JP2011250256A - Video playback device and video playback method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a video playback device and a video playback method that can smoothly playback a video from a switched angle after starting a process for switching an angle without increasing the cost therefor.SOLUTION: If any decoding process of sub video data needs not be performed at a second decode unit 240, a first decode unit 220 performs a decoding process of main video data from one angle simultaneously while the second decode unit 240 performs a decoding process of the main video data from another angle. On switching the angle, the main video data decoded by the first decode unit 220 and that decoded by the second decode unit 240 are switched and displayed. Thus, any process for decoding the main video data of a switched angle after starting a process for switching an angle as well as any new proprietary video decoder are not necessary.

Description

  The present invention relates to a video playback device and a video playback method, and is suitable for use in, for example, a video playback device having a function (multi-angle playback function) for selectively playing back video shot from different angles.

  Video playback devices such as DVD and Blu-ray Disc (registered trademark), which are optical disc standards, are provided with a multi-angle playback function as one of various functions. This multi-angle playback function is a function that allows a user to select a desired angle from a plurality of angles in a scene of simultaneous progress, and to play a video of the selected angle.

  The multi-angle playback function includes seamless angle switching and non-seamless angle switching (see, for example, Patent Document 1). In seamless angle switching, a point at which the angle can be switched (angle change point) is determined in advance, and the process of switching the angle is started after the video of the original angle is reproduced to that point. However, after starting the process of switching the angle, actually, it takes about several seconds to decode the main video data of the switching destination angle. For this reason, after starting the process of switching the angle, there has been a problem that it is not possible to smoothly reproduce the video of the switching destination angle. This will be described using an example with reference to FIG.

  FIG. 8 is a diagram illustrating an example of seamless angle switching. FIG. 8 shows a state in which source packets constituting main video data of a plurality of angles (angles 1 to N) are arranged in time series. As shown in FIG. 8, the main video data of angle 1 includes source packets in which angle change point A and angle change point B are set. The main video data of angle 2 includes a source packet in which an angle change point C is set. The main video data of the angle N includes a source packet in which the angle change point D and the angle change point E are set.

  In FIG. 8, first, it is assumed that main video data of angle 1 is being reproduced. Next, it is assumed that an angle switching operation for switching the main video data from the angle 1 to the angle 2 is performed by the user at time (a). In this case, after the main video data of angle 1 is reproduced up to the angle change point C (time (b)) of the main video data of angle 2, the process of switching the angle is started. Furthermore, it takes about several seconds from the start of the process of switching the angle 1 to the time (c) when the decoding process of the main video data of the switching destination angle 2 is completed. For this reason, after the process of switching the angle 1 is started, the video of the switching destination angle 2 cannot be smoothly reproduced. It should be noted that nothing is played back while the main video data of angle 2 is being decoded (that is, from time (b) to (c)).

  Next, it is assumed that an angle switching operation for switching the main video data from the angle 2 to the angle N is performed by the user at time (d). In this case, after the main video data of angle 2 is reproduced until the angle change point E (time (e)) of the main video data of angle N, the process of switching the angle is started. Further, it takes about several seconds from the start of the process of switching the angle 2 to the time (f) when the decoding process of the main video data of the angle N to be switched to is completed. For this reason, after the process of switching the angle 2 is started, the video of the switching destination angle N cannot be smoothly reproduced. It should be noted that nothing is played back while the main video data of angle N is being decoded (that is, from time (e) to (f)).

  On the other hand, in non-seamless angle switching, an angle change point is not determined. Therefore, it is possible to immediately start the process of switching the angle when an operation for switching the angle is performed. However, even if the processing for switching the angle is started immediately, it takes about several seconds to actually decode the main video data of the switching destination angle. A still image is reproduced during the decoding process. In other words, even with non-seamless angle switching, there has been a problem that it is not possible to smoothly play back the video at the switching destination angle after starting the process of switching the angle. This will be described using an example with reference to FIG.

  FIG. 9 is a diagram illustrating an example of non-seamless angle switching. FIG. 9 shows a state in which source packets constituting main video data of a plurality of angles (angles 1 to N) are arranged in time series. As shown in FIG. 9, unlike the case of seamless angle switching, no angle change point is set in the main video data of angles 1 to N. Therefore, it is possible to start the process of switching the angle immediately after performing the operation for switching the angle.

