamming signal processing system according to an embodiment of the present invention.
7 is a block diagram schematically illustrating a jamming signal processing system according to a preferred embodiment of the present invention.
8 is a block diagram illustrating internal configurations that may be added to the jamming signal processing system shown in FIG.
9 is a flowchart schematically illustrating a method of processing a jamming signal according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the 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 addition, the preferred embodiments of the present invention will be described below, but it is needless to say that the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

Existing systems that identify threats by analyzing various threat signals that occur on the battlefield and send jamming to identified threats can be used to identify unidentified threats (eg, new threats not defined, threats not stored in the library, etc.) Jamming can not be done.

In order to develop a jamming algorithm for unidentified threats, it is necessary to develop a device that simulates the success of jamming by receiving and analyzing jamming signals through generation and transmission of unknown signals. Hereinafter, an apparatus for developing an optimized jamming algorithm for unknown signals will be described.

1 is a reference diagram for explaining the operation principle of a jamming signal processing system according to an embodiment of the present invention.

The conventional threat signal generating apparatus generates a threat signal based on the information stored in the library and does not have a function of stopping the radar generation by analyzing the jamming signal. That is, the conventional threat signal generating apparatus has a problem that it can not determine whether or not the jamming is successful by transmitting and generating a threat signal, and receiving and analyzing the jamming signal. In order to determine the jamming success of the unknown signal, it is necessary to verify the algorithm through the corresponding device.

The jamming signal processing system proposed in the present invention is operated in the following order to solve the above-mentioned problem.

First, the jamming signal processing system generates a threat signal based on the information stored in the library (S110).

Thereafter, the jamming signal processing system transmits the threat signal to the outside (S120).

Thereafter, the jamming signal processing system receives and analyzes the jamming signal for the threat signal (S130).

Thereafter, the jamming signal processing system determines whether or not the jamming signal is normally generated by the jamming signal generator based on the result of analyzing the jamming signal (S140).

If it is determined that the jamming signal has been normally generated, the jamming signal processing system stops external transmission of the threat signal (S150).

Next, an operation method of the jamming signal processing system will be described. 2 is a flowchart schematically illustrating a method of operating a jamming signal processing system according to an embodiment of the present invention.

First, the jamming signal processing system generates a jamming signal and transmits it to a jamming signal generator equipped with an algorithm for generating a jamming signal (S210). The jamming signal processing system can generate the unknown signal by generating frequency, PW, PRI and the like through the radar generator arbitrarily. Since the signal generated by the jamming signal processing system is an arbitrary component, the system receiving the signal receives it as the unknown signal.

Thereafter, the jamming signal processing system receives the jamming signal for the unknown signal from the jamming signal generator and analyzes the jamming signal (S220).

Thereafter, the jamming signal processing system compares the result obtained by analyzing the jamming signal with the information used when the jamming signal generator generates the jamming signal (S230), and verifies whether or not the jamming signal is normally generated by the jamming signal generator (S240) .

In the above, the jamming signal processing system can analyze the jamming signal and calculate the jamming technique as a result. In addition, the jamming signal processing system can previously store the information used in generating the jamming signal in the library of the database in order to determine whether or not the jamming signal has been normally generated.

The jamming signal processing system determines that the jamming signal is normally generated by the jamming signal generator when it is determined in step S240 that the jamming technique obtained as a result of the analysis matches the one stored in the library. On the other hand, if the jamming signal processing system determines that the jamming technique does not match the one stored in the library, it determines that the jamming signal is not generated normally by the jamming signal generator.

If it is determined that the jamming signal is normally generated, the jamming signal processing system controls the threat signal to no longer be output (S250). On the other hand, if it is determined that the jamming signal has not been normally generated, the jamming signal processing system controls the threat signal to be output again.

The jamming signal processing system according to the present invention is an apparatus for developing an algorithm for generating an optimized jamming library for a known signal, and generates and transmits a unknown signal, receives a jamming signal of the system to which the algorithm is applied, And confirm the jamming success / failure.

The jamming signal processing system generates the unknown signal and stores the jamming signal for the transmitted signal in the library during transmission. The jamming signal analysis is used to compare the jamming signal with the library, Stop. The optimization algorithm can determine that the threat signal is stopped and store the signal and the jamming specification in the library.

