JP2017122685A - Electromagnetic information leakage evaluation device, electromagnetic information leakage evaluation method, and electromagnetic information leakage evaluation processing program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To properly estimate the frequency of an electromagnetic wave containing screen information and the drawing frequency of the screen information.SOLUTION: An electromagnetic information leakage evaluation device in an embodiment comprises an estimation section that, when a frequency satisfying a predetermined condition and having a high electric field strength level is present, in a frequency spectrum obtained by analysing a signal of frequency components in a predetermined bandwidth of an electromagnetic wave emitted from a display device as an estimation object of the drawing frequency of screen information, either in the vicinity of a first frequency represented by a product of horizontal direction resolution of the screen information displayed on the display device and a refreshing rate of the screen information or in the vicinity of a second frequency represented by a product of vertical direction resolution and the refreshing rate, estimates a frequency corresponding to a peak of the electric field strength level as candidate for the drawing frequency, and estimates the predetermined bandwidth as candidate for the frequency of the electromagnetic wave containing the screen information.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to an electromagnetic information leakage evaluation apparatus, an electromagnetic information leakage evaluation method, and an electromagnetic information leakage evaluation processing program.

  The threat of electromagnetic wiretapping that obtains information from weak electromagnetic waves radiated from electronic devices has been pointed out. For example, the threat of screen snooping using leaked electromagnetic waves from display devices has been a concern. This threat of screen snooping is particularly a concern for stationary displays with relatively high electromagnetic wave strength.

  When the interface for transferring screen information to a display device is a conventional analog interface, the screen is displayed as a bit string of analog voltage values including luminance information in the device or in the wiring connecting the display device and the electronic device. Information is transmitted. When there is a color change or color shading on the screen, the above-mentioned analog voltage value changes, so that there is a possibility that an electromagnetic field is generated and is radiated to the outside as a so-called electromagnetic wave.

  In most cases, the leakage electromagnetic wave radiated to the outside (far) is a harmonic component of an electromagnetic field generated by the change in the analog voltage value. For this reason, a leaked electromagnetic wave is received by an antenna, detected, and demodulated, whereby a bit string of analog voltage values including the original screen information can be obtained. Furthermore, this bit string is input to the RGB input terminal of the monitor corresponding to the analog interface, and the vertical synchronization signal and the horizontal synchronization signal specific to the display device to be screened are simultaneously input, so that the display screen contents can be changed. Can be reproduced (see, for example, Non-Patent Document 1).

  The analog interface is an interface for a CRT display (CRT display) that performs drawing by a raster scan method. Even in the mainstream LCD displays (liquid crystal displays), many displays have an analog interface in order to maintain interface compatibility.

  Also in an LCD display using a digital interface, the liquid crystal driver IC performs D / A conversion, drives the liquid crystal with a voltage value corresponding to the number of bits, and a portion where these data are processed and transmitted serially. Present in the device. For this reason, there is a possibility that electromagnetic waves including screen information may leak from the liquid crystal driving unit, and there is a concern about the threat of screen snooping as with a display having an analog interface.

  In addition, with the development of mobile terminals in recent years, smartphones and tablet terminals having a touch screen function are rapidly spreading. These are frequently used in public spaces where third parties exist, and the chances of browsing confidential information on the screen are increasing, increasing the risk of eavesdropping.

Yasuo Suzuki, Kimihiro Tajima, Masao Masugi, Hiroshi Yamane, “Technology for Countermeasures against Information Leakage due to Electromagnetic Waves Eradiated from PC”, NTT Technical Journal (August 2008), p.11-15, November 30, 2015 Search, Internet <URL: http://www.ntt.co.jp/journal/0808/files/jn200808011.pdf>

  As a countermeasure against such information leakage, it is conceivable to block electromagnetic waves leaking from electronic devices. However, normally, when an electromagnetic wave radiated from an electronic device equipped with a display is received by an antenna, the received electromagnetic wave includes a signal component generated inside the electronic device and a harmonic component of this signal component. And has a wide frequency component. That is, since a frequency component not related to the display screen on the display is also received, it is difficult to specify only the frequency component related to the display screen on the display and block it.

