JP2023177179A - storage medium - Google Patents

Abstract

To provide a storage medium for recording a computer program to be used in a beverage glass system by which a large-sized image is projected on glass side surfaces.SOLUTION: A storage medium records a computer program to be used in a beverage glass system by which one original image is displayed with the use of n pieces (n is an integer of two or more) of beverage glasses and images. The beverage glass system includes: an image division section for dividing the original image into first to n-th images; first to n-th beverage glasses; first to n-th video display devices; and first to n-th transparent sections for visually recognizing the first to n-th images through the first to n-th beverage glasses. An enlarged image of the original image is displayed on the first to n-th transparent sections by the first to n-th images.SELECTED DRAWING: Figure 1

Description

The present invention relates to a drinking glass system and a storage medium used in the drinking glass system.

Glasses have been developed that have various functions in addition to the function of holding beverages.
For example, Patent Documents 1 to 3 disclose drinking glasses invented by the inventor of the present application. This drinking glass consists of a glass body, a storage part that extends inward from the bottom of the glass body to store a mobile phone or smartphone, and a storage part that extends inward from the side of the glass body and passes through mobile phone radio waves. It is equipped with a waveguide section for controlling the waveguide. Even when the glass body is filled with a beverage, this beverage glass can transmit radio waves from a mobile phone to the outside through the waveguide, allowing wireless communication.
Patent Document 4 discloses a drinking glass invented by the inventor of the present application. This beverage presentation glass is equipped with an image display device fixed to the side of the glass and a reflective mirror placed inside the glass body, and can create an effect that simulates the image of the image display device by projecting it inside the glass. It is a possible glass.

Patent No. 6337256 Patent No. 6406742 Patent No. 6432960 Patent No. 6488049

However, in the beverage presentation glasses of Patent Documents 1 to 4, it is impossible to project a large-sized image on the side surface of the glass.

In view of the above problems, it is an object of the present invention to provide a drinking glass system capable of projecting a large-sized image on the side surface of the glass.
Another object of the present invention is to provide a storage medium storing a computer program for use in the drinking glass system.

The drinking glass system of the present invention is a drinking glass system that displays one original image using n (n is an integer of 2 or more) drinking glasses and images, and the original image is an image dividing unit that divides into n images, first to nth drinking glasses corresponding to the first to nth images, and first to nth drinking glasses corresponding to the first to nth images; a video display device, a first to nth fixing mechanism for fixing the first to nth drinking glasses and the first to nth video display devices, and the first to nth images; and first to nth transparent parts for viewing through the first to nth drinking glasses, and all of the first to nth drinking glasses have a bottomed cylindrical shape having an upper opening. The first to nth transparent parts are all curved in the horizontal direction, and the first to nth video display devices are each fixed to a side surface of the first to nth drinking glass. The first to nth images are respectively displayed on the first to nth video display devices, and the first to nth transparent parts and the first to nth images are There is a one-to-one correspondence, and the corresponding first to n images are transmitted through the first to n-th transparent parts, and the first to n-th beverage glasses are filled with beverages. When the first to nth drinking glasses are arranged in a horizontal line or a vertical line, an enlarged image of the original image is displayed on the first to nth transparent parts by the first to nth images. Features.
Further, at least one of the first to n-th drinking glasses is provided with a lid that closes the upper opening.
Further, the image dividing section is characterized in that it is computer software or a computer program.
Moreover, it is characterized by comprising computer software or a computer program for displaying the first to n-th images on the corresponding first to n-th video display devices, respectively.
Further, the original image is an image of each frame constituting a moving image.
The invention is also characterized in that the original image is an image of a man and woman kissing.
The recording medium of the present invention is a storage medium storing a computer program used in the above-mentioned drinking glass system, and the computer program is stored in the first to n-th video display devices respectively corresponding to the first to n-th video display devices. outputting or displaying an image, and when the first to nth drinking glasses are lined up horizontally or vertically when filled with beverages, the first to nth drinking glasses display the first to nth images. It is characterized in that an enlarged image of the original image is displayed on the first to nth transparent parts.
Further, the computer program divides the original image obtained from a computer memory into the first to nth images, and the first to nth drinking glasses are configured to divide the first to nth drinking glasses into the first to nth drinking glasses when filled with a beverage. When the glasses are arranged horizontally or vertically, an enlarged image of the original image is displayed on the first to nth transparent parts by the first to nth images.
Further, the computer program receives a signal from a sensor capable of detecting that the first to n-th drinking glasses are arranged, and the computer program receives a signal from a sensor that can detect that the first to nth drinking glasses are arranged, and the computer program outputting or displaying first to nth images; and when the first to nth drinking glasses are arranged horizontally or vertically in a row when filled with beverages, the first to nth drinking glasses are arranged horizontally or vertically; An enlarged image of the original image is displayed on the first to nth transparent parts by the nth image. The computer program also inputs the number of the first to nth drinking glasses. The computer program may divide the original image obtained from the computer memory based on the number of drinking glasses.

