KR20030024021A - Head Mount Display - Google Patents

Abstract

PURPOSE: A head mounted display is provided, which is worn conveniently and has a low fabrication cost with a simple structure, and reduces fatigue of eyes as assuring a visual field. CONSTITUTION: According to the head mounted display, an optical signal output part(10) is connected to a video device and converts a video signal from the video device into an optical signal and then outputs it. And a lens part(20) has a plurality of film layers which are arranged on an optical signal output path of the optical signal output part and are stacked each other, and a reflector(23) which is intervened in each film layer and has a fixed reflection angle for the optical signal to converge to eyes of a user. The reflection angle of the reflector becomes smaller as going to a film layer arranged outermost from the film layer adjacent to the eyes. The optical signal output part is a LCOS(Liquid Crystal On Silicon) or a GLV(Grating Light Valve).

Description

Head Mount Display Device {Head Mount Display}

The present invention relates to a head mounted display.

In general, the head-mounted display device is developed as a kind of visual output device that is worn and worn on the user's head in a virtual reality (VR) system, and is increasingly used in various fields. Such a head mounted display device is a device that displays a video displayed by a display device such as a conventional LCD or a CRT to a user using a precise optical mechanism.

The head mounted display device requires a very precise optics in order to focus on a very short distance and not to cause eye strain since the image screen is located at a position very close to the eye.

As a conventional head-mounted display device, as shown in FIG. 1, various types of reflecting mirrors are provided in the opaque lens unit 120, and are connected to an image device (portable DVD player or computer main body, etc.) not shown. It receives the video signal from and provides a large image through the reflector. However, such a conventional head-mounted display device provides an image that is excellent enough to produce an effect equivalent to viewing a large 45-inch screen from 2 meters in front, but is not suitable for everyday wear due to structural limitations, and is worn without transparency. The disadvantage is that it is impossible to move.

In addition, another conventional head mounted display device illustrated in FIG. 2 overcomes the aforementioned disadvantages of the conventional head mounted display device by providing a lens unit 120a in which a small prism is inserted into the spectacle lens 110. . However, such a conventional head-mounted display device is provided with a small prism 120a in the lens, which not only obstructs the field of view of the prism portion, but also causes eye fatigue when used for a long time due to the fixed position of the prism. The problem is that the entire field of view cannot be used as a displayable area.

Accordingly, an object of the present invention is to provide a head-mounted display device that can be easily worn, the structure is simple and the volume is small, thereby reducing the management and manufacturing cost of the product, and also reducing eye fatigue while securing a visual field during wearing. To provide.

1 is a perspective view of a conventional head mounted display device;

2 is a perspective view of another conventional head mounted display device;

3 is a perspective view of a head mounted display device according to the present invention;

4 is a block diagram of a head mounted display device according to the present invention;

5 to 8 illustrate a process of manufacturing a lens unit in the head mounted display device according to the present invention.

<Description of the symbols for the main parts of the drawings>

1: head mounted display device

10: optical signal output section 11: LCOS

12: video signal input unit 13: silicon chip

15: Liquid Crystal 20: lens unit

21 film layer 23 reflector

30: latch holding unit 40: imaging device

According to an aspect of the present invention, there is provided a head mounted display device comprising: an optical signal output unit connected to a predetermined image device to convert an image signal from the image device into an optical signal and output the optical signal; A lens having a plurality of transparent film layers disposed on the optical signal output path of the optical signal output unit and stacked on each other, and reflectors forming a predetermined reflection angle so that the optical signals interposed in the respective film layers are converged to the user's eyes. It is achieved by a head mounted display device characterized in that it comprises a portion.

Here, the reflector is preferably disposed so that the reflection angle becomes smaller from the film layer adjacent to the eye toward the film layer disposed at the outermost part, so that the reflection angle is formed so that the optical signal output from the optical signal output unit converges on the user's eye.

The optical signal output unit may be provided as a liquid crystal on silicon (LCOS) or a grating light valve (GLV), and the lens unit may be a planar lens curved upward and downward on a perspective surface so that the optical signal may be converged to the user's eyes. It is effective to be prepared.

And a pair of latch holding portions coupled to the lens portion and held by the user's ear, wherein the optical signal output portion is disposed in the latch holding portion, and the lens portion and the optical signal output portion are each paired. Of course, it can be prepared.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. Here, some of the drawings have been somewhat exaggerated for convenience of explanation.

