KR20130123693A - An apparatus for processing autostereoscopic image - Google Patents

Abstract

A stereoscopic image processing apparatus without glasses is disclosed. A display panel includes subpixels which generate a display. A stereoscopic image filter is arranged on the front side of the display panel and controls the directivity of light which passes through or is outputted from the display panel. The stereoscopic image filter is tilted at 21.8 degrees with regard to the display panel.

Description

An autostereoscopic image processing apparatus

The present invention relates to an autostereoscopic 3D image processing apparatus, and more particularly, to an autostereoscopic 3D image processing apparatus that enables a 3D image to be viewed without wearing 3D glasses.

Recently, display technology for representing 3D images has been researched and utilized in various fields. In particular, an electronic device displaying a 3D image by using a technology of displaying a 3D image is attracting attention.

The technique of displaying a 3D image uses the principle of binocular parallax, in which an observer feels a stereoscopic feeling due to binocular disparity, and is classified into a shutter glass method, a glasses-free method, a full three-dimensional method, and the like.

1 is a structural diagram showing the structure of an autostereoscopic 3D display.

Referring to FIG. 1, the autostereoscopic 3D display 1 includes a display panel 10 and a 3D image filter 20. The stereoscopic filter 20 is disposed at a predetermined distance 15 from the display panel 10. The stereoscopic filter 20 may include a plurality of lenticulars or a plurality of barriers.

The user 11 views the stereoscopic image according to the number of viewpoints and the viewpoint intervals designed at the designated viewing distance 25. Here, the number of views means the number of positions where different images can be viewed on a multi-view display. The viewing distance 25, the number of viewpoints, and the viewing intervals depend on the design conditions of the stereoscopic image filter. The stereoscopic image filter 20 is designed as a multi-view in order to provide a natural stereoscopic image and a wider unit of view. Here, the natural stereoscopic image may mean an image having binocular parallax and monocular parallax. In designing the stereoscopic filter, the stereoscopic filter is attached to the display panel in an inclined form so as to match the horizontal and vertical resolution ratios of the image to be displayed.

2 is a diagram illustrating an embodiment of arrangement of a stereoscopic image filter.

Referring to FIG. 2, the autostereoscopic 3D display 2 includes a display panel 30 and a 3D image filter 50. The number of viewpoints of the display panel 30 is nine. That is, the display panel 30 displays nine viewpoint images. In addition, the stereoscopic filter 50 has an inclination angle 51 of 18.43 degrees. The inclination of the stereoscopic image filter may mean an angle 51 at which the edge of the barrier of the stereoscopic image filter is inclined with respect to the vertical axis 21 of the display panel, and the angle at which the edge or the vertical axis of the lens of the stereoscopic image filter is inclined (51). May mean.

3 is a view showing another embodiment of the arrangement of the stereoscopic image filter.

Referring to FIG. 3, the autostereoscopic 3D display 3 includes a display panel 60 and a 3D image filter 70. The number of viewpoints of the display panel 30 is nine. That is, the display panel 60 displays nine viewpoint images. In addition, the stereoscopic image filter 70 has an inclination angle 71 of 9.46 degrees.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide an autostereoscopic 3D image processing apparatus for displaying 3D images without generating moiré.

Another technical problem to be achieved by the present invention is to reduce ghosting, which is a cross-talk phenomenon subjectively perceived by a user, by using a cross-talk phenomenon generated according to the distribution of light intensity. The present invention provides an autostereoscopic 3D processing apparatus capable of improving the quality of 3D images.

In order to achieve the above technical problem, an autostereoscopic 3D processing apparatus according to the present invention includes a display panel including subpixels for generating a display, and light disposed on a front surface of the display panel and passing through the display panel. Or a stereoscopic image filter for controlling the direction of light emitted from the display panel, wherein the stereoscopic image filter is formed to be inclined by 21.8 degrees with respect to the display panel.

The stereoscopic image filter may be a lenticular lens substrate having a plurality of lenses. The lenticular lens substrate further includes a lenticular array for converting transmitted light into circularly polarized light, and the lenticular array may be activated or deactivated according to the type of an image displayed by the display panel.

The stereoscopic image filter may be a parallax barrier that alternately forms a transmission region and an opacity region. The opaque region of the stereoscopic filter may be activated or deactivated according to the type of the image on which the display panel is displayed.

The width of the pitch of the stereoscopic image filter may correspond to the horizontal width of 2.4 to 13 subpixels.

The width of the pitch of the stereoscopic image filter may be an integer multiple of the horizontal width of the subpixel or a non-integral multiple.

The image displayed by the display panel may include at least one of a 2D image, a stereo image, and a multiview image.

The display panel may be one of a plasma display panel (PDP), a liquid crystal display (LCD), and a light-emitting diode (LED) panel.

The autostereoscopic 3D image processing apparatus may further include a backlight disposed on a rear surface of the display panel and supplying light to the display panel.

The number of viewpoints of the multiview image displayed by the display panel may be between 12 and 65.

The viewpoint image may be disposed on the display panel in such a manner that the viewpoint image increases by 5 viewpoints in the horizontal direction and increases by 6 viewpoints in the vertical direction.

The autostereoscopic 3D image processing apparatus determines user location information related to the location of the user using a camera photographing an image of the user and the captured image, and displays the view of the viewpoint images based on the determined user location information. The control unit may further include a control unit for generating a control signal for controlling. The pitch of the stereoscopic image filter may move according to the control signal. In addition, a plurality of viewpoint images to be displayed on the display panel may be arranged according to the control signal.

According to the autostereoscopic 3D image processing apparatus according to the present invention, the 3D image is displayed without generating moiré, and the image quality of the 3D image is reduced since the ghosting, which is a cross-talk perceived by the user, is reduced. Can be improved.

