JP2020016869A - Digital telescopic eyeglasses - Google Patents

Abstract

To achieve eyeglasses and magnifying glass that enable videos to be freely magnified and contracted over a distance of a wide range, wearing like eyeglasses.SOLUTION: A video of a camera is made viewable like eyeglasses by configuring to: mount a right-eye camera 001 and left-eye camera 002 to an eye position of eyeglasses; mount a right-eye liquid crystal panel 009 and left-eye liquid crystal panel 010 on a rear side; and view a display via a right-eye convex lens 011 and left-eye convex lens 012. Further, contact lenses having a function equivalent to the convex lens are worn, and thereby thinning becomes made possible without using the convex lens. By enabling an image processing device to switch the video of the camera to a magnifying screen by a one touch, due to a focusing function of the camera, a crisp magnified/contracted image video can be viewed regardless of vision. External information can be taken in due to an extention of a system, which in turn a need as a mobile device making an input/output of digital data possible can be also expected.SELECTED DRAWING: Figure 2

Description

The present invention relates to glasses having a telephoto function. Alternatively, it can be used as a glasses-type telescope.

Some glasses have the function of a telescope, but the shape like an opera glass is the mainstream, and the workability and mobility of the glasses are poor, so they are mainly used for ornamental use while sitting on a chair. there were.

Further, in the case of conventional glasses, since the magnification is determined by a combination of optical lenses, it is difficult to make the magnification variable like zooming.

In order to have the magnifying function, it is necessary to have the shape of a conventional telescope. In the case where the conventional telescope is attached to the glasses, the fashionability is low and the functionality is low.

2. Description of the Related Art Digital camera technology has advanced, and glasses having an enlargement function can be realized by combining the performance of a CCD camera with a high-definition display such as a liquid crystal display and digital processing technology.

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The conventional glasses with a telephoto function are long and bulky in the front-back direction, so it is difficult to wear and work or move around. Since the zoom function is optical, it has a cylindrical telescope structure. In addition, since the focal length cannot be continuously adjusted from a distance of about 10 cm near the hand to a distance of several tens of meters, a magnifying glass for working at hand and a telescope for long-distance magnification are different. You have to redo to see the distance. For example, the glasses that look at hand are magnifiers that use convex lenses. Those who look far away have opera glasses.

The digital glasses of the present invention are shaped like glasses, process images of a digital camera set at eye positions, and project the images on a video display panel such as a liquid crystal panel installed on the back side of the camera. It is a pair of glasses that allow the user to look at the projected image directly through the convex lens and look at the display as if it were a normal field of view. In addition, it is also possible to substitute the convex lens part with a special convex lens contact lens. In this case, the installation space and focal length of the convex lens can be omitted, so the thickness of the glasses is thin and lightweight. Can be There is also a method of combining a convex lens and a contact lens.

By embedding this structure in the structure of the glasses so that the images captured by the camera can be viewed with the naked eye in real time, digital glasses using a digital camera and a digital video panel can be made. Naturally, the image projected by the camera is processed by the digital processing element and displayed on the video display panel. Therefore, as a device configuration, a camera, a digital processing device, and a digital display are required. In addition, by performing enlargement and reduction by the function of the CPU of the digital arithmetic device, the glasses become large-function glasses, so that enlargement can be realized. The focusing function of the camera uses a known technique of the camera, and the zoom function is used as a zoom by setting a range for displaying a moving image captured by the camera. That is, it can be realized by a program for changing the setting of the image display range of the digital arithmetic device. At this time, if a switch is provided at the helicopter portion of the glasses by operating the touch switch of the glasses body, a function of changing the magnification with one touch is provided, and the operation can be performed, and the magnification can be easily changed.

In addition, an accelerometer is provided inside the glasses to control the camera's function by shaking the head. It is also possible to operate the camera by blinking. If you use this device, you can see the image magnified through the screen in real time and adjust the focus with the function of the camera. A magnifying glass can be realized.

