JP2023120937A - Encrypted signal generation device, encrypted signal decryption system, encrypted signal generation method, and encrypted signal decryption method - Google Patents

Abstract

To provide a novel mechanism for encrypted signal generation and decryption.SOLUTION: An encrypted signal generation device 1 includes: an encrypted signal generation unit 5 that generates an electrical signal corresponding to an encrypted signal; a wave generator unit 10 having a first wave generator 11 and a second wave generator 12 disposed facing the first wave generator 11 at a predetermined distance apart; and a signal amplifier 13 that transmits an encrypted electrical signal transmitted from the encrypted signal generation device 1 to the first wave generator 11, and transmits an encrypted electrical signal that is out of a phase with or in phase with the encrypted electrical signal to the second wave generator 12. The encrypted signal generation device generates waves corresponding to the encrypted signal by transmitting the above encrypted signals to the respective first wave generator 11 and second wave generator 12.SELECTED DRAWING: Figure 4

Description

The present invention relates to an encrypted signal generator, an encrypted signal decoding system, an encrypted signal generating method, and an encrypted signal decoding method.

Conventionally, for example, as in Patent Document 1, an inverse piezoelectric material having an optically smooth surface for incidence and emission of a light beam and transparency to light, and this inverse piezoelectric material An optical deflector composed of a pair of electrodes for supplying power is known.

Further, as in Patent Document 2, a group of information to be transmitted is divided into predetermined constituent elements, different fundamental periods corresponding to the predetermined constituent elements are assigned, and analog waveforms having different fundamental periods are generated. A signal generation method is known in which signals are continuously arranged one cycle at a time to generate a non-periodic continuous signal.

Japanese Patent Publication No. 59-31044 Japanese Patent No. 6656648

Encrypted signal generators of various configurations are used, but there is a need for novel configurations that are different from conventional encrypted signal generators.

There is also a need for an encrypted signal generation method using a non-periodic continuous signal as in Patent Document 2 and a decryption method thereof.

The present invention has been made in view of the above points, and an object of the present invention is to provide a novel mechanism for generating an encrypted signal. Another object is to provide a novel mechanism for decoding an encrypted signal.

In order to achieve the above object, the present invention arranges a pair of wave generators to send encrypted electrical signals of the same phase or different phases to each.

Specifically, the encrypted signal generator of the first invention is
an encrypted signal generator that generates an electrical signal corresponding to the encrypted signal;
a wave generator unit having a first wave generator and a second wave generator disposed facing the first wave generator at a predetermined distance;
The encrypted electrical signal transmitted from the encrypted signal generator is transmitted to the first wave generator, and the encrypted electrical signal out of phase with or in phase with the encrypted electrical signal is transmitted to the second wave generator. a signal amplifier that transmits to the wave generator;
By transmitting the encrypted electrical signals to the first wave generator and the second wave generator, respectively, waves corresponding to the encrypted signals are generated.

According to the above configuration, by generating waves (hereinafter referred to as electromagnetic waves, sound waves, etc.) respectively corresponding to the encrypted signals in the pair of wave generators, the antinodes where the waves overlap and the nodes where the waves weaken each other. , and by decoding the distribution pattern, a decryptable encrypted signal can be generated. The phase-shifted encrypted signals may be shifted by 1/4 wavelength or 1/8 wavelength as well as the opposite phase.

In the second invention, in the first invention,
Each of the first wave generator and the second wave generator is entirely or partially made of crystal.

According to the above configuration, it is possible to cause oscillation with high frequency accuracy using the inverse piezoelectric effect of crystal. Therefore, a new encryption mechanism can be formed.

In a third invention, in the first invention,
Each of the first wave generator and the second wave generator comprises a crystal plate and a pair of electrodes supporting the crystal plate.

According to the above configuration, an electromagnetic wave is generated with a stable radiation pattern, so the distribution pattern of the electromagnetic wave can be accurately measured.

In a fourth invention, in any one of the first to third inventions,
A plurality of wave generator units are arranged such that the plate-like first wave generator and the plate-like second wave generator are separated by a predetermined width in the thickness direction, and the thickness direction is parallel to the tangent line of the circle. , are circumferentially spaced apart.

