JP4301250B2 - Signal reproducing apparatus and method - Google Patents

Description

  The present invention relates to a signal reproducing apparatus and method for reproducing encoded moving picture data by decoding encoded image data, and more particularly to a signal reproducing apparatus and method for reproducing a plurality of moving pictures having the same attribute.

  A characteristic common to optical disks is random access. A DVD (digital video disc: DVD-VIDEO), which is an optical disc, incorporates a multi-angle function, a multi-story function, and the like, taking advantage of this feature.

  The multi-angle function is a function for playing back images taken simultaneously from a plurality of different camera angles, for example, a function that makes it possible to play back images of a plurality of angles with respect to one image.

  In the DVD, data that enables selective reproduction of the plurality of angles is configured as an angle block. The angle block is formed by cutting the video data of each angle into small pieces. In the DVD, a so-called interleave structure is adopted, and the angle blocks are mixed and recorded on the signal recording surface. The DVD adopts such a data recording structure, thereby realizing the multi-angle function and the multi-story function.

  For example, the DVD playback device can play back a DVD as described above, and switch to a video of the desired angle during playback in real time.

  Note that there are two types of angle blocks, and an angle block (hereinafter referred to as SML_AG_BLK) that can be seamlessly connected to other angles when images of simultaneous progress are switched, that is, seamlessly. There are other angle blocks, that is, angle blocks (hereinafter referred to as NSML_AGL_BLK) whose angles can be switched only in a non-seamless manner.

  Patent document 1 is known as a prior art.

International Publication No. 95/12197 Pamphlet

  By the way, when the SML_AG_BLK is reproduced, the DVD reproducing apparatus can switch the angle seamlessly, but it takes about several seconds until the angle is switched after attempting to switch the angle. That is, the DVD playback apparatus cannot play back another angle at the moment of switching the angle. Therefore, even if the viewer switches when he / she wants to view a video at another angle, he / she cannot see the video at the other angle at the moment of switching, and misses the desired video.

  Further, in the reproduction of the SML_AG_BLK, the angle switching is limited to once every several seconds. In all angles, sub-picture data including audio data and subtitle information is encoded only for those related to the video of the angle to be reproduced.

  Further, when the NSML_AG_BLK is played, the DVD playback device must stop playback when switching the angle, then switch to another angle and restart playback. In this way, an image in which each angle is not smoothly connected becomes difficult for a viewer to see.

  In the reproduction of NSML_AG_BLK, another angle at the moment of switching the angle can be reproduced. Further, there are generally more places where the angle can be switched than the SML_AG_BLK. Further, even when switching to a video of another angle, audio data and sub-video data different from the video of the other angle can be decoded.

  When the NSML_AG_BLK and NSML_AG_BLK are played, the DVD playback device cannot switch the angle seamlessly and instantaneously even if the angle can be switched.

  In addition, for example, if the video display of each angle can be provided to the viewer at the same time, each angle video can be confirmed at all times, so that the video can be overlooked by switching each angle and the difficulty of viewing can be eliminated as described above. Therefore, it is also desirable to provide an apparatus that can simultaneously display a plurality of angles of video.

  Therefore, the present invention has been made in view of the above-described circumstances, and even when images of a plurality of angles recorded on a recording medium are simultaneously or switched, a seamless image can be viewed instantaneously. An object of the present invention is to provide a signal reproducing apparatus and method.

In order to solve the above-described problem, the signal reproduction device according to the present invention includes a reading unit that reads the encoded image data of the plurality of angles from a recording medium on which a video of a plurality of angles is recorded as encoded image data. , a demultiplexer incorporating a plurality pieces of storage means for storing the coded image data read by the reading means, the coded image data output from the plurality of storage means alternately taken into the demultiplexer The encoded image data of a plurality of angles is switched and input for each encoding unit, and includes decoding means for decoding the input encoded image data and generating decoded image data.

In addition, in order to solve the above-described problem, the signal reproduction method according to the present invention reads a plurality of types of encoded image data from a recording medium on which a plurality of angles of video are recorded as encoded image data. And a plurality of stages of storing the encoded image data read in the reading process in a plurality of storage means, and the encoded image data output from the plurality of stages of storage are alternately performed by a demultiplexer. And a decoding step of generating the decoded image data by decoding the input encoded image data and inputting the encoded image data of the plurality of angles captured by the demultiplexer for each encoding unit. And have.

  According to the present invention, a plurality of encoded image data can be decoded and instantaneously switched or simultaneously reproduced at a plurality of angles. For example, even in seamless video reproduction, You can switch to an angle image.

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

  First, a first embodiment is a DVD reproducing apparatus configured to reproduce a DVD (digital video disk: DVD-VIDEO) by applying the signal reproducing apparatus and method according to the present invention.

  Note that a DVD is a recording medium on which an image compression-encoded by MPEG2 (Moving Picture Coding Experts Group 2) is recorded. As data constituting image data, an I-picture consisting of an intra-frame encoded image, A P picture made of an inter-frame forward-predicted encoded image and a B picture made of a bi-directional predictive encoded image are recorded.

  The I picture is encoded image data that can be generated by compressing and encoding one image without performing predictive encoding, and generates an image by decoding only the data itself. The P picture is encoded image data created by predictive encoding from an image in the previous frame. The B picture is encoded image data created by predictive encoding from images in the previous and subsequent frames.

  That is, when decoding, the I picture does not require other encoded image data, and the P picture or B picture requires one or two other encoded image data. Decoding of these encoded image data is performed by a data decoder on the frame memory of the DVD playback apparatus.