The drinking glass system of the present invention is a system that displays or composes (or forms) an original image (strictly speaking, an enlarged image of the original image) using a plurality of (two or more) video display devices and drinking glasses. In principle, the more glasses and video display devices you have, the larger the image size can be.
The drinking glass system of the present invention is capable of displaying an enlarged image of an original image on the side surface of the glass (the transparent part of the side surface of the glass) by using the lens effect of the horizontally curved beverage in the drinking glass. Moreover, the enlarged image can be colored by the beverage in the drinking glass.

A perspective view showing a drinking glass system according to a first embodiment A front view showing a drinking glass system according to the first embodiment Front view showing an example of a drinking glass system with a lid Front view showing an example of a drinking glass system where the original image is a kiss image Flowchart diagram of computer program for drinking glass system Flowchart diagram of computer program for drinking glass system Flowchart diagram of computer program for drinking glass system Flowchart diagram of computer program for drinking glass system Flowchart diagram of computer program for drinking glass system

[First embodiment of beverage glass system]
DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of a drinking glass system of the present invention will be described below with reference to the drawings.
The drinking glass system 1 of the present invention is a drinking glass system that displays one original image using n (n is an integer of 2 or more) drinking glasses and images. For this reason, an example will be shown in which n=2 (original image 100 is divided into two).
As shown in FIGS. 1 and 2, the beverage glass system 1 in the case of n=2 includes an image dividing section 200 that divides the original image 100 into a first image 82 and a second image 92, and a first beverage glass system 1. The drinking glass 10, the second drinking glass 20, the first video display device 80, the second video display device 90, and the first video display device 80 are fixed to the first drinking glass 10. The first fixing mechanism 15 , the second fixing mechanism 25 that fixes the second video display device 90 to the second drinking glass 20 , and the first image 82 visible through the first drinking glass 10 It is generally composed of a first transparent part 12 for viewing the second image 92 through the second drinking glass 20, and a second transparent part 22 for viewing the second image 92 through the second drinking glass 20.
The image dividing unit 200 is used to divide the original image 100 into a first image 82 and a second image 92. The image dividing unit 200 may be embedded in the bottom or wall of the first drinking glass 10 or the second drinking glass 20 in the form of a dedicated IC, ASIC, or the like. Further, it may be implemented as computer software or a computer program in a computer inside or outside the housing of the first video display device 80 or the second video display device 90. Furthermore, the image dividing section 200 may be implemented as computer software on a cloud server. The image dividing unit 200 can divide the original image 100 existing (or stored) in a computer (ordinary personal computer, mobile phone computer, server computer, etc.) into a first image 82 and a second image 92. It doesn't matter where it is implemented in such a form. In the examples shown in FIGS. 1 and 2, the original image 100 is divided into left and right parts in the horizontal direction (in the examples shown in FIGS. 1 and 2, the character image of A is used as the original image 100 and the first image is 82 and a second image 93). The original image 100 divided into the first image 82 and the second image 92 is constructed (or reconstructed) by arranging the first drinking glass 10 and the second drinking glass 20 in a horizontal line. Note that the original image 100 may be configured (or reconfigured) by dividing the original image 100 in the vertical direction and arranging the drinking glass 10 and the second drinking glass 20 in a vertical line. Furthermore, in the examples of FIGS. 1 and 2, the image dividing unit 200 transfers the data of the first image 82 and the second image 92 to the first video display device 80 and the second video display device 90 using radio waves. However, the image dividing unit 200 and the first video display device 80 and the second video display device 90 may be directly connected by wire or the like.
The first drinking glass 10 and the second drinking glass 20 are bottomed cylindrical bodies having an upper opening, and examples of the shapes of the first drinking glass 10 and the second drinking glass 20 are as follows. , a normal cup-shaped shape curved in the horizontal direction as shown in FIG. 1, and a beer mug-shaped (or mug-shaped) shape provided with a handle 16 (or handle 26). Examples of the material for the first drinking glass 10 and the second drinking glass 20 include glass and transparent resin. The first drinking glass 10 and the second drinking glass 20 are bottomed cylindrical bodies (cylindrical shapes curved in the horizontal direction), and the beverage L is filled inside thereof. A first video display device 80 is fixed to the first drinking glass 10, and a second video display device 90 is similarly fixed to the second drinking glass 20.
The first video display device 80 is a video display device for displaying a first image 82. Similarly, the second video display device 90 is a video display device for displaying a second image 92. In the drinking glass system 1 of the present invention, as shown in FIG. 1, each divided image (in the example of FIG. 1, the first image 82 and the second image 92) of the original image 100 corresponding to each video display device is displayed. be done.
The first fixing mechanism 15 is a fixing mechanism for fixing the first video display device 80 to the side surface of the first drinking glass 10 , and the second fixing mechanism 25 is a fixing mechanism for fixing the first video display device 80 to the side surface of the first drinking glass 10 . This is a fixing mechanism for fixing the second video display device 90 to the side surface. The first fixing mechanism 15 and the second fixing mechanism 25 may be any type of fixing mechanism as long as they can fix each video display device to each drinking glass. For the fixing mechanism 25), not only the pocket mechanism as shown in FIG. 1 but also a screw mechanism, a magnet mechanism, etc. may be used.
The first transparent part 12 (provided on the side surface of the first drinking glass 10 ) is a transparent part. Similarly, the second transparent portion 22 is provided on the side surface of the second drinking glass 20 for viewing the image (second image 92) of the second video display device 90 through the second drinking glass 20. ) It is a transparent part. The first transparent part 12 and the second transparent part 22 transmit each divided image of the original image 100 (in the example of FIG. 1, the first image 82 and the second image 92) to the outside of each drinking glass. Moreover, the first transparent part 12 and the second transparent part 22 are curved in the horizontal direction. Note that the first drinking glass 10 (or the second drinking glass 20) in FIG. 22). It should be noted that the sides of the first drinking glass 10 and the second drinking glass 20 do not necessarily all need to be transparent (that is, transparent parts), and the user U can see through the glasses (attached to the side of the drinking glass). Other areas do not need to be transparent as long as the images on each video display device can be viewed.