1 is a structural diagram showing a structure of an autostereoscopic 3D display;
2 is a diagram illustrating an embodiment of arrangement of a stereoscopic image filter;
3 is a view showing another embodiment of arrangement of a stereoscopic image filter;
4 is a block diagram showing the configuration of a preferred embodiment of an autostereoscopic 3D image processing apparatus according to the present invention;
5 illustrates an example of moiré generated between a pattern of a display panel and a pattern of a stereoscopic image filter;
6 is a view for explaining a moiré generated by a pattern of a display panel and a pattern of a stereoscopic image filter;
7 is a diagram illustrating an arrangement of a display panel and a stereoscopic image filter;
FIG. 8 is a diagram illustrating cross-talk generated by a distribution of intensity of light emitted by a display panel and ghosting which is a cross-tuck perceived by a user;
9 is a view showing an embodiment of arrangement of a stereoscopic image filter according to the present invention;
10 is a view showing another embodiment of an arrangement of a stereoscopic image filter according to the present invention;
FIG. 11 is a view showing an image of a moiré generated when a stereoscopic image filter is disposed to have an inclination of 18.43 degrees; FIG.
FIG. 12 is a view showing an image of a moiré generated when a stereoscopic image filter is disposed to have a slope of 12.53 degrees; FIG.
FIG. 13 is a view showing an image of a moiré generated when a stereoscopic image filter is disposed to have a tilt of 14.93 degrees; FIG.
FIG. 14 is a view showing an image of a moiré generated when a stereoscopic image filter is arranged to have a tilt of 23.96 degrees; FIG.
FIG. 15 is a view showing an image of a moiré generated when a stereoscopic image filter is disposed to have a tilt of 21.8 degrees; FIG.
16 is a view showing an embodiment of the number of viewpoints between both eyes;
FIG. 17 is a view illustrating a cross-talk and ghosting phenomenon according to the embodiment of FIG. 16; FIG.
18 is a view showing another embodiment of the number of viewpoints between both eyes;
FIG. 19 is a view illustrating a cross-talk and ghosting phenomenon according to the embodiment of FIG. 18; FIG.
20 is a view showing another embodiment of arrangement of a stereoscopic image filter according to the present invention;
21 is a view showing the principle of the liquid crystal Lenticular,
22 illustrates a structure of a preferred embodiment of a lenticular lens substrate, and
FIG. 23 is a view illustrating a path of light adjusted according to a polarization pattern of light incident on the lenticular lens substrate of FIG. 12.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. At this time, the configuration and operation of the present invention shown in the drawings and described by it will be described as at least one embodiment, by which the technical spirit of the present invention and its core configuration and operation is not limited.

Although the terms used in the present invention have been selected in consideration of the functions of the present invention, it is possible to use general terms that are currently widely used, but this may vary depending on the intention or custom of a person skilled in the art or the emergence of new technology. Also, in certain cases, there may be a term selected arbitrarily by the applicant, in which case the meaning thereof will be described in detail in the description of the corresponding invention. Therefore, it is to be understood that the term used in the present invention should be defined based on the meaning of the term rather than the name of the term, and on the contents of the present invention throughout.

Figure 4 is a block diagram showing the configuration of a preferred embodiment of the autostereoscopic 3D image processing apparatus according to the present invention.

Referring to FIG. 4, the autostereoscopic 3D image processing apparatus 100 according to the present invention includes a receiver 101, a demultiplexer 130, a video decoder 134, an audio decoder 138, a buffer 140, and graphics. The processor 145 may include at least one of a display 150, a voice output unit 160, an input device 170, a storage unit 180, and a controller 190. According to an embodiment, the autostereoscopic 3D image processing apparatus 100 may include a camera 195.

The autostereoscopic 3D image processing apparatus 100 is, for example, an intelligent display device in which a computer support function is added to a broadcast reception function. Or, it can be equipped with a convenient interface such as Magic Remote Control. The autostereoscopic 3D image processing apparatus 100 is connected to the Internet and a computer with the support of a wired or wireless Internet function, and can also perform functions such as e-mail, web browsing, banking, or gaming. A standardized general-purpose OS can be used for these various functions. For example, on a general-purpose OS kernel, various applications can be freely added or removed, so that various user-friendly functions can be performed. More specifically, for example, the autostereoscopic 3D image processing apparatus 100 may be a network TV, an HBBTV, a smart TV, an open hybrid TV (OHTV), or the like, and in some cases, a mobile terminal, a smartphone, a PC, and a home appliance. Applicable to

The receiver 101 may receive broadcast data, video data, audio data, information data, and application data. The image data may be image data for displaying a 2D image and image data for displaying a 3D image. In addition, the 3D image may include at least one of a stereo image or a multiview image.

The 3D image may be a 3D video (3D video) including a plurality of 3D image frames. In some embodiments, the 3D image frame may include a 2D image frame having a specific width and width and a depth image corresponding thereto. Here, the 2D image frame includes color image data. The color image data includes pixel values. Hereinafter, the two-dimensional image frame is called a color image. The depth image may be represented by a gray level and may have the same resolution as the pixel resolution of the 2D image frame. The pixels included in the depth image may each have a depth value corresponding one-to-one with the pixels included in the 2D image frame. The depth value may be displayed in gray level. For example, the gray level may have a value of 0 to 255.

The receiver 101 may include a tuner 110, a demodulator 120, a mobile communication unit 115, a network interface 125, a voice detector 133, and an external signal receiver 135. The tuner unit 110 may receive a stream signal including data through a broadcasting network, and the demodulator 120 demodulates the received stream signal. The mobile communication unit 115 may receive data through a mobile communication network such as a 2G communication network, a 3G communication network, and a 4G communication network. In addition, the network interface 125 may transmit and receive data through a network, the external signal receiver 125 may receive an application and content from an external device, and may receive an image frame from the camera 195. The image frame may be an image frame captured by the user.

The demultiplexer 130 demultiplexes the stream signal output from the demodulator 120 into a video signal and an audio signal. In addition, the demultiplexer 130 may receive image data, audio data, broadcast data, information data, and application data from the mobile communication unit 115, the network interface unit 125, and the external signal receiving unit 135.

The video decoder 134 decodes the video signal demultiplexed by the demultiplexer 130 and stores the decoded video signal in the buffer 140.

The graphics processor 145 controls the display 150 to display image data stored in the buffer 140. The graphic processor 145 may arrange and synthesize the viewpoint images included in the image data, and output the synthesized image to the display 150. The graphic processor 145 may arrange viewpoint images under the control of the controller 190. That is, the graphic processor 145 may arrange the viewpoint images according to a control signal for adjusting the arrangement of the viewpoint images generated by the controller 190.

