WO2022254709A1 - Communication traffic analysis device, control circuit, storage medium, and communication traffic analysis method - Google Patents

Abstract

This communication traffic analysis device (20) comprises: a signal section calculation unit (21) which calculates a first signal section group from waveform information on radio waves including signals; a signal section correction unit (22) which corrects the first signal section group and generates a second signal section group; and a communication traffic information calculation unit (23) which calculates communication traffic information by using the second signal section group.

Description

Communication traffic analysis device, control circuit, storage medium, and communication traffic analysis method

The present disclosure relates to a communication traffic analysis device, control circuit, storage medium, and communication traffic analysis method for analyzing communication traffic.

　Conventionally, analysis of communication traffic flowing on the network has been performed. In Patent Document 1, for communication traffic flowing on a network, an application state is estimated from time-series data such as throughput, packet data size, and packet arrival interval, and information input from multiple time-series data of communication traffic. A technique for improving estimation accuracy by selecting is disclosed.

WO2019/176997

As in resource control in wireless communication, when monitoring the communication status of wireless communication devices operating in the surrounding area and analyzing the communication traffic, the results are utilized for wireless communication resource allocation. It is conceivable to analyze communication traffic information by estimating signal intervals and the like. However, according to the above conventional technology, packets on a wired network are targeted. Therefore, it does not take into account the drop in signal level due to multipath fading that accompanies the movement of the transceiver, the noise generated at the receiver, etc., and observation errors are included in time-series data such as signal time and signal interval, resulting in incorrect communication. There was a problem that traffic analysis could not be performed.

In general, the amplitude of the signal contained in the observed radio waves fluctuates greatly due to multipath fading, etc., and also oscillates in small cycles due to thermal noise of the receiver. When the signal section is determined by comparing the signal amplitude and the threshold value, if the signal amplitude is near the threshold value in most of the signal section, the signal section detection result includes many instantaneous interruptions in the signal section and the signal time is short. , and a large number of signal intervals with small signal intervals are generated. Further, when the signal amplitude is greatly reduced in a part of the signal section, the detection result of the signal section includes the divided signal. In this way, when a signal section is detected in a state including a momentary interruption of a signal, a division of a signal, etc., the signal time and signal interval, which are communication traffic information, become short, and the accuracy of communication traffic analysis is lowered.

The present disclosure has been made in view of the above, and aims to obtain a communication traffic analysis apparatus capable of improving the accuracy of communication traffic analysis for signals included in radio waves.

In order to solve the above-described problems and achieve the object, the communication traffic analysis device of the present disclosure includes a signal section calculation unit that calculates a first signal section group from waveform information of radio waves including signals; characterized by comprising a signal section correction unit that corrects a signal section group and generates a second signal section group, and a communication traffic information calculation section that calculates communication traffic information using the second signal section group. do.

The communication traffic analysis device according to the present disclosure has the effect of improving the accuracy of communication traffic analysis for signals included in radio waves.

FIG. 1 shows a configuration example of a communication system including a communication traffic analysis device according to Embodiment 1; 4 is a flow chart showing the operation of the communication traffic analysis device according to the first embodiment; FIG. 4 is a diagram showing an example of signal sections corrected by the signal section correcting unit of the communication traffic analysis apparatus according to the first embodiment; FIG. 4 is a diagram showing a configuration example of a processing circuit provided in the communication traffic analysis apparatus according to the first embodiment when the processing circuit is realized by a processor and a memory; FIG. 4 is a diagram showing an example of a processing circuit provided in the communication traffic analysis apparatus according to the first embodiment when the processing circuit is configured with dedicated hardware; FIG. 10 is a diagram showing a configuration example of a communication traffic analysis device according to a second embodiment;

A communication traffic analysis device, a control circuit, a storage medium, and a communication traffic analysis method according to embodiments of the present disclosure will be described below in detail with reference to the drawings.

Embodiment 1.
FIG. 1 is a diagram showing a configuration example of a communication system 40 including a communication traffic analysis device 20 according to Embodiment 1. As shown in FIG. A communication system 40 includes a receiving device 10 , a communication traffic analysis device 20 and a host device 30 . The receiving device 10 receives radio waves including signals via an antenna (not shown) and outputs waveform information of the received radio waves to the communication traffic analysis device 20 . The communication traffic analysis device 20 analyzes communication traffic information based on the radio wave waveform information acquired from the receiving device 10 and outputs the analysis result to the host device 30 . Based on the analysis results obtained from the communication traffic analysis device 20, the host device 30 allocates wireless resources, monitors resource usage of wireless communication, and the like.

