JP2021167967A - Electronic device and display method - Google Patents

Abstract

To provide an electronic device and a display method.SOLUTION: The electronic device of the embodiment includes: a display unit; an optical system that displays a virtual image of a display image displayed on the display unit on the user's line of sight; an adjustment mechanism that adjusts a display position of the virtual image with respect to a display position change direction of the virtual image that occurs in response to a change in the shape or size of the user's head; and a setting mechanism that sets a change direction of a brightness of the virtual image. The display unit displays a first virtual image together with the background visible on the user's line of sight, and displays a second virtual image for enhancing the visibility of the first virtual image together with the background visible on the user's line of sight prior to the timing of displaying the first virtual image. When a brightness of the background is brighter than a first brightness, it increases a brightness of the first virtual image, and when the brightness of the background is darker than the first brightness, it changes the brightness of the first virtual image in the direction set by the setting mechanism.SELECTED DRAWING: Figure 2

Description

The present invention relates to electronic devices and display methods.

An electronic device, for example, a wearable device that provides information such as an image or a message on an extension of at least one line of sight of the wearer has been put into practical use. In this type of wearable device, the wearer can visually recognize both the image or scenery directly viewed and the image or message displayed superimposed on the image or scenery without substantially moving the line of sight.

Japanese Unexamined Patent Publication No. 2010-516186

However, if the image or message (information) displayed on the extension of the line of sight of one eye is different from the direct-view image or landscape (information) seen on the extension of the line of sight of the other eye, the wearer may use either eye. In some cases, only the information entered may be perceived (recognized).

That is, it is suggested that stereoscopic vision consists of visual recognition (perception) by both eyes, but when displaying information different from the information perceived by the other eye on the extension of the line of sight of one eye, the line of sight of one eye. It is required that the information displayed on the extension of is stably visible.

Although it is possible to configure the display mechanism so that the information to be displayed can be perceived by both eyes, the weight and size of the wearable device are increased. This not only reduces the wearability of the wearable device, but may also cause withdrawal from the wearer (of the device), deviation of the information to be displayed from the line of sight, and the like. Also, the large scale and increased costs of wearable devices and systems for displaying information are unacceptable today.

An object of the present invention is to provide an electronic device and a display method for enhancing the visibility of information perceived by the other eye when displaying information different from the information perceived by the other eye on an extension of the line of sight of one eye. It is to be.

According to the embodiment, the electronic device worn by the user includes a display unit, an optical system for displaying a virtual image of the display image displayed on the display unit on the user's line of sight, and the shape or size of the user's head. It is provided with an adjustment mechanism for adjusting the display position of the virtual image with respect to the change direction of the display position of the virtual image generated in response to the change, and a setting mechanism for setting the change direction of the brightness of the virtual image. The display unit displays the first virtual image together with the background visible on the user's line of sight. The display unit displays the second virtual image for enhancing the visibility of the first virtual image together with the background visible on the user's line of sight prior to the timing of displaying the first virtual image. The display unit increases the brightness of the first virtual image when the background brightness is brighter than the first brightness, and increases the brightness of the first virtual image when the background brightness is darker than the first brightness. Is changed in the direction set by the setting mechanism.

An example of the electronic device according to the embodiment is shown. An example of the electronic device according to the embodiment is shown. An example of the main configuration of the electronic device according to the embodiment is shown. An example of display control of an electronic device according to an embodiment is shown. An example of display control of an electronic device according to an embodiment is shown. An example of a display example in the electronic device according to the embodiment is shown. An example of a display example in the electronic device according to the embodiment is shown. An example of a display example in the electronic device according to the embodiment is shown. An example of the electronic device according to the embodiment is shown. An example of the electronic device according to the embodiment is shown. An example of the main configuration of the electronic device according to the embodiment is shown.

Hereinafter, one embodiment will be described with reference to the drawings.

1 and 2 are schematic views showing an example of a wearable device (electronic device) according to the embodiment. The wearable device is a portable terminal device (which can be worn by the user on the head), and for example, information from a smartphone (tablet PC) associated with a smartphone (or tablet PC) as a control unit can be freely transferred with both hands. It is displayed at a predetermined position on the extension of the wearer's line of sight so that it can be visually recognized in a hands-free state that can be moved to. Hereinafter, embodiments of the wearable device will be described by taking an eyeglass type as an example. The wearable device may be a head-mounted display type that is worn on the wearer's head.

The wearable device 101 includes a light projecting unit (display information generation unit) 1, a light projecting unit support unit (main body) 2, a screen (display unit) 3, a drive circuit unit (image display circuit and light source drive circuit, or a signal processing unit). (Sometimes referred to as) 4, the communication unit 5, the power supply unit 6, and the like are included.

