KR100275387B1 - Virtual reality display - Google Patents

Abstract

PURPOSE: A virtual reality display is provided to simplify structure and to realize a high-density and super-resolution image by preparing a screen of one frame with a line light source. CONSTITUTION: A line light source(1) comprises several light emitting devices aligned to a first direction. A light path(3) transfers the line light from the line light source(1). A first focusing unit(2) focuses the line light from the line light source(1) to the light path(3). A light separation unit(5) separates the light emitted from the light path(3) in two paths. Two actuator mirrors(7,8) reflect each line light separated by the light separation unit(5) at a direction perpendicular to the first direction. The virtual reality display is power-efficient.

Description

Virtual reality display

The present invention relates to a virtual reality display device, and more particularly, to a virtual reality display device using a line light source.

The virtual reality display device refers to a system showing a virtual phenomenon created by an artificial environment, in particular, a computer graphic system. One can experience various things through the virtual reality display device. For example, astronauts can conduct flight training through a virtual reality display without flying a real airplane. In addition, people can encounter various real situations through the virtual reality display device. A representative example of such a virtual reality display device is a head mounted display (HMD), which provides image information to two displays and displays positioned at a certain distance in front of the human eye in the form of goggles. An image processing drive. Thus, people wear the HMD as described above and taste virtual reality by the image appearing on the display.

In the case of HMD, which is commercially available up to now, a liquid crystal display (LCD) or a cathode ray tube (CRT) is mainly applied as a display element. In the case of liquid crystal displays, the number of pixels that can be arranged per unit area is limited, which makes it difficult to raise the resolution to a high level, and in the case of cathode ray tubes, the length is long, heavy, and consumes a lot of power. Emits harmful waves that are harmful to the eyes, such as electron beams.

An object of the present invention is to provide a high resolution virtual reality display device.

Another object of the present invention is to provide a virtual reality display device capable of miniaturization and light weight and low power consumption.

1 is a schematic structural diagram of a preferred embodiment of a virtual reality display device according to the present invention.

FIG. 2 is a schematic excerpt perspective view illustrating a main portion of the virtual reality display device illustrated in FIG. 1.

FIG. 3 is a perspective view illustrating an operation of an actuating mirror applied to the virtual reality display device illustrated in FIG. 1 and a change in a traveling path of light.

4 is a front view illustrating a first example of a line light source that may be applied to the virtual reality display device illustrated in FIG. 1.

5 is an explanatory diagram for explaining the structure of a screen of one frame for transmitting the actual screen in line units.

6 is a front view illustrating a second example of a line light source that may be applied to the virtual reality display device illustrated in FIG. 1.

FIG. 7 is a front view illustrating a third example of the line light source that may be applied to the virtual reality display device illustrated in FIG. 1.

According to the present invention for achieving the above object, a line light source by a plurality of light source elements arranged in the first direction; Light guiding means for transmitting line light from the line light source; Spectroscopic means for branching the line light emitted from the light guiding means in two paths; The present invention provides a virtual reality display device comprising: two actuating mirrors each reflecting line light branched by the spectroscopic means and scanning in a direction perpendicular to the first direction.

In the present invention, a first light converging means for converging the line light from the lie light source to the light guiding means is provided between the line light source and the light guiding means, and the light guiding means is provided between the light guiding means and the branching means. Preferably, a second light converging means for focusing the light emitted from the light into the branching means is provided.

In addition, the line light source is preferably applied to the light emitting diodes arranged in a line as a light source element, and to display the unit image sequentially line by line.

