TW201805688A - Display adjustment method for near-eye display device wherein the effect of focusing image multiple times can be achieved if the image outputted to one, or any two or more layers of the display module is processed in a symmetrical manner - Google Patents

Abstract

A display adjustment method for a near-eye display device is capable of at least arranging, on a near-eye display device, at least one layer of display module, at least one image output module, and an image output adjustment module, and at least one image can be outputted to the display module through the image output module, afterwards, the image outputted to the display module can be adjusted and displayed clearly through a fusion technology, a collimation technology or/and a chamfering technology. Preferably, the image output adjustment module can process multiple images in a symmetrical manner so that the image outputted to the display module has the image focusing effect. When the display module consists of multiple layers, the effect of multiple image focusing can be achieved if the image outputted to one, or any two or more layers of the display module is processed in a symmetrical manner.

Description

Display adjustment method for near-eye display

The present invention relates to a display adjustment method for a near-eye display, and particularly to a display adjustment method capable of adjusting the output image to be clearly presented through an image fusion technology, a collimation technology, and / or a lead angle technology. .

In response to the increasing demand for real-time information in modern society, the delivery of on-demand information has received much attention. The near-eye display is a good choice for portable personal information devices due to its portability and combined with electronic devices that can update and transfer images, colors or text at any time. Early near-eye displays were mostly used for military or government purposes. Recently, manufacturers have seen business opportunities and introduced near-eye displays to homes. In addition, entertainment-related players are also optimistic about the potential of this market. For example, manufacturers of home amusement instruments and software for amusement instruments have invested in research and development.

Current near-eye displays (NEDs) include head-mounted displays (HMDs), which project images directly into the viewer's eyes. These displays can overcome other factors in the form of mobile display by synthesizing a virtual large-format display surface. Available in limited screen sizes or for virtual or augmented reality applications.

The near-eye display can be further subdivided into two categories: immersive displays and see-through displays. Among them, an immersive display can be used in a virtual reality (VR) environment to use a synthetic presentation image to completely cover the user's field of vision. In augmented reality (AR) applications, see-through displays can be used, in which text, other synthetic annotations, or images can be superimposed in the field of view of users in the physical environment. In terms of display technology, AR applications require translucent displays (for example, implemented by optical or electro-optical methods) so that the near-eye display can simultaneously view the physical world.

However, due to the fact that the human eye cannot focus (focus) on an object placed at a close distance (for example, when the user is wearing glasses, reading the distance between the lens of the magnifying glass and the user's eye) Difficult to construct. Therefore, the near-eye display must be adjusted to make the viewer comfortable to use, otherwise it will lead to situations that affect the use, such as out-of-focus, etc. However, traditionally, complex and bulky optical components are used for adjustment. Most of them must be worn directly on the viewer's head, so the near-eye displays that are too bulky are often not acceptable to consumers.

Therefore, in order to overcome the above problems, if an image fusion technology, a collimation technology, or / and a lead angle technology can be used to adjust the output image so that it can be clearly presented, it will not need to use heavy optical components, and it can also save The extra cost of using bulky optics should be an optimal solution.

The present invention is to provide a display adjustment method for a near-eye display, which can be adjusted through a fusion technology, a collimation technology, and / or a lead angle technology so that the output image can be clearly presented, so that it is not necessary to use bulky Optical components, and can also save the extra cost of using bulky optical components.

The above-mentioned display adjustment method for a near-eye display can be achieved by: (1) at least one display module, at least one image output module, and an image output adjustment module are arranged on a near-eye display, and the The image output module is capable of outputting at least one image to the display module; and (2) adjusting and outputting to the display module through an image fusion technology, a collimation technology, and / or a lead angle technology The image can be clearly displayed.

More specifically, the fusion technology is to control the image output module to simultaneously display a plurality of images with the same content and the corresponding display positions on the display module, so that a user can wear the near-eye display, The user's eyeball can see a clear image that is displayed after multiple images are superimposed on the display module.

More specifically, the image output adjustment module can process a plurality of images in a symmetrical manner so that the image output to the display module has an image focusing effect.