3 is a perspective view of a head mounted display device according to the present invention. As shown in the figure, the head mounted display device 1 according to the present invention is provided in a form similar to glasses, and receives a video signal from a predetermined video device 40 (for example, a portable DVD player or a computer body). The optical signal output unit 10 receives and converts the optical signal into an optical signal, and has a plurality of transparent film layers 21 stacked on each other and a reflector 23 interposed in each film layer 21 having a predetermined reflection angle. alkylene jeubu 20 and lens portion 20 are engaged with hook retention ears of the user and a hook retention portion (30) of the pair.

The optical signal output unit 10 is connected to a predetermined image device 40 and receives an image signal (RGB signal and V, H sync signal) from the image device 40 and converts the image signal into an optical signal. 11, but may be provided as a liquid crystal on silicon (GLV) or a grating light valve (GLV), but the present invention will be described as being provided as an LCOS (11).

As shown in the block diagram of FIG. 4, the LCOS 11 includes an image signal input unit 12 that receives an image signal from the image device 40, and an image signal input from the image signal input unit 12 as an optical signal. Silicon chip 13 to be converted, and Liquid Crystal (15) for receiving and displaying the optical signal converted by the silicon chip (13).

The image signal input unit 12 is electrically connected to the image device 40 to receive an image signal (RGB signal and V, H sync signal) from the image device 40 and transmit the image signal to the silicon chip 13.

The silicon chip 13 converts the image signal received from the image signal input unit 12 into an optical signal that can be output from the lens unit 20 to be described later, and transmits the converted image signal to the liquid crystal 15. When the light is reflected by the liquid crystal 15, the image is projected onto the lens unit 20 to be described later.

The lens unit 20 is disposed on the optical signal output path of the optical signal output unit 10 and is provided with a plurality of transparent film layers 21 stacked on each other and interposed in each film layer 21 to output the optical signal output unit 10. It includes a reflector 23 to form a predetermined reflection angle so that the optical signal output from the) converges to the eyes of the user.

Each film layer 21 has a thickness of about 5 microns and is made of transparent polyester or polyethylene (see Fig. 5). In each film layer 21, as shown in Fig. 7, a reflector 23 which reflects an optical signal will be incorporated. When each of the film layers 21 prepared as described above are laminated to each other by about 2000 sheets and pressed by a method such as heat-resistant compression, the lens unit 20 having a thickness of about 1 centimeter is completed.

The reflector 23 may be made of a material such as silver or aluminum, which can be totally reflected, and is embedded in each film layer 21 forming the lens unit 20 along the longitudinal direction (see FIG. 7). Each reflector 23 is arranged so that the reflection angle becomes smaller from the film layer 21 adjacent to the eye toward the outermost film layer 21, thereby totally reflecting the optical signal output from the optical signal output unit 10, One display screen is formed (see Fig. 8). The display screen formed by the reflector 23 may adjust the position of the optical signal output unit 10 manually, or by adjusting the output position of the optical signal in software, so that the display screen is moved up and down of the lens unit 20. You can adjust the movement from side to side.

A process of forming one lens unit 20 by a plurality of film layers 21 having a reflector 23 having a predetermined reflection angle will be described with reference to FIGS. 5 to 8 as follows.

First, as shown in FIG. 5, a plurality of thin and transparent film layers 21 having a thickness of about 5 microns are provided.

6, the film layer 21 is cut using a water gun or a laser so as to incorporate the reflector 23 into each film layer 21. As shown in FIG. Here, the cutting angle θ of each film layer 21 is determined by the reflection angle of each reflector 23.

The reflecting angle of each reflector 23 is arranged so that the reflecting angle becomes smaller from the film layer 21 adjacent to the eye toward the film layer 21 disposed at the outermost side, so that the optical signal output from the optical signal output unit 10 is used. It is embedded in the film layer 21 so as to converge with the eyes of (see Fig. 8). Here, the spacing of each reflector 23 is located at intervals of about 15-20 microns, as shown in Figure 8, the user can secure the field of view even while wearing the head-mounted display device of the present invention through the spacing have.

The method of coupling the reflector 23 to the film layer 21 provided as shown in FIG. 6 may include various methods. In the present invention, both the film layers cut from the reflector 23 heated in a liquid state at a predetermined reflection angle ( 21), the reflector 23 and the film layer 21 are combined by pressing both film layers 21 (refer FIG. 7).