Hereinafter, exemplary embodiments of a virtual reality display device according to the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, a virtual reality display device according to an exemplary embodiment of the present invention generally includes four elements, that is, a linear LED array 1, an optical fiber 3, a spectroscope 5, and an actuating mirror 7. Equipped with 8. The linear light emitting diode array 1 displays images of one frame in a line-by-line order, and is composed of a plurality of LED chips arranged in a first direction. The optical fiber 2 transmits line light incident from the linear LED array 1. The spectroscopic section 5 as the spectroscopic means splits the light emitted from the optical fiber 2 in two paths, that is, by the naked eye. The actuating mirrors 7 and 8 reproduce the image of one frame by scanning the line light, and are synchronized with the generation signal of the line light generated by the linear LED array 1. The actuating mirrors 7 and 8 scan a range of angles in a second direction orthogonal to the first direction of line light incident from the spectroscopic section 3 in the first direction.

In the above structure, between the linear light emitting diode array 1 and the optical fiber 2, a first focusing part 2 for converging the line light emitted from the linear light emitting diode array 1 to the optical fiber 2 is provided. Prepared. The first focusing part 2 is composed of a plurality of lenses and focuses the line light from the linear light emitting diode array 1 to the thin optical fiber 2 to the spectroscopic part 5 through the optical fiber 2. Allows light to be transmitted The first focusing unit has a magnification adjusted to focus line light from the linear LED array to the optical fiber. A second focusing part 4 is provided between the optical fiber 2 and the spectroscopic part 5 to focus light transmitted through the optical fiber 2. The second focusing unit 4 focuses on the spectroscopic unit 5 to recognize the image with the naked eye, and has a magnification adjusted according to the size of the virtual screen. The spectroscope 4 is for obtaining line light incident through one path and split into two paths, and is made of a single or a plurality of optical materials. In the present embodiment, the beam splitter 51 which splits the first incident line light into two and a reflecting mirror 52 reflecting one line light separated by a traveling path parallel to the other line light. The reflector 52 is only for propagating the light to the desired position, and may be omitted depending on the position of the actuating mirrors 7 and 8 or the arrangement of the optical parts including the same. In addition, the spectroscope 5 may further include other optical components according to overall design conditions in addition to the beam splitter 51 and the reflector 52.

As shown in FIG. 3, the actuating mirrors 7 and 8 reflect the incident line light in a predetermined angle range while vibrating a predetermined angle range. At this time, the reflection direction vibrates at regular intervals in the direction orthogonal to the longitudinal direction of the line light, that is, in the second direction. When the actuating mirrors 7 and 8 operate at a speed of 60 HZ, the unit image, that is, the image of one frame, is also 60 HZ. At this time, the rotation angle range of the actuating mirror (7) (8) recognizes the entire light from the actuating mirror (7) (8) whose range is visible to the naked eye, that is, the angle is continuously changed with the naked eye. It should be within the range that can be done, otherwise the whole image cannot be seen. In addition, the distance between the actuating mirrors 7 and 8 should be equal to the average distance between both eyes when the actuating mirrors 7 and 8 are viewed by the naked eye. It is preferable to add a gap adjusting means capable of adjusting the gap between (7) and (8). The driving body for operating the actuating mirrors 7 and 8 may be a generally known mechanical or magnetically vibrating body.

Referring to FIG. 4, the LED chips 11 are arranged in a line on the linear LED array 1. In the case of monochromatic light, the LED chips 11 emit the same color light. At this time, the number of the LED chip 11 determines the resolution of one screen. For example, in the case of a screen having a resolution of 640 * 480, the number of the LED chips 11 is 640 or 480. Therefore, when the image signal is sent to the linear LED array 1, 640 or 480 pixel signals are sent at a time so that the linear LED array displays one line of the screen, and this operation is performed 480 or 640 times, thereby Screen transmission ends. This frame forming process can generally be easily understood from a linear sequential driving method such as in a flat panel display panel, for example, a plasma display panel or a liquid crystal display panel.

Referring to FIG. 5, an image 10 of a frame of a display screen having a resolution of 640 * 480 is displayed by a linear light emitting diode array 1 line by line in a vertical direction, and a frame of one frame for one period. The image 10 is displayed. At the same time, the line light transmitted from the optical fiber 3 completes one screen by the scanning operation of the actuating mirrors 7 and 8.

