JP5707120B2 - Video output device, display method, and display device - Google Patents

Description

  Embodiments described herein relate generally to a video output device that outputs a parallax image, a display method, and a display device.

  Stereoscopic image display devices that display multi-parallax images (three-dimensional images) have been developed and are becoming popular.

  On the other hand, it cannot be said that content (video software) including three-dimensional image (multi-parallax) image data and reproducible as a stereoscopic image is sufficiently supplied.

JP-A-7-298311

  From the above-mentioned background, there are relatively few viewers who can imagine how it will look when content including three-dimensional image data is reproduced by a stereoscopic image display device that can reproduce stereoscopic images. is assumed.

  An object of the present invention is a three-dimensional image display device capable of reproducing a three-dimensional image, a video output device for outputting a parallax image that can increase an opportunity for a viewer to view a three-dimensional image obtained by reproducing content including three-dimensional image data, A display method and a display device are provided.

According to the embodiment, the image output device, a planar image based on the first video signal, second stereoscopically visible image based on the video signal including the intrinsic stereoscopic signal which does not depend on the signal conversion prepared in advance the preparative, comprising a synthesizing unit for synthesizing to display the same screen, and a control unit for the combining unit to input a control signal for displaying an image obtained by combining, based on the second video signal stereoscopically visible image, startup, or when starting to input the first video signal, or when the input switching to the first video signal, or when the input is switched from the first video signal, said first The two-dimensional image based on one video signal is synthesized by the synthesis unit.

Schematic which shows an example of the display apparatus (video output device) to which the embodiment is applied. Schematic which shows an example of the structure which produces | generates a parallax image in the video output device to which embodiment is applied. Schematic which shows an example of the parallax image generation method to which embodiment is applied. Schematic which shows an example of the parallax image generation method to which embodiment is applied. Schematic which shows an example of the signal output of the video output device to which embodiment is applied. Schematic which shows an example of the signal output of the video output device to which embodiment is applied. Schematic which shows an example of the video output (display signal) of the video output device to which embodiment is applied. Schematic which shows an example of the video output (display signal) of the video output device to which embodiment is applied. Schematic which shows an example of the display apparatus (video output device) to which the embodiment is applied.

  Hereinafter, embodiments will be described with reference to the drawings.

  FIG. 1 shows an example of a display device to which the embodiment is applied. The elements, configurations, and functions described below may be realized by hardware, or may be realized by software using a microcomputer (processing device, CPU) or the like.

  The display device 1 is, for example, a 3D video playback device capable of stereoscopically displaying an input video signal. For example, a tablet PC (Personal Computer), a digital photo frame, a multifunctional mobile terminal device called a smartphone, a television receiver, or the like including. Although 3D video will be described later, naked-eye 3D display by displaying a multi-parallax image (no shutter mechanism is required from the viewer) is possible.

  The display device 1 includes an input image signal processing unit 11, a depth information generation unit 13, a multi-parallax image generation unit 15, a multi-parallax image conversion unit 17, a storage unit (true stereoscopic image signal input holding unit) 19, and an output image selection / synthesis unit. 21, a control unit 23, a stereoscopic image conversion unit 25, a flat display device (display panel) 27, a GUI (Graphical User Interface) processing unit 29, and an operation input unit 31. In order to input a selection instruction by the viewer, the operation input unit 31 receives a selection instruction or input instruction from the remote controller (remote controller) 33 and supplies a control command corresponding to the content to the control unit 23.

  The display panel (planar display device) 27 is arranged opposite to the panel main body (planar display unit) 27a including pixels arranged in a matrix and the panel main body 27a, and a plurality of exits for controlling light rays from the pixels. And a light beam control element 27b having a pupil.

  As the panel body 27a, for example, a liquid crystal panel or a plasma display panel can be used.