  Therefore, in order to implement countermeasures against the threat of screen snooping via leaked electromagnetic waves, it is necessary to take measures such as shielding to block broadband electromagnetic waves. This is difficult.

  In addition, if the frequency corresponding to the screen information is known in the leaked electromagnetic wave, it is possible to take measures against blocking the target frequency range. In the first place, there is a method for evaluating whether screen information is leaked from electronic devices, There has been no method for appropriately evaluating which frequency band should be taken against leakage when information is leaked.

  An object of the present invention is to provide an electromagnetic information leakage evaluation apparatus, an electromagnetic information leakage evaluation method, and an electromagnetic information leakage evaluation processing program capable of appropriately estimating the frequency of electromagnetic waves including screen information and the drawing frequency of screen information. It is to be.

  In order to achieve the above object, a first aspect of an electromagnetic information leakage evaluation apparatus according to an embodiment of the present invention includes an antenna unit that inputs an electromagnetic wave radiated from a display device that is an estimation target of a drawing frequency of screen information. A bandpass filter unit that outputs a signal of a frequency component of a predetermined band for the electromagnetic wave input by the antenna unit, a detection demodulator unit that detects and demodulates the signal output by the bandpass filter unit, and the detection demodulator unit A frequency characteristic confirmation unit that obtains a frequency spectrum by performing a fast Fourier transform on the signal output from the display, and in the frequency spectrum, a horizontal resolution of screen information displayed on the display device and a refresh rate of the screen information In the vicinity of the first frequency indicated by the product, or the vertical resolution of the screen information displayed on the display device; When a frequency that satisfies a predetermined condition and has a high electric field intensity level exists in the vicinity of the second frequency indicated by the product of the refresh rate, the frequency corresponding to the peak of the electric field intensity level is set to the drawing frequency. An apparatus is provided that includes an estimation unit that estimates as a candidate and estimates the predetermined band as a frequency candidate of an electromagnetic wave including the screen information.

  According to a second aspect of the electromagnetic information leakage evaluation apparatus configured as described above, in the first aspect of the electromagnetic information leakage evaluation apparatus, the display in which the horizontal resolution, the vertical resolution, and the refresh rate are unknown. A storage device that stores a plurality of horizontal resolution candidates, a vertical resolution candidate, and a refresh rate candidate of the screen information displayed on the device; In the vicinity of the first frequency indicated by the product of the horizontal resolution belonging to any of the patterns stored in the storage device and the refresh rate belonging to the pattern, or the vertical resolution and the pattern belonging to the pattern In the vicinity of the second frequency indicated by the product of the refresh rate belonging to An apparatus for estimating a frequency corresponding to a peak of the electric field strength level as a candidate for the drawing frequency and estimating the predetermined band as a candidate for a frequency of an electromagnetic wave including the screen information when a frequency having the electric field strength level exists. I will provide a.

  A first aspect of an electromagnetic information leakage evaluation method according to an embodiment of the present invention is a method applied to an electromagnetic information leakage evaluation device, and is emitted from a display device that is an estimation target of a drawing frequency of screen information. Input an electromagnetic wave, output a signal of a frequency component of a predetermined band for the input electromagnetic wave, detect and demodulate the output signal, and perform a fast Fourier transform on the detected and demodulated signal to obtain a frequency spectrum. In the frequency spectrum, it is displayed near the first frequency indicated by the product of the horizontal resolution of the screen information displayed on the display device and the refresh rate of the screen information, or displayed on the display device. In the vicinity of the second frequency indicated by the product of the vertical resolution of the screen information and the refresh rate, a high electric field strength level satisfying a predetermined condition is set. If frequency is present, the electric field strength level frequency corresponding to the peak is estimated as a candidate of the drawing frequency, provides a method for estimating a predetermined band as a candidate for a frequency of an electromagnetic wave including the screen information.