The jamming signal processing system according to the present invention can verify the algorithm for generating the optimized jamming library for the unknown signal through the above-described operation, and can perform the break-lock simulation through the jamming signal analysis.

Since the existing threat signal generator / generator is generated by generating the signal specified in the library, it does not receive the signal generated from the target device. Therefore, the jamming signal is analyzed using a separate receiver without analyzing / discriminating.

However, the apparatus proposed in the present invention (i.e., an apparatus for developing an algorithm for generating an optimized jamming library for the unknown signal) generates a threat signal and receives a jamming signal generated in the target apparatus, Therefore, it is not necessary to use a separate receiving device, analyzes the received signal in order to simulate the break-lock of the actual radar, and if it matches with the predetermined library, it determines that it is break-lock and stops generating the threat signal .

The existing system can not judge whether or not the jamming has succeeded. It is necessary to use the actual radar to determine whether the vehicle is in a break-lock state. In order to verify the algorithm using the radar, . The present invention solves this problem, and algorithm verification using the present apparatus is possible through a predetermined library.

3 is a reference diagram for explaining a process of verifying an algorithm for generating a jamming signal in the jamming signal processing system according to an embodiment of the present invention.

When the signal transmission unit 312 constituting the jamming signal processing system 310 transmits the unknown signal, the jamming optimization algorithm 320 transmits jamming in a predetermined order through signal analysis.

Thereafter, the signal receiving unit 313 receives the jamming signal generated according to the algorithm 320, and the signal analyzing unit 311 analyzes the jamming signal and determines whether or not the jamming is successful by comparing with the jamming technique stored in the library.

Since the jamming signal # 1 and the jamming signal # 2 do not coincide with the library, the jamming signal processing system 310 continuously generates the unknown signal.

However, since the jamming signal # 3 (jamming signal # 3) matches the library, the jamming signal processing system 310 stops generating the unknown signal.

When the signal generation is stopped, the algorithm 320 determines that the signal is stopped and stores the optimized jamming scheme.

We verify whether algorithm development is completed through algorithm verification of unknown signal jamming technique.

On the other hand, the jamming signal processing system 310 may also include a jamming optimization algorithm 320 to generate and output a jamming signal for the unknown signal. Hereinafter, this will be described in more detail.

In the present invention, the jamming signal processing system 310 may include a jamming signal verifying apparatus and a jamming signal generating apparatus. The jamming signal verifying apparatus is an apparatus for generating a jamming signal and verifying the generation of a jamming signal, as described above with reference to Figs. 1 to 3. The jamming signal generating apparatus generates and outputs a jamming signal to the unknown signal, which will be described later with reference to Figs. 4 to 6. Fig.

The operation principle of the existing jamming system will be described as follows. 4 is a reference diagram for explaining the operation principle of a conventional jamming system.

In the conventional jamming system, when a threat signal is received (S405), the threat signal is analyzed based on the library (S410).

Then, if the threat signal is identified (S415), the conventional jamming system applies the jamming technique (S420) and transmits the jamming signal to the outside (S425). The conventional jamming system can improve the survival rate of the system put into the battlefield by transmitting the jamming signal against the identified threat (S430).

On the other hand, in the conventional jamming system, if the threat signal is not identified (S435), it is impossible to find an appropriate jamming technique and it becomes impossible to transmit the jamming signal to the outside (S440). In the conventional jamming system, since the jamming transmission is impossible with respect to the unidentified threat, the survival rate of the system put into the whole field may be reduced (S445).

The present invention has been proposed in order to overcome the disadvantages of the conventional jamming system. When the unidentified threat is received, various jamming signals are transmitted to find an optimized jamming technique by checking a break-lock, And transmits the optimized jamming signal to a non-identified signal received thereafter to improve the survivability.

Hereinafter, the system proposed above will be described with reference to FIGS. 5 and 6. FIG. The proposed system adopts an algorithm for generating an optimized jamming library for an unknown signal.

5 is a flowchart illustrating an operation method of a jamming signal processing system according to another embodiment of the present invention. And FIG. 6 is a reference diagram for explaining a process of generating a jamming signal by the jamming signal processing system according to an embodiment of the present invention.