According to the above configuration, a stable anti-node and node distribution pattern can be easily formed by appropriately arranging the anti-node and node distribution patterns, and the anti-node and node distribution patterns due to the complex interference of waves generated from a plurality of wave generator units can be used. can form a new cryptographic scheme.

In the fifth invention, in the fourth invention,
A plurality of wave generator units are arranged in a regular N-sided shape with N equal intervals in the circumferential direction,
When the width in the thickness direction between the first wave generator and the second wave generator of the first wave generator unit is W1,
The width Wn at the n-th vertex is
Wn=W1×(N+n−1)/N
is represented by

According to the above configuration, a new encryption scheme can be formed by utilizing the distribution pattern of antinodes and nodes resulting from complex interference of waves generated from a plurality of wave generator units.

In the sixth invention, in the fifth invention,
Assuming that the difference width between the n-th width Wn and the n+1-th width Wn+1 is ΔW,
ΔW=W1/N
is.

According to the above configuration, the distribution pattern of antinodes and nodes due to interference of waves generated from a plurality of wave generator units becomes more complicated, so variations in the encryption mechanism can be formed.

In a seventh invention, in any one of the first to sixth inventions,
A pattern for scanning a spatial distribution pattern of constructive antinode portions and destructive node portions between the first wave generated from the first wave generator and the second wave generated from the second wave generator. a scanning device;
and a pattern storage device storing a pattern code correspondence table storing patterns scanned by the pattern scanning device by the number of encrypted codes.

According to the above configuration, it is possible to obtain an optimal encrypted signal decryption system capable of decrypting an encrypted signal using a pair of wave generators.

In the eighth invention, in the seventh invention,
Pattern comparison for comparing the spatial distribution pattern scanned by the pattern scanning device with the pattern code correspondence table in a state in which the encrypted signals are transmitted to the first wave generator and the second wave generator, respectively. a processor;
and a decoding device for decoding based on the result of comparison by the pattern comparison processing device.

According to the above configuration, if a pattern code adaptation table corresponding to the arrangement of wave generators is prepared, it can be compared by the pattern comparison processing device and decrypted by the decryption device. can be formed.

The encrypted signal generation method of the ninth invention comprises:
generating an electric signal corresponding to the encrypted signal from the encrypted signal generator;
For a wave generator unit having a first wave generator and a second wave generator arranged facing the first wave generator at a predetermined distance,
The encrypted electrical signal transmitted from the encrypted signal generator is transmitted to the first wave generator, and the encrypted electrical signal out of phase with or in phase with the encrypted electrical signal is transmitted to the second wave generator. send to the wave generator,
By transmitting the encrypted electrical signals to the first wave generator and the second wave generator, respectively, waves corresponding to the encrypted signals are generated.

According to the above configuration, a pair of wave generators generate waves corresponding to the respective encrypted signals, thereby generating an antinode portion where the waves overlap and a node portion where the waves weaken each other. Decryption can generate a decryptable encrypted signal.

In the tenth invention, in the ninth invention,
The pattern scanning device detects the pattern of the spatial distribution of the antinode portion and the node portion that weaken each other between the first wave generated from the first wave generator and the second wave generated from the second wave generator. and scan with
A pattern code correspondence table is created in which patterns scanned by the pattern scanning device are stored for the number of encrypted codes.

According to the above configuration, a new encryption scheme can be formed by preparing a pattern code adaptation table that matches the arrangement of the wave generators.

In the eleventh invention, in the tenth invention,
In a state in which the encrypted signals are transmitted to the first wave generator and the second wave generator respectively, the pattern of the spatial distribution scanned by the pattern scanning device is compared with the pattern code correspondence table, and the result of the comparison is obtained. Decrypt based on

According to the above configuration, the pattern comparison processing device can compare and the decryption device can decrypt, so a new encryption mechanism can be formed.

