JP2013214788A - Video signal processing apparatus and video signal processing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To output video signals after two-dimensional-three-dimensional video conversion in a frame sequential manner without interposing a frame memory, when video signals are output to a frame sequential display device that alternately displays a video for a left eye and a video for a right eye, by using a two-dimensional-three-dimensional video conversion device for simultaneously outputting the video for a right eye and the video for a left eye.SOLUTION: Video signals are stored in a frame memory; the video signals stored in the frame memory are read out repeatedly, for example, for the first time, and for the second time; and the video signals are output to a two-dimensional-three-dimensional video conversion device. When the video signals are read out for the first time, a video signal for a left eye of the two-dimensional-three-dimensional video conversion device is selected, and when the video signals are read out for the second time, a video signal for a right eye of the two-dimensional-three-dimensional video conversion device is selected; and the selected video signals are output.

Description

  The present invention relates to a video processing apparatus. More specifically, the present invention relates to a video signal processing apparatus and method that do not use an extra data storage apparatus and method by performing frame rate conversion in advance when converting a video signal into a stereoscopic video.

  2. Description of the Related Art In recent years, some video display devices represented by television receivers are capable of 3D (three-dimensional) display. As one of the 3D display methods of the video display device, the left-eye video signal and the right-eye video signal, which are called frame sequential, are sequentially displayed, and the shutter of the glasses applied by the viewer in synchronization with the displayed video is set to the left eye, A technique for stereoscopic viewing by opening and closing the right eye and the frame unit is used.

  For such video display devices, 2D (2D) video is generated by performing 2D-3D conversion so that 2D video produced in the past can be displayed in 3D. It is also possible to view the 3D video through glasses. As an example of such a 2D-3D conversion technique, there is a 2D-3D video conversion technique for converting 2D video into 3D video as disclosed in Patent Document 1. In this technique, depth information is detected from an input video signal, and a right-eye video signal and a left-eye video signal are simultaneously generated based on the depth information.

  Using this 2D-3D conversion technology, a conventional video display device for 3D display of 2D video first performs 2D-3D conversion processing on the video signal, and simultaneously generates a right-eye video signal and a left-eye video. The signals are output by rearranging the order of the video signals so as to be frame sequential.

  FIG. 4 is a block diagram of a video signal processing apparatus that performs 3D display using the 2D-3D conversion technology. FIG. 5 is an image diagram schematically showing video output from each unit of the video signal processing apparatus. The configuration will be described below.

  The video signal decoding unit 1 decodes a broadcast signal or a signal read from a recording medium, and outputs the decoded signal to the resizing unit 12 as a video signal. The video signal here is a signal representing a two-dimensional planar video. FIG. 5 shows an image of the video signal output from the video signal decoding unit 1 as an output of the video signal decoding unit.

  Next, the resizing unit 12 temporarily writes the input video signal in the frame memory unit 3. When reading out, the input video signal is enlarged or reduced (resized) in accordance with the display size displayed on the display device. Resizing is performed by thinning out the image in the vertical and horizontal directions when the image is reduced, and outputting a plurality of times when the image is enlarged. At that time, in order to prevent image quality deterioration due to frequency folding of the video, resizing is often performed by filtering in the horizontal and vertical directions. It may also include converting an interlace signal to a progressive signal.

  Subsequently, the 3D conversion unit 14 inputs the video signal resized by the resizing unit 12, generates depth information from the video signal, generates a right-eye video and a left-eye video according to the depth information, and Video signal and left-eye video signal. The right-eye video and the left-eye video are generated by adjusting the horizontal shift amount of the input video signal according to the depth information. The 3D conversion unit 14 is configured without a frame memory, and the right-eye video signal and the left-eye video signal are simultaneously output from the 3D conversion unit 14. FIG. 5 shows an image of the output of the 3D conversion unit 14.

  Then, the frame rate conversion unit 15 writes the right-eye video signal and the left-eye video signal output from the 3D conversion unit 14 in the frame memory unit 16. When reading from the frame memory unit 16, the frame rate is converted to the frame rate to be displayed on the display panel, and at the same time, the left-eye video signal and the right-eye video signal are alternately output in frame sequential.

  FIG. 5 shows an image diagram of a video read from the frame rate conversion unit 15.

  As shown in FIG. 5, the video signal output from the video signal decoding unit 1 is output simultaneously with the left-eye video and the right-eye video when output by the 3D conversion unit 14. Thereafter, the frame rate conversion unit 15 rearranges the left-eye video signal and the right-eye video signal simultaneously output by the 3D conversion unit 14 so as to be frame sequential while performing frame rate conversion.

JP 2009-44722 A

  However, in the above-described video processing device, the left-eye video signal and the right-eye video signal, which are 3D videos that have been 3D-converted by the 3D conversion unit 14, are output simultaneously. For this reason, when 3D display is performed in a frame sequential manner, it is necessary to rearrange the left-eye video signal and the right-eye video signal in time series before sending them to the display device. That is, the left-eye video signal and the right-eye video signal output simultaneously must be output in the order of the left-eye video signal, the right-eye video signal, the left-eye video signal, and so on.