First, an operation method of the jamming signal processing system will be described with reference to FIG. Each configuration of the jamming signal processing system 310 that implements the method of FIG. 5 refers to that shown in FIG.

When the unknown signal is received by the signal receiving unit 313 (S505), the signal analyzing unit 311 analyzes the unknown signal (S510). At this time, the signal analyzer 311 analyzes the unknown signal based on the library.

Thereafter, the signal analyzer 311 determines whether the unknown signal is identifiable based on the analysis result of the unknown signal (S515).

If it is determined that the unknown signal is identifiable, the jamming technique application / generation unit 315 detects an optimized jamming technique for the identified unknown signal based on the information stored in the library 314 (S520).

Thereafter, the jamming technique application / generation unit 315 generates a jamming signal based on the detected optimum jamming technique, and the signal transmission unit 312 transmits the jamming signal to the outside (S525).

Thereafter, the brake lock confirmation unit (not shown) determines whether a break-lock is generated based on the signal received by the signal reception unit 313 after the jamming signal is transmitted (S530). The break lock confirmation unit is provided in the jamming signal processing system 310. If the lock-on signal is not received through the analysis of the received signal, it is determined that a break lock has occurred.

Break-lock is a phenomenon in which a system that uses radar to detect and track a target loses its target and can no longer track the target. The jamming signal generating system 340 according to the present invention analyzes the threat signal when the threat signal (ex. Enemy radar signal) is received, and transmits the optimized jamming signal to the radar. If it is determined that the threat signal is not transmitted from the system (eg, enemy radar) that has transmitted the threat signal, the position is no longer exposed. Therefore, the jamming signal generation system 340 generates a jamming signal It is judged to be successful. In the present invention, the time when the jamming signal generation system 340 determines that the jamming has succeeded is determined as the time when the break lock occurs.

If it is determined in step S530 that no break lock has been generated, the jamming technique application / generation unit 315 applies the remaining techniques except for the jamming technique previously used for generating the jamming signal among the jamming techniques stored in the library, And S525 are repeated. The jamming technique application / generation unit 315 may repeat the above process until it is determined that a brake lock is generated.

If it is determined in step S530 that the brake lock is not generated, the jamming technique application / generation unit 315 may perform steps S520 and S525 again using the same jamming technique as before.

On the other hand, if it is determined in step S530 that a break lock has occurred, the jamming signal processing system 310 determines that the survival rate of the system inserted in the battlefield is improved and ends the jamming signal generation and output algorithm according to FIG.

If it is determined in step S515 that the unknown signal is not identifiable, the jamming technique application / generation unit 315 generates a jamming signal by selecting the highest priority jamming technique according to the scenario to which the sequence is applied (S535).

The jamming technique application / generation unit 315 is an element necessary for developing an algorithm for generating an optimized jamming library for the unknown signal, and starts jamming by applying a predetermined sequence according to characteristics of the analyzed signals after the unknown signal analysis. In other words, the jamming technique applying / generating unit 344 analyzes the unknown signals, and if the jamming technique applying unit 344 corresponds to a similar jam based on the identified library corresponding to the corresponding jam (eg, RF band, PRI / PW, etc.) Jamming is initiated by sending a signal. At this time, the jamming signal transmitted by the jamming technique application / generation unit 344 is not an optimized jamming signal, but is useful for finding an optimized jamming technique in a short period of time because the characteristic corresponds to a similar jam.

Jamming is a technique that is not used in conventional jamming systems. It uses the frequency characteristics of the signal, PW (Pulse Width), and PRI (Pulse Repeat Interval) as variables to apply the most probable library The most optimized techniques are selected, and several scenarios to apply the order are created and charged differently according to the unknown threat signal.

In the conventional jamming system, the jamming technique generation algorithm is applied only to the identified threats, but the jamming signal processing system 310 according to the present invention applies the sequential jamming technique to an unidentified signal as an algorithm for jamming.

If the jamming signal is generated in step S535, the signal transmitting unit 312 transmits the jamming signal to the outside (S540).

Thereafter, the brake lock confirmation unit determines whether a break-lock is generated based on the signal received by the signal reception unit 313 after the jamming signal is transmitted (S545, S550). As described above, when the lock-on signal is not received through analysis of the received signal, the brake lock confirming unit can determine that a brake lock has occurred.