In the twelfth invention, in the tenth or eleventh invention,
Preparing patterns of spatial distribution of antinodes and nodes generated by waves at a frequency of one period of an encryption code corresponding to a predetermined component as a pattern code correspondence table;
dividing the group of information to be transmitted into the predetermined constituent elements by the encrypted signal generating unit, and assigning separate fundamental periods corresponding to the predetermined constituent elements, respectively;
A non-periodic continuous signal is generated by successively arranging the analog waveforms having different fundamental periods one by one.

According to the above configuration, the information group to be transmitted is divided into predetermined constituent elements, and the basic period (one period of the periodic signal, the time code) is applied to each of the constituent elements, thereby developing the data on the time axis. becomes possible. In other words, the difference in information is expressed relatively using only the length of time. If the analog waveform is, for example, a pulse wave, information can be conveyed with a minimal number of pulses instead of digital. An aperiodic continuous signal is a signal in which one period of a waveform with different frequencies is continuous, that is, a signal that does not repeat itself after a specified time interval. This allows the generation of an encrypted signal of linguistic information and its decryption.

As described above, according to the present invention, it is possible to provide a novel mechanism for generating and decoding encrypted signals.

It is a perspective view which shows an encryption signal generator. It is a top view which shows an encryption signal generator. It is a front view which shows an encryption signal generator. 2 is a schematic diagram showing the internal configuration of an encrypted signal generator; FIG. 3 is a block diagram showing a schematic configuration of a receiving section; FIG. It is a front view which shows a wave generator unit. FIG. 4 is a side view showing a wave generator unit; FIG. 4 is a diagram showing the arrangement of antinodes and nodes when in-phase encrypted signals are generated from first and second wave generators; FIG. 4 is a diagram showing the arrangement of antinodes and nodes when anti-phase encrypted signals are generated from first and second wave generators; FIG. 4 is an explanatory diagram showing an example of allocation of reference times and reference frequencies; FIG. 2 is a diagram for explaining an aperiodic continuous signal, where (a) is a time code (time band), (b) is a sine wave, and (c) is a pulse wave. FIG. 4 is a conceptual diagram regarding the arrangement of wave generators when four wave generator units are arranged;

BEST MODE FOR CARRYING OUT THE INVENTION An embodiment of the present invention will be described below with reference to the drawings.

1 to 3 show an encrypted signal generator 1 according to an embodiment of the present invention. This encrypted signal generator 1 includes a box-shaped storage case 2 made of, for example, a transparent acrylic cast plate. I have. The storage case 2 is not provided with a part of the side surfaces (for example, the front surface and the rear surface), and has an atrium structure. Inside the housing case 2, a side surface of a rectangular parallelepiped device housing case 3 made of aluminum alloy or the like is fixed with a flat sign nut 4 or the like.

Although not shown in detail, the apparatus storage case 3 is connected to an electric wire to be connected to an external power supply (AC power supply) or the like, and an encrypted signal generator 5 is provided inside. It is preferable to extend the electric wire from a portion of the storage case 2 without side walls (for example, the rear surface) toward the external power source. The encrypted signal generator 5 can generate an encrypted signal such as an aperiodic continuous signal, which will be described later. The shape and material of the housing of the encrypted signal generator 1 are not limited to this.

For example, five wave generator units 10 are provided on the top surface of the device housing case 3 . This number may be any number as long as it is one or more. 6 and 7, the wave generator unit 10 is arranged facing the first wave generator 11 and separated from the first wave generator 11 by a predetermined width. It has a second wave generator 12 . This predetermined width may be the same for all the wave generator units 10, or may be set differently, for example, as described later with reference to FIG. The first wave generator 11 and the second wave generator 12 are wholly or partially made of a crystal plate. For example, the first wave generator 11 may be a right-handed crystal and the second wave generator 12 may be a left-handed crystal, or both may be a right-handed crystal or a left-handed crystal. A pattern 6 corresponding to the arrangement of the wave generator units 10 may be provided on the top surface of the storage case 2 by laser engraving or the like.

A pair of electrodes 14 are connected to the first wave generator 11 and the second wave generator 12 by silver paste, solder, or the like, and a signal amplifier 13 is connected to each of the electrodes 14 . The signal amplifier 13 is composed of an electronic circuit including, for example, transistors. For example, copper wires or the like constituting the electrodes 14 are inserted into and supported by a plurality of disk-shaped support plates 15 made of resin or the like. Although not shown in detail, an LED may be provided at an arbitrary position on the support plate 15 so as to emit light as appropriate.

