KR101866291B1 - Apparatus and method for measuring optical of stereoscopic display - Google Patents

Abstract

The present invention relates to an optical measuring apparatus and method of a 3D display capable of measuring a main viewing distance and a viewing angle of a 3D display.
The optical measuring method of a stereoscopic display according to an embodiment of the present invention includes disposing an optical measuring instrument equipped with a polarizing member so as to be horizontal with the upper end of a 3D display panel and measuring an angle of the optical measuring instrument in a predetermined angle unit from 0 to 90 Calculating a crosstalk of the 3D image with reference to the upper end; The optical measuring instrument equipped with the polarizing member is disposed so as to be horizontally aligned with the lower end of the 3D display panel and the angle of the optical measuring instrument is changed in a predetermined angle unit in the range of 0 ° to 90 ° so that the crosstalk of the 3D image based on the lower end Calculating; Calculating a crosstalk of the 3D image based on the upper end portion and a viewing angle of 10% or less of the crosstalk of the 3D image based on the lower end portion; And calculating a region where the viewing angle of the lower end portion and the viewing angle of the upper end portion overlapping with each other is 10% or less of the crosstalk of the 3D image.

Description

TECHNICAL FIELD [0001] The present invention relates to an optical measuring apparatus and method for a stereoscopic display,

The present invention relates to a stereoscopic (3D) display, and more particularly, to an optical measuring apparatus and method of a 3D display capable of measuring a main viewing distance and a viewing angle of a 3D display.

In recent years, in response to the practical use of 3D (3 Dimension) broadcasting, a 3D display device has attracted considerable attention as a next generation display device. Accordingly, it is increasingly necessary to evaluate the optical characteristics of the 3D display and inform the consumer of the superiority of the product.

However, since the 3D display is still in the stage of entering the market, and there is no objective, standardized optical characteristic evaluation system, the optical characteristic of the objective 3D display can not be provided to the consumer (viewer). As a result, despite the fact that 3D display is attracting much attention as a next generation display, activation of 3D broadcasting and spread of 3D display devices are delayed.

The 3D display device implements the 3D image using the binocular parallax of the viewer, and a shutter glass (SG) method and a film type patterned retarder (FPR) method have been developed.

In the double shutter glass system, a left eye image and a right eye image are sequentially displayed on a display panel according to time, and a left eye image and a right eye image sequentially displayed through a shutter glass are selectively transmitted to realize a 3D image.

The FPR system divides the display area of the left and right eye images of the display panel in a spatially divided manner, and selectively implements a 3D image by selectively transmitting the left eye image and the right eye image through polarizing film glasses.

Due to the optical characteristics of the FPR-type 3D display, when a viewer looks at the image within a certain viewing angle and viewing distance, it is recognized as a 3D image. Therefore, the viewer should be provided with the optical characteristic information of the FPR type 3D display.

However, the 3D viewing angle measurement method of the FPR type 3D display uses the method of measuring the contrast ratio (CR) of the existing 2D image.

The conventional method of measuring a viewing angle of a 3D display generates a gap between a 3D viewing angle and a region capable of viewing an actual 3D image. In addition, although the 3D viewing angle can be varied according to the total pitch of the FPR display device and the main viewing distance, the conventional technology always shows the same 3D viewing angle irrespective of the performance and viewing distance of the FPR display device.

As a result, even if the 3D viewing angle is measured, there is a difference between the viewing angle and the measured viewing angle of the 3D viewer. Accordingly, the viewer can view the 3D image in a region narrower than the viewing angle of the 3D image, and the viewer perceives that the viewing angle of the 3D image is narrow.

As described above, there is a problem that the optical characteristic measurement method of the 3D display according to the prior art can not accurately measure the optical characteristic of the 3D display.

In order to solve such a problem, it is necessary to clearly measure a viewing angle capable of viewing a 3D image and an optimal viewing distance (a main viewing distance) capable of recognizing a 3D image, and to transmit optical characteristic information of the 3D display to a viewer However, a method (system) for objectively measuring the optical characteristics of a 3D display has not been proposed so far. There is also a need for an optical measuring apparatus and method for a 3D display capable of clearly expressing a 3D viewing area that is expressed emotionally and providing it to viewers.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical measuring method (system) of a 3D display capable of measuring optical characteristics of a 3D display.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical measuring method of a 3D display capable of measuring a main viewing distance of a 3D display.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an optical measuring method of a 3D display capable of measuring a viewing angle of a 3D display.

