JP2013197631A - Communication jamming device and communication jamming method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently jam communication.SOLUTION: A communication jamming device 110 jams radio communication about which an additional period when a redundant signal is transmitted is set periodically and which is received in synchronization on the basis of the redundant signal. A receiving unit 112 receives a radio signal 121 transmitted by radio communication. A detection unit 113 detects the additional period on the basis of the signal received by the receiving unit 112. An extraction unit 114 extracts a signal during the additional period detected by the detection unit 113 from the received signal. A transmission unit 115 wirelessly transmits the signal extracted by the extraction unit 114 after the detected additional period.

Description

  The present invention relates to a communication jamming apparatus and a communication jamming method.

  As an example of the conventional communication interference, there is a power interference that outputs an interference radio wave uniformly distributed in a band that may be used in the wireless communication to be interfered to cause the communication interference in the band. As one of digital modulations in wireless communication, OFDM (Orthogonal Frequency Division Multiplexing) in which data is carried on a plurality of carrier waves (subcarriers) orthogonal to each other is known. In OFDM, a technique of performing symbol synchronization using a guard interval is known (for example, see Patent Document 1 below).

JP-A-7-99486

  However, the above-described conventional communication interference technique has a problem that communication cannot be efficiently interrupted. For example, in power jamming, since a jamming wave is generated in a wide band including a band that may be used in radio communication to be jammed, power consumption increases.

  An object of the present invention is to provide a communication jamming apparatus and a communication jamming method capable of efficiently jamming communication in order to solve the above-described problems caused by the prior art.

  In order to solve the above-described problems and achieve the object, according to one aspect of the present invention, an additional period in which a redundant signal is transmitted is periodically set, and reception is performed while synchronizing on the receiving side based on the redundant signal. In the case of interfering with the wireless communication performed, the wireless signal transmitted by the wireless communication is received, the additional period is detected based on the received signal, and the detected additional period is detected from the received signals A communication jamming apparatus and a communication jamming method are proposed in which the above signal is extracted, and the extracted signal is wirelessly transmitted after the detected additional period.

  Further, according to another aspect of the present invention, when the additional period during which the redundant signal is transmitted is periodically set and the reception side interferes with wireless communication that is received while being synchronized based on the redundant signal. , Receiving a radio signal transmitted by the wireless communication, detecting the additional period based on the received signal, extracting the signal of the period immediately before the detected additional period from the received signal, A communication jamming apparatus and a communication jamming method for wirelessly transmitting an extracted signal after the detected additional period is proposed.

  According to one aspect of the present invention, there is an effect that communication can be efficiently interrupted.

FIG. 1 is a diagram illustrating an example of a communication jamming device according to an embodiment. FIG. 2-1 is a diagram illustrating an example of communication interruption by the communication disturbance device. FIG. 2-2 is a diagram illustrating another example of communication interruption by the communication disturbance device. FIG. 3 is a diagram illustrating an example of the configuration of the communication jamming apparatus. FIG. 4 is a diagram illustrating an example of the configuration of the digital processing unit. FIG. 5 is a diagram illustrating an example of the configuration of the IQ detection unit. FIG. 6 is a diagram illustrating an example of the configuration of the IQ combining unit. FIG. 7 is a diagram illustrating an example of a signal to be disturbed. FIG. 8 is a diagram illustrating an example of the peak value of the correlation value. FIG. 9 is a diagram illustrating an example of the synchronization detection operation. FIG. 10 is a diagram illustrating an example of a transmission operation. FIG. 11 is a diagram illustrating an example of timing control by the timing generation unit. FIG. 12 is a flowchart illustrating an example of reception processing. FIG. 13 is a flowchart illustrating a modification of the reception process. FIG. 14 is a flowchart illustrating an example of the transmission process. FIG. 15 is a diagram (part 1) illustrating a first example of communication interference. FIG. 16 is a second diagram illustrating a first example of communication interruption. FIG. 17 is a diagram (part 1) illustrating a second example of communication interference. FIG. 18 is a second diagram illustrating a second example of communication interruption. FIG. 19 is a first diagram illustrating a third example of communication interruption. FIG. 20 is a second diagram illustrating a third example of communication interference.

  Embodiments of a communication jamming apparatus and a communication jamming method according to the present invention will be described below in detail with reference to the accompanying drawings.

(Embodiment)
FIG. 1 is a diagram illustrating an example of a communication jamming device according to an embodiment. As shown in FIG. 1, the communication system 100 includes a wireless communication device 101, a wireless communication device 102, and a communication jamming device 110. The wireless communication device 101 and the wireless communication device 102 perform wireless communication with each other. For example, the wireless communication device 101 transmits a wireless signal 121 to the wireless communication device 102. The radio signal 121 is, for example, an OFDM (Orthogonal Frequency Division Multiplex) radio signal.

  Specifically, the wireless communication device 101 on the transmission side divides the data to be transmitted into a plurality of subcarriers orthogonal to each other and transmits the data. Thereby, interference between subcarriers can be eliminated, the frequency interval between subcarriers can be narrowed, and radio frequency utilization efficiency can be increased. The radio communication device 102 on the receiving side demodulates data by separating each subcarrier using orthogonality between subcarriers using, for example, discrete Fourier transform.

  In addition, in the wireless communication from the wireless communication device 101 to the wireless communication device 102, the additional period is set periodically. The additional period is a guard interval set between symbols in order to suppress intersymbol interference in OFDM, for example. Hereinafter, a case where the additional period is a guard interval will be described. In the guard interval, the wireless communication device 101 transmits a redundant signal. The wireless communication device 102 receives the symbol period of the wireless signal 121 while synchronizing based on the redundant signal transmitted in the guard interval.

  The communication jamming device 110 blocks radio communication from the radio communication device 101 to the radio communication device 102, for example. Specifically, the communication jamming device 110 includes a reception antenna 111, a reception unit 112, a detection unit 113, an extraction unit 114, a transmission unit 115, and a transmission antenna 116. The receiving unit 112 receives a wireless signal 121 transmitted from the wireless communication device 101 by wireless communication from the wireless communication device 101 to the wireless communication device 102 via the reception antenna 111. The reception unit 112 outputs the received signal to the detection unit 113 and the extraction unit 114.

  The detection unit 113 detects the guard interval set in the radio signal 121 based on the signal output from the reception unit 112. For example, the length of the guard interval is known, and the detection unit 113 detects the start timing of the guard interval. The detection unit 113 notifies the extraction unit 114 of the detected guard interval.

  For example, the redundant signal included in the wireless signal 121 is a signal obtained by duplicating the wireless signal 121 in the transmission period immediately after the guard interval in which the redundant signal is transmitted in each transmission period different from the guard interval. In this case, the detection unit 113 can detect a guard interval based on a comparison result of signals at different points in time that are different from the signal output from the reception unit 112 by the length of the transmission period. However, the detection method of the guard interval by the detection unit 113 is not limited to this. For example, the detection unit 113 may detect the guard interval by detecting a change in the phase of the signal output from the reception unit 112.