  By adjusting the positions of the left and right cameras to be the same as the positions of the eyes of the subject, a sense of realism is obtained, and a sense of distance and a positional relationship become closer to reality. The embodiment shows a possible embodiment. However, the position of the camera is not necessarily the position of the eye, and it is possible to realize the function of the glasses even at a position other than the position of the eye, such as the position of the eye on the frame. That is, the mounting position of the camera can be freely designed depending on the application. The above-described device that is both glasses and a magnifying glass is hereinafter referred to as digital glasses.

According to the present invention, it is possible to enlarge a distant scenery as if wearing glasses, and it is possible to enlarge the work even at a close distance. By displaying a clear image on the display panel using the focus function, the aperture function, and the like of the camera, any person with nearsightedness, farsightedness, and astigmatism can see clear images regardless of eyesight. For example, if you are a myopic person and have presbyopia, you will not be able to focus on the subject while wearing glasses, and you will need to take a closer look with the glasses removed. If you have a computer, you cannot see the text on the computer screen and the text on the book with the same glasses on. In such a case, in the present invention, work can be performed with the same glasses.

Also, when looking at a distant distance, for example, when looking at a fishing boat and then checking the state of the reel at hand, both states can be seen using the same glasses.

Also, by changing the camera to an infrared camera, it can be used as a night vision camera. It is also useful as a device for visualizing special environments such as inspections using an ultraviolet camera.

From the above, according to the present invention, it is possible to see a distant view and a near view irrespective of visual acuity, and to manufacture glasses having a telephoto function.

As another application, since the eyes can be completely shielded from external rays, it can be used as a protective device for protecting the eyes when working in welding or special light. Light with high energy and invisible light, such as an infrared laser, is dangerous because it may cause blindness, so it is necessary to protect it with sunglasses. By visualizing with the glasses using a camera that can see the infrared rays, it is possible to work safely while checking the light.

In medical treatment, it is also useful as a loupe used by doctors during surgery. In addition, a person with visual impairment or the like can obtain the effect of supplementing his or her eyesight by adjusting the color and brightness of the image on the display screen according to the symptom of the person. It can also be used as an assistive device for people with eye disorders.

In IT, it is possible to work without changing glasses while watching the display, keyboard, materials, etc. with the naked eye. In addition, by obtaining information by WIFI or Bluetooth, the OS for working by displaying related information from the net or images of other cameras in a small frame on a screen of glasses or on a selection screen. Use as an auxiliary device of the device is also possible. In AV, it is also possible to receive an image projected on the main glasses from an external network and project the image, and use it as an AV receiver by incorporating and synchronizing an audio device.

In addition, since the data acquired by the digital glasses is a stereo image, it is possible to connect the glasses to a network and acquire a real image of the stereo camera by storing the glasses, and the glasses can be used as a stereo image input device. Can be used.

FIG. 1 is a front view of an external view of the first embodiment. FIG. 2 is a cross-sectional view of the eyeglasses according to the first embodiment as viewed from above. FIG. 3 is a rear view of the external view of the first embodiment. FIG. 4 is an explanatory diagram of a lens position adjustment function according to the first embodiment. FIG. 5 is an explanatory diagram when the contact lens of the example is used. FIG. 6 is an explanatory diagram of a camera position adjustment function according to the embodiment. FIG. 7 is an explanatory diagram of the internal equipment of the glasses according to the first embodiment. FIG. 8 is a layout diagram of the electrical device inside the glasses according to the first embodiment. FIG. 9 is a layout diagram of the electric device inside the glasses according to the second embodiment. FIG. 10 is a layout diagram of the electrical device inside the glasses according to the third embodiment. FIG. 11 is a system configuration diagram of the first embodiment. FIG. 12 is a system configuration diagram of the second embodiment. FIG. 13 is a system configuration diagram of the third embodiment. FIG. 14 is a system configuration diagram of the fourth embodiment (Embodiment A) FIG. 15 shows Example A (Example B) as an appearance of Examples 1 and 2. FIG. 16 shows Example B (Example C) as an appearance of Examples 1 and 2. FIG. 17 shows Example C as an appearance of Example 3 (Example D). FIG. 18 shows Example D (Example E) showing the appearance when a dedicated contact lens is used in Example 3. FIG. 19 is an external view showing an external appearance from the front and an external appearance from the rear when a dedicated contact lens is used in Example 4 (Example F). FIG. 20 is an embodiment in which components are integrated on the back side of the liquid crystal panel of the fifth embodiment. FIG. 21 is an external view of Example F as the external appearance of Example 5.

