KR102431523B1 - Radar jamming system and radar jamming method - Google Patents

Abstract

A radar jamming system and a radar jamming method may be disclosed. A radar jamming system according to an embodiment of the present invention includes: an spurious signal removal filtering unit for receiving a radar signal and removing the spurious signal from the radar signal; an intermediate frequency band conversion unit connected to the spurious signal removal filtering unit and performing intermediate frequency conversion for converting a frequency into an intermediate frequency band on the radar signal from which the spurious signal has been removed; a first amplifier connected to the intermediate frequency band converter and amplifying the radar signal frequency-converted to the intermediate frequency band; an intermediate frequency filter bank that performs at least one filtering process among a wideband filtering process, a middle band filtering process, and a narrowband filtering process on the frequency-converted radar signal; and a high-frequency storage unit for storing the filtered radar signal.

Description

Radar jamming system and radar jamming method

The present invention relates to a radar jamming system and a radar jamming method.

The radar jamming system is a kind of jamming system, and there are two methods of jamming the radar jamming system as follows. First, there is a jamming method that simultaneously jams forward and backward when a signal of a threat is detected without detecting the direction of the target. In addition, there is a method in which jamming is first performed forward when detection of a signal of a threat exists in the front, and jamming is performed backward when detection of a signal of a threat exists in the rear.

In general, a radar jamming system receives a wideband radar signal, and turns on/off each of a splitter for distributing the received wideband radar signal in parallel, a plurality of narrowband filters, and a plurality of narrowbandpass filters (ie, filter paths) a switch, and an amplifier connected to each of the plurality of narrow-pass filters.

The conventional radar jamming system may determine the number of paths of the narrow-pass filter based on the narrow-pass filter band. For example, in the case of a radar signal having a bandwidth of 10 GHz and a narrow-pass filter having a bandwidth of 0.2 GHz, 50 paths (ie, 50 narrow-pass filters) are required. For this reason, there is a problem in that the size, weight, cost, etc. of the radar jamming system increase due to an increase in the number of narrow-pass filters and switches. In addition, it is difficult to manufacture a divider for multiple distribution of a wideband radar signal and a narrowband pass filter, which increases the cost of manufacturing the divider and the narrowband pass filter. Furthermore, in the conventional radar jamming system, as the number of narrow-pass filters increases, the number of amplifiers connected to the narrow-pass filters also increases, which results in increased power consumption and increased heat generation.

On the other hand, the conventional radar jamming system controls a switch using threat radar frequency information, detects the presence or absence of a signal by performing envelope detection on the passed target frequency signals, and controls the detection reference strength to control the high frequency memory device. The signal is stored in However, since the conventional radar jamming system performs envelope detection and the like on target frequency signals, it is very difficult to adjust the characteristics of analog paths to be similar.

The present invention may provide a radar jamming system and a radar jamming method for performing frequency conversion on a radar signal into an intermediate frequency band and performing filtering on the frequency-converted radar signal.

According to an embodiment of the present invention, a radar jamming system may be disclosed. A radar jamming system according to an embodiment includes: an spurious signal removal filtering unit for receiving a radar signal and removing the spurious signal from the radar signal; an intermediate frequency band conversion unit connected to the spurious signal removal filtering unit and performing intermediate frequency conversion to convert a frequency into an intermediate frequency band on the radar signal from which the spurious signal has been removed; a first amplifier connected to the intermediate frequency band converter and amplifying the radar signal frequency-converted to the intermediate frequency band; an intermediate frequency filter bank for performing at least one filtering process among a wideband filtering process, a middle band filtering process, and a narrowband filtering process on the frequency-converted radar signal; and a high-frequency storage unit for storing the filtered radar signal.

In an embodiment, the intermediate frequency band converter comprises: a frequency up-converter for generating an intermediate frequency converted signal for converting the radar signal into a signal having an intermediate frequency; and a mixer configured to generate a radar signal having the intermediate frequency by synthesizing the spurious signal-filtered radar signal and the intermediate frequency converted signal.

In an embodiment, the frequency up-converter may include a local oscillator.

In an embodiment, the frequency up-converter may generate the intermediate frequency converted signal based on a jamming target and time control.

In one embodiment, the intermediate frequency filter bank, a wideband pass filter for passing a wideband signal with respect to the frequency-converted radar signal; a middle-pass filter for passing a middle-band signal to the frequency-converted radar signal; a first selector for selecting at least one of the broadband pass filter and the middle pass filter; a narrowband pass filter for passing a narrowband signal with respect to the frequency-converted radar signal; a narrowband suppression filter for suppressing a narrowband signal with respect to the frequency-converted radar signal; and a second selector configured to select at least one of the narrowband pass filter and the narrowband suppression filter.