  The light beam control element 27b is called, for example, a parallax barrier or a parallax barrier, and even if the individual exit pupils are images viewed through the same position (pupil), the light beams can be seen so that different images can be seen depending on the viewing angle. To control. Specifically, for example, when only left and right parallax (horizontal parallax) is given, a slit plate having a plurality of slits or a lenticular sheet (cylindrical lens array) is used. A pinhole array or a lens array is used to realize left-right parallax and vertical parallax (vertical parallax). That is, the slit of the slit plate, the cylindrical lens of the cylindrical lens array, the pinhole of the pinhole array, and the lens of the lens array are the exit pupils. In this embodiment, an example in which the display panel 27 includes a light beam control element 27b having a plurality of exit pupils will be described. For example, a parallax barrier is generated electronically by a transmissive liquid crystal display device or the like, The shape, position, and the like of the barrier pattern can be arbitrarily changed electronically as long as the display device can display an image for stereoscopic image display described later.

  The input image signal processing unit 11 receives and decodes the input two-dimensional image signal provided by the broadcaster or distributor, that is, video content, for example, the title 3 or the encoded multi-parallax image signal 5.

  The depth information generation unit 13 receives the input image signal processing unit 11 and analyzes the decoded two-dimensional image signal (title) 3 or multi-parallax image signal 5 to generate image depth information (depth information). Although the depth information is schematically shown in FIG. 2, for example, as described in Japanese Patent Laid-Open No. 2000-261828, for example, a background region extraction unit 131, a motion vector detection unit 133, a background motion vector detection unit 135, and a relative motion vector calculation A background motion image is obtained by extracting a background motion image signal from the input video signal (two-dimensional video signal), that is, the title 3 by the background motion extraction unit 131. A motion vector (video motion vector) is obtained from the image signal of the region other than the background region separated in step, and the background motion vector and motion vector detection unit 133 obtained by the background region extraction unit 131 are obtained by the background motion vector detection unit 135. A representative background motion vector is calculated from the video motion vector, and the relative motion vector calculation unit 137 It can be obtained by obtaining a relative motion vector (subtracting the representative motion vector from the motion vector) from the video motion vector obtained by the motion vector detecting unit 133 and the representative background motion vector obtained by the background motion vector detecting unit 135. .

  The depth information is used by the multi-parallax image generation unit 15 to generate a multi-parallax image viewed from, for example, nine directions. In other words, the multi-parallax image generation unit 15 uses, for example, a parallax image viewed from the left direction for an object (for example, the object 43 in the screen display 41 shown in FIG. 3) whose depth information is on the front. Since the object 43 appears to be shifted to the right side with respect to the object in the background 45, a parallax image viewed from the left direction is generated by performing a process for shifting the image to the right side. In this way, parallax images viewed from nine positions in the horizontal direction from left to right are generated. Performing the process of shifting the position of the object is supposed to be a process of simply distorting the image because the background image should be visible, but there is no information in the input image.

  When the depth information is included in the image signals supplied from the multi-parallax image generation unit 15 and the input image signal processing unit 11, the input image signal processing is performed without using the depth information generated by the depth information generation unit 13. A multi-parallax image is generated using an image signal (image signal indicated by a broken line) supplied from the unit 11 to the multi-parallax image generation unit 15.

As shown in FIG. 4, the normal image 51 inputted to the input image signal processing unit 11, by the depth information generating unit 13 and the multiple parallax image generator 15 of the above-described two-parallax image 55 or multi-parallax image image 5 Is converted to 7. Further, the image signal input as pre 2nd parallax images 53, is converted into multi-parallax image 57 by multiple parallax image generator 15.

In order to stereoscopically display (perceive as a stereoscopic image) the display image displayed from such a two-parallax image 55 (53), the viewer needs a shutter mechanism such as 3D glasses.

  On the other hand, the multi-parallax image 57 generated by the multi-parallax image generation unit 15 is referred to as naked eye 3D, and can be perceived as a stereoscopic image by the viewer without the need for the shutter mechanism described above.

  For example, the multi-parallax image conversion unit 17 converts the input multi-parallax image signal 5 (5a, 5b, 5c, 5d) into a multi-parallax image suitable for display on the display panel 27 and outputs the converted image. For example, assuming that the number of parallaxes of the input multi-parallax image signal is N and the number of parallaxes suitable for display on the display panel 27 is n, when N> n, the input multi-parallax image signal is thinned and the number of parallaxes is n. Multi-parallax images, and when N <n, interpolation is performed using the input multi-parallax image signal to generate and output a multi-parallax image having n parallaxes. When N = n, the input multi-parallax image signal is output as it is as a multi-parallax image. Note that the multi-parallax image signal 5 (5a, 5b, 5c, 5d) may be an image signal distributed via broadcast or a network, a reproduced video image signal, or a personal computer (Personal Computer, Hereinafter, it may be a multi-parallax image signal generated by PC).