  The extraction unit 114 extracts the guard interval signal notified from the detection unit 113 from the signal output from the reception unit 112. For example, the extraction unit 114 extracts all signals of the guard interval notified from the detection unit 113 from the signals output from the reception unit 112. Alternatively, the extraction unit 114 may extract a part of the guard interval signal notified from the detection unit 113 from the signal output from the reception unit 112. Further, the signal extracted by the extraction unit 114 may include signals before and after the guard interval. As a result, a signal including at least a part of the redundant signal transmitted in the guard interval by the wireless communication device 101 can be extracted. Extraction unit 114 outputs the extracted signal to transmission unit 115.

  The transmission unit 115 wirelessly transmits the signal output from the extraction unit 114 as an interference wave 122 via the transmission antenna 116. In addition, the transmission unit 115 transmits the signal output from the extraction unit 114 after the guard interval detected by the detection unit 113. For example, the transmission unit 115 performs radio transmission after delaying the signal output from the extraction unit 114 for a predetermined time. Alternatively, the transmission unit 115 may acquire the end time of the guard interval from the detection unit 113 and wait until the acquired end time before wirelessly transmitting the signal.

  According to the communication jamming device 110 shown in FIG. 1, it is possible to intercept the redundant signal in the guard interval portion of the radio signal 121 to be intercepted, and perform radio transmission by delaying the intercepted redundant signal. This makes it difficult to synchronize with the redundant signal of the guard interval in the radio communication device 102 on the receiving side. For this reason, radio | wireless communication can be disturbed efficiently.

  Further, the transmission unit 115 may repeatedly transmit the signal output from the extraction unit 114 until the guard interval next to the guard interval notified from the detection unit 113. This makes it difficult to synchronize with the redundant signal of the guard interval in the radio communication device 102 on the receiving side.

  Further, the communication jamming device 110 may include a control unit that stops the reception of the radio signal by the reception unit 112 when the detection unit 113 does not detect the guard interval for a predetermined time or more. Thereby, when the transmission of the radio signal 121 to be disturbed is stopped, the reception of the radio signal by the receiving unit 112 can be automatically stopped. For this reason, for example, power consumption can be suppressed.

  Further, the communication jamming device 110 may include a control unit that alternately executes reception of a radio signal by the reception unit 112 and transmission of a signal by the transmission unit 115. Thereby, the detection unit 113 can detect the guard interval in a state where the redundant signal is not transmitted by the transmission unit 115. For this reason, it can be avoided that the redundant signal transmitted as an interference wave by the transmission unit 115 wraps around to the reception unit 112 and it becomes difficult for the detection unit 113 to detect the guard interval.

(Communication interference by communication interference device)
Next, an example of communication interference by the communication interference device 110 shown in FIG. 1 will be described.

  FIG. 2-1 is a diagram illustrating an example of communication interruption by the communication disturbance device. In FIG. 2A, the horizontal axis indicates time. The radio signal 210 is a radio signal to be interfered received by the reception unit 112, for example, the radio signal 121 illustrated in FIG. In the radio signal 210, symbol periods 211, 212, 213,... (Transmission period) in which data is transmitted and guard intervals 221, 222,... In which redundant signals are transmitted are alternately set.

  The detection periods 231, 232,... Are guard intervals detected by the detection unit 113. In the example shown in FIG. 2A, guard intervals 221, 222,... Of the radio signal 210 are detected by the detection unit 113 as the detection periods 231, 232,.

  Extracted signals 241, 242,... Are signals extracted by the extracting unit 114. In the example shown in FIG. 2A, by extracting each part of the detection periods 231, 232,... Of the radio signal 210, each of the guard intervals 221, 222,. The signal is being extracted.

  The transmission signals 251, 252,... Are signals transmitted by the transmission unit 115, for example, the interference wave 122 illustrated in FIG. In the example shown in FIG. 2A, each signal of the guard intervals 221, 222,... Extracted as the extracted signals 241, 242,.

  A reception signal 260 indicates a signal received by the wireless communication device 102 on the reception side. The reception signal 260 is a signal obtained by combining the radio signal 210 with the transmission signals 251, 252,. For this reason, in the received signal 260, each signal of the guard intervals 221, 222,. Therefore, in the wireless communication device 102, symbol synchronization based on the guard intervals 221, 222,... Can be made difficult. That is, it is difficult for the wireless communication device 102 to determine the symbol boundaries in the received signal 260, and thus it is difficult to receive each signal in the symbol periods 211, 212, 213,.

  FIG. 2-2 is a diagram illustrating another example of communication interruption by the communication disturbance device. 2-2, the same parts as those shown in FIG. 2-1 are denoted by the same reference numerals and description thereof is omitted. The extraction unit 114 may extract a signal immediately before the guard interval notified from the detection unit 113 from the signal output from the reception unit 112.

  In the example shown in FIG. 2B, the extracted signals 241, 242, 242,... Are the signals of the end periods 211a, 212a, 213a,. Therefore, the transmission signals 251, 252,... Are also signals in the end periods 211 a, 212 a,.

  For this reason, in the received signal 260, each signal of the tail periods 211a, 212a, 213a,... Is delayed and copied beyond the guard intervals 221, 222, and 223, respectively. For this reason, interference between symbol periods 211, 212, 213,... (Intersymbol interference) occurs, making it difficult to demodulate each signal during symbol periods 211, 212, 213,. For this reason, it becomes difficult for the wireless communication device 102 to receive each signal of the symbol periods 211, 212,.

  Further, the extraction unit 114 extracts, from the signals output from the reception unit 112, signals of the guard interval notified from the detection unit 113 and the period immediately before the guard interval notified from the detection unit 113. May be. As a result, in the received signal 260, each signal of the guard intervals 221, 222,... (See, for example, FIG. 2-1) and each signal of the tail periods 211a, 212a, 213a,. , Is duplicated. Therefore, symbol synchronization based on the guard intervals 221, 222,... Can be made difficult, intersymbol interference can be generated, and demodulation of each signal in the symbol periods 211, 212, 213,.

(Configuration of communication jamming device)
FIG. 3 is a diagram illustrating an example of the configuration of the communication jamming apparatus. A communication jamming device 300 shown in FIG. 3 is a configuration example of the communication jamming device 110 shown in FIG. As illustrated in FIG. 3A, the communication jamming device 300 includes a reception antenna 311, a reception-side switch 312, a local signal generator 313, a frequency converter 314, a bandpass filter 315, and an A / D converter. 316, a digital processing unit 320, a D / A converter 331, a local signal generator 332, a frequency converter 333, a transmission side switch 334, a transmission antenna 335, and a transmission / reception switching control unit 340. ing.