In an embodiment, the intermediate frequency filter bank may further include a filter selection control unit for controlling the first selector and the second selector by using the threat radar frequency information.

In one embodiment, the high frequency storage unit, the envelope detection unit for performing envelope detection on the filtered radar signal; and a signal storage unit configured to store the filtered radar signal based on the envelope detection.

In an embodiment, the envelope detection unit detects the presence or absence of a signal by performing envelope detection on the filtered radar signal, and a reference for storing the filtered radar signal based on the detected presence or absence age can be determined.

In an embodiment, the signal storage unit may store the filtered radar signal based on the reference intensity.

In an embodiment, the high frequency storage unit may further include a second amplifier disposed between the intermediate frequency filter bank and the envelope detector and amplifying the radar signal filtered by the intermediate frequency filter bank. have.

According to an embodiment of the present invention, a radar jamming method in a radar jamming system may be disclosed. A radar jamming method according to an embodiment includes: removing, in an unwanted signal removal filtering unit of the radar jamming system, an unwanted signal from a received radar signal; performing, in an intermediate frequency band converter of the radar jamming system, an intermediate frequency conversion for frequency conversion to an intermediate frequency band on the radar signal from which the unnecessary signal has been removed; amplifying, by the first amplifying unit of the radar jamming system, the radar signal frequency-converted to the intermediate frequency band; performing, in the intermediate frequency filter bank of the radar jamming system, at least one filtering process among a wideband filtering process, a middle band filtering process, and a narrowband filtering process on the frequency-converted radar signal; and storing the filtered radar signal in the high frequency storage unit of the radar jamming system.

In one embodiment, the step of performing an intermediate frequency conversion for converting a frequency to an intermediate frequency band on the radar signal from which the unnecessary signal is removed comprises: an intermediate frequency conversion signal for converting the radar signal into a signal having an intermediate frequency creating a; and generating the radar signal having the intermediate frequency by synthesizing the unwanted signal-filtered radar signal and the intermediate frequency converted signal.

In an embodiment, the generating of the intermediate frequency converted signal may include generating the intermediate frequency converted signal based on a jamming target and time control.

In one embodiment, the step of performing at least one filtering process among a wideband filtering process, a medium-band filtering process, and a narrowband filtering process on the frequency-converted radar signal includes passing a wideband signal with respect to the frequency-converted radar signal selecting at least one first filter from among a wide band pass filter that transmits a signal or a middle pass filter that passes a middle band signal with respect to the frequency-converted radar signal; performing at least one filtering process among the wideband filtering process and the middle band filtering process on the radar signal frequency-converted through the selected at least one first filter; selecting at least one second filter from among a narrow-pass filter for passing a narrow-band signal with respect to the frequency-converted radar signal or a narrow-band suppression filter for suppressing a narrow-band signal with respect to the frequency-converted radar signal; and performing a narrowband pass filtering process or a narrowband suppression filtering process on the frequency-converted radar signal through the selected at least one second filter.

In an embodiment, the selecting of the at least one first filter may include selecting at least one of the wideband pass filter and the middle pass filter using threat radar frequency information. have.

In an embodiment, the selecting of the at least one second filter may include selecting at least one of the narrowband pass filter and the narrowband suppression filter using threat radar frequency information. can

In an embodiment, the storing of the filtered radar signal comprises: performing envelope detection on the filtered radar signal; and storing the filtered radar signal based on the envelope detection.

In an embodiment, the performing the envelope detection on the filtered radar signal includes: detecting the presence or absence of a signal by performing envelope detection on the filtered radar signal; and determining a reference intensity for storing the filtered radar signal based on the detected presence or absence.

In an embodiment, storing the filtered radar signal based on the envelope detection may include storing the filtered radar signal based on the reference intensity.

In an embodiment, the storing of the filtered radar signal may further include amplifying the filtered radar signal.

According to various embodiments of the present invention, only target frequency signals may be output by filtering the radar signal, the presence or absence of the signal may be detected through envelope detection, and the radar signal may be stored by controlling the detected reference strength. can be

In addition, since the path is small, the analog configuration can be simplified, thereby reducing the size, weight, cost, etc. of the radar jamming system.

In addition, since heat generation is low, analog hardware development is relatively easy, and a wideband signal can be filtered using one filter instead of using a plurality of filters, filtering characteristics can be improved.