Then, the encrypted electric signal transmitted from the encrypted signal generator 5 is transmitted to the first wave generator 11, and the phase of the encrypted electric signal is out of phase with or in phase with the encrypted electric signal. It is configured to transmit to the two wave generator 12 . When the phase is shifted by a half wavelength, that is, in the case of the opposite phase, it is easy to grasp the positions of the antinode and node of the wave, but the shift may be by 1/4 wavelength or 1/8 wavelength, for example. The signal amplifier 13 may be provided inside the device storage case 3 outside the wave generator unit 10 as shown in FIG. 4, or may be provided inside the wave generator unit 10 (not shown).

The first wave generator 11 and the second wave generator 12 are fixed to the electrode 14 and the support plate 15 and covered with a bottom cap 16 and a transparent, translucent or colored opaque glass cap 17 having a circular cross section. However, it is advantageous to be more insensitive to temperature and humidity if, for example, it is sealed in a vacuum.

By transmitting the encrypted signals to the first wave generator 11 and the second wave generator 12 respectively, waves corresponding to the encrypted signals are generated in the respective units.

In this embodiment, oscillation with high frequency precision can be generated using the inverse piezoelectric effect of crystal. The first wave generator 11 and the second wave generator 12 may be disc-shaped crystals instead of rectangular plate-shaped crystals, and may be other vibration-generating members such as metals and piezoelectric ceramics. However, any material that exhibits an inverse piezoelectric effect is conceivable.

In this embodiment, two electrodes support a wave generator made of one crystal plate. It acts like a so-called dipole antenna and generates weak electromagnetic waves. This electromagnetic wave can be measured by the receiving unit 30, which will be described later.

For example, as shown in FIG. 12, the plurality of wave generator units 10 are arranged such that plate-like first wave generators 11 and second wave generators 12 are spaced apart by a predetermined width in the thickness direction. They are spaced circumferentially so that they are parallel to the tangent of the circle. By arranging a plurality of wave generator units 10 in this way, an encrypted signal can be easily and effectively generated.

The encrypted signal decryption system of this embodiment includes the encrypted signal generator 1 described above and a receiver 30 for receiving the encrypted signal generated by the encrypted signal generator 1. The receiver 30 includes: The following are possible.

As shown in FIG. 5, the receiving section 30 is configured so that the first wave generated from the first wave generator 11 and the second wave generated from the second wave generator 12 constructively and destructively interact with each other. An electromagnetic field scanning device 31 is provided as a pattern scanning device for scanning the spatial distribution pattern of the node portion. When measuring the generated electromagnetic wave, for example, a general-purpose three-dimensional electromagnetic wave measurement system may be used.

The receiving unit 30 further includes an electromagnetic field pattern storage device 32 as a pattern storage device for storing a pattern code correspondence table 34 in which the patterns scanned by the electromagnetic field scanning device 31 are arranged for the number of encrypted codes.

Further, the receiving unit 30 stores the pattern of the spatial distribution scanned by the electromagnetic field scanning device 31 in the pattern code correspondence table 34 while transmitting the encrypted signals to the first wave generator 11 and the second wave generator 12 respectively. An electromagnetic field pattern comparison processing device 33 is provided for processing by comparison with. The electromagnetic field pattern comparison processor 33 actually scans the spatial distribution of the "antinodes" where the electromagnetic waves generated from the wave generator unit 10 strengthen each other and the "nodes" where the electromagnetic waves generated from the wave generator unit 10 weaken each other. The obtained result is compared with the pattern code correspondence table 34 stored in the electromagnetic field pattern storage device 32 to select the corresponding encryption code.

The receiving unit 30 also includes a decoding device 35 for decoding based on the result of comparison by the electromagnetic field pattern comparison processing device 33 . The decoding device 35 decodes the code into characters, etc., corresponding to the encrypted code through comparison by the electromagnetic field pattern comparison processing device 33, and arranges information such as the decoded characters to decode the encrypted signal.