More specifically, when the display module is multi-layer, if the image output to one layer, any two layers, or more than two layers of the display module is processed in a symmetrical manner, it can reach multiple times. The effect of image focus.

More specifically, the display of a plurality of images with the same content on the display module and the display position is symmetrical can be further processed by a lead angle to adjust a plurality of images with the same content and the display position is symmetrical. Image display angle.

More specifically, the collimation technology is to perform a collimation process on each pixel or a collimation process on each image, so as to guide the image output by the image output module to the display module. The direction of the light and improve the resolution after the image is output.

More specifically, the collimation technology directs light through a micro lens technology or a light well technology on the display module, where the micro lens technology changes light through at least one micro lens, and the The light well technology passes through a light well so that the light passing through the light well can go straight.

More specifically, the micro lens can be further subjected to a guide angle process to adjust the direction of the collimated light.

More specifically, during the manufacturing process of the display module, collimation technology or micro-lens technology can be used for processing, so that the display module after shipment has the effect of directing light.

More specifically, the lead angle technology is to perform lead angle processing on each pixel or lead angle processing on each image, so that the angle of each image output to the display module is different, so that More than two images can be merged together.

More specifically, the lead angle technology is to perform lead angle processing on the display module itself, and the lead angle of the display module will be able to adjust the light direction so that two or more images can be overlapped and merged.

More specifically, the guide angle technology is to enable different display angles of the images output by the image output module, so that two or more images can be overlapped and merged.

More specifically, the focus distance of every two images output by the image output module to the display module can be adjusted to change the depth of field.

More specifically, the display module can be a transparent display or a non-transparent display, and the transparent display has at least one transparent real scene area, and the center of the non-transparent display has at least one real scene window.

More specifically, the display adjustment method for a near-eye display is capable of simultaneously displaying multiple images of the same content around a transparent real scene area on the transparent display.

More specifically, the display adjustment method for a near-eye display can display multiple images of the same content at the same time around a live view window on the non-transparent display.

Regarding other technical contents, features and effects of the present invention, they will be clearly presented in the following detailed description of the preferred embodiments with reference to the drawings.

Please refer to FIG. 1, which is a schematic flowchart of a display adjustment method for a near-eye display according to the present invention. As can be seen from the figure, the steps are: (1) At least one display module, at least one An image output module and an image output adjustment module, and at least one image can be output to the display module 101 through the image output module; and (2) an image fusion technology, a collimation technology, or / And a lead angle technology to adjust so that the image output to the display module can be presented 102 clearly.

Because the present invention can enable one or two or more technologies of fusion technology, collimation technology, and / or guide angle technology to enable the image output to the display module to be clearly presented, the near-eye display 1 is like the second As shown in the figure, it has at least one layer of display module 11, at least one image output module 12, and an image output adjustment module 13. The near-eye display 1 is a near-eye capable of directly projecting an image into a viewer's eyes. Display devices, and can be used in environments such as virtual reality (VR) or augmented reality (AR) as appropriate (such as head-mounted displays);

The fusion technology mentioned in the present invention is to control the image output module 12 to display a plurality of images with the same content and corresponding display positions on the display module 11 at the same time, so that a user can wear the near-eye display. , The user's eyeball can see the clear image presented by overlapping multiple images on the display module;

As shown in FIG. 3A and FIG. 3B, the display positions are symmetrical, and multiple images 121 can be processed in a symmetrical manner, so that the image 121 output to the display module 11 has an image focusing effect. The person is watching with near eyes, so if multiple images 121 are displayed in a symmetrical manner, the images 121 viewed by both eyes will be transmitted to the brain after the optic nerve crosses and merge into a single clear image, so it can achieve image focus effect;

In addition, when the display module 11 is multi-layered, if the image output to one layer, any two layers, or more than two layers of the display module 11 is processed in a symmetrical manner, multiple image focusing can be achieved. Effect.