Furthermore, according to various embodiments of the present invention, a narrow band can be made narrower and a band suppression filter can be used, so that the removal probability of an unwanted interference signal adjacent to the target radar signal can be increased.

1 is a block diagram schematically showing a conventional radar jamming system.
2 is a block diagram schematically showing the configuration of a filter bank of a conventional filter bank unit.
3 is a diagram illustrating an example of selecting a narrowband signal in a conventional radar jamming system.
4 is a block diagram schematically illustrating a radar jamming system according to an embodiment of the present invention.
5 is a block diagram schematically showing the configuration of an intermediate frequency filter bank according to an embodiment of the present invention.
6 is a flowchart illustrating a radar jamming method according to an embodiment of the present invention.
7 is a diagram illustrating an example of selecting a radar signal according to an embodiment of the present invention.

Embodiments of the present invention are exemplified for the purpose of explaining the technical spirit of the present invention. The scope of the rights according to the present invention is not limited to the embodiments presented below or specific descriptions of these embodiments.

All technical and scientific terms used in the present invention, unless otherwise defined, have the meanings commonly understood by one of ordinary skill in the art to which this invention belongs. All terms used in the present invention are selected for the purpose of more clearly describing the present invention and not to limit the scope of the present invention.

As used herein, expressions such as "comprising", "including", "having", etc. are open-ended terms that include the possibility of including other embodiments, unless otherwise stated in the phrase or sentence in which the expression is included. (open-ended terms).

Expressions in the singular in the present invention may include the meaning of the plural unless otherwise stated, and the same applies to expressions in the singular in the claims.

Expressions such as “first” and “second” used in the present invention are used to distinguish a plurality of components from each other, and do not limit the order or importance of the components.

As used herein, the term “unit” refers to software or hardware components such as field-programmable gate arrays (FPGAs) and application specific integrated circuits (ASICs). However, "units" are not limited to hardware and software. A “unit” may be configured to reside on an addressable storage medium, or it may be configured to refresh one or more processors. Thus, by way of example, “part” includes components such as software components, object-oriented software components, class components, and task components, processes, functions, attributes, procedures, subroutines, It includes segments of program code, drivers, firmware, microcode, circuits, data, databases, data structures, tables, arrays, and variables. Functions provided within components and “parts” may be combined into a smaller number of components and “parts” or separated into additional components and “parts”.

As used herein, the expression "based on" is used to describe one or more factors affecting the action or action of a decision judgment, which are described in a phrase or sentence in which the expression is included, which expression is a decision , does not exclude additional factors affecting the conduct or behavior of judgment.

In the present invention, when it is said that a certain element is "connected" or "connected" to another element, a certain element can be directly connected or connectable to another element, or a new other element. It should be understood that the elements may be connected or may be connected via an element.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In the accompanying drawings, identical or corresponding components are assigned the same reference numerals. In addition, in the description of the embodiments below, overlapping description of the same or corresponding components may be omitted. However, even if description regarding components is omitted, it is not intended that such components are not included in any embodiment.

1 is a block diagram schematically showing a conventional radar jamming system. Referring to FIG. 1 , the radar jamming system 100 includes a distribution unit 110 , a filter bank unit 120 , a first amplifier 130 , a coupling unit 140 , a second amplifier 150 , and an envelope detection unit. 160 and a high frequency storage unit 170 may be included.

The distribution unit 110 receives the radar signal and distributes the received radar signal in parallel. That is, the distribution unit 110 distributes the received radar signal in parallel according to the number of filter banks of the filter bank unit 120 .

The filter bank unit 120 is connected to the distribution unit 110 , and receives the radar signal distributed by the distribution unit 110 . The filter bank unit 120 performs filtering processing on the received radar signal. The filter bank unit 120 includes a plurality of filter banks 121_1 to 121_4 having N (N is an integer greater than or equal to 1) channels.

The first amplifier 130 is connected to the filter bank unit 120 and amplifies the radar signal filtered by the filter bank unit 120 . The first amplifier 130 includes a plurality of amplifiers 131_1 to 131_4 connected one-to-one to the plurality of filter banks 121_1 to 121_4 of the filter bank unit 120 .

The coupling unit 140 is connected to the first amplifying unit 130 and receives the radar signal amplified by the first amplifying unit 130 . The combiner 140 combines the received radar signal and outputs the combined radar signal.

The second amplifying unit 150 is connected to the coupling unit 140 , and receives the radar signal combined by the coupling unit 140 . The second amplifier 150 amplifies the received radar signal and outputs the amplified radar signal.