As a method of implementing the present invention, based on the frame structure of conventional glasses, a video display screen that is close to a viewer via a convex lens is viewed, and the video is attached to the surface of the glasses and captured by a camera. Is projected.

If the camera is attached to the position of the eye of the person, the image becomes more realistic, becomes closer to the actual image seen by the eyes, and is effective for manual work. The mounting position of the camera has a structure that can be finely adjusted, and the wearer's view can be reproduced by adjusting the distance between the eyes and the position. A function of finely adjusting the height of the glasses is also provided, and the height position of the eye line can be similarly adjusted. With this function, the wearer can obtain a sense of distance when viewing with the naked eye.

The digital glasses incorporate a camera, a video display screen, a digital control device, a battery, a touch switch, a push switch, and a lens. The digital control device converts video captured by the camera into a video signal and converts the video display screen. Is output to

By incorporating a program to change the resolution of the video signal into the program inside the digital control device, the resolution is changed by the signal touching the external touch switch, and the magnification of the screen is digitally changed to instantly change the magnification. Can be converted. With this function, the magnification of the image can be easily changed. There are other ways to change the magnification, but the setting of which range to display in the number of effective pixels is equivalent to setting the magnification of the screen, so any calculation method may be used as long as the result is the same. . In addition, by installing a lens with an optical zoom function, it is possible to perform zoom operation by incorporating changes in the optical zoom setting into the program, and this method can also be used to operate the switch in the same way as the method described in this manual Can be changed, and a clearer image can be obtained.

By installing a microphone in addition to the switch, operation by voice recognition becomes possible. It is possible to operate the camera by voices such as “increase” or “decrease” the magnification of the camera and “bright” or “dark” the image brightness by programming software of the control device, and the operation can be simplified.

Since the digital controller has the functions of a normal computer such as a CPU and a memory, it has an external communication function so that it can capture and display signals from outside, and at the same time, transmit the image of digital glasses to the outside It becomes possible. WiFi and BLUETOOTH are examples. In addition to that, it is possible to simultaneously display a map and information of a place shown on the camera by obtaining position information by incorporating a gyro and a GPS function. It is also possible to send camera information to the Internet via WIFI and obtain information on the net relating to the image of the image. The digital glasses can be used as a data input / output terminal device that can incorporate many of the current Internet technologies for additional functions.

Of course, as the digital glasses, the method of using them simply as glasses with no enlargement function without such additional functions is firstly basic, but it is possible to add additional values to other functions depending on the application. is there.

FIG. 1 is an external view of one embodiment of the device of the present invention. On the surface of the glasses, a right-eye camera (001) is mounted at a position corresponding to the right eye, and a left-eye camera (002) is mounted at a position corresponding to the left eye. This apparatus has a vine (007) and a tip cell (008), like ordinary glasses, and can be worn. When mounted, the vertical position can be adjusted with the lens vertical position adjustment knob (004). FIG. 2 is a cross-sectional view of the apparatus when viewed from above. A right-eye convex lens (011) and a left-eye convex lens (012) are located ahead of the right-eye line of sight (013) and the left-eye line of sight (014), respectively, and the focal lengths of these lenses are adjusted to the distance between the image display panels installed opposite to each other. This structure allows the user to view the image on the panel at a close distance. In this embodiment, a liquid crystal panel is used, and a right-eye liquid crystal panel (009) and a left-eye liquid crystal panel (010) are provided for the right eye and the left eye, respectively. The structure using the convex lens is a general method for viewing an image at a short distance, and other than this method, any method that focuses on a short distance can be used.