I would like to add some additional information about the first transparent part 12 and the second transparent part 22.
As shown in FIG. This is a transparent area provided on the side of the glass 10 (or the second drinking glass 20) for viewing through the glass 10 (or the second drinking glass 20). The user U can view the first image 82 (the first It is possible to visually recognize the second image 92 (the image on the video display device 80) and the second image 92 (the image on the second video display device 90) from outside the first drinking glass 10 and the second drinking glass 20. .
Note that the broken line P1 in FIG. The first image 82 displayed on the video display device 80 (more precisely, the video display surface 81) passes through (or passes through) the beverage L in the first drinking glass 10 and the first transparent portion 12. and reaches the outside of the first drinking glass 10. Note that, similarly to the optical path P1, the optical path P2 in FIG. There is something illustrated for this purpose.
Since the first drinking glass 10 and the second drinking glass 20 have a cylindrical shape (like a normal glass or mug), the first transparent part 12 and the second transparent part 22 (i.e. The side surfaces of the first drinking glass 10 and the second drinking glass 20 are curved in the horizontal direction. Therefore, the beverage L in these beverage glasses is also inevitably curved in the horizontal direction as shown in FIG. Since the refractive index of light in water (approximately 1.33) is larger than that of air (approximately 1.0003), the beverage L curved in the horizontal direction acts as a lens, so the first The image 82 and the second image 92 are enlarged in the horizontal direction. In other words, the curved beverage L acts as a light refractive medium for a cylindrical lens (or a biconvex lens).
As shown in FIG. 1, the user U is inside the first drinking glass 10 or the second drinking glass 20 through the first transparent part 12 or the second transparent part 22 that is curved in the horizontal direction. By viewing the first image 82 and the second image 92 through the curved beverage L (that is, through the beverage lens), it is possible to view the enlarged image 83 of the first image and the enlarged image 93 of the second image. It is. In other words, the enlarged image 101 of the original image (the enlarged image 83 of the first image and the enlarged image of the second image An enlarged image of the original image consisting of 93 images is displayed.
In the beverage glass system 1 of the present invention, since the beverage L itself functions as a lens, there is no need to provide a separate magnifying lens on the beverage glass, and the first beverage glass 10 and the second beverage glass 20 It is possible to reduce the weight. The image magnification of the first image 82 and the second image 92 is different from that of the first drinking glass 10 (strictly speaking, the first transparent part 12) and the second drinking glass 20 (strictly speaking, the second This can be increased by reducing the radius of curvature of the transparent portion 22 (that is, the radius of curvature of the beverage L, which is a lens). This is based on the basic principle of optics and lenses that the smaller the radius of curvature of the lens, the greater the magnification of the lens (for details, please refer to specialized books on lenses and optics).