The envelope detector 160 is connected to the second amplifier 150 and receives the radar signal amplified by the second amplifier 150 . The envelope detection unit 160 detects the presence or absence of a signal by performing envelope detection processing on the received radar signal, and determines a reference strength for storing the radar signal in the high frequency storage unit 170 .

The high frequency storage unit 170 is connected to the second amplification unit 150 and the envelope detection unit 160 , and based on the reference intensity determined by the envelope detection unit 160 , the radar amplified by the second amplification unit 150 . Save the signal.

2 is a block diagram schematically showing the configuration of a filter bank of a conventional filter bank unit. Referring to FIG. 2 , the filter bank 121_i (1≤i≤4) includes a divider 210 , a switching unit 220 , a pass filtering unit 230 , a combiner 240 , and a filter selection control unit 250 . do.

The distributor 210 receives the radar signal distributed by the distributor 110 and redistributes the received radar signal in parallel. The distributor 210 redistributes the radar signal in parallel based on the number of switches and pass filters of the switching unit 220 and the pass filtering unit 230 .

The switching unit 220 is connected to the distributor 210 and receives the radar signal distributed by the distributor 210 . The switching unit 220 connects to the pass filtering unit 230 based on a control signal provided from the filter selection control unit 250 . The switching unit 220 includes a plurality of switches 220_1 to 220_N.

The pass filtering unit 230 is connected to the switching unit 220 , and receives a radar signal from the switching unit 220 . The pass filtering unit 220 performs filtering processing on the received radar signal. The pass filtering unit 230 includes a plurality of narrowband pass filters 230_1 to 230_N connected one-to-one to the plurality of switches 220_1 to 220_N.

The combiner 240 is connected to the pass filtering unit 230 and receives the radar signal filtered by the pass filtering unit 230 , that is, each of the plurality of narrowband pass filters 230_1 to 230_N. The combiner 240 combines the filtered radar signal and outputs the combined radar signal.

The filter selection control unit 250 is connected to the switching unit 220 and generates a control signal for controlling on or off of each of the plurality of switches 220_1 to 220_N of the switching unit 220 . The generated control signal is output to the switching unit 220 . The filter selection control unit 250 generates a control signal for controlling on or off of each of the plurality of switches 220_1 to 220_N based on the threat radar frequency information.

3 is a diagram illustrating an example of selecting a signal in a conventional radar jamming system. As shown in FIG. 3 , the radar jamming system 100 may facilitate filtering control of a radar signal when the threat radar frequency information is known, and may respond to narrowband and wideband radar signals. However, the conventional radar jamming system 100 determines the number of paths of the narrow-pass filter based on the narrow-pass filter band. As a result, the number of the narrow-pass filters 230_1 to 230_N and the switches 220_1 to 220_N increases, thereby increasing the size, weight, and cost of the radar jamming system 100 . In addition, there is a problem in that the multi-distribution of the wideband radar signal and the manufacturing of the narrow-pass filters 230_1 to 230_N are difficult, thereby increasing the cost of manufacturing the divider and the narrow-pass filter. Furthermore, in the conventional radar jamming system, as the number of narrow-pass filters increases, the number of amplifiers connected to the narrow-pass filters also increases, which results in increased power consumption and increased heat generation.

On the other hand, the conventional radar jamming system 100 controls a switch using threat radar frequency information, detects the presence or absence of a signal by performing envelope detection on passed target frequency signals, and controls the detection reference strength, etc. The radar signal is stored in the high frequency storage unit 170 . However, since the conventional radar jamming system 100 performs envelope detection and the like on target frequency signals, it is very difficult to similarly adjust the characteristics of analog paths.

4 is a block diagram schematically illustrating a radar jamming system according to an embodiment of the present invention. Referring to FIG. 4 , the radar jamming system 400 includes a spurious signal removal filtering unit 410 , an intermediate band frequency conversion unit 420 , a first amplifier 430 , an intermediate frequency filter bank 440 , and a high frequency storage unit. (450).

The spurious signal removal filtering unit 410 may receive a radar signal and filter the received radar signal. In an embodiment, the spurious signal removal filtering unit 410 may perform filtering to remove the spurious signal from the radar signal.

The intermediate frequency band converter 420 may be connected to the spurious signal removal filtering unit 410 and receive the radar signal filtered by the spurious signal removal filtering unit 410 . The intermediate frequency band converter 420 may perform intermediate frequency conversion for converting a frequency into an intermediate frequency band on the unwanted signal-filtered radar signal. In an embodiment, the intermediate frequency band converter 420 may include a frequency up converter 421 and a mixer 422 as shown in FIG. 4 .

