KR20200137905A - Apparatus and method for generating jamming signal - Google Patents

Abstract

According to an embodiment of the present invention, a jamming signal generation method comprises the steps of: receiving a communication signal; generating a jamming signal upon receiving the communication signal and allocating a power amount to the jamming signal; radiating the jamming signal to which the power amount has been allocated; removing an amount of self-interference generated by the radiated jamming signal; calculating a power amount of the communication signal based on a cancellation amount of residual self-interference according to the cancellation of the amount of self-interference; and adjusting a power amount of a jamming signal radiated after the radiated jamming signal based on the calculated power amount of the communication signal. Accordingly, the reception performance of a jamming signal generation device may be improved.

Description

Apparatus and method for generating jamming signals {APPARATUS AND METHOD FOR GENERATING JAMMING SIGNAL}

The present invention relates to a jamming signal generating apparatus and a jamming signal generating method.

Wireless channels have been threatened with security and interference from unauthorized users and malicious attacks for a long time due to their physical propagation characteristics, and to solve this problem, the transmission contents are mainly encrypted to prevent eavesdropping by malicious terminals or through authentication. A method of blocking network access of users has been proposed.

However, even if the contents of messages transmitted between end users and network access sections or between end users are encrypted, cryptography-based methods that rely only on complexity are increasingly exposed to threats by increasingly developing computing technologies.

Accordingly, in recent years, an artificial noise jamming technique that artificially increases the uncertainty of the channel itself has been used in the transmitting or receiving node to improve the security performance.

However, when artificial noise is used in the transmitting device, there is a limitation that synchronization with the receiving device and exchanging advance information for noise cancellation must be performed secretly, and self-interference when transmitting artificial noise in the receiving device Since a problem occurs, there may be a problem that the reception performance of the receiving device is deteriorated.

Therefore, in order to solve this problem, a secure beamforming technique was proposed in the transmitting device and the self-interference cancellation technique used in the full-duplex technique was used in the receiving device. There is a need to develop a security communication technology that can completely eliminate the problem.

Korean Registered Patent Publication, 10-1403020 (registered on May 27, 2014)

The problem to be solved of the present invention is to propose a jamming signal generating apparatus and a jamming signal generating method.

In addition, by generating an optimal jamming signal through such a device and method, the optimal jamming signal is emitted, and the amount of self-interference caused by the radiated jamming signal is eliminated while the optimal jamming signal is emitted. Preventing an attack in advance may be included in the problem to be solved of the present invention.

However, the problem to be solved of the present invention is not limited to the ones mentioned above, and another problem to be solved that is not mentioned can be clearly understood by those of ordinary skill in the art from the following description. will be.

A method for generating a jamming signal according to an embodiment, the method comprising: receiving a communication signal; Generating a jamming signal upon receiving the communication signal and allocating a power amount to the jamming signal; Emitting a jamming signal to which the power amount is allocated; Removing an amount of magnetic interference generated by the radiated jamming signal; Calculating an amount of power of the communication signal based on an amount of residual self-interference removal according to the amount of self-interference removal; And adjusting the power amount of the jamming signal radiated after the radiated jamming signal based on the calculated power amount of the communication signal.

In addition, the step of removing the amount of self-interference may include generating a jamming signal having a phase opposite to that of the radiated jamming signal, and superimposing the received signal and the jamming signal having the opposite phase after performing the step of radiating the jamming signal. The amount of magnetic interference can be eliminated.

In addition, the received signal may be a signal obtained by adding the communication signal and the radiated jamming signal.

In addition, the calculating of the power amount of the communication signal may be performed based on the residual removal amount of self-interference and the amount of power of the communication signal.

In the jamming signal generating apparatus according to an embodiment, the signal receiving unit for receiving a communication signal; A jamming signal generator generating a jamming signal when receiving the communication signal and emitting the generated jamming signal; A self-interference removing unit that removes an amount of self-interference generated by the radiated jamming signal; And a jamming signal power control unit for allocating a power amount to the radiated jamming signal, wherein the jamming signal power control unit comprises: after removing the self-interference amount by the self-interference removing unit, the communication signal is Control the amount of power.

