JP2013156471A - Encryption image recognition system, and encryption image recognition method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a system for preventing information leakage by visual inspections from images displayed on various displays of portable terminals, personal computers, ATMs, etc., and various screens of cinemas etc. to a high degree, and sufficiently protecting privacy and security.SOLUTION: An encryption image recognition system has: an encryption unit which generates and outputs a time division encryption image frame group, and an encryption key corresponding to the time division encryption image frame group according to an input original image; a transmission unit which generates a synchronization signal in response to the time division encryption image frame group and the encryption key which are input from the encryption unit, and outputs the synchronization signal with the time division encryption image frame group and the encryption key; a display unit which displays an encrypted image according to the time division encryption image frame group and the synchronization signal which are input from the transmission unit; and a restoration unit which restores the encrypted image in response to the encryption key and the synchronization signal.

Description

  The present invention relates to an encrypted image recognition system and an encrypted image recognition method for displaying an image obtained by encrypting an original image and restoring the encrypted image by viewing the displayed image through a restoration unit.

  When various types of information terminals are used outdoors or indoor public places, there is always a danger that privacy and security cannot be protected due to information leakage by visual observation of displayed images. Therefore, when using these, careful operation is required under the responsibility of each individual. As defense means for preventing information leakage, for example, in the case of a portable terminal such as a mobile phone or a personal computer, a peep prevention film for narrowing the viewing angle is put on the surface of the display, and ATMs of banks and convenience stores are used. In the case of, measures have been taken such as entering a password while paying attention to whether there is a peep or voyeur.

  On the other hand, Patent Document 1 discloses an image display device including a main body and glasses that can prevent an original image from being recognized by a person other than the user. In this apparatus, an original image to be concealed and an image composed of the opposite color are alternately displayed on the screen in a time-sharing manner, and the original image is concealed by canceling the original image with the opposite color image by the afterimage. On the other hand, the user can visually observe the display image through glasses that can change the light transmission by combining a polarization switching machine that switches the polarization direction in synchronization with the timing of the time-divided display image and a polarization filter. Only the original image can be extracted from the display image and browsed.

JP2009-204948

  In Patent Document 1, since an original image to be concealed and an image composed of the opposite color are displayed on the screen alternately in a time-division manner, it is relatively easy for a third party to know the filtering cycle. Could be filtered. As a result, the original image is recognized by a third party, resulting in a risk that privacy and security are not protected.

  The present invention highly prevents leakage of information from images displayed on various displays such as mobile terminals, personal computers, ATMs, and various screens such as movies, and provides sufficient privacy and security protection. With the goal.

  An encryption unit that generates and outputs a time-division encrypted image frame group and an encryption key corresponding to the time-division encrypted image frame group according to the input original image, and the time input from the encryption unit In response to the divided encrypted image frame group and the encryption key, a synchronization signal is generated, and the synchronization signal is output together with the time-division encrypted image frame group and the encryption key. And a display unit that displays an encrypted image according to the time-division encrypted image frame group and the synchronization signal, and a restoration unit that restores the encrypted image in response to the encryption key and the synchronization signal. It is characterized by that.

  According to the present invention, it is possible to highly prevent leakage of information from images displayed on various displays such as mobile terminals, ATMs, personal computers, and various screens such as movies, and to protect sufficient privacy and security. It becomes possible to do.

It is a figure which shows the encryption image recognition system of embodiment of this invention. It is a figure which shows the encryption image recognition system of embodiment of this invention. It is a figure which shows the Example of the encryption image recognition of embodiment of this invention. It is a figure which shows the Example of the encryption image recognition of embodiment of this invention. It is a figure which shows the Example of the encryption image recognition of embodiment of this invention. It is a figure which shows the Example of the encryption image recognition of embodiment of this invention. It is a figure which shows the encryption image recognition system of embodiment of this invention. It is a figure which shows the encryption image recognition system of embodiment of this invention. It is a figure which shows the encryption image recognition system of embodiment of this invention.

The best mode for carrying out the present invention will be described with reference to the drawings. However, the preferred embodiments described below are technically preferable for carrying out the present invention, but the scope of the invention is not limited to the following.
(First embodiment)
The configuration of the first embodiment of the present invention will be described with reference to FIG. The encrypted image recognition system 1 shown in FIG. 1 generates an encryption key corresponding to a time-division encrypted image frame group obtained by time-division encryption of an original image such as a still image or a moving image and a time-division encrypted image frame group. An encryption unit 10 that generates a synchronization signal in response to the time-division encrypted image frame group and the encryption key, and outputs a synchronization signal together with the time-division encrypted image frame group and the encryption key. The display unit 12 that displays an encrypted image according to the time-division encrypted image frame group and the synchronization signal, and the encrypted image displayed on the display unit 12 is visually checked by the transmitted encryption key and the synchronization signal. A restoration unit 13 for restoring the converted image. The restoration unit 13 is, for example, a glasses type as shown in FIG. 1, and includes a shutter unit 14 for restoring an encrypted image to an original image by a shutter function and a shutter control unit 15 for controlling opening and closing of the shutter.

  Details of the first embodiment will be described with reference to FIG. FIG. 2 shows an encrypted image recognition system 2 according to the first embodiment of the present invention. Original images such as still images and moving images are captured by the encryption unit 200. In the encryption unit 200, first, the time division number determination unit 201 calculates the original image time division number 251 and the dummy image time division number 252 inserted between the time-divided original image frames from the frame rate of the display unit 220. Decide.

  From the original image, a time-division original image frame group 253 time-divided by the time-division original image generation unit 202 and a time-division dummy image frame group 254 obtained by converting the original image and time-division by the time-division dummy image generation unit 203 are generated. Is done. Further, in the encrypted image generation unit 204, the time-division encrypted image frame group in which the image frames of the time-division original image frame group 253 and the image frames of the time-division dummy image frame group 254 are randomly arranged in time series. 256 is generated. On the other hand, the encryption key generation unit 205 generates an encryption key 257 having information 255 on the time-series arrangement of time-division original image frames in the time-division encrypted image frame group 256.