  As shown in FIG. 1, the DVD playback apparatus for playing back the DVD is configured by dividing the frame memory 14 used for decoding into three areas. The frame memory 14 includes a display storage area 14a that forms nine storage areas corresponding to display of nine different videos, for example, videos in nine directions, and decoded I and P pictures, ie, decoding. It has a first decoding storage area 14b and a second decoding storage area 14c for storing image data.

  As described above, the I picture or the P picture is stored in the first decoding storage area 14b and the second decoding storage area 14c. For example, when decoding a P picture, the P picture is stored in either the first decoding storage area 14b or the second decoding storage area 14c and stored in the other decoding storage area. Decoding is performed using the decoded image data of the decoded I picture or P picture.

  Then, the decoded image data composed of the I picture or the P picture decoded in the first decoding storage area 14b or the second decoding storage area 14c is subjected to reduction processing and divided in the display storage area 14a. Stored in the designated area.

The display storage area 14a is an area for storing display image data, nine nine areas ₁₄ corresponding to display an image of Ang _a1, 14 _{a2, 14 a3,} 14 a4, _{14 a5,} The decoded image data is divided into 14 _a6 , 14 _a7 , 14 _a8 , and 14 _a9 , and the decoded image data subjected to the reduction process is stored in each area.

  Note that, by reproducing the display image data, for example, the image data in the display storage area 14a is reproduced on the monitor. Further, the mode of the storage area of the display storage area 14a can be arbitrarily selected. In this case, the decoded image data stored in the storage area formed in the selected mode is reproduced as an image in the portion corresponding to the storage area of the display screen such as a monitor by the display screen data.

  For example, in the reproduction by executing the multi-angle function, each of the decoded image data constituting the video of the angle at the same time is stored in each area. For example, the decoded image data relating to the video of the first angle to the ninth angle is allocated and stored in nine areas.

  By providing the frame memory 14 configured in this way, for example, a DVD playback device decodes encoded image data constituting a plurality of angles of video stored on a DVD, and obtains them by decoding them at once. For example, the video can be displayed on each display unit of the monitor.

  Hereinafter, the frame memory 14 will be described in more detail using the DVD playback apparatus 1 configured as shown in FIG.

  As shown in FIG. 2, the DVD reproducing apparatus 1 includes a pickup 2 that reproduces an RF signal from a recording medium (DVD) 100, an RF signal reproduced by the pickup 2, and a binarization process of the RF signal. An RF circuit 3 that performs the decoding, a data decoder 4 that is supplied with the reproduction data from the RF circuit 3 and performs decoding processing such as error correction, and the reproduction data that has been decoded by the data decoder 4 is compressed into main video compression data and sub-video compression And a demultiplexer 5 that distributes the data and the compressed audio data.

  The compressed main video data is composed of encoded image data such as the I picture, P picture, and B picture.

  In addition, the DVD playback apparatus 1 includes the frame memory 14 and decodes the main video compressed data output from the demultiplexer 5, and decodes the sub-video compressed data and combines it with the main video data. A sub-picture decoder 7, an audio decoder 8 that decodes the audio compression data, and video data obtained by synthesizing the sub-picture data and the main picture data from the sub-picture decoder 7 to be supplied and converted into an NTSC signal or a PAL signal. / NTSC, PAL conversion circuit (hereinafter simply referred to as NTSC conversion circuit) 9 and a digital / analog conversion circuit (hereinafter simply referred to as A / D conversion circuit) which is supplied with audio data from the audio decoder 8 and converts it into an analog signal. ) 10.

  Further, the DVD playback apparatus 1 controls the pickup 2, the RF circuit 3, the data decoder 4, the demultiplexer 5, the video decoder 6, the sub-picture decoder 7, the audio decoder 8, the NTSC conversion circuit 9 and the A / D conversion circuit 10. A controller 11, a user interface 12 that mediates the controller 11 and user operation input, and a memory 13 that serves as a data storage unit of the controller 11 are provided.

  Also, the NTSC signal or PAL signal from the NTSC conversion circuit 9 output from the DVD playback apparatus 1 is input to the monitor 200 and imaged.

  As shown in FIG. 14, the recording medium 100 played back by the DVD playback apparatus 1 is recorded in a Video Object Set (hereinafter referred to as VOBS) as a unit of one movie work or the like.

  The VOBS is composed of a plurality of video objects (hereinafter referred to as VOBs). For example, a DVD is configured to have different story development for each VOB corresponding to a multi-story function in which one movie can be viewed in a plurality of story developments. And VOB is comprised by several Cell.

  The cell is a unit of one scene in a movie, for example. That is, the combination for each scene becomes a VOB, and the multi-stream function and the like are configured by the difference in the combination. The Cell is composed of a plurality of Video Object Units (hereinafter referred to as VOBU).

  The VOBU is composed of a plurality of groups of main video compression data, sub-video compression data, and audio compression data. The main video compressed data, sub video compressed data, or audio compressed data is packed and output from the demultiplexer 5 into a main video pack (V_PCK), sub video pack (SP_PCK), or audio pack (A_PCK), as will be described later. The

  The main video compressed data is data that becomes the main video of a movie, and constitutes a video stream in the DVD format. The sub-picture compressed data is data such as subtitles and constitutes a sub-picture stream in the DVD format. The audio compression data is data relating to audio, and constitutes an audio stream in the DVD format.

  Here, GOP (Group of Picture) in the MPEG2 system is an angle block in which video data of each angle is segmented on a DVD, adopts an interleave structure, and is recorded on the DVD by mixing the angle blocks. Yes. The GOP is recorded by adopting an interleave structure in 1 VOBU, for example. As shown in FIG. 15, one GOP is usually composed of an I picture, a P picture, and a B picture, and the I picture, the P picture, and the B picture are configured to be 15 in total.

  The recording medium (DVD) 100 on which data is recorded in the above format is read by the pickup 2 provided in the DVD playback apparatus 1.