As shown in FIG. 2, the drinking glass system 1 of the present invention has a lens effect of the beverage inside the first drinking glass 10 and the second drinking glass 20. By simply arranging the drinking glasses 20 horizontally in a row, the first image 82 (strictly speaking, an enlarged image 83 of the first image) and the second image 92 (strictly speaking, an enlarged image 93 of the second image) can be used to create an original image. It is possible to display (or project) an enlarged image 101 of an image on the first transparent section 12 and the second transparent section 22.
In FIGS. 1 and 2, the drinking glass system 1 of the present invention has been explained by showing an example where n=2 (that is, when the original image 100 is divided into two pieces). However, when n is an integer larger than 2, for example, Even if n=3 (that is, when 100 original images are divided into 3 pieces) or n=100 (that is, when 100 original images are divided into 100 pieces), the number of drinking glasses and video display devices increases accordingly. The basic configuration and principle are exactly the same as in the case where n=2.
As shown in FIGS. 1 and 2, the drinking glass system 1 of the present invention uses n drinking glasses (n is an integer of 2 or more) and images (or video display devices) to create one original image 100 (or more). Strictly speaking, since this is a method of displaying (or configuring) an enlarged image 101 of the original image, it is possible to project a much larger image than a method using a single video display device or drinking glass. (In principle, the more you increase the number of video display devices and drinking glasses, the larger the image size can be without reproduction). Additionally, the synergy with the lens effect of the curved (horizontally) beverage within each glass allows for the projection of images of very large size.
Since the beverage glass system 1 of the present invention uses the beverage L itself as a light refractive medium of the lens, an original image 100 (strictly speaking, an enlarged image 101 of the original image) that is visible to the user U due to the color of the beverage L in the glass is used. ) can be colored. For example, if amber-colored whiskey is used as the beverage L, it is possible to render the enlarged image 101 of the original image seen by the user U in an amber color.
Depending on the outside temperature and humidity, when a cold beverage is poured into a drinking glass, condensation occurs (water droplets form on the surface of the glass), so either the first drinking glass 10 or the second drinking glass 20 is used. By wiping off the dew condensation, it is possible to keep either the left or right halves of the original image 100 (strictly speaking, the enlarged image 101 of the original image) masked by dew condensation.
The beverage glass system 1 of the present invention creates an original image by filling only one of the first beverage glass 10 and the second beverage glass 20 with a beverage with low light transmittance (for example, red wine, coffee, etc.). It is also possible to mask either the left or right half of the image 100 (more specifically, the enlarged image 101 of the original image).