  The reception antenna 111 illustrated in FIG. 1 can be realized by the reception antenna 311, for example. The receiving unit 112 illustrated in FIG. 1 can be realized by, for example, the local signal generator 313, the frequency converter 314, the band pass filter 315, and the A / D converter 316. The detection unit 113 and the extraction unit 114 illustrated in FIG. 1 can be realized by the digital processing unit 320, for example. 1 can be realized by a D / A converter 331, a local signal generator 332, and a frequency converter 333, for example. The transmission antenna 116 illustrated in FIG. 1 can be realized by the transmission antenna 335, for example.

  The receiving antenna 311 receives an RF (Radio Frequency: high frequency) signal from the air, and outputs the received RF signal to the receiving side switch 312. The reception side switch 312 (SW) switches on / off of reception processing of the RF signal (communication wave) under the control of the transmission / reception switching control unit 340. Specifically, the reception-side switch 312 outputs an RF signal from the reception antenna 311 to the frequency converter 314 when turned on. The reception side switch 312 does not output the RF signal from the reception antenna 311 to the frequency converter 314 when it is off.

  The local signal generator 313 generates a local signal (local signal). The local signal generator 313 outputs the generated local signal to the frequency converter 314. The frequency converter 314 converts the RF signal output from the reception-side switch 312 to the frequency of the IF (Intermediate Frequency) band by mixing (mixing) with the local signal output from the local signal generator 313. To do. The frequency converter 314 outputs the IF signal converted into the IF band to the band pass filter 315. Note that the frequency of the local signal of the local signal generator 313 (that is, the IF band to be converted) can be set in advance by the user.

  A band pass filter 315 (BPF: Band Pass Filter) extracts and passes an IF signal in a band to be disturbed (a band to be disturbed) from the IF signals output from the frequency converter 314. As a result, it is possible to limit the band subject to communication interference. The IF signal that has passed through the bandpass filter 315 is output to the A / D converter 316. Note that the band extracted by the bandpass filter 315 can be set in advance by the user. Alternatively, the band pass filter 315 may be omitted.

  The A / D converter 316 (Analog / Digital) converts the IF signal output from the bandpass filter 315 from an analog signal to a digital signal. The A / D converter 316 outputs the signal converted into the digital signal to the digital processing unit 320.

  The digital processing unit 320 performs digital processing based on the signal output from the A / D converter 316 and generates interference wave data. The digital processing unit 320 outputs the IF signal of the generated interference wave data to the D / A converter 331. Further, the digital processing unit 320 outputs a transmission / reception switching instruction signal to the transmission / reception switching control unit 340. The digital processing unit 320 can be realized by an arithmetic means such as an FPGA (Field Programmable Gate Array). The configuration of the digital processing unit 320 will be described later (see, for example, FIG. 4).

  The D / A converter 331 (Digital / Analog) converts the IF signal output from the digital processing unit 320 from a digital signal to an analog signal. The D / A converter 331 outputs the IF signal converted into the analog signal to the frequency converter 333.

  The local signal generator 332 generates a local signal (local signal). The local signal generator 332 outputs the generated local signal to the frequency converter 333. The frequency converter 333 converts the IF signal output from the D / A converter 331 into the RF band (high frequency band) by mixing with the local signal output from the local signal generator 332. The frequency converter 333 outputs the RF signal converted into the RF band to the transmission side switch 334.

  The transmission side switch 334 (SW) switches on / off of transmission of the RF signal (interference wave) under the control of the transmission / reception switching control unit 340. Specifically, the transmission side switch 334 outputs the RF signal from the frequency converter 333 to the transmission antenna 335 when it is on. Further, the transmission side switch 334 does not output the RF signal from the frequency converter 333 to the transmission antenna 335 when it is off. The transmission antenna 335 transmits the RF signal output from the transmission side switch 334 to the air as an interference wave.

  The transmission / reception switching control unit 340 is a control unit that alternately executes reception of communication waves and transmission of interference waves. Specifically, the transmission / reception switching control unit 340 turns on the reception-side switch 312 and turns off the transmission-side switch 334, thereby causing communication waves to be received. In addition, the transmission / reception switching control unit 340 causes the reception side switch 312 to be turned off and the transmission side switch 334 to be turned on, thereby causing transmission of the interference wave.

  For example, the transmission / reception switching control unit 340 periodically switches between communication wave reception and interference wave transmission based on the transmission / reception switching instruction signal output from the digital processing unit 320. The transmission / reception switching control unit 340 can be realized by arithmetic means such as an FPGA. Further, the transmission / reception switching control unit 340 may be incorporated in the digital processing unit 320.

(Example of the configuration of the digital processing unit)
FIG. 4 is a diagram illustrating an example of the configuration of the digital processing unit. As shown in FIG. 4, the digital processing unit 320 (see, for example, FIG. 3) includes a numerically controlled oscillation unit 401, an IQ detection unit 402, a timing generation unit 403, received wave memories 404 to 408, and a memory control unit 409. 410, a correlation detection unit 411, a symbol synchronization determination unit 412, an addition unit 413, 414, a numerically controlled oscillation unit 415, and an IQ synthesis unit 416.

  A numerically controlled oscillator 401 (NCO: Numerically Controlled Oscillator) oscillates a periodic signal and outputs the oscillated signal to the IQ detector 402. The IQ detection unit 402 separates the IF signal input to the digital processing unit 320 into an I signal and a Q signal by performing IQ detection based on the signal output from the numerical control oscillation unit 401. IQ detector 402 outputs the separated I signal and Q signal (I, Q). The I signal and Q signal output from the IQ detection unit 402 are output to the reception wave memories 404 to 408 and the correlation detection unit 411. The configuration of the IQ detection unit 402 will be described later (see, for example, FIG. 5).

  Timing generation section 403 generates a reception timing signal, synchronization detection timing signal, and transmission timing signal based on the correlation detection pulse output from symbol synchronization determination section 412. The reception timing signal is a signal indicating a period (reception window) in which the I signal and the Q signal output from the IQ detection unit 402 to the reception wave memories 404 to 408 are stored in the reception wave memories 404 to 408. The reception timing signal is output to the memory control units 409 and 410.

  The synchronization detection timing signal is a signal indicating a period during which symbol synchronization is detected. The synchronization detection timing signal is output to the memory control unit 409. The transmission timing signal is a signal indicating the period during which the I signal and the Q signal stored in the reception wave memories 405 to 408 are read and transmitted as interference waves for each of the reception wave memories 404 to 408. The transmission timing signal is output to the memory control unit 410. Control of each timing by the timing generation unit 403 will be described later (see, for example, FIG. 11).

  The reception wave memory 404 (# 0) is a memory that stores reception waves for synchronization detection. The reception wave memory 404 stores the I signal and the Q signal output from the IQ detection unit 402 according to control by the memory control unit 409. The received wave memory 404 outputs the stored I signal and Q signal to the correlation detection unit 411 under the control of the memory control unit 409.