In addition, the signal receiver may receive a signal obtained by adding the communication signal and the radiated jamming signal.

In addition, the self-interference removing unit may be configured to generate a jamming signal for an opposite phase of the radiated jamming signal, and to remove an amount of self-interference by overlapping a signal received from the signal receiving unit and a jamming signal for the opposite phase. have.

In addition, the jamming signal power control unit may control an amount of power of the communication signal based on the amount of residual self-interference removal and the amount of power of the communication signal.

A jamming signal generation system according to an embodiment, comprising: a transmission device for transmitting a communication signal; And a jamming signal generating device receiving the communication signal from the transmitting device, wherein the jamming signal generating device comprises: a signal receiving unit receiving the communication signal; A jamming signal generator generating a jamming signal when receiving the communication signal and emitting the generated jamming signal; A self-interference removing unit that removes an amount of self-interference generated by the radiated jamming signal; And a jamming signal power control unit for allocating a power amount of the radiated jamming signal. Including, the jamming signal power control unit is configured to receive a feedback of the residual self-interference removal amount after removing the self-interference amount from the self-interference removing unit, and calculate the power amount of the communication signal based on the self-interference removal amount. have.

In addition, the transmission device may include a case of transmitting only the communication signal to the jamming signal generating device.

In addition, the transmission device may include a case of transmitting the communication signal and the jamming signal to the jamming signal generating device at the same time.

In the computer-readable recording medium according to an embodiment, as a computer-readable recording medium storing a computer program, the computer program, when executed by a processor, receiving a communication signal and receiving the communication signal Generating a jamming signal, allocating a power amount to the jamming signal, radiating a jamming signal allocated with the power amount, removing an amount of self-interference generated by the radiated jamming signal, and determining the amount of self-interference After removing the amount of self-interference from the removing step, receiving feedback on the amount of remaining self-interference, and calculating the amount of power of the communication signal based on the amount of self-interference Include.

In the computer program according to an embodiment, a computer program stored in a computer-readable recording medium, wherein the computer program, when executed by a processor, receives a communication signal and a jamming signal when the communication signal is received. Generating, allocating a power amount to the jamming signal, radiating a jamming signal to which the power amount is allocated, removing an amount of self-interference generated by the radiated jamming signal, and removing the amount of self-interference After removing the amount of self-interference from, receiving feedback from the amount of remaining self-interference, and calculating the amount of power of the communication signal based on the amount of self-interference removed, and instructions for causing the processor to perform a method.

According to an embodiment, the jamming signal generating apparatus removes the amount of self-interference generated by the jamming signal, and dynamically adjusts the amount of power of the radiated jamming signal by receiving feedback on the amount of residual self-interference according to the self-interference removal from the jamming signal power control unit. This can improve the reception performance of the jamming signal generating device.

In addition, by transmitting a jamming signal and a signal for removing self-interference (a jamming signal having a phase opposite to that of the radiated jamming signal) to the channel used for data transmission, potential eavesdroppers around the area in transmitting and receiving communication signals Security can be improved by preventing eavesdropping attempts by people.

1 is a block diagram of an apparatus for generating a jamming signal according to an exemplary embodiment.
2 is a block diagram of a system for generating a jamming signal according to an embodiment.
3 is a block diagram of a system for generating a jamming signal according to another embodiment.
4 is an exemplary flowchart for a procedure of a method for generating a jamming signal according to an embodiment.
5 is a graph showing an optimal power distribution plan according to an embodiment of the present invention.

Advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in a variety of different forms, and only these embodiments make the disclosure of the present invention complete, and are common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to those who have, and the invention is only defined by the scope of the claims.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout this specification.

1 is a block diagram of an apparatus for generating a jamming signal according to an exemplary embodiment.