If it is determined that the break lock is generated, the jamming technique storage unit (not shown) stores the jamming technique used for generating the jamming signal in the library together with information on the pattern of the unknown signal in step S555. Then, the jamming signal processing system 310 can detect the jamming technique every time a unknown signal having the same pattern is input, and utilize it to generate a jamming signal. The jamming technique storage unit is not shown in FIG. 6, but may be provided in the jamming signal processing system 310 in addition to the break lock confirmation unit.

In the conventional jamming system, only the determined jamming is transmitted and only one jamming is continuously transmitted irrespective of success or failure. On the other hand, the jamming signal processing system 310 according to the present invention transmits jamming through the sequential jamming technique, determines the jamming success after the transmission, and stores the optimized jamming algorithm in the library.

This procedure of the jamming signal processing system 310 determines whether or not the jamming has succeeded or failed, and if a threat occurs in the same signal, the conventional system is hit, while the system according to the present invention can survive .

Even if the operation is performed in the same area, the jamming can be succeeded even if the unknown signal is inputted by using the library reflecting the sequential jamming technique according to the present invention.

The algorithm for automatically registering the library by judging optimization jamming does not apply any existing system, and the algorithm can be applied to various platforms and used.

If it is determined in step S550 that the brake lock is not generated, the jamming technique application / generation unit 315 generates a jamming signal by selecting the jamming technique of the next rank according to the scenario to which the sequence is applied (S560, S535, S540 ). This operation of the jamming technique application / generation unit 315 can be continuously repeated until it is determined that a brake lock is generated.

The operation method of the jamming signal processing system described with reference to FIG. 5 will be summarized as follows.

Development of an algorithm for generating an optimized jamming library for unknown signal is an algorithm development to find an effective jamming technique even when the received threat is not identifiable and increase the survival rate of the system through jamming transmission.

If you receive an unknown radar signal, it is impossible to identify it even if you analyze it. However, analysis of the signal can determine whether it is a search radar or a lock-on radar. According to the present invention, the PA (Pulse Amplitude) characteristic of the received signal is analyzed to determine whether it is a signal by a search radar or a signal by a lock-on radar according to the pattern.

The algorithm transmits jamming signals by sequentially applying jamming techniques in a predefined order to lock-on unknown signals.

Jamming is judged to be successful at the time when break-lock is released due to release of lock-on to the unknown signal received after sequential jamming transmission, and the applied jamming technique is stored in the library in an optimized manner.

If a signal of the same pattern is received as a result of analysis of the unknown signal, an optimized jamming technique is applied according to the stored library. When signals of different patterns are received, the jamming technique is sequentially applied again in a predefined order, .

If you store the library in the same way as above, jamming can be successful even for unknown signals in the area. The algorithm can be applied to the battlefield system, and even if the operation is performed in a new area, it can improve the survival ability and improve the operational performance. That is, the present invention complements the disadvantage of not being able to jam the unidentified signals of the existing system, thereby enhancing the survival rate of the system put into the battlefield and improving the operational performance.

Next, referring to FIG.

When a signal is generated by the radar # 1 (Radar # 1) 330, the jamming signal processing system 310 confirms that the corresponding signal is not in the library through the reception / analysis and judges it as a unknown signal. Then, the jamming signal processing system 310 confirms that the unknown signal is locked-on.

The jamming signal processing system 310 determines that the signal is a missed signal, and sequentially applies a predefined jamming technique (n) to transmit a jamming signal, determines whether the device is locked-on, Check the occurrence.

If no break-lock occurs for the first jamming scheme, the second jamming scheme is applied to transmit the jamming signal. In the same way, a break-lock is detected and the jamming signal is transmitted by applying the n-th jamming technique according to whether the break-lock has occurred.

The jamming signal processing system 310 determines whether a break-lock occurs when a lock-on signal is not received through the analysis of the received signal, and stores the signal pattern and the technique in the library for the generated jamming technique do. Then, the signal of the radar # 1 330 is determined to be an identification signal that is not an unknown signal, so that the system can survive by transmitting the jamming by applying the optimum jamming technique.