For example, the configurations of the electromagnetic field pattern storage device 32, the electromagnetic field pattern comparison processing device 33, and the decoding device 35 are not particularly limited, and may be composed of, for example, electronic circuits, PCs (personal computers), servers, and the like.

The result of decoding by the decoding device 35 can be displayed on a display output device 36 such as a liquid crystal display. It is desirable to record the result of decryption on a recording medium or the like as appropriate for post-processing.

- Arrangement position of multiple wave generator units -
Next, an example of a method for determining the arrangement positions of the plurality of wave generator units 10 will be described.

First, as shown in FIG. 12, a regular N-sided polygon tangent to a circle C of arbitrary size is prepared. The number of vertices is N, and the respective vertices are represented by V1 to VN. Numbering is uniquely determined clockwise or counterclockwise from any vertex on the circumference.

At each vertex V1 to VN, a tangent line to the circle C is taken, and the first wave generator 11 and the second wave generator 12 are arranged on the tangent line.

The thickness direction of the first wave generator 11 and the second wave generator 12 and the tangent line of the circle are parallel, and the surface direction component of the first wave generator 11 and the second wave generator 12 and the tangent line of the circle are perpendicular to each other. Deploy. Also, the first wave generator 11 and the second wave generator 12 are arranged so that the center point of each intersection at the point of contact is located on the circumference of the circle C. As shown in FIG.

The first wave generator 11 on the right side facing the center of the circle is XR, the second wave generator 12 on the left side when facing the center of the circle is XL, XR corresponding to the n-th vertex Vn is XRn, and similarly XL. be XLn. At this time, the width between XRn and XLn is Wn.

When a plurality of wave generator units 10 are arranged at equal intervals in the circumferential direction in a regular N-sided shape, the width of the wave generator unit 10 at the first vertex V1 in the thickness direction (arbitrary ) is the basic width W1, the width Wn at the n-th vertex is
Wn=W1×(N+n−1)/N
is represented by

Then, if the difference width between the n-th width Wn and the n+1-th width Wn+1 is ΔW,
ΔW=W1/N
becomes.

For example, as shown in FIG. 12, when N=4 and W1=10 mm, the difference ΔW is 10/4=2.5 mm, W2=12.5 mm, W3=15.0 mm, W4=17. .5 mm. In this manner, the width between the first wave generator 11 and the second wave generator 12 in each wave generator unit 10 can be easily calculated, and the proper arrangement of the wave generator units 10 can be easily performed. can.

-Operation of Encrypted Signal Generator 1-
Next, the operation of the encrypted signal generator 1 according to this embodiment will be described with reference to FIGS. 8 and 9. FIG.

First, a method for generating an encrypted signal will be described. Encrypted signal generating section 5 for wave generator unit 10 having first wave generator 11 and second wave generator 12 arranged opposite to first wave generator 11 at a predetermined distance from first wave generator 11 , to the first wave generator 11, and to the second wave generator 12, the encrypted electric signal having the same phase as the encrypted electric signal.

By transmitting the encrypted signals to the first wave generator 11 and the second wave generator 12, respectively, waves (for example, electromagnetic waves) corresponding to the encrypted signals are generated.

For example, in the first wave generator 11 and the second wave generator 12 in one wave generator unit 10, the state of waves at a given moment is as shown in FIG. The solid-line circles represent peaks of the waveform generated from each wave generator, and the dashed-line circles represent the troughs of the waveform. The points where peaks of the waveforms intersect and the points where the valleys of the waveforms intersect are indicated by black dots as reinforcing points, and the points of intersection between the peaks of the waveform and the valleys of the waveform are indicated by white points as weakening points. The belly portion connecting the black dots is indicated by a very thick line, and the node portion connecting the white lines is indicated by a thinner thick line. In reality, the areas indicated by these extra thick lines and thick lines each have a three-dimensional spread as curved surfaces.

When the first wave generator 11 and the second wave generator 12 transmit opposite-phase signals, the positions of the extra-thick line and the thick line are switched as shown in FIG.