An object of the present invention is to provide an optical measuring method of a 3D display capable of measuring viewing distances and viewing angles that viewers can normally view 3D images and expressing optical information of measured 3D displays in quantified values And to provide a method of manufacturing the same.

According to another aspect of the present invention, there is provided an optical measuring method for a stereoscopic display, comprising the steps of disposing a light measuring instrument equipped with a polarizing member so as to be horizontally aligned with an upper end of a 3D display panel, Calculating a crosstalk of the 3D image based on the upper end by changing an angle in a predetermined angle unit in a range; The optical measuring instrument equipped with the polarizing member is disposed so as to be horizontally aligned with the lower end of the 3D display panel and the angle of the optical measuring instrument is changed in a predetermined angle unit in the range of 0 ° to 90 ° so that the crosstalk of the 3D image based on the lower end Calculating; Calculating a crosstalk of the 3D image based on the upper end portion and a viewing angle of 10% or less of the crosstalk of the 3D image based on the lower end portion; And calculating a region where the viewing angle of the lower end portion and the viewing angle of the upper end portion overlapping each other is 10% or less of the crosstalk of the 3D image.

According to an aspect of the present invention, there is provided an optical measuring apparatus for a stereoscopic display, comprising: a test image supply unit for generating a 3D image test signal; A 3D display panel for displaying a left eye image and / or a right eye image based on the 3D image test signal supplied from the test image supply unit; A polarizing member installed to face the 3D display panel and selectively transmitting the left eye image and the right eye image displayed on the 3D display; A light meter for measuring a luminance of an image transmitted through the polarizing member; And an analyzer for generating optical characteristic information of the 3D image based on the luminance measurement result of the optical measuring instrument.

The present invention provides an optical measurement method (system) of a 3D display capable of measuring the optical characteristics of a 3D display.

The present invention provides an optical measurement method of a 3D display capable of measuring the main viewing distance of a 3D display.

The present invention provides an optical measuring method of a 3D display capable of measuring a viewing angle of a 3D display.

The present invention provides an optical measuring method of a 3D display that measures viewing distances and viewing angles that viewers can normally view 3D images, and can express optical information of measured 3D displays in quantified values.

The present invention has the effect of providing the consumer (viewer) with the optical characteristic information of the 3D display.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing an optical measuring apparatus of a stereoscopic display according to an embodiment of the present invention. Fig.
2 is a view showing an image pattern displayed on a display panel;
3 shows a plurality of measurement points set in a stereoscopic display according to an embodiment of the present invention;
4 to 8 are views showing a method of optical measurement of a stereoscopic display according to an embodiment of the present invention.

The present invention relates to a 3D display optical system capable of measuring a main viewing distance and a viewing angle in which a viewer can normally view a 3D image among various optical characteristics of a 3D display, numerically measuring the measured optical information, Measuring apparatus and method (system).

The optical measurement method of the 3D display according to the embodiment of the present invention can be applied to the following 3D image display methods.

1. Three-dimensional image display system composed of FPR type 3D display panel including film type pattern retarder capable of screen space division and linear polarizing film glasses or circular polarizing film glasses.

2. A stereoscopic image display system composed of a display that sequentially displays images according to time and a shutter glass (SG).

3. A stereoscopic image display system comprising a display including a time-division polarizing plate capable of switching screens and linear polarizing film glasses or circular polarizing film glasses.

All or some of the optical measuring method of the 3D display according to the embodiment of the present invention can be applied to other stereoscopic image display systems other than the stereoscopic image display systems.

Hereinafter, an optical measuring apparatus and method of a 3D display according to embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a view showing an optical measuring apparatus of a stereoscopic display according to an embodiment of the present invention.

1, an optical measuring apparatus for a stereoscopic display according to an exemplary embodiment of the present invention includes a test image supply unit 100, a 3D display panel 200, a polarization member 300, a light meter 400, 500).