The audio decoder 138 decodes the audio signal demultiplexed by the demultiplexer 130, and outputs the decoded audio signal to the voice output unit 160.

The display 150 displays the image 152. The image 152 may be an image obtained by synthesizing the viewpoint images included in the stereo image. The display 150 may include a display panel and a stereoscopic filter. The display panel may include a plurality of subpixels and display at least one viewpoint image. The subpixel may be referred to as a unit pixel, and means a minimum pixel unit capable of representing red (R), green (G), and blue (B), respectively, in the display panel.

The stereoscopic filter controls the direction of light emitted from the display panel so that the viewpoint image displayed on the display panel can be viewed at different positions. The slope of the stereoscopic image filter may have a value between 20 degrees and 23 degrees. More preferably, the inclination of the stereoscopic filter may be 21.8 degrees.

In addition, the display 150 may operate in connection with the controller 190. The display 150 may display a graphical user interface (GUI) 153 that provides an easy-to-use interface between a user of the stereoscopic image processing apparatus and an application running on the operating system or the operating system.

The voice output unit 160 may receive voice data from the audio decoder 138 and the controller 190 and output a sound 161 in which the received voice data is reproduced.

The input device 170 may be a touch screen disposed on or in front of the display 150, and may be a communication unit that receives a signal from the remote controller 111. The input device 170 may receive a remote control transmission signal from the remote control 111.

According to some embodiments, the receiver 101 may be a communicator that receives a signal from the remote controller 111. That is, the external signal receiver 135 may receive a remote control transmission signal from the remote controller 111.

The storage unit 180 generally provides a place for storing program codes and data used by the autostereoscopic 3D image processing apparatus 100. The program code may be a program code of an application received by the receiver 101 and a program code of an application stored when the autostereoscopic 3D image processing apparatus 100 is manufactured. Applications can also be written in programming languages such as HTML, XML, HTML5, CSS, CSS3, JavaScript, Java, C, C ++, Visual C ++, and C #.

The storage unit 180 may store a face image of the user captured by the camera 195. The controller 190 may detect a user from an image captured by the camera 195 by using a face image of the user stored in the storage 180.

The storage unit 180 may be implemented as a read only memory (ROM), a random access memory (RAM), a hard disk drive, or the like. The program code and data may reside in a removable storage medium, and may be loaded or installed onto the autostereoscopic image processing apparatus 100 as needed. Removable storage media may include CD-ROM, PC-CARD, memory cards, floppy disks, magnetic tape, and network components.

The controller 190 executes a command and performs an operation associated with the autostereoscopic 3D image processing apparatus 100. For example, the controller 190 may control input and output between the components of the autostereoscopic 3D processing apparatus 100 and reception and processing of data by using a command retrieved from the storage unit 180.

The controller 190 executes program code along with an operating system and generates and uses data. The operating system is generally known and will not be described in more detail. By way of example, the operating system may be a Window based OS, Unix, Linux, Palm OS, DOS, Android, Macintosh, and the like. The operating system, other computer code, and data may be present in the storage unit 180 that operates in conjunction with the control unit 190.

The controller 190 may be implemented on a single chip, multiple chips, or multiple electrical components. For example, various architectures may be used for the controller 190, including dedicated or embedded processors, single purpose processors, controllers, ASICs, and the like.

The controller 190 may recognize the user action and control the autostereoscopic 3D processing apparatus 100 based on the recognized user action. The user action may include selecting a physical button of a stereoscopic image processing apparatus or a remote control, performing a predetermined gesture on the touch screen display surface, or selecting a soft button, and performing a predetermined gesture recognized from an image captured by the imaging device 195. And the execution of a predetermined utterance recognized by speech recognition. The gesture may include a touch gesture and a space gesture.

The input device 170 receives the gesture 171, and the controller 190 executes commands for performing operations associated with the gesture 171. In addition, the storage unit 180 may include a gesture operating program 181 which may be part of an operating system or a separate application. Gesture operator 181 generally recognizes the occurrence of gesture 171 and in turn responds to gesture 171 and / or gesture 171 to inform one or more software agents of what action (s) should be taken. Contains the command of.

The controller 190 may perform a function of head trekking. The controller 190 detects a plurality of users in the image output from the camera 195 and obtains user location information indicating the locations of the detected plurality of users. The controller 190 may determine the location of the user by tracking the location of various eyes. The user location information may include user location information indicating the location of the first user and user location information indicating the location of the second user. In addition, the user location information may include eye location information indicating the location of the user's eyes.

In some embodiments, the controller 190 may detect the eyes of the user in the image output from the camera 195, and determine eye positions to generate eye position information indicating the position of the eyes. The controller 190 may detect the eyes of the user by using a face image of the user which is previously captured and stored in the storage 180.

In some embodiments, the controller 190 controls the display 150 to adjust the optical path of the view image displayed by the display 150 by using the acquired user position information, so that the view image is assigned to eye positions of a plurality of users. It can be made to enter the spot. In some embodiments, the controller 190 may control the position of the barrier image or the lens of the stereoscopic image filter included in the display 150 to adjust the viewpoint image to be delivered to the sweet spot. The controller 190 may determine the arrangement of the barrier or the lens by using the acquired user position information, and adjust the position of the barrier or the lens of the filter according to the determined arrangement.

In some embodiments, the controller 190 may determine the arrangement of the plurality of viewpoint images by using the acquired user location information, and arrange and synthesize the viewpoint images according to the determined arrangement.

In some embodiments, the controller 190 may generate a control signal for adjusting the arrangement of the plurality of viewpoint images using the obtained user location information, and may output the generated control signal to the graphic processor 145.

In some embodiments, the controller 190 determines an interval between the display panel included in the display 150 and the stereoscopic image filter by using the acquired user location information, and adjusts an interval between the display panel and the stereoscopic image filter according to the determined interval. I can regulate it.

In some embodiments, the controller 190 may determine the interval between the 3D image pixel period and the display panel included in the display 150 and the 3D image filter using the obtained user location information. The controller 190 arranges and views viewpoint images according to the determined stereoscopic pixel period, and controls the display 150 to display the synthesized viewpoint images. In addition, the controller 190 may adjust the distance between the display panel and the filter according to the determined interval.