As mentioned above, n times of jamming is applied to n radars, and the optimized technique is stored in the library. If no unknown signal is received, all the unknown signals in the area are stored in the library.

The library can then be used to perform operations in the area, and the optimization algorithms can be applied to systems operating in new areas.

On the other hand, the jamming signal generating system 340 for the unknown signal # 1 of the radar # 1 310 adds the jamming signal # 3 (jamming signal # 3, It is possible to determine the jamming signal # 3 as the optimized jamming signal when break-lock occurs. On the other hand, when the braking lock is generated in the jamming signal # 1 (jamming signal # 1, first generated jamming signal) for the unknown signal # 2 of the radar # 2 320, # 1 can be determined as the optimized jamming signal and when a break lock occurs in the jamming signal # 2 (meaning jamming signal # 2, second generated jamming signal) against the unknown signal # 3dp of the radar # 3 330, The signal # 2 can be determined as the optimized jamming signal. Thus, the number of jamming signals generated according to the radar can be determined according to the sequence application scenario based on the analysis result of the received signal. The above-mentioned sequence application scenario refers to an algorithm that generates stored jamming signals in order and finds an optimum jamming signal using a break lock and stores the jamming signal in a library.

The present invention described with reference to FIGS. 4 to 6 can find an optimized jamming scheme against an unidentified threat and enhance the survivability of a system put into the battlefield through jamming transmission.

The present invention described with reference to Figs. 1 to 6 can be applied to an electric field system (or electronic warfare system) for improving survivability, an electric field system (or an electronic warfare system) performed in a new operation area, a device for signal acquisition / Can be applied. The present invention can be used, for example, in an electronic warfare (EA) system, and it is possible to actively create a library in an area where a pre-established library can not be used, thereby improving survivability.

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention has been described with reference to Figs. Best Mode for Carrying Out the Invention Hereinafter, preferred forms of the present invention that can be inferred from the above embodiment will be described.

7 is a block diagram schematically illustrating a jamming signal processing system according to a preferred embodiment of the present invention. 8 is a block diagram illustrating internal configurations that may be added to the jamming signal processing system shown in FIG.

7, the jamming signal processing system 600 includes a threat signal processing unit 610, a jamming signal reception determination unit 620, a jamming signal generation determination unit 630, a power supply unit 640, and a main control unit 650 do.

The power supply unit 640 performs a function of supplying power to each of the components constituting the jamming signal processing system 600. The main control unit 650 performs a function of controlling the overall operation of each configuration of the jamming signal processing system 600. In consideration of the fact that the jamming signal processing system 600 may be provided in a normal threat signal generation system, the power supply unit 640 and the main control unit 650 may not be included in the present embodiment.

The threat signal processing unit 610 outputs a threat signal. The threat signal processing unit 610 can generate and output an unknown signal that is not defined in the library as a threat signal.

The threat signal processing unit 610 may perform a function of outputting a threat signal again when it is determined that the jamming signal has not been received for a predetermined time by the jamming signal reception determination unit 620. [

The threat signal processing unit 610 may control the jamming signal generation determination unit 630 to prevent the threat signal from being output when it is determined that the jamming signal is normally generated. In addition, the threat signal processing unit 610 may perform a function of outputting a threat signal again when it is determined that the jamming signal is not normally generated by the jamming signal generation determination unit 630. [

The jamming signal reception determination unit 620 determines whether a jamming signal for the threat signal is received after the threat signal is output by the threat signal processing unit 610. [

The jamming signal reception determination unit 620 can determine whether a jamming signal is received for a predetermined time. At this time, the predetermined time may be counted from the point of outputting the threat signal.

The jamming signal generation determination unit 630 compares the information obtained by analyzing the jamming signal with the information stored in the library when the jamming signal reception determination unit 620 determines that the jamming signal is received, and determines whether or not the jamming signal is normally generated And performs a function of judging.

The jamming signal generation determination unit 630 can acquire the jamming technique from the information obtained by analyzing the jamming signal. At this time, the jamming signal generation determination unit 630 can determine whether or not the jamming signal is normally generated based on whether or not the jamming technique is stored in the library.

If it is determined that the jamming technique is stored in the library, the jamming signal generation determination unit 630 determines that the jamming signal is normally generated by the jamming signal generation device. On the other hand, if it is determined that the jamming technique is not stored in the library, the jamming signal generation determination unit 630 determines that the jamming signal is not normally generated by the jamming signal generation device.