The optical measuring apparatus of the stereoscopic display according to an embodiment of the present invention including the above-described configuration may measure the optical characteristics of the 3D display, and may provide the measured values to a viewer (user).

Here, the measuring item for measuring the optical characteristic of the 3D display may be a viewing angle and a main viewing distance for the viewer (user) to view the 3D image normally. At this time, the viewing angle and the main viewing distance when the crosstalk (C / T) of the 3D image is 10% or less are measured.

The crosstalk of the 3D image is caused by the interference between the left eye and the right eye occurring between the white pattern image and the black pattern image, and is important for measuring the image quality of the 3D image.

As an example, the crosstalk of the 3D image includes the case where the left eye image or the right eye image is a full screen white image and the crosstalk when the left eye image or the right eye image is a full screen black image. The crosstalk includes the case where the left eye image is black, the right eye image is white, the left eye image is white, and the right eye image is black.

The test image supply unit 100 generates a 3D image test signal for measuring the optical characteristics of the 3D display panel 200 and supplies the generated 3D image test signal to the 3D display panel 200.

The 3D display panel 200 displays a 3D image including a film type pattern retarder capable of space division.

Referring to FIG. 2, the 3D display panel 200 displays a 3D test image based on a 3D image test signal from the test image supply unit 100.

The 3D image test signal includes a left eye image L and a right eye image R, which are displayed on the 3D display panel 200 in a spatially or temporally divided manner. At this time, the left eye image and the right eye image are displayed as test images for measuring the optical characteristics of the 3D display panel 200 to be measured by the optical measuring instrument 400, that is, the viewing angle and the main viewing distance.

At this time, the 3D test image may be composed of the first pattern image to the fourth pattern image.

The first pattern image is a full white image in which the left eye image and the right eye image are displayed in white (L_white_R_white).

The second pattern image is an image in which the left eye image is black and the right eye image is white (L_black - R_white).

The third pattern image is an image in which the left eye image is white and the right eye image is black (L_white - R_black).

The fourth pattern image is a full black image in which the left eye image and the right eye image are displayed in black (L_black - R_black).

Here, the 3D test image may be configured using all of the first pattern image to the fourth pattern image, or a 3D test image may be formed using only a part of the first pattern image to the fourth pattern image. As an example, a 3D test image may be constructed using the second pattern image to the fourth pattern image.

The 3D display panel 200 may be installed in the cradle 210. At this time, the 3D display panel 200 can be vertically mounted with a predetermined height from the ground by the cradle 210 and rotatably mounted in a predetermined direction (horizontal direction and vertical direction).

The 3D display panel 200 may divide the left eye image L and / or the right eye image R, spatially or temporally, based on the 3D image test signal supplied from the test image supply unit 100.

The FPR-type 3D display panel 200 includes a plurality of unit pixels (not shown), a plurality of left eye retarders, and a plurality of right eye retarders.

Each of the plurality of unit pixels includes red, green, and blue sub-pixels that are formed for each region intersected by a plurality of horizontal lines and a plurality of vertical lines to display an image.

Here, a plurality of horizontal lines or a plurality of vertical lines are divided into a left eye image display line and a right eye image display line. As an example, an odd-numbered horizontal line may be set as a left-eye image display line, and an even-numbered horizontal line may be set as a right-eye image display line. However, the present invention is not limited to this, and the display lines of the left eye image and the right eye image may be set as opposed to the above case.

As another example, the odd-numbered vertical lines may be set as the left-eye image display line, and the even-numbered vertical lines may be set as the right-eye image display line. However, the present invention is not limited to this, and the display lines of the left eye image and the right eye image may be set as opposed to the above case.

Each of the plurality of left eye retarder patterns is formed to correspond to the left eye image display line and polarizes the left eye image L displayed on the left eye image display line.

Each of the plurality of right eye retarder patterns is formed so as to correspond to the right eye image display line and polarizes the right eye image R displayed on the right eye image display line.

The left eye retarder pattern and the right eye retarder pattern may have different optical axes, for example, a phase difference of 90 [deg.].

The panel driving unit displays the left eye image L and / or the right eye image R on the 3D display panel corresponding to the 3D image test signal supplied from the test image supply unit 100 based on the driving method of the 3D display panel.