  The storage unit (intrinsic stereoscopic image signal input holding unit) 19 displays a stereoscopic image (multi-parallax image) that can be displayed on the display panel 27 when displaying an activation screen such as a logo mark, a product name, or a guidance screen, for example. Intrinsic 3D data (intrinsic stereoscopic image signal) used for the purpose is stored. The intrinsic 3D data is a stereoscopic image signal generated in advance via a 3D (stereoscopic image) camera or the like, and is different from the converted multi-parallax image generated by the above-described multi-parallax image generation unit. In addition, during startup processing immediately after the main power supply of the display device 1 is turned on, or switching of the supply source of the image signal input to the input image signal processing unit 11, for example, playback of a title being received is connected to the outside When switching to playback of a title held by a recorder device (recording / playback device) or switching of a channel (broadcasting station) being received, a stereoscopic image obtained by playing back true 3D data held by the storage unit 19 is displayed on the display panel 27. Is displayed. Thereby, it is possible to notify the viewer of the characteristics of the stereoscopic image that can be displayed on the display panel 27 and the difference from the normal image (2D). In other words, the viewer can be interested in the 3D data image (the user can have a consciousness to see the 3D image).

  Based on the control signal from the control unit 23, the output image selection / synthesis unit 21 selects either the multi-parallax image output from the multi-parallax image generation unit 15 or the multi-parallax image output from the multi-parallax image conversion unit 17. A multi-parallax image is selected, and the selected multi-parallax image and a multi-parallax image based on a stereoscopic image signal obtained by reproducing the true 3D data supplied from the storage unit (true stereoscopic image signal input holding unit) 19 are converted into a stereoscopic image. The data is sent to the conversion unit 25. When a selection instruction input from the viewer via the operation input unit 31 is required, a selection instruction input screen generated by the GUI processing unit 29 is also displayed.

  The control unit 23 performs control corresponding to a control command from the operation input unit 31 that has received a signal generated when the viewer operates, for example, a signal generated by operating the remote controller 33 (for example, a signal using infrared rays). Generate a signal. The output image selection / combination unit 21 is controlled by the control signal from the control unit 23, and the true 3D held by the storage unit (intrinsic stereoscopic image signal input holding unit) 19 when the power of the display device 1 is turned on, for example. The multi-parallax image obtained by reproducing the data is sent to the stereoscopic image conversion unit 25.

  The stereoscopic image conversion unit 25 performs processing such as rearrangement of pixels to be output by the individual exit pupils of the panel main body 27a on the multi-parallax image supplied from the output image selection / synthesis unit 21, and generates a panel as a plurality of parallax images. Send to main body 27a. In addition, when each parallax image is composed of three sub-pixels (for example, R (red), G (green), and B (blue)), information in pixel units is rearranged in units of sub-pixels. Processing is performed to generate an image for stereoscopic image display. Further, as disclosed in Japanese Patent Application Laid-Open No. 2006-98779, only a part that is actually necessary among the parallax images may be collected and converted into a format suitable for transmission and compression of the parallax image (for example, a tile image).

  5A and 5B show the concept of switching the screen display when the display device 1 is started or when the input is switched.

  When the power of the display device 1 is turned on, that is, at the time of start-up or when the input is switched, the “3D” video 101 is displayed on the display panel 27 as a start-up screen such as a logo mark, a product name, or a guide screen. Subsequently, after a check according to the startup routine at power-on, video display is started with the function selected at the previous power-off. At this time, when the television broadcast is selected as the function used when the power is turned off, the screen display on the display panel 27 is switched to the normal image (“2D”) 103 in order to receive and start the television broadcast. .