The configuration and operation of the communication traffic analysis device 20 will be explained. As shown in FIG. 1 , the communication traffic analysis device 20 includes a signal section calculator 21 , a signal section corrector 22 and a communication traffic information calculator 23 . The signal section correction section 22 includes a first coupling section 221 and a second coupling section 222 . FIG. 2 is a flow chart showing the operation of the communication traffic analysis device 20 according to the first embodiment.

In the communication traffic analysis device 20, the signal section calculator 21 calculates a first signal section group including one or more first signal sections i from the waveform information of radio waves including signals. Specifically, the signal interval calculation unit 21 acquires waveform information of radio waves including the signal that has passed through the low-pass filter from the receiving device 10 . Waveform information may be a combination of in-phase and quadrature components of a signal after quasi-quadrature detection, but is not limited to this. If the receiving device 10 does not allow radio waves to pass through the low-pass filter, the signal interval calculation unit 21 may cause the radio waves to pass through the low-pass filter. The signal interval calculator 21 converts the acquired waveform information of the radio wave into amplitude information or power information of the waveform (step S1).

The signal section calculator 21 calculates the first signal section i of the signal included in the radio wave based on the amplitude information or power information of the converted waveform (step S2). Specifically, the signal section calculator 21 performs threshold determination on the converted waveform amplitude information or power information to calculate the first signal section i. The threshold value used here may be a preset value or a value calculated by the signal interval calculator 21 . The method of calculating the threshold value in the signal interval calculating unit 21 is, for example, a method of calculating from the probability distribution of values assuming that the noise component of the signal follows a certain distribution such as a normal distribution, and the result of performing a Fourier transform. A method of calculating from the maximum and minimum values of the spectrum can be considered, but is not limited to these.

For the first signal interval i calculated by the signal interval calculator 21, for example, when N+1 signals are detected, the rise time Tu1 _i of the signal corresponding to each calculated first signal interval i, It is expressed by a combination including two or more values of the fall time Td1 _i and the signal time L _i indicating the length of the first signal interval i. Note that i=0, 1, . . . , N. Since these three values have a relationship of fall time Td1 _i =rise time Tu1 _i +signal time L _i , the remaining one value can be calculated if two of the three values are included. be. Hereinafter, as an example, a combination of the rise time Tu1 _i and the fall time Td1 _i will be used for explanation, but it is also possible to use a combination of other values. The signal section calculator 21 outputs information of the calculated first signal section group including one or more first signal sections i to the signal section corrector 22 . In this manner, the signal section calculator 21 performs threshold determination on the waveform information of radio waves including the signal that has passed through the low-pass filter, and calculates the first signal section group.

The signal section correction unit 22 corrects the first signal section group and generates a second signal section group. Specifically, the signal section correcting unit 22 combines the first signal sections i that satisfy the specified conditions among the first signal sections i included in the first signal section group, and generates the second signal. A second signal interval p included in the interval group is generated.

In the signal interval correction unit 22, first, the first coupling unit 221 calculates the rise time Tu1 _i and the fall time of each first signal interval i included in the first signal interval group acquired from the signal interval calculation unit 21. From the combination of Td1 _i , the signal time L _i (i=0, 1, . A signal interval D _i (i=1, . . . , N), which is the time from i−1, is calculated (step S3). Signal interval D _i is calculated by signal interval D _i =rise time Tu1 _i -fall time Td1 _i−1 . It should be noted that the first combining unit 221 omits the process of calculating the signal time _Li when the information of the first signal interval group acquired from the signal interval calculating unit 21 includes the information of the signal time _Li . can do.

The first combining unit 221 determines whether the signal duration _Li is equal to or less than the first threshold and the signal interval _Di is equal to or less than the second threshold for each first signal section i (step S4 ). Specifically, the first combiner 221 compares the signal time _Li with a first threshold and the signal interval _Di with a second threshold for each first signal interval i. If the signal time _Li is less than or equal to the first threshold and the signal interval _Di is less than or equal to the second threshold (step S4: Yes), the first combiner 221 combines the first signal section i and the previous time period. is combined with the first signal section i−1 of (step S5). A signal interval in which the first signal intervals are combined is called a third signal interval j. If at least one of the signal time _Li is greater than the first threshold and the signal interval _Di is greater than the second threshold (step S4: No), the first coupling unit 221 performs the first and the first signal section i−1 of the previous time period are not combined, and the process of step S5 is omitted.