The light projecting unit 1 includes a light source 10, at least an information display unit 7, and a projection (enlargement) optical system 8. The light projecting unit 1 incorporates a drive circuit unit 4, a communication unit 5, and a power supply unit 6, and a string portion extending from a predetermined position of the main body 2, for example, a frame-shaped portion when the wearable device 101 is formed in a spectacle shape (a string portion). It is located so that it can be attached to and detached from the ear hook). The light projecting unit 1 may be built in, for example, a frame-shaped portion.

The main body 2 integrally supports a transparent body 9 that functions as a counterweight for the light projecting unit 1 and the screen 3 together with the light projecting unit 1 and the screen 3. In the screen 3, the brightness is spatially modulated based on the display image (image displayed by the information display unit 7) obtained by illuminating the information (image) displayed by the information display unit 7 of the light projecting unit 1 with the light from the light source 10. The image light 13 magnified by the projection (enlargement) optical system 8 is visualized. That is, the screen 3 transmits a part of the image seen on the extension of the line of sight of the wearer wearing the wearable device 101, that is, the background (environment) image, and the displayed image is enlarged together with the visible image of the image light 13. Make it visible (perceptible) to the wearer. Based on the display data acquired by the communication unit 5, the drive circuit unit 4 includes an image corresponding to the first information (display image displayed in the display area 3a of the screen 3 for a predetermined period) on the information display unit 7, such as an image or video. Display a message (text). The image corresponding to the first information may be abbreviated as the first information or the image or image of the first information. The communication unit 5 uses an information supply source, for example, a system controller or data on a network, as a base data for generating an image corresponding to the first information (video data or text data) displayed by the information display unit 7. Received from the server, for example, stored in the built-in memory unit (storage module 44 shown in FIG. 3) 44. The information supply source is an external memory that conforms to, for example, the USB (Universal Serial Bus) standard, can be connected to the communication unit 5 or the drive circuit unit 4, and the communication unit 5 or the drive circuit unit 4 can read (data). It may be a device. The power supply unit 6 includes, for example, a button-type battery, a terminal for connection, a connection line between the drive circuit unit 4 and the communication unit 5, and the like. The information display unit 7 is, for example, a reflective liquid crystal display (LCD) panel, and displays first information based on display control by the drive circuit unit 4. The transparent body 9 integrally has, for example, a light amount detection sensor surface (photoelectric conversion film), and the brightness of the environment (background) that the wearer visually recognizes through the screen 3 (of the wearable device 101) and the transparent body 9. It is preferable to be able to obtain information. Of course, it goes without saying that a light amount detection sensor for acquiring information on the brightness of the environment (background) may be independently provided. Further, when a camera function (lens and image processing unit) is provided, it goes without saying that the brightness detection function may be used.

A slide switch 16 and a rotary knob 17 are provided at a predetermined position of the light projecting unit 1, for example, a bottom surface portion. The switch 16 can adjust, for example, the brightness (brightness (and color tone) of the illumination light output by the light source 10) of the image light 13 (image corresponding to the display information) emitted by the light projecting unit 1. The knob 17 can adjust the projection (emission) angle of the image light 13 emitted by the light projecting unit 1, for example. By configuring the switch 16 and the knob 17 so that the adjustment amount can be set by different operations, the wearer can visually check the visible image obtained by visualizing the image light 13 on the screen 3, and the wearer can touch the brightness and the brightness. The projection angle can be adjusted. That is, by operating the switch 16, it is possible to provide the display brightness and color tone of the visible image desired by the wearer. Further, the projection angle can be adjusted by the knob 17 so that the visible image can be displayed at the optimum position according to the shape and size of the wearer's head. Needless to say, the adjustment targets of the switch 16 and the knob 17 may be reversed, and the positions of the switch 16 and the knob 17 may be reversed.

The light projecting unit 1 can also have a speaker 18 at a predetermined position, for example, a bottom surface portion. The speaker 18 is useful for notifying (reproducing the voice information) the worker who is the wearer (of the wearable device) as voice information, for example, a message from the administrator (or the supervisor).

Next, the display of information (image) on the screen 3 by the light projecting unit 1 will be described.

The light source 10 of the light projecting unit 1 is preferably a dimming white LED module (L-cos) including, for example, three LED (Light Emitting Diode) elements. Each LED element of the dimmable white LED module has a different emission color from each other, the output light amount of each (element) can be changed independently, and light of any color can be output. A part of the white light (illumination light) from the light source 10 is directed to the information display unit 7 by the half mirror surface 11 of the mirror prism 12. The information display unit 7 is illuminated by the illumination light from the light source 10 reflected by the half mirror surface 11. As a result, the image corresponding to the first information (video or message) displayed by the information display unit 7 is reflected toward the mirror prism 12. Hereinafter, the light including the image corresponding to the first information reflected by the information display unit 7 is referred to as an image light 13.