  The pickup 2 irradiates the signal recording surface of the recording medium 100 with laser light from a laser light source incorporated in the pickup 2 and receives the reflected light reflected on the signal recording surface. The pickup 2 supplies an RF signal reproduced according to the received light to the RF circuit 3.

  The RF circuit 3 performs waveform equalization and binarization of the RF signal to generate reproduction data and its synchronization signal. Digital data and the like generated by the RF circuit 3 are supplied to the data decoder 4.

  The data decoder 4 performs processing such as data demodulation and error correction based on the reproduction data generated by the RF circuit 3. The digital data demodulated by the data decoder 4 is supplied to the demultiplexer 5.

  Here, the digital data includes main video compression data. Therefore, the encoded image data is read from the recording medium 100 by the pickup 2, the RF circuit 3, and the data decoder 4.

  The demultiplexer 5 divides digital data reproduced from the recording medium 100 that has been subjected to error correction decoding processing by the data decoder 4 into various packs, that is, a main video pack, a sub video pack, or an audio pack. Each pack is output to each decoder.

  A track buffer is provided between the demultiplexer 5 and the data decoder 4 in order to absorb the processing speed of the demultiplexer 5 and the data decoder 4.

  The demultiplexer 5 supplies the main video pack composed of the main video compression data to the video decoder 6, supplies the sub video pack composed of the sub video compression pack to the sub video decoder 7, and converts the audio pack composed of the audio compression pack into the audio decoder. 8 is supplied.

  The video decoder 6 performs a decoding process on the main video compressed data in the supplied main video pack, and generates main video data expanded by the decoding process. Here, the main video data is decoded image data which is a decoded I picture, P picture, and B picture. The video decoder 6 has the frame memory 14 described above for performing decoding processing.

Here, regarding the decoding process performed by the video decoder 6 using the frame memory 14, for example, the ninth multi-angle video I picture or I picture and P in the VOBU configured to be able to execute the multi-angle function, for example. A case where a picture is decoded and forward reproduction is performed will be described. Note that the decoding of the I picture will be described in the case where the first VOBU and the I picture I2 in the _second VOBU are sequentially decoded. The decoding process of the I picture and P picture will be described in the case where the I picture I ₂ , P picture P ₅ , and P picture P ₈ in the first VOBU are sequentially decoded.

When decoding only the I picture, the video decoder 6 decodes the I picture I ₂ included in the input main video compressed data as shown in FIG. Is stored in the decoding storage area 14b. The video decoder 6 performs decoding of the I picture I ₂ while rewriting it on the first decoding storage area 14b, for example.

After decoding, the video decoder 6, as shown in FIG. 3 (b), is subjected to reduction processing to the I picture I ₂ decoded, the the region 14 _a9 of the display of the ninth angle in the display storage area 14a The decoded I picture I ₂ subjected to the reduction process is copied.

The stored I picture I ₂ reduced in the display storage area 14 a is displayed as an image on the divided display section of the monitor 200 via the sub-picture decoder 7 and the NTSC conversion circuit 9.

The DVD playback device 1 displays the image generated by the decoded I picture I _2, while the next I picture is stored in the first decoding storage area 14 b of the frame memory 14 as shown in FIG. In other words, the I picture I ₂ recorded in the second VOBU is stored. Here, the video decoder 6, in the same manner as was carried out in I picture _{I 2} in the first VOBU, the second by decoding the I picture _{I 2} in VOBU, subjected to subsequent reduction processing, display storage area 14a To copy.

The I picture I ₂ of the _second VOBU that has been reduced and copied to the display storage area 14 a is displayed on the monitor 200 as the next image of the I picture I ₂ of the first VOBU. Specifically, the decoded image data (main video data) obtained by decoding in the video decoder 6 as described above is supplied to the sub-video decoder 7.

  The sub-picture decoder 7 decodes the sub-picture compressed data in the supplied sub-picture pack, synthesizes the decoded sub-picture data with the main picture data supplied from the video decoder 6, and outputs the picture. Generate data. That is, the sub video decoder 7 synthesizes subtitle data and the like reproduced as sub video data with the main video data. The sub video decoder 7 outputs the main video data as it is as video data when there is no sub video data. The sub video decoder 7 supplies the generated video data to the NTSC conversion circuit 9.

  The NTSC conversion circuit 9 converts the video data from digital data into a television signal such as NTSC or PAL. The television signal from the NTSC conversion circuit 9 is displayed as an image on the monitor 200.

The television signal input to the monitor 200 includes the I picture I ₂ decoded by the video decoder 6. Further, the monitor 200 divides and displays nine display screens corresponding to a plurality of divided storage areas of the display storage area 14 a of the frame memory 14. Here, the division display follows, for example, the division mode of the display storage area. Thus, the display screen of the monitor 200 to display one formed by being divided, the video based on the I picture I ₂ is displayed.

  Note that the audio decoder 8 performs a decoding process on the compressed audio data in the audio pack, and generates decompressed audio data. In other words, if the audio data is compressed by the MPEG2 system, the audio decoder 8 performs decompression processing corresponding to this and generates audio compression data. In addition to the MPEG2 format, the audio decoder 8 performs processing corresponding to the linear PCM or Dolby AC3 format. The audio decoder 8 supplies the generated audio data to the A / D conversion circuit 10.

  The A / D conversion circuit 10 converts audio data that is digital data into analog audio data and outputs the analog audio data. By supplying this output to a speaker or the like, the user can view the video reproduced from the recording medium 100.

  The controller 11 controls the pickup 2, RF circuit 3, data decoder 4, demultiplexer 5, video decoder 6, sub-picture decoder 7, audio decoder 8, NTSC conversion circuit 9 and A / D conversion circuit 10. The controller 11 receives an operation input via an operation panel or a user interface 12 which is a remote controller, and controls each circuit based on the operation input.