FIG. 3 shows a rear view of the digital glasses of the present embodiment. As shown in FIG. 2, the liquid crystal panel is viewed through the convex lens, and the right-eye liquid crystal panel (009) is viewed from the right-eye convex lens (011). With the left eye, the image of the camera can be seen by looking at the left-eye liquid crystal panel (010) from the left-eye convex lens (012). Since it is necessary that the position of the eyeball of the wearer and the position of the lens match, the left-right adjustment is performed by turning the left lens left-right adjustment screw (0171) and the right lens left-right adjustment screw (017) to shift the lens left and right. Can be adjusted. The vertical position has a structure in which the position of the nose pad (015) is moved up and down by turning the lens up / down adjustment screw (004) so that the eyes can be aligned with the center of the lens. FIG. 4 shows the details. The convex lens has a lens frame (019) attached, and a threaded rod (018) connected to a position adjusting screw is attached to the frame. This structure is embedded in the lens frame (020) in a positional relationship as shown. The lens is fitted in a groove (191) in the figure, and can be moved along the groove and adjusted to a predetermined position by turning a left and right adjustment screw (017). For vertical adjustment, a lens vertical position adjustment screw (004) is connected to the nose pad (015) through a nose pad screw hole (016). The nose pad idles at the connection with the screw. According to this composition, the position of the nose pad (015) can be adjusted by turning the lens vertical position adjustment screw, and the eyes can be adjusted to the lens.
This is an embodiment showing a method of adjusting the eyes and the focus of the lens by adjusting the lateral direction of the lens and adjusting the position of the nose pad. Any other method can be applied as long as the function is to adjust up, down, left and right.

FIG. 5 shows an explanatory diagram when a contact lens is used without using a convex lens. By realizing the function of the convex lens (119) with the contact lens (120) as shown in the figure, the convex lens becomes unnecessary, and the thickness of the digital glasses can be made closer to that of conventional glasses. By increasing the power of the lens for hyperopia, a contact lens suitable for the contact lens for the digital glasses is manufactured. In this case, the frame for fixing the 003 lens in FIG. 1 becomes unnecessary, and the structure of the glasses becomes much simpler. The external view is shown in Example E of FIG.
It is also possible to use both the contact lens (120) and the convex lens (119), and the focal length can be made shorter than when only the convex lens (119) is used. Useful for thinning.

FIG. 6 shows the position adjustment function of the camera. This shows a method for aligning the position of the camera with the position of the wearer's eyes. In the camera fixing method, a support plate cover (023) is attached to the back side of the camera substrate (025), and a horizontal axis support plate (022) is passed between the cover and the substrate.
As for the left and right positions, the support plate is slid and adjusted to a predetermined position. As for the vertical position, the camera supporting and fixing plate (026) is opened in a double door as shown in the figure, the horizontal axis supporting plate (022) is set at a predetermined position, and then the supporting and fixing plate (026) is closed. When closed, the lid is configured to be caught by the projection, and the camera support and fixing plate is closed so that the camera board (024) is attached and pressed against the back surface. Therefore, the position in the height direction is also determined, and the indicator plate cover (023) is also provided in the left and right directions. ) Is fixed because it is a soft material such as rubber.
This method represents an example for determining the position of the camera, and any other method may be used as long as the camera can be fixed. For example, by using a velcro, the velcro can be attached to the back side of the camera and the mounting surface, and the area of the tape on the mounting surface can be increased to provide an adjusting function.

FIG. 7 shows an installation state of devices necessary for the glasses. The positional relationship between the liquid crystal panel, the camera, and the lens is as described above, but the image control device for adjusting and displaying an image is an example in which the left and right are independently installed. In that case, a right video control device (101) and a left video control device (102) are provided. The power supply used for this is also independent, and the right battery (103) and the left battery (104) are provided separately. If an image disappears due to some trouble, the power supply and the control unit are made independent so that either image does not disappear and one screen can be turned on even in the worst situation during mounting. Power supply configuration.
Further, the batteries (103) and (104) are installed at the position of the destination cell (008) in consideration of the weight balance to improve the weight balance in the front-back direction.

FIG. 8 shows an arrangement related to electricity and control.
The right control device (201) and the left control device (202) independently receive video signals from the right camera (205) and the left camera (206), process the signals, and then process the right liquid crystal panel (203) and the left liquid crystal. The image is transmitted to the panel (204) and projected. In this embodiment, the control device has a CPU and can perform measures such as enlarging / reducing a video and taking in other images. For example, by operating the operation switch (207), power on / off and maintenance operations can be increased. The program is stored in the right memory with the right CPU as a master, for example. This program enables setting operations such as start-up and drop operations and image quality settings.
In addition to this, the system configuration can also be used to adjust the telephoto function by changing the resolution of an image during use. The operation of the touch switch (208) is taken into the CPU and the program for changing the magnification is operated. Since this signal is shared by the two CPUs via the communication cable (214), this signal instantly shares the same magnification information and sets the same magnification on both the left and right sides.
FIG. 11 also shows a system configuration.