In the FPR type 3D display panel 200, the panel driving unit supplies the left eye image L and the right eye image R corresponding to the 3D image test signal supplied from the test image supply unit 100 to the left eye image display line, And displays it on the video display line.

To this end, the panel driving unit may include an image converting unit (not shown) for converting the 3D image test signal into a left eye image L and a right eye image R. [

Meanwhile, when the 3D display panel 200 is a liquid crystal display (LCD) panel, the 3D display includes a backlight unit (not shown) that irradiates the 3D display panel with light.

The polarizing member 300 is installed to face the 3D display panel 200 to selectively transmit the left eye image L and the right eye image displayed on the 3D display 300 to be incident on the optical measuring instrument 400. For this purpose, the polarizing member 300 may be composed of left eye glasses and right eye glasses.

The left eye glasses transmit only the left eye image L out of the left eye image L and the right eye image R displayed temporally or sporadically in the 3D display panel 200.

When the 3D display panel 200 displays the left eye image L based on the FPR method, the left eye glasses are configured to include a polarizing filter that transmits only the left eye image L. [

The left eye glasses are installed so as to face the light measuring device 400 when measuring the optical characteristics of the left eye image L displayed on the 3D display panel 200. [ At this time, the left eyeglasses may be placed on the glasses holder (not shown) or the optical measuring instrument 400 so as to be adjacent to the optical measuring instrument 400. The left eye glasses may be separated from the optical measuring instrument 400 by at least 10 mm .

The right eye glasses transmit only the right eye image R displayed on the 3D display panel 200. [

When the 3D display panel 200 displays the right eye image R based on the FPR method, the right eye glasses include a polarizing filter which transmits only the right eye image R. [

The right eye glasses are installed so as to face the optical measuring instrument 400 when measuring the optical characteristics of the right eye image R displayed on the 3D display panel 200. [ At this time, the right eyeglasses may be placed on a separate spectacles holder (not shown) adjacent to the optical instrument 400 or an eyeglass holder (not shown) provided on the optical instrument 400, And is spaced apart from the optical measuring instrument 400 by at least 10 mm.

On the other hand, the polarizing member 300 may be mounted on an optical bench (not shown) so that the optical measuring instrument 400 has a predetermined rotation angle?. The rotation angle delta is measured in a clockwise direction when viewed from the optical meter 400 and the rotation angle of the 3D display panel 200 May be defined as an angle rotated about the horizontal axis of the display unit 200.

On the other hand, the polarizing member 300 may be formed in the form of a film or a plate so as to be movable on the front surface of the optical measuring instrument 400.

1, the optical measuring instrument 400 measures the luminance of the left eye image and the right eye image transmitted through the polarization member 300.

At this time, the optical measuring instrument 400 is spaced apart from the 3D display panel 200 by a predetermined measurement distance, and is installed so as to be perpendicular to the 3D display panel 200. The optical measuring instrument 400 may be installed to have a predetermined angle difference in the horizontal and / or vertical direction with respect to the 3D display panel 200.

Here, the distance between the optical measuring instrument 400 and the 3D display panel 200, that is, the measuring distance l _M , is 2 m or more or 3 L (where L is the 3D display screen height V, width H, One).

Referring to FIG. 3, the optical measuring instrument 400 is installed on the 3D display panel 200 so as to be located on the same line as each of the plurality of measurement points P1 to P9. At this time, the optical measuring instrument 400 may be installed at right angles to the measurement points P1 to P9 set on the 3D display panel 200. [ The optical measuring instrument 400 may be installed so as to have a predetermined angle difference in the horizontal and / or vertical directions with respect to each measurement point P1 to P9 set in the 3D display panel 200. [

The plurality of measurement points include the 0th to 9th measurement points P1 to P9.

The first measurement point P1 may be set to correspond to the central portion of the 3D display panel 200. [

The second measurement point P2 may be set to correspond to the upper end of the center portion of the 3D display panel 200. [

The third measurement point P3 may be set to correspond to the lower end of the center of the 3D display panel 200. [

The fourth measurement point P4 may be set to correspond to the left side of the center of the 3D display panel 200. [

The fifth measurement point P5 may be set to correspond to the center right side of the 3D display panel 200. [

The sixth measurement point P6 to the ninth measurement point P9 may be set to correspond to the respective corner portions of the 3D display panel 200. [

The optical measuring instrument 400 measures the luminance of the incident left eye image L and / or right eye image R.