Referring to FIG. 1, the jamming signal generating apparatus 100 includes a signal receiving unit 110, a jamming signal generating unit 120, a self-interference canceling unit 130, and a jamming signal power control unit 140. In addition, the jamming signal generating apparatus 100 may include a receiving antenna (not shown) for receiving a received signal.

In this case, according to an embodiment, the jamming signal generating apparatus 100 may not include at least one of the configurations illustrated in FIG. 1 and/or may additionally include a configuration not illustrated in FIG. 1. In addition, each of the components included in the jamming signal generating apparatus 100 may be implemented in the form of a software module or a hardware module, or a combination of a software module and a hardware module.

First, the signal reception unit 110 is a component that receives a communication signal. Here, the communication signal is a signal for data transmission and may be a signal related to a security signal or the like.

When receiving a communication signal, the jamming signal generator 120 generates a jamming signal and emits a jamming signal. In addition, when the jamming signal generator 120 radiates a jamming signal, the signal receiver 110 may receive a communication signal and the radiated jamming signal.

In more detail, the jamming signal may generate a jamming sequence as shown in Equation 1 below.

Here, θ represents a Data Sub Carrier (DSC) index used for data transmission, and redundant indexes during an interleaving process to transmit one data set are represented as Psets.

Therefore, if the DSC (Data Sub Carrier) of the corresponding set (Pset) is attacked, interleaving is invalidated and a jamming signal can be emitted to be vulnerable to self-interference.

On the other hand, as another example, if the transmitting device uses Direct Sequence Spread Spectrum (DSSS), the receiving device can spread the same spreading code to the jamming symbol and transmit it, and FHSS (Frequency Hopping Spread Spectrum, frequency hopping modulation) Even in the case of, the jamming signal can be transmitted by synchronizing when transmitting the jamming symbol of the receiving device based on the frequency hopping sequence information.

The self-interference removing unit 130 removes a self-interference generated by the radiated jamming signal. In more detail, the self-interference removing unit 130 may remove self-interference based on a full-duplex technique.

For example, the self-interference removing unit 130 generates a jamming signal for the opposite phase of the jamming signal radiated from the jamming signal generator 120, and jamming the signal received from the signal receiving unit 110 and the opposite phase. The amount of self-interference can be eliminated by overlapping signals. In this case, the signal received by the signal receiving unit 110 is a signal obtained by adding a communication signal and a radiated jamming signal.

In another embodiment in which the self-interference cancellation unit 130 removes self-interference, a part of the jamming signal transmitted by the jamming signal generation unit 120 is made into an opposite phase and overlapped with the signal received by the signal receiving unit 110 You can also remove it. For example, as an embodiment, a transformer may be used to generate a signal obtained by converting a part of a jamming signal into an opposite phase.

The jamming signal power control unit 140 allocates a power amount for the jamming signal when the jamming signal generator 120 initially emits the jamming signal. In this case, when the jamming signal is initially radiated, the jamming signal generating apparatus 100 receives a communication signal and emits the jamming signal for the first time. For example, the initially set jamming signal power amount may be within a power amount range similar to that of a transmitting device that transmits a communication signal.

Furthermore, the jamming signal power control unit 140 removes the amount of self-interference in the self-interference canceling unit 130, and then controls the amount of power of the communication signal based on the amount of residual self-interference that is generated.

In more detail, the jamming signal power control unit 140 calculates the amount of power of the communication signal by calculating the amount of interference remaining and the amount of power of the received signal after removing the amount of self-interference, and optimal jamming based on the calculated amount of power of the communication signal. The amount of signal transmission power can be determined.

That is, the jamming signal power control unit 140 may receive feedback of residual self-interference from the self-interference canceling unit 130 and dynamically adjust the power of the jamming signal to be radiated after the initial jamming signal radiated.

