JP2012070099A - Radio wave receiving device and signal analysis method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio wave receiving device which can continuously detect a frequency hopping signal without increasing a processing time, and to provide a signal analysis method used for the device.SOLUTION: The radio wave receiving device has an antenna, an RF receiver, a division filter, an IF receiver and a detection processor. The antenna receives a radio wave. The RF receiver narrows a reception signal received by the antenna according to a specified broad-band, and converts the narrowed reception signal into an IF signal of an IF band. The division filter applies amplitude detection on an RF signal of which the band is narrowed by the RF receiver, and produces a result of the broad-band detection. The IF receiver narrows the IF signal from the RF receiver according to a specified narrow-band, applies amplitude detection and phase detection on the narrowed IF signal, and produces a result of the narrow-band detection. The detection processor performs first detection processing to the reception signal by performing video integration of the result of the broad-band detection, and performs second detection processing to the reception signal by performing FFT of the result of the narrow-band detection.

Description

  Embodiments described herein relate generally to a radio wave receiving apparatus that is mounted on a flying body and detects a target from received radio waves, and a signal analysis method used in the apparatus.

  In general, there is a method in which a plurality of antennas and receivers having different reception bands are prepared and processed in parallel when detecting existing radio waves and obtaining specifications such as frequency from the detected radio waves.

  By the way, the radio wave receiving device mounted on the flying object includes a receiving broadband antenna, a receiving unit that can change the receiving band, and a signal processing unit. In this type of radio wave receiver, when trying to determine the number and frequency of received radio wave sources, the reception unit narrows down the band of the received radio wave, and the signal processing unit analyzes the narrowed radio wave. I do. With such a configuration, the radio wave receiving apparatus can continuously detect radio waves if the frequency band of the incoming radio waves matches the reception band of the receiving unit.

  However, when a frequency hopping signal is transmitted from the transmission source, the frequency band of the frequency hopping signal may not match the reception band of the receiving unit. In such a case, it is difficult for the conventional radio wave receiver to continuously detect radio waves. Here, the frequency hopping signal is a signal whose transmission frequency is randomly changed in a short time on the radio wave transmission side so that the radio wave cannot be detected by other than the desired radio wave receiver.

  Note that a method of dealing with frequency hopping signals can be considered by setting a wide bandwidth of the reception band. However, analysis processing increases as the bandwidth increases, and radio wave analysis takes time. In the radio wave receiver mounted on the flying object, since it is desired to shorten the operation time, a method that increases the processing time is not preferable.

Japanese Patent Laid-Open No. 10-89897

  As described above, in the conventional radio wave receiver mounted on the flying object, it is difficult to detect the frequency hopping signal without increasing the processing time.

  An object of the present invention is to provide a radio wave receiver capable of detecting a frequency hopping signal without increasing the processing time and a signal analysis method used in this apparatus.

  According to the embodiment, the radio wave receiver includes an antenna, an RF receiver, a division filter, an IF receiver, and a detection processor. The antenna receives radio waves. The RF receiver narrows down the received signal received by the antenna by a designated wide band assumed to include a frequency hopping signal, and converts the narrowed received signal into an IF signal in the IF band. The division filter performs amplitude detection on the RF signal whose band is narrowed by the RF receiver, and generates a wideband detection result. The IF receiver narrows down the IF signal from the RF receiver by a designated narrow band designated among the bands obtained by dividing the IF signal, and performs amplitude detection and phase detection on the narrowed IF signal. Generate band detection results. The detection processor performs a first detection process on the received signal by video integrating the high-band detection result, and performs a second detection on the received signal by performing an FFT on the narrow-band detection result. Process.

It is a figure which shows the structure of the flying body which mounts the electromagnetic wave receiver which concerns on embodiment. It is a block diagram which shows the function structure of the electromagnetic wave receiver of FIG. It is a block diagram which shows the function structure of the division | segmentation filter of FIG. FIG. 3 shows a detection result output from the detection processor of FIG. 2 to the signal analysis processor when the received signal includes a frequency hopping signal. FIG. 4 shows a diagram of detection results output from the detection processor of FIG. 2 to the signal analysis processor when the received signal does not include a frequency hopping signal. It is a figure which shows an example of the sequence diagram at the time of the receiving part of the radio wave receiving apparatus of FIG. 2 outputting a wideband detection result and a narrowband detection result to a signal processing part. It is a figure which shows an example of the flowchart at the time of the signal processing part of the radio wave receiver of FIG. 2 performing signal analysis operation | movement. It is a figure which shows the other example of the flowchart at the time of the signal processing part of the radio wave receiver of FIG. 2 performing signal analysis operation | movement. It is a block diagram which shows the other example of a function structure of the division | segmentation filter of FIG.