Even if the light source 10 has three light emitting units (three-plate type L-cos) that independently output light of each color of R (red), G (green), and B (blue), for example. good. In addition, in order to reduce the weight and improve the dynamic characteristics of the image, a single green color may be used. Also, if three antigens R, G, and B are used, one frame will be obtained in three scans, but if a single color is used, the frame rate can be tripled (or the same dynamic characteristics can be obtained at a frame rate of 1/3). Become).

When the above-mentioned monochromatic light or a light source 10 that outputs a plurality of monochromatic lights is used, the information display unit 7 displays an image by, for example, a DMD (Digital Mirror Device) method obtained by a MEMS (Micro Electro Mechanical Syestm) technology. , It is possible to output a higher resolution image. Further, by using three independent light emitting units, it is possible to further expand the variable range of the contrast ratio and the adjustment range of the brightness. Each light emitting unit (light source) may be a laser element. Further, as shown in the latter part by FIGS. 10 and 11, the light (image) output by the laser display array obtained by applying DLP (Digital Light Precessing), that is, the MEMS technology is displayed on the screen of the wearer's eyes (retina). As a result, it is also possible to apply a "retinal scanning method" that allows the wearer to directly perceive.

The image light 13 passes through the mirror prism 12, is magnified to a predetermined size by the lens 14 of the projection optical system 8, reaches the Fresnel lens type half mirror surface 15 of the screen 3, and becomes a visible image. The visible image (image light 13 reaching the Fresnel lens type half mirror surface 15) is an extension of the line of sight of one eye of the wearer wearing the main body 2, and the magnification provided by the Fresnel lens type half mirror surface 15 is magnified. It can be visually recognized (perceived) with a predetermined size according to. The image light 13 has one light projecting unit 1, the distance between the screen 3 displaying the visible image obtained by the light projecting and the light projecting unit 1, and the light projecting unit 1 to the screen 3. Although it depends on the angle at which the image is emitted, it can be visually recognized (perceived) by only one eye of the wearer. The weight of the wearable device 101 can be reduced by configuring the light projecting unit 1 so that it can be visually recognized (perceived) by only one eye of the wearer and provides the image light 13 (display information). As a result, it is possible to work for a long time with the wearable device 101 attached. That is, it is possible to reduce the burden (load) on the wearer when the wearable device 101 is worn and the work is performed for a long time.

FIG. 3 is a schematic view showing an example of the configuration of the drive circuit unit.

The drive circuit unit 4 includes a processor (CPU (Central Processing Unit) 41), a light source control unit 42, a display image generation unit (LCD drive circuit) 43, a storage module (memory unit) 44, and the like. The processor 41 and the display image generation unit 43 may be realized by a processor mounted on one electronic circuit. Further, even if the drive circuit unit 4 is, for example, a one-chip microcomputer (MPU), and the processor 41, the light source control unit 42, the display image generation unit 43, the memory unit 44, etc. are realized as the firmware of the processor 41. good.

The processor 41 drives the display image generation unit (LCD drive circuit) 43 at the image display timing corresponding to the first information acquired by the communication unit 5, and the display information or communication held by the recording module (memory unit) 44. An image corresponding to the first information, which is display information (data) acquired via the unit 5 (or the drive circuit unit 4), is displayed on the information display unit 7. The processor 41 also drives the light source control unit 42 to output light of a predetermined color from the light source 10 to illuminate the image displayed by the information display unit 7 (corresponding to the first information). The processor 41 further displays the image corresponding to the first information generated by the display image generation unit 43 on the information display unit 7 at a predetermined timing in the previous stage for a predetermined period (time). ) The image corresponding to the second information for enabling visual recognition (perception) is displayed on the information display unit 7. In the display of the image corresponding to the second information, the wearer's perception (visual field) of the first information and the perception (visual field) of the background (environment visible through the screen 3 and the transparent body 9) are irregularly repeated. It is useful for deterring exposure to alternating "visual field struggles (sometimes called ambivalent figure perception)" (visual field struggles occur when the wearer perceives with both eyes).

FIG. 4 shows an example of display control in the electronic device shown in FIGS. 1 to 3 in terms of software.

As shown in FIG. 4, it is detected that it is the display timing of the display image on the screen 3 of the wearable device 101 [01]. When the display timing is [01-YES], a specific image (image corresponding to the second information) for enabling the image (display image) corresponding to the first information to be visually recognized (perceived) for a predetermined period (time) or longer. ) Is displayed in advance of the timing at which the first image is displayed by a predetermined timing [02].