The frequency up-converter 421 may generate a signal for converting a radar signal into a signal having an intermediate frequency (hereinafter, referred to as an "intermediate frequency conversion signal"). In an embodiment, the frequency up-converter 421 may generate an intermediate frequency-converted signal based on a jamming target and time control. In an embodiment, the frequency up-converter 421 may use a direct digital synthesizer (DDS) for fast frequency change. In an embodiment, the frequency up-converter 421 may include a local oscillator (LO).

The mixer 422 is connected to the spurious signal removal filtering unit 410 and the frequency up-converting unit 421 , receives the spurious signal-filtered radar signal from the spurious signal removal filtering unit 410 , and the frequency up-converting unit 421 . ) can receive an intermediate frequency converted signal. The mixer 422 may generate a radar signal having an intermediate frequency by synthesizing the spurious signal-filtered radar signal and the intermediate frequency converted signal.

The first amplifier 430 may be connected to the intermediate frequency band converter 420 to receive a radar signal having an intermediate frequency from the intermediate frequency band converter 420 . The first amplifier 430 may amplify a radar signal having an intermediate frequency.

The intermediate frequency filter bank 440 may be connected to the first amplifier 430 to receive the radar signal amplified from the first amplifier 430 . The intermediate frequency filter bank 440 may perform at least one filtering process among a wideband filtering process, a middle band filtering process, and a narrowband filtering process on the amplified radar signal. In one embodiment, the intermediate frequency filter bank 440 may perform at least one filtering process among a wideband filtering process, a middle band filtering process, and a narrowband filtering process by using the threat radar frequency information.

The high frequency storage unit 450 may be connected to the intermediate frequency filter bank 440 to receive the radar signal filtered by the intermediate frequency filter bank 440 . The high frequency storage unit 450 may store the received radar signal. In an embodiment, the high frequency memory unit 450 may include a second amplifier 451 , an envelope detection unit 452 , and a signal storage unit 453 as shown in FIG. 1 .

The second amplifier 451 may be connected to the intermediate frequency filter bank 440 to receive the radar signal filtered by the intermediate frequency filter bank 440 . Also, the second amplifying unit 451 may amplify the received radar signal.

The envelope detector 452 may be connected to the second amplifying unit 451 to receive the radar signal amplified by the second amplifying unit 451 . The envelope detector 452 may detect the presence or absence of a radar signal by performing envelope detection on the received radar signal, and determine a reference strength (ie, a storage reference) for storing the radar signal.

The signal storage unit 453 may be connected to the second amplifier 451 and the envelope detection unit 452 . The signal storage unit 453 may store the radar signal amplified by the second amplifier 451 based on the reference intensity determined by the envelope detection unit 452 .

5 is a block diagram schematically showing the configuration of an intermediate frequency filter bank according to an embodiment of the present invention. Referring to FIG. 5 , the intermediate frequency filter bank 440 includes a first selector 510 , a wide band pass filter 520 , a middle pass filter 530 , a second select unit 540 , and a narrow pass filter ( 550) and a narrowband suppression filter 560. Also, the intermediate frequency filter bank 440 may further include a filter selection control unit 570 .

The first selector 510 may select at least one of the wideband pass filter 520 and the middle pass filter 530 . In an embodiment, the first selector 510 includes a first front-end selector 511 disposed in front of the wideband pass filter 520 and the middle pass filter 530 , and a wideband pass filter 520 and A first rear-end selector 512 disposed at a rear end of the middle-pass filter 530 may be included.

The broadband pass filter 520 may be connected to the first selector 510 . For example, the broadband pass filter 520 may be disposed between the first front-end selector 511 and the first rear-end selector 512 . The wideband pass filter 520 may perform a filtering process for passing the wideband signal on the radar signal amplified by the first amplifier 430 .

The middle pass filter 530 may be connected to the first selector 510 . For example, the middle pass filter 530 may be disposed between the first front-end selector 511 and the first rear-end selector 512 . The middle pass filter 530 may perform a filtering process for passing the middle band signal to the radar signal amplified by the first amplifier 430 .

The second selector 540 may select at least one of the narrowband pass filter 550 and the narrowband suppression filter 560 . In an embodiment, the second selector 540 includes a second front-end selector 541 disposed in front of the narrowband pass filter 550 and the narrowband suppression filter 560 , and the narrowband pass filter 550 . ) and a second rear end selector 542 disposed at the rear end of the narrowband suppression filter 560 .