  The controller 11 performs write control and read control in the frame memory 14 via the video decoder 6. That is, the controller 11 is formed for the reduction process of the decoded image data stored in the decoding storage area of the frame memory 14 and the one decoded image data subjected to the reduction process for the divided display of the display storage area 14a. Write control is performed in one storage area. Then, the controller 11 performs read control for reading the decoded image data stored in the display storage area 14a.

  The decoded image data is read from the display storage area 14a by reading the display image data in units of the display storage area 14a. With the display image data, an image based on the decoded image data stored in the one storage image corresponding to the storage area 200 is displayed at a display position corresponding to the storage area of the monitor.

  Therefore, by performing the same decoding and reduction processing on the 9th angle I-picture on the 1st to 8th I-pictures, the DVD player 1 can The first to eighth angle images at the same time as the angle image can be simultaneously displayed on the monitor 200. In this case, for example, as shown in FIGS. 5A to 5D, decoding of the encoded image data constituting the image of each angle is performed using the first angle image (200a) and the second angle image. The image (200b),..., The ninth angle image (200i), and the first angle image (200a) are generated.

  If only the I picture is decoded, the frame memory 14 only needs to include at least one decoding storage area as described above.

In the case of decoding the I picture and the P picture, the video decoder 6 first decodes the input I picture I _{2 and} decodes the first decoding of the frame memory 14 as shown in FIG. It is stored in the storage area 14b.

After decoding, the video decoder 6, as shown in FIG. 4 (b), is subjected to reduction processing to the I picture I ₂ decoded, the the region 14 _a9 of the display of the ninth angle in the display storage area 14a The decoded I picture I ₂ subjected to the reduction process is copied.

The image generated by the I picture I ₂ that has been reduced and stored in the display storage area 14 a is displayed on one display unit of the monitor 200 corresponding to the display storage area 14 a of the frame memory 14.

On the other hand, as shown in FIG. 4C, the video decoder 6 predicts the next input P picture P ₅ by the decoded I picture I ₂ stored in the first decoding storage area 14b. The data is decoded and stored in the second decoding storage area 14c.

After storing the P picture P ₅ after decoding in the second decoding storage area 14c, the video decoder 6, as shown in FIG. 4 (d), it is subjected to reduction processing in the P-picture P ₅ decoded, display copying P picture _{P 5} after decoding which has been subjected to the reduction process in the region _{14 a9} of the use memory area 14a.

The image generated by the P picture P ₅ reduced and stored in the display storage area 14 a is displayed as the next image of the I picture I ₂ displayed on the one display unit of the monitor 200. .

In decoding P picture P _8, the video decoder 6, as shown in FIG. 4 (e), the P-picture P ₈ next entered, stored in the second decoding storage area 14c and decoding by predicting a P-picture P ₅ after decoding is stored in the first decoding storage area 14b.

After storing the P picture P ₈ after decoding the first decoded memory area 14b, the video decoder 6, as shown in FIG. 4 (f), is subjected to reduction processing in the P-picture P ₈ decoded, display copying use storage area P picture _{P 8} after decoding which has been subjected to the reduction process in the region _{14 a9} of 14a.

The image generated by the P picture P ₈ reduced and stored in the display storage area 14 a is displayed as the next image of the P picture P ₅ displayed on the one display unit of the monitor 200. .

  Therefore, images based on the decoded I picture and P picture are displayed one after another on the one display section of the monitor 200.

  The DVD playback apparatus 1 performs the above-described decoding and reduction processing, which has been performed on the ninth angle I picture and P picture, similarly on the first to eighth angle I pictures and P picture. The first to eighth angle images at the same time as the ninth angle image can be displayed on the corresponding display units of the monitor 200.

  The forward reproduction performed by decoding only the I picture or the I picture and the P picture described above is applied, for example, when high-speed reproduction is executed. If normal playback is performed, a decoding storage area may be further provided in the frame memory 14.

  Further, the DVD playback apparatus 1 can also perform reverse playback, and can display the first to ninth angles of the same time on the monitor 200 as described above. For example, in the reverse playback using the I picture, the I picture in the GOP is decoded such that the I picture in the n-th VOBU is decoded after decoding the I-picture in the n-th VOBU. Do it.

In reverse playback using an I picture and a P picture, the I picture is first decoded in the first decoding storage area 14b, and then the P picture is decoded in the second decoding storage area. Do. For example, the I picture I ₂ is decoded in the first decoding storage area 14c, and the P picture P ₅ in the same VOBU is decoded in the second decoding storage area 14c based on the decoded I picture I _2. In this way, the decoding process is performed, and the reverse display is performed by reversing the display on the monitor 200 from the decoding order, that is, by reproducing in the order of P picture P ₅ and I picture I ₂ .

  Next, with respect to the frame memory 14 configured so that the DVD playback apparatus 1 can perform backward playback, for example, a case of decoding an I picture and a P picture constituting a ninth angle video will be described.

  As shown in FIG. 6, the frame memory 14 configured to be able to reproduce in the reverse direction stores a display storage area 14a forming nine storage areas, and a first decoded image data after decoding an I picture or P picture. Decoding storage area 14b, second decoding storage area 14c, and third decoding storage area 14d.

  That is, when applied to backward reproduction, the frame memory 14 is further provided with a third decoding storage area 14d.

When playing backward, as shown in FIG. 7 (a), decodes the I picture I ₂ that is input is stored in the first decoded memory area 14b of the frame memory 14.

Thereafter, the video decoder 6, as shown in FIG. 7 (b), the P picture P ₅ that was then entered, with I picture I ₂ after decoding stored in the first decoded memory area 14b The data is decoded by prediction and stored in the second decoding storage area 14c.