This makes it possible to extend the time (period) during which the wearer can perceive (visualize) the image corresponding to the first information, as will be described later with reference to FIGS. 6-8.

FIG. 5 shows an example of display control in the electronic device shown in FIGS. 1 to 3 in terms of software.

As shown in FIG. 5, it is detected that it is the display timing of the display image on the screen 3 of the wearable device 101 [11]. When the display timing is set to [11-YES], it is detected that the brightness of the wearer's field of view (the scenery seen by the wearer), which is the background of the image displayed on the screen 3 of the wearable device 101, is a predetermined brightness. [12]. When the brightness of the background is darker than the predetermined brightness [12-YES], in the specific image (image corresponding to the second information) displayed in the display area 3a of the screen 3, the contrast difference of the background area of the specific image is increased. A suppressed image (display image) is prepared [13]. Hereinafter, a specific image for making the image corresponding to the information of the prepared display image perceptible for a predetermined period or longer is displayed in advance of the timing of displaying the first image by a predetermined timing [14]. When the brightness of the background is brighter than the predetermined brightness [12-NO], an image (display image) in which the contrast difference of the background area of the specific image is enhanced is prepared in the specific image to be displayed in the display area 3a of the screen 3. [15], the first image is displayed in advance of the timing of displaying the first image by a predetermined timing [14]. The image (display image) in which the contrast difference in the background region of the specific image described in the block [13] is suppressed is, for example, an image as described in FIG. 8 (b). Further, the image (display image) in which the contrast difference in the background region of the specific image described in the block [15] is increased is an image as described in FIG. 7B, for example.

Hereinafter, when the image corresponding to the first information (image or message) is displayed on the screen 3 by using FIGS. 6 to 8, it is possible to prevent the wearer's perception from being exposed to the “visual field struggle”. An image display method corresponding to the second information will be illustrated. In the example shown in FIGS. 6 to 8, when the wearable device 101 wearer moves in the city (street), a map near the current position or a target location (in the map) is displayed. However, for example, it is possible to guide the wearer to a place to move in the factory.

6 (a)-FIG. 6 (c) is a table of images corresponding to the first information and images corresponding to the second information that can prevent the wearer's perception from being exposed to "visual field struggle". It is the schematic which shows an example.

FIG. 6A shows an environment (background) that the wearable device 101 wearer perceives (visually recognizes) through the screen 3 and the transparent body 9, that is, how the wearer wears the wearable device and sees the background with both eyes. The relationship between the display area 3a and the display area 3a is schematically shown.

FIG. 6C shows a state in which an image corresponding to the first information is visualized in the display area 3a of the screen 3, and is perceived (visually recognized) by the wearable device 101 wearer, that is, when the wearable device is worn. The appearance of the wearer with both eyes is schematically shown.

FIG. 6B corresponds to the second information for surely visually recognizing (perceiving) the first information in the display area 3a of the screen 3 before visualizing the image corresponding to the first information. The state in which the image is displayed is schematically shown. The image corresponding to the second information shown in FIG. 6B is a blank display that does not include an image or a message, for example, a white image over the entire area (a white image in which the brightness signal is sufficiently enhanced as compared with the first information) or. It is preferable that the background is transparent as it is, that is, a black image in which the brightness signal is “0”).

That is, the entire white image shown in FIG. 6B is displayed in the display area 3a for a certain period of time at a predetermined timing in the previous stage in which the image corresponding to the first information shown in FIG. 6C is displayed in the display area 3a. This makes it possible to reduce the exposure of the wearable device 101 wearer's perception to "visual field struggle". As a result, it is possible to extend the time (period) during which the wearable device 101 wearer can perceive (visually recognize) the image corresponding to the first information shown in FIG. 6 (c).