  The time-division encrypted image frame group 256 and the encryption key 257 are sent to the encrypted image transmission unit 211 and the encryption key transmission unit 212 of the transmission unit 210, respectively. The encrypted image transmission unit 211 transmits the time-division encrypted image frame group 256 to the display unit 220 and the image / key synchronization control unit 213. The encryption key transmission unit 212 transmits the encryption key 257 to the restoration unit 230 and the image / key synchronization control unit 213. The image / key synchronization control unit 213 receives the time division encrypted image frame group 256 and the encryption key 257 and generates a synchronization signal 258 between the time division encrypted image frame group 256 and the encryption key 257. Further, the image / key synchronization control unit 213 transmits the synchronization signal 258 to the display unit 220 and the restoration unit 230.

The display unit 220 receives the time-division encrypted image frame group 256 and the synchronization signal 258, and displays the encrypted image 259. In addition, the restoration unit 230 receives the encryption key 257 and the synchronization signal 258, and sends a shutter open / close signal 260 from the shutter control unit 231 to the shutter unit 232 in synchronization with the encrypted image displayed on the display unit 220. In response to this, the shutter unit 232 opens and closes, and the time-division dummy image frame 254 inserted in a time-division manner into the time-division encrypted image frame group 256 is removed. That is, the shutter unit 232 opens in synchronization with each time-division original image frame in the time-division encrypted image frame group 256, and the shutter unit 232 closes in synchronization with each time-division dummy image frame. The image frame group 254 is removed. Therefore, the parties recognize the original image restored from the encrypted image 259 by visually observing only the time-division original image frame group 253 by viewing the display unit 220 via the restoration unit 230. be able to.
Example 1
The encryption unit 200 generates a time-division encrypted image frame group 256 and an encryption key 257, uses the subsequent encrypted image display 261, and a specific example of recognizing the original image by restoration using FIGS. 3A and 3B. I will explain. 3A and 3B show an embodiment of encrypted image recognition according to the present invention.

  First, the time division number determination unit 201 determines the time division number of the original image FIG. 3A (a) from the frame rate of the display unit 220. For example, when the frame rate of the display unit 220 corresponds to 30 fps (frames / second), the image analysis unit 201 allocates, for example, 15 time division original image frames and 15 time division dummy image frames. Hereinafter, this assignment will be described as an example.

  The time division original image generation unit 202 generates a time division original image frame group diagram 3A (b). Since 15 frames are assigned to the time-division original image frame, the time-division original image frame group FIG. 3A (b) is composed of 15 time-division image frames. The fifteen image frames are composed of image frames with discrete pixels. When all these image frames are overlapped, the original image is restored.

  An image frame generation method using discrete pixels is as follows. First, the entire surface of the original image FIG. 3A (a) is divided into a plurality of groups of 15 pixels. For each group, one pixel is randomly selected from the group in order. These selected pixels are collected in all groups to form one frame, and a time-division original image frame group diagram 3A (b) consisting of 15 frames is generated. At this time, it is desirable that one image frame is decomposed so that the original image cannot be recognized.

  When the original image FIG. 3A (a) is not divisible by 15, a group of less than 15 pixels is also generated, and pixels are also selected in order from the group in a random manner. The selection from this group ends when there are no more pixels.

  On the other hand, the time division dummy image frame group FIG. 3A (c) is generated by the time division dummy image generation unit 203. At this time, the time-division dummy image frame group FIG. 3A (c) is composed of 15 time-division image frames. These 15 image frames are generated as follows. First, the color information of the original image is analyzed, and a dummy image having a color arrangement different from that of the original image is generated while maintaining the ratio of each color on the original image. A dummy image frame including a plurality of discrete pixels is generated from the dummy image.

  For example, in the case of the original image FIG. 3A (a), the colors are 20% orange, 50% light blue, 15% beige, 5% white, 5% green, and 5% brown. The original image is converted into an arrangement different from the arrangement of the colors of the original image while maintaining this color ratio. Thereafter, a dummy image frame including a plurality of discrete pixels is generated, and a time-division dummy image frame group is shown in FIG. 3A (c). The method for generating an image frame using discrete pixels is the same as the method for generating an image frame using discrete pixels in the time-division original image frame group FIG. 3A (b).

  The reason why the dummy image frame maintains the color ratio of the original image is as follows. That is, for example, if a user of this encrypted image recognition system is reading a black and white document, an image frame having a color scheme different from that of the original image such as red or blue is inserted as a dummy image frame. In this case, the original image and the dummy image can be easily separated by visual inspection. In order to avoid this, it is effective to use a dummy image having the same color ratio as the original image.

  The time-division original image frame group diagram 3A (b) and the time-division dummy image frame group diagram 3A (c) generated as described above are randomly arranged on the time series, and the time-division encrypted image frame group diagram. 3B (d) is generated. This time-division encrypted image frame group FIG. 3B (d) includes 30 image frames. Further, at this time, in the time-division encrypted image frame group FIG. 3B (d), the position on the time series of each frame of the time-division original image frame group FIG. 3A (b) arranged on the time series (FIG. In 3B (d), an encryption key diagram 3B (e) corresponding to 1, 4, 6,... Is generated.

  3B (d) and encryption key FIG. 3B (e) generated as described above are synchronization signals for synchronizing the time-division encrypted image frame group and the encryption key by the transmission unit 210. Are transmitted to the display unit 220 and the restoration unit 230, respectively. In the display unit 220, the time-division encrypted image frame group diagram 3B (d) made up of 30 image frames is displayed at 30 fps with a synchronization signal, so that the encrypted image diagram 3B (f) is displayed. . Even if this is directly observed, the original image is not recognized.

  On the other hand, the restoration unit 230 is, for example, a glasses type as shown in FIG. 1, and the shutter is opened and closed in synchronization with the encryption key. As the shutter unit 14, the following method can be used. That is, the shutter unit 14 is combined with a polarization switching unit and a polarization filter unit that switch the polarization direction in synchronization with the timing of the time-divided display image. This combination changes the light transmission and opens and closes. The shutter unit 14 can also be opened and closed by using a liquid crystal filter made of black and white TN liquid crystal, ferroelectric liquid crystal, or the like and changing the light transmittance. By visually observing the display unit 220 through the restoration unit 230 described above, the restored image FIG. 3B (g) is recognized by the afterimage effect obtained by viewing only the time-division original image frame group.