In addition, if the display module is a transparent display 111, as shown in FIG. 4A, at least one transparent real scene area 1111 is provided at the center of the transparent display 111, and the image output module 12 can output an image to the transparent real scene area. For areas other than 1111, on the one hand, when multiple transparent images 121 of the same content are displayed at the same time around the transparent reality area 1111, the output image 121 can be made symmetrical to achieve the effect of image focusing. It will not be output to the transparent real scene area 1111, so the viewer can directly see the outside real scene through the transparent real scene area 1111, so as to achieve the combination of the virtual image and the real image;

If the display module is a non-transparent display 112, as shown in FIG. 4B, at least one real-view window 1121 can be provided at the center of the non-transparent display 112, and the image output module 12 can output an image 121 to the real-view window. Areas other than 1121. On the one hand, when multiple real-life images 121 are displayed around the real-world window 1121, the output image can be symmetrical to achieve the effect of image focus. On the other hand, because image 121 does not Output to the real view window 1121, so the viewer can directly see the real scene outside through the real view window 1121, so as to achieve the combination of the virtual image and the real image.

In addition, when a plurality of images with the same content and corresponding display positions are displayed on the display module, each image can be processed by a lead angle to adjust a plurality of images with the same content and the display positions are symmetrical. The image display angle is such that the image 121 seen by both eyes is easier to focus and merge into a single clear image, so that the effect of image focusing is more obvious.

The collimation technology mentioned in the present invention is to collimate each pixel or collimate each image to guide the image output by the image output module 12 to the display module 11 The light direction, and improve the resolution after the image is output;

The above-mentioned collimation technology is described as follows: (1) The display module 11 is guided by a micro-lens technology to direct light, wherein the micro-lens technology is to change light through at least one micro-lens, and the micro-lens can Guide angle treatment is then performed to adjust the direction of the collimated light; (2) A light well technology is used to guide the light on the display module 11, wherein the light well technology is transmitted through a light well so that the light passing through the light well can Straight forward; (3) During the manufacturing process of the display module 11, collimation technology or micro lens technology can be used for processing, so that the display module has the effect of directing light to achieve the purpose of image focusing.

The lead angle technology mentioned in the present invention is to perform a lead angle process on each pixel or a lead angle process on each image, so that the angle of each image output to the display module 11 is different, so that the two More than one image can be overlapped and merged;

The above-mentioned guide angle technical description is as follows: (1) The guide angle processing can be performed on the display module 11 itself so that the guide angle of the display module 11 can adjust the light direction to achieve more than two The images can be overlapped and merged; (2) The image display angle output by the image output module 12 can be different, so that two or more images can be overlapped and merged. In this state, two or more image output modules 12 must be used , And adjust the angle of the image output module 12 itself or the setting position of the image output module 12 (the setting position is different, even if the angle of each image output module 12 itself is the same, the final output is The image position of the display module 11 will also be different).

In addition to the above-mentioned fusion technology, collimation technology and guide angle technology, the focus distance of each two images output by the image output module 12 to the display module 11 can be adjusted to change the depth of field.

Compared with other conventional technologies, the display adjustment method for near-eye displays provided by the present invention has the following advantages: 1. The present invention can be achieved by a fusion technology, a collimation technology, and / or a lead angle technology. The adjustment enables the output image to be presented clearly, so that it does not need to use bulky optical elements, and can also save the extra cost of using bulky optical elements. 2. The system of the present invention can use a transparent display or a non-transparent display, and at least one real scene area is set in the center, and the image is output to an area outside the real scene area. Therefore, during the image display process, the viewer Then you can directly see the outside real scene through the real scene area to achieve the effect of combining virtual and real images. Such an effect will be very suitable for augmented reality (AR).

The present invention has been disclosed as above through the above-mentioned embodiments, but it is not intended to limit the present invention. Any person with ordinary knowledge in this technical field will understand the foregoing technical features and embodiments of the present invention without departing from the present invention. Within the spirit and scope of the invention, some modifications and retouching can be made. Therefore, the scope of patent protection of the present invention shall be subject to the definition of the claims attached to this specification.