  Hereinafter, embodiments will be described with reference to the drawings.

  FIG. 1 is a schematic diagram showing a configuration of a flying object equipped with a radio wave receiver 11 according to the present embodiment. The flying body shown in FIG. 1 includes a guidance device 10 and a steering device 20.

  The guidance device 10 includes a radio wave reception device 11 and a target tracking device 12. The radio wave receiver 11 receives radio waves and detects a target from the received radio waves. The target tracking device 12 generates a guidance signal so as to follow the detected target, and outputs the guidance signal to the steering device 20.

  The steering device 20 controls the attitude of the flying object so that the flying object flies in the target direction according to the guidance signal from the guidance device 10.

  FIG. 2 is a block diagram showing a functional configuration of the radio wave receiver 11 according to the present embodiment.

  The radio wave receiver 11 shown in FIG. 2 includes a receiving broadband antenna 111, a receiving unit 112, and a signal processing unit 113.

  The broadband antenna 111 constantly receives radio waves from the target in a wide frequency band, for example, UHF to millimeter wave band. The broadband antenna 111 outputs the received radio wave as a reception signal to the reception unit 112.

  The reception unit 112 includes an RF receiver 1121, a division filter 1122, an IF receiver 1123, and a control unit 1124.

  The RF receiver 1121 narrows the band of the received signal from the wideband antenna 111 according to the designated wideband designated by the control unit 1124. The RF receiver 1121 outputs a reception signal (RF signal) with a narrowed band to the division filter 1122. Further, the RF receiver 1121 converts the reception signal with the narrowed band into an IF signal in the IF band. The RF receiver 1121 outputs the IF signal to the IF receiver 1123. The designated broadband will be described in detail by the control unit 1124.

  FIG. 3 is a block diagram showing a functional configuration of the division filter 1122 of the radio wave receiver 11 according to the present embodiment. The division filter 1122 illustrated in FIG. 3 includes a distributor 11221, filters 11222-1 to 11222-4, and detectors 11223-1 to 11223-4.

  The distributor 11221 distributes the RF signal from the RF receiver 1121 into four, and outputs each to the filters 11222-1 to 11222-4.

  The filters 11222-1 to 11222-4 are set with passbands A to D, respectively, and pass only signals in the set passband among the IF signals from the distributor 11221. Here, the pass bands A to D are designated by the control unit 1124 out of the bands obtained by dividing the band of the RF signal from the RF receiver 1121 into four. Pass signals A to D that have passed through the pass bands A to D of the filters 11222-1 to 11222-4 are supplied to the detectors 11223-1 to 11223-4, respectively.

  The detectors 11223-1 to 11223-4 detect the amplitude of the passing signals A to D from the filters 11222-1 to 11222-4. Here, since phase sampling requires high-speed data sampling, only the amplitude detection is performed in the detectors 11223-1 to 11223-4. The detectors 11223-1 to 11223-4 output the wideband detection results A to D obtained by the respective amplitude detections to the signal processing unit 113.

  The IF receiver 1123 narrows down the band of the IF signal from the RF receiver 1121 according to the designated narrow band designated by the control unit 1124. The IF receiver 1123 performs amplitude detection and phase detection on the IF signal whose band is narrowed. Then, the IF receiver 1123 outputs the narrowband detection result obtained by the amplitude detection and the phase detection to the signal processing unit 113. The designated narrow band will be described in detail by the control unit 1124.

  The control unit 1124 designates the designated broadband to the RF receiver 1121. Here, the designated broadband is designated from the bands obtained by dividing the frequency band of the broadband antenna 111 by a predetermined bandwidth. At this time, the predetermined bandwidth is set relatively wide so that the frequency hopping signal is included in the band. When an instruction to designate a new designated broadband is input from the outside, the control unit 1124 designates the new designated broadband to the RF receiver 1121 in accordance with the instruction.