  In the first embodiment, the time division number determination unit 201 assigns 15 frames to the time division original image frame and 15 frames to the time division dummy image frame. However, the time division number and the time division dummy of the time division original image frame are allocated. The time division numbers of the image frames need not be equal, the time division number of the time division original image frame may be larger, and the time division number of the time division dummy image frame may be larger.

In the first embodiment, the time-division original image frame group diagram 3A (b) and the time-division dummy image frame group diagram 3A (c) are randomly arranged on the time series, and the time-division encrypted image frame group diagram is shown. Although the case where 3B (d) is generated has been described, the present invention is not limited to this, and it is also possible to arrange them with a certain regularity on the time series.
(Example 2)
A specific example in which the encryption unit 200 generates a time-division encrypted image frame group and an encryption key and then recognizes the original image by displaying and restoring the encrypted image will be described with reference to FIGS. 4A and 4B. . 4A and 4B show an embodiment of encrypted image recognition according to the present invention.

  First, the time division number determination unit 201 determines the time division number of the original image FIG. 4A (a) from the frame rate of the display unit 220. The time-division original image generation unit 202 divides the original image FIG. 4A (a) for the left eye and the right eye by alternately allocating pixel rows (FIG. 4A (b)), and separates the left eye image and the right eye image. Then, the time-division original image frame group diagram 4A (c) is generated. Further, the time-sharing dummy image generation unit 203 divides the original image FIG. 4A (a) for the left eye and the right eye by alternately allocating pixel rows (FIG. 4A (b)), and for the left eye and the right eye. A time-division dummy image frame group diagram 4A (d) is generated for each image.

  At this time, when the frame rate of the display unit 220 corresponds to 60 fps, the time division number determination unit 201, for example, provides 15 left-eye and right-eye time-division original image frames, respectively, for the left-eye and right-eye. 15 frames are allocated to each time-division dummy image frame. Hereinafter, this assignment will be described as an example.

  The method of generating each image frame using discrete pixels in the time-division original image frame group diagram 4A (c) and the time-division dummy image frame group diagram 4A (d) for each of the left eye and the right eye is the case of the first embodiment. It is the same.

  The generated time-division original image frame group diagram 4A (c) and time-division dummy image frame group diagram 4A (d) are randomly arranged on the time series, and time-division ciphers corresponding to the left eye and the right eye respectively. 4B (e) and FIG. 4B (f) are generated. Furthermore, the time-series positions of the frames of the time-division original image frame group arranged on the time series at this time (in FIG. 4, 1, 4, 6,... For the left eye, 1, 3, 6... Are generated for left eye and right eye encryption keys corresponding to FIG. 4B (g).

  4B (e), FIG. 4B (f) and the encryption key FIG. 4B (g) are generated by the transmission unit 210 using the time division encryption. The image frame group and the encryption key are transmitted to the display unit 220 and the restoration unit 230 together with a synchronization signal for synchronizing the encryption key.

  A left-rotating circular polarizing filter and a right-rotating circular polarizing filter are provided on the surface of the display unit 220 in correspondence with the left-eye pixel row and the right-eye pixel row. On the other hand, a left-rotating circular polarizing filter and a right-rotating circular polarizing filter are also provided on the surfaces of the left-eye shutter and the right-eye shutter of the glasses-type restoration unit 230, respectively. Thereby, the pixel row for the left eye of the display image is recognized only for the left eye, and the pixel row for the right eye is recognized only for the right eye.

  The restoration unit 230 uses a liquid crystal filter made of black and white TN liquid crystal, ferroelectric liquid crystal, or the like as the shutter unit 14, and opens and closes by changing light transmittance.

  In the display unit 220, a time-division encrypted image frame group (for the left eye) composed of 30 image frames (for the left eye) FIG. 4B (e) and a time-division encrypted image frame group (for the right eye) composed of 30 image frames are illustrated in FIG. A total of 60 image frames with f) are displayed at 60 fps with a synchronization signal, whereby the encrypted image FIG. 4B (h) is displayed. Even if this is directly observed, the original image is not recognized. On the other hand, the left-eye shutter and the right-eye shutter of the restoration unit 230 are opened and closed in synchronization with the left-eye and right-eye encryption keys, respectively. By visually observing the display unit 220 through the restoration unit 230, the restored image FIG. 4B (i) is recognized by the afterimage effect obtained by viewing only the time-division original image frame group.

  In the above method, the original image is divided into those for the left eye and for the right eye, thereby further enhancing the encryption.

  In the second embodiment, the time division number determination unit 201 assigns 15 frames to the left-eye and right-eye time-division original image frames, and 15 frames to the left-eye and right-eye time-division dummy image frames. These time division numbers need not be equal.

In the second embodiment, the time-division original image frame group diagram 4A (c) and the time-division dummy image frame group diagram 4A (d) are randomly arranged on the time series, and the time-division encrypted image frame group diagram is shown. Although the case of generating 4B (e) and FIG. 4B (f) has been described, the present invention is not limited to this, and it is also possible to arrange them with a certain regularity on the time series.
(Second Embodiment)
A second embodiment will be described with reference to FIG. FIG. 5 shows an encrypted image recognition system 5 according to the second embodiment of the present invention in the configuration of FIG. Original images such as still images and moving images are captured by the encryption unit 500. In the encryption unit 500, first, the time division number determination unit 501 determines the original image time division number 551 and the dummy image time division number 552 inserted between the time-divided original image frames from the frame rate of the display unit 520. Decide.

  From the original image, a time-division original image frame group 553 time-divided by the time-division original image generation unit 502 and a time-division dummy image frame group 554 obtained by converting the original image and time-division by the time-division dummy image generation unit 503 are generated. Is done. Further, the encrypted image generation unit 504 stores each image frame of the time division original image frame group 553 and each image frame of the time division dummy image frame group 554 with one or more pre-stored in the encryption key storage unit 505. A time-division encrypted image frame group 556 arranged along the encryption key 555 designated from the encryption keys is generated.

  The encryption key 555 stored in the encryption key storage unit 505 includes arrangement information for arranging the image frames of the time division original image frame group 253 and the image frames of the time division dummy image frame group 254 in time series. Have. Further, when specifying an encryption key from one or more encryption keys stored in advance in the encryption key storage unit 505, the encryption key may be specified by referring to the time division number information obtained by the image analysis unit 501. It is possible (not shown in FIG. 5).