Thereafter, the video decoder 6, as shown in FIG. 7 (c), use the P-picture P ₈ next entered, the P picture P ₅ after decoding stored in the second decoding storage area 14c Is decoded by the predicted data and stored in the third decoding storage area 14d.

Then, the decrypted data is copied to the display storage area 14a in the reverse order of the decryption process. That is, as shown in FIG. 7 (d), first the third is subjected to reduction processing in the P-picture P ₈ after decoding stored in the decoding memory area 14d, a ninth angle in the display storage area 14a copying P picture P ₈ after decoding which has been subjected to the reduction process in the region 14 _a9 of the display of.

Next, as shown in FIG. 7 (e), is subjected to reduction processing in the second after decoding stored in the decoding memory area 14c P-picture P _5, the region 14 _a9 of the display storage area 14a copying P picture P ₅ after decoding which has been subjected to the reduction process.

Then, as shown in FIG. 7 (f), the decoded I picture I ₂ stored in the first decoding storage area 14 b is reduced, and the area 14 a ₉ in the display storage area 14 a The decoded I picture I ₂ subjected to the reduction process is copied.

As described above, by sequentially copying the P picture P ₈ , the P picture P ₅ , and the I picture I ₂ to the area 14 a ₉ of the display storage area 14 a, the DVD _player 1 can monitor the monitor corresponding to the area 14 a _9. Images of P picture P ₈ , P picture P ₅ , and I picture I ₂ can be sequentially displayed on one display unit 200.

  Note that the reverse reproduction performed by decoding only the I picture and the P picture described above is applied when, for example, high-speed reverse reproduction is executed. In addition, if normal reverse playback is performed, one decoding storage area may be provided in the frame memory 14.

  The above is a description of the frame memory 14 configured to be performed by decoding only the I picture or the I picture and the P picture, and the case of performing reverse reproduction using the frame memory 14.

  Since the DVD playback apparatus 1 includes the frame memory 14 configured as described above, it is possible to simultaneously display videos of a plurality of angles at the same time during forward playback and backward playback.

  As a result, for example, it is possible to solve the problem of missing a video of another angle at the moment of switching, which has been a problem in seamless video switching. For example, the viewer can see a seamless video and can also watch videos of other angles he wants to watch at the same time.

  Note that the video of the angle to be reproduced may be a non-seamless video as well as a seamless video.

  In addition, the video of each angle is configured in units of, for example, 1 VOBU, and the video of each angle of the video at the same time has an attribute between VOBUs. That is, the DVD playback device 1 decodes the pictures in each of the associated VOBUs when playing back video of each angle.

  However, the present invention is not limited to this. For example, when decoding a picture of a video of another angle at the time of forward playback, the DVD playback apparatus 1 displays the video of the other angle of the VOBU belonging to the next time. It is also possible to decode the constituent pictures. Also, the DVD playback device 1 decodes the pictures constituting the images of the other angles of the VOBU belonging to the true time when decoding the video of other angles at the time of reverse playback. You can also.

  Next, a second embodiment will be described. The second embodiment is a DVD reproducing apparatus configured to reproduce a DVD by applying the signal reproducing apparatus and method according to the present invention.

  Note that the DVD is configured in a data format having a multi-angle function as in the first embodiment. That is, the DVD employs the MPEG2 system, and video is compressed and recorded as an I picture, P picture, and B picture. Hereinafter, a case where a DVD in which videos of two different angles are recorded will be described.

  As shown in FIG. 8, the DVD playback apparatus includes two video decoders, and switches the output of decoded image data obtained by decoding with the two video decoders, and outputs it to a subsequent circuit.

  Specifically, the DVD reproducing apparatus 1 includes a pickup 2 that reproduces an RF signal from the recording medium 100, an RF signal reproduced by the pickup 2, and an RF circuit 3 that performs binarization processing on the RF signal. Digital data output from the data decoder 4 is provided with a data decoder 4 that is supplied with reproduction data from the circuit 3 and performs decoding processing such as error correction, and a first storage area 21a and a second storage area 21b. And a demultiplexer 5 that distributes the digital data decoded by the data decoder 4 into main video compressed data, sub-video compressed data, and audio compressed data.

  Also, the DVD playback apparatus 1 decodes the main video data by decoding the first video decoder 22 and the second video decoder 23 that decode the main video compressed data output from the demultiplexer 5, and the sub video compressed data. And sub-picture decoder 7 for synthesizing, audio decoder 8 for decoding the compressed audio data, and video data obtained by synthesizing sub-video data and main video data from sub-picture decoder 7 are supplied and converted to an NTSC signal or a PAL signal. A digital / NTSC, PAL conversion circuit (hereinafter simply referred to as NTSC conversion circuit) 9 and a digital / analog conversion circuit (hereinafter simply referred to as A / D conversion circuit) which is supplied with audio data from the audio decoder 8 and converts it into an analog signal. And 10).

  Further, the DVD player 1 includes a pickup 2, an RF circuit 3, a data decoder 4, a demultiplexer 5, a first video decoder 22, a second video decoder 23, a changeover switch 24, a sub-picture decoder 7, an audio decoder 8, A controller 11 that controls the NTSC conversion circuit 9 and the A / D conversion circuit 10, a user interface 12 that mediates the operation input of the controller 11 and the user, and a memory 13 that is a data storage unit of the controller 11 are provided.

  The pickup 2 that reproduces the RF signal from the recording medium 100, the RF circuit 3 that performs signal processing of the RF signal, and the data decoder 4 that decodes the reproduction data that has been signal-processed by the RF circuit 3, each have a normal processing speed. For example, it is configured so that it can be doubled. Here, the normal processing refers to processing performed when, for example, one angle of video is read from the recording medium 100.