In addition, the jamming signal power control unit 140 may adjust the power of the jamming signal to minimize the reception performance of the jamming signal generating apparatus 100 and maximize the amount of interference of the jamming signal of an external node. Specifically, the jamming signal power control unit 140 may adjust the power of the radiated jamming signal so that the amount of self-interference approaches zero. At this time, the reason that the jamming signal power control unit 140 adjusts the self-interference amount close to zero is that an optimal jamming signal power amount can be derived as the self-interference amount approaches zero.

A detailed description of the control of the power amount of the communication signal based on the residual self-interference cancellation amount by the jamming signal power control unit 140 will be described later in detail with reference to FIG. 5.

In addition, the configuration included in the jamming signal generating device 100 is not in a fixed position as illustrated in FIG. 1, but it is possible to change the position of the configuration included in the jamming signal generating device according to whether or not it is applied.

2 to 3 are configuration diagrams of a system for generating a jamming signal according to an embodiment.

2 to 3, the jamming signal generating system 300 includes a transmitting device 200 and a jamming signal generating device 100. Here, since the jamming signal generating apparatus 100 is the same as the jamming signal generating apparatus of FIG. 1, a detailed description of the jamming signal generating apparatus 100 will be omitted.

The transmission device 200 transmits a communication signal to the jamming signal generating device 100. In addition, the jamming signal generating system 300 is to synchronize the signals of the transmitting device 200 and the jamming signal generating device 100 first before transmitting the communication signal from the transmitting device 200 to the jamming signal generating device 100. I can.

Referring to FIG. 3, the transmission device 200 may include a transmission jamming signal generation unit 210 and a signal transmission unit 220. In addition, a single or multiple antennas (not shown) may be connected to the transmission jamming signal generator 210 and the signal transmitter 220.

For example, as an embodiment, when an antenna (not shown) connected to the transmission jamming signal generator is a single, a jamming signal capable of canceling a preset appointment with the jamming signal generator 100 may be generated, and the transmitter 220 When the number of antennas (not shown) connected to is multiple, the jamming signal generating apparatus 100 may be configured not to be affected through a predetermined jamming signal or beamforming.

The transmission jamming signal generation unit 210 of the transmission device 200 illustrated in FIG. 3 may radiate a jamming signal to the wireless channel 150, and the signal transmission unit 220 may transmit a communication signal.

4 is an exemplary flowchart for a procedure of a method for generating a jamming signal according to an embodiment. The jamming signal generating method shown in FIG. 4 can be performed by the jamming signal generating apparatus shown in FIG. 1. In addition, the method of generating a jamming signal illustrated in FIG. 4 is only exemplary.

Referring to FIG. 4, the jamming signal generating apparatus 100 receives a communication signal (S10). Specifically, the communication signal transmitted by the transmitting device 200 is received by the jamming signal generating device 100.

Depending on the embodiment, before the step of receiving the communication signal from the jamming signal generating device 100, a step of synchronizing signals of the transmitting device 200 and the jamming signal generating device 100 may be performed.

When the jamming signal generating device 100 receives a communication signal, the jamming signal generating unit 120 generates a jamming signal, and the jamming signal power generated by the jamming signal power control unit 140 through the jamming signal generating unit 120 The amount is allocated (S20).

At this time, the jamming signal generation unit 120 emits a jamming signal that has been assigned a power amount from the jamming signal power control unit 140 (S30). When the jamming signal generator 120 receives a communication signal from the jamming signal generator 100, the jamming signal generator 120 may radiate a jamming signal to the wireless channel 150.

When the jamming signal is radiated from the jamming signal generator 120, an amount of self-interference is generated by the radiated jamming signal, and the amount of self-interference may be removed by the self-interference removing unit 130 (S40). In more detail, the self-interference removing unit 130 generates a jamming signal having a phase opposite to that of the jamming signal radiated from the jamming signal generation unit 120, radiates the jamming signal, and receives a signal received from the jamming signal generating device 100 The amount of self-interference can be eliminated by superimposing a (communication signal + radiated jamming signal) and a jamming signal having an opposite phase.