  For example, when the time division number determination unit 501 assigns 15 time division numbers to the time division original image frame and 15 time division dummy image frames, the time division encrypted image frame group 556 has 30 image frames. It becomes. The encryption key 555 stored in advance has information on where in the 30 image frames the image frames of the time-division original image frame group 553 are arranged.

  The time-division encrypted image frame group 556 and the encryption key 555 are sent to the encrypted image transmission unit 511 and the encryption key transmission unit 512 of the transmission unit 510, respectively. The encrypted image transmission unit 511 transmits the time-division encrypted image frame group 556 to the display unit 520 and the image / key synchronization control unit 513. In addition, the encryption key transmission unit 512 transmits the encryption key 555 to the restoration unit 530 and the image / key synchronization control unit 513. The image / key synchronization control unit 513 receives the time division encrypted image frame group 556 and the encryption key 555 and generates a synchronization signal 557 between the time division encrypted image frame group 556 and the encryption key 555. Further, the image / key synchronization control unit 513 transmits the synchronization signal 557 to the display unit 520 and the restoration unit 530.

The display unit 520 receives the time-division encrypted image frame group 556 and the synchronization signal 557, and displays the encrypted image 558. Further, the restoration unit 530 receives the encryption key 555 and the synchronization signal 557, and sends a shutter open / close signal 559 from the shutter control unit 531 to the shutter unit 532 in synchronization with the encrypted image 558 displayed on the display unit 520. . In response to this, the shutter unit 532 opens and closes, and the time-division dummy image frame 554 inserted into the time-division encrypted image frame group 556 in a time-division manner is removed. That is, the shutter unit 532 is opened in synchronization with each time-division original image frame in the time-division encrypted image frame group 556, and the shutter unit 532 is closed in synchronization with each time-division dummy image frame. Only the image frame group 554 is removed. Therefore, the parties recognize the original image restored from the encrypted image 558 by the afterimage effect by viewing only the time-division original image frame group 553 by viewing the display unit 520 via the restoration unit 530. be able to.
(Third embodiment)
A third embodiment will be described with reference to FIG. FIG. 6 shows an encrypted image recognition system 6 according to the third embodiment of the present invention in the configuration of FIG. Original images such as still images and moving images are captured by the encryption unit 600. In the encryption unit 600, first, the time division number determination unit 601 determines the original image time division number 651 and the dummy image time division number 652 to be inserted into the time-division frame between the original images from the frame rate of the display unit 620. Decide.

  From the original image, a time-division original image frame group 653 time-divided by the time-division original image generation unit 602 and a time-division dummy image frame group 654 obtained by converting the original image and time-division by the time-division dummy image generation unit 603 are generated. Is done. Further, the encrypted image generation unit 604 stores the image frames of the time division original image frame group 653 and the time division dummy image frame group 654 in one or more encryption keys stored in advance in the encryption key storage unit 605. To generate a time-division encrypted image frame group 656 arranged in accordance with the encryption key designated from the above. When specifying an encryption key from one or more encryption keys stored in advance in the encryption key storage unit 605, it is also possible to specify with reference to the time division number information obtained by the image analysis unit 601. Yes (not shown in FIG. 6).

  For example, when the time division number determination unit 601 assigns 15 time division numbers to the time division original image frame and 15 time division dummy image frames, the time division encrypted image frame group 656 has 30 image frames. It becomes. The encryption key 655 stored in advance has information on where in the 30 image frames the image frames of the time-division original image frame group 653 are arranged.

  The time-division encrypted image frame group 656 and the encryption key designation signal 657 are sent to the encrypted image transmission unit 611 and the encryption key designation signal transmission unit 612 of the transmission unit 610, respectively. The encryption key designation signal 657 is a signal for designating an encryption key from one or more encryption keys stored in advance in the encryption key storage unit 605, and corresponds to the encryption key 655.

  The encrypted image transmission unit 611 transmits the time-division encrypted image frame group 656 to the display unit 620 and the image / key synchronization control unit 613. Also, the encryption key designation signal transmission unit 612 transmits the encryption key designation signal 657 to the restoration unit 630 and the image / key synchronization control unit 613. The image / key synchronization control unit 613 receives the time division encrypted image frame group detection signal 658 and the encryption key designation signal 657 and receives the encryption key designated from the time division encrypted image frame group signal 656 and the encryption key designation signal 657. A synchronization signal 658 is generated. Further, the image / key synchronization control unit 613 transmits the synchronization signal 658 to the display unit 620 and the restoration unit 630.

  The display unit 620 receives the time division encrypted image frame group 656 and the synchronization signal 658 and displays the encrypted image 659.

The restoration unit 630 receives the encryption key designation signal 657 and designates the encryption key 660 from one or more encryption keys stored in advance in the encryption key storage unit 633 (not shown in FIG. 1). By using the encryption key 660 and the synchronization signal 658, a shutter open / close signal 661 is sent from the shutter control unit 631 to the shutter unit 632 in synchronization with the encrypted image 659 displayed on the display unit 620. Corresponding to this, the shutter 632 is opened and closed to remove the time-division dummy image frame group 654 inserted into the encrypted image 659 in a time-division manner. That is, the shutter unit 632 is opened in synchronization with each time-division original image frame group 653 in the time-division encrypted image frame group 656, and the shutter is closed in synchronization with each time-division dummy image frame group 654. Only the divided dummy image frame group 654 is removed. Therefore, the parties recognize the original image restored from the encrypted image 659 by visually observing only the time-division original image frame group 653 by viewing the display unit 620 via the restoration unit 630. be able to.
(Fourth embodiment)
A fourth embodiment will be described with reference to FIG. FIG. 7 shows an encrypted image recognition system 7 according to the fourth embodiment of the present invention in the configuration of FIG. In the present embodiment, a plurality of parties recognize different original images while simultaneously viewing the encrypted images displayed at one place.

  N original images such as still images and moving images are captured by the encryption unit 700. In the encryption unit 700, first, the time division number determination unit 701 inserts between the time division number 751 of each original image (1 to N) and the time division original image frame from the frame rate of the display unit 720. The number of time divisions 752 of the dummy image is determined.