On the other hand, the jamming signal processing system 600 may not only verify the jamming signal generating device using the threat signal, but also receive the threat signal, generate a jamming signal therefrom, and output it to the target. That is, the jamming signal processing system 600 in the present invention may include a system having a jamming signal verification function and a system having a jamming signal generation function.

As shown in FIG. 7, the system having the jamming signal verifying function may include a threat signal processing unit 610, a jamming signal reception determination unit 620, and a jamming signal generation determination unit 630. In the case of the system having the jamming signal generating function, as shown in FIG. 8, the signal identification determiner 661, the jamming scheme determiner 662, the jamming signal generator 663, the jamming signal output unit 664, A technique processing unit 665, a jamming technique number determination unit 666, and the like.

Hereinafter, a system having a jamming signal generating function as a superposition of the jamming signal processing system 600 will be described with reference to FIG. In the present embodiment, the jamming signal processing system 600 having the jamming signal generation function can determine the jamming technique based on whether the threat signal is identifiable, and generate and output a jamming signal.

The signal identification determination unit 661 determines whether the first signal is identifiable based on the information stored in the library.

The jamming technique determination unit 662 determines whether or not the first signal can be identified by the signal identification determination unit 661. The jamming technique determination unit 662 determines the jamming technique for the first signal based on the information about the pulse of the first signal, .

The jamming technique determination unit 662 determines a jamming technique based on the frequency characteristics of the first signal, the pulse width (PW) of the first signal, and the pulse repetition interval (PRI) One can be used.

The jamming signal generation unit 663 generates a jamming signal based on the jamming technique determined by the jamming technique determination unit 662. [

The jamming signal output unit 664 performs a function of outputting the jamming signal generated by the jamming signal generation unit 663 to the outside.

The jamming technique determination unit 662 may sequentially determine at least two jamming techniques based on the analysis result of the characteristics of the first signal. Then, the jamming signal output unit 664 may sequentially output the jamming signals according to the determined order of the at least two jamming techniques.

On the other hand, if it is determined that the second signal is not also identifiable, the jamming scheme determination unit 662 continuously determines the jamming scheme for the first signal until it is determined that the signal received after the second signal is identifiable Can be performed.

Meanwhile, the jamming signal processing system 600 may further include a jamming technique number determination unit 666.

The jamming technique number determination unit 666 determines the number of jamming techniques based on the analysis result of the characteristic of the first signal.

The jamming scheme determination unit 662 may sequentially determine the jamming schemes based on the number of the jamming schemes determined by the jamming scheme number determination unit 666. [

On the other hand, if the jamming signal is output to the outside, the signal identification determiner 661 can determine whether the second signal received thereafter is identifiable. In consideration of this point, the jamming signal processing system 600 may further include a jamming signal output unit 665. [

The jamming signal output unit 665 stores the jamming technique determined by the jamming technique determination unit 662 in the library when it is determined that the second signal is identifiable.

The jamming signal output unit 665 may control the jamming technique to be applied to generate a jamming signal whenever a signal having the same pattern as that of the first signal is received after the jamming technique is stored in the library.

If it is determined that the first signal is a non-identifiable unknown signal, the signal identification determiner 661 estimates the first signal as a radar signal output by a search radar or a lock-on radar do. In the above, the search radar is used to monitor radar located in a specific area (eg, airport, port, enemy area, etc.), and to monitor the target (eg, airplane, ship, Means the radar used for. Lock-on radar means a radar with an automatic tracking function (Sight and track).

When the first signal is judged to be a locked-on unknown signal, the signal identification determination unit 661 outputs the jamming signal to the outside and determines whether the second signal received thereafter is identified. If it is determined that the lock-on of the second signal is canceled, the signal identification determination unit 661 determines that the jamming has succeeded at the time when the break-lock (tracking stop) occurs. Then, the jamming signal output unit 665 stores the jamming technique applied to the jamming signal generation in the library in a manner optimized for the first signal.