The image corresponding to the first information shown in FIG. 6 (c) and the entire white image (or black image) shown in FIG. 6 (b) are continuously impulse-displayed, that is, alternately displayed at a predetermined timing. By making the wearer perceive alternately, the period (time) during which the wearer can perceive the image corresponding to the first information shown in FIG. 6 (c) is increased to about 1 minute (60 seconds). It is known that it can be done. The timing of alternately displaying the image corresponding to the first information and the entire white image (or black image) depends on the size of the image to be displayed, the brightness of the image, the contrast of the image, and the like. The range is 1 to 100 times per second, preferably 2 to 20 times per second, more preferably 5 to 10 times per second, and the number of times is preferably such that the wearer does not feel tired of the eyes. The size of the image to be displayed (the size of the display area 3a of the screen 3) is, for example, the appearance (perception) of the image corresponding to the first information without the wearer moving the line of sight on the extension of the wearer's line of sight. It is a possible size, for example, larger than approximately 50% of the area of the screen 3. The brightness of the image is preferably classified based on, for example, a bright case and a dark case as compared with the brightness of the environment (background) that the wearer visually recognizes through the screen 3 and the transparent body 9. For example, when the brightness of the background (scenery seen by the wearer) acquired (detected) by the light amount detection sensor surface (photoelectric conversion film) 9 is dark, it is preferable to increase the brightness of the image. On the other hand, when a bright image (an image corresponding to the first information) is displayed when the background (the scenery seen by the wearer) is dark, the pupil of the wearer's eyes sharply shrinks, making it difficult to see the background. There is. Therefore, when displaying the image corresponding to the first information, the adjustment function of assigning the brightness of the image to the (brightness adjustment) switch 16 to brighten or darken the image is adjusted to the wearer's preference. It is preferably adjustable. In addition, for example, at night or in a room where the lighting is set to be dark, it is possible to invert (positive-negative conversion) the brightness of the image message or image portion corresponding to the first information and the brightness of the background. be.

7 (a)-FIG. 7 (c) is a table of images corresponding to the first information and images corresponding to the second information that can prevent the wearer's perception from being exposed to "visual field struggle". It is the schematic which shows an example.

FIG. 7A is the same as FIG. 6A, and schematically shows the relationship between the appearance of the background with both eyes of the wearer when the wearable device is worn and the display area 3a.

7 (c) is the same as FIG. 6 (a), and the state in which the wearable device 101 wearer perceives (visually recognizes) the state in which the image corresponding to the first information is visualized, that is, when the wearable device is worn. The appearance of the wearer with both eyes is schematically shown.

FIG. 7B is a display example of an image corresponding to the second information displayed in the display area 3a. The image corresponding to the second information is the difference in contrast between the image or message portion of the image corresponding to the first information displayed in the (finally) display area 3a shown in FIG. 7C and the background portion thereof. It is preferable that the image is an enhanced image.

That is, at a predetermined timing in the previous stage of displaying the image corresponding to the first information shown in FIG. 7 (c) in the display area 3a, the contrast between the image or message portion shown in FIG. 7 (b) and the background portion thereof. By displaying the image with the increased difference in the display area 3a for a certain period of time, it is possible to reduce the exposure of the wearable device 101 wearer's perception to the “visual field struggle”. Thereby, it is possible to extend the time (period) during which the wearable device 101 wearer can perceive (visually recognize) the image corresponding to the first information shown in FIG. 7C within a predetermined condition. ..

The wearer perceives the image corresponding to the first information by alternately displaying the image corresponding to the first information and the image in which the contrast difference between the video or message portion and the background portion is increased. It is the same as the display method described with reference to FIG. 6 that the possible period (time) can be increased to about 1 minute (60 seconds). Further, when displaying the image corresponding to the first information, whether to brighten or darken the brightness of the image is adjusted according to the wearer's preference by, for example, an adjustment function assigned to the (brightness adjustment) switch 16. It is preferable that it is possible. Further, for example, at night or in a room where the lighting is set to be dark, it is preferable to invert (positive-negative conversion) the brightness of the image message or image portion corresponding to the first information and the brightness of the background thereof.

8 (a) -FIG. 8 (c) is a table of images corresponding to the first information and images corresponding to the second information that can prevent the wearer's perception from being exposed to "visual field struggle". It is the schematic which shows an example.

8 (a) is the same as FIG. 6 (a) and FIG. 7 (a), and schematically shows the relationship between the appearance of the background with both eyes of the wearer when the wearable device is worn and the display area 3a. show.

FIG. 8 (c) is the same as that of FIGS. 6 (c) and 7 (c), and the state in which the wearer of the wearable device 101 perceives (visually recognizes) the state in which the image corresponding to the first information is visualized. That is, the appearance of the wearable device with both eyes when the wearable device is worn is schematically shown.

FIG. 8B is a display example of an image corresponding to the second information displayed in the display area 3a. The image corresponding to the second information is the difference in contrast between the image or message portion of the image corresponding to the first information displayed in the (finally) display area 3a shown in FIG. 8C and the background portion thereof. It is preferable that the image is a suppressed image. It should be noted that the image may be an image in which the difference in contrast between the image or message portion of the image corresponding to the first information and the background portion thereof is suppressed and the brightness is reduced. Further, the image may be an image in which the brightness of the image corresponding to the first information is reduced.