The analyzer 500 analyzes the luminance of the left eye image and / or the right eye image measured by the optical measuring instrument 400 to generate optical characteristic information of the 3D display panel 200. Here, the optical characteristic information includes the crosstalk of the left eye image and the right eye image, that is, the crosstalk of the 3D image, the viewing angle, and the main viewing distance.

4, the analyzer 500 measures the crosstalk of the 3D image using the brightness information of the image provided from the optical measuring instrument 400. When the crosstalk is 10% or less, the viewing angle and the main viewing distance . According to the measured optical characteristic results, the information about the area where the 3D image can be viewed can be numerically expressed and provided to the user.

4 to 8 are views showing an optical measuring method of a stereoscopic display according to an embodiment of the present invention. Hereinafter, an optical measurement method of a stereoscopic display according to an embodiment of the present invention will be described with reference to FIGS.

As shown in FIG. 5, the binocular (left eye and right eye) crosstalk of an image displayed on the 3D display panel 200 can be measured. At this time, the 3D display panel 200 divides and displays the left eye image and the right eye image spatially.

At this time, the 3D display panel 200 may display either the left eye image or the right eye image as a full screen white image according to the first through fourth pattern images of the test image shown in FIG. 2 . In addition, the remaining one of the left eye image and the right eye image may be displayed as a full screen white image or a full screen black image.

In addition, the 3D display panel 200 may display the left eye image and the right eye image as a full screen black image. At this time, the full screen white image means a 100% white image, and the full screen black image means a 100% black image.

An area where the 3D image can be viewed can be represented by a 3D viewing angle in the 3D all-optical characteristic value. In order to measure the 3D viewing angle, the pattern images shown in FIG. 2 are displayed on the 3D display panel 200.

Then, a filter serving as 3D glasses, that is, polarizing glasses is mounted on the optical measuring instrument 400 so that the luminance value is minimized. Thereafter, the brightness is measured at intervals of 1 degree upward / downward with respect to the center of the 3D display panel 200, and a range in which the 3D C / T value becomes 10% or less is calculated. In addition, the brightness is measured at left and right intervals of 1 degree with reference to the center of the 3D display panel 200, and a range in which the 3D C / T value is 10% or less is calculated.

The optical measuring instrument 400 on which the polarizing member 300 is mounted may be disposed so as to be horizontally aligned with the upper end of the 3D display panel 200 and the optical measuring instrument 400 may be disposed at a predetermined angle unit For example, 1 degree unit) to calculate the crosstalk of the 3D image based on the upper end portion.

The optical measuring instrument 400 on which the polarizing member 300 is mounted is disposed so as to be horizontally aligned with the lower end of the 3D display panel 200 and the optical measuring instrument 400 is moved in the range of 0 to 90 degrees , And the crosstalk of the 3D image based on the lower end is calculated.

At this time, the crosstalk of the 3D image can be calculated using the measured results for the left eye image and the right eye image, respectively.

Specifically, a method for calculating the 3D crosstalk [%] based on the left eye will be described.

The 3D display panel 200 displays a full screen white image with the left eye image and a full screen black image with the right eye image. At this time, the optical meter 400 is aligned with the left eyeglasses of the polarization member 300, and the brightness of the screen center P1 of the 3D display panel 200 is measured. Then, the information of the measured luminance is recorded as the first luminance value, and the first luminance value is provided to the analysis unit 500.

Here, the first luminance value means the luminance value of the left eye reference according to the left eye white image and the right eye black image.

Then, the video signal displayed on the 3D display panel 200 is changed to display a full screen black image with the left eye image and a full screen white image with the right eye image. At this time, the optical meter 400 is aligned with the left eyeglasses of the polarization member 300, and the brightness of the screen center P1 of the 3D display panel 200 is measured. Then, the measured luminance information is recorded as a second luminance value, and the second luminance value is provided to the analysis unit 500. [

Here, the second luminance value means the luminance value of the left eye reference according to the left eye black image and the right eye white image.