Hereinafter, when a 3D video playback instruction (3D selection instruction input) is given from the remote controller 33 or the operation input unit 31 by the viewer, the screen display 107 of the display panel 27 is set to “CH” selected (at the time of activation). This is a guidance display for displaying, for example, “(CH) selected (at start-up)” on a normal image (“2D”) 107a (103 video is output as it is) for reproducing and displaying the title to be supplied. The “3D” video 107b obtained by reproducing the intrinsic 3D data held by the storage unit (true stereoscopic image signal input holding unit) 19 is displayed. That is, normal image and a ( "2D") that plays an intrinsic 3D data "3D" images, that displays on the same screen.
As shown in FIG. 5B, when the function selected when the power is turned off last time is, for example, the reproduction of recorded data from the recorder device, the “3D” video 101 is displayed as the startup screen. Thereafter, for example, the thumbnail screen portion indicating the title of the television broadcast is the “2D” display 111a, the guidance display indicating the recording date and time, and the thumbnail portion of the input video from the video camera taken by the viewer himself are “3D” display. A guidance screen 111 which is 111b is displayed. Also, for example, when the viewer selects playback of a title recorded from a television broadcast, the title (recorded television broadcast) is displayed as a “2D” display 113a. A reproduction screen (display) 113 to be a “3D” display 113b is displayed.

  More specifically, as shown in FIG. 6, when the power of the display device 1 is turned on [01], a “3D” image during startup (startup) or standby is displayed [02].

  Next, whether or not there is a request for displaying “3D video” from the viewer, that is, whether or not there is a display selection instruction is checked [03], and if there is a selection instruction [03-YES], the genuine 3D data held in the storage unit is reproduced. It is displayed together with the normal image [04].

  Thereafter, the video signal selected by the viewer is reproduced and displayed [05].

  In addition, following the display of “3D” video at startup (start-up) or standby, when a selection instruction from the viewer is not input [03-NO], “2D” video according to the normal image signal is displayed. Needless to say, [06].

  FIG. 7 shows a display example when a 2D image and a 3D image are simultaneously displayed on the display panel.

  A display 701 illustrated in FIG. 7 indicates a state in which the viewer selects a plurality of titles input from the outside. For example, when the viewer selects the title [711], the thumbnail display [711a] of the title is displayed normally (“2D”), and a frame (border indicating the thumbnail display [711a] or the selected title is displayed. ) The display [711b] is a “3D” display according to the true 3D data of the display screen held by the storage unit 19. In addition, the guidance display unit [711c] that displays the description of the selected title [711] (in a state where focus for selection is applied) follows the true 3D data of the display screen held by the storage unit 19. 3D "display.

  Thereby, the viewer can be interested in the 3D data image (the user can be conscious of seeing the 3D image).

  FIG. 8 shows a display example when a 2D image and a 3D image are simultaneously displayed on the display panel.

  A display 801 shown in FIG. 8 shows a state in which the display device 1 displays a plurality of titles recorded by the recorder device, for example, so as to be selectable by the viewer.

  In FIG. 8, thumbnails (title reduction) portions 811a, 812a, 813a, 814a, and 815a are displayed as normal (“2D”) images in the recorded title displays 811 to 815.

  On the other hand, frames (borders) 811b, 812b, 813b, 814b and 815b for displaying individual titles, and explanations of each title ([ch] name, date and time, separator display) 811c, 812c, 813c, 814c and the like 815c becomes “3D” display according to the true 3D data of the display screen held by the storage unit 19.

  Therefore, the viewer can be interested in the 3D data image (the user can be conscious of seeing the 3D image).

  FIG. 9 shows a specific example in which the display device shown in FIG. 1 is applied to a television receiver.

Another example of will be described.

  A TV apparatus (video reproduction apparatus) 901 shown in FIG. 9 receives and reproduces content including television broadcast, audio (audio), and video (video) supplied by, for example, spatial waves or wired transmission, that is, a program. The TV apparatus 901 can also play back content supplied through the Internet (network) network 1001. Note that the TV device 901 may include a recording medium such as an HDD (hard disk) and an encoder, and may be formed so that content can be recorded. Moreover, although the embodiment described below takes a TV device as an example, a display (monitor device) and a speaker can be separated to form a tuner unit called, for example, an STB (set top box).

