KR100265496B1 - A hmd for three-dimensional pictures - Google Patents

Abstract

PURPOSE: A head mount display is to have a left and right image signal dividing function, thereby viewing a three dimensions image. CONSTITUTION: The head mount display includes a color reflective mirror(40a,40b) for a red and blue filter, and a red and blue filter for transmitting a visible rays of a red and blue band in an optical image which an optical path thereof is transformed by a reflective mirror. After a light reflected from a light source(1) is transformed into a light component of a light component of single polarized light by the first polarized filter(2), a left and right image signal are combined every color band to form an optical image on a liquid crystal display(3), and are filtered by the second polarized filter(2). The light are divided into a P wave and an S wave by two reflective mirrors having a dielectric coating film. Each of the P and S wave radiates onto the color reflective mirror.

Description

HMD for 3-D Imaging

The present invention relates to an optical system of a head mounted display device (HMD) for a three-dimensional image that allows viewing of a three-dimensional stereoscopic image without wearing a separate device, and more particularly, changes the path to the user's field of view after the image is displayed. The present invention relates to an HMD for a three-dimensional (3D) image that allows an enlarged three-dimensional (3D) image to be viewed by selectively separating left and right signals from the left and right by a color light filter in a device and condensing the left and right signals to a left and right field of view.

The Head Mounted Display (HMD), which is causing a new wind in the electronics industry these days, uses optical elements such as liquid crystal displays (LCDs) and polarizing filters to control image signals through lenses and mirrors. By expanding and condensing, the principle is very simple, and the optical system used therein can be implemented in a variety of functions by appropriately arranged in various ways.

The conventional HMD includes, as shown in FIG. 1, a back light 1 that emits light against a single eye; A liquid crystal display (3) for controlling the rotation of the polarization axis of the light component filtered by the first polarization filter (2) according to the input image signal; A second polarization filter (2 ') for filtering only polarization components in a specified direction among the output light of the liquid crystal display (3); A total reflection mirror (4) for totally reflecting the image displayed output light passing through the second polarization filter (2 ') to change a path; And an eyepiece red for condensing the totally reflected optical image; It was configured to include, and was provided with another configuration similar to the configuration of Figure 1 to configure the HMD for both eyes.

In the conventional HMD configured as described above, the light emitted from the light source 1 passes through the first polarization filter 2 so that only the polarization component in the direction of the polarization filter is output, and the output of the single polarized light is output. In the liquid crystal display 3, the polarization axis is passed through without rotation or rotation by a cell voltage applied or blocked according to the video signal to be displayed.

As described above, the light component in which the polarization direction is controlled and output according to whether the power is applied to each cell of the liquid crystal display 3 is output by the second polarization filter 2 '. However, optical components that are perpendicular to each other are not output so that an optical image corresponding to the applied image signal is formed.

The optical image formed as described above is totally reflected by the user's eye through the total reflection mirror 4 and is incident on the eyepiece lens 5, and the light components incident on the eyepiece lens 5 are focused on both eyes of the user. As a result, the image is recognized by the user as an enlarged virtual image.

However, the HMD configured and operated as described above has the same configuration for both eyes, in particular, an expensive LCD, so that the price of the device increases and the product competitiveness is lowered. There has been a problem, and in order to solve this problem, a simple structure HMD such as FIG. 2 using a single LCD has been proposed and filed by the applicant.

The HMD of the single LCD of Fig. 2 is a single light source 1 which is a backlight; A first polarization filter (2) for filtering out a polarization component inclined at 45 ° to a space with respect to a plane on the drawing among light incident from the light source (1); A single liquid crystal display 3 using the polarization component to form an optical image as in the prior art; A second polarization filter (2 ') for filtering incident light by the same polarization axis as the first polarization filter (2); A prism 10 having two orthogonal reflecting surfaces, each reflecting surface having a dielectric coating so that the reflected polarization components are different; Two total reflection mirrors 4 for redirecting each polarization component separated and reflected by the prism 10 to a user's field of view; And two eyepiece lenses 5 for condensing the changed light components to form an enlarged virtual image; It is configured to include.

In the HMD of the single LCD configured as described above, the polarization axis of the image-displayed optical image passing through the liquid crystal display 3 and the second polarization filter 2 'is virtual by the incident and reflected light in the prism 10. 45 ° inclined with respect to the plane and incident on each reflecting surface of the prism 10. The reflection and separation of two polarization components, S and P waves, which are perpendicular to and parallel to the virtual plane, respectively, form an enlarged virtual image by subsequent path change and condensation.