Subsequently, the video signal displayed on the 3D display panel 200 is changed to display a full screen black image using the left eye image and the right eye image. At this time, the optical meter 400 is aligned with the left eyeglasses of the polarization member 300, and the brightness of the screen center P1 of the 3D display panel 200 is measured. Then, the measured luminance information is recorded as the third luminance value, and the third luminance value is provided to the analysis unit 500. [

Here, the third luminance value means a luminance value of the left eye reference according to the left eye black image and the right eye black image.

The analyzer 500 calculates the 3D crosstalk [%] based on the left eye using the first luminance value to the third luminance value provided from the optical measuring instrument 400.

Specifically, the first reference value obtained by subtracting the third luminance value from the second luminance value is divided into a second reference value obtained by subtracting the third luminance value from the first luminance value, 3D crosstalk [%] is calculated.

Accordingly, when a viewer views the 3D image by wearing the polarizing member 300, it is possible to measure how much the right eye image has caused interference with the left eye image transmitted through the left eye glasses.

Next, a method of calculating 3D crosstalk [%] based on the right eye will be described.

The 3D display panel 200 displays a full screen white image with the right eye image and a full screen black image with the left eye image. At this time, the optical measuring instrument 400 is aligned with the right eyeglasses of the polarizing member 300, and the brightness of the screen center P1 of the 3D display panel 200 is measured. Then, the measured brightness information is recorded as a fourth brightness value, and the fourth brightness value is provided to the analysis unit 500. [

Here, the fourth luminance value means the luminance value of the right eye reference according to the right eye white image and the left eye black image.

Then, the video signal displayed on the 3D display panel 200 is changed to display a full screen black image with the right eye image and a full screen white image with the left eye image. At this time, the optical measuring instrument 400 is aligned with the right eyeglasses of the polarizing member 300, and the brightness of the screen center P1 of the 3D display panel 200 is measured. Then, the measured luminance information is recorded as a fifth luminance value, and the fifth luminance value is provided to the analysis unit 500. [

Here, the fifth luminance value means the luminance value of the right eye reference according to the right eye black image and the left eye white image.

Subsequently, the video signal displayed on the 3D display panel 200 is changed to display a full screen black image with the right eye image and the left eye image. At this time, the optical measuring instrument 400 is aligned with the right eyeglasses of the polarizing member 300, and the brightness of the screen center P1 of the 3D display panel 200 is measured. Then, the measured luminance information is recorded as the sixth luminance value, and the sixth luminance value is provided to the analysis unit 500. [

Here, the sixth luminance value means the luminance value of the left eye reference according to the left eye black image and the right eye black image.

The analyzer 500 calculates the 3D crosstalk [%] based on the right eye using the fourth luminance value to the sixth luminance value provided from the optical measuring instrument 400. [

Specifically, the third reference value obtained by subtracting the sixth luminance value from the fifth luminance value is divided into a fourth reference value obtained by subtracting the sixth luminance value from the fourth luminance value, 3D crosstalk [%] is calculated.

Accordingly, when the viewer views the 3D image by wearing the polarizing member 300, it is possible to measure how much the left eye image has caused interference with the perceived right eye image transmitted through the right eye glasses.

The 3D crosstalk of the 3D display can be measured objectively and the measured 3D crosstalk information can be provided to the user through the embodiment of the present invention described above.

Here, the crosstalk of the 3D image measured on the basis of the left eye and the right eye is not only the first measurement point P1 of the 3D display panel 200 but also the remaining second measurement point P2 to the ninth measurement point P9 Can be measured in the same manner.

The measurement of the 3D crosstalk according to the embodiment of the present invention may be performed after the 3D display panel 200 and the polarizing member 300 are aged for a predetermined time.

Then, only when the 3D crosstalk is 10% or less, the viewing angle and the main viewing distance can be measured and information on the 3D viewing area, which can normally view the 3D image, can be obtained as shown in FIG.

Referring to FIG. 5, the brightness of an image is measured while changing the angle of the 3D display panel 200 in the upward / downward direction or the left / right direction at an interval of 1 degree with respect to the center P1 of the 3D display panel 200 so that the 3D crosstalk value is 10% (The range) of the angle? This is defined as a viewing angle at the center (first viewing angle).