  In addition, the control unit 1124 designates the pass bands A to D for the filters 11222-1 to 11222-4 based on the designated wide band designated for the RF receiver 1121. The control unit 1124 designates new passbands A to D corresponding to the designated wideband at the timing of designating a new designated wideband.

  In addition, the control unit 1124 designates the designated narrow band for the IF receiver 1123. Here, the designated narrow band is set from the bands obtained by dividing the frequency band of the IF signal from the RF receiver 1121 by a predetermined bandwidth. At this time, the predetermined bandwidth is set to be relatively narrow so that the frequency of the signal included in the radio wave can be uniquely obtained based on the sampling theorem. When an instruction to designate a new designated narrow band is input from the outside, the control unit 1124 designates the new designated narrow band to the IF receiver 1123 according to the instruction.

  The signal processing unit 113 includes a signal converter 1131, a detection processor 1132, and a signal analysis processor 1133.

  The signal converter 1131 performs analog-to-digital conversion on the wideband detection results A to D from the division filter 1122 and outputs the results to the detection processor 1132 as wideband digital signals A to D, respectively. The signal converter 1131 performs analog-digital conversion on the narrowband detection result from the IF receiver 1123 and outputs the result to the detection processor 1132 as a narrowband digital signal.

  When the detection processor 1132 accumulates a predetermined number of wideband digital signals A from the signal converter 1131, the detection processor 1132 performs video integration on the accumulated wideband digital signals A. The detection processor 1132 determines whether or not the integral value A of the video integration for the wideband digital signal A exceeds a preset first threshold value. The detection processor 1132 determines that the received signal is detected in the pass band A when the integral value A exceeds the first threshold value. The detection processor 1132 stores the detection result in the pass band A.

  Also, the detection processor 1132 performs the same processing as the broadband digital signal A on the broadband digital signals B to D from the signal converter 1131 and determines whether or not the received signal is detected in the pass bands B to D. Judging. Then, the detection processor 1132 stores the detection results in the pass bands B to D.

  In addition, when the detection processor 1132 accumulates a predetermined number of narrowband digital signals from the signal converter 1131, the detection processor 1132 performs FFT (Fast Fourier Transform) on the accumulated narrowband digital signals. The detection processor 1132 determines whether or not the FFT amplitude value exceeds a preset second threshold value. If the FFT amplitude value exceeds the second threshold, the detection processor 1132 determines that the received signal has been detected in the designated narrow band. The detection processor 1132 stores the detection result in the designated narrow band. The first and second threshold values may be the same value or different values.

  The detection processor 1132 determines whether or not the reception signal detection processing in the pass bands A to D and the designated narrow band has been repeated a preset number of times. The detection processor 1132 outputs the stored detection result to the signal analysis processor 1133 when the detection process is repeated a preset number of times. Here, the preset number of times indicates the number of times that it can be recognized that a frequency hopping signal is included in the received signal.

  The signal analysis processor 1133 determines whether or not a frequency hopping signal is included in the received signal based on the detection result from the detection processor 1132.

  FIG. 4 shows a conceptual diagram of a detection result output from the detection processor 1132 to the signal analysis processor 1133 when the received signal includes a frequency hopping signal. According to FIG. 4, the received signal is detected in the designated narrow band, and the received signal is detected in the designated wide passbands A to D. As shown in FIG. 4, the signal analysis processor 1133, when the received signal is not continuously detected in the designated narrow band and the received signal is randomly detected in the pass bands A to D, It is determined that a hopping signal is included.

  FIG. 5 shows a conceptual diagram of a detection result output from the detection processor 1132 to the signal analysis processor 1133 when the received signal does not include a frequency hopping signal. According to FIG. 5, the received signal is detected in the designated narrow band, and the received signal is detected only in the designated wide band B. As illustrated in FIG. 5, the signal analysis processor 1133 determines that a frequency hopping signal is not included in the received signal when the received signal is continuously detected in the designated narrow band.

  Next, the signal analysis operation by the radio wave receiver 11 configured as described above will be described in detail with reference to FIGS.

  FIG. 6 is a diagram illustrating an example of a sequence diagram when the reception unit 112 of the radio wave reception device 11 according to the present embodiment outputs the wideband detection results A to D and the narrowband detection result to the signal processing unit 113.

  First, in the RF receiver 1121 and the IF receiver 1123, a designated wide band and a designated narrow band are designated by the control unit 1124, respectively. In addition, in the filters 11222-1 to 11222-4, the passbands A to D are designated based on the designated wide band by the control unit 1124.