That is, at a predetermined timing in the previous stage of displaying the image corresponding to the first information shown in FIG. 8 (c) in the display area 3a, the contrast between the image or message portion shown in FIG. 8 (b) and the background portion thereof. By displaying the image in the display area 3a for a certain period of time while suppressing the difference and further reducing the brightness, it is possible to reduce the exposure of the wearable device 101 wearer's perception to the “visual field struggle”. As a result, it is possible to extend the time (period) during which the wearable device 101 wearer can perceive (visually recognize) the image corresponding to the first information shown in FIG. 8 (c). The first method is to suppress the difference in contrast between the image or message portion and the background portion thereof, and to alternately display the image with reduced brightness at a predetermined timing (perceive the wearer alternately). The period (time) during which the wearer can perceive the image corresponding to the above information can be increased, which is the same as the display method described with reference to FIG. 6 or 7. Further, when displaying the image corresponding to the first information, whether to brighten or darken the brightness of the image is adjusted according to the wearer's preference by, for example, an adjustment function assigned to the (brightness adjustment) switch 16. It is preferable that it is possible. Further, for example, at night or in a room where the lighting is set to be dark, it is preferable to invert (positive-negative conversion) the brightness of the image message or image portion corresponding to the first information and the brightness of the background thereof.

In the display of the image corresponding to the second information described with reference to FIGS. 6 to 8, the color of the image or message portion of the image corresponding to the first information and the color of the background portion thereof are, for example, complementary colors. It may be displayed in a related color. Further, the color (display color) of the image corresponding to the second information may be a color similar to the color (color tone) around the display area 3a, that is, the background color (color tone), or may be a pair color. Further, the color of the image (display color) corresponding to the second information may be a warning color (red), for example, when the information to be displayed is a warning or caution (for safety management). The combination of the color of the image or message part and the color of the background part is arbitrary in any display. For example, the image or message may be displayed as black and the background may be displayed as white. It is also possible to display white and black as the background.

FIG. 9 is a schematic view showing an example of another embodiment of the wearable device. The same or substantially equivalent configurations as those of the wearable device described with reference to FIGS. 1 to 3 are designated by the same reference numerals, and detailed description thereof will be omitted.

The wearable device 1001 shown in FIG. 9 includes a light source (display information generation unit) 1011, a screen (image display unit for wearers) 1003, a light source and screen support unit (housing) 1002, and a drive circuit unit (image display). It includes a circuit and a light source drive circuit, or a signal processing unit) 4, a communication unit 5, a power supply unit 6, and the like.

The light projecting unit 1011 includes a light source 10, at least an information display unit 7, a projection (enlargement) optical system 8, and an image output mirror 1021. The light projecting unit 1011 incorporates a drive circuit unit 4, a communication unit 5, and a power supply unit 6, and is positioned at a predetermined position of the housing 1002, for example, a position that does not obstruct the line of sight of the wearer who wears the wearable device 1001. do. The screen 1003 magnifies the display image obtained by illuminating the image displayed by the information display unit 7 of the light projecting unit 1011 with the light from the light source 10 by the projection (enlargement) optical system 8, and the screen 1003 by the image output mirror 1021. The image light 13 incident on the light source 13 is visualized. That is, the screen 1003 transmits an image seen on the extension of the line of sight of the wearer wearing the wearable device 1001, that is, a part of the background (environment) image, and the displayed image is enlarged together with the visible image of the image light 13. Make it visible (perceptible) to the wearer.

The screen 1003 includes a concave mirror (Fresnel lens type half mirror surface) 1032 having a Fresnel type and a half mirror characteristic, a front side transparent refracting body 1031, a back side transparent refracting body 1033, a liquid crystal light shielding layer 1034, and the like. The screen 1003 is formed in a substantially translucent parallel flat plate shape. Therefore, the outside scenery can be visually recognized as a background field of view through the screen 1003.

The Frenel lens type half mirror surface 1032 is located between the front side transparent refracting body 1031 and the back side transparent refracting body 1033, and a part of the image light 13 reflected by the mirror surface 1021 is placed in the vicinity of the wearer's pupil 1111. Reflects on.

The wearable device 1001 shown in FIG. 9 can be used in a state where the vision correction glasses 1101 are worn due to a decrease in vision at a far point or a near point, or a difference between left and right eyes. That is, the arrangement of the screen 1003 and the light projecting unit 1011 has a degree of freedom as compared with the wearable device 101 shown in FIGS. 1 to 3. Further, the image light 13 which is an enlarged display image of the information display unit 7 passes through the lens portion of the visual acuity correction glasses 1101 only once and is guided to the wearer's pupil 1111. As a result, the same lens unit of the visual acuity correction glasses 1101 can simultaneously realize the visual acuity correction for the external scenery (background field of view) and the visual acuity correction for the additional image. Therefore, even the wearer wearing the vision correction glasses 1101 can visually recognize the external scenery (background field of view) and the displayed image at the same time.