The narrowband pass filter 550 may be connected to the second selector 540 to receive the filtered radar signal from the second selector 540 . For example, the narrowband pass filter 550 may be disposed between the second front-end selector 541 and the second rear-end selector 542 . The narrowband pass filter 550 may perform filtering processing for passing the narrowband signal on the received radar signal.

The narrowband suppression filter 560 may be connected to the second selector 540 to receive the filtered radar signal from the second selector 540 . For example, the narrowband suppression filter 560 may be disposed between the second front end selector 541 and the second rear end selector 542 . The narrowband suppression filter 550 may perform filtering processing for suppressing the narrowband signal on the received radar signal.

The filter selection control unit 570 may be connected to the first selection unit 510 and the second selection unit 540 . The filter selection controller 570 may generate a control signal for controlling the first selector 510 and the second selector 540 . In an embodiment, the filter selection controller 570 may generate a control signal for controlling the first selector 510 and the second selector 540 by using the threat radar frequency information.

For example, the filter selection control unit 570 uses the threat radar frequency information to select a control signal (hereinafter, referred to as “first control signal"). The filter selection control unit 570 may transmit the generated first control signal to the first selection unit 510 . In addition, the filter selection control unit 570 uses the threat radar frequency information, and a control signal for selecting at least one filter from the narrowband pass filter 550 or the narrowband suppression filter 560 (hereinafter, “second control”) signal"). The filter selection control unit 570 may transmit the generated second control signal to the second selection unit 540 .

According to the above-described embodiment, a path may be selected by various combinations of the wideband pass filter 520 , the middle pass filter 530 , the narrowband pass filter 550 , and the narrowband suppression filter 560 .

Although process steps, method steps, algorithms, etc. are described in a sequential order in the flowcharts shown herein, such processes, methods, and algorithms may be configured to operate in any suitable order. In other words, the steps of the processes, methods, and algorithms described in various embodiments of the invention need not be performed in the order described herein. Also, although some steps are described as being performed asynchronously, in other embodiments some of these steps may be performed concurrently. Further, the exemplification of a process by description in the drawings does not imply that the exemplified process excludes other changes and modifications thereto, and that the exemplified process or any of its steps may be used in any of the various embodiments of the present invention. It is not meant to be essential to one or more, nor does it imply that the illustrated process is preferred.

6 is a flowchart illustrating a radar jamming method according to an embodiment of the present invention. Referring to FIG. 6 , in step S602 , the spurious signal removal filtering unit 410 may perform spurious signal removal filtering processing on the radar signal. In an embodiment, the spurious signal removal filtering unit 410 may receive a radar signal and perform spurious signal removal filtering processing on the received radar signal. For example, as shown in FIG. 7 , the spurious signal removal filtering unit 410 removes and filters the spurious signal from the radar signal including the narrowband signal 710 , the interference signal 720 , and the wideband signal 730 . By performing , the radar signal from which the interference signal 720 corresponding to the unwanted signal is removed, that is, the radar signal including the narrowband signal 710 and the wideband signal 730 may be output.

In operation S604 , the intermediate frequency band converter 420 may perform intermediate frequency conversion for frequency conversion to the intermediate frequency band on the radar signal from which the unnecessary signal has been removed by the spurious signal removal filtering unit 410 .

In an embodiment, the intermediate frequency band converter 420 may generate an intermediate frequency converted signal, and may generate a radar signal having an intermediate frequency by synthesizing the radar signal from which the unwanted signal is filtered and the intermediate frequency converted signal. For example, as shown in FIG. 7 , the intermediate frequency band converter 420 synthesizes a radar signal including a narrowband signal 710 and a wideband signal 730 and an intermediate frequency converted signal to obtain an intermediate frequency. It is possible to generate a radar signal with

In step S606 , the first amplifier 430 may amplify the radar signal frequency-converted to the intermediate frequency band by the intermediate frequency band converter 420 and output the amplified radar signal.

In step S608 , the intermediate frequency filter bank 440 may perform at least one filtering process among a wideband filtering process, a middle band filtering process, and a narrowband filtering process on the radar signal amplified by the first amplifier 430 . .

In one embodiment, the intermediate frequency filter bank 440 may perform at least one filtering process among a wideband filtering process, a middle band filtering process, and a narrowband filtering process by using the threat radar frequency information. For example, as shown in FIG. 7 , the intermediate frequency filter bank 440 performs wideband filtering on the radar signal through the wideband pass filter 520 selected by the first selector 510 to perform a wideband signal ( 730) can be output. In addition, as shown in FIG. 7 , the intermediate frequency filter bank 440 performs narrowband filtering on the radar signal through the narrowband pass filter 550 selected by the second selector 540 to perform narrowband signal processing. 710 may be output.