  In the TV apparatus 901, the title (content) or the external input signal acquired by the tuner / input unit 911 is separated into video (video) data and audio (audio) data by a separation (Demux) unit 912. The tuner / input unit 911 determines whether the input video signal, that is, the content is a normal video (2D) signal or a stereoscopic video (3D) signal, and a control signal (or EPG (electronic program)) attached to the input video signal. It can be identified according to the description in the table).

  The video (video) data separated by the separation unit 912 is decoded by the video (video) decoder 922 of the video (video) processing block 921 and output as a digital video (video) signal. Note that when the content or external input signal received by the tuner / input unit 911 is, for example, video and audio from a video camera or the like, separation by the separation unit 912 is not necessary (can be through), depending on the signal input method. Needless to say.

  The video (video) data decoded by the video decoder 922 is input to a video (video) processing unit 923 that processes the video output device so that the video output device can be displayed, and can be displayed on a display 924 at a later stage. It is converted into interlace (i) / non-interlace (p) or the like and supplied to the display 924. Note that the output of the video (video) processing unit 923 may be output to an output terminal 925 to which, for example, an external monitor device or a projection device (projector device) can be connected.

  A stereoscopic video processing unit 926 that obtains a stereoscopic video signal from the video signal for stereoscopic display of the video is also provided after the video (video) processing unit 923. The stereoscopic video processing unit 926 includes at least the depth information generation unit 13, the multi-parallax image generation unit 15, the multi-parallax image conversion unit 17, and the output image selection / synthesis unit 19 described with reference to FIG. When the input image signal is a two-parallax signal, it may be directly input to the input terminal of the stereoscopic video processing unit 926. In addition, the stereoscopic video processing unit 926, in accordance with control information from the main control block 951, has a format corresponding to a preset display method, such as a side-by-side method, a Frame-Sequential method, an Above-Below method, or the like. Output video output signal. Of course, the same applies to display devices that use lenticular lenses that do not require deflection glasses (shutters) that are widely used in 3D (stereoscopic image) display devices.

  On the other hand, the audio data separated by the separation unit 912 is decoded by the audio (audio) decoder 932 of the audio (audio) processing block 931 and output as a digital audio (audio) signal.

  The audio (audio) signal decoded by the audio decoder 932 passes through the audio (audio) processing unit 933 that is processed so as to be reproducible by the audio output device, and is input to the DA converter 934 that obtains an analog audio (audio) output. The

  An analog audio (audio) output from the DA converter 934 is input to a speaker 935, for example. The output from the DA converter 934 may be further branched to an output terminal 936 to which an AV (Audio Visual) amplifier or the like can be connected.

  In the TV apparatus 901 described above, each of the tuner unit 911, the separation unit 912, the video (video) processing block 921, and the audio (audio) processing block 931 is controlled by the main control block 951 and executes a predetermined operation.

  The main control block 951 includes, for example, a CPU (Central Processing Unit) or a microcomputer. The main control block 951 has a memory unit 952 including at least a ROM holding an operation program and a RAM functioning as a work memory, and a connection with the Internet network 1001, that is, acquisition of various information from the Internet network 1001, and the Internet network 1001. A network (LAN) control unit 953 for controlling access from the user to the reader, and a reader / writer 954 that can be used for capturing true 3D data (true stereoscopic image signal) or video information prepared by the viewer from the outside, at least Including. The reader / writer 954 can read data held in a semiconductor memory device represented by an SD (Secure Digital) card, for example.

  The main control block 951 is also connected with an operation input unit 903 that receives a control input from the user.

  The operation input unit 903 includes, for example, a channel key (button) for specifying a channel selected by the tuner (input) unit 911, a power switch used for turning on / off the power, or a remote controller (hereinafter referred to as a remote controller) 905. It includes at least a receiving unit that receives instructions and control inputs. In addition, a key operation input unit (keyboard) that enables input of characters, symbols, numbers, or the like may be connected.

  Hereinafter, switching between stereoscopic display and normal display will be described by taking control input from the remote controller 905 as an example.

  The remote controller 905 includes a selection input unit that can output a selection signal for switching between stereoscopic display and normal display, for example, an input button (key) 905a. 951 can be entered. Note that the remote controller 905 can change a depth feeling prepared in advance in a three-dimensional display, and a setting button (key) 905b for setting a change in the depth feeling in response to a viewer's request. It is preferable to have.