The jamming signal processing system 600 described above can be mounted on a flight vehicle. In this case, the jamming technique determination unit 662 can further utilize the position information of the flying object when determining the jamming technique. This takes into account the fact that a fixed search radar or lock-on radar can continuously output signals with the same pattern over a long period of time at that location.

On the other hand, the jamming signal processing system 600 is not limited to being mounted on a flight vehicle. The jamming signal processing system 600 may be mounted on a land vehicle (e.g., a vehicle) or a marine vehicle (e.g., a ship).

Next, an operation method of the jamming signal processing system 600 will be described. 9 is a flowchart schematically illustrating a method of processing a jamming signal according to a preferred embodiment of the present invention.

First, the threat signal processing unit 610 outputs a threat signal (S710).

Then, the jamming signal reception determiner 620 determines whether a jamming signal for the threat signal is received for a predetermined time (S720).

If it is determined that the jamming signal has been received, the jamming signal generation determining unit 630 compares the information obtained by analyzing the jamming signal with the information stored in the library to determine whether the jamming signal is normally generated (S730).

Between step S720 and step S730, if the threat signal processing unit 610 determines that the jamming signal has not been received for a predetermined time, the threat signal may be output again. The above-described step performed by the threat signal processing unit 610 may be performed simultaneously with step S730.

If it is determined in step S730 that the jamming signal has been normally generated, the threat signal processing unit 610 may control to prevent the threat signal from being output any more. Also, if the threat signal processing unit 610 determines that the jamming signal has not been normally generated, the threat signal may be output again.

On the other hand, after step S730, the process of generating the jamming signal can be further performed. This will be described below.

First, the signal identification determination unit 661 determines whether the first signal is identifiable based on the information stored in the library (A).

If it is determined that the first signal is not identifiable, the jamming scheme determination unit 662 determines a jamming scheme for the first signal based on the information about the pulse of the first signal (B).

Then, the jamming signal generator 663 generates a jamming signal based on the jamming technique determined by the jamming technique determiner 662 (C).

Then, the jamming signal output unit 664 outputs the jamming signal to the outside (D).

On the other hand, after step D, the signal identification determination unit 661 can determine whether or not the subsequent second signal is identifiable. At this time, if it is determined that the second signal is identifiable, the jamming signal output unit 665 may store the jamming technique determined by the jamming technique determination unit 662 in the library.

Meanwhile, after the jamming technique is stored in the library, the jamming signal output unit 665 can control the jamming technique to be applied to generate a jamming signal whenever a signal having the same pattern as the first signal is received.

Between steps A and B, the number of jamming techniques may be determined based on the result of analyzing the characteristics of the first signal. Then, the jamming technique determination unit 662 sequentially determines at least two jamming techniques based on the number of the jamming techniques, and then the jamming signal output unit 664 sequentially outputs the jamming signals in order of determining at least two jamming techniques As shown in FIG.

It is to be understood that the present invention is not limited to these embodiments, and all elements constituting the embodiment of the present invention described above are described as being combined or operated in one operation. That is, within the scope of the present invention, all of the components may be selectively coupled to one or more of them. In addition, although all of the components may be implemented as one independent hardware, some or all of the components may be selectively combined to perform a part or all of the functions in one or a plurality of hardware. As shown in FIG. In addition, such a computer program may be stored in a computer readable medium such as a USB memory, a CD disk, a flash memory, etc., and read and executed by a computer to implement an embodiment of the present invention. As the recording medium of the computer program, a magnetic recording medium, an optical recording medium, a carrier wave medium, and the like can be included.

Furthermore, all terms including technical or scientific terms have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined in the Detailed Description. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

It will be apparent to those skilled in the art that various modifications, substitutions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. will be. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . 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.