In FIG. 1 and FIG. 2, the drinking glass system 1 of the present invention has been explained by showing an example where n=2 (that is, when the original image 100 is divided into two pieces), but even when n is an integer larger than 2, The drinking glass system 1 of the present invention is basically the same as the case where n=2, only that the number of drinking glasses and video display devices is increased by the number of divisions of the original image 100.
The drinking glass system of the present invention is a drinking glass system that displays one original image using n (n is an integer of 2 or more) drinking glasses and images, and the drinking glass system of the present invention includes: An image dividing unit (in the example of FIG. 1, the image dividing unit divides the original image (original image 100 in the example of FIG. 1) into first to nth images (first image 82 and second image 92 in the example of FIG. 1). image dividing unit 200), and first to nth drinking glasses (the example of FIG. 1) corresponding to the first to nth images (first image 82 and second image 92 in the example of FIG. 1). In the example shown in FIG. to the n-th video display device (in the example of FIG. 1, the first video display device 80 and the second video display device 90), and the first to n-th drinking glasses (in the example of FIG. 1, the first video display device 80 and the second video display device 90). (the drinking glass 10 and the second drinking glass 20) and the first to nth video display devices (in the example of FIG. 1, the first video display device 80 and the second video display device 90) are each fixed. the first to nth fixing mechanisms (first fixing mechanism 15 and second fixing mechanism 25 in the example of FIG. 1) and the first to nth images (the first image in the example of FIG. 82 and a second image 92) through the first to nth drinking glasses (in the example of FIG. 1, the first transparent part 12 and the second transparent part The first to nth drinking glasses (the first drinking glass 10 and the second drinking glass 20 in the example of FIG. 1) all have upper openings (the upper opening in the example of FIG. 1). It is a bottomed cylindrical body having an opening 11 and an upper opening 21), and the first to nth transparent parts (in the example of FIG. 1, the first transparent part 12 and the second transparent part 22) are all horizontal. The first to nth video display devices (in the example of FIG. 1, the first video display device 80 and the second video display device 90) are curved in the first to nth drinking glasses. (in the example of FIG. 1, the first drinking glass 10 and the second drinking glass 20) are fixed to the side surfaces of the first to nth video display devices (in the example of FIG. The corresponding first to nth images (in the example of FIG. 1, the first image 82 and the second image 92) are displayed on the video display device 80 and the second video display device 90, respectively. The first to nth transparent parts (the first transparent part 12 and the second transparent part 22 in the example of FIG. 1) and the first to nth images (the first image 82 and the second transparent part in the example of FIG. 1) 2 images 92) have a one-to-one correspondence, and the first to nth transparent parts (in the example of FIG. 1, the first transparent part 12 and the second transparent part 22) correspond to each other. The first to nth images (the first image 82 and the second image 92 in the example of FIG. 1) are transmitted through the first to nth drinking glasses (the first image 82 and the second image 92 in the example of FIG. 1). When the first to nth drinking glasses are lined up horizontally or vertically when filled with beverages, the first to nth images (in the example of FIG. 1 image 82 and second image 92), the enlarged image of the original image (the enlarged image 101 of the original image in the example of FIG. 1) becomes the It is characterized in that it is displayed on the transparent section 12 and the second transparent section 22).

The beverage glass system 1 of the present invention displays the first to nth images (the first image 82 and the second image 92 in the example of FIG. 1) on the first to nth video display devices (in the example of FIG. In example 1, computer software or a computer program for displaying on the first video display device 80 and the second video display device 90 may be provided. The storage location (implementation location) of these computer software or computer programs may be anywhere, and for example, they may be implemented in a computer inside or outside the casing of the first video display device 80 and the second video display device 90. However, it may be implemented in a computer of a cloud server, storage server, or image distribution server. Further, it may be implemented in an ASIC embedded in a drinking glass or a dedicated IC computer.

I would like to add some additional information about the shape of the drinking glass used in the drinking glass system 1 of the present invention.
The shape of the drinking glass used in the drinking glass system 1 of the present invention is not limited to a normal cup or mug shape such as the first drinking glass 10 and the second drinking glass 20 as shown in FIG. It may also have a bottle shape with a lid 30 that closes the upper opening as shown in FIG.
As shown in FIG. 3, either the first drinking glass 10 or the second drinking glass 20 may be provided with a lid 30, or the first drinking glass 10 and the second drinking glass 20 may be provided with a lid 30. Both may be provided with lids 30.