Here, the first threshold value may be a preset value or a value calculated by the first combining unit 221 . When the first threshold is calculated by the first combiner 221, for example, the first combiner 221 estimates the transmission rate from the result of estimating the communication bandwidth of the signal and the result of estimating the modulation scheme. , the first threshold is calculated from a preset minimum transmission data unit. Also, the first combiner 221 selects the first transmission data unit from the preset minimum transmission data unit based on the result of estimating the communication bandwidth of the signal and the transmission rate estimated from the preset maximum value of the spectral efficiency. A threshold of 1 may be calculated. For the second threshold, it is conceivable to use a preset minimum value of the signal interval _Di.

The first combining unit 221 repeats the processes of steps S4 and S5 for all the first signal intervals i for which the signal time L _i and the signal interval D _i have been calculated in step S3. Thereby, the first combiner 221 obtains a combination of the rise time Tu3 _j and the fall time Td3 _j for the third signal interval j. Note that j=0, 1, . . . , M and M≦N. The first combiner 221 combines the rise time Tu3 _j and the fall time Td3 _j for the third signal section j together with the rise time Tu1 _i for the first signal section i obtained from the signal section calculator 21 . and the fall time Td1 _i to the second coupling unit 222 .

In the signal interval correction unit 22, the second coupling unit 222 then receives from the first coupling unit 221 the combination of the rise time Tu1 _i and the fall time Td1 _i for the first signal interval i, and a third and a combination of rise time Tu3 _j and fall time Td3 _j for signal interval j of . The second combiner 222 compares the signal sections before and after the processing of the first combiner 221, that is, compares the first signal section i and the third signal section j (step S6). Specifically, the second coupling unit 222 outputs the third _signal interval _j is divided into a plurality, here K. The second combining unit 222 calculates the number _{x k} of first signal intervals i before processing by the first combining unit 221, which are included in each interval k obtained by dividing the third signal interval j into K pieces. . Note that k=1, 2, . . . , K. The second combining unit 222 targets the combination of the third signal section j and the third signal section j+1, which are the preceding and succeeding signal sections, for the third signal section j after the processing of the first combining section 221. , the bias of the number x _k of the first signal intervals i in the third signal interval j and the third signal interval j+1.

Regarding the method of comparing the biases, for example, x _K /Σx _k in the third signal interval j is greater than or equal to a preset threshold, and x ₁ /Σx _k in the third signal interval j+1 is similarly preset. Another possible method is to set the condition to be equal to or greater than a threshold. Note that the range of Σx _k is from k=1 to K. Here, when dividing the third signal section j into K pieces, the width of the divided section k varies depending on the signal time _Lj of the original third signal section j. Therefore, for the method of comparing the biases, for example, (x _K−1 +x _K )/Σx _k in the third signal interval j is equal to or greater than a preset threshold, and (x ₁ +x ₂ )/Σx _k is also equal to or greater than a preset threshold value, the number of post-division sections k targeted in the numerator may be appropriately changed.

The second coupling unit 222 compares the imbalances under the conditions as described above, and finds that there are many instantaneous interruptions before and after the signal division in the third signal section j and the third signal section j+1, which are the signal sections before and after the signal section. It is possible to detect the occurrence, and to detect signal division when the signal amplitude is significantly reduced due to multipath fading. That is, the second coupling unit 222 combines the third signal section j and the third signal It can be determined that the signal was divided between the section j+1. If the comparison condition as described above is satisfied, that is, if there is an imbalance in the distribution of momentary interruptions in the preceding and succeeding third signal section j and the third signal section j+1 (step S7: Yes), the second coupling section 222 combines the preceding and succeeding third signal intervals, namely the third signal interval j and the third signal interval j+1 (step S8). The signal interval in which the third signal intervals are combined is called the second signal interval p. If the comparison condition as described above is not satisfied, that is, if there is no imbalance in the distribution of momentary interruptions in the preceding and subsequent third signal section j and the third signal section j+1 (step S7: No), the second coupling unit 222 does not combine the preceding and succeeding third signal intervals, that is, the third signal interval j and the third signal interval j+1, and omits the processing of step S8.