  The reception wave memories 405 to 408 (# 1 to # 4) are memories that store reception waves for interference. The reception wave memories 405 to 408 store the I signal and the Q signal output from the IQ detection unit 402 according to control by the memory control unit 410. The received wave memories 405 to 408 output the stored I signal and Q signal under the control of the memory control unit 410. The I signal output from the reception wave memories 405 to 408 is output to the adder 413. The Q signal output from the reception wave memories 405 to 408 is output to the adder 414.

  The memory control unit 409 controls the reception wave memory 404 so as to store the I signal and the Q signal from the IQ detection unit 402 during the period (reception window) indicated by the reception timing signal output from the timing generation unit 403. The memory control unit 409 controls the reception wave memory 404 so as to output the stored I signal and Q signal during the period indicated by the synchronization detection timing signal output from the timing generation unit 403.

  The memory control unit 410 controls the reception wave memories 405 to 408 so as to store the I signal and the Q signal from the IQ detection unit 402 during the period indicated by the reception timing signal output from the timing generation unit 403. In addition, the memory control unit 409 controls the reception wave memories 405 to 408 so as to output the stored I signal and Q signal during the period indicated by the transmission timing signal output from the timing generation unit 403.

  Correlation detection section 411 detects the peak value of the correlation value between the I signal and Q signal output from IQ detection section 402 and the I signal and Q signal output from reception wave memory 404. For example, the correlation detection unit 411 multiplies the I signal and Q signal output from the IQ detection unit 402 by the complex conjugate of the I signal and Q signal output from the reception wave memory 404, and the moving average of the multiplication results To calculate the peak value of the correlation value. The moving average period is, for example, a guard interval length Tg (see, for example, FIG. 7). Correlation detection section 411 outputs the detected peak value to symbol synchronization determination section 412.

  The symbol synchronization determination unit 412 determines symbol synchronization based on the peak value output from the correlation detection unit 411. Specifically, the symbol synchronization determination unit 412 determines whether or not the timing of the reception window indicated by the reception timing signal currently output from the timing generation unit 403 matches the timing of the guard interval of the signal to be disturbed. judge. For example, the symbol synchronization determination unit 412 determines symbol synchronization by comparing the peak value output from the correlation detection unit 411 with a threshold (see, for example, FIG. 8). The symbol synchronization determination unit 412 outputs a correlation detection pulse indicating the determination result to the timing generation unit 403.

  Adder 413 adds the I signals output from received wave memories 405 to 408 at different timings, and outputs the result to IQ combiner 416. Adder 414 adds the Q signals output from received wave memories 405 to 408 at different timings and outputs the result to IQ combiner 416.

  The numerically controlled oscillator 415 (NCO) oscillates a periodic signal and outputs the oscillated signal to the IQ combiner 416. IQ combiner 416 combines the I signal and Q signal output from adders 413 and 414 based on the signal output from numerically controlled oscillator 415 and converts the signal into an IF signal. IQ combiner 416 outputs the converted IF signal. The configuration of the IQ combining unit 416 will be described later (see, for example, FIG. 6).

  As shown in FIG. 4, the digital processing unit 320 includes four memories (received wave memories 405 to 408) for storing received wave data. As a result, it is possible to easily generate an interference wave (for example, see FIG. 10) in which the received wave data of four systems having different timings are overlapped. However, the number of memories for storing received wave data may be 1 to 3 or 5 or more. The reception wave memories 404 to 408 may be provided outside the digital processing unit 320.

(Configuration of IQ detector)
FIG. 5 is a diagram illustrating an example of the configuration of the IQ detection unit. As shown in FIG. 5, the IQ detection unit 402 (see, for example, FIG. 4) includes a phase shifter 501, mixers 502 and 503, and low-pass filters 504 and 505. The phase shifter 501 delays the signal output from the numerically controlled oscillator 401 by 90 [°], and outputs the delayed signal to the mixer 502.

  The mixer 502 mixes the IF signal input to the IQ detection unit 402 and the signal output from the phase shifter 501, and outputs a signal obtained by the mixing to the low-pass filter 504. The mixer 503 mixes the IF signal input to the IQ detection unit 402 and the signal output from the numerically controlled oscillation unit 401, and outputs a signal obtained by the mixing to the low-pass filter 505.

  A low-pass filter 504 (LPF: Low Pass Filter) removes an unnecessary wave component by extracting a low-frequency component of the signal output from the mixer 502. The low pass filter 504 outputs the extracted signal as an I signal. The low-pass filter 505 (LPF) removes unnecessary wave components by extracting low-frequency components of the signal output from the mixer 503. The low-pass filter 505 outputs the extracted signal as a Q signal.

(Configuration of IQ synthesis unit)
FIG. 6 is a diagram illustrating an example of the configuration of the IQ combining unit. As illustrated in FIG. 6, the IQ combining unit 416 (see, for example, FIG. 4) includes a phase shifter 601, mixers 602 and 603, and an adding unit 604. The phase shifter 601 delays the signal output from the numerically controlled oscillator 415 by 90 [°], and outputs the delayed signal to the mixer 602.

  The mixer 602 mixes the I signal input to the IQ combining unit 416 and the signal output from the phase shifter 601, and outputs the IF signal obtained by the mixing to the adding unit 604. The mixer 603 mixes the Q signal input to the IQ synthesis unit 416 and the signal output from the numerical control oscillation unit 415, and outputs the IF signal obtained by the mixing to the addition unit 604. The adder 604 adds the IF signal output from the mixer 602 and the IF signal output from the mixer 603, and outputs an IF signal as a result of the addition.

(Interference signal)
FIG. 7 is a diagram illustrating an example of a signal to be disturbed. The horizontal axis in FIG. 7 indicates time. The vertical axis direction in FIG. 7 indicates the signal intensity. The interference target signal 700 is one period of the interference target OFDM signal. The interference target signal 700 includes a guard interval 710 and a symbol period 720.

  The length of the guard interval 710 is Tg. The length of the symbol period 720 is 1 / f0. That is, f0 is the fundamental frequency of the interference target signal 700. The guard interval 710 portion of the interference target signal 700 is a redundant signal that duplicates the signal of the end period 721 having the length Tg at the end of the immediately following symbol period 720.

  The correlation detection unit 411 illustrated in FIG. 4 includes a signal in a period indicated by the synchronization detection timing signal and a signal in a period 1 / f0 before the period indicated by the synchronization detection timing signal in the interference target signal 700. The peak value of the correlation value is detected. Thereby, when the period indicated by the synchronization detection timing signal coincides with the end period 721, the correlation between the signals of the guard interval 710 and the end period 721, which are the same signal, is detected, and the peak value of the correlation value is large. Become.