  When radio waves are received by the antenna 111, a received signal is supplied to the RF receiver 1121. The RF receiver 1121 narrows the band of the received signal according to the designated wide band from the control unit 1124 (sequence S61), and outputs the received signal with the narrowed band to the division filter 1122 as an RF signal. The RF receiver 1121 converts the received signal with the narrowed band into an IF signal (sequence S62) and outputs the IF signal to the IF receiver 1123.

  The division filter 1122 distributes the RF signal from the RF receiver 1121 into four (sequence S63), and narrows each band with a filter 11222-1,... Of the pass band A, and a filter 11222-4 of the pass band D ( Sequence S64). The division filter 1122 performs amplitude detection on the passing signals from the filters 11222-1 to 11222-4, and outputs the wideband detection results A to D obtained as a result of the amplitude detection to the signal processing unit 113 (sequence S65). .

  IF receiver 1123 narrows down the band of the IF signal according to the designated narrow band designated by control unit 1124 (sequence S66). The IF receiver 1123 performs phase detection and amplitude detection on the IF signal whose band is narrowed (sequence S67). The narrowband detection result acquired by phase detection and amplitude detection is output to the signal processing unit 113. The receiving unit 112 repeats the processing of sequences S61 to S67 for the reception signal from the antenna 111, and outputs the wideband detection results A to D and the narrowband detection result to the signal analysis processor 1133.

  When an instruction to designate a new designated broadband is input from the outside, the control unit 1124 designates a new designated broadband to the RF receiver 1121 in accordance with the instruction. When an instruction for designating a new designated narrow band is input from the outside, the control unit 1124 designates a new designated narrow band for the IF receiver 1123 according to the instruction. When the designated wide band or the designated narrow band is newly designated, the processes of sequences S61 to S67 are repeated, and the wide band detection results A to D and the narrow band detection result are output to the signal processing unit 113.

  FIG. 7 is a diagram illustrating an example of a flowchart when the signal processing unit 113 of the radio wave receiver 11 according to the present embodiment performs a signal analysis operation.

  First, the signal converter 1131 receives the wideband detection results A to D from the detectors 11223-1 to 11223-4, and receives the narrowband detection results from the IF receiver 1123. The signal converter 1131 converts the wideband detection results A to D into wideband digital signals A to D, and converts the narrowband detection results into a narrowband digital signal (step S71).

  When the number of wideband digital signals A to D necessary for video integration is supplied, the detection processor 1132 performs video integration on the wideband digital signals A to D. Further, when the number of narrowband digital signals necessary for FFT is supplied, the detection processor 1132 performs FFT on the narrowband digital signal (step S72).

  The detection processor 1132 determines whether or not the integration values A to D of the video integration exceed the first threshold value. If so, the detection processor 1132 determines that the received signal is detected in the passbands A to D. To do. The detection processor 1132 determines whether the FFT amplitude value exceeds the second threshold value. When exceeding, the detection processor 1132 determines that the received signal is detected in the designated narrow band (step S73). The detection processor 1132 stores detection results in the pass bands A to D and the designated narrow band.

  Subsequently, the detection processor 1132 determines whether or not the detection processing in the pass bands A to D and the designated narrow band has been repeated a preset number of times (step S74). When the detection processing in the pass bands A to D and the designated narrow band is repeated a preset number of times (Yes in step S74), the detection processor 1132 outputs the stored detection result to the signal analysis processor 1133. When the detection processes in the pass bands A to D and the designated narrow band are not repeated a preset number of times (No in step S74), the processes in steps S71 to S74 are repeated until the number of repetitions reaches that number.

  Based on the detection result from the detection processor 1132, the signal analysis processor 1133 determines whether or not the received signal is continuously detected in the designated narrow band (step S <b> 75). If the received signal is continuously detected in the designated narrow band as shown in FIG. 5 (Yes in step S75), the signal analysis processor 1133 determines that the frequency hopping signal is not included in the received signal (step S76). ), The process is terminated. As shown in FIG. 4, when the received signal is not continuously detected in the designated narrow band (No in step S75), the signal analysis processor 1133 determines in which of the pass bands A to D the received signal is detected. Confirmation (step S77).

