KR20020022519A - Head Set of Head Mounted Display - Google Patents

Abstract

PURPOSE: A headset of a head mounted display device is provided to make a viewer accurately observe the surrounding images by reducing the size of the surrounding images corresponding to a magnification ratio. CONSTITUTION: A headset of a head mounted display device comprises a video display unit(201), a lighting unit(202) providing a light to the video display unit, a pair of half reflectors(203) respectively reflecting the image displayed on the video display unit to the right and left eyes of a viewer(200), a pair of convex lenses(204) magnifying the images reflected onto the reflectors and picking up the images on the right and left eyes of the viewer, and a pickup distance adjusting unit(205) adjusting a pickup distance to pick up the surrounding images transmitting through the reflectors on the normal recognizable positions of the right and left eyes of the viewer. The pickup distance adjusting unit is a concave lens for reducing the size of the surrounding image corresponding to the magnification ratio of the convex lens.

Description

Headset of Head Mounted Display Device

The present invention relates to a head mounted display device, and more particularly, to a headset of a head mounted display device.

Recently, various personal electronic products have appeared due to the development of electronic and multimedia technologies. As personal electronic products, various products such as video and audio reproducing devices, computers, and entertainment devices are appearing. In particular, as a personal display device, a three-dimensional stereoscopic image display device that allows a user to enjoy a larger screen while wearing it on a head, and a head mounted display device (HMD) is introduced to provide a more realistic and realistic screen. You can enjoy it.

The HMD shows an image displayed by a display device such as a liquid crystal display (LCD) or a CRT to a user by using a precise optical mechanism. Since the HMD has an image screen positioned very close to the eye, very precise optics are required to focus on a very short distance and to prevent eye fatigue.

1 is a block diagram of a stereoscopic image HMD according to the prior art, which is a Republic of Korea Patent No. 10-0226870 filed July 29, 1999. Referring to this, the prior art will be described.

According to the related art, when a video signal in which left and right screens are sequentially recorded in each field of a recording medium is input, a sync separator 40 for separating a sync of the video signal is input, and the separated sync signal is input. A field discrimination unit 42 for discriminating and outputting an odd field and an even field, and a video signal processor 41 for processing the video signal output from the sync separation unit 40 to be displayed. ), An image display unit 46 comprising an LCD for displaying the video signal processed by the video signal processing unit 41, and two light sources 48 configured to face each other left and right around the image display unit 46. 48 ', the first driver 43 for driving the image display part 46, and the two light sources 48, 48' in accordance with each field signal output from the field discriminator 42. In order to match the synchronization signal of the field The second driver 44 (45) for driving the display to display the image displayed on the image display section 46 and the left side to prevent the images displayed on the image display section 46 from being reversed left and right. , The right and left signal inversion unit 55 to invert right. Reference numerals 49 and 49 'are semi-transparent mirrors, 47 and 47' are light absorbing plates for absorbing 50% of the light not transmitted through the semi-transparent mirror, and 50,50 'are the above-mentioned. It is an eyepiece lens that enlarges the image light transmitted from the transflective mirror and enters the observer's eyes "51, 51 '".

The HMD according to the related art configured as described above receives video signals sequentially recorded, that is, video signals in which left and right screens are sequentially recorded in each field, and separates the sync signals through the sync separator 40.

The separated sync signal is input to the field discriminator 42 to output signals corresponding to the odd field and the even field. On the other hand, the video signal output from the sink separating unit 40 is input to the first drive unit 43 driving the image display unit 46 to display an image. At this time, the left and right images are sequentially displayed. Accordingly, the field discrimination signal determined by the field discrimination unit 42 synchronized with the left and right video signals is input to the left and right second driving units 44 and 45, respectively, and displayed on the image display unit 46. Flashes in synchronization with.

In addition, assuming that the image display unit 46 is an image display unit 46 having left and right image inversion functions, the synchronization signal is converted to the left and right inversion signals of the image display unit 40 at the same time that the image display unit 46 blinks and the first image is displayed. It is input to the drive part 43. The input of the left and right inversion signals prevents two images, i.e., left and right images, from being inverted with each other. At this time, the left and right signal inversion unit 55 is provided on the EUD right in which the image display unit 46 does not have a left and right image inversion function as described above, and the inversion signal is input to the first driving unit 43 so that the left and right images are inverted. If it does, reverse the process.

Referring to the optical system for displaying an image signal, each image recorded in the odd field and even field is transflected with each illumination light as the left and right light sources 48 and 48 'are alternately lit on the image display unit 46. The left and right eyes 51 and 51 'of the observer are irradiated through the mirrors 49 and 49', so that they are alternately seen. At this time, 50% of the light is transmitted through the semi-transparent mirrors 49 and 49 ', and the remaining 50% is reflected and absorbed by the light absorbing plates 47 and 47'.

In this way, the video signal reproduced through the recording medium is irradiated to the left and right eyes through the left and right transflective mirrors and the left and right lenses in each driving unit, thereby enabling to enjoy a three-dimensional stereoscopic image.

When the HMD is worn by an observer, only the image displayed through the image display unit 46 is visible and the image of the surrounding environment is not visible, but the human sees a close or far distance according to his / her will. Can be. That is, by adjusting the thickness of the lens through the optic nerve to fit the distance you want to see, you can see near or far by focusing on the subject.

Therefore, as a part of solving the problem, a see-through method has been applied, which uses the above-described principle, so that a peripheral image other than the image display unit 46 can be viewed without taking off the headset of the HMD.