Here, the horizontal angle [theta] H and the vertical angle [theta] V of the viewing angle can be freely changed within the range of 0 [deg.] To 90 [deg.].

As an example, the horizontal angle [theta] H can be changed in units of 1 [deg.] On the basis of 0 [deg.] And a horizontal viewing angle of 10% or less of the crosstalk of the 3D image displayed on the 3D display panel 200 can be measured.

Similarly, the vertical angle [theta] V can be changed in units of 1 [deg.] On the basis of 0 [deg.] And a vertical viewing angle of 10% or less of the crosstalk of the 3D image displayed on the 3D display panel 200 can be measured.

On the other hand, if the viewing angle is measured based on only the center P1 of the 3D display panel 200, an error may occur in the measured viewing angle and the actual viewing angle. As described below, the viewing angle is further measured based on the upper end of the center portion and the lower end of the central portion of the 3D display panel 200, thereby reducing the error of the viewing angle.

Referring to FIGS. 6 to 8, the range in which the 3D image can be normally viewed should include the viewing angle at the upper and lower ends of the 3D display panel 200. Therefore, similarly to the method of calculating the first viewing angle, a viewing angle with respect to the upper end of the center portion and the lower end of the center portion of the 3D display panel 200 is measured.

Specifically, the optical measuring instrument 400 is disposed so as to be horizontal to the upper end of the central portion of the 3D display panel 200, that is, the second measuring point P2 shown in FIG. 3, (range) in which the crosstalk of the 3D image displayed on the 3D display panel 200 is 10% or less can be calculated. This is defined as a viewing angle of the upper end (second viewing angle).

Next, the optical measuring instrument 400 is disposed so as to be horizontal with the lower end of the central portion of the 3D display panel 200, that is, the third measuring point P3 shown in FIG. 3, (range) in which the crosstalk of the 3D image displayed on the 3D display panel 200 is 10% or less can be calculated. This is defined as the viewing angle at the lower end (third viewing angle).

On the other hand, the left and right viewing angles of the upper and lower ends of the 3D display panel 200 can be measured by changing the vertical angle as well as the horizontal angle to the left and right in units of ± 1 ° with respect to 0 °. At this time, the crosstalk of the 3D image is also set to 10% or less.

As described above, when the viewer views the area where the viewing angle (first viewing angle) at the center portion, the viewing angle (second viewing angle) at the upper end, and the viewing angle (the third viewing angle) at the upper portion overlap with each other measured under the condition that the crosstalk of the 3D image is 10% It is defined as a 3D viewing area in which a 3D image can be normally viewed.

4, the area in which the upper viewing angle and the lower viewing angle are overlapped is the largest area among the 3D viewing areas. Then, the viewing distance at which the vertical viewing angle becomes maximum is obtained. Therefore, the distance D1 from the point at which the vertical viewing angle becomes maximum to the 3D display panel 200 is defined as the 3D main viewing distance. That is, the height of the upper and lower portions of the 3D image at which the 3D image can be viewed at the main viewing distance can be defined as a vertical viewing angle.

(Viewing angle and main viewing distance) capable of normally viewing the 3D image displayed on the 3D display panel 200 through the above-described optical measuring apparatus and method of the stereoscopic display, and can provide the measured viewing distance to the viewer .

In addition, a main viewing distance, a horizontal viewing angle, and a vertical viewing angle capable of viewing a 3D image with an optimal image quality are measured, and they are expressed as an approximate numerical value to provide a viewer with a 3D display device as a reference .

Meanwhile, although not shown in the drawing, the horizontal and vertical viewing angles may be changed by rotating the optical measuring instrument 400 at a predetermined angle. In addition, the horizontal and vertical viewing angles may be changed by rotating the 3D display panel 200 by a predetermined angle in the horizontal and vertical directions.

The measurement of the 3D crosstalk according to the viewing angle according to the embodiment of the present invention may be performed after the 3D display panel 200 and the polarizing member 300 are aged for a predetermined time.

In the above description, the viewing angle and the main viewing distance are measured on the basis of the first measuring point P1, the second measuring point P2 and the third measuring point P3, Respectively. However, this shows one embodiment among various embodiments of the present invention. As another embodiment of the present invention, as shown in Fig. 3, the viewing angle and the main viewing distance at the fourth measuring point P4 to the ninth measuring point P9 are further measured, Can be provided.