The wearable device 1001 shown in FIG. 9 also has a liquid crystal light-shielding layer 1068. The liquid crystal light-shielding layer 1068 makes the screen 1003 non-transparent (reflecting surface) by applying a predetermined voltage to the front and back transparent electrodes 1068-1 and 1068-2 at a predetermined timing. That is, the screen 1003 can block external light when the liquid crystal light-shielding layer 1068 is on (light-shielding). As a result, basically, when the lens unit of the visual acuity correction glasses 1101 simultaneously realizes visual acuity correction for the external scenery (background field of view) and visual acuity correction for the additional image, for example, when displaying emergency information on the additional image. By blocking external light, only the displayed image can be efficiently visually recognized by the operator. This shading of external light is also useful, for example, when the wearer wants the wearer to gaze at the additional image.

In the wearable device 1001 shown in FIG. 9, a virtual image with respect to the display image displayed by the information display unit 7 is formed (displayed) by the combination of the lens group 14 and the screen 1003.

By the way, when the distance from the wearer's pupil 1111 to the virtual image position (the position where the wearer recognizes that the virtual image can be seen) is shorter than the first distance, for example, 10 cm, it is necessary to visually recognize the additional image seen near the eyes. , Increases the visual burden on the wearer. Further, when the virtual image position is shorter than the first distance, there is a risk of inducing myopia, for example, in the wearer (viewer). From the viewpoint of eye health, it is generally said that when looking at an object, it is preferable to keep it at least 30 cm away. Further, when estimating some margin, it is desirable that the distance to the virtual image position is 50 cm or more. Therefore, in the embodiment, the virtual image position is set to 10 cm or more, preferably 30 cm or more, and more preferably 50 cm or more in terms of the distance from the position of the wearer's pupil.

The wearable device 1001 may be, for example, a head-mounted display type, and may be placed on the wearer's head, for example, or may be supported by the wearer's shoulder or upper body. Of course, any (various) mounting methods called hands-free support are available.

10 and 11 are schematic views showing still another example of the embodiment of the wearable device. The same or substantially equivalent configurations as those of the wearable device described with reference to FIGS. 1 to 3 or 9 are designated by the same reference numerals and detailed description thereof will be omitted.

The wearable device 201 shown in FIGS. 10 and 11 includes a light projecting unit (display information generation unit) 210, a light projecting unit support unit (housing) 2, a display image reflector 203, and a drive circuit unit (image display circuit or signal processing). (Sometimes referred to as a unit) 204, a communication unit 5, a power supply unit 6, and the like are included.

The light projecting unit 210 includes an information display unit 211 and a projection (enlargement) optical system 212.

The information display unit 211 is, for example, obtained by applying MEMS technology, for example, by DLP (Digital Light Precessing) using a plurality of fine laser element groups (laser arrays) capable of outputting an image equivalent to a pixel of 1920 × 1080. Display the image directly (generate the image by self-luminous). The image (self-luminous image) displayed by the information display unit 211 is magnified by the projection (enlargement) optical system 212, and the image reflection optical system 214 of the display image reflector 203 enables the wearer to directly perceive the image. It reflects toward the wearer's eyes (retina).

The image catadioptric system 214 includes, for example, a Fresnel magnifying half mirror having concave mirror characteristics, and a display image of the information display unit 211 magnified by the projection (magnifying) optical system 212 is displayed on the retina (pupil) of the wearer. I will guide you to.

The image reflection optical system 214 is provided on a surface opposite to the surface on which the image reflection optical system 214 reflects an image toward the wearer's pupil (retinal), for example, a transmitted light amount adjusting liquid crystal layer or a transmitted light amount variable layer ( It may have a polarizing layer) 215. That is, when the brightness of the background (outside scenery) on the extension of the wearer's line of sight is dark or too bright, the incident light is restricted by the transmitted light amount adjusting liquid crystal layer or the transmitted light amount variable layer 215. Therefore, the brightness (easiness of visibility) of the display image guided by the image reflection optical system 214 to the wearer's retina (pupil) can be adjusted.

FIG. 11 is a schematic view showing an example of the configuration of the drive circuit unit of the wearable device shown in FIG.

The drive circuit unit 204 includes a processor (CPU) 41, a light emission control unit 221, a display image generation unit (image processing unit) 222, a storage module (memory unit) 223, and the like.