  The second aspect of the electromagnetic information leakage evaluation method is the first aspect of the electromagnetic information leakage evaluation method, in which the electromagnetic information leakage evaluation device includes the horizontal resolution, the vertical resolution, and the A storage device for storing a plurality of patterns of horizontal resolution candidates, vertical resolution candidates, and refresh rate candidates of screen information displayed on the display device with an unknown refresh rate; In the frequency spectrum, in the vicinity of the first frequency indicated by the product of the horizontal resolution belonging to any pattern stored in the storage device and the refresh rate belonging to the pattern, or the vertical resolution belonging to the pattern And the predetermined frequency in the vicinity of the second frequency indicated by the product of the refresh rate belonging to the pattern. If there is a frequency that satisfies the condition and has a high electric field strength level, the frequency corresponding to the peak of the electric field strength level is estimated as the drawing frequency candidate, and the predetermined band is the frequency of the electromagnetic wave including the screen information. A method of estimating as a candidate is provided.

  An aspect of the electromagnetic information leakage evaluation processing program according to the embodiment of the present invention is a program used in a computer that operates as a part of the electromagnetic information leakage evaluation apparatus according to the first aspect, and the computer includes the antenna unit, A program for causing the band-pass filter unit, the detection demodulation unit, the frequency characteristic confirmation unit, and the estimation unit to function is provided.

  According to the present invention, it is possible to appropriately estimate the frequency of electromagnetic waves including screen information and the drawing frequency of screen information.

The figure explaining the structure of the electromagnetic information leakage evaluation apparatus in the 1st Embodiment of this invention. The flowchart which shows an example of the processing operation by the electromagnetic information leakage evaluation apparatus in the 1st Embodiment of this invention. The figure which shows an example of the database which registered the resolution and the refresh rate pattern of the screen information of a display terminal used with the electromagnetic information leakage evaluation apparatus in the 2nd Embodiment of this invention in a table format. The flowchart which shows an example of the processing operation by the electromagnetic information leakage evaluation apparatus in the 2nd Embodiment of this invention.

Embodiments according to the present invention will be described below.
(First embodiment)
First, the first embodiment will be described.
In the first embodiment, only the frequency component of the electromagnetic wave including the screen information is specified from the frequency component of the electromagnetic wave radiated from the display device (display device).
In the first embodiment, an electromagnetic wave radiated from the display device is acquired, the acquired electromagnetic wave is detected and demodulated, and the presence or absence of a specific frequency component is confirmed. When screen information is included in the acquired electromagnetic wave, a drawing frequency signal can be observed by detecting and demodulating the electromagnetic wave.
Data related to screen information displayed on the display device has a periodicity depending on the resolution. For this reason, in a frequency channel in which information is leaked, periodicity is observed in the demodulated data. Therefore, a frequency having this periodicity is called a drawing frequency. This drawing frequency corresponds to the horizontal synchronization signal of the analog interface.
Therefore, by analyzing the signal after detection and demodulation, and examining the frequency component near the frequency calculated from the resolution and refresh rate of the screen information in the analyzed signal, the screen information is included in the acquired electromagnetic wave. It can be estimated whether or not.

Next, a specific example of the first embodiment will be described.
FIG. 1 is a diagram for explaining the configuration of an electromagnetic information leakage evaluation apparatus according to the first embodiment of the present invention.
As shown in FIG. 1, the electromagnetic information leakage evaluation apparatus according to the first embodiment determines whether or not screen information is included in an electromagnetic wave radiated from a target display terminal 10 that is an estimation target of a screen information drawing frequency. The antenna unit 11, the amplifier unit 12, the band pass filter unit (BPF) 13, the detection demodulation unit 14, the frequency characteristic confirmation unit (spectrum monitor) 15, the control unit 16, and the storage device 17 are evaluated.