I would like to add some additional information about the original image 100.
The original image 100 may be an image of each frame that makes up a moving image (that is, a still image of one frame of each frame that makes up a moving image). Further, the original image 100 may be any image existing in a computer (more precisely, stored in a computer memory, database, computer storage medium, etc.). The original image 100 may be an image or a moving image taken with a camera or a video camera, or each frame image of a moving image downloaded from a computer such as a cloud server.
As shown in FIG. 4, the original image 100 may be an image of a man and woman kissing. By doing this, when the first drinking glass 10 and the second drinking glass 20 are arranged in a horizontal line (horizontal direction), the image of a man and woman kissing (more precisely, the enlarged image 101 of the original image) will be displayed as the first drinking glass. Because it is reflected on the side surfaces of the drinking glass 10 and the second drinking glass 20 (in the example of FIG. 4, the first transparent part 12 and the second transparent part 22), the first drinking glass 10 and the second drinking glass 20 are It is possible to reproduce (or compose, or form) an image of a man and woman kissing only when the drinking glasses 20 of No. 2 are brought close to each other. ).
In addition, in FIGS. 1, 2, 3, and 4, the original image 100 is divided in the horizontal direction (horizontal direction), and the divided images are shown as side surfaces (transparent parts) of a plurality of drinking glasses arranged in a horizontal line (horizontal direction). ), but in the drinking glass system 1 of the present invention, the original image 100 is divided in the vertical direction (vertical direction) and divided into a single column (vertical direction). The display may be reconstructed using the side surfaces (transparent parts) of a plurality of drinking glasses arranged side by side. Furthermore, the original image 100 may be divided by combining horizontal (horizontal) and vertical (vertical) divisions (in this case, by arranging the drinking glasses horizontally and vertically, the original image 100 can be divided into 100).

I would also like to add some information regarding the orientation of the video display device when it is fixed to a drinking glass.
Since the drinking glass system 1 of the present invention is a system in which the original image 100 is visually recognized through each drinking glass (strictly speaking, through each transparent part), the first image display device 80 as shown in FIG. is fixed to the side surface of the first drinking glass 10 with its image display surface 81 facing the drinking glass 10 (Similarly, the second image display device 90 is fixed to the side surface of the second drinking glass 10). When it is fixed to the side of the drinking glass 20, it is fixed with the image display surface 91 facing the drinking glass 20). That is, in the drinking glass system 1 of the present invention, the first to nth video display devices are fixed to each drinking glass so that their images are transmitted through each transparent part.

FIG. 5 shows a flowchart of a computer program used in the drinking glass system 1 of the present invention. In STEP 1, the first image 82 is output or displayed on the first video display device 80, and in STEP 2, the second image 92 is output or displayed on the second video display device 90, and then the program ends (that is, in STEP 1 (In STEP 2, the corresponding first to nth images are output or displayed on the first to nth video display devices.)
FIG. 6 shows a flowchart of a computer program used in the drinking glass system 1 of the present invention. After dividing the original image acquired from the computer memory in STEP 1 into first to nth images (first image 82 and second image 92 in the example of FIG. 6), the program ends.
FIG. 7 shows a flowchart of a computer program used in the drinking glass system 1 of the present invention. In STEP 1, the original image acquired from the computer memory is divided into a first image 82 and a second image 92, in STEP 2, the first image 82 is output or displayed on the first video display device 80, and in STEP 3, the second image 82 is divided into a first image 82 and a second image 92. The program ends after outputting or displaying the second image 92 on the video display device 90 of.

After detecting (or receiving) a sensor or a button press signal from the user and detecting that the drinking glasses are arranged vertically or horizontally (planarly), the programs shown in FIGS. 5, 6, and 7 are executed. may be executed.
The sensor can be any sensor that can detect that glasses are lined up, such as a sound microphone sensor (detects that glasses are lined up by the sound of the glasses colliding), a camera sensor (detects that glasses are lined up by image analysis), or a distance sensor. sensor (detects when the glasses are lined up by measuring the distance between each glass), acceleration sensor (detects when the glasses are lined up by detecting the impact when the glasses collide), button sensor (detects when the glasses are lined up visually by the user) For example, a button or a touch panel button to notify the computer that the items have been arranged.
An example of a flowchart in that case (when receiving a signal from a sensor that can detect that glasses are lined up) is shown in FIG.
In STEP 1, a signal from a sensor capable of detecting that glasses (the first to n-th drinking glasses) are arranged is received, and in STEP 2, the first to n-th video display devices respectively correspond to the first to n-th video display devices. The process ends after outputting or displaying the n-th image (that is, displaying an enlarged image of the original image on the side surface of the first to n-th drinking glasses).

The computer may be configured to be able to obtain the number n of drinking glasses input by the user (that is, the number of divisions of the original image projected on the side of the drinking glass).
An example of a flowchart in that case (in a case where the user is allowed to input the number n of drinking glasses) is shown in FIG.
In STEP 1, the number of drinking glasses (that is, the number of divisions n of the original image) input by the user (in advance) is acquired from the computer memory, and in STEP 2, the original image acquired from the computer memory is calculated as the number of drinking glasses. Divide and finish based on.