In some embodiments, the controller 190 may determine the interval between the 3D image pixel period and the display panel included in the display 150 and the 3D image filter using the obtained user location information. The controller 190 may generate a control signal for adjusting the arrangement of the plurality of viewpoint images according to the determined stereoscopic pixel period, and output the generated control signal to the graphic processor 145.

In some embodiments, the controller 190 may determine the layout of the viewpoint image based on at least one of user location information, a slope of the stereoscopic image filter, a period of the stereoscopic image filter, and the number of viewpoints. The viewpoint image to be displayed by the subpixel is determined according to the arrangement of the viewpoint image determined. That is, the controller 190 may determine a viewpoint image to be displayed by the subpixel based on at least one of user position information, a slope of the stereoscopic image filter, a period of the stereoscopic image filter, and the number of viewpoints. The graphic processor 145 rearranges unit pixels with respect to the viewpoint image according to the arrangement of the viewpoint image determined by the controller 190.

In some embodiments, the 3D image processing apparatus 100 applies a period of the 3D image filter differently according to the number of viewpoints used. Accordingly, the present invention can design and use a stereoscopic image filter having a period of an optimal stereoscopic image filter according to the number of viewpoints used, and display a stereoscopic image without moiré. The period of the stereoscopic image filter may be an integer multiple of unit pixels and may be a non-integer multiple.

Preferably, the number of viewpoints used in the 3D image processing apparatus 100 has a value between at least 12 and 65. In terms of the number of subpixels, it is between 2.4 and 13 pixels. The slope of 21.8 degrees requires the use of at least 12 viewpoints, so that the observation position is not a pseudoscopic image space caused by the intrusion of images of different unit views. In addition, in the case of using the number of view points of 65 or less, it is possible to prevent the resolution of the image provided to the user at an appropriate viewing distance, and the pitch width at which the stereoscopic image filter is unknown may be considered.

FIG. 5 is a diagram illustrating an example of moiré generated between a pattern of a display panel and a pattern of a stereoscopic image filter, and FIG. 6 is a view for explaining a moiré generated by a pattern of a display panel and a pattern of a stereoscopic image filter. 7 is a diagram illustrating an arrangement of a display panel and a stereoscopic image filter.

5 to 7, moiré may occur as shown in FIG. 5 due to interference between the unit pixel pattern of the display panel 710 according to the inclination angle of the stereoscopic image filter 720 and the period of the stereoscopic image filter 720. Can be. Moirre refers to a new stripe shape 511 that occurs when two regular patterns 610 and 710 overlap. In addition, the period of the stereoscopic image filter means the width of the pitch.

FIG. 8 is a diagram illustrating a cross-talk generated at a neighboring view point as a distribution of light intensity emitted by a display panel and ghosting which is a cross-tuck perceived by a user in connection with the cross-talk.

Referring to FIG. 8, the X-axis 810 denotes a viewpoint position (1 viewpoint, 2 viewpoints, 3 viewpoints, 4 viewpoints, 5 viewpoints, 6 viewpoints, and 7 viewpoints) which are positions for viewing each viewpoint image. Axis 820 represents the intensity of light. Graphs 833, 834, 835, 836, 837 show the intensity distribution of the viewpoint image, respectively. For example, the graph 833 illustrates the intensity distribution of the third viewpoint image, and the graph 834 illustrates the intensity distribution of the fourth viewpoint image. These intensity distributions involve nearby viewpoint locations and generate cross chins.

In addition, when displaying an image of a predetermined depth or more from the user's point of view, the nearby viewpoint image may be invaded and ghosting may occur. The left eye 801 of the user at the viewpoint position (four views) is ghosted from an image provided by the third viewpoint image 833 and the fifth viewpoint image 835 that are adjacent images of the fourth viewpoint image 834. ). In addition, at the viewpoint location (6 views), the right eye 802 of the user is ghosted from an image provided by the involvement of the fifth viewpoint image 835 and the seventh viewpoint image 837, which are neighboring images of the sixth viewpoint image 836. 841). Cross-talk and ghosting mean that an unintended point of view image is seen at a different point of view on an autostereoscopic display, but cross chin is an item measured by a measuring device. This item is recognized by subjective judgment.

9 is a view showing an embodiment of the structure of a display according to the present invention.

Referring to FIG. 9, the display 150 includes a display panel 910 and a stereoscopic image filter 950.

The display panel 910 alternately arranges green, blue, and red subpixels in a row direction. Here, the row direction refers to a direction from the subpixel 911 to the subpixel 914 through the subpixel 912 and the subpixel 913. In addition, since the green, blue, and red subpixels are alternately arranged in the row direction, the green (G) subpixel is positioned in the subpixel 911 that is the subpixel of the first row and the first column. The subpixel 912 becomes a blue (B) subpixel, and the subpixel 913, which is a subpixel of one row and three columns, becomes a red (R) subpixel. Also, the subpixel 914 which is the subpixel of the first row and the fourth column becomes the green subpixel.

The sub-pixels having the same color are arranged in the display panel 910 in the column direction. The column direction refers to a direction from the subpixel 911 to the subpixel 931 through the subpixel 921. Further, since the subpixels of the same color are arranged in the column direction, the subpixel 921 which is the subpixel of the second row and the first column becomes the green subpixel which is the same subpixel as the subpixel 911. The subpixel 922, which is a subpixel of two rows and two columns, becomes a blue subpixel that is the same subpixel as the subpixel 912. Subpixel 923, which is a subpixel of two rows and three columns, becomes a red subpixel that is the same subpixel as subpixel 913, and a subpixel 924, which is a subpixel of two rows and four columns, is the same as the subpixel 914. It becomes a green sub pixel which is a sub pixel.

The number displayed on the subpixel indicates the viewpoint image to be displayed by the subpixel. For example, the subpixel 911 displays the eleventh viewpoint image, the subpixel 912 displays the sixteenth viewpoint image, and the subpixel 923 displays the 27th viewpoint image.

In the embodiment of FIG. 9, when the number of viewpoints is 45, the unit pixel rearrangement is performed on the 45 viewpoint images in a 5 viewpoint period in a horizontal direction and a 6 viewpoint period in a vertical direction.