The antenna unit 11 receives as wide an electromagnetic wave as possible radiated from the target display terminal 10. The amplifier unit 12 amplifies the radio wave signal received by the antenna unit 11 to a level sufficient for subsequent processing. The band pass filter unit 13 passes only a signal having a specific frequency component among the radio wave signals amplified by the amplifier unit 12.
The detection demodulation unit 14 detects and demodulates the signal that has passed through the band pass filter unit 13.
The frequency characteristic confirmation unit 15 obtains a frequency spectrum which is a signal in the frequency domain by performing FFT (Fast Fourier Transform) analysis on the signal input from the detection demodulation unit 14, and displays the frequency spectrum on a built-in monitor. .
The control unit 16 controls the frequency band of the signal passing through the bandpass filter unit 13 and the frequency confirmed by the frequency characteristic confirmation unit 15, and records the measurement result and the measurement progress status in the storage device 17. The storage device 17 is a storage medium such as a nonvolatile memory.
The above-described configuration may be configured by either hardware or software, and may be configured by using functions of devices such as a spectrum analyzer and a personal computer.

Next, a procedure for specifying a candidate for an electromagnetic wave frequency including screen information and a candidate for a drawing frequency in the electromagnetic wave radiated from the target display terminal 10 will be described. FIG. 2 is a flowchart showing an example of a processing operation performed by the electromagnetic information leakage evaluation apparatus according to the first embodiment of the present invention.
First, the control unit 16 knows that the horizontal resolution of the screen of the target display terminal 10 is X (dpi), the vertical resolution is Y (dpi), and the screen refresh rate is Z (Hz). , The provisional candidate values of the drawing frequency of the screen information, the frequencies f1 and f2 that are so-called rough candidate values are calculated, and the calculated f1 and f2 are set in the frequency characteristic confirmation unit 15, and Recording is performed in the storage device 17 (S1).
f1 is obtained by X × Z, and f2 is obtained by Y × Z. Regarding f1 and f2, separately calculated values may be recorded in advance in the storage device 17 without depending on the control unit 16.

Next, the control unit 16 records these values in the storage device 17 with the lower limit value of the frequency range measured by the frequency characteristic confirmation unit 15 as fl and the upper limit value as fh. fl and fh are set within a range supported by an electromagnetic information leakage evaluation apparatus as a measurement component to be used.
Further, the control unit 16 sets the initial value of the center frequency fm in the frequency band of the electromagnetic wave radiated from the target display terminal 10 to pass through the band-pass filter unit 13 as the above lower limit value fl, and sets this value as the band. It sets in the pass filter part 13 and the frequency characteristic confirmation part 15, and records it on the memory | storage device 17 (S2). The frequency fm is a center frequency of a frequency band having a predetermined width.

  Next, an arbitrary image is displayed on the target display terminal 10 (S3). Note that the image displayed on the target display terminal 10 is not a white noise screen, but an image that can be determined to be significant by human vision, such as characters and figures.

  Next, the antenna unit 11 receives the electromagnetic waves radiated from the target display terminal 10. The received radio wave is amplified by the amplifier unit 12 and then passes through the bandpass filter unit 13 so that only the signal of the frequency component belonging to the band of the predetermined width from the center frequency fm set as described above. Is transmitted to the detection demodulator 14 (S4). The detection demodulator 14 detects and demodulates the signal input from the bandpass filter 13 (S5).

  Next, the frequency characteristic confirmation unit 15 obtains a frequency domain signal by performing FFT analysis on the signal obtained in S5 (S6), and obtains this signal from the lower limit value fl set as described above. It is displayed on the built-in monitor within the range of the upper limit value fh.

  Then, the frequency characteristic confirmation unit 15 has a frequency component having a higher electric field strength in the vicinity of the frequency f1 set in S1 or in the vicinity of the frequency f2 than the electric field strength level of other frequency bands in the displayed signal. Is checked (S7). The electric field strength level in the other frequency band mentioned here refers to a value obtained by averaging electric field strength levels in a predetermined frequency range with a frequency separated by a frequency determined from f1 or f2.

  If there is a frequency component having an electric field strength level higher than Adb in the vicinity of the frequency f1 or f2 in comparison with the electric field strength level of other frequency bands (Yes in S7), the frequency characteristic confirmation unit 15 The center frequency fm set from 16 is estimated as a candidate of the frequency of the electromagnetic wave including the screen information radiated from the target display terminal 10, and the value of this frequency is recorded in the storage device 17. A is a detection threshold and may be arbitrarily determined.