The computer programs of the flowcharts shown in FIGS. 5, 6, 7, 8, and 9 may be stored in known storage media such as flash memory, DRAM, magnetic storage media, optical storage media, etc. Further, it may be installed (saved) in the form of application software in a memory in the same housing as the first video display device 80 and the second video display device 90. The computer algorithms in the flowcharts shown in FIGS. 5, 6, 7, 8, and 9 are examples, and other algorithms may be used. Note that the computer algorithms in the flowcharts shown in Figures 5, 6, and 7 are examples of n = 2 (that is, when dividing the original image 100 into two), but the same applies when n is a larger integer. It can be handled using an algorithm.
The computer program of the flowcharts shown in FIGS. 5, 6, 7, 8, and 9 is a computer program used in the beverage glass system 1 of the present invention, and when the first to nth beverage glasses are filled with beverages. When the first to nth drinking glasses are arranged in a horizontal line or a vertical line, an enlarged image of the original image is displayed on the first to nth transparent parts by the first to nth images. Features.

The present invention is a drinking glass system that allows an original image to be enlarged and displayed or formed or reconstructed into a very large size image using two or more drinking glasses and a video display device. . As described above, the present invention has industrial applicability.

U User L Beverage (liquid)
P1 Optical path P2 Optical path 1 Drinking glass system 10 First drinking glass 11 Top opening 12 First transparent part 15 First fixing mechanism 16 Handle 20 Second drinking glass 21 Top opening 22 Second transparent part 25 Second fixing mechanism 26 Handle 30 Lid 80 First video display device 81 Video display surface 82 First image 83 Enlarged image of the first image 90 Second video display device 91 Video display surface 92 Second image 93 Enlarged image 100 of the second image Original image 101 Enlarged image 200 of the original image Image division section

The present invention is a drinking glass system.Contains computer programs used forRegarding storage media.

SUMMARY OF THE INVENTION In view of the above problems, an object of the present invention is to provide a storage medium storing a computer program for use in a drinking glass system capable of projecting a large-sized image on the side surface of the glass.

The storage medium of the present invention is a storage medium that stores a computer program used in a drinking glass system that displays one original image using n (n is an integer of 2 or more) drinking glasses and images, and The drinking glass system includes an image dividing unit that divides the original image into first to nth images, first to nth drinking glasses corresponding to the first to nth images, and the first to nth drinking glasses. to n-th video display devices corresponding to n-th images, and first to n-th video display devices for fixing the first to n-th drinking glasses and the first to n-th video display devices, respectively. an n-th fixing mechanism; and a first to n-th transparent section for viewing the first to n-th images through the first to n-th drinking glasses; All of the drinking glasses are bottomed cylindrical bodies having an upper opening, the first to nth transparent parts are all curved in the horizontal direction, and the first to nth video display devices are each of the first to nth transparent parts. The first to nth images are respectively fixed to the side surfaces of the first to nth drinking glasses, and the first to nth images are respectively displayed on the first to nth video display devices, and the first to nth images are respectively fixed to the side surfaces of the first to nth drinking glasses. The n transparent parts and the first to n-th images have a one-to-one correspondence, and the corresponding first to n-th images are transmitted through the first to n-th transparent parts, When the first to nth drinking glasses are filled with a beverage, when the first to nth drinking glasses are arranged in a horizontal line or a vertical line, an enlarged image of the original image is created by the first to nth images. the computer program receives a signal from a sensor capable of detecting that the first to nth drinking glasses are lined up; outputting or displaying the first to nth images respectively corresponding to the first to nth video display devices; When the glasses are arranged in a row horizontally or vertically, an enlarged image of the original image is displayed on the first to nth transparent portions using the first to nth images.
The storage medium of the present invention is a storage medium that stores a computer program used in a drinking glass system that displays one original image using n (n is an integer of 2 or more) drinking glasses and images, and The drinking glass system includes an image dividing unit that divides the original image into first to nth images, first to nth drinking glasses corresponding to the first to nth images, and the first to nth drinking glasses. to n-th video display devices corresponding to n-th images, and first to n-th video display devices for fixing the first to n-th drinking glasses and the first to n-th video display devices, respectively. an n-th fixing mechanism; and a first to n-th transparent section for viewing the first to n-th images through the first to n-th drinking glasses; All of the drinking glasses are bottomed cylindrical bodies having an upper opening, the first to nth transparent parts are all curved in the horizontal direction, and the first to nth video display devices are each of the first to nth transparent parts. The first to nth images are respectively fixed to the side surfaces of the first to nth drinking glasses, and the first to nth images are respectively displayed on the first to nth video display devices, and the first to nth images are respectively fixed to the side surfaces of the first to nth drinking glasses. The n transparent parts and the first to n-th images have a one-to-one correspondence, and the corresponding first to n-th images are transmitted through the first to n-th transparent parts, When the first to nth drinking glasses are filled with a beverage, when the first to nth drinking glasses are arranged in a horizontal line or a vertical line, an enlarged image of the original image is created by the first to nth images. the first to nth transparent portions , the computer program inputting the number of the first to nth drinking glasses, and the computer program displaying the original images obtained from the computer memory; It is characterized by dividing based on the number of drinking glasses.