The second combining unit 222 repeats the processing from step S6 to step S8 for all the third signal sections j. Thereby, the second combiner 222 obtains a combination of the rise time Tu2 _p and the fall time Td2 _p for the second signal interval p. Note that p=0, 1, . . . , P and P≦M. The second combiner 222 outputs a combination of the rise time Tu2 _-p and the fall time Td2- _p for each second signal section p to the communication traffic information calculator 23 as information of the second signal section group.

The communication traffic information calculation unit 23 obtains the rise time Tu2 _p and the fall time Td2 for each second signal interval p from the second coupling unit 222, that is, the signal interval correction unit 22, as second signal interval group information. Get the combination of _p . The communication traffic information calculation unit 23 uses the second signal section group, that is, the combination of the rise time Tu2 _p and the fall time Td2 _p for each second signal section p to calculate the signal section, the signal interval D _p , the signal Communication traffic information such as minimum value, maximum value, average value, and dispersion for amplitude and the like to be used by the host device 30 is calculated (step S9). The communication traffic information calculator 23 outputs the calculated communication traffic information to the host device 30 .

Here, the signal section corrected by the signal section correction unit 22 of the communication traffic analysis device 20 will be described. FIG. 3 is a diagram showing an example of signal sections corrected by the signal section correction unit 22 of the communication traffic analysis apparatus 20 according to the first embodiment. FIG. 3(a) shows an example in which waveform information of radio waves received by the receiving device 10 is represented by amplitude information. The amplitude of the signal contained in the radio waves fluctuates greatly due to multipath fading and the like, and further oscillates in small cycles due to thermal noise of the receiving device 10 and the like. When a signal section is determined by a threshold value of signal amplitude, if the signal amplitude is near the threshold value in most of the signal section (Fig. 3(b)), the detection result of the signal section contains many momentary interruptions in the signal section. , a large number of signal intervals with small signal times and signal intervals (FIG. 3(c)). Also, when the signal amplitude drops significantly in a part of the signal section ((d) in FIG. 3), the detection result of the signal section includes a plurality of signal sections in which one originally divided signal section ((e) in FIG. 3). )).

In the signal section correction unit 22, the first coupling unit 221 corrects the momentary interruption of the signal as shown in FIGS. 3(b) and 3(c). That is, the first combining unit 221 determines that the signal time L _i in the first signal section i is equal to or less than the first threshold and the signal interval _D i from the first signal section i−1 in the previous time zone. is less than or equal to the second threshold, the first signal interval i whose signal time L _i is less than or equal to the first threshold is combined with the first signal interval i−1 of the previous time period to obtain a third signal interval generate j. In addition, the second coupling section 222 corrects the division of the signal as shown in FIGS. 3(d) and 3(e). In other words, the second coupling unit 222 selects the adjacent third signal section j and the third signal section j+1 in the third signal section j if there is an imbalance in instantaneous interruption that satisfies the conditions specified. The third signal interval j and the third signal interval j+1 are combined to generate the second signal interval p.

Next, the hardware configuration of the communication traffic analysis device 20 will be explained. In the communication traffic analysis device 20, the signal interval calculator 21, the signal interval corrector 22, and the communication traffic information calculator 23 are implemented by processing circuits. The processing circuitry may be a processor and memory executing programs stored in the memory, or may be dedicated hardware. Processing circuitry is also called control circuitry.

FIG. 4 is a diagram showing a configuration example of the processing circuit 90 when the processing circuit included in the communication traffic analysis device 20 according to Embodiment 1 is realized by the processor 91 and the memory 92. As shown in FIG. A processing circuit 90 shown in FIG. 4 is a control circuit and includes a processor 91 and a memory 92 . When the processing circuit 90 is composed of the processor 91 and the memory 92, each function of the processing circuit 90 is implemented by software, firmware, or a combination of software and firmware. Software or firmware is written as a program and stored in memory 92 . In the processing circuit 90, each function is realized by the processor 91 reading and executing the program stored in the memory 92. FIG. That is, the processing circuit 90 has a memory 92 for storing a program that results in the processing of the communication traffic analysis device 20 being executed. This program can also be said to be a program for causing the communication traffic analysis device 20 to execute each function realized by the processing circuit 90 . This program may be provided by a storage medium storing the program, or may be provided by other means such as a communication medium.