The pixel value to be displayed in the view image is determined according to the position of the subpixel. For example, since the subpixels 911 are located in one row and one column, the pixel values corresponding to one row and one column of the eleventh viewpoint image are displayed. In addition, since the subpixels 922 are positioned in 2 rows and 2 columns, the pixel values corresponding to 2 rows and 2 columns of the 22nd viewpoint image are displayed.

In addition, the pixel value to be displayed in the view image is determined according to the type of the subpixel. For example, since the type of the subpixel 911 is a green subpixel, a green pixel value is displayed among pixel values corresponding to one row and one column of the eleventh viewpoint image. In addition, since the type of the subpixel 922 is a blue subpixel, a blue pixel value is displayed among pixel values corresponding to 2 rows and 2 columns of the 22nd viewpoint image.

The stereoscopic filter 950 is disposed in front of the display panel 910, and the display panel 910 emits light so that two or more viewpoint images displayed on the display panel 910 can be viewed at different positions. Control directionality Here, controlling the directionality of the light may mean blocking the optical path of some of the viewpoint images, and may mean refracting the viewpoint images.

When the display panel 910 displays a viewpoint image included in a multiview image through each subpixel, the user views the displayed viewpoint images through the stereoscopic filter 950, and the left and right eyes of the user are respectively displayed on the display panel. One of the viewpoint images provided at 910 may be viewed independently, so that the user may feel a 3D effect.

The stereoscopic filter 950 may be one of a liquid crystal parallax barrier and a liquid lenticular filter.

In some embodiments, the 3D image filter 950 may include transmission regions and opacity regions arranged at regular intervals. The light emitted from the display panel 910 is transmitted through the transmission area to reach the user's right eye or left eye. When the stereoscopic image filter 950 is a liquid crystal parallax barrier, the opaque region may be configured as a barrier, and the pair of transmissive and opaque regions may be referred to as pitch. The transmission region and the non-transmission region of the stereoscopic image filter 950 may be moved under the control of the controller 190. In this case, the 3D image filter 950 may be fixed to the display 150. In addition, the stereoscopic image filter 950 has a plurality of switch modes indicating the position of the opaque region. That is, the stereoscopic image filter 950 may have a switch mode indicating the position of the opaque region for each position of the opaque region.

In addition, the opaque region of the stereoscopic filter 950 may be activated and deactivated. When the opaque region is activated, the opaque region blocks the transmission of light incident thereon. When the opaque region is inactivated, the opaque region transmits light incident thereto.

In some embodiments, when the stereoscopic filter 950 is a liquid crystal lenticular filter, the transmission region and the non-transmission region may be distinguished by a lens, and one lens may be referred to as a pitch. The lens of the stereoscopic image filter 950 may be moved under the control of the controller 190. In this case, the 3D image filter 950 may be fixed to the display 150. In addition, the stereoscopic image filter 950 has a plurality of switch modes indicating the position of the lens. That is, the stereoscopic image filter 950 may have a switch mode indicating the position of the lens for each lens position.

The slope of the stereoscopic filter 950 may have a value between 20 degrees and 23 degrees. More preferably, the inclination of the stereoscopic filter 950 may be 21.8 degrees. The inclination of 21.8 degrees of the stereoscopic filter 950 is not recognized as moiré due to the characteristic of the angle in relation to the pattern of the display panel 910. However, since the width of the unit pixel varies according to the size and resolution of each display panel used, the moire reduction condition should be optimized to the period of the stereoscopic image filter according to the display conditions.

In the embodiment of FIG. 9, the period of the stereoscopic image filter 950 is nine times the unit pixel. That is, the period of the stereoscopic image filter 950 is 9 times the width of the unit pixel. In addition, the stereoscopic filter 950 has an inclination of 21.8 degrees, and the inclination corresponds to six subpixels in the horizontal direction and five pixel periods in the vertical direction in the embodiment of FIG. 9.

10 is a view showing another embodiment of the arrangement of the three-dimensional image filter according to the present invention.

Referring to FIG. 10, the display 150 includes a display panel 1010 and a stereoscopic image filter 1050.

The display panel 1010 alternately arranges green, blue, and red subpixels in a row direction. In this case, the row direction refers to a direction from the subpixel 1011 to the subpixel 1014 through the subpixel 1012 and the subpixel 1013. In addition, since the green, blue, and red subpixels are alternately arranged in the row direction, the green (G) subpixel is positioned in the subpixel 1011 which is the subpixel of the first row and the first column. The subpixel 1012 becomes a blue (B) subpixel, and the subpixel 1013, which is a subpixel of one row and three columns, becomes a red (R) subpixel. In addition, the subpixel 1014, which is a subpixel of one row and four columns, becomes a green subpixel again.

Sub-pixels of the same color are arranged in the display panel 1010 in the column direction. In this case, the column direction refers to a direction from the subpixel 1011 to the subpixel 1031 through the subpixel 1021. Further, since the subpixels of the same color are arranged in the column direction, the subpixel 1021 which is the subpixel of the second row and the first column becomes the green subpixel which is the same subpixel as the subpixel 1011. Also, the subpixel 1022, which is a subpixel of two rows and two columns, becomes a blue subpixel that is the same subpixel as the subpixel 1012. The subpixel 1023, which is a subpixel of 2 rows and 3 columns, becomes a red subpixel, which is the same subpixel as the subpixel 1013, and the subpixel 1024, which is a subpixel of 2 rows and 4 columns, is the same as the subpixel 1014. It becomes a green sub pixel which is a sub pixel.

In the embodiment of FIG. 10, when the number of views is 23, unit pixel rearrangement is performed according to a period of 5 viewpoints in a horizontal direction and a period of 6 viewpoints in a vertical direction. Indicates the view image to be displayed. For example, the subpixel 1011 displays the third viewpoint image, the subpixel 1012 displays the eighth viewpoint image, and the subpixel 1023 displays the nineteenth viewpoint image.

The pixel value to be displayed in the view image is determined according to the position of the subpixel. For example, since the subpixels 1011 are positioned in one row and one column, the subpixels 1011 display pixel values corresponding to one row and one column of the third view image. In addition, since the subpixels 1022 are positioned in two rows and two columns, the pixel values corresponding to the two rows and two columns of the fourteenth viewpoint image are displayed.