However, the HMD configured as described above to form an image also does not have a configuration for providing a stereoscopic image, as in the conventional HMD of FIG. 1, so that the user may separate the left and right signals when the provided image is a stereoscopic image. The user must wear glasses with colored cellophane or color lenses, which doubles the frustration and discomfort of the wearer, making it difficult for the user to watch for a long time. It was not possible to wear a separate color filter glasses for viewing the three-dimensional image.

Therefore, the present invention was created to solve the above problems, and provides an HMD for a three-dimensional image with a built-in left and right video signal separation function so that three-dimensional stereoscopic image can be viewed without wearing a separate device for left and right separation. Its purpose is to.

1 shows a configuration of a single eye among the configurations of a conventional HMD,

2 is a configuration diagram of an HMD using a single liquid crystal display,

3 to 5 is a block diagram of a preferred embodiment of the HMD for a three-dimensional image according to the present invention.

* Explanation of symbols for main parts of the drawings

1: Back-light 2, 2 ': polarization filter

3: Liquid Cristal Display 4: Total Reflection Mirror

5: Eye-piece Lens 6a: Red Light Filter

6b: blue light filter 10: prism

40: color reflection mirror 40a: color reflection mirror for red filter

40b: color reflection mirror for blue filter

HMD for the three-dimensional image according to the present invention for achieving the above object, in the head-mounted display device (HMD), with respect to the incident polarization component, two orthogonally polarized light components constituting the polarization component Prismatic to separate and reflect; Lighting means for emitting light; First polarized light filtering means formed such that a polarization axis that polarizes the emitted light is inclined at a predetermined angle with respect to an imaginary plane formed as an incident path of the emitted light and a reflection path by the prism; Image display means which is rubbed at the same inclination angle with the predetermined angle and selectively rotates the polarization axis of the polarized light by 90 ° according to an applied image signal; Second polarized light filtering means for transmitting the light component of a specific polarization axis among the transmitted light of the image display means and entering the prism; Two color reflecting means for differently selecting only a specific color band from each of the light components separated and reflected by the prism and rerouting each of them; And two eyepieces for condensing the rerouted light components, respectively; It is characterized by being configured to include.

In the HMD for the three-dimensional image configured as described above, light emitted from a single illumination means passes through the first polarization filtering means, thereby forming an incident path of the emitted light and a path of light reflected by the prism thereafter. Only the light component of the polarization axis inclined at a predetermined angle with respect to the imaginary plane is filtered, and the image display means for receiving the polarized light component of the filtered light and selectively rotating the polarization axis by 90 ° according to whether the corresponding cell is powered. Will pass. The light component passing through the image display means passes through the second polarization filtering means selectively according to whether the polarization axis is rotated, and then enters the prism, and the reflecting surface of the prism is configured to reflect the incident polarization component. The polarized light component orthogonal to the virtual plane and the polarized light component included in the virtual plane are separately reflected, and the separated and reflected light components are applied to the respective color reflecting means, and are different from each other by the respective color reflecting means. Only optical signals in the selected left and right specific color bands are respectively reflected and rerouted, and then focused by the two eyepieces, thereby allowing the user to view the left and right separated images.

Hereinafter, the configuration and operation of a preferred embodiment of the HMD for a three-dimensional image according to the present invention will be described in detail with reference to the accompanying drawings.

3 and 4 are schematic diagrams of a preferred embodiment of an HMD for a three-dimensional image according to the present invention. The configuration of FIG. 3 is a red and blue visible light band instead of the total reflection mirror 4 in the HMD configuration of FIG. Color reflecting mirrors 40a and 40b for reflecting red and blue filters; 4 includes a red and blue light filters 6a and 6b for transmitting only visible light of red and blue bands in the optical image routed by the total reflection mirror 4 in the HMD configuration of FIG. Is further included.

In the HMD for the three-dimensional image according to the present invention configured as shown in FIG. 3, first, light emitted from the light source 1 becomes a light component of a single polarized light inclined by 45 ° by the first polarization filter 2. Afterwards, the left and right image signals are synthesized by color bands in the liquid crystal display 3, and are polarized by the second polarization filter 2 ′, which is then reflected on two reflective surfaces on the prism 10. This is reflected by dividing the P wave and the S wave, respectively.