Of course, it is obvious that the system can be realized with one system of CPU and one system of power supply, and this patent does not specialize in two systems of right and left.
This system can be realized by a small microcomputer system called Raspberry Pi, for example. By developing and developing a new system from the conventional source code, it is possible to construct a program for the device. Further, since such a one-board microcomputer can support WIFI or the like, communication with an external communication device by radio waves facilitates connection with an external CPU. By displaying additional information about the real position from the network in addition to the image of the camera of the present system and the information of the database at the same time, the utility value as a multifunctional glasses apparatus can be expanded.

FIG. 15 shows a design example of the first embodiment. The whole is covered with a cover, and only the position (301) of the camera is opened.

FIG. 12 shows the system configuration of the second embodiment. This system shows an embodiment in which one control device (215) having a CPU for performing image processing and one battery (216) are used. This case can be dealt with by changing the software program of the CPU so that two cameras can be input. The design appearance is the same as that of the first embodiment as shown in FIG.
FIG. 13 shows the system configuration of the third embodiment. In this example, a single liquid crystal panel (217) is used as the display liquid crystal panel. In this system, the screen for both eyes is displayed on one sheet using a horizontally long liquid crystal panel. The image of the camera is two inputs as in the first and second embodiments, but the screen is divided into halves by the software program of the control device (215), and the images of the right camera and the left camera are projected on the respective screens. Glasses can be realized.

FIG. 9 is a layout diagram of the inside of the glasses in the case of the third embodiment. Since the number of CPUs is one and the number of display devices is one, the battery space is also reduced, and the arrangement is as shown in the figure. A configuration in which the device is housed in the front half of the glasses or in one of the left and right sides is conceivable, and the finished appearance of the product in this case is as shown in FIGS. 16B and 17C. Appearance. Reference numeral 16 denotes a case where the battery is mainly stored in the front half. In this case, the battery can be stored in the rear half. FIG. 17 shows a case in which it is stored in the left half.
In this embodiment, when a dedicated contact lens is used without using a convex lens, a lens frame is not required, and thus a structure as shown in Embodiment D of FIG. 18 can be realized.

FIG. 14 illustrates a system in which camera information and video information are made wireless based on the system configuration of the third embodiment, and a signal from the camera is transmitted to a separate CPU by radio waves.
The camera controller outputs from the left camera controller (225) and the right camera controller (226) via the camera signal transmitter (223) to the camera signal receiver provided on the image processing controller (215) side. This is displayed on the liquid crystal panel (217). By adopting this system, it is not necessary to mount a large-volume image processing control device on the glasses, so that slim digital glasses can be realized. At the same time, the capacity of the battery is reduced and the weight can be reduced.

FIG. 10 is a mounting schematic diagram in the case of the system of FIG. In this case, the video signal receiver (222), the camera signal transmitter (219), and the like can be incorporated into the back of the display to minimize the equipment on the vine (007) side. By integrating this and other equipment into a module, space can be saved and production costs can be reduced.
Since the image processing control board (231) can be carried in a pocket or a bag, space-saving digital glasses can be realized. By constructing the software of the image processing device with a smartphone application, a method using a smartphone is also conceivable.

In this embodiment, an external view in the case where a dedicated contact lens (120) is used in this case is shown in FIG. 19E. Since there is no lens fixing frame (003) as in the first embodiment as seen from the back, the thickness in the line of sight becomes small. By using wireless communication, there is no longer anything to be stored in the vine (007), and the digital glasses can be realized with a clean appearance similar to conventional glasses.
In this example, the case where the liquid crystal panel (218) with the touch panel is used is shown. However, since the lens frame 003 for the convex lens is not required, the operation can be changed because the liquid crystal panel can be touched. This is an example of adopting only. It can be used for setting auxiliary operations. It can be used for any of the examples 1 to 3.