In addition, the pixel value to be displayed in the view image is determined according to the type of the subpixel. For example, since the type of the subpixel 1011 is a green subpixel, the green pixel value is displayed among pixel values corresponding to one row and one column of the third view image. In addition, since the type of the subpixel 1022 is a blue subpixel, a blue pixel value is displayed among pixel values corresponding to 2 rows and 2 columns of the 14th viewpoint image.

The stereoscopic filter 1050 is disposed in front of the display panel 1010, and the display panel 1010 may be used to display two or more viewpoint images displayed on the display panel 1010 at different positions. Control directionality

When the display panel 1010 displays a viewpoint image included in a multiview image through each sub-pixel, the user views the displayed viewpoint images through the stereoscopic filter 320, and the left and right eyes of the user are respectively displayed on the display panel. One of the viewpoint images provided at 1010 may be viewed independently, so that the user may feel a 3D effect.

The stereoscopic filter 1050 may be one of a liquid crystal parallax barrier and a liquid lenticular filter.

In some embodiments, the stereoscopic image filter 1050 may include transmission regions and opacity regions arranged at regular intervals. Light emitted from the display panel 1010 is transmitted through the transmission area to reach the right eye or the left eye of the user. When the stereoscopic image filter 1050 is a liquid crystal parallax barrier, the opaque region may be configured as a barrier, and the pair of transmissive and opaque regions may be referred to as pitch. The transmission region and the non-transmission region of the stereoscopic image filter 1050 may be moved under the control of the controller 190. In this case, the 3D image filter 1050 may be fixed to the display 150. In addition, the stereoscopic image filter 1050 has a plurality of switch modes indicating the position of the opaque region. That is, the stereoscopic image filter 1050 may have a switch mode indicating the position of the opaque region for each position of the opaque region.

In some embodiments, when the stereoscopic image filter 1050 is a liquid crystal lenticular filter, the transmission region and the non-transmission region may be distinguished by a lens, and one lens may be referred to as a pitch. The lens of the stereoscopic filter 1050 may be moved under the control of the controller 190. In this case, the 3D image filter 1050 may be fixed to the display 150. In addition, the stereoscopic image filter 1050 has a plurality of switch modes indicating the position of the lens. That is, the stereoscopic filter 1050 may have a switch mode indicating the position of the lens for each lens position.

In the embodiment of FIG. 10, the period of the stereoscopic image filter 1050 is a non-integer multiple of a unit pixel. The period of the stereoscopic image filter 1050 is 4.6 times the unit pixel. That is, the period of the stereoscopic image filter 1050 is 4.6 times the width of the unit pixel. In addition, the stereoscopic filter 1050 has an inclination of 21.8 degrees, and the inclination corresponds to six subpixels in the horizontal direction and five pixel periods in the vertical direction in the embodiment of FIG. 10.

FIG. 11 is a diagram illustrating an image of a moiré generated when the stereoscopic image filter is disposed to have an inclination of 18.43 degrees, and FIG. 12 is a diagram of a moire generated when the stereoscopic image filter is arranged to have an inclination of 12.53 degrees. FIG. 13 is a diagram illustrating an image of a moiré generated when the stereoscopic image filter is disposed to have an inclination of 14.93 degrees, and FIG. 14 is a stereoscopic image filter arranged to have an inclination of 23.96 degrees. It is a figure which shows the image which picked up the moire which generate | occur | produces in the state, and FIG. 15 is a figure which shows the image which imaged the moire which arises in the state in which the stereoscopic image filter was arrange | positioned so that it may have inclination of 21.8 degree | times.

11 to 15, the period of the stereoscopic image filter has a width of about 10 subpixels.

11 to 15, the stereoscopic image filter having an inclination of 18.43 degrees generates a moiré 1120 due to interference between the pattern of the display panel and the pattern 1110 of the stereoscopic image filter as shown in FIG. There is a limit. In addition, the stereoscopic image filter having a slope of 12.53 degrees has a limit of lowering image quality by generating the moiré 1220 due to the interference between the pattern of the display panel and the pattern 1210 of the stereoscopic image filter as shown in FIG. 12. In addition, the stereoscopic image filter having an inclination of 14.93 degrees has a limit of lowering image quality by generating the moire 1320 due to the interference between the pattern of the display panel and the pattern 1310 of the stereoscopic image filter as shown in FIG. 13. In addition, the stereoscopic image filter having a slope of 23.96 degrees has a limit of deteriorating image quality by generating the moiré 1420 due to the interference between the pattern of the display panel and the pattern 1410 of the stereoscopic image filter as shown in FIG. 14. However, it can be seen in FIG. 15 that the stereoscopic filter 1510 having the inclination of 21.8 degrees does not generate moiré. The stereoscopic image filter 1510 has a period of the stereoscopic image filter under optimal conditions.

FIG. 16 is a diagram illustrating an example of the number of viewpoints between both eyes, and FIG. 17 is a diagram illustrating cross-talk and ghosting phenomena according to the embodiment of FIG. 16. FIG. 18 is a diagram illustrating another embodiment of the number of viewpoints between both eyes, and FIG. 19 is a diagram for describing cross-talk and ghosting phenomena shown in accordance with the embodiment of FIG. 18.

16 to 19, the stereoscopic image processing apparatus 1600 of FIG. 16 and the stereoscopic image processing apparatus 1800 of FIG. 18 have the same viewing widths 1610 and 1810 and the same binocular disparity 1620 and 1820. To the user. In addition, the number of viewpoints provided by the stereoscopic image processing apparatus 1600 between the left eye 1601 and the right eye 1602 of the user is three, and the stereoscopic image processing apparatus 1800 is provided between the left eye 1801 and the right eye 1802 of the user. The number of viewpoints provided in is nine. The unit viewpoint interval 1840 of the stereoscopic image processing apparatus 1800 providing a large number of viewpoints is formed to be narrower than the unit viewpoint interval 1630 of the stereoscopic image processing apparatus 1600 providing a small number of viewpoints. At this time, the user perceives the same depth (1650, 1850). 16 illustrates conditions corresponding to the stereoscopic image filters of FIGS. 2 to 3, and FIG. 18 illustrates conditions corresponding to the stereoscopic filters of FIGS. 9 to 10.