  At that time, when the 3D video generated by the 3D conversion unit 14 is temporarily stored in the frame memory unit 16 and read out from the frame memory unit 16 at a desired rate suitable for the display device, the left-eye video, the right-eye video, and the left-eye video are stored. The video signals are output sequentially in the order of. As described above, the frame memory unit 16 for storing the 3D-converted video is required. However, in the case of an embedded device for consumer use, it is not realistic to mount a large amount of memory in terms of cost, mounting surface, and the like. Absent.

  The present invention has been made in view of the above-described problems. For a video image that has been subjected to 2D-3D conversion, a frame of a 3D signal can be obtained by reducing the amount of frame memory used and using an existing frame memory. A video signal processing device and a video signal processing method that enable sequential output are provided.

  In order to solve the above problems, a video signal processing apparatus according to the present invention receives a two-dimensional video signal, generates the same video signal twice as the video signal, and generates a frame rate that constitutes a three-dimensional video. A resizing / frame rate converting unit that outputs a video signal having the same frame rate as the output signal and outputs a selection signal for distinguishing between the video signal generated first time and the video signal generated second time among the video signals; A 3D conversion unit that generates a three-dimensional video for the video signal output from the frame rate conversion unit and outputs a right-eye video signal and a left-eye video signal at the same time, and the resizing / frame rate conversion unit A selector that selects and outputs either the right-eye video signal or the left-eye video signal output from the 3D conversion unit according to the output selection signal; That.

  According to the video signal processing device or the video signal processing method of the present invention, it is possible to realize a 3D display device without newly adding a frame memory from the conventional video display device.

The figure showing the structure of the video processing apparatus in embodiment An image diagram of a frame generated by a video processing device according to an embodiment Flow chart of video processing in the embodiment A diagram showing the configuration of a conventional video processing apparatus Image diagram of frames generated by a conventional video processing device

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

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

  FIG. 1 is a block diagram of a video signal processing apparatus according to an embodiment.

  The video signal decoding unit 1 is the same as the video signal decoding unit 1 in the conventional video signal processing apparatus, decodes a broadcast signal or a signal read from a recording medium, and outputs it as a video signal. The video signal is a signal representing a two-dimensional planar video.

  Next, the resizing / frame rate converting unit 2 once writes the video signal input from the video signal decoding unit 1 in the frame memory unit 3 in the same manner as the resizing unit 12 of the conventional video signal processing apparatus. When the written video signal is read from the frame memory unit 3, the video is resized, and at the same time, the frame rate conversion is performed to output a video signal of 2 (unit × integer) frames from the video signal of 1 frame. . This output video signal has the same content for at least two frames. FIG. 2 shows an image of the video signal output from the resize / frame rate conversion unit 2. As shown in FIG. 2, the output from the resizing / frame rate converting unit 2 has a frame rate twice that of the output from the video signal decoding unit 1, and the video signal having the same content is output twice. . The frame memory unit 3 includes a readable / writable memory such as a D-RAM and an S-DRAM, and is a frame memory or the like that can store one screen of a video signal.

  At this time, the resize / frame rate conversion unit 2 outputs a Low frame determination signal to the selector 5 for the first time of the video signal output twice, and a High frame determination signal for the second time. This frame discrimination signal later indicates a left-eye video signal and a right-eye video signal, and becomes a selector signal for selecting a video signal by the selector 5. The definition of High and Low of the selector signal may be reversed.

  The 3D conversion unit 4 performs the same processing as the 3D conversion unit 14 of the conventional video processing device. The 3D conversion unit 4 generates depth information from the 2D video signal output from the resize / frame rate conversion unit 2 and responds to the depth information. To generate and output a right-eye video signal and a left-eye video signal. Although the processing is the same as that of the 3D conversion unit 4 in the conventional video processing device 4, the operating frame rate is the frame rate displayed on the display panel.

  FIG. 2 shows a video signal output from the 3D conversion unit 4. The left-eye video signal and the right-eye video signal are generated from the 3D conversion unit 4 and output according to the frame rate of the video signal output by the resizing / frame rate conversion unit 2.

  Finally, the selector 5 outputs either the left-eye video signal or the right-eye video signal output by the 3D conversion unit in accordance with the frame discrimination signal generated by the resize / frame rate conversion unit 2. When the frame discrimination signal is Low, the left-eye video signal is selected, and when it is High, the right-eye video signal is selected and output. The selection of the frame discrimination signal, the left-eye video signal, and the right-eye video signal may be reversed.

  FIG. 2 shows a video signal output from the selector 5. As shown in FIG. 2, the video signal corresponding to the frame rate of the video signal output by the resizing / frame rate conversion unit 2, that is, the frame rate displayed on the display panel is output in a frame sequential manner.