Claims (16)

A jamming signal generating device for generating and outputting the jamming signal with respect to a threat signal using an algorithm for generating a jamming signal; And
A threat signal processing unit for generating and outputting the threat signal; A jamming signal reception judging unit for judging whether or not a jamming signal for the threat signal is received from the jamming signal generating apparatus; And a jamming signal generation determination unit for determining whether the jamming signal is normally generated by comparing the information obtained by analyzing the jamming signal with the information stored in the library when it is determined that the jamming signal has been received, A jamming signal verifying device for verifying an algorithm for generating the jamming signal mounted on the jamming signal generating device based on a result of judging whether or not the jamming signal is generated;
The jamming signal processing system comprising: The method according to claim 1,
Wherein the threat signal processor outputs the threat signal again when it is determined that the jamming signal has not been received for a predetermined period of time. The method according to claim 1,
Wherein the threat signal processing unit generates an unknown signal that is not defined in the library as the threat signal and outputs the generated threat signal. The method according to claim 1,
Wherein the jamming signal generation determination unit obtains a jamming technique from information obtained by analyzing the jamming signal and determines whether the jamming signal is normally generated based on whether or not the jamming technique is stored in the library Jamming Signal Processing System Using Threat Signals. The method according to claim 1,
Wherein the threat signal processing unit controls the threat signal to no longer be output if it is determined that the jamming signal is normally generated and controls the threat signal to be output again if it is determined that the jamming signal is not normally generated Jamming Signal Processing System Using Threat Signals. The method according to claim 1,
The jamming signal generating apparatus includes:
A signal identification determiner for determining whether the first signal is identifiable based on information stored in the library;
A jamming technique determination unit for determining a jamming technique for the first signal based on information about a pulse of the first signal when it is determined that the first signal is not identifiable;
A jamming signal generator for generating a jamming signal based on the determined jamming technique; And
A jamming signal output unit for outputting the jamming signal to the outside,
The jamming signal processing system comprising: The method according to claim 6,
Wherein the jamming technique determination unit uses at least one of a frequency characteristic of the first signal, a pulse width of the first signal, and a pulse repetition period of the first signal as information on the pulse. Processing system. The method according to claim 6,
Wherein the signal identification determiner determines whether a second signal received after the jamming signal is output to the outside,
The jamming signal generating apparatus includes:
And if the second signal is determined to be identifiable, storing the determined jamming technique in the library,
Wherein the jamming signal processing system further comprises: 9. The method of claim 8,
The jamming scheme processing unit controls the determined jamming scheme to apply the generated jamming signal every time a signal having the same pattern as that of the first signal is received after the determined jamming scheme is stored in the library Jamming signal processing system using threat signal. The method according to claim 6,
Wherein the jamming technique determination unit sequentially determines at least two jamming techniques based on a result of analyzing characteristics of the first signal,
Wherein the jamming signal output unit sequentially outputs the jamming signals according to the determined order of the at least two jamming techniques. 11. The method of claim 10,
The jamming signal generating apparatus includes:
Determining a number of jamming techniques based on a result of analyzing the characteristics of the first signal;
Further comprising:
Wherein the jamming scheme determination unit sequentially determines jamming schemes based on the number of the jamming schemes. The method according to claim 6,
The jamming signal output control device is mounted on a flying object,
Wherein the jamming technique determination unit further uses the position information of the flying object when determining the jamming technique. Generating a threat signal and outputting the threat signal;
Generating a jamming signal for the threat signal using an algorithm for generating a jamming signal and outputting the jamming signal;
Determining whether a jamming signal for the threat signal is received from the jamming signal generator;
Determining whether the jamming signal is normally generated by comparing the information obtained by analyzing the jamming signal with information stored in the library if the jamming signal verifying device determines that the jamming signal is received; And
The jamming signal verifying apparatus verifying whether or not the jamming signal is normally generated, verifying an algorithm for generating the jamming signal mounted on the jamming signal generating apparatus based on a result obtained by judging whether or not the jamming signal is normally generated
And generating a threat signal using the threat signal. 14. The method of claim 13,
When the jamming signal verifying apparatus judges that the jamming signal has not been received for a predetermined period of time,
And generating a threat signal using the threat signal. 14. The method of claim 13,
Controlling the jamming signal verifier so that the threat signal is no longer output if it is determined that the jamming signal is normally generated, and controlling the threat signal to be output again if it is determined that the jamming signal is not normally generated
And generating a threat signal using the threat signal. 14. The method of claim 13,
Determining whether the first signal is identifiable based on information stored in the library;
Determining the jamming scheme for the first signal based on the information about the pulse of the first signal if the jamming signal generator determines that the first signal is not identifiable;
Generating the jamming signal based on the determined jamming technique; And
Wherein the jamming signal generating device outputs the jamming signal to the outside
And generating a threat signal using the threat signal.

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