It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

100: Test image supply unit
200: 3D display panel
300: polarization member
400: Optical measuring instrument
500: Analytical Department

Claims (10)

The optical measuring instrument equipped with the polarizing member is disposed so as to be horizontally aligned with the upper end of the 3D display panel and the angle of the optical measuring instrument is changed in a predetermined angle unit in the range of 0 ° to 90 ° so that the crosstalk of the 3D image Calculating;
The optical measuring instrument equipped with the polarizing member is disposed so as to be horizontally aligned with the lower end of the 3D display panel and the angle of the optical measuring instrument is changed in a predetermined angle unit in the range of 0 ° to 90 ° so that the crosstalk of the 3D image based on the lower end Calculating;
Calculating a crosstalk of the 3D image based on the upper end portion and a viewing angle of 10% or less of the crosstalk of the 3D image based on the lower end portion; And
Calculating a region in which the viewing angle of the lower end portion and the viewing angle of the upper end portion overlapping each other is 10% or less of the crosstalk of the 3D image,
Wherein the optical measuring instrument is installed so as to be in line with each of a plurality of measurement points set on the 3D display panel to measure optical characteristics of an image displayed on the 3D display panel. The method according to claim 1,
Wherein a 3D viewing area is defined as an area where a cross-talk of the 3D image is 10% or less and a viewing angle of a lower end overlaps with a viewing angle of a top part. 3. The method of claim 2,
Wherein a region in which the upper viewing angle overlaps with the lower viewing angle is defined as a viewing angle. The method of claim 3,
Wherein the distance from the point at which the vertical viewing angle becomes maximum to the 3D display panel is defined as a main viewing distance of the 3D image. 5. The method of claim 4,
Wherein the range of the crosstalk of the 3D image with respect to the upper end portion and the crosstalk of the 3D image with respect to the lower end portion is 10% or less, the viewing angle and the main viewing distance are generated as numerical data, Way. The method according to claim 1,
The 3D display panel includes:
A first pattern image for displaying a left eye image and a right eye image in white, a second pattern image for displaying a left eye image in black, a right eye image in white, a left eye image in white, a right eye image in black, A pattern image, a left eye image, and a right eye image are displayed in black,
And at least three pattern images of the first pattern image to the fourth pattern image are displayed as a 3D test image. The method according to claim 1,
Wherein the plurality of measurement points include:
A first measurement point set to correspond to a central portion of the 3D display panel,
A second measurement point set to correspond to an upper end of a central portion of the 3D display panel,
A third measurement point set to correspond to the lower end of the central portion of the 3D display panel,
A fourth measurement point set to correspond to the left side of the center of the 3D display panel,
A fifth measuring point set to correspond to the right side of the center portion of the 3D display panel and
And a sixth to ninth measurement points set to correspond to the respective corner portions of the 3D display panel. 8. The method of claim 7,
The optical measuring instrument is provided with a predetermined angle difference in the horizontal or vertical direction with respect to the first to ninth measuring points set on the 3D display panel to measure optical characteristics of the image displayed on the 3D display panel Of the stereoscopic display. A test image supply unit for generating a 3D image test signal;
A 3D display panel for displaying a left eye image and / or a right eye image based on the 3D image test signal supplied from the test image supply unit;
A polarizing member installed to face the 3D display panel and selectively transmitting the left eye image and the right eye image displayed on the 3D display;
A light meter for measuring a luminance of an image transmitted through the polarizing member; And
And an analyzer for generating optical characteristic information of the 3D image based on the luminance measurement result of the optical measuring instrument,
Wherein the optical measuring instrument is installed so as to be in line with each of a plurality of measurement points set on the 3D display panel to measure optical characteristics of an image displayed on the 3D display panel. 10. The apparatus according to claim 9, wherein the analyzing unit, based on the optical characteristic information,
A crosstalk of the 3D image based on the upper end of the 3D display panel is 10% or less, a crosstalk of the 3D image based on the lower end of the 3D display panel is 10% or less, a viewing angle of the 3D image, Is generated as numerical data. ≪ RTI ID = 0.0 > 1 < / RTI >

Images