  From N original images (1 to N), N time-division original image frame groups (1 to N) 753 time-divided by the time-division original image generation unit 702 and originals by the time-division dummy image generation unit 703 are used. N time-division dummy image frame groups (1 to N) 754 obtained by converting the image and time-division are generated. Further, in the encrypted image generation unit 704, N is obtained by randomly arranging the image frames of the time division original image frame group (1 to N) 753 and the time division dummy image frame group (1 to N) 754 in time series. A number of time-division encrypted image frame groups (1 to N) 756 are generated. On the other hand, in the encryption key generation unit 705, N encryption keys (1 to 1) having information 755 on the time series of each time division original image frame of the time division encrypted image frame group (1 to N) 756 are displayed. N) 757 is generated.

  The time-division encrypted image frame group (1 to N) 756 and the encryption key (1 to N) 757 are transmitted from the transmission unit 710 to the display unit 720 and the restoration unit 730, respectively. The encrypted image transmission unit 711 transmits the time-division encrypted image frame group (1 to N) 756 to the display unit 720 and the image / key synchronization control unit 713. The encryption key transmission unit 712 transmits the encryption key (1 to N) 757 to the restoration unit 730 and the image / key synchronization control unit 713. The image / key synchronization control unit 713 receives the time division encrypted image frame group 756 and the encryption key 757 and generates a synchronization signal 758 for the time division encrypted image frame group 756 and the encryption key 757. Further, the image / key synchronization control unit 713 transmits the synchronization signal to the display unit 720 and the restoration unit 730.

  The display unit 720 receives the N time-division encrypted image frame groups (1 to N) 756 and the synchronization signal 758, and displays the encrypted images 759 in the order of 1, 2,.

  The restoration unit 730 performs encryption of 1 to N by an encryption key specification unit 731 (not shown in FIG. 1) that specifies one encryption key specified from among the N encryption keys (1 to N) 757. An encryption key 760 corresponding to the original image to be restored is designated in the image. In response to the encryption key 760 and the synchronization signal 758, a shutter open / close signal 761 is sent from the shutter control unit 732 to the shutter unit 733 in synchronization with the encrypted image 759 displayed on the display unit 720. Corresponding to this, the shutter unit 732 opens and closes, and the time-division dummy image frame inserted in the time-division manner into the encrypted image 759 and the non-designated time-division original image frame are removed. That is, the shutter unit 732 is opened in synchronization with one designated time-division original image frame group in the time-division original image frame group (1 to N) 756, and in other cases, the shutter unit 732 is closed. , One designated time-division original image frame group is recognized. Therefore, the first party can recognize one designated original image from the encrypted image 759 by viewing the display unit 720 via the restoration unit 730.

  At this time, the second party viewing the same display unit 720 can recognize another original image. That is, the second party restores an original image different from the first party by restoring the original key different from the first party by restoring the encryption key 760 corresponding to the original image specified separately from the first party. It is possible to visually recognize the display unit simultaneously with the first party using the unit. That is, in this embodiment, a plurality of parties recognize different original images while simultaneously viewing the encrypted image 759 displayed at one place.

  In FIG. 7, N time-division encrypted image frame groups (1 to N) are used. However, one time-division encryption in which all frames of N image frame groups 1 to N are mixed. It is good also as a frame group. In this case, the N encryption keys 1 to N are encryption keys 1 to N having information on the time-series arrangement of time-division original image frames of a specified original image from the one time-division encryption frame group. And

In FIG. 7, the encryption key is generated as needed together with the generation of the time-division encrypted image frame group, but may be stored in advance in the encryption unit or the restoration unit.
(Example of change)
The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the spirit of the present invention.
(1) Modification 1
In FIG. 1, the restoring unit 13 includes the glasses structure shown in FIG. 1, but is not limited to the glasses structure, and is not limited to a helmet visor structure, a contact lens structure that is directly inserted into the eye, an automobile, or the like A plate shape such as a windshield or side glass is possible.
(2) Modification example 2
In FIG. 1, the display unit 12 includes the display for the personal computer shown in FIG. 1, but is not limited to this, and various displays such as mobile terminals and ATMs, and various screens such as movies are possible. It is.

(Appendix)
(Appendix 1)
An encryption unit that generates and outputs a time-division encrypted image frame group and an encryption key corresponding to the time-division encrypted image frame group according to the input original image;
A synchronization signal is generated in response to the time division encrypted image frame group and the encryption key input from the encryption unit, and the synchronization signal is output together with the time division encrypted image frame group and the encryption key. A transmission unit;
A display unit that displays an encrypted image according to the time-division encrypted image frame group input from the transmission unit and the synchronization signal;
An encrypted image recognition system comprising: a restoration unit that restores the encrypted image in response to the encryption key and the synchronization signal.

(Appendix 2)
The encryption unit is
A time division number determining unit that determines and outputs a time division number of a predetermined original image and a time division number of a dummy image;
A time-division image generation unit that generates and outputs a time-division original image frame group from the original image and the time-division number of the original image;
A time-division dummy image generation unit for generating and outputting a time-division dummy image frame group from the number of time divisions of the original image and the dummy image;
The time division original image frame group and the time division dummy image frame group are received, and each image frame of the time division original image frame group and each image frame of the time division dummy image frame group are randomly or a certain rule An encrypted image generation unit that generates and outputs arrangement information of the time-division encrypted image frame group and the time-division encrypted image frame group that are arranged with characteristics;
The encrypted image recognition system according to appendix 1, further comprising: an encryption key generation unit that generates and outputs the encryption key in response to the arrangement information.

(Appendix 3)
The transmitter is
An encrypted image transmission unit that receives the time-division encrypted image frame group and outputs the time-division encrypted image frame group;
An encryption key transmitter that receives the encryption key and outputs the encryption key;
An image / key synchronization control unit that receives the time-division encrypted image frame group and the encryption key, and generates and outputs a synchronization signal between the time-division encrypted image frame group and the encryption key. The encrypted image recognition system according to any one of appendices 1 and 2.

(Appendix 4)
The restoration unit is
A shutter control unit that receives the encryption key and the synchronization signal and generates and outputs a shutter opening / closing signal corresponding to the encryption key and the synchronization signal;
4. The encrypted image recognition system according to claim 1, further comprising: a shutter unit that receives the shutter opening / closing signal and performs opening / closing in accordance with the shutter opening / closing signal.