After the self-interference is removed by the self-interference removing unit 130, the jamming signal power control unit 140 may calculate the amount of power of the communication signal based on the amount of residual self-interference removed by the self-interference canceling unit 130. (S50). Here, the residual magnetic interference removal amount is residual magnetic interference generated after the magnetic interference removal unit 130 removes the magnetic interference amount. In more detail, the jamming signal power control unit 140 may calculate the power amount of the communication signal based on the residual self-interference removal amount and the power amount of the communication signal.

The jamming signal power control unit 140 calculates the amount of power of the communication signal, and then the jamming signal emitted from the jamming signal generator 120 based on the calculated power amount of the communication signal, that is, a jamming signal radiated after step S30. The amount of power of can be adjusted (S60).

Meanwhile, the amount of power of a signal received from the jamming signal generating apparatus 100 may be expressed as Equation 2 below.

Here, the power amount of the jamming signal is expressed as P _JB , and the value of β needs to be adjusted.

Therefore, if the amount of power P _JB of the jamming signal multiplied by the β value is sufficiently reduced, the effect of self-interference caused by the jamming signal can be reduced, but Equation 3 below is as shown in Equation 3, which expresses the reception capability SINR of the eavesdropper. Since it also affects the parameters that prevent the eavesdropping effect of eavesdroppers, it cannot be reduced unconditionally.

Therefore, as a method of reducing the amount of power of the jamming signal as described above, since the parameter for preventing the eavesdropping effect of the eavesdropper can also be affected, the amount of self-interference generated by the jamming signal is removed, and the amount of self-interference is removed. A method of dynamically adjusting the power amount of the radiated jamming signal by receiving feedback on the residual self-interference cancellation amount has been devised.

5 is a graph showing an optimal power distribution plan according to an embodiment of the present invention.

Referring to FIG. 5, the horizontal axis of the graph represents the ratio to the residual removal amount of self-interference, and the vertical axis of the graph represents the total power, that is, the power amount of the communication signal. Looking specifically at the graph, as the ratio to the residual removal amount of self-interference, which is the horizontal axis, increases, the power amount of the communication signal, which is the vertical axis, decreases.

Accordingly, the jamming signal power control unit 140 receives the residual removal amount of self-interference according to the removal of the self-interference amount from the self-interference removal unit 130 by using the relationship between the residual self-interference removal amount and the power amount of the communication signal. Based on the calculation of the power amount of the communication signal, based on the calculated power amount of the communication signal, it is possible to dynamically adjust the power amount of the jamming signal to be radiated.

As described above, according to an embodiment, according to an embodiment, the jamming signal generating apparatus removes the amount of self-interference generated by the jamming signal, and receives the residual amount of self-interference according to the self-interference removal from the jamming signal power control unit, The amount of power can be dynamically adjusted, and this can improve the reception performance of the jamming signal generator.

In addition, by transmitting a jamming signal and a signal for removing self-interference (a jamming signal having a phase opposite to that of the radiated jamming signal) to the channel used for data transmission, potential eavesdroppers around the area in transmitting and receiving communication signals Security can be improved by preventing eavesdropping attempts by people.

On the other hand, the method according to this embodiment can be implemented in the form of a computer program stored in a computer-readable recording medium programmed to perform each step of the method, and also includes a computer program programmed to perform each step of the method. It can be implemented in the form of a computer-readable recording medium to store.

The above description is merely illustrative of the technical idea of the present invention, and those of ordinary skill in the art to which the present invention pertains will be able to make various modifications and variations without departing from the essential quality of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain the technical idea, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: jamming signal generator
110: signal receiver
120: jamming signal generator
130: magnetic interference cancellation unit
140: jamming signal power control unit
200: transmitting device
300: jamming signal generation system

Claims (13)