When the wave generator is made of crystal, it may be affected by temperature and humidity, but the influence can be reduced by keeping the inside of them in a vacuum state with the bottom cap 16 and the glass cap 17. By doing so, it becomes easier to stably obtain one spatial distribution pattern for one frequency signal.

Even when five wave generator units 10 are arranged as shown in FIG. Instead, the waves generated from the wave generator units 10 strengthen and weaken each other.

Although the details of the simulation results are omitted, the spatial distribution pattern corresponding to the arrangement of the five wave generator units 10 is fixed, and one spatial distribution pattern exists for a signal of a certain frequency. I know it. When a plurality of wave generator units 10 are arranged, the spatial distribution pattern generated by the plurality of wave generator units 10 becomes more complicated than the pattern of the spatial distribution generated by one wave generator unit 10 . The advantage is that the pattern code correspondence table 34 can be prepared for many kinds of amplitudes.

－Example of Encrypted Signal－
In the encrypted signal generation procedure shown in FIG. 10, first, an information group to be transmitted is divided into predetermined constituent elements. When the information group to be transmitted is linguistic information, the linguistic information is divided into predetermined components, consonants and vowels. To simplify the explanation, the information group to be transmitted is described below as an example of language information, but the information group to be transmitted is not limited to language information.

Specifically, when there is linguistic information "sora" as shown in FIG. 10, it is divided into consonants "S" and "L" and vowels "o" and "a".

A separate fundamental period is then assigned to each of the predetermined components. In the case of the linguistic information of FIG. 10, separate fundamental periods are assigned to consonants and vowels respectively. Details will be described later, but for example, according to a predetermined rule, 0.028 seconds for "S", 0.15 seconds for "O", 0.02 seconds for "L", and 0.1 seconds for "A" is assigned.

Then, as shown in FIG. 10, the analog waveforms having different assigned fundamental periods are successively arranged one period at a time to generate an aperiodic continuous signal. An aperiodic continuous signal is a signal that is a series of aperiodic signals, and an aperiodic signal is a signal that does not repeat itself after a specified time interval. In this case, the linguistic information about "Sora" can be transmitted as an aperiodic continuous signal in 0.298 seconds in total. In other words, the aperiodic continuous signal is transmitted in the form of a continuous time code representing the time band of each phoneme.

Since all languages in the world are made up of phonemes consisting of consonants and vowels, linguistic information using all languages in the world can be divided into predetermined components, consonants and vowels. For this reason, in the present embodiment, separate fundamental periods corresponding to the divided consonants and vowels are assigned, and analog waveforms having separate fundamental periods are continuously arranged one cycle at a time to generate an aperiodic continuous signal. Therefore, language information can be transmitted with a minimum number of analog waves.

The aperiodic continuous signal represented by the time code as shown in FIG. 11(a) is a signal of continuous sine waves as analog waves as shown in FIG. ) as an analog wave may be a continuous signal, and the type of analog wave is not particularly limited.

As described above, in this embodiment, by applying the basic period to each of the divided components of the information group to be transmitted, it is possible to develop the information group on the time axis. If the analog waveform is a pulse wave as shown in FIG. 11(c), information can be transmitted with a minimum number of pulses instead of digital. Even in the case of sine waves as shown in FIG. 11(b), information can be transmitted with a minimum number of sine waves.

Then, the generated aperiodic continuous signal can be transmitted by changing the transmission speed to an arbitrary transmission speed at the time of transmission. In the present embodiment, a fundamental period corresponding to each predetermined component is assigned, so the signal can be established as long as the ratio of the assigned fundamental period (time code: length of time) is maintained. Therefore, even if the speed is changed to an arbitrary speed, the signal can be maintained, and the information group to be transmitted can be reliably reproduced at the time of reception. This makes it possible to easily maximize the amount of information per unit time.

In this embodiment, the encrypted signal generator 1 divides the information group to be transmitted into predetermined constituent elements, assigns different fundamental periods corresponding to the predetermined constituent elements, and separates the fundamental periods. An aperiodic continuous signal is generated by continuously arranging analog waveforms having cycles one cycle at a time.