In the stereoscopic image processing apparatus 1600 of FIG. 16, only one neighboring viewpoint 1712 is invaded in one direction from the left eye image 1711 and the right eye image 1713, as shown in FIG. 17. Although less than 1800, only three viewpoint images are provided between the left eye 1601 and the right eye 1602 of the user, so that the disparity between the viewpoint images 1711, 1712, and 1713 is largely applied. You'll see a big video of ghosting. This phenomenon occurs larger as the depth of the image increases. Here, disparity means a degree of difference between an image incident on the left eye and an image incident on the right eye.

The stereoscopic image processing apparatus 1800 of FIG. 18 has five neighboring viewpoints 1912, 1913, 1914, 1915, and 1916 in one direction in the left eye image 1911 and five in one direction in the right eye image 1919, as shown in FIG. 19. Invasion of the two adjacent viewpoints 1914, 1915, 1916, 1917, 1918 is observed, resulting in more cross chins than the stereoscopic image processing device 1600, but there are nine between the left eye 1801 and the right eye 1802 of the user. Since the viewpoint image is provided, the amount of parallax between the viewpoint images 1911 to 1919 is small, so that a natural blur phenomenon occurs in general, and the overlapping image does not occur, so the user sees an image with low ghosting. Accordingly, the stereoscopic image processing apparatus 1800 generates less ghosting, which is a cross tuck perceived by the user, than the stereoscopic image processing apparatus 1600.

Therefore, when providing the user with more viewpoints in the same viewing range, the ghosting perceived by the user is degraded. The stereoscopic image filter 950 illustrated in FIG. 9 has a width of nine unit pixels due to the viewpoint arrangement characteristics (arranged in a manner in which the viewpoint image is increased by 5 points in the horizontal direction and 6 points in the vertical direction) in the aforementioned unit pixels. The stereoscopic image filter 1050 shown in FIG. 10 has a view point of 4.6 due to the viewpoint disposition characteristics (arrangement of the view image in increments of 5 points in the horizontal direction and 6 points in the vertical direction) in the aforementioned unit pixels. Has 23 views in unit pixel widths. However, the stereoscopic image filter 50 illustrated in FIG. 2 has 9 views at 9 unit pixel widths, and the stereoscopic image filter 70 illustrated in FIG. 3 has 9 views at 4.5 unit pixel widths. Accordingly, the present invention can provide the user with more view counts in the same stereoscopic filter filter period. Therefore, since the present invention provides the user with more viewpoints in the same viewing area width, ghosting, which is a cross tuck of a stereoscopic image perceived by the user, is lowered than before.

20 is a view showing another embodiment of the arrangement of the three-dimensional image filter according to the present invention.

Referring to FIG. 20, the display 150 includes a display panel 2010, a stereoscopic filter 2020, and a backlight 2040.

The display panel 2010 is a component corresponding to the display panel 910 of FIG. 9 and will not be described in detail below.

The stereoscopic filter 2020 may be one of a liquid crystal parallax barrier and a lenticular lens substrate. The stereoscopic image filter 2020 is a component corresponding to the stereoscopic image filter 950 of FIG. 9 and a detailed description thereof will be omitted.

The lenticular lens substrate 2020 may be disposed on the front surface of the display panel 2010. In this case, the lenticular lens substrate 2020 may be disposed to be spaced apart from the display panel 2010 by a predetermined distance l so that the image is placed on the focal plane of the lenticular lens.

The lenticular lens substrate 2020 may be a liquid crystal lenticular filter. In this case, the lens 2021, the lens 2022, the lens 2023, the lens 2024, and the lens 2025 included in the lenticular lens substrate 2020 may be liquid crystal lenses.

The backlight 2040 supplies light to the display panel 2010. The backlight 2040 is disposed on the back of the display panel 2010 and may include one or more backlight lamps and a driving circuit thereof. The light supplied by the backlight 2040 may be light having no polarization component. When the display panel 2010 is a PDP, the display 150 may not include the backlight 2040.

21 is a view showing the principle of the liquid crystal Lenticular.

Referring to FIG. 21, the liquid crystal lenticular filter 2120 may include a liquid crystal (LC) disposed between the transparent electrodes (ITO) 2121 and 2122 and the transparent electrode. The liquid crystal lenticular filter 2120 adjusts the refraction of light emitted from the display panel 2110 through liquid crystal (LC) so that the viewpoint zeros are positioned on an appropriate sweet spot. That is, liquid crystal (LC) forms lenses that refract light. The liquid crystal lenticular filter 2120 may adjust the position, direction, and arrangement of the liquid crystal (LC) by adjusting a voltage applied to the transparent electrode ITO. The position of the lens to be formed may be changed according to the position, direction, and arrangement of the liquid crystal (LC), and thus the sweet spot may be changed.

The liquid crystal lenticular filter 2120 may have a unit electrode in which the electrodes in the lens are divided into a predetermined number, and a refractive index of the liquid crystal is changed by applying a voltage corresponding to the shape of the lens to be formed to have a distribution for each unit electrode. A lens can be formed.

In addition, the liquid crystal lenticular filter 2120 may move the lens by adjusting a voltage applied to the unit electrode. That is, the liquid crystal lenticular filter 2120 applies voltages respectively applied to the unit electrodes to the unit electrodes moved by the number of unit electrodes having a length corresponding to the movement amount to form the lens, so that the unit lenses are moved by the movement amount. The unit lens may be formed at the position.

The liquid crystal lenticular filter 2120 may activate and deactivate the liquid crystal LC. When the liquid crystal is activated, a plurality of lenses are formed. When the liquid crystal is deactivated, the liquid crystal lenticular filter 2120 transmits the incident light without refracting.

The controller 190 may control activation and deactivation of the liquid crystal LC of the liquid crystal lenticular filter 2120. When the 2D image is displayed, the controller 190 may control the liquid crystal LC of the liquid crystal lenticular filter 2120 to be inactivated. In addition, when the stereoscopic image is displayed, the controller 190 may control the liquid crystal LC of the liquid crystal lenticular filter 2120 to be activated.

FIG. 22 illustrates a structure of a preferred embodiment of a lenticular lens substrate. FIG.

22 is a cross-sectional view illustrating a structure of an embodiment of a lenticular lens substrate. Referring to FIG. 22, the lenticular lens substrate 2210 may be disposed in front of the display panel 2010 or on the rear surface of the display panel 2010, between the display panel 2010 and the backlight unit 1640. Can be.