  When stereoscopic display is selected by operating the remote controller 905, the output of the video (video) processing unit 923 is input to the stereoscopic video processing unit 926 before being output to the display 924 or the output terminal 925, and will be described in detail later. Is converted to a stereoscopic video signal, and then output to the display 924 or the output terminal 925.

  In the TV apparatus shown in FIG. 9, the normal image (“2D”) described with reference to FIGS. 5A, 5 </ b> B, 7, and 8, and intrinsic 3D data supplied via the reader / writer 954. A “3D” image based on (true stereoscopic image signal) can be displayed simultaneously (within the same screen), thereby making it possible for viewers to be interested in 3D data video (3D video You can be conscious of trying to see it).

  Although not described in detail, the TV apparatus 1 can also set the reader / writer 954 to USB connection via a USB (Universal Serial Bus) terminal. In this case, one or a plurality of interfaces capable of USB connection, For example, a recorder or HDD device that can exchange data via a network controller compliant with the DLNA (Digital Living Network Alliance (registered trademark)) standard, Bluetooth (registered trademark) not shown, or the like, or portable Needless to say, a terminal device may be connected.

  As described above, by adopting the present proposal, a stereoscopic image obtained by reproducing intrinsic 3D data prepared in advance can be displayed simultaneously (within the same screen) when a title (content) is reproduced and displayed. Thereby, the viewer can be notified of the feature of the stereoscopic image and the difference from the normal image (2D). In other words, the viewer can be interested in the 3D data image (the user can have a consciousness to see the 3D image).

  Note that the concept of the display device shown in FIGS. 1 and 9 can be applied to a video playback device having no display unit, such as a DVD player device, or a video recording / playback device, such as a recorder device. Nor.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1 ... Display apparatus (digital photo frame / tablet PC / smart phone), 3 ... Two-dimensional (2D) image signal, 5 ... Multi parallax image signal, 11 ... Input image signal processing part, 13 ... Depth information generation part, 15 ... Many Parallax image generation unit, 17 ... multi-parallax image conversion unit, 19 ... storage unit (true stereoscopic image signal input holding unit), 21 ... output image selection / synthesis unit, 23 ... control unit, 25 ... stereoscopic image conversion unit, 27 ... display Panel (flat display device), 29... GUI processing unit, 31 .. operation input unit, 33... Remote control (remote controller), 131... Background region extraction unit, 133. ... Relative motion vector calculation unit, 901 ... Television apparatus (display apparatus).

Claims (5)

A planar image based on the first video signal, and a stereoscopically visible image based on the second video signal including an intrinsic stereoscopic signal which does not depend on the signal conversion which is prepared in advance, synthesized to display the same screen A synthesis unit to
A control unit for inputting a control signal for displaying the video synthesized by the synthesis unit, and
The stereoscopically viewable image based on the second video signal is the start-up time , the input start time of the first video signal, the input switching to the first video signal, or the first video image. A video output device that is synthesized by the synthesis unit with a planar image based on the first video signal when switching the input from the signal.   The video output device according to claim 1, further comprising a display unit configured to display a video. Obtain the first video signal to play the input signal as it is,
Including intrinsic stereoscopic signal that is not based on a prepared signal conversion, the second video signal can be stereoscopically, to be displayed as the first video signal and the same image, by combining the first video signal Generating a third video signal;
Startup, or when starting to input the first video signal, or when the input switching to the first video signal, or when the input is switched from the first video signal, or if the accepted selection instruction, A display method for outputting a video signal based on the synthesized third video signal. A display unit for displaying images;
An image in which the display unit displays the plane image based on the first video signal and a second stereoscopically visible image based on the video signal including the intrinsic stereoscopic signal which does not depend on the signal conversion prepared in advance a synthesizing unit for synthesizing to display the same screen,
A control unit for inputting a control signal for displaying the video synthesized by the synthesis unit to the display unit;
The second video signal, at an input start of the startup, or the first video signal, or when the input switching to the first video signal, or when the input is switched from the first video signal, the A display device synthesized by the synthesis unit. The display device according to claim 4 , wherein the combining unit superimposes the second video signal prepared in advance on the first video signal.

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