In step S610 , the high frequency storage unit 450 may store the radar signal filtered by the intermediate frequency filter bank 440 . In an embodiment, the high frequency storage unit 450 detects the presence or absence of a signal by performing envelope detection on the filtered radar signal, and a reference intensity for storing the filtered radar signal based on the detected presence or absence. can be decided In some embodiments, the high frequency storage unit 450 may store the filtered radar signal based on the reference intensity.

Optionally, the high frequency storage unit 450 may store the radar signal by amplifying the radar signal filtered by the intermediate frequency filter bank 440 and performing envelope detection on the amplified radar signal.

As described above, the radar jamming system 400 according to the present embodiment may output only target frequency signals by filtering the radar signal, detect the presence or absence of a signal through envelope detection, and determine the detected reference strength. It can be controlled to store the radar signal. In addition, the radar jamming system 400 according to the present embodiment can simplify the analog configuration because there are few paths, thereby reducing the size, weight, and cost. In addition, the radar jamming system 400 according to the present embodiment generates less heat and is relatively easy to develop analog hardware, and since it uses one filter instead of using several conventional filters for a wideband signal, the filtering characteristics can be improved. have. Furthermore, the radar jamming system 400 according to the present embodiment can make a narrow band narrower and use a band suppression filter, so that it is possible to increase the removal probability of an unnecessary interference signal adjacent to the target radar signal.

Although the above method has been described through specific embodiments, the above method may also be implemented as computer readable code on a computer readable recording medium. The computer-readable recording medium includes all types of recording devices in which data readable by a computer system is stored. Examples of the computer-readable recording medium include ROM, RAM, CD-ROM, magnetic tape, floppy disk, and optical data storage device. In addition, the computer-readable recording medium is distributed in a computer system connected to a network, so that the computer-readable code can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the above embodiments can be easily inferred by programmers in the technical field to which the present invention pertains.

Although the technical idea of the present invention has been described by the examples shown in some embodiments and the accompanying drawings above, it does not depart from the technical spirit and scope of the present invention that can be understood by those of ordinary skill in the art to which the present invention pertains. It should be understood that various substitutions, modifications, and alterations in scope may be made. Further, such substitutions, modifications and alterations are intended to fall within the scope of the appended claims.

400: radar jamming system, 410: spurious signal removal filtering unit, 420: mid-band frequency converter, 421: frequency up-converter, 422: mixer, 430: first amplifier, 440: intermediate frequency filter bank, 450: high frequency Storage unit 451: second amplification unit, 452: envelope detection unit, 453: signal storage unit, 510: first selector, 520: wide-pass filter, 530: middle-pass filter, 540: second selector, 550: Narrow-pass filter, 560: narrow-band suppression filter, 570: filter selection control

Claims (20)