The program includes a first step in which the signal interval calculation unit 21 calculates a first signal interval group from waveform information of a radio wave including a signal, and a signal interval correction unit 22 corrects the first signal interval group. Then, the second step of generating the second signal interval group and the third step of calculating the communication traffic information by the communication traffic information calculation unit 23 using the second signal interval group are performed in the communication traffic analysis. It can also be said that it is a program executed by the device 20 .

Here, the processor 91 is, for example, a CPU (Central Processing Unit), a processing device, an arithmetic device, a microprocessor, a microcomputer, or a DSP (Digital Signal Processor). In addition, the memory 92 is a non-volatile or volatile memory such as RAM (Random Access Memory), ROM (Read Only Memory), flash memory, EPROM (Erasable Programmable ROM), EEPROM (registered trademark) (Electrically EPROM), etc. A semiconductor memory, a magnetic disk, a flexible disk, an optical disk, a compact disk, a mini disk, or a DVD (Digital Versatile Disc) is applicable.

FIG. 5 is a diagram showing an example of the processing circuit 93 when the processing circuit included in the communication traffic analysis device 20 according to the first embodiment is configured with dedicated hardware. The processing circuit 93 shown in FIG. 5 is, for example, a single circuit, a composite circuit, a programmed processor, a parallel programmed processor, an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or a combination thereof. thing applies. The processing circuit may be partly implemented by dedicated hardware and partly implemented by software or firmware. Thus, the processing circuitry may implement each of the functions described above through dedicated hardware, software, firmware, or a combination thereof.

As described above, according to the present embodiment, in the signal section correction unit 22 of the communication traffic analysis device 20, the first combining unit 221 corrects the detection result of the signal whose signal level is near the threshold value, The second combiner 222 corrects the detection result for a signal that is largely split due to multipath fading. Thus, when receiving radio waves, the communication traffic analysis apparatus 20 can improve the accuracy of communication traffic analysis for signals included in the radio waves.

Embodiment 2.
In the first embodiment, the case where communication traffic analysis device 20 is connected to receiving device 10 and host device 30 has been described. In the second embodiment, a case will be described where the communication traffic analysis device 20 has a reception function, an application classification function, etc., and outputs analysis results to a cooperating device.

FIG. 6 is a diagram showing a configuration example of the communication traffic analysis device 20a according to the second embodiment. The communication traffic analysis device 20 a includes a receiver 24 , a signal section calculator 21 , a signal section corrector 22 , a communication traffic information calculator 23 and an application classifier 25 .

The receiving unit 24 receives radio waves with an antenna (not shown), performs processing such as band limitation, down-conversion, and analog-to-digital conversion on the received analog signal, which is the radio wave, and converts it into a digital signal. It is converted into signal information by performing detection processing. The receiving unit 24 outputs the converted signal information to the signal interval calculating unit 21 .

The processing contents of the signal interval calculation unit 21, the signal interval correction unit 22, and the communication traffic information calculation unit 23 are the same as those in the first embodiment.

The application classification unit 25 classifies the communication traffic information acquired from the communication traffic information calculation unit 23 . As for the classification method in the application classification unit 25, a method using a preset threshold value is conceivable. As for the classification method in the application classification unit 25, a model is learned by inputting possible parameters in advance by a method such as a k-nearest neighbor method, a decision tree, a neural network, or the like, which is a multi-class classification method based on machine learning. It is also conceivable to implement by performing multi-class classification.

The hardware configuration of the communication traffic analysis device 20a will be explained. In the communication traffic analysis device 20a, the receiving section 24 is implemented by a receiving circuit. The signal interval calculation unit 21, the signal interval correction unit 22, the communication traffic information calculation unit 23, and the application classification unit 25 are implemented by processing circuits. The processing circuit may be processor 91 and memory 92 for executing programs stored in memory 92, as shown in FIGS. , may be dedicated hardware.

As described above, according to the present embodiment, the communication traffic analysis device 20a includes the reception unit 24 and the application classification unit 25, thereby outputting highly accurate application classification results to the cooperating devices. can be done.

The configurations shown in the above embodiments are only examples, and can be combined with other known techniques, or can be combined with other embodiments, without departing from the scope of the invention. It is also possible to omit or change part of the configuration.

10 receiver, 20, 20a communication traffic analysis device, 21 signal section calculator, 22 signal section corrector, 23 communication traffic information calculator, 24 receiver, 25 application classifier, 30 host device, 40 communication system, 221 th 1 connecting portion, 222 second connecting portion.