In addition, the lenticular lens substrate 2210 may include a lenticular lens 2230 that selectively deflects a path of light supplied from the display panel 2010 and a lenticular array that determines the refractive index of the lenticular lens 2230 according to the polarization form of light. 2240).

The lenticular lens 2230 includes a concave isotropic medium layer 2234 and an anisotropic medium layer 2236, and the isotropic medium layer 2234 may have a convex shape according to a designer's intention.

The lenticular array 2240 may include two substrates 2242 and a liquid crystal layer 2245 positioned between the two substrates 2242. The liquid crystal layer 2245 includes liquid crystal modes such as twist nematic (TN), vertical alignment (VA), and the like, in-plane switching (IPS), and ferroelectric liquid crystal (FLC), which rotate in the horizontal direction. It can be applied, and is not limited to a specific liquid crystal mode.

However, in the TN, VA, etc., in which the liquid crystal rotates in the vertical direction, an elliptical polarization component exists among the polarization components of light in the liquid crystal layer, and the light path of the elliptical polarization component is changed by the lenticular lens 2230. Therefore, the liquid crystal mode applied to the lenticular lens 2230 is preferably applied to the IPS and FLC modes in which the liquid crystal rotates in the horizontal direction.

FIG. 23 is a view illustrating a path of light adjusted according to a polarization pattern of light incident on the lenticular lens substrate of FIG. 22.

Referring to FIG. 23, when displaying a 2D image, the controller 190 controls the power to be turned off between two substrates 2242. Accordingly, no electric field is formed between the two substrates 2242, and the refractive index of the liquid crystal layer 2245 is not different.

Therefore, the light C1 of the linearly polarized state incident from the display panel 2010 passes through the liquid crystal layer 2245 as it is and is incident on the lenticular lens 2230. In addition, the light b2 passing through the liquid crystal layer 2245 passes through the isotropic medium layer 2234 and the anisotropic medium layer 2236 of the lenticular lens 2230 as it is. Light C3 passing through the lenticular lens 2230 is incident to the left and right eyes of the viewer 2001. The viewer 2001 perceives the 2D image through the light C3.

When displaying a stereoscopic image, the controller 190 controls power to be applied between the two substrates 2242. As a result, an electric field is formed between the two substrates 2242, and the refractive index of the liquid crystal layer 2245 is changed.

Therefore, the light D1 of the linearly polarized state incident from the display panel 2010 is converted into the circularly polarized state while passing through the liquid crystal layer 2245 and is incident on the lenticular lens 2230. The circularly polarized light D2 passing through the liquid crystal layer 2245 is incident on the anisotropic medium layer 2236 of the lenticular lens 2230 without changing its state, but the isotropic medium layer 2234 and the anisotropic medium layer 2236 are incident. Depending on the circularly polarized state at the interface of the refracted at a predetermined angle, the path of light is changed. The light D3 whose path is changed is moved to the corresponding sweet spot and is incident on the left and right eyes of the viewer. The viewer perceives the 3D image through the viewpoint image incident to the left eye and the viewpoint image incident to the right eye.

The present invention can also be embodied as computer-readable codes on a computer-readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer apparatus is stored. Examples of the computer-readable recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, and the like, and may be implemented in the form of a carrier wave (for example, transmission via the Internet) . The computer-readable recording medium may also be distributed to networked computer devices so that computer readable code can be stored and executed in a distributed manner.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation in the embodiment in which said invention is directed. It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the scope of the appended claims.

Claims (15)

A display panel including subpixels for generating a display; And
It is disposed in front of the display panel, and includes a three-dimensional filter for controlling the direction of the light passing through the display panel or the light emitted from the display panel,
And the stereoscopic image filter is inclined by 21.8 degrees with respect to the display panel. The method of claim 1,
The stereoscopic filter,
Autostereoscopic image processing apparatus, characterized in that the lenticular lens substrate having a plurality of lenses. The method of claim 2,
The lenticular lens substrate,
Further comprising a lenticular array for converting transmitted light into circularly polarized light,
And the lenticular array is activated or deactivated according to a type of an image displayed by the display panel. The method of claim 1,
The stereoscopic filter,
An autostereoscopic 3D image processing apparatus, characterized in that the parallax barrier alternately forms a transmission region and an opacity region. 5. The method of claim 4,
And an opaque region of the stereoscopic filter is activated or deactivated according to the type of the image on which the display panel is displayed. The method of claim 1,
The width of the pitch (Pich) of the three-dimensional image filter is autostereoscopic 3D image processing apparatus, characterized in that corresponding to the horizontal width of 2.4 to 13 sub-pixels. The method of claim 1,
An autostereoscopic 3D image processing apparatus, characterized in that the width of the pitch (Pitch) of the three-dimensional image filter is an integer multiple of the horizontal width of the sub-pixel or a non-integer multiple. The method of claim 1,
And the image displayed by the display panel includes at least one of a two-dimensional image, a stereo image, and a multi-view image. The method of claim 1,
The display panel may be one of a plasma display panel (PDP), a liquid crystal display (LCD) and a light-emitting diode (LED) panel. The method of claim 1,
The autostereoscopic 3D image processing apparatus further comprising a backlight disposed on a rear surface of the display panel and configured to supply light to the display panel. The method of claim 1,
An autostereoscopic 3D image processing apparatus, characterized in that the number of viewpoints of the multi-view image displayed by the display panel is between 12 and 65. The method of claim 1,
An eyeglass stereoscopic image processing apparatus, wherein the viewpoint image is disposed on the display panel in such a manner that the viewpoint image is increased by 5 points in the horizontal direction and 6 points in the vertical direction. The method of claim 1,
A camera for photographing an image of a user; And
And a controller configured to determine user location information related to the location of the user by using the captured image and to generate a control signal for controlling the display of the viewpoint images based on the determined user location information. Glasses-free stereoscopic image processing device. The method of claim 13,
Autostereoscopic 3D image processing apparatus, characterized in that the pitch of the stereoscopic filter is moved in accordance with the control signal. The method of claim 13,
And a plurality of viewpoint images to be displayed on the display panel according to the control signal.

Images