A radar jamming system comprising:
an spurious signal removal filtering unit for receiving a radar signal and removing the spurious signal from the radar signal;
an intermediate frequency band conversion unit connected to the spurious signal removal filtering unit and performing intermediate frequency conversion for converting a frequency to an intermediate frequency band on the radar signal from which the spurious signal has been removed;
a first amplifier connected to the intermediate frequency band converter and amplifying the radar signal frequency-converted to the intermediate frequency band;
an intermediate frequency filter bank for performing at least one filtering process among a wideband filtering process, a middle band filtering process, and a narrowband filtering process on the frequency-converted radar signal; and
and a high-frequency storage unit for storing the filtered radar signal,
The intermediate frequency band converter
a frequency up-converter for generating an intermediate frequency converted signal for converting the radar signal into a signal having an intermediate frequency; and
A mixer for generating a radar signal having the intermediate frequency by synthesizing the spurious signal-filtered radar signal and the intermediate frequency converted signal
A radar jamming system comprising a. delete The radar jamming system of claim 1, wherein the frequency up-converter includes a local oscillator. The radar jamming system of claim 1, wherein the frequency up-converting unit generates the intermediate frequency-converted signal based on a jamming target and time control. The method of claim 1, wherein the intermediate frequency filter bank is
a wideband pass filter for passing a wideband signal with respect to the frequency-converted radar signal;
a middle-pass filter for passing a middle-band signal to the frequency-converted radar signal;
a first selector for selecting at least one of the broadband pass filter and the middle pass filter;
a narrowband pass filter for passing a narrowband signal with respect to the frequency-converted radar signal;
a narrowband suppression filter for suppressing a narrowband signal with respect to the frequency-converted radar signal; and
A second selection unit for selecting at least one of the narrowband pass filter and the narrowband suppression filter
A radar jamming system comprising a. 6. The method of claim 5, wherein the intermediate frequency filter bank is
A filter selection control unit for controlling the first selection unit and the second selection unit using threat radar frequency information
Radar jamming system further comprising. The high-frequency storage unit according to claim 1, wherein
an envelope detector configured to detect an envelope on the filtered radar signal; and
Signal storage unit for storing the filtered radar signal based on the envelope detection
A radar jamming system comprising a. The method of claim 7, wherein the envelope detection unit
detecting the presence or absence of a signal by performing envelope detection on the filtered radar signal;
A radar jamming system that determines a reference strength for storing the filtered radar signal based on the detected presence or absence. The radar jamming system of claim 8 , wherein the signal storage unit stores the filtered radar signal based on the reference intensity. 8. The high-frequency storage unit according to claim 7, wherein
A second amplifying unit disposed between the intermediate frequency filter bank and the envelope detector and amplifying the radar signal filtered by the intermediate frequency filter bank
Radar jamming system further comprising. A radar jamming method in a radar jamming system, comprising:
removing the spurious signal from the received radar signal by the spurious signal removal filtering unit of the radar jamming system;
performing, in an intermediate frequency band converter of the radar jamming system, an intermediate frequency conversion for frequency conversion to an intermediate frequency band on the radar signal from which the unnecessary signal has been removed;
amplifying, by the first amplifying unit of the radar jamming system, the radar signal frequency-converted to the intermediate frequency band;
performing, in the intermediate frequency filter bank of the radar jamming system, at least one filtering process among a wideband filtering process, a middle band filtering process, and a narrowband filtering process on the frequency-converted radar signal; and
Storing the filtered radar signal in the high-frequency storage unit of the radar jamming system,
The step of performing an intermediate frequency conversion for converting a frequency to an intermediate frequency band on the radar signal from which the unnecessary signal has been removed,
generating an intermediate frequency converted signal for converting the radar signal into a signal having an intermediate frequency; and
generating a radar signal having the intermediate frequency by synthesizing the spurious signal-filtered radar signal and the intermediate frequency converted signal
A radar jamming method comprising a. delete The method of claim 11, wherein the generating of the intermediate frequency converted signal comprises:
generating the intermediate frequency converted signal based on a jamming target and time control;
A radar jamming method comprising a. The method of claim 11, wherein performing at least one of a wideband filtering process, a midband filtering process, and a narrowband filtering process on the frequency-converted radar signal comprises:
selecting at least one first filter from among a wideband filter for passing a wideband signal with respect to the frequency-converted radar signal and a middle-pass filter for passing a middleband signal with respect to the frequency-converted radar signal;
performing at least one filtering process among the wideband filtering process and the middle band filtering process on the radar signal frequency-converted through the selected at least one first filter;
selecting at least one second filter from among a narrow-band filter for passing a narrow-band signal with respect to the frequency-converted radar signal or a narrow-band suppression filter for suppressing a narrow-band signal with respect to the frequency-converted radar signal; and
performing a narrowband pass filtering process or a narrowband suppression filtering process on the frequency-converted radar signal through the selected at least one second filter
A radar jamming method comprising a. 15. The method of claim 14, wherein selecting the at least one first filter comprises:
selecting at least one first filter from among the wideband pass filter and the middle pass filter using threat radar frequency information
A radar jamming method comprising a. 15. The method of claim 14, wherein selecting the at least one second filter comprises:
selecting at least one of the narrowband pass filter and the narrowband suppression filter using the threat radar frequency information
A radar jamming method comprising a. The method of claim 11, wherein the storing of the filtered radar signal comprises:
performing envelope detection on the filtered radar signal; and
Storing the filtered radar signal based on the envelope detection
A radar jamming method comprising a. 18. The method of claim 17, wherein performing envelope detection on the filtered radar signal comprises:
detecting the presence or absence of a signal by performing envelope detection on the filtered radar signal; and
determining a reference intensity for storing the filtered radar signal based on the detected presence or absence
A radar jamming method comprising a. The method of claim 18, wherein the storing of the filtered radar signal based on the envelope detection comprises:
Storing the filtered radar signal based on the reference intensity
A radar jamming method comprising a. The method of claim 17, wherein the storing of the filtered radar signal comprises:
amplifying the filtered radar signal
Radar jamming method further comprising.

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