  The demultiplexer 5 is also configured so that the data processing speed can be double that of normal processing. Thereby, the demultiplexer 5 can perform the distribution of the input main video compressed data, sub-video compressed data, and audio compressed data without different from the normal processing.

  Hereinafter, components of the DVD reproducing apparatus 1 will be described. Note that portions described in the DVD playback apparatus 1 according to the first embodiment are denoted by the same reference numerals as those in FIG. 2, and description thereof is omitted.

  The DVD playback device 1 inputs encoded image data and the like recorded on the recording medium 100 to the track buffer 21 via the pickup 2, the RF circuit 3 and the data decoder 4.

  The track buffer 21 has two storage areas, a first storage area 21a and a second storage area 21b. The track buffer 21 stores the digital data input to each storage area. Here, the digital data includes main video compression data, sub-video compression data, and audio compression data divided by the demultiplexer 5 as described above.

  The track buffer 21 absorbs the difference in processing speed between the data decoder 4 and the demultiplexer 5. Then, the track buffer 4 outputs digital data to the demultiplexer 5 in accordance with a transfer command from the demultiplexer 5.

  As described above, the demultiplexer 5 has a processing speed that is twice the normal processing speed. The demultiplexer 5 alternately captures the digital data output from each of the storage areas of the track buffer 21, divides the captured digital data into main video compressed data, sub video compressed data, and audio compressed data, and the first The data is output to the video decoder 22 or the second video decoder 23, the sub-picture decoder 7 and the audio decoder 8.

  The main video compression data output to the first video decoder 22 and the second video decoder 23 is so-called encoded image data, and is data composed of so-called I picture, P picture, and B picture. The output is performed on each video decoder 6 so as to be, for example, 1 GOP unit. The main video compressed data, sub-video compressed data, and audio compressed data are packed and supplied to each decoder provided at the subsequent stage of the demultiplexer 5.

  Note that each of the first video decoder 22 and the second video decoder 23 has a frame memory including three decoding storage areas for decoding an I picture, a P picture, and a B picture.

  The first video decoder 22 and the second video decoder 23 decode input encoded image data. The decoding process performed here is performed by inter-frame prediction. The decoded image data decoded by the first video decoder 22 and the second video decoder 23 is input to the changeover switch 24.

  The changeover switch 24 supplies one of the decoded image data from the first video decoder 22 or the second video decoder 23 to the sub-picture decoder 7 at the subsequent stage. Switching of the changeover switch 24 is performed by the controller 11.

  For example, when a switching command is received during the output of the decoded image data from the first video decoder 21, the changeover switch 24 converts the output data to the decoded image data from the second video decoder 23 by the switching operation. Switch. Therefore, the encoded image data decoded by the first video decoder 22 and the second video decoder 23 is instantaneously switched by the selector switch 24 so that either one is output. For example, such switching is performed at the time of switching of an angle image.

  The decoded image data output via the changeover switch 24 is displayed as an image on the monitor 200 via the sub-picture decoder 7 and the NTSC conversion circuit 9.

  Therefore, the DVD playback apparatus 1 according to the second embodiment can instantaneously switch to another angle during playback of the video of one angle, so that another angle at the moment of the switching is reproduced. Can be displayed on the monitor 200.

  With this DVD playback device 1, for example, the viewer does not miss a video of another angle that he / she wants to watch when switching to a video of another angle.

  The video of the angle here may be not only a seamless video but also a non-seamless video, and the DVD playback apparatus 1 can instantaneously switch and play back regardless of the type of these videos.

  Even if the video is switched to the video of the other angle, for example, the video data of the video of the one angle is used as the sub video data and the audio data. That is, the sub-video data and audio data of the video at the other angles are not output from the demultiplexer 5 and are not decoded.

  Further, when there is a difference in bit rate between the encoded image data input to the first video decoder 22 and the encoded image data input to the second video decoder 23, the demultiplexer 5 and the first video decoder The controller 11 monitors, for example, the empty area of the video buffer (not shown) provided between the two and the empty capacity of the video buffer (not shown) provided between the demultiplexer 5 and the second video decoder 23. Then, data may be sent from the demultiplexer 5 to a video buffer having an empty area. Each video buffer is a buffer that absorbs the difference between the distribution processing speed of the demultiplexer 5 and the processing speed of each video decoder decoding. That is, when this buffer is used and one buffer is full, data is sent to another buffer to absorb the bit rate difference.

  Further, as shown in FIG. 9, the DVD playback apparatus 1 according to the second embodiment includes a video decoder 26 having a processing speed twice the normal processing speed, and between the demultiplexer 5 and the video decoder 26. It is also possible to provide a change-over switch 25 provided in FIG.

  The changeover switch 25 outputs the encoded image data from the demultiplexer 5 to the video decoder 26 in units of 1 GOP, for example. Switching of the changeover switch 25 is performed by the controller 11.

  For example, when a switching command is issued during output of encoded image data corresponding to a video of one angle, the changeover switch 25 outputs encoded image data corresponding to a video of another angle. Therefore, by the switching operation of the changeover switch 25, either the encoded image data corresponding to the video of one angle or the encoded image data corresponding to the video of the other angle is output.

  The video decoder 26 can decode the encoded image data from the changeover switch 25 at twice the normal processing speed. The decoded compressed data obtained by decoding by the video decoder 26 is displayed as an image on the monitor 200 via the sub video decoder 7, the sub video decoder 7 and the NTSC conversion circuit 9.

  Therefore, even if the changeover switch 25 and the video decoder 26 having the double decoding process are provided, the DVD playback apparatus 1 can switch the video angle instantaneously and seamlessly.