20 and 21 show the digital glasses of the embodiment F. In the embodiment F, functions required as digital glasses are housed in the substrate (230) to make them compact. The system configuration can be realized by adopting an optimal method for downsizing as a system similar to the embodiments A to E. In the embodiment F, the parts divided in A to F are combined into a single board. Then, by being integrated, it can be stored in a space corresponding to the lens portion of the glasses. With this structure, the digital glasses in a form close to conventional glasses can be realized. As long as the battery is small, it can be mounted on a board, but for a long time, it must be supplied from the outside. Although not shown, power can be supplied through a connector connected to the outside to enable long-term use. Also, since the network of the control device needs to be linked for the right eye and the left eye, the network is formed by wireless or wired communication. Further, in this embodiment, there is a control camera (225), which can monitor the state of the eyeball of the wearer. This camera is sent to the image processing control device (215) and can operate the functions of the glasses according to the blink, the position of the eyeball, and the like. An X-axis slide camera stand (226) and a Z-axis slide camera stand (227) are provided for camera position adjustment, and the position of the camera can be adjusted by sliding the stand. This can also be solved by using a velcro or a mounting method having a position adjustment function using a magnet.
FIG. 21 shows an external view of Example F of the digital glasses when the substrate (230) is used. By connecting the substrates (230) manufactured for the right and left as shown in the figure and attaching the temple (007), the structure of the glasses can be formed. The cover (025) protects the board and the camera. Use a smoked resin material or the like so that the image can be seen with a camera. Alternatively, if it is opaque, a camera opening (301) is provided in front of the camera as in the embodiment A of FIG.

INDUSTRIAL APPLICABILITY The present invention is made into glasses having a telephoto function, and can be used in a wide range of fields such as factory work, office work, medical surgery, inspection, sports appreciation, fishing, crafts, and general life. It can also be used for medical purposes such as a vision assist device for people with visual impairment. It is also useful as a special environment protector to protect your eyes.

001. Right eye camera 002. Left eye camera 003. Lens fixing frame 004. Lens up / down knob 005. Push button switch 006. Touch switch 007. Vine 008. Destination cell 009. Right eye liquid crystal panel 010. Left eye liquid crystal panel 011. Right eye convex lens 012. Left eye convex lens 013. Right-eye line of sight 014. Left eye gaze 015. Nose pad 016. Screw hole for nose pad 017. Right lens left / right adjustment screw 018. Screw hole 019. Lens frame 020. Lens frame 21. Camera 022. Horizontal shaft support plate 023. Support plate cover 024. Camera board 025. Cover 026. Camera support fixing plate 101. Right image control device 102. Left video control device 103. Right battery 104. Left battery 105. Right eye lens 106. Left eye lens 107. Lens frame 108. Operation switch 109. Lens position adjustment / adjustment mechanism 110. Vertical adjustment dial 111. Right camera fixing plate 112. Left-eye camera vertical fixing plate 113. Right eye camera 114. Right-eye camera control board 115. Left eye camera 116. Left-eye camera control board 117. Right-eye camera left / right fixing plate 118. Left eye camera left and right fixing plate 119. Convex lens 120. Dedicated contact lens 121. Eye 122. Focusing distance 123. Video display screen 201. Right control device 202. Left control device 203. Right liquid crystal panel 204. Left liquid crystal panel 205. Right camera 206. Left camera 207. Operation switch 208. Touch switch 209. Right battery 210. Left battery 211. Power supply line 212. Screen data signal line 213. Camera signal line 214. Communication cable 215. Control device 216. Battery 217. Left and right shared liquid crystal panel 218. Liquid crystal panel with touch panel 219. Camera signal transmitter 220. Image signal transmitter 221. Camera signal receiver 222. Image signal receiver 223. Switch signal transmitter 224. Switch signal receiver 225. Control camera 226. X-axis slide camera stand 227. Z-axis slide camera base 228. Camera interface circuit 229. Display interface circuit 230. Substrate 231. Image processing control board 301. Camera aperture

Claims (22)