As described above, in the case of linguistic information, an aperiodic continuous signal is generated in accordance with the linguistic information. This aperiodic continuous signal is an encrypted electrical signal.

Then, the encrypted signal generator 5 generates an electrical signal corresponding to the encrypted signal that is the basis of the non-periodic continuous signal. Since this electrical signal is an aperiodic continuous signal, it contains encrypted continuous character information and the like.

Next, a method for decoding the encrypted signal generated in this manner will be described.

First, the pattern of the spatial distribution of the antinode portion and the node portion that weaken each other between the first wave generated from the first wave generator 11 and the second wave generated from the second wave generator 12 is electromagnetically generated. A pattern code correspondence table 34 is created in which patterns scanned by the field scanning device 31 and scanned by the electromagnetic field scanning device 31 for the number of encryption codes are stored.

Even when five wave generator units 10 are arranged as shown in FIG. 1, there is a spatial distribution pattern that matches the arrangement. It may be stored in the storage device 32 .

In this way, the pattern of the spatial distribution for each fundamental period corresponding to the predetermined constituent element is recorded in the pattern code correspondence table 34. In the case of a non-periodic continuous signal, the pattern of the spatial distribution is repetitive wave generation. It is generated from the body unit 10.

Then, in a state in which the encrypted signals are transmitted to the first wave generator 11 and the second wave generator 12 respectively, the spatial distribution pattern scanned by the electromagnetic field scanning device 31 is compared with the pattern code correspondence table 34. Then, the decoding device 35 decodes the result based on the comparison result, and the display output device 36 displays it or records it on a recording medium.

Therefore, according to the encrypted signal generator 1 according to the present embodiment, it is possible to provide a novel mechanism for generating and decoding encrypted signals.

(Other embodiments)
The present invention may be configured as follows for the above embodiment.

That is, in the above-described embodiment, the encrypted signal is composed of an "aperiodic continuous signal", but the present invention is not limited to this.

The encrypted signal generation unit 5 has a control unit that uses software (program) such as a microcomputer, for example. It may be configured such that an arbitrary encrypted signal created by predetermined software or the like can be generated from the encrypted signal generating section 5 by inserting and removing it.

Other configurations of the electromagnetic field pattern storage device 32, the electromagnetic field pattern comparison processing device 33, the decoding device 35, etc. are not particularly limited, and software (programs) such as microcomputers and programmable logic controllers (PLC) are used. It may be realized by combining hardware (circuit components).

In the above embodiment, an interference pattern based on the principle of superposition of waves is used for electromagnetic waves that are transverse waves, but the interference pattern is used for sound waves that are longitudinal waves. good too. In that case, the electromagnetic field scanning device 31 becomes a sound wave pattern scanning device, the electromagnetic field pattern storage device 32 becomes a sound wave pattern storage device, and the electromagnetic field pattern comparison processing device 33 becomes a sound wave pattern comparison processing device. In the case of sound wave patterns, it is easily affected by temperature, and it is not a simple overlap or cancellation of waves. can.

The above embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its applications, or uses.

1 encrypted signal generator
2 storage case
3 Equipment storage case
4 Flat sign nut
5 Encrypted signal generator
6 patterns
10 wave generator unit
11 first wave generator
12 second wave generator
13 signal amplifier
14 electrodes
15 support plate
16 bottom cap
17 glass cap
30 receiver
31 electromagnetic field scanning device (pattern scanning device)
32 electromagnetic field pattern storage device (pattern storage device)
33 electromagnetic field pattern comparison processing device (pattern comparison processing device)
34 pattern code correspondence table
35 decoding device
36 display output device

In the twelfth invention, in the eleventh invention,
Preparing patterns of spatial distribution of antinodes and nodes generated by waves at a frequency of one period of an encryption code corresponding to a predetermined component as a pattern code correspondence table;
dividing the group of information to be transmitted into the predetermined constituent elements by the encrypted signal generating unit, and assigning separate fundamental periods corresponding to the predetermined constituent elements, respectively;
A non-periodic continuous signal is generated by successively arranging the analog waveforms having different fundamental periods one by one.