1‧‧‧Near-eye display
11‧‧‧Display Module
111‧‧‧ transparent display
1111‧‧‧ transparent real area
112‧‧‧ Non-transparent display
1121‧‧‧real view window
12‧‧‧Image output module
121‧‧‧Image
13‧‧‧Image output adjustment module

[FIG. 1] It is a schematic flow chart of a display adjustment method for a near-eye display according to the present invention. [Figure 2] Schematic diagram of the near-eye display of the near-eye display display adjustment method of the present invention. [FIG. 3A] It is a schematic diagram of the first implementation of the fusion image of the display adjustment method for the near-eye display of the present invention. [FIG. 3B] It is a schematic diagram of the second implementation of the fusion image of the display adjustment method for the near-eye display of the present invention. [FIG. 4A] It is a schematic diagram of the fusion image implementation of the transparent display for the display adjustment method for the near-eye display of the present invention. [FIG. 4B] It is a schematic diagram of the fusion image implementation for a non-transparent display of the display adjustment method for a near-eye display of the present invention.

Claims (16)

A display adjustment method for a near-eye display is as follows: At least one display module, at least one image output module, and an image output adjustment module are provided on a near-eye display, and the image output module is passed through the image output module. At least one image can be output to the display module; and an image output to the display module can be clearly displayed through an image fusion technology, a collimation technology, and / or a lead angle technology. The display adjustment method for a near-eye display as described in claim 1, wherein the fusion technology is to control the image output module to simultaneously display a plurality of images with the same content and symmetrical display positions on the display module, In order for a user to put on the near-eye display, the user's eyeball can see a clear image that is displayed after the multiple images are superimposed on the display module. The display adjustment method for a near-eye display as described in claim 2, wherein the image output adjustment module can process a plurality of images in a symmetrical manner so that the image output to the display module has an image focusing effect . The display adjustment method for a near-eye display as described in claim 2, wherein when the display module is multi-layer, if the image output to one layer, any two layers, or more than two layers of the display module is symmetrical, After processing in this manner, the effect of image focusing can be achieved multiple times. The display adjustment method for a near-eye display as described in claim 1, wherein a plurality of images having the same content and the display positions are displayed on the display module can be further processed by a lead angle to adjust a plurality of images having the same content. The image display angle of the content and the image whose display position is symmetric. The display adjustment method for a near-eye display as described in claim 1, wherein the collimation technology is to collimate each pixel or collimate each image to guide the image output mode. The light direction of the image output to the display module by the group, and improve the resolution after the image is output. The display adjustment method for a near-eye display as described in claim 1, wherein the collimation technology is to direct light through a micro lens technology or a light well technology on the display module, wherein the micro lens technology is transmitted through At least one micro lens changes the light, and the light well technology passes a light well so that the light passing through the light well can go straight. The display adjustment method for a near-eye display according to claim 6, wherein the microlens can be further subjected to a guide angle process to adjust the direction of the collimated light. The display adjustment method for a near-eye display according to claim 6, wherein the manufacturing process of the display module can be processed using collimation technology or micro-lens technology, so that the display module has the effect of directing light . The display adjustment method for a near-eye display as described in claim 1, wherein the lead angle technology is to perform a lead angle processing on each pixel or a lead angle processing on each image so that each output is output to the display mode. The angles of the images on the group are different, so that two or more images can overlap and merge. The display adjustment method for a near-eye display as described in claim 9, wherein the lead angle technology is to perform lead angle processing on the display module itself, and the lead angle of the display module will be able to adjust the light direction to Enable two or more images to overlap and merge. The display adjustment method for a near-eye display according to claim 9, wherein the guide angle technology is to enable different image display angles output by the image output module so that two or more images can be overlapped and merged. The display adjustment method for a near-eye display according to claim 1, wherein the focus distance of every two images output by the image output module to the display module can be adjusted to change the depth of field. The display adjustment method for a near-eye display according to claim 1, wherein the display module can be a transparent display or a non-transparent display, and the transparent display has at least one transparent real scene area, and the non-transparent display area The center of the display has at least one live view window. The display adjustment method for a near-eye display as described in claim 13, capable of simultaneously displaying a plurality of images of the same content around the transparent real scene area on the transparent display. The display adjustment method for a near-eye display as described in claim 13, can display multiple images with the same content at the same time around the real-view window on the non-transparent display.