  Thus, the redundant signal transmitted in the guard interval 710 is, for example, a signal obtained by duplicating the radio signal in the symbol period 720 immediately after the guard interval 710 in each symbol period (each transmission period). In this case, the digital processing unit 320 can detect the guard interval 710 based on a comparison result of signals at different points in time in the received signal that differ by the length 1 / f0 of the transmission period.

(Peak value of correlation value output from correlation detector)
FIG. 8 is a diagram illustrating an example of the peak value of the correlation value. The horizontal axis in FIG. 8 indicates time (number of samples). The vertical axis in FIG. 8 indicates the peak value (correlation peak value) output from the correlation detection unit 411 as an absolute value. A peak value characteristic 810 indicates the characteristic of the peak value output from the correlation detection unit 411 with respect to time. For example, the symbol synchronization determination unit 412 determines that the symbols are synchronized when the peak value from the correlation detection unit 411 exceeds a predetermined threshold value 801, and the symbol synchronization when the peak value does not exceed the predetermined threshold value 801. Determine that they are not synchronized.

(Synchronous detection operation time chart)
FIG. 9 is a diagram illustrating an example of the synchronization detection operation. In FIG. 9, a disturbance target signal 910 indicates an ODFM signal to be disturbed. In the interference target signal 910, a symbol period (Data) and a guard interval (GI: Guard Interval) are alternately set. It is assumed that symbol synchronization has succeeded before the synchronization detection operation shown in FIG. The digital processing unit 320 sets a reception window 920 in the vicinity of the guard interval 911 of the interference target signal 910.

  The window length 921 of the reception window 920 is, for example, at least twice the length of the guard interval 911. Also, the timing of the reception window 920 is, for example, a timing at which the reception window 920 includes the guard interval 911 and the period of the window length 921 immediately before the guard interval 911. The digital processing unit 320 stores the reception data 931 to 933 in the reception window 920 in the interference target signal 910 in the reception wave memories 405 to 408.

  As indicated by reference numerals 901 and 902, the correlation detection unit 411 receives received wave data read from the received wave memory 405 and received wave data received in the next receiving window at a timing shifted by one symbol length from the head of the guard interval 911. Correlation with is detected. The correlation detection pulse 940 is a correlation detection pulse output from the correlation detection unit 411. The correlation detection pulse 940 is a signal that becomes High when the peak value of the correlation value is detected in the first half of the reception window 920.

(Transmission operation time chart)
FIG. 10 is a diagram illustrating an example of a transmission operation. In FIG. 10, the same parts as those shown in FIG. After performing symbol synchronization by the synchronization detection operation shown in FIG. 9, the transmission operation shown in FIG. 10 is performed. The synchronization detection period 1010 is a period during which symbol synchronization is detected by the correlation detection unit 411 and the symbol synchronization determination unit 412.

  The transmission data 1021 to 1024 indicates data that is read from the reception wave memories 405 to 408 (# 1 to # 4) and transmitted. As shown in the transmission data 1021 to 1024, the digital processing unit 320 repeatedly transmits the reception data stored in the reception wave memories 405 to 408. Further, the digital processing unit 320 gives a time difference to the transmission data 1021 to 1024, respectively.

  Thereby, for example, the reception data 931 stored in the first reception window 920 are continuously transmitted while overlapping each other in time. Since the transmission data 1021 to 1024 is added to the reception-side wireless communication device 102, the reception of the interference target signal 910 in the wireless communication device 102 can be made difficult (see, for example, FIGS. 15 to 20). .

(Timing control by the timing generator)
FIG. 11 is a diagram illustrating an example of timing control by the timing generation unit. 11, the same parts as those shown in FIG. 10 are denoted by the same reference numerals, and the description thereof is omitted. A reception signal input state 1110 indicates an on / off state of the reception side switch 312. A transmission signal output state 1120 indicates an on / off state of the transmission side switch 334. The reception signal input state 1110 and the transmission signal output state 1120 are controlled by transmission / reception switching signals output from the timing generation unit 403 to the transmission / reception switching control unit 340.

  In the reception window 920, the timing generation unit 403 turns on the reception signal input state 1110 and turns off the transmission signal output state 1120. As a result, the synchronization detection operation shown in FIG. 9 can be performed. Further, the timing generation unit 403 turns off the reception signal input state 1110 and turns on the transmission signal output state 1120 in a period different from the reception window 920. As a result, the transmission operation shown in FIG. 10 can be performed.

  A reception timing signal 1130 is a reception timing signal output from the timing generation unit 403 to the memory control units 409 and 410. The reception timing signal 1130 is a signal indicating the reception window 920.

  The synchronization detection timing signal 1140 is a synchronization detection timing signal output from the timing generation unit 403 to the memory control unit 409. The synchronization detection timing signal 1140 is a signal indicating a synchronization detection period 1010 that is a period of the first half of the reception window 920 indicated by the reception timing signal 1130.

  Transmission timing signals 1151 to 1154 are transmission timing signals output from the timing generation unit 403 to the memory control unit 410. Transmission timing signals 1151 to 1154 indicate timings at which the received wave data stored in the received wave memories 405 to 408 (# 1 to # 4) are read and transmitted, respectively. The timing generation unit 403 gives time differences to the transmission data 1021 to 1024 by shifting the timings indicated by the transmission timing signals 1151 to 1154, respectively.

(Reception processing)
FIG. 12 is a flowchart illustrating an example of reception processing. For example, the communication jamming apparatus 300 repeatedly executes the following steps as the reception process. First, the timing generation unit 403 determines whether or not the reception window 920 is High (step S1201). When the reception window 920 is High (step S1201: Yes), the transmission / reception switching control unit 340 determines whether or not the reception side switch 312 is turned on (step S1202).

  In step S1202, when the reception side switch 312 is on (step S1202: Yes), the communication jamming apparatus 300 proceeds to step S1204. When the reception side switch 312 is not turned on (step S1202: No), the transmission / reception switching control unit 340 turns on the reception side switch 312 (step S1203).

  Next, the receiving antenna 311 receives a communication wave wirelessly transmitted from the wireless communication device 101 (step S1204). Next, the frequency converter 314 converts the frequency of the communication wave received in step S1204 into an IF band (step S1205). Next, the band pass filter 315 extracts a signal in the disturbance target band from the signals whose frequency is converted to the IF band in step S1205 (step S1206).

  Next, the A / D converter 316 converts the signal extracted in step S1206 into a digital signal (step S1207). Next, the IQ detection unit 402 performs IQ detection that separates the signal converted into the digital signal in step S1207 into an I signal and a Q signal (step S1208). Next, the memory control unit 409 and the memory control unit 410 store the received wave data obtained by the IQ detection in step S1208 in the received wave memories 404 to 408 (# 0 to # 4) (step S1209).

  Next, the memory control unit 409 determines whether or not the synchronization detection period 1010 is reached (step S1210). If the synchronization detection period 1010 is not reached (step S1210: No), the communication jamming apparatus 300 returns to step S1201. When the synchronization detection period 1010 is reached (step S1210: Yes), the memory control unit 409 reads the received wave data from the received wave memory 404 (# 0) (step S1211).