Claims (12)

an encrypted signal generator that generates an electrical signal corresponding to the encrypted signal;
a wave generator unit having a first wave generator and a second wave generator disposed facing the first wave generator at a predetermined distance;
The encrypted electrical signal transmitted from the encrypted signal generator is transmitted to the first wave generator, and the encrypted electrical signal out of phase with or in phase with the encrypted electrical signal is transmitted to the second wave generator. a signal amplifier that transmits to the wave generator;
An encrypted signal generator, wherein waves corresponding to the encrypted signals are respectively generated by transmitting the encrypted electric signals to the first wave generator and the second wave generator. 2. The encrypted signal generator as set forth in claim 1, wherein said first wave generator and said second wave generator are entirely or partially made of crystal. 2. The encrypted signal generator according to claim 1, wherein said first wave generator and said second wave generator each comprise a crystal plate and a pair of electrodes supporting said crystal plate. A plurality of wave generator units are arranged such that the plate-like first wave generator and the plate-like second wave generator are separated by a predetermined width in the thickness direction, and the thickness direction is parallel to the tangent line of the circle. , are spaced apart in the circumferential direction. A plurality of wave generator units are arranged in a regular N-sided shape with N equal intervals in the circumferential direction,
When the width in the thickness direction between the first wave generator and the second wave generator of the first wave generator unit is W1,
The width Wn at the n-th vertex is
Wn=W1×(N+n−1)/N
5. The encrypted signal generator according to claim 4, characterized by being represented by: Assuming that the difference width between the n-th width Wn and the n+1-th width Wn+1 is ΔW,
ΔW=W1/N
6. The encrypted signal generator according to claim 5, wherein: An encrypted signal generator according to any one of claims 1 to 6;
A pattern for scanning a spatial distribution pattern of constructive antinode portions and destructive node portions between the first wave generated from the first wave generator and the second wave generated from the second wave generator. a scanning device;
An encrypted signal decoding system, comprising: a pattern storage device storing a pattern code correspondence table storing patterns scanned by the pattern scanning device by the number of encrypted codes. Pattern comparison for comparing the spatial distribution pattern scanned by the pattern scanning device with the pattern code correspondence table in a state in which the encrypted signals are transmitted to the first wave generator and the second wave generator, respectively. a processor;
8. The encrypted signal decoding system according to claim 7, further comprising a decoding device for decoding based on the result of comparison by said pattern comparison processing device. generating an electric signal corresponding to the encrypted signal from the encrypted signal generator;
For a wave generator unit having a first wave generator and a second wave generator disposed facing the first wave generator at a predetermined distance,
The encrypted electrical signal transmitted from the encrypted signal generator is transmitted to the first wave generator, and the encrypted electrical signal out of phase with or in phase with the encrypted electrical signal is transmitted to the second wave generator. send to the wave generator,
An encrypted signal generating method, wherein waves corresponding to the encrypted signals are respectively generated by transmitting the encrypted electrical signals to the first wave generator and the second wave generator. The pattern scanning device detects the pattern of the spatial distribution of the antinode portion and the node portion that weaken each other between the first wave generated from the first wave generator and the second wave generated from the second wave generator. and scan with
10. The encrypted signal generation method according to claim 9, wherein a pattern code correspondence table storing patterns scanned by the pattern scanning device for the number of encrypted codes is created. preparing a pattern code correspondence table created by the encrypted signal generation method of claim 10;
In a state in which the encrypted signals are transmitted to the first wave generator and the second wave generator respectively, the pattern of the spatial distribution scanned by the pattern scanning device is compared with the pattern code correspondence table, and the result of the comparison is obtained. An encrypted signal decryption method, characterized in that decryption is performed based on the Preparing patterns of spatial distribution of antinodes and nodes generated by waves at a frequency of one period of an encryption code corresponding to a predetermined component as a pattern code correspondence table;
dividing the group of information to be transmitted into the predetermined constituent elements by the encrypted signal generating unit, and assigning separate fundamental periods corresponding to the predetermined constituent elements, respectively;
12. The method of decoding an encrypted signal according to claim 10, wherein the analog waveforms having different fundamental periods are successively arranged one period at a time to generate an aperiodic continuous signal.