Claims (14)

1. a signal interval calculation unit that calculates a first signal interval group from waveform information of radio waves including signals;
   a signal section correction unit that corrects the first signal section group to generate a second signal section group;
   a communication traffic information calculation unit that calculates communication traffic information using the second signal interval group;
   A communication traffic analysis device comprising:
2. The signal interval calculation unit performs threshold determination on waveform information of radio waves including the signal that has passed through the low-pass filter, and calculates the first signal interval group.
   2. The communication traffic analysis device according to claim 1, wherein:
3. The signal section correcting unit combines the first signal sections that satisfy a specified condition among the first signal sections included in the first signal section group, and includes the first signal sections in the second signal section group. generating a second signal interval that is
   3. The communication traffic analysis device according to claim 1 or 2, characterized in that:
4. The signal section correction unit is
   When the signal time in the first signal section is equal to or less than the first threshold and the signal interval from the first signal section in the previous time period is equal to or less than the second threshold, the signal time is equal to or less than the first threshold. a first combiner that combines the first signal interval below a threshold of and the first signal interval of a previous time period to generate a third signal interval;
   Among the third signal intervals, if there is a bias in momentary interruption that satisfies the conditions defined in the adjacent third signal intervals, the adjacent third signal intervals are combined to generate the second signal. a second joint that produces an interval;
   4. The communication traffic analysis device according to claim 3, comprising:
5. The first combining unit calculates the first threshold based on a transmission rate estimated from an estimation result of a communication bandwidth of the signal and an estimation result of a modulation scheme.
   5. The communication traffic analysis device according to claim 4, wherein:
6. The first combining unit calculates the first threshold value based on the estimation result of the communication bandwidth of the signal and the transmission rate estimated from the set spectral efficiency.
   5. The communication traffic analysis device according to claim 4, wherein:
7. A control circuit for controlling a communication traffic analysis device,
   calculating a first signal interval group from waveform information of radio waves including signals;
   correcting the first group of signal intervals to generate a second group of signal intervals;
   calculating communication traffic information using the second signal interval group;
   A control circuit that causes the communication traffic analysis device to execute:
8. A storage medium storing a program for controlling a communication traffic analysis device,
   Said program
   calculating a first signal interval group from waveform information of radio waves including signals;
   correcting the first group of signal intervals to generate a second group of signal intervals;
   calculating communication traffic information using the second signal interval group;
   is executed by the communication traffic analysis device.
9. A first step in which the signal interval calculation unit calculates a first signal interval group from waveform information of radio waves including signals;
   a second step in which a signal section correction unit corrects the first group of signal sections to generate a second group of signal sections;
   a third step in which a communication traffic information calculation unit calculates communication traffic information using the second signal interval group;
   A communication traffic analysis method comprising:
10. In the first step, the signal interval calculation unit performs threshold determination on waveform information of radio waves including the signal that has passed through the low-pass filter, and calculates the first signal interval group.
    10. The communication traffic analysis method according to claim 9, characterized by:
11. In the second step, the signal section correction unit combines the first signal sections satisfying a specified condition among the first signal sections included in the first signal section group, and generating a second signal interval included in the group of 2 signal intervals;
    11. The communication traffic analysis method according to claim 9 or 10, characterized by:
12. the signal section correction unit comprises a first coupling unit and a second coupling unit;
    The second step includes
    When the signal duration of the first signal section is equal to or less than a first threshold and the signal interval from the first signal section in the previous time zone is equal to or less than a second threshold , a first combining step of combining said first signal interval in which said signal time is equal to or less than said first threshold and said first signal interval of a previous time period to produce a third signal interval;
    In the case where the second coupling section has an imbalance of momentary interruptions that satisfy the conditions specified in the adjacent third signal intervals among the third signal intervals, the adjacent third signal intervals are connected to each other. a second combining step of combining to produce said second signal interval;
    12. The communication traffic analysis method according to claim 11, comprising:
13. In the first combining step, the first combining unit calculates the first threshold value based on a transmission rate estimated from a communication bandwidth estimation result of the signal and a modulation scheme estimation result. ,
    13. The communication traffic analysis method according to claim 12, wherein:
14. In the first combining step, the first combining unit calculates the first threshold value based on a communication bandwidth estimation result of the signal and a transmission rate estimated from the set spectral efficiency. ,
    13. The communication traffic analysis method according to claim 12, wherein:

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