  Next, the correlation detection unit 411 detects a correlation value between the current reception wave data output from the IQ detection unit 402 and the reception wave data read out in step S1211 (step S1212). Next, the correlation detection unit 411 determines whether it is a symbol synchronization determination timing (step S1213). The symbol synchronization determination timing is, for example, the end timing of the synchronization detection period 1010.

  In step S1213, when it is not the determination timing (step S1213: No), the communication jamming apparatus 300 returns to step S1201. When it is the determination timing (step S1213: Yes), the correlation detection unit 411 calculates the peak value of the correlation value, and the symbol synchronization determination unit 412 determines whether or not the peak value exceeds the threshold value (step S1214). . Thereby, it can be determined whether or not the symbol synchronization is successful.

  In step S1214, when the peak value exceeds the threshold (step S1214: Yes), it can be determined that the symbol synchronization is successful. In this case, the communication jamming apparatus 300 returns to step S1201. If the peak value does not exceed the threshold value (step S1214: No), it can be determined that the symbol synchronization has not succeeded. In this case, the timing generation unit 403 changes the timing of the reception window 920 by adjusting the reception timing signal 1130 (step S1215), and returns to step S1201. In step S1215, the timing generation unit 403 delays the timing of the reception window 920 by a certain amount, for example.

  In step S1201, when the reception window 920 is not high (step S1201: No), the transmission / reception switching control unit 340 turns off the reception side switch 312 (step S1216), and ends a series of reception processing.

  FIG. 13 is a flowchart illustrating a modification of the reception process. The communication jamming apparatus 300 may repeatedly execute the steps shown in FIG. Steps S1301 to S1315 shown in FIG. 13 are the same as steps S1201 to S1215 shown in FIG. Following step S1315, the timing generation unit 403 determines whether or not the cumulative change amount of the timing of the reception window 920 in step S1315 exceeds the symbol length (eg, Tg) of the interference target signal 910 (step S1316).

  If the accumulated change amount does not exceed the symbol length in step S1316 (step S1316: No), the communication jamming apparatus 300 returns to step S1301. When the accumulated change amount exceeds the symbol length (step S1316: Yes), the transmission / reception switching control unit 340 turns off the reception side switch 312 (step S1317), and the series of reception processing ends.

  As described above, the reception operation may be stopped when no guard interval is detected (successful symbol synchronization) for a predetermined time or longer. As a result, the reception operation by the communication jamming device 300 can be automatically stopped when the radio signal to be disturbed is no longer transmitted. For this reason, for example, power consumption can be suppressed.

(Transmission process)
FIG. 14 is a flowchart illustrating an example of the transmission process. The communication jamming apparatus 300 repeatedly executes, for example, the following steps as transmission processing. First, the timing generation unit 403 determines whether or not the reception window 920 is Low (step S1401). When the reception window 920 is Low (step S1401: Yes), the transmission / reception switching control unit 340 determines whether or not the transmission side switch 334 is turned on (step S1402).

  In step S1402, when the transmission side switch 334 is turned on (step S1402: Yes), the communication jamming apparatus 300 proceeds to steps S1404, S1406, S1408, and S1410. When the transmission side switch 334 is not turned on (step S1402: No), the transmission / reception switching control unit 340 turns on the transmission side switch 334 (step S1403).

  Next, the memory control unit 410 determines whether or not it is the transmission timing signal 1151 of the received wave data stored in the received wave memory 405 (# 1) (step S1404). When it is not the transmission timing signal 1151 (step S1404: No), the memory control unit 410 skips step S1405. In this case, zero data is output from the received wave memory 405 to the adders 413 and 414. If it is the transmission timing signal 1151 (step S1404: Yes), the memory control unit 410 reads the received wave data from the received wave memory 405 (# 1) (step S1405). The received wave data read in step S1405 is output to the adding units 413 and 414.

  Further, the memory control unit 410 determines whether or not it is the transmission timing signal 1152 of the received wave data stored in the received wave memory 406 (# 2) (step S1406). If it is not the transmission timing signal 1152 (step S1406: No), the memory control unit 410 skips step S1407. In this case, zero data is output from the received wave memory 406 to the adding units 413 and 414. If it is the transmission timing signal 1152 (step S1406: Yes), the memory control unit 410 reads the received wave data from the received wave memory 406 (# 2) (step S1407). The received wave data read in step S1405 is output to the adding units 413 and 414.

  Further, the memory control unit 410 determines whether or not it is the transmission timing signal 1153 of the reception wave data stored in the reception wave memory 407 (# 3) (step S1408). If it is not the transmission timing signal 1153 (step S1408: No), the memory control unit 410 skips step S1409. In this case, zero data is output from the received wave memory 407 to the adders 413 and 414. If it is the transmission timing signal 1153 (step S1408: Yes), the memory control unit 410 reads the received wave data from the received wave memory 407 (# 3) (step S1409). The received wave data read in step S1409 is output to the adding units 413 and 414.

  Further, the memory control unit 410 determines whether or not it is the transmission timing signal 1154 of the received wave data stored in the received wave memory 408 (# 4) (step S1410). If it is not the transmission timing signal 1154 (step S1410: No), the memory control unit 410 skips step S1411. In this case, zero data is output from the received wave memory 407 to the adders 413 and 414. If it is the transmission timing signal 1154 (step S1410: Yes), the memory control unit 410 reads the received wave data from the received wave memory 408 (# 4) (step S1411). The received wave data read in step S1411 is output to the adding units 413 and 414.

  Next, the adders 413 and 414 add the received wave data from the received wave memories 405 to 408 (step S1412). Next, the IQ synthesis unit 416 performs IQ synthesis on the received wave data added in step S1412 and converts it into an IF signal (step S1413). Next, the D / A converter 331 converts the IF signal converted in step S1413 into an analog signal (step S1414).

  Next, the frequency converter 333 converts the frequency of the IF signal converted into the analog signal in step S1414 into the RF band (step S1415). Next, the transmission antenna 335 transmits the signal converted into the RF band in step S1415 to the air as an interference wave (step S1416), and the process returns to step S1401.

  In step S1401, when the reception window 920 is not low (step S1401: No), the transmission / reception switching control unit 340 turns off the transmission side switch 334 (step S1417), and ends a series of transmission processing.

  As described above, the communication jamming apparatus 300 includes a plurality of memories each storing received wave data, and the signals stored in the plurality of memories are overlapped at different timings and in time. The signal read and added is transmitted. Thereby, it is possible to easily generate an interference wave in which a plurality of received wave data are overlapped. By transmitting an interference wave in which a plurality of received wave data are overlapped, the number of repetitions of the received data can be increased, so that reception on the receiving side can be made more difficult.