  When the signal analysis processor 1133 confirms in which pass band the received signal is detected in step S77, the signal analysis processor 1133 determines whether or not the band in which the received signal is detected changes randomly (step S78). If the band in which the received signal is detected changes randomly (Yes in step S78), the signal analysis processor 1133 determines that the frequency hopping signal is included in the received signal (step S79), and performs processing. Terminate. If the band in which the received signal is detected does not change randomly (No in step S78), the process proceeds to step S76.

  As described above, in the above-described embodiment, the reception signal narrowed down by the designated wide band is subjected to amplitude detection by the division filter 1122, and the IF signal narrowed down by the designated narrow band is subjected to amplitude detection and phase detection by the IF receiver 1123. I am doing so. As described above, the phase detection is performed only for the IF signal whose band is narrowed by the designated narrow band. For this reason, it is not necessary to perform phase detection in a wide band, and the processing amount in the division filter 1122 is suppressed. As a result, the radio wave receiving device 11 can reduce the processing time.

  In the above embodiment, the received signal is detected with reference to the detection result by video integration for the wideband detection result and the detection result by FFT for the narrowband detection result. Conventionally, since the received signal is not detected in the non-tuning period of the narrow band system, if the received signal enters the non-tuning period, it has not been possible to determine whether the tracking is lost or whether it can be received again. In the present embodiment, even if the received signal enters the non-tuning period of the narrow band system, it is possible to determine whether or not the tracking can be continued while the received signal is detected in the wide band system. That is, even if the received signal includes a frequency hopping signal, the received signal can be detected.

  In the above embodiment, the designated wide band is divided into four bands A to D, and it is confirmed in which band the received signal is received. As a result, it is possible to check whether or not the band of the received signal changes at random, so it is possible to determine whether or not the frequency hopping signal is included in the received signal. In addition, since these processes are performed by the signal processing unit 113, a large hardware configuration is not necessary. That is, the radio wave receiver 11 can realize the above processing with a small hardware scale suitable for a flying object.

  Therefore, according to the radio wave receiver 11 according to the present embodiment, it is possible to continuously detect the frequency hopping signal without increasing the processing time.

  In the above embodiment, the example in which the designated wide band is distributed to four by the division filter 1122 has been described. However, the number of distribution is not limited to four.

  In the above-described embodiment, the example in which the signal processing unit 113 performs the signal analysis operation according to the flowchart illustrated in FIG. 7 has been described. However, the operation of the signal processing unit 113 is not limited to this.

  For example, as shown in FIG. 8, the signal analysis processor 1133 determines whether or not the band in which the received signal is detected is one or less (step S81). When the band where the received signal is detected is 1 or less (Yes in Step S81), the signal analysis processor 1133 refers to the information on the band where the received signal is detected and needs to readjust the designated narrow band. Is output to the outside (step S82). When the band which detected the received signal is two or more places (No of Step S81), signal analysis processor 1133 shifts the processing to Step S76.

  When a new designated narrow band is designated for the IF receiver 1123 by the control unit 1124 in accordance with an external signal, the processes shown in FIGS. 6 and 8 are repeated again. As described above, changing the designated narrow band increases the number of cases where detection is performed in the designated narrow band, which is more effective in determining whether or not to continue tracking.

  Further, in the above-described embodiment, the case where the division filter 1122 has the functional configuration illustrated in FIG. 3 has been described as an example. However, the functional configuration of the division filter 1122 is not limited to that shown in FIG. For example, the division filter 1122 may include a switch 11224 as illustrated in FIG. The switch 11224 receives the wideband detection results A to D from the detectors 11223-1 to 11223-4, and outputs any of the wideband detection results to the signal processing unit 113 according to the switching signal from the control unit 1124. At this time, the control unit 1124 generates a switching signal so that the switch 11224 outputs the wideband detection results A to D to the signal processing unit 113 at a predetermined timing and order. Note that the timing and order in which the wideband detection results A to D are output are not limited.

  As described above, when the division filter 1122 includes the switch 11224, the connection line between the reception unit 112 and the signal processing unit 113 can be reduced. That is, the hardware scale in the radio wave receiver 11 can be reduced.