  Next, a third embodiment will be described. The third embodiment is a DVD reproducing apparatus configured to reproduce a DVD by applying the signal reproducing apparatus and method according to the present invention.

  The DVD reproducing apparatus according to the third embodiment is configured to simultaneously reproduce a plurality of angles of video. Therefore, as shown in FIG. 10, the DVD reproducing apparatus includes a first video decoder 23 and a second video decoder 24 to which main video compressed data from the demultiplexer 5 is input, and the first video decoder. And a mixing circuit 27 for mixing the decoded image data output from the second video decoder 23 and the second video decoder 23, respectively.

  That is, the DVD playback apparatus 1 according to the third embodiment adopts a configuration including a mixing circuit 27 instead of the changeover switch 24 in the DVD playback apparatus 1 used as the second embodiment.

  The DVD reproducing apparatus 1 configured in this way monitors the mixed image 27 output from the first video decoder 22 and the decoded image data output from the second video decoder 23 by the mixing circuit 27. 200 can be supplied.

  For example, when the decoded video data constituting the first angle video is output from the first video decoder 22 and the decoded video data constituting the first angle video is output from the second video decoder 23, As shown in FIGS. 12A to 12B, the first angle image (shown in FIG. 12A) and the second angle image (shown in FIG. 12B). Can be displayed simultaneously (shown in FIG. 12C).

  As shown in FIG. 12C, if the first angle image and the second angle image are not overlapped on the screen of the monitor 200, the DVD playback device 1 is the first player. The video decoder 23 and the second video decoder 24 can share a frame memory composed of three decoding storage areas.

  Further, since each of the first video decoder 22 and the second video decoder 23 includes a frame memory, as shown in FIGS. 13A to 13B, an image of the first angle (FIG. 13). (Shown in (a)) is displayed using the entire display screen of the monitor 200, and an image of the second angle (shown in FIG. 13B) is displayed using a part of the display screen of the monitor 200 (FIG. 13 (FIG. 13). c)).

  Also, the DVD playback apparatus 1 can decode I-pictures, P-pictures, and B-pictures by using a frame memory composed of three decoding storage areas, thereby enabling normal playback.

  Therefore, the DVD playback apparatus 1 can normally play back videos of two different angles at the same time as when two video decoders are provided as described above, and the two videos played back at different angles at the same time. Can be displayed on the monitor 200.

  Next, a fourth embodiment will be described. The fourth embodiment is a DVD reproducing apparatus configured to reproduce a DVD by applying the signal reproducing apparatus and method according to the present invention.

  The DVD playback apparatus according to the fourth embodiment is configured to be able to simultaneously play back images of a plurality of angles and to switch the images of the angle being played seamlessly and instantaneously. . Therefore, as shown in FIG. 11, the DVD reproducing apparatus includes a first video decoder 22 and a second video decoder 23 to which the main video compressed data from the demultiplexer 5 is input, and the first video decoder. The mixing circuit 27 that mixes the decoded image data output from the video decoder 22 and the second video decoder 23 and the transmission of the decoded image data output from the first video decoder 22 to the mixing circuit 27 are turned on and off. A switch 28 and a switch 29 that turns on and off the transmission of decoded image data output from the second video decoder 23 to the mixing circuit 27 are provided.

  In the DVD reproducing apparatus 1 configured as described above, the decoded image data output from the first video decoder 22 and the second video decoder 23 are output by the mixing circuit 27 when the switch 28 and the switch 29 are turned on. The decoded image data can be mixed and supplied to the monitor 200. For example, the DVD playback device 1 can supply the monitor 200 so that the mixed video is displayed in FIGS. 12C and 13C.

  Furthermore, the DVD playback apparatus 1 can also decode the encoded image data by switching the first video decoder 22 and the second video decoder 23 by turning on and off the switch 28 and the switch 29. In this case, the switch 29 is turned off when the switch 28 is on, and the switch 29 is turned on when the switch 28 is off.

  For example, when a switching command is issued during the output of decoded image data constituting one angle video from the first video decoder 22, the switch 28 is turned off while the switch 29 is turned on. Thus, the second video decoder 23 can output the decoded image data constituting the video of another angle. That is, one of the image pressure encoded data decoded by the first video decoder 22 and the second video decoder 23 is instantaneously switched and output.

  Therefore, the DVD playback apparatus 1 can instantaneously switch to another angle video during playback of the video of one angle, and display the video of the other angle switched on the monitor 200. .

  From the above, the DVD playback apparatus 1 according to the fourth embodiment can simultaneously play a plurality of angles, and can instantaneously switch to a video of another angle even if it is a seamless video.

  With this DVD playback device 1, for example, the viewer can watch videos of other angles at the same time, and even when he wants to watch other angles by switching operation, he / she misses the video of the desired angle when switching. Disappears.

  The DVD playback apparatus 1 according to the second to fourth embodiments has been described by taking the playback of a DVD on which two angles of video are recorded as an example, but three or more, for example, videos of a plurality of m angles. Can be played back. In this case, the DVD playback apparatus 1 configures each unit so that the processing speed of 2 and 2 times becomes m and the processing speed of m times, respectively.

  The configurations and functions and effects of some embodiments of the signal reproducing apparatus and method according to the present invention described above are summarized as follows.

  That is, first, in the embodiment of the signal reproduction device according to the present invention, the decoding means for decoding the encoded image data of one angle among the plurality of angles read by the reading means to generate the decoded image data of the plurality of angles. And a storage unit for decoding that stores decoded image data of one angle among a plurality of angles generated by the decoding unit, and a storage unit for display in which a storage area for storing and displaying the display image data is formed. And reducing the decoded image data stored in the decoding storage means, writing the reduced decoded image data in the storage area of the display storage means, and storing the decoded image data written in the storage area. And a control means for reading out the display image data included, thereby simultaneously playing back images of a plurality of angles composed of the encoded image data. Can.