(Example 1 of communication interruption)
FIG. 15 is a diagram (part 1) illustrating a first example of communication interference. FIG. 15 shows a transmission operation by the communication jamming apparatus 300 according to communication jamming example 1. In FIG. 15, the same parts as those shown in FIG. Here, it is assumed that communication jamming apparatus 300 repeatedly transmits only transmission data 1021 read out from received wave memory 405 (# 1) and transmitted as a jamming wave.

  FIG. 16 is a second diagram illustrating a first example of communication interruption. FIG. 16 shows a received wave in the wireless communication device 102 on the receiving side according to communication jamming example 1. 16, the same parts as those shown in FIG. 15 are denoted by the same reference numerals, and the description thereof is omitted. A reception wave 1610 indicates a reception wave in the wireless communication device 102. The reception wave 1610 is a reception in which the interference target signal 910 (original reception wave) transmitted from the transmission-side wireless communication device 101 and the transmission data 1021 (interference wave) transmitted from the communication disturbance device 300 are combined. Become a wave.

  Therefore, in the received wave 1610, the guard interval is duplicated even in the symbol period of the interference target signal 910, and symbol synchronization by the guard interval is difficult. For this reason, reception in the wireless communication device 102 can be made difficult. Also, in the received wave 1610, the end of the symbol period of the interference target signal 910 is duplicated in the symbol period of the next period and is received as a delayed wave exceeding the guard interval. For this reason, inter-symbol interference occurs, making it difficult to demodulate the symbol period, making reception at the wireless communication device 102 even more difficult.

(Example 2 of communication interruption)
FIG. 17 is a diagram (part 1) illustrating a second example of communication interference. FIG. 17 shows a transmission operation by the communication jamming apparatus 300 according to communication jamming example 2. 17, parts that are the same as the parts shown in FIG. 15 are given the same reference numerals, and descriptions thereof will be omitted. In the communication interference example 2, the transmission data 1021 includes the guard intervals 931a, 932a,... Of the reception data 931, 932,..., And does not include the end of the symbol period immediately before the guard interval.

  FIG. 18 is a second diagram illustrating a second example of communication interruption. FIG. 18 shows a received wave in the radio communication device 102 on the receiving side according to communication interference example 2. 18, parts that are the same as the parts shown in FIG. 16 are given the same reference numerals, and descriptions thereof will be omitted.

  In the received wave 1610 according to the communication interference example 2, the guard interval is duplicated even in the symbol period of the interference target signal 910, and symbol synchronization by the guard interval is difficult. For this reason, reception in the wireless communication device 102 can be made difficult. Thus, even if the end of the symbol period immediately before the guard interval is not included in the transmission data 1021, reception by the wireless communication device 102 can be made difficult.

(Example 3 of communication interruption)
FIG. 19 is a first diagram illustrating a third example of communication interruption. FIG. 19 shows a transmission operation by the communication jamming apparatus 300 according to communication jamming example 3. 19, parts that are the same as the parts shown in FIG. 15 are given the same reference numerals, and descriptions thereof will be omitted. In the communication jamming example 3, the transmission data 1021 includes the end periods 931b, 932b,... Of the symbol period immediately before the guard interval in the reception data 931, 932,.

  FIG. 20 is a second diagram illustrating a third example of communication interference. FIG. 20 shows a received wave in the wireless communication device 102 on the receiving side according to communication jamming example 3. 20, parts that are the same as the parts shown in FIG. 16 are given the same reference numerals, and descriptions thereof will be omitted.

  In the received wave 1610 according to the communication jamming example 3, the end of the symbol period of the signal to be disturbed 910 is duplicated in the symbol period of the next period and is received as a delayed wave exceeding the guard interval. For this reason, inter-symbol interference occurs and it becomes difficult to demodulate the symbol period, and reception by the wireless communication device 102 can be made difficult. Thus, even if the guard interval is not included in the transmission data 1021, reception by the wireless communication device 102 can be made difficult.

  15 to 20, the case where the communication jamming apparatus 300 repeatedly transmits only the transmission data 1021 read and transmitted from the received wave memory 405 (# 1) as a jamming wave has been described. On the other hand, the communication jamming apparatus 300 may repeatedly transmit the transmission data 1022 to 1024 of the reception wave memories 406 to 408 (# 2 to # 4) in a superimposed manner. As a result, reception at the wireless communication device 102 can be made more difficult.

  As described above, according to the communication jamming apparatus 300 according to the embodiment, it is possible to intercept the redundant signal of the guard interval in the OFDM signal to be disturbed, and perform radio transmission by delaying the intercepted redundant signal. This makes it difficult to perform symbol synchronization by the guard interval on the receiving side, and can efficiently interfere with wireless communication.

  Specifically, since the guard interval part is transmitted as an interference wave and makes symbol synchronization difficult and interferes with communication, for example, compared with the case where power interference is performed, power consumption for transmission of the interference wave can be suppressed. it can. Moreover, since it is not necessary to transmit an interference wave to each frequency at which an interference target signal may be transmitted, for example, power interference, it is possible to suppress power consumption for the transmission of the interference wave. At the same time, it is possible to suppress the influence on the communication in the band that is not the object of interference.

  In the above-described embodiment, the case where the OFDM communication wave is targeted for interference has been described. However, communication waves of various systems other than the OFDM scheme can also be targeted for interference. That is, for example, with respect to wireless communication in which a guard interval is periodically set and reception is performed while symbol synchronization is performed using the guard interval, the communication jamming device 300 may make symbol synchronization difficult and disturb communication. it can.

  As described above, according to the communication jamming apparatus and the communication jamming method, communication can be efficiently jammed.

  The following additional notes are disclosed with respect to the embodiment described above.

(Supplementary Note 1) In a communication jamming apparatus that periodically sets an additional period during which a redundant signal is transmitted, and interferes with radio communication that is received on the receiving side while being synchronized based on the redundant signal,
A receiver for receiving a radio signal transmitted by the radio communication;
A detection unit for detecting the additional period based on a signal received by the reception unit;
An extraction unit for extracting a signal of an additional period detected by the detection unit from the received signal;
A transmission unit that wirelessly transmits the signal extracted by the extraction unit after the detected additional period;
A communication jamming device comprising:

(Supplementary note 2) The communication jamming apparatus according to supplementary note 1, wherein the extraction unit extracts signals of the detected additional period and a period immediately before the detected additional period.

(Supplementary note 3) The communication jamming device according to Supplementary note 1 or 2, wherein the transmission unit repeatedly transmits the extracted signal until the additional period next to the detected additional period. .

(Supplementary note 4) Any one of Supplementary notes 1 to 3, further comprising a control unit that stops reception of the radio signal by the reception unit when the additional period is not detected by the detection unit for a predetermined time or more. Communication jamming device as described in one.