Furthermore, if there is a frequency component having an electric field strength level higher than Adb in comparison with the electric field strength level of other frequency bands in the vicinity of the frequency f1, the frequency characteristic confirmation unit 15 sets the peak electric field strength in this frequency component. The frequency having the frequency is estimated as a candidate for the drawing frequency of the screen information included in the electromagnetic wave emitted from the target display terminal 10, and the value of this frequency is recorded in the storage device 17.
In addition, if there is a frequency component having an electric field strength level higher than Adb in comparison with the electric field strength in other frequency bands in the vicinity of the frequency f2, the frequency characteristic confirmation unit 15 has the peak electric field strength in this frequency component. The frequency is estimated as the drawing frequency candidate, and the value of this frequency is recorded in the storage device 17 (S8).

  If the electric field strength level of the frequency in the vicinity of the frequencies f1 and f2 is not higher than Adb after S8 (No in S7), the frequency characteristic confirmation unit 15 Information is notified to the control unit 16. Receiving this notification, the control unit 16 changes the center frequency fm of the passband by the bandpass filter unit 13 to fm + α (S9). α is a measurement step and may be arbitrarily determined. The control unit 16 sets the changed center frequency fm in the band pass filter unit 13 and the frequency characteristic confirmation unit 15 and records it in the storage device 17.

Next, the control unit 16 compares fm changed in S9 with fh recorded in the storage device 17. If fm> fh is not satisfied (No in S10), the operation proceeds to S4 and subsequent operations based on the center frequency fm changed in S9. If the currently set center frequency fm> fh (Yes in S10), the control unit 16 ends the process.
When the electromagnetic wave frequency candidate including the screen information and the drawing frequency candidate have not been recorded at S8, the frequency characteristic confirmation unit 15 confirms that the leakage electromagnetic wave including the image information is not confirmed. A message or the like may be displayed on a built-in monitor.

Through the above procedure, it is possible to estimate the candidate for the frequency of the electromagnetic wave including the screen information and the candidate for the drawing frequency of the screen information.
In S <b> 1, based on the specifications of the target display terminal 10, the frequencies f <b> 1 and f <b> 2, which are provisional candidate values of the drawing frequency, as approximate estimates of the drawing frequency are the operations of the clock IC used by the target display terminal 10. There is a high possibility that the screen cannot be reconstructed based on the leaked electromagnetic wave of this frequency without considering the frequency variation. Therefore, in order to reconstruct the screen based on the leaked electromagnetic wave, it is necessary to specify the drawing frequency of the target display terminal 10 that is the leak source with high accuracy.
On the other hand, if the method described in the first embodiment is used, a frequency having a high electric field strength level in the vicinity of the frequencies f1 and f2 is calculated based on electromagnetic waves leaked from the target display terminal 10 that is actually operating. Since it can be estimated as a drawing frequency candidate, the drawing frequency candidate can be estimated with sufficient accuracy for reconstructing the screen based on the leaked electromagnetic wave.

  By implementing the first embodiment of the present invention, it is possible to estimate the frequency of an electromagnetic wave including screen information and the estimation of a drawing frequency in a short time, and it is possible to evaluate a risk and take measures against a threat of snooping. Can be easily considered.

(Second Embodiment)
Next, a second embodiment will be described. In addition, the description similar to 1st Embodiment in this embodiment is abbreviate | omitted.
In the first embodiment, various resolutions and refresh rates of the screen information of the target display terminal 10 are known, and based on these, provisional candidate values f1 and f2 are obtained as approximate values of the drawing frequency. . However, if the resolution of the screen information of the target display terminal 10 is unknown, even if the signal after detection and demodulation is subjected to FFT analysis and a high level frequency component is observed, whether or not this frequency component is related to the screen information. Therefore, the method described in the first embodiment cannot be used as it is.
Therefore, in the second embodiment, a database in which a plurality of types of patterns having general resolutions and refresh rates adopted by display terminals distributed in the market are registered in the storage device 17. Then, for each of the patterns registered in the database, the method described in the first embodiment is performed to estimate the electromagnetic wave frequency candidate including the screen information and the drawing frequency candidate.