  FIG. 3 is a flowchart showing the flow of signal processing in the embodiment of the present invention.

  First, a video signal is received (S1) and stored in the frame memory unit 3 (S2).

  Subsequently, the video signal stored in the frame memory unit 3 is read as the first time, and then the video signal having the same contents is read out from the frame memory unit 3 as the second time (S3).

  The video signals read repeatedly are sequentially supplied to the 3D conversion unit 4. The 3D conversion unit 4 simultaneously outputs a left-eye video signal and a right-eye video signal, which are 3D-converted video signals (S4).

  When the video signal for the first repetition is supplied to the 3D conversion unit 4, the video signal for the left eye is selected from the output of the 3D conversion unit 4, and the video signal for the second repetition is supplied to the 3D conversion unit 4. In this case, the right-eye video signal is selected from the outputs of the 3D conversion unit 4 (S5), and is output to the display panel.

  As described above, in the present embodiment, for the video signal decoded by the video signal decoding unit 1, the resize / frame rate conversion unit 2 performs resizing according to the display size and the frame rate of the display panel, and the frame rate conversion. And simultaneously. After that, the 3D conversion unit 4 simultaneously generates the left-eye video signal and the right-eye video signal at the display panel frame rate, and the selector 5 selects either the left-eye video signal or the right-eye video signal. By outputting, a frame-sequential 3D image is output. With the above configuration, the video signal after the 3D conversion is output in a frame sequential manner, and the frame memory for temporarily storing the video signal associated with the frame rate conversion performed after the conventional 3D conversion can be reduced. it can.

  The video signal processing device and the video signal processing method of the present invention are useful for application to a stereoscopic video display device such as a television receiver.

1 Video Signal Decoding Unit 2 Resize / Frame Rate Conversion Unit 3 Frame Memory Unit 4 3D Conversion Unit 5 Selector

Claims (5)

For a video signal including a two-dimensional video, a three-dimensional video composed of a right-eye video and a left-eye video is generated, and a right-eye video signal including the right-eye video and the left-eye video are generated. In the video signal processing apparatus that alternately outputs the video signal for the left eye including the video,
The two-dimensional video signal is input, the same video signal as the video signal is generated twice in succession, and a video signal having the same frame rate as the frame rate constituting the three-dimensional video is output. A resize / frame rate converter for outputting a selection signal for distinguishing between a video signal generated first time and a video signal generated second time among the generated video signals;
A 3D conversion unit that generates a three-dimensional image for the video signal output from the resizing / frame rate conversion unit and outputs a right-eye video signal and a left-eye video signal simultaneously;
In response to the selection signal output by the resizing / frame rate conversion unit, the right-eye video signal or the left-eye video signal output from the 3D conversion unit is selected and output,
When the selection signal indicates that the video signal is generated for the first time, the video signal for the right eye is selected,
A video signal processing apparatus comprising: a selector that selects the left-eye video signal when the selection signal indicates that the video signal is generated for the second time. The resizing / frame rate conversion unit includes:
2. The persistent signal processing apparatus according to claim 1, wherein the input video signal is stored in a frame memory, and the same video signal as the video signal is continuously generated twice by reading the frame memory twice. . The selector is
In response to the selection signal output by the resizing / frame rate conversion unit, the right-eye video signal or the left-eye video signal output from the 3D conversion unit is selected and output,
When the selection signal indicates that the video signal is generated for the first time, the video signal for the left eye is selected and output,
2. The video signal processing apparatus according to claim 1, wherein when the selection signal indicates that the video signal is generated for the second time, the video signal for the right eye is selected and output. The resizing / frame rate conversion unit includes:
The two-dimensional video signal is input, the video signal is enlarged / reduced according to a display size, and the same video signal as the enlarged / reduced video signal is generated twice in succession to form the three-dimensional video. A video signal having the same frame rate as the frame rate is output, and a selection signal for distinguishing the first generated video signal from the second generated video signal from the second generated video signal is also output. The video signal processing apparatus according to claim 1. Generating a three-dimensional video composed of a right-eye video signal and a left-eye video signal for a video signal including a two-dimensional video; and a right-eye video signal including the right-eye video; A video signal processing method in a video signal processing apparatus that alternately outputs a left-eye video signal including a left-eye video,
A storage step of inputting the two-dimensional video signal and storing it in a frame memory;
Read the video signal stored in the frame memory as the first time, output to the 3D conversion unit, and read the video signal having the same content as the video signal as the second time, and output to the 3D conversion unit Steps,
In the first reading of the video signal in the reading step, a left-eye video signal is selected and output from the left-eye video signal and the right-eye video signal simultaneously output from the 3D conversion unit, and the reading step A video signal processing method comprising: an output step of selecting and outputting a video signal for the right eye from the video signals output from the 3D conversion unit in the case of reading the video signal for the second time.

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