  Although the embodiment of the present invention has been described, this embodiment is presented as an example and is not intended to limit the scope of the invention. This embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. These embodiments and their modifications are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 10 ... Guidance device 11 ... Radio wave receiving device 111 ... Reception wideband antenna 112 ... Reception part 1121 ... RF receiver 1122 ... Divided filter 11221 ... Divider 11222-1 to 11222-4 ... Filter 11223-1 to 11223-4 ... Detection Unit 11224 ... Switch 1123 ... IF receiver 1124 ... Control unit 113 ... Signal processing unit 1131 ... Signal converter 1132 ... Detection processor 1133 ... Signal analysis processor 12 ... Target tracking device 20 ... Steering device

Claims (8)

An antenna for receiving radio waves,
An RF receiver that narrows the received signal received by the antenna by a designated wide band that is assumed to include a frequency hopping signal, and converts the narrowed received signal into an IF signal in an IF band;
A division filter that performs amplitude detection on an RF signal whose band is narrowed by the RF receiver, and generates a wideband detection result;
The IF signal from the RF receiver is narrowed down by a designated narrow band designated among the bands obtained by dividing the IF signal, and the narrowed IF signal is subjected to amplitude detection and phase detection to generate a narrow band detection result. An IF receiver,
A first detection process for the received signal is performed by video integrating the high band detection result, and a second detection for the received signal is performed by performing FFT (Fast Fourier Transform) on the narrow band detection result. A radio wave receiving apparatus comprising: a detection processor that performs processing.   It further comprises a signal analysis processor that refers to the results of the first and second detection processes in the detection processor and determines whether or not a frequency hopping signal is included in the received signal. The radio wave receiver according to claim 1. The split filter is
A distribution unit that distributes an RF signal from the RF receiver to a plurality of connection lines;
Each of the plurality of connection lines is connected to each of the plurality of connection lines, and one of the bands obtained by dividing the RF signal is designated as a pass band. A pass signal that passes through the pass band among the RF signals from the distribution unit Multiple filters to output,
Amplitude detection is performed on the passing signals from the plurality of filters, and a detector for generating a broadband detection result for each passing signal is provided.
The signal analysis processor includes:
When the received signal is continuously detected in the designated narrow band by the second detection process, it is determined that the received signal does not include a frequency hopping signal;
When the received signal is not continuously detected in the designated narrow band due to the second detection result, and the received signal is randomly detected in the plurality of pass bands by the first detection process. The radio wave receiver according to claim 2, wherein the received signal is determined to include a frequency hopping signal.   2. The radio wave receiving apparatus according to claim 1, wherein the width of the designated narrow band is a width capable of uniquely obtaining the frequency of the IF signal.   4. The radio wave receiving apparatus according to claim 3, wherein the division filter further includes a switch that outputs a wideband detection result for each of the passing signals generated by the detector at a timing and an order according to an instruction. The antenna receives radio waves,
The received signal received by the antenna by the RF receiver is narrowed down by a designated wide band assumed to include a frequency hopping signal,
The RF receiver converts the narrowed reception signal into an IF signal in the IF band,
The division filter performs amplitude detection on the RF signal whose band is narrowed by the RF receiver, and generates a wideband detection result,
By the IF receiver, the IF signal from the RF receiver is narrowed down by a designated narrow band designated among the bands obtained by dividing the IF signal,
By the IF receiver, the narrowed IF signal is subjected to amplitude detection and phase detection to generate a narrowband detection result,
A detection processor performs a first detection process on the received signal by video integrating the high-band detection result,
A signal analysis method characterized in that the detection processor performs a second detection process on the received signal by performing FFT (Fast Fourier Transform) on the narrowband detection result.   The signal analysis processor determines whether or not a frequency hopping signal is included in the received signal with reference to the results of the first and second detection processes in the detection processor. 6. The signal analysis method according to 6. The split filter is
The distribution unit distributes the RF signal from the RF receiver to a plurality of connection lines,
A pass signal that has passed through the pass band among the RF signals distributed from the distribution unit to the plurality of connection lines is output by a plurality of filters in which one of the bands obtained by dividing the RF signal is designated as a pass band. ,
The detector performs amplitude detection on the passing signals from the plurality of filters, and generates a broadband detection result for each passing signal,
The signal analysis processor includes:
When the received signal is continuously detected in the designated narrow band by the second detection process, it is determined that the received signal does not include a frequency hopping signal;
When the received signal is not continuously detected in the designated narrow band due to the second detection result, and the received signal is randomly detected in the plurality of pass bands by the first detection process. The signal analysis method according to claim 7, wherein it is determined that the received signal includes a frequency hopping signal.

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