The processor 41 drives the display image generation unit 222 at the display timing of the image corresponding to the first information acquired by the communication unit 5, and the display information or the communication unit 5 (or the drive circuit unit 204) held by the storage module 223. The information display unit 211 is instructed to perform an operation corresponding to an image corresponding to the first information which is display information (data) acquired via the above. The processor 41 also drives the light emission control unit 221 to control the color and contrast ratio of the image displayed by the information display unit 211. Further, when the processor 41 operates the information display unit 211 corresponding to the image corresponding to the first information generated by the display image generation unit 222, the processor 41 corresponds to the first information at a predetermined timing in the preceding stage. The information display unit 211 is operated in response to the image corresponding to the second information for enabling the image to be visually recognized (perceived) for a predetermined period (time) or longer.

As described above, in the electronic device and the display method of the embodiment, when displaying information different from the information perceived by the other eye on the extension of the line of sight of one eye, the information is displayed on the extension of the line of sight of one eye. It is possible to provide a state in which information can be stably and visually recognized for a predetermined period of time.

As a result, information perceived by the other eye, which is different from the image information (display image) displayed on the wearable device worn by the worker, for example, in the parts yard of a factory, the product warehouse of a mail order company, or the delivery department of a retail business. Visibility can be ensured. That is, one of the wearers (workers) can be made to perceive the predetermined information without affecting the perception of the information (background, etc.) to be perceived by the other eye.

Therefore, it is required that the other one of the wearer (worker) perceive the predetermined information only by the eyes, for example, a situation in which the movement of a vehicle or the like is assumed (safety is not always guaranteed). When displaying specific information to be perceived by one eye below, the other eye can continue to recognize (perceive) the background, etc. that has been visually recognized (perceived).

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

101, 201, 1001 ... Wearable device 1, 210, 1002 ... Floodlight unit, 3 ... Screen, 4, 204 ... Drive circuit unit (display image generation unit), 7, 211 ... Information display unit, 203 ... Display image reflection Body (guide member), 214 ... Image reflection optical system, 215 ... Transmitted light amount adjustable liquid crystal layer or transmitted light amount variable layer (polarizing layer).

Claims (8)

An electronic device worn by a user
Display and
An optical system for displaying a virtual image of a display image displayed on the display unit in the line of sight of the user, and
An adjustment mechanism that adjusts the display position of the virtual image with respect to the direction of change in the display position of the virtual image that occurs in response to a change in the shape or size of the user's head.
It is equipped with a setting mechanism for setting the changing direction of the brightness of the virtual image.
The display unit displays a first virtual image together with a background visible on the user's line of sight.
The display unit displays a second virtual image for enhancing the visibility of the first virtual image together with a background visible on the user's line of sight prior to the timing of displaying the first virtual image.
The display unit increases the brightness of the first virtual image when the brightness of the background is brighter than the first brightness, and increases the brightness of the first virtual image when the brightness of the background is darker than the first brightness. An electronic device that changes the brightness of a device in a direction set by the setting mechanism. The optical system includes a lens that projects the display image and a half mirror that forms a virtual image of the display image projected by the lens.
The electronic device according to claim 1, wherein the background image on the line of sight of the user is visible to the user through the half mirror. The electronic device according to claim 1 or 2, wherein the image light including the display image can pass through the vision correction glasses used by the user only once and be guided to the pupil of the user. The electronic device according to claim 2, wherein the image light including the display image reflected by the half mirror can pass through the visual acuity correction glasses used by the user only once and be guided to the pupil of the user. In a display method in which a virtual image of a display image displayed on a display unit provided in an electronic device attached to a user is displayed on the user's line of sight.
Prior to the timing at which the display unit displays the first virtual image together with the background visible on the user's line of sight, a second virtual image for enhancing the visibility of the first virtual image is placed on the user's line of sight. Displayed on the display with the visible background,
The adjustment mechanism is used to adjust the display position of the virtual image with respect to the direction of change in the display position of the virtual image that occurs in response to a change in the shape or size of the user's head.
Set the changing direction of the brightness of the first virtual image,
When the brightness of the background is brighter than the first brightness, the brightness of the first virtual image is increased, and when the brightness of the background is darker than the first brightness, the brightness of the first virtual image is increased. A display method that changes in the set direction. The virtual image is displayed on the line of sight of the user by using a half mirror that forms a virtual image of the displayed image projected by the lens.
The display method according to claim 5, wherein the background image on the line of sight of the user is visible to the user through the half mirror. The display method according to claim 5 or 6, wherein the image light including the display image can pass through the vision correction glasses used by the user only once and be guided to the pupil of the user. The display method according to claim 6, wherein the image light including the display image reflected by the half mirror can pass through the visual acuity correction glasses used by the user only once and be guided to the pupil of the user.

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