In this way, the film layer 21 having the reflector 23 therein is stacked as shown in FIG. 8, and then the film layers 21 are combined to prepare the lens unit 20 by heat-pressurizing the respective film layers 21. In forming the lens unit 20 by heat-resistant pressing the plurality of film layers 21, the lens unit 20 is heat-resistant pressed to have a concave planar lens shape so that the optical signal can be converged to the eyes of the user (Fig. 8). As shown, the lens portion is formed concave a predetermined angle toward the eyes of the user).

According to such a configuration, the video signal generated from the predetermined video device 40 is input to the video signal input unit 12 and transferred to the silicon chip 13, and the silicon chip 13 converts the video signal into an optical signal. Convert it and pass it to Liquid Crystal (15). Accordingly, when light is reflected by the liquid crystal 15, an image to be projected on the lens unit 20 is generated. The generated optical signal is converged to the eyes of the user through the lens unit 20 disposed on the optical signal output path to provide an image to the user. Here, the optical signal output from the optical signal output unit 10 has the same effect as seeing a large screen of 45 inches from 2 meters in front by a plurality of reflectors 23 arranged to converge to the user's eyes as described above. Outputs the video.

Thus, since the head mounted display device 1 according to the present invention is provided in a form similar to glasses, it is easy to wear, the structure is simple and the volume is small, as well as the manufacturing cost is reduced, as shown in Figure 3, By using the distance between the reflector 23 and the reflector 23 (approximately 15-20 microns; see FIGS. 3 and 8), a field of view can be secured even when the head mounted display device 1 is worn. Due to the wide display screen formed by 23, there is provided a head mounted display device 1 that can reduce eye fatigue.

In the above-described embodiment, the optical signal output unit 10 is provided as an LCOS 11 or a GLV. However, this is only an example. The optical signal output unit 10 converts an image signal into an optical signal using a tricolor filter and outputs the optical signal. Of course, it can be provided in various forms.

In the above-described embodiment, the head mounted display device 1 according to the present invention has been described as being provided in a form similar to glasses. However, this is merely an example of the most ideal embodiment and can be provided in various forms.

In addition, in the above-described embodiment, the head mounted display device 1 according to the present invention has been described as being provided in the form of a monocular (Monocular). Of course, it can be prepared as. In this case, the lens unit 20 and the optical signal output unit 10 are provided in pairs, respectively.

In the above-described embodiment, the reflector 23 is made of a material such as silver or aluminum, which can be totally reflected, and the plurality of film layers 21 are described as being made of a thin and transparent material such as polyester or polyethylene, but this is one embodiment. Only the reflector 23 may be provided with various materials that can be totally reflected, and the film layer 21 may also be provided with various materials that may form a transparent and thin layer.

In the above-described embodiment, the plurality of film layers 21 are described as being bonded by heat-resistant compression, but this is only one embodiment, and the film layers 21 may be combined by various bonding methods such as using a transparent adhesive. Of course it can.

As described above, a lens is formed of an optical signal output unit for converting and outputting an image signal into an optical signal and a plurality of film layers in which a reflector having a predetermined reflection angle is incorporated so that the optical signal output from the optical signal output unit converges to the eyes of the user. By providing a wealth, there is provided a head mounted display device which can reduce eye fatigue while securing a field of view even when worn.

As described above, according to the present invention, the head-mounted display which is easy to wear, the structure is simple and the volume is small, which can reduce the management and manufacturing cost of the product, and also reduce the eye fatigue while ensuring the visibility even when wearing. An apparatus is provided.

Claims (7)

In the head mounted display device, An optical signal output unit connected to a predetermined image device to convert an image signal from the image device into an optical signal and output the optical signal; A lens having a plurality of transparent film layers disposed on the optical signal output path of the optical signal output unit and stacked on each other, and reflectors forming a predetermined reflection angle so that the optical signals interposed in the respective film layers are converged to the user's eyes. And a head mounted display device. The method of claim 1, And the reflector is arranged such that a reflection angle becomes smaller from the film layer adjacent to the eye toward the outermost film layer. The method of claim 1, And the optical signal output unit is a liquid crystal on silicon (LCOS). The method of claim 1, And the optical signal output unit is a grating light valve (GLV). The method of claim 1, The lens unit is a head-mounted display device characterized in that the perspective surface is provided with a planar lens bent up and down. The method of claim 1, It is coupled to the lens unit further comprises a pair of retaining holding portion to hold the user's ear, And the optical signal output unit is disposed in the latch holding unit. The method of claim 1, And the lens unit and the optical signal output unit are provided in pairs, respectively.