Next, a specific example of the second embodiment will be described.
First, in the second embodiment, a database in which a plurality of resolution patterns including a general resolution and a refresh rate of screen information used for display terminals distributed in the market are registered in advance in the storage device 17.

The control unit 16 can use the patterns registered in the database for estimation of electromagnetic wave frequency candidates including screen information and drawing frequency candidates. Since the resolution of the display terminal is standardized, the types of patterns are limited. Therefore, it is easy to collect information in advance. FIG. 3 is a table showing an example of a database in which resolution and refresh rate patterns of display terminal screen information used in the electromagnetic information leakage evaluation apparatus according to the second embodiment of the present invention are registered.
Information necessary for configuring a resolution pattern to be registered in the database is a vertical resolution, a horizontal resolution, and a refresh rate.

  The control unit 16 selects any one unselected resolution pattern among the resolution patterns A, B, C... Registered in the database (S21). Here, it is assumed that the resolution pattern A shown in FIG. 3 is selected.

  In this case, the control unit 16 uses the horizontal resolution X, the vertical resolution Y, and the refresh rate Z belonging to the selected resolution pattern A to provisionally set the screen information drawing frequency in the target display terminal 10. Frequency f1 and f2 that are candidate values are calculated in the same manner as in the first embodiment, and the calculated value is set in the frequency characteristic confirmation unit 15 (S1a). Thereafter, S2 to S10 described in the first embodiment can be similarly performed.

  If the answer is Yes in S10, that is, if the currently set center frequency fm> fh and before all resolution patterns registered in the database have been selected (No in S22), the process goes to S21. Return.

Moreover, if it is after finishing selecting all the resolution patterns registered in the database (Yes of S22), the control part 16 will complete | finish a process.
When the electromagnetic wave frequency candidate including the screen information and the drawing frequency candidate have not been recorded at S8, the frequency characteristic confirmation unit 15 confirms that the leakage electromagnetic wave including the image information is not confirmed. A message or the like may be displayed on a built-in monitor.

As described above, in the second embodiment of the present invention, it is possible to quickly estimate the electromagnetic wave frequency candidate including the screen information and the drawing frequency candidate for the display terminal whose resolution and refresh rate are unknown. It becomes. Therefore, it is possible to easily evaluate the risk and examine countermeasures against the threat of eavesdropping.
The database used in the present embodiment may be recorded in a memory in the control unit 16 or may be stored on a network.

  According to each of the embodiments described above, it is possible to estimate a candidate for an electromagnetic wave frequency including screen information and a candidate for a drawing frequency in a short time, and various display terminals and displays exposed to the threat of screen snooping. With regard to the interface, it becomes possible to easily evaluate the risk and examine countermeasures against the threat of eavesdropping.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

  In addition, the method described in each embodiment is, for example, a magnetic disk (floppy (registered trademark) disk, hard disk, etc.), optical disk (CD-ROM, etc.) as a program (software means) that can be executed by a computer (computer). It can be stored in a recording medium such as a DVD, MO, etc., semiconductor memory (ROM, RAM, flash memory, etc.), or transmitted and distributed by a communication medium. The program stored on the medium side includes a setting program that configures software means (including not only the execution program but also a table and data structure) in the computer. A computer that implements this apparatus reads a program recorded on a recording medium, constructs software means by a setting program as the case may be, and executes the above-described processing by controlling the operation by this software means. The recording medium referred to in this specification is not limited to distribution, but includes a storage medium such as a magnetic disk or a semiconductor memory provided in a computer or a device connected via a network.

  DESCRIPTION OF SYMBOLS 10 ... Target display terminal, 11 ... Antenna part, 12 ... Amplifier part, 13 ... Band pass filter part, 14 ... Detection demodulation part, 15 ... Frequency characteristic confirmation part, 16 ... Control part, 17 ... Memory | storage device.