That is, the headset of the see-through HMD according to the prior art, as shown in Figure 2, the image display unit 101, a light source 102 for providing light to the image display unit 101, one image is displayed, the image It is composed of a semi-reflective mirror 103 for reflecting the image of the display unit 101 to the observer 100 side, and a convex lens 104 for enlarging the image reflected by the semi-reflective mirror 103 to image the observer 100. In this case, the two image sources having different incidence distances, that is, the artificial image and the natural surrounding image displayed on the image display unit 101 are captured by the eye of the observer 100 through the convex lens 104 which enlarges the image. Therefore, the surrounding image may not be correctly recognized or may be recognized in a reversed form.

2 illustrates an example of the prior art, and in the case of all other HMDs, a configuration for enlarging an image thereof, that is, a configuration corresponding to the convex lens 104 of FIG. When you see the problem that is not recognized correctly, or reversed in common occurs.

The see-through HMD according to the prior art has two images having different incidence distances, that is, a convex lens that enlarges an image of its own image and surrounding images. There is a problem that is not recognized correctly or in reversed form.

Accordingly, an object of the present invention is to provide a headset of an HMD that enables an observer to naturally observe an image generated by the HMD itself and a surrounding image without visual difference.

1 is a layout showing a configuration of a head mounted display device according to the prior art

2 is a layout diagram schematically illustrating a configuration of a headset of a see-through head mounted display device according to the related art.

3 is a layout showing the configuration of a preferred embodiment of a head mounted display device headset according to the present invention;

Explanation of symbols for main parts of the drawings

201: image display means 202: lighting means

203: semi-reflective mirror 204: convex lens

205: imaging distance adjusting means

The present invention provides a headset of a head mounted display device comprising an image display means and an image enlargement means for enlarging an image displayed on the image display means at a predetermined ratio to capture the image of the viewer. And an image capturing distance adjusting means for adjusting an image capturing distance of the peripheral image such that another image is captured at the normal image recognition point of the observer through the image enlargement means.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a layout showing the configuration of a preferred embodiment of a head mounted display device headset according to the present invention.

As shown in FIG. 3, the headset of the HMD according to an embodiment of the present invention has an image display means 201 displaying one image and an illumination providing light to the image display means 201 according to one control signal. Means 202, a pair of semi-reflective mirrors 203 for reflecting the image displayed on the image display means 201 in the direction of the right eye and the left eye of the observer 200, and the respective semi-reflective mirrors 203 A pair of convex lenses 204 for enlarging the image reflected by the right eye or the left eye of the observer 200, and the peripheral image passing through the semi-reflective mirror 203 is the image of the observer 200. And an image capturing distance adjusting means 205 for adjusting the image capturing distance so as to image the normal recognition distance between the right eye and the left eye.

In this case, the image display means 201 uses a reflective LCD, the lighting means 202 uses a high-brightness R / G / B LED, the imaging distance adjusting means 205 uses a concave lens, and the concave lens is the convex. The image is reduced at an image reduction ratio equal to that of the lens 204.

Hereinafter, the image display operation of the present invention configured as described above will be described in detail.

First, the image display means 201 displays an image signal processed by the HMD through a predetermined recording medium, and the lighting means 202 is driven in accordance with a control signal provided by the HMD to provide light to the image display means 201. To provide.

Accordingly, the image display means 201 enters the display image into the semi-reflective mirror 203 by reflecting the light provided from the illumination means 202.

Then, the semi-reflective mirror 203 reflects the image incident from the image display means 201 to the convex lens 204, and the convex lens 204 enlarges it at a predetermined magnification ratio to the right eye and the left side of the observer 200. Each image is taken by the eye.

Therefore, the observer 200 observes a two-dimensional or three-dimensional stereoscopic image provided by the HMD.

On the other hand, the imaging distance adjusting means 205 is a peripheral image other than the image display means 201 through the semi-reflective mirror 203 through the convex lens 204 of the right eye and left eye of the observer 200 Adjust the imaging distance so that the image is captured at the normal recognition point.

In other words, the peripheral image is reduced by a ratio enlarged by the convex lens 204 before being incident on the convex lens 204, so that the peripheral image is reduced as in the case of not wearing the HMD through the convex lens 204. To make it visible.

The present invention described above describes an embodiment of the headset of the HMD, and in the case of the headset of all the HMDs having the image display means 201 and the image augmentation means, that is, the convex lens 204, the observer accurately displays the surrounding image. Since it reveals a common problem that cannot be recognized, it is apparent that it is applicable to the see-through stereoscopic image display field by linking the imaging distance adjusting means such as the concave lens 205 of the present invention without complicated circuit configuration and modulation. .

The headset of the head mounted display device according to the present invention reduces the peripheral image by a ratio enlarged by the image enlargement means, so that the viewer can see the surrounding image accurately since natural recognition of the peripheral image can be performed in the same manner as when the HMD is not worn. There is an effect that can increase the user's convenience by eliminating the inconvenience.

Claims (4)

A headset of a head mounted display apparatus having an image display means and an image magnification means for enlarging an image displayed on the image display means at a predetermined ratio and capturing the image of the viewer. And an image capturing distance adjusting means for adjusting an image capturing distance of the peripheral image such that a peripheral image having a different incident distance from the image displayed on the image display means is captured at a normal image recognition point of the viewer through the image enlargement means. Headset display device headset. According to claim 1, And the imaging distance adjusting means is installed between the peripheral image and the image expanding means. According to claim 1, Headset display device headset, characterized in that the imaging distance adjusting means is a concave lens. The method of claim 3, wherein And said concave lens has a reduction ratio proportional to an image enlargement ratio of said image enlargement means.