  Therefore, for example, the signal reproduction apparatus can provide a video at the same time regardless of whether or not it is non-seamless, and the viewer does not miss the video he / she wants to watch.

  Here, at least one decoding storage unit is provided, and the intra-frame encoded image data of the encoded image data is decoded by using the one decoding storage unit and recorded on the recording medium. For example, the multi-angle video can be reproduced. Further, at least two decoding storage units are provided, and the inter-frame forward encoded image data of the encoded image data is decoded using the two decoding storage units and recorded on the recording medium. The above-mentioned multi-angle video can be reproduced. Further, at least three decoding storage means are provided, and the inter-frame forward encoded image data of the encoded image data is decoded using the three decoding storage means and recorded on the recording medium. The above-mentioned multi-angle video can be reproduced in the reverse direction.

  Next, an embodiment of the signal reproduction device according to the present invention includes m storage means for storing encoded image data read by the reading means, and the encoded image data output from the m storage means. By providing decoding means for decoding and generating decoded image data, it is possible to decode a plurality of encoded image data and reproduce video of a plurality of angles by switching instantaneously or simultaneously.

  The signal reproduction apparatus can instantaneously switch to a video of another angle even in seamless video reproduction, for example.

  Furthermore, in order to solve the above-mentioned problem, the embodiment of the signal reproduction method according to the present invention decodes the encoded image data of one angle among the plurality of angles read out in the reading step to decode the plurality of angles. A display step in which a decoding step for generating image data, a decoded image data storage step for storing decoded image data of one angle among a plurality of angles generated by the decoding step, and a storage area for divided display are formed. A display storage step for storing data, and the decoded image data stored in the decoded image data storage step is reduced, and the reduced decoded image data is stored in the storage area of the display storage step. And a control step of reading display image data including the decoded image data written in the storage area. Data makes it possible to reproduce an image of a plurality of angles including simultaneously.

  Therefore, according to the signal reproduction method, for example, it is possible to simultaneously provide video regardless of whether or not it is non-seamless, and the viewer does not miss the video he / she wants to watch.

  In addition, in order to solve the above-described problem, the embodiment of the signal reproduction method according to the present invention outputs an m-stage storage process for storing the encoded image data read in the read process and an m-stage storage process. A decoding step of decoding the encoded image data and generating decoded image data, thereby decoding a plurality of encoded image data and instantaneously switching or simultaneously reproducing a plurality of angles of video be able to.

  According to the signal reproduction method, for example, even in seamless video reproduction, it is possible to instantaneously switch to another angle video.

  It should be noted that the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention.

It is a block diagram which shows the frame memory with which the DVD reproduction apparatus used as the 1st Embodiment of this invention is provided. It is a circuit diagram which shows the said DVD reproduction apparatus. In the frame memory, when decoding encoded image data, it is a block diagram showing how I picture is particularly decoded. In the frame memory, when decoding encoded image data, it is a block diagram showing how I picture and P picture are decoded in particular. It is a top view which shows the monitor used for description of the procedure which decodes encoding image data. It is a block diagram which shows the said frame memory comprised for reverse reproduction. FIG. 5 is a block diagram showing a state of decoding I picture and B picture in particular when decoding encoded image data in the frame memory configured for reverse reproduction. It is a circuit diagram which shows the DVD reproducing | regenerating apparatus which becomes the 2nd Embodiment of this invention. It is a circuit diagram which shows the case where the principal part of the DVD reproducing apparatus used as the second embodiment is changed. It is a circuit diagram which shows the principal part structure of the DVD reproducing | regenerating apparatus used as the 3rd Embodiment of this invention. It is a circuit diagram which shows the principal part structure of the DVD reproducing | regenerating apparatus used as the 4th Embodiment of this invention. It is a top view which shows the monitor on which the image of several angles is displayed. It is a top view which shows the monitor in which the image of several angles is displayed by the other display method. It is a data format which shows DVD reproduced | regenerated by the DVD reproduction apparatus used as the said 1st thru | or 4th embodiment. It is a data format indicating a GOP recorded on the DVD.

Explanation of symbols

  1 signal reproduction device, 2 pickup, 3 RF circuit, 4 data decoder, 5 demultiplexer, 14 frame memory, 14a display storage area, 14b first decoding storage area, 14c second decoding storage area, 14d first 3 decoding storage area, 21 track buffer, 22 first video decoder, 23 second video decoder, 24 changeover switch, 25 changeover switch, 26 video decoder, 27 mixing circuit, 28 switch, 29 switch

Claims (3)

Reading means for reading out the encoded image data of the plurality of angles from a recording medium in which video images of a plurality of angles are recorded as encoded image data;
A plurality of storage means for storing the encoded image data read by the reading means;
A demultiplexer that alternately captures the encoded image data output from the plurality of storage means;
Decoding means for decoding the input encoded image data and generating decoded image data by switching the multi-angle encoded image data fetched by the demultiplexer to be input for each encoding unit. Playback device. 2. The signal reproducing apparatus according to claim 1, wherein the demultiplexer and the decoding means have a data processing speed that is a multiple of the decoding processing speed when the video for one angle is read . A reading step of reading out a plurality of types of encoded image data from a recording medium on which video images of a plurality of angles are recorded as encoded image data;
A plurality of storage steps for storing the encoded image data read in the reading step in a plurality of storage means;
A step of alternately capturing the encoded image data output from the plurality of stages of storage steps by a demultiplexer;
The decoding step of decoding the input encoded image data and generating the decoded image data by switching the encoded image data of the plurality of angles fetched by the demultiplexer and being input for each encoding unit. Playback method.

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