Claims (5)

An antenna unit that inputs electromagnetic waves radiated from a display device that is an estimation target of a drawing frequency of screen information;
A band pass filter unit that outputs a signal of a frequency component of a predetermined band for the electromagnetic wave input by the antenna unit;
A detection and demodulation unit for detecting and demodulating the signal output by the bandpass filter unit;
A frequency characteristic confirmation unit that obtains a frequency spectrum by performing a fast Fourier transform on the signal output from the detection demodulation unit;
In the frequency spectrum, the vicinity of the first frequency indicated by the product of the horizontal resolution of the screen information displayed on the display device and the refresh rate of the screen information, or the screen information displayed on the display device When a frequency that satisfies a predetermined condition and has a high electric field intensity level exists in the vicinity of the second frequency indicated by the product of the vertical resolution and the refresh rate, the frequency corresponding to the peak of the electric field intensity level And an estimation unit for estimating the predetermined band as a candidate for the frequency of the electromagnetic wave including the screen information. The horizontal resolution candidate, the vertical resolution candidate, and the refresh rate candidate of the screen information displayed on the display device for which the horizontal resolution, the vertical resolution, and the refresh rate are unknown. A storage device for storing a plurality of patterns;
The estimation unit includes
In the frequency spectrum, in the vicinity of the first frequency indicated by the product of the horizontal resolution belonging to any pattern stored in the storage device and the refresh rate belonging to the pattern, or in the vertical direction belonging to the pattern When a frequency satisfying a predetermined condition and having a high electric field intensity level exists in the vicinity of the second frequency indicated by the product of the resolution and the refresh rate belonging to the pattern, the frequency corresponding to the peak of the electric field intensity level The electromagnetic information leakage evaluation apparatus according to claim 1, wherein the estimation is performed as a candidate for the drawing frequency, and the predetermined band is estimated as a candidate for a frequency of an electromagnetic wave including the screen information. A method applied to an electromagnetic information leakage evaluation device,
Input the electromagnetic wave radiated from the display device for which the drawing frequency of screen information is estimated,
Output a signal of a frequency component of a predetermined band for the input electromagnetic wave,
Detecting and demodulating the output signal,
A frequency spectrum is obtained by fast Fourier transforming the detected and demodulated signal,
In the frequency spectrum, the vicinity of the first frequency indicated by the product of the horizontal resolution of the screen information displayed on the display device and the refresh rate of the screen information, or the screen information displayed on the display device When a frequency that satisfies the predetermined condition and has a high electric field strength level exists in the vicinity of the second frequency indicated by the product of the vertical resolution and the refresh rate, this corresponds to the peak of the electric field strength level. An electromagnetic information leakage evaluation method, wherein a frequency is estimated as a drawing frequency candidate, and the predetermined band is estimated as a frequency candidate of an electromagnetic wave including the screen information. The electromagnetic information leakage evaluation device includes a horizontal resolution candidate of the screen information displayed on the display device whose resolution in the horizontal direction, the vertical resolution and the refresh rate are unknown, and a resolution in the vertical direction. A storage device for storing a candidate and a plurality of patterns of the refresh rate candidate;
In the frequency spectrum, in the vicinity of the first frequency indicated by the product of the horizontal resolution belonging to any pattern stored in the storage device and the refresh rate belonging to the pattern, or in the vertical direction belonging to the pattern When a frequency satisfying the predetermined condition and having a high electric field intensity level exists in the vicinity of the second frequency indicated by the product of the resolution and the refresh rate belonging to the pattern, this corresponds to the peak of the electric field intensity level. The electromagnetic information leakage evaluation method according to claim 3, wherein a frequency is estimated as the drawing frequency candidate, and the predetermined band is estimated as a frequency candidate of an electromagnetic wave including the screen information. A program used for a computer operating as a part of the electromagnetic information leakage evaluation apparatus according to claim 1,
The computer,
The electromagnetic information leakage evaluation processing program for functioning as said antenna part, said band pass filter part, said detection demodulation part, said frequency characteristic confirmation part, and said estimation part.