Like the embodiment of this patent, it has a camera, a video display panel, a digital processing device, a battery, an operation switch, a convex lens, and is incorporated in the shape of the glasses, and the eye position when the glasses are worn. Digitally processes the image of the camera installed in the camera, displays it on the digital display screen installed in front of the left and right eyes, and sees the image through the convex lens to improve the eye ability like the function of ordinary glasses. Glasses that complement and allow you to view in real time an image that has been subjected to image processing, such as enlargement or reduction, using a camera lens or digital image technology. The eyeglasses having the same configuration as the eyeglasses, wherein a contact lens is used as a convex lens for focusing an eye on an image, and the contact lens. (There are cases where a convex lens and a contact lens are combined and cases where only a contact lens is used.) 20. The eyeglasses according to claim 2, wherein the focus correction function by the convex lens is omitted, and the eyeglasses have a configuration as shown in FIG. 19 (that is, the structure of the convex lens portion is omitted from claim 1). 3. The spectacles according to claim 1, wherein the spectacles have an adjusting function for adjusting the position of the convex lens to the position of the eye of the person wearing the spectacles. 4. The glasses according to claim 1, wherein the position of the camera attached to the glasses is adjusted to the position of the eyes of a person wearing the glasses. In claim 1, claim 2, and claim 3, as in the system configuration 4 in the embodiment, the video signal captured by the camera of the glasses body is transmitted to the video control device separately provided by wireless transmission. Glasses that can be transmitted to the glasses body after being processed by the digital processing device, the signals received by the glasses body can be displayed on a digital display screen, and the images of the glasses can be viewed. In claim 1, claim 2, and claim 3, required electronic components are collectively loaded on one substrate, and the embodiment is formed into a single board as shown in FIG. 20, thereby saving space and weight. Glasses control board and glasses that can be designed. 4. The glasses according to claim 1, 2, or 3, wherein the type of camera installed at the eye position of the glasses is an infrared camera so that infrared images can be viewed even in a dark place. 4. The high-sensitivity glasses according to claim 1, 2 or 3, wherein the type of camera installed at the position of the eyes is a high-sensitivity camera, so that it can be viewed even in a dark place. The ultraviolet spectacles according to claim 1, wherein an ultraviolet camera is mounted as a camera installed at a position of an eye, so that ultraviolet rays can be visualized. 4. The data display according to claim 1, wherein the digital processing device has a communication function, and the result of processing both communication information and information from the camera by the communication function can be displayed on a screen. Glasses with functions. 4. The glasses according to claim 1, further comprising a microphone, having a voice input function of the digital processing device, and capable of operating the digital processing function of the glasses by voice by voice recognition. The glasses according to any one of claims 1, 2, and 3, wherein the glasses have a speaker and an audio output function of the digital processing device, and can provide guidance on operation of the glasses. 4. The glasses according to claim 1, wherein a gyro is provided to detect an angle of the glasses, and the magnification is automatically changed according to a posture of a wearer's neck. 4. The method according to claim 1, wherein when the glasses are worn, the wearer of the glasses has an optical sensor, such as an optical sensor or a camera, and recognizes the wearing state to turn on / off the switch and operate the glasses. Glasses that can do. 4. The glasses according to claim 1, 2 or 3, wherein the digital processing device can record a moving image by an operation including a switch function by software of the glasses, such as a switch. 4. The glasses according to claim 1, 2 or 3, wherein the digital processing device can record a still image by an operation including a switch function of the software such as a switch. 4. The glasses according to claim 1, 2, or 3, which can display a screen of a personal computer connected to a network and can be used as a display of the personal computer due to the function of the digital processing device. According to claim 1, claim 2, and claim 3, the function of transmitting data of the camera to an external device by a communication function with an external device rather than the function of the digital processing device is used as a transmitting device of a stereo camera. Glasses that can be. In claim 1, claim 2, and claim 3, the function of the digital processing device is used as a data transmission device of the 3D display device by transmitting camera data to an external crisis by a communication function with an external device. Glasses that can be. According to claim 1, claim 2, and claim 3, the stereo camera data and the 3D data, which are input from the external device by the communication function, can be easily visually confirmed. Glasses useful as a data playback device. According to the first, second and third aspects of the present invention, the image from the infrared camera is thermographically processed and the image of the temperature distribution is displayed on the digital processing apparatus by the function of the digital processing apparatus. Glasses with the function of.

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