INDUSTRIAL APPLICABILITY The present invention is a storage medium storing a computer program for use in a drinking glass system capable of projecting a large-sized image on the side of a glass, and has industrial applicability.

Claims (10)

A drinking glass system that displays one original image using n drinking glasses (n is an integer of 2 or more) and images,
an image dividing unit that divides the original image into first to nth images;
first to nth drinking glasses corresponding to the first to nth images;
first to nth video display devices corresponding to the first to nth images;
first to nth fixing mechanisms for fixing the first to nth drinking glasses and the first to nth video display devices, respectively;
a first to nth transparent portion for viewing the first to nth images through the first to nth drinking glasses;
The first to nth drinking glasses are all bottomed cylindrical bodies having an upper opening,
The first to nth transparent parts are all curved in the horizontal direction,
The first to nth video display devices are each fixed to a side surface of the first to nth drinking glasses,
The first to nth images are displayed on the first to nth video display devices, respectively,
The first to n-th transparent parts and the first to n-th images have a one-to-one correspondence,
The first to nth images corresponding to the first to nth transparent parts are transmitted through the first to nth transparent parts,
When the first to nth drinking glasses are filled with a beverage, when the first to nth drinking glasses are arranged in a horizontal line or a vertical line, an enlarged image of the original image is created by the first to nth images. A drinking glass system characterized by displaying information on the first to nth transparent parts. The drinking glass system according to claim 1, wherein at least one of the first to nth drinking glasses is provided with a lid that closes the upper opening. Drinking glass system according to any one of claims 1 to 2, characterized in that the image segmentation unit is computer software or a computer program. 4. The computer program according to claim 1, further comprising computer software or a computer program for displaying the first to nth images on the corresponding first to nth video display devices. Drinking glass system as described. The drinking glass system according to any one of claims 1 to 4, wherein the original image is an image of each frame constituting a moving image. The drinking glass system according to any one of claims 1 to 5, wherein the original image is an image of a man and a woman kissing. A storage medium storing a computer program for use in the drinking glass system according to any one of claims 1 to 6,
The computer program outputs or displays the first to nth images corresponding to the first to nth video display devices, respectively;
When the first to nth drinking glasses are filled with a beverage, when the first to nth drinking glasses are arranged in a horizontal line or a vertical line, an enlarged image of the original image is created by the first to nth images. A storage medium characterized by being displayed on first to nth transparent parts. A storage medium storing a computer program for use in the drinking glass system according to any one of claims 1 to 6,
The computer program divides the original image obtained from a computer memory into the first to nth images;
When the first to nth drinking glasses are filled with a beverage, when the first to nth drinking glasses are arranged in a horizontal line or a vertical line, an enlarged image of the original image is created by the first to nth images. A storage medium characterized by being displayed on first to nth transparent parts. A storage medium storing a computer program for use in the drinking glass system according to any one of claims 1 to 6,
the computer program receives a signal from a sensor capable of detecting that the first to nth drinking glasses are arranged;
The computer program outputs or displays the first to nth images corresponding to the first to nth video display devices, respectively;
When the first to nth drinking glasses are filled with a beverage, when the first to nth drinking glasses are arranged in a horizontal line or a vertical line, an enlarged image of the original image is created by the first to nth images. A storage medium characterized by being displayed on first to nth transparent parts. A storage medium storing a computer program for use in the drinking glass system according to any one of claims 1 to 6,
the computer program inputting the number of the first to nth drinking glasses;
A storage medium, wherein the computer program divides the original image obtained from a computer memory based on the number of drinking glasses.