(Supplementary note 5) As described in any one of Supplementary notes 1 to 4, further comprising: a control unit that alternately executes reception of the wireless signal by the reception unit and transmission of a signal by the transmission unit. Communication jammer.

(Supplementary note 6) A plurality of memories each storing the extracted signal are provided,
Any one of appendices 1 to 5, wherein the transmitting unit transmits a signal obtained by reading and adding the signals stored in the plurality of memories so as to overlap each other at different timings. The communication jamming device according to claim 1.

(Supplementary note 7) The redundant signal is a signal obtained by duplicating the radio signal in a transmission period immediately after the additional period in which the redundant signal is transmitted among transmission periods different from the additional period,
Any one of appendices 1 to 6, wherein the detection unit detects the additional period based on a comparison result of signals at different points in time of the received signal that differ by the length of the transmission period. The communication jamming device according to one.

(Supplementary note 8) The communication jamming device according to any one of supplementary notes 1 to 7, wherein the radio signal is a signal subjected to orthogonal frequency division multiplexing.

(Supplementary Note 9) In a communication jamming apparatus that periodically sets an additional period during which a redundant signal is transmitted and interferes with wireless communication in which reception is performed while being synchronized based on the redundant signal on the receiving side,
A receiver for receiving a radio signal transmitted by the radio communication;
A detection unit for detecting the additional period based on a signal received by the reception unit;
An extraction unit that extracts a signal in a period immediately before the additional period detected by the detection unit from the received signal;
A transmission unit that wirelessly transmits the signal extracted by the extraction unit after the detected additional period;
A communication jamming device comprising:

(Additional remark 10) In the communication interference method in which the additional period in which the redundant signal is transmitted is periodically set and the wireless communication is performed while being synchronized on the reception side based on the redundant signal,
Receiving a wireless signal transmitted by the wireless communication;
Detecting the additional period based on the received signal;
Extracting the detected signal of the additional period from the received signal,
A communication jamming method, wherein the extracted signal is wirelessly transmitted after the detected additional period.

(Additional remark 11) In the communication interference method for interfering with wireless communication in which an additional period in which a redundant signal is transmitted is periodically set and reception is performed on the receiving side in synchronization with the redundant signal,
Receiving a wireless signal transmitted by the wireless communication;
Detecting the additional period based on the received signal;
Extracting the signal of the period immediately before the detected additional period from the received signal,
A communication jamming method, wherein the extracted signal is wirelessly transmitted after the detected additional period.

DESCRIPTION OF SYMBOLS 100 Communication system 101,102 Wireless communication apparatus 110,300 Communication jamming device 111,311 Reception antenna 112 Reception part 113 Detection part 114 Extraction part 115 Transmission part 116,335 Transmission antenna 121,210 Radio signal 122 Interference wave 211-213, ... , 720 Symbol period 211a, 212a, 213a,..., 721 Trailing period 221, 222, 223,..., 710, 911 Guard interval 231, 232 Detection period 241, 242 Extraction signal 251, 252 Transmission signal 260 Reception signal 312 Reception side switch 313, 332 Local signal generator 314, 333 Frequency converter 315 Band pass filter 316 A / D converter 320 Digital processing unit 331 D / A converter 334 Transmission side switch 340 Transmission / reception switching control unit 401 415 Numerical control oscillator 402 IQ detection unit 403 Timing generation unit 404 to 408 Received wave memory 409, 410 Memory control unit 411 Correlation detection unit 412 Symbol synchronization determination unit 413, 414, 604 Addition unit 416 IQ synthesis unit 501 601 Phase shifter 502, 503, 602, 603 Mixer 504, 505 Low-pass filter 700, 910 Interference target signal 801 Threshold 920 Reception window 921 Window length 931-933 Reception data 940 Correlation detection pulse 1010 Synchronization detection period 1021-1024 Transmission data 1110 Reception signal input state 1120 Transmission signal output state 1130 Reception timing signal 1140 Synchronization detection timing signal 1151-1154 Transmission timing signal 1610 Reception wave

Claims (10)

In the communication jamming apparatus that periodically sets the additional period during which the redundant signal is transmitted and interferes with the wireless communication in which reception is performed while being synchronized based on the redundant signal on the receiving side,
A receiver for receiving a radio signal transmitted by the radio communication;
A detection unit for detecting the additional period based on a signal received by the reception unit;
An extraction unit for extracting a signal of an additional period detected by the detection unit from the received signal;
A transmission unit that wirelessly transmits the signal extracted by the extraction unit after the detected additional period;
A communication jamming device comprising:   The communication jamming apparatus according to claim 1, wherein the extraction unit extracts signals of the detected additional period and a period immediately before the detected additional period.   The communication jamming apparatus according to claim 1, wherein the transmission unit repeatedly transmits the extracted signal until the additional period next to the detected additional period.   4. The control unit according to claim 1, further comprising: a control unit configured to stop reception of the radio signal by the reception unit when the additional period is not detected for a predetermined time or more by the detection unit. Communication jammers.   5. The communication jamming device according to claim 1, further comprising: a control unit that alternately executes reception of the radio signal by the reception unit and transmission of the signal by the transmission unit. . The redundant signal is a signal obtained by duplicating the radio signal in a transmission period immediately after the additional period in which the redundant signal is transmitted, in each transmission period different from the additional period,
The said detection part detects the said additional period based on the comparison result of the signal of each time which differs only in the length of the said transmission period among the said received signals. The communication jamming device according to claim 1.   The communication jamming apparatus according to any one of claims 1 to 6, wherein the radio signal is an orthogonal frequency division multiplexed signal. In the communication jamming apparatus that periodically sets the additional period during which the redundant signal is transmitted and interferes with the wireless communication in which reception is performed while being synchronized based on the redundant signal on the receiving side,
A receiver for receiving a radio signal transmitted by the radio communication;
A detection unit for detecting the additional period based on a signal received by the reception unit;
An extraction unit that extracts a signal in a period immediately before the additional period detected by the detection unit from the received signal;
A transmission unit that wirelessly transmits the signal extracted by the extraction unit after the detected additional period;
A communication jamming device comprising: In the communication disturbing method in which the additional period in which the redundant signal is transmitted is periodically set, and the wireless communication in which reception is performed while synchronizing based on the redundant signal on the receiving side is performed,
Receiving a wireless signal transmitted by the wireless communication;
Detecting the additional period based on the received signal;
Extracting the detected signal of the additional period from the received signal,
A communication jamming method, wherein the extracted signal is wirelessly transmitted after the detected additional period. In the communication disturbing method in which the additional period in which the redundant signal is transmitted is periodically set, and the wireless communication in which reception is performed while synchronizing based on the redundant signal on the receiving side is performed,
Receiving a wireless signal transmitted by the wireless communication;
Detecting the additional period based on the received signal;
Extracting the signal of the period immediately before the detected additional period from the received signal,
A communication jamming method, wherein the extracted signal is wirelessly transmitted after the detected additional period.

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