Receiving a communication signal;
Generating a jamming signal upon receiving the communication signal and allocating a power amount to the jamming signal;
Emitting a jamming signal to which the power amount is allocated;
Removing an amount of magnetic interference generated by the radiated jamming signal;
Calculating an amount of power of the communication signal based on an amount of residual self-interference removal according to the amount of self-interference removal; And
And adjusting the power amount of the jamming signal radiated after the radiated jamming signal based on the calculated power amount of the communication signal.
How to generate jamming signals. The method of claim 1,
The step of removing the amount of magnetic interference,
Generating a jamming signal having a phase opposite to that of the radiated jamming signal, and removing the amount of self-interference by overlapping the received signal and the jamming signal having the opposite phase after performing the step of radiating the jamming signal,
How to generate jamming signals. The method of claim 2,
The received signal is,
A signal obtained by adding the communication signal and the radiated jamming signal,
How to generate jamming signals. The method of claim 1,
The step of calculating the power amount of the communication signal,
Performed based on the residual removal amount of self-interference and the amount of power of the communication signal,
How to generate jamming signals. A signal receiver for receiving a communication signal;
A jamming signal generator generating a jamming signal when receiving the communication signal and emitting the generated jamming signal;
A self-interference removing unit that removes an amount of self-interference generated by the radiated jamming signal; And
And a jamming signal power control unit for allocating a power amount to the radiated jamming signal,
The jamming signal power control unit,
After removing the amount of self-interference in the self-interference removing unit, controlling the amount of power of the communication signal based on the remaining self-interference,
Jamming signal generator. The method of claim 5,
The signal receiving unit receives a signal obtained by adding the communication signal and the radiated jamming signal,
Jamming signal generator. The method of claim 5,
The magnetic interference removing unit,
It is configured to generate a jamming signal for an opposite phase of the radiated jamming signal, and to remove an amount of self-interference by overlapping a signal received from the signal receiving unit and a jamming signal for the opposite phase
Jamming signal generator. The method of claim 5,
In the jamming signal power control unit, in controlling the amount of power of the communication signal based on the amount of residual self-interference cancellation and the amount of power of the communication signal,
Jamming signal generator. A transmission device for transmitting a communication signal; And
Includes; a jamming signal generating device for receiving the communication signal from the transmitting device,
The jamming signal generating device,
A signal receiver for receiving the communication signal;
A jamming signal generator generating a jamming signal when receiving the communication signal and emitting the generated jamming signal;
A self-interference removing unit that removes an amount of self-interference generated by the radiated jamming signal; And
A jamming signal power control unit for allocating a power amount of the radiated jamming signal; Including,
The jamming signal power control unit is configured to receive a feedback on a residual amount of self-interference after removing the amount of self-interference from the self-interference removing unit, and calculate the amount of power of the communication signal based on the amount of self-interference,
Jamming signal generation system. The method of claim 9,
Including a case in which the transmitting device transmits only the communication signal to the jamming signal generating device,
Jamming signal generation system. The method of claim 9,
The transmission device includes a case of transmitting the communication signal and the jamming signal to the jamming signal generating device at the same time,
Jamming signal generation system. As a computer-readable recording medium storing a computer program,
The computer program, when executed by a processor,
Receiving a communication signal,
Generating a jamming signal when receiving the communication signal, and allocating a power amount to the jamming signal; and
Radiating a jamming signal to which the amount of power has been allocated,
Removing an amount of self-interference generated by the radiated jamming signal,
After removing the amount of self-interference from the step of removing the amount of self-interference, receiving feedback on the amount of remaining self-interference, and calculating the amount of power of the communication signal based on the amount of self-interference Containing an instruction to do,
Computer-readable recording medium. As a computer program stored in a computer-readable recording medium,
The computer program, when executed by a processor,
Receiving a communication signal,
Generating a jamming signal when receiving the communication signal, and allocating a power amount to the jamming signal; and
Radiating a jamming signal to which the amount of power has been allocated,
Removing an amount of self-interference generated by the radiated jamming signal,
After removing the amount of self-interference from the step of removing the amount of self-interference, receiving feedback on the amount of remaining self-interference, and calculating the amount of power of the communication signal based on the amount of self-interference Containing an instruction to do,
Computer program.

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