Meanwhile, in the linear LED array 1, one pixel 111 is composed of three LED chips in a color type. In this case, as shown in FIG. 6, the LED chips are arranged in the order of RGBRGB, or FIG. As shown in Fig. 7, the LED chips are arranged in three rows, where each row emits light of different colors, for example, the first row is red, the second row is green, and the third row is blue.

In the case of a color linear light emitting array having a single column as shown in FIG. 6, since one pixel 111 is composed of three LED chips, for example, if a resolution of 640 * 480 is used, for example, 640 * 3 or 480 * 3 LED chips are provided. Arranged in line.

In the case of FIG. 7, since the color light is different for each column, LED chips of 640 or 480 different color lights are arranged in each row.

In the above, two specific examples of LED chip arrangements have been described. In addition, various types of arrangements can be realized. As in a typical color display, pixels can be implemented with three LED chips, or as in a two-color display, a pixel can be implemented with two LED chips.

In the virtual reality display device according to the present invention as described above, the screen viewed through the line light source and the virtual screen, ie, the actuating mirror, is isolated by the optical component including the optical fiber, thereby controlling the line light from the line light source. The design of the line light source is free because it is easy and the size of the line light source, in particular, the length and the size of the virtual screen are not limited to each other. That is, the size of the virtual screen can be freely adjusted regardless of the size of the line light source, and vice versa. This is because a series of optical components can be freely controlled between the line light source and the virtual screen. The line light source can only be regarded as limited by the focusing means for focusing the first focusing part, ie, the line light from the line light source, onto the optical fiber, but the first focusing part is designed to correspond to the size of the line light source, in particular the magnification can be freely adjusted. It is not related to this. And the virtual screen can also be adjusted regardless of the size of the line light source. It is possible to freely adjust the size of the virtual screen by adjusting the design, in particular, the magnification of the optical component, especially the second focusing part, on the traveling path of the line light emitted from the optical fiber under appropriate conditions. Therefore, by securing a sufficient length of the line light source, in particular, the number of pixels, it is possible to realize an ultra-high resolution virtualized screen compressed to a constant size. In the case of such a compressed virtual screen, even if the distance between the pixels of the actual line light source is greatly enlarged, the distance between the pixels on the virtual screen is reduced correspondingly, so that the user cannot recognize the distance between the pixels.

According to the present invention as described above, since a frame of one frame is formed by line light sources in line units, it is possible to obtain a low power consumption type virtual reality display device with a simplified and smaller overall structure than a conventional virtual reality display device. In particular, the virtual reality display device according to the present invention can realize a high-density, ultra-high resolution virtual screen by appropriate design of the internal optical component.

The present invention as described above is not limited to the above embodiments, and can be implemented in various forms based on the technical idea of the present invention, which also belongs to the technical scope of the present invention.

Claims (6)

A line light source by a plurality of light source elements arranged in a first direction; Light guiding means for transmitting line light from said line light source; First converging means for concentrating line light from the line light source to the light guiding means; Spectroscopic means for branching the line light emitted from the light guiding means in two paths; And two actuating mirrors, each reflecting line light branched by the spectroscopic means and scanning in a direction orthogonal to the first direction. The virtual reality display device according to claim 1, wherein a second focusing means is provided between the light guiding means and the spectroscopic means. The virtual reality display device of claim 1, wherein the light guiding means is an optical fiber. The said spectroscopic means is any one of the beam splitter which splits the light radiate | emitted from the said light guide means into two paths, and the light isolate | separated by the beam splitter is the progress of another light. Virtual reality display device comprising a reflector reflecting in the direction parallel to the path. The method according to any one of claims 1 to 3, And the light source elements are LED chips. The method of claim 5 The light source device is a virtual reality display device characterized in that the combination of the different types of LED chips of different light emission colors.

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