(Appendix 5)
An encryption unit that generates a time-division encrypted image frame group according to an input original image and a pre-stored encryption key, and outputs the time-division encrypted image frame group and the pre-stored encryption key; ,
A synchronization signal is generated in response to the time-division encrypted image frame group input from the encryption unit and the pre-stored encryption key, and the synchronization signal is transmitted to the time-division encrypted image frame group and the pre- A transmitter for outputting together with the stored encryption key;
A display unit that displays an encrypted image according to the time-division encrypted image frame group input from the transmission unit and the synchronization signal;
An encrypted image recognition system comprising: an encryption key stored in advance; and a restoration unit that restores the encrypted image in response to the synchronization signal.

(Appendix 6)
The encryption unit is
A time division number determining unit that determines and outputs a time division number of a predetermined original image and a time division number of a dummy image;
A time-division image generation unit that generates and outputs a time-division original image frame group from the original image and the time-division number of the original image;
A time-division dummy image generation unit for generating and outputting a time-division dummy image frame group from the number of time divisions of the original image and the dummy image;
The time division original image frame group and the time division dummy image frame group are received, and each image frame of the time division original image frame group and each image frame of the time division dummy image frame group are stored in the pre-stored encryption key. An encrypted image generation unit for generating and outputting the time-division encrypted image frame group arranged in time series by:
The encrypted image recognition system according to appendix 5, further comprising: an encryption key storage unit that stores and outputs the encryption key stored in advance.

(Appendix 7)
The transmitter is
An encrypted image transmission unit that receives the time-division encrypted image frame group and outputs the time-division encrypted image frame group;
An encryption key transmitter that receives the pre-stored encryption key and outputs the pre-stored encryption key;
Image / key synchronization control that receives the time-division encrypted image frame group and the pre-stored encryption key, and generates and outputs a synchronization signal between the time-division encrypted image frame group and the pre-stored encryption key The encrypted image recognition system according to any one of appendices 5 to 6, wherein the encrypted image recognition system comprises:

(Appendix 8)
The restoration unit is
A shutter control unit that receives the encryption key stored in advance and the synchronization signal, and generates and outputs a shutter opening / closing signal corresponding to the encryption key stored in advance and the synchronization signal;
An encrypted image recognition system according to any one of appendices 5 to 7, further comprising: a shutter unit that receives the shutter open / close signal and performs opening / closing in accordance with the shutter open / close signal.
Encryption that generates a time-division encrypted image frame group according to an input original image and a pre-stored encryption key, and outputs the time-division encrypted image frame group and the pre-stored encryption key designation signal And
A synchronization signal is generated in response to the time-division encrypted image frame group input from the encryption unit and the pre-stored encryption key designation signal, and the synchronization signal is converted to the time-division encrypted image frame group. A transmitter for outputting together with the previously stored encryption key designation signal;
A display unit that displays an encrypted image according to the time-division encrypted image frame group input from the transmission unit and the synchronization signal;
In response to the pre-stored encryption key designation signal, a pre-stored encryption key is output, and has a restoration unit that restores the encrypted image from the pre-stored encryption key and the synchronization signal. A featured encrypted image recognition system.

(Appendix 10)
The encryption unit is
A time division number determining unit that determines and outputs a time division number of a predetermined original image and a time division number of a dummy image;
A time-division image generation unit that generates and outputs a time-division original image frame group from the original image and the time-division number of the original image;
A time-division dummy image generation unit for generating and outputting a time-division dummy image frame group from the number of time divisions of the original image and the dummy image;
The time division original image frame group and the time division dummy image frame group are received, and each image frame of the time division original image frame group and each image frame of the time division dummy image frame group are stored in the pre-stored encryption key. An encrypted image generation unit for generating and outputting the time-division encrypted image frame group arranged in time series by:
The encrypted image recognition system according to appendix 9, further comprising: an encryption key storage unit that stores and outputs the prestored encryption key and outputs the prestored encryption key designation signal.

(Appendix 11)
The transmitter is
An encrypted image transmission unit that receives the time-division encrypted image frame group and outputs the time-division encrypted image frame group;
An encryption key transmitter that receives the pre-stored encryption key designation signal and outputs the pre-stored encryption key designation signal;
An image / key that receives the time-division encrypted image frame group and the pre-stored encryption key designation signal and generates and outputs a synchronization signal between the time-division encrypted image frame group and the pre-stored encryption key The encrypted image recognition system according to any one of appendices 9 to 10, further comprising a synchronization control unit.

(Appendix 12)
The restoration unit is
An encryption key storage unit that stores the pre-stored encryption key, receives the pre-stored encryption key designation signal, and outputs the pre-stored encryption key;
A shutter control unit that receives the encryption key stored in advance and the synchronization signal, and generates and outputs a shutter opening / closing signal corresponding to the encryption key stored in advance and the synchronization signal;
The encrypted image recognition system according to any one of appendices 9 to 11, further comprising a shutter unit that receives the shutter opening / closing signal and performs opening / closing in accordance with the shutter opening / closing signal.

(Appendix 13)
The restoration unit includes an encryption key designating unit that designates an encryption key from among a plurality of encryption keys, and generates and outputs a shutter opening / closing signal corresponding to the encryption key designated by the encryption key designating unit and the synchronization signal A shutter control unit,
The encrypted image recognition system according to any one of appendices 1 to 12, further comprising: a shutter unit that receives the shutter opening / closing signal and performs opening / closing according to the shutter opening / closing signal.

(Appendix 14)
15. The encrypted image recognition system according to appendix 14, wherein there are a plurality of restoration units.

(Appendix 15)
Any one of Supplementary notes 1 to 14, wherein the restoration unit is a glasses structure, a visor structure of a helmet, a contact lens structure that is directly inserted into eyes, or a windshield or side glass of an automobile or the like. 2. The encrypted image recognition system according to item 1.

(Appendix 16)
Any one of Supplementary notes 2 to 4, 6 to 8, or 10 to 15, wherein a ratio of colors constituting the dummy image is equal to a ratio of colors constituting the original image The encrypted image recognition system according to the item.