The light components of the P wave and the S wave which are separated from each reflecting surface through the prism 10 are separated from each other by SiO and MgF ₂ having different stacking and thicknesses so that the red and blue bands in the visible light are selected and reflected. Two color reflecting mirrors 40a and 40b each having a dielectric coating film are incident. The S-wave light component incident on the red filter color reflection mirror 40a reflects only the red band recorded as the left signal of the incident light, and the blue filter color reflection mirror 40b is incident P. Among the wave light components, only the blue band recorded as the right signal is reflected, separated into left and right signals, changed to the user's gaze, and then focused by the eyepiece lens 5 to focus on each of them. A three-dimensional stereoscopic image magnified more than twice is formed.

In another embodiment of the HMD for the 3D image according to the present invention configured as shown in FIG. 4, the left and right composite signals are separated into P waves and S waves by the prism 10 as in the embodiment of FIG. After the path is changed by the total reflection mirror 4, the red left image and the blue right image are selectively extracted by the red and blue light filters 6a and 6b, respectively, and condensed by the eyepiece lens 5, respectively. The user visually recognizes the three-dimensional stereoscopic image.

On the other hand, the color light filter (6a, 6b) is provided to be detachable by the user, if the provided image is not a three-dimensional image to remove the image to watch, if the provided image is a three-dimensional image, By installing at a location to implement a three-dimensional image can increase the usefulness of the device.

FIG. 5 is a configuration diagram of another embodiment of the HMD for a three-dimensional image according to the present invention. In the configuration of the conventional HMD optical system of FIG. 1, color reflection reflecting a red (or blue) band instead of the total reflection mirror 4 is shown. Mirror 40; It is configured to include, in the configuration for the other single view (not shown) is provided with a color reflecting mirror 40 reflecting a color band different from the reflected band, that is, a blue (or red) band, as described above As in the process, the left and right signals distinguished by the color band are separated to provide a 3D stereoscopic image to the user.

HMD for the three-dimensional image according to the present invention configured and operated as described above, by allowing the user to watch the three-dimensional stereoscopic image without wearing a separate device for left and right separation, viewing of the stereoscopic image is more convenient, It can be selectively adapted to two-dimensional and three-dimensional images, thereby increasing the usefulness of the device.

Claims (6)

A head mounted display device (HMD), comprising: a prism for separately reflecting two incident polarized light components constituting the polarization component with respect to an incident polarization component; Lighting means for emitting light; First polarized light filtering means formed such that a polarization axis that polarizes the emitted light is inclined at a predetermined angle with respect to an imaginary plane formed as an incident path of the emitted light and a reflection path by the prism; Image display means which is rubbed at the same inclination angle with the predetermined angle and selectively rotates the polarization axis of the polarized light by 90 ° according to an applied image signal; Second polarized light filtering means for transmitting a light component on a specific polarization side of the transmitted light of the image display means to be incident on the prism; Two color reflecting means for differently selecting only a specific color band from each of the light components separated and reflected by the prism and rerouting each of them; And two eyepieces for condensing the rerouted light components, respectively; HMD for a three-dimensional image comprising a. The HMD of claim 1, wherein the differently selected color bands are red and blue visible light bands. The method according to claim 1, wherein the two color reflecting means have a dielectric coating film of SiO and MgF ₂ in different lamination and thickness so that color bands in visible light are selected and reflected differently from each other. HMD for dimensional imaging. A head mounted display device (HMD), comprising: a prism for separately reflecting two incident polarized light components constituting the polarization component with respect to an incident polarization component; Lighting means for emitting light; First polarized light filtering means formed such that a polarization axis that polarizes the emitted light is inclined at a predetermined angle with respect to an imaginary plane formed as an incident path of the emitted light and a reflection path caused by the prism; Image display means which is rubbed at the same inclination angle with the predetermined angle and selectively rotates the polarization axis of the polarized light by 90 ° according to an applied image signal; Second polarized light filtering means for transmitting the light component of a specific polarization axis among the transmitted light of the image display means and entering the prism; Two total reflection means for rerouting each light component separated and reflected by the prism; Two color band filtering means for differently selecting and transmitting only a specific color band among the changed light components; And two eyepieces for condensing light of the transmitted color band, respectively; HMD for a three-dimensional image comprising a. 5. The HMD of claim 4, wherein the color band filtering means is detachably provided. A head mounted display device (HMD), comprising: two light sources for emitting light; Two first polarization filtering means for respectively polarizing the emitted light components; Two image display means for selectively rotating the polarization axis of the polarized light by 90 ° according to an applied video signal; Two second polarized light filtering means for transmitting light components of a specific polarization axis among the transmitted light of the image display means; First and second color reflecting means for changing a path by selecting only a specific color band from the polarized light components differently from each other; And two eyepieces for condensing the rerouted light components, respectively; HMD for a three-dimensional image comprising a.

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