(Appendix 17)
A first step of generating and outputting a time division encrypted image frame group and an encryption key corresponding to the time division encrypted image frame group according to the input original image;
A second step of generating a synchronization signal in response to the time-division encrypted image frame group and the encryption key, and outputting the synchronization signal together with the time-division encrypted image frame group and the encryption key;
A third step of displaying an encrypted image according to the time-division encrypted image frame group and the synchronization signal;
An encrypted image recognition method, comprising: a fourth step of restoring the encrypted image in response to the encryption key and the synchronization signal.

(Appendix 18)
The first step comprises:
Determining and outputting the time division number of a predetermined original image and the time division number of a dummy image; and
Generating and outputting a time-division original image frame group from the original image and the number of time divisions of the original image;
Generating and outputting a time-division dummy image frame group from the number of time divisions of the original image and the dummy image;
The time division original image frame group and the time division dummy image frame group are received, and each image frame of the time division original image frame group and each image frame of the time division dummy image frame group are randomly or a certain rule Generating and outputting sequence information of the time-division encrypted image frame group and the time-division encrypted image frame group arranged with a property;
The encrypted image recognition method according to claim 17, further comprising: generating and outputting the encryption key in response to the arrangement information.

(Appendix 19)
The second step comprises:
Receiving the time division encrypted image frame group and outputting the time division encrypted image frame group;
Receiving the encryption key and outputting the encryption key;
Supplementary notes 17 to 18 including a step of receiving the time-division encrypted image frame group and the encryption key, and generating and outputting a synchronization signal between the time-division encrypted image frame group and the encryption key. The encrypted image recognition method according to claim 1.

(Appendix 20)
The fourth step includes
Receiving the encryption key and the synchronization signal and generating and outputting a shutter opening / closing signal corresponding to the encryption key and the synchronization signal;
The encrypted image recognition method according to any one of appendices 17 to 19, further comprising a step of receiving the shutter open / close signal and performing opening / closing in accordance with the shutter open / close signal.
A first step of generating a time-division encrypted image frame group according to the input original image and a pre-stored encryption key, and outputting the time-division encrypted image frame group and the pre-stored encryption key When,
A synchronization signal is generated in response to the time-division encrypted image frame group and the pre-stored encryption key, and the synchronization signal is output together with the time-division encrypted image frame group and the pre-stored encryption key A second step;
A third step of displaying an encrypted image according to the time-division encrypted image frame group and the synchronization signal;
An encrypted image recognition method comprising: a fourth step of restoring the encrypted image in response to the encryption key stored in advance and the synchronization signal.

(Appendix 22)
The first step comprises:
Determining and outputting the time division number of a predetermined original image and the time division number of a dummy image; and
Generating and outputting a time-division original image frame group from the original image and the number of time divisions of the original image;
Generating and outputting a time-division dummy image frame group from the number of time divisions of the original image and the dummy image;
The time division original image frame group and the time division dummy image frame group are received, and each image frame of the time division original image frame group and each image frame of the time division dummy image frame group are stored in the pre-stored encryption key. Generating and outputting the time-division encrypted image frame group arranged in time series by:
The encrypted image recognition method according to appendix 21, further comprising a step of storing and outputting the encryption key stored in advance.

(Appendix 23)
The second step comprises:
Receiving the time division encrypted image frame group and outputting the time division encrypted image frame group;
Receiving the pre-stored encryption key and outputting the pre-stored encryption key;
Receiving the time-division encrypted image frame group and the pre-stored encryption key, and generating and outputting a synchronization signal between the time-division encrypted image frame group and the pre-stored encryption key. The encrypted image recognition method according to any one of appendices 21 to 22, characterized by:

(Appendix 24)
The fourth step includes
Receiving the encryption key stored in advance and the synchronization signal, and generating and outputting a shutter opening / closing signal corresponding to the encryption key stored in advance and the synchronization signal;
24. The encrypted image recognition method according to any one of appendices 21 to 23, further comprising a step of receiving the shutter open / close signal and performing opening / closing in accordance with the shutter open / close signal.
A time-division encrypted image frame group is generated according to the input original image and a pre-stored encryption key, and the time-division encrypted image frame group and the pre-stored encryption key designation signal are output. And the steps
A synchronization signal is generated in response to the time-division encrypted image frame group and the pre-stored encryption key designation signal, and the synchronization signal is used as the time-division encrypted image frame group and the pre-stored encryption key designation. A second step of outputting together with the signal;
A third step of displaying an encrypted image according to the time-division encrypted image frame group and the synchronization signal;
A fourth step of outputting a pre-stored encryption key in response to the pre-stored encryption key designating signal and restoring the encrypted image from the pre-stored encryption key and the synchronization signal; And a method for recognizing an encrypted image.

(Appendix 26)
The first step comprises:
Determining and outputting the time division number of a predetermined original image and the time division number of a dummy image; and
Generating and outputting a time-division original image frame group from the original image and the number of time divisions of the original image;
Generating and outputting a time-division dummy image frame group from the number of time divisions of the original image and the dummy image;
The time division original image frame group and the time division dummy image frame group are received, and each image frame of the time division original image frame group and each image frame of the time division dummy image frame group are stored in the pre-stored encryption key. Generating and outputting the time-division encrypted image frame group arranged in time series by:
The encrypted image recognition method according to appendix 25, further comprising the steps of: storing and outputting the prestored encryption key; and outputting the prestored encryption key designation signal.

(Appendix 27)
The second step comprises:
Receiving the time division encrypted image frame group and outputting the time division encrypted image frame group;
Receiving the pre-stored encryption key designation signal and outputting the pre-stored encryption key designation signal;
Receiving the time-division encrypted image frame group and the pre-stored encryption key designation signal, and generating and outputting a synchronization signal between the time-division encrypted image frame group and the pre-stored encryption key designation signal The encrypted image recognition method according to any one of appendices 25 to 26, characterized by comprising:

(Appendix 28)
The fourth step includes
Storing the pre-stored encryption key, receiving the pre-stored encryption key designation signal, and outputting the pre-stored encryption key;
Receiving the encryption key stored in advance and the synchronization signal, and generating and outputting a shutter opening / closing signal corresponding to the encryption key stored in advance and the synchronization signal;
The encrypted image recognition method according to any one of appendices 25 to 27, further comprising a step of receiving the shutter opening / closing signal and performing opening / closing according to the shutter opening / closing signal.

(Appendix 29)
The fourth step includes a step of designating an encryption key from among a plurality of encryption keys, and generates and outputs a shutter open / close signal corresponding to the encryption key designated in the encryption key designation step and the synchronization signal. Steps,
29. The encrypted image recognition method according to any one of appendices 17 to 28, further comprising a step of receiving the shutter opening / closing signal and performing opening / closing according to the shutter opening / closing signal.

(Appendix 30)
The encrypted image recognition method according to appendix 29, wherein the fourth step is performed at a plurality of locations.

(Appendix 31)
Supplementary notes 17 to 30 characterized in that the fourth step is performed with a glasses structure, a visor structure of a helmet, a contact lens structure that is directly inserted into the eye, or a windshield or side glass of an automobile or the like. The encrypted image recognition method according to claim 1.

(Appendix 32)
Any one of appendices 18 to 20, 22 to 24, and 26 to 31, wherein a ratio of colors constituting the dummy image is equal to a ratio of colors constituting the original image The encryption image recognition method as described.

1, 2, 5, 6, 7 Encrypted image recognition system 10, 200, 500, 600, 700 Encryption unit 201, 501, 601, 701 Time division number determination unit 202, 502, 602, 702 Time division original image generation Unit 203, 503, 603, 703 Time division dummy image generation unit 204, 504, 604, 704 Encrypted image generation unit 205, 705 Encryption key generation unit 505, 605 Encryption key storage unit 11, 210, 510, 610, 710 Transmission Unit 211, 511, 611, 711 Encrypted image transmission unit 212, 512, 712 Encryption key transmission unit 612 Encryption key designation signal transmission unit 213, 513, 613, 713 Image / key synchronization control unit 12, 220, 520, 620, 720 Display unit 13, 230, 530, 630, 730 Restoration unit 15, 231, 531, 631, 732 Utter control section 14, 232, 532, 632, 733 shutter section 633 encryption key storage section 731 encryption key designation section

Claims (10)

An encryption unit that generates and outputs a time-division encrypted image frame group and an encryption key corresponding to the time-division encrypted image frame group according to the input original image;
A synchronization signal is generated in response to the time division encrypted image frame group and the encryption key input from the encryption unit, and the synchronization signal is output together with the time division encrypted image frame group and the encryption key. A transmission unit;
A display unit that displays an encrypted image according to the time-division encrypted image frame group input from the transmission unit and the synchronization signal;
An encrypted image recognition system comprising: a restoration unit that restores the encrypted image in response to the encryption key and the synchronization signal. The encryption unit is
A time division number determining unit that determines and outputs a time division number of a predetermined original image and a time division number of a dummy image;
A time-division image generation unit that generates and outputs a time-division original image frame group from the original image and the time-division number of the original image;
A time-division dummy image generation unit for generating and outputting a time-division dummy image frame group from the number of time divisions of the original image and the dummy image;
The time division original image frame group and the time division dummy image frame group are received, and each image frame of the time division original image frame group and each image frame of the time division dummy image frame group are randomly or a certain rule An encrypted image generation unit that generates and outputs arrangement information of the time-division encrypted image frame group and the time-division encrypted image frame group that are arranged with characteristics;
The encrypted image recognition system according to claim 1, further comprising: an encryption key generation unit that generates and outputs the encryption key in response to the array information. The transmitter is
An encrypted image transmission unit that receives the time-division encrypted image frame group and outputs the time-division encrypted image frame group;
An encryption key transmitter that receives the encryption key and outputs the encryption key;
An image / key synchronization control unit that receives the time-division encrypted image frame group and the encryption key, and generates and outputs a synchronization signal between the time-division encrypted image frame group and the encryption key. The encrypted image recognition system according to any one of claims 1 to 2. The restoration unit is
A shutter control unit that receives the encryption key and the synchronization signal and generates and outputs a shutter opening / closing signal corresponding to the encryption key and the synchronization signal;
4. The encrypted image recognition system according to claim 1, further comprising: a shutter unit that receives the shutter opening / closing signal and performs opening / closing in accordance with the shutter opening / closing signal. 5. An encryption unit that generates a time-division encrypted image frame group according to an input original image and a pre-stored encryption key, and outputs the time-division encrypted image frame group and the pre-stored encryption key; ,
A synchronization signal is generated in response to the time-division encrypted image frame group input from the encryption unit and the pre-stored encryption key, and the synchronization signal is transmitted to the time-division encrypted image frame group and the pre- A transmitter for outputting together with the stored encryption key;
A display unit that displays an encrypted image according to the time-division encrypted image frame group input from the transmission unit and the synchronization signal;
An encrypted image recognition system comprising: an encryption key stored in advance; and a restoration unit that restores the encrypted image in response to the synchronization signal. The encryption unit is
A time division number determining unit that determines and outputs a time division number of a predetermined original image and a time division number of a dummy image;
A time-division image generation unit that generates and outputs a time-division original image frame group from the original image and the time-division number of the original image;
A time-division dummy image generation unit for generating and outputting a time-division dummy image frame group from the number of time divisions of the original image and the dummy image;
The time division original image frame group and the time division dummy image frame group are received, and each image frame of the time division original image frame group and each image frame of the time division dummy image frame group are stored in the pre-stored encryption key. An encrypted image generation unit for generating and outputting the time-division encrypted image frame group arranged in time series by:
6. The encrypted image recognition system according to claim 5, further comprising an encryption key storage unit for storing and outputting the encryption key stored in advance. The restoration unit includes an encryption key designating unit that designates an encryption key from among a plurality of encryption keys, and generates and outputs a shutter opening / closing signal corresponding to the encryption key designated by the encryption key designating unit and the synchronization signal A shutter control unit,
The encrypted image recognition system according to claim 1, further comprising a shutter unit that receives the shutter opening / closing signal and performs opening / closing according to the shutter opening / closing signal.   The encrypted image recognition system according to claim 7, wherein there are a plurality of restoration units.   9. The restoration part according to claim 1, wherein the restoration part is a glasses structure, a visor structure of a helmet, a contact lens structure that is directly inserted into an eye, or a windshield or a side glass of an automobile or the like. The encrypted image recognition system according to claim 1.   The encryption according to any one of claims 2 to 4, or 6 to 9, wherein a ratio of colors constituting the dummy image is equal to a ratio of colors constituting the original image. Image recognition system.

Images