  In FIG. 9, first, assume that main video data of angle 1 is being reproduced. Next, it is assumed that an angle switching operation for switching the main video data from the angle 1 to the angle 2 is performed by the user at time (a). In this case, the process of switching the angle 1 is immediately started, but actually, it takes about several seconds until the time (b) when the decoding process of the main video data of the angle 2 to be switched is completed. For this reason, after the process of switching the angle 1 is started, the video of the switching destination angle 2 cannot be smoothly reproduced. It should be noted that a still image is reproduced while the main video data of angle 2 is being decoded (that is, from time (a) to (b)).

  Next, it is assumed that an angle switching operation for switching the main video data from the angle 2 to the angle N is performed by the user at time (c). In this case, the process of switching the angle 2 is started immediately, but in actuality, it takes about several seconds until the time (d) when the decoding process of the main video data of the switching destination angle N is completed. For this reason, after the process of switching the angle 2 is started, the video of the switching destination angle N cannot be smoothly reproduced. Note that a still image is reproduced while the decoding processing of the main video data of the angle N is being performed (that is, from time (c) to (d)).

  As a technique for dealing with the above problem, the compressed data corresponding to all angles is pre-read and stored in the memory, and when the angle to be reproduced is switched, the angle stored in the switching destination is already stored. A technique is disclosed in which angle switching can be quickly performed by reading out corresponding compressed data and performing an image reproduction operation (see, for example, Patent Document 2).

  In addition, a dedicated video decoder for decoding each angle video is provided, and among the decoded data decoded by each video decoder, the decoded data corresponding to the switching destination angle is output, so that the angle switching can be instantaneously performed. A technique that can be performed is disclosed (for example, see Patent Document 3).

JP 2004-328450 A JP 2000-299836 A JP 2006-217634 A

  However, with the technique described in Patent Document 2, although it is possible to reduce the time for reading the compressed data corresponding to the switching destination angle, it is actually necessary to execute the decoding process for the read compressed data. Therefore, there has been a problem that the angle switching is delayed by the time required to complete the decoding process.

  On the other hand, according to the technique described in Patent Document 3, unlike the technique described in Patent Document 2, it is not necessary to start the decoding process when the angle is switched. Can do. However, the technique described in Patent Document 3 has a problem in that it is necessary to prepare a dedicated video decoder for decoding all angle videos in advance, leading to an increase in cost.

  The present invention has been made to solve such a problem, and can smoothly reproduce the video of the switching destination angle after starting the process of switching the angle without increasing the cost. The purpose is to be able to.

  In order to solve the above-described problem, in the present invention, in the second decoding unit, it is determined whether or not it is necessary to execute the decoding process of the sub-picture data, and when it is determined that it is not necessary to execute the decoding process, At the same time as the decoding process of the main video data of one angle is executed in the first decoding unit, the second decoding unit is controlled to execute the decoding process of the main video data of another angle. When an angle switching operation is performed, the main video data decoded by the first decoding unit and the main video data decoded by the second decoding unit are switched and displayed on the display unit.

  According to the present invention configured as described above, when it is not necessary to execute the decoding process of the sub-video data in the second decoding unit, the second decoding unit is also used for the decoding process of the main video data. While the main video data decoded by one of the first decoding unit and the second decoding unit is displayed on the display unit, the main video data of the angle to be switched next in the other decoding unit is displayed. The decoding process is executed in the background. Therefore, for example, when switching from one angle to another angle, there is no need to start decoding of main video data of another angle from the start of the switching process. Further, since the angle switching process as described above is performed by using the second decoding unit originally provided in the video reproduction apparatus for decoding the sub-video data, a dedicated video decoder is used as in the prior art. There is no need to prepare a new one, and an increase in cost can be prevented.

It is a block diagram which shows the structural example of the video reproduction system provided with the video reproduction apparatus by this embodiment. It is a figure which shows the example of the angle switch by this embodiment. It is a figure which shows the example of the angle switch by this embodiment. It is a figure which shows the example of the angle switch by this embodiment. It is a flowchart which shows the operation example of the video reproduction apparatus by this embodiment. It is a flowchart which shows the example of a video reproduction operation | movement of the video reproduction apparatus by this embodiment. It is a flowchart which shows the example of a video reproduction operation | movement of the video reproduction apparatus by this embodiment. It is a figure which shows the example of seamless angle switching. It is a figure which shows the example of non-seamless angle switching.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram illustrating a configuration example of a video playback system 120 including the video playback device 100 according to the present embodiment.

  As shown in FIG. 1, the video playback system 120 includes an optical disc 140, an operation input unit 160, and a display 180 (corresponding to the display unit of the present invention) in addition to the video playback device 100. The video playback apparatus 100 has a function of selectively playing back video shot from different angles (multi-angle playback function). In order to realize the multi-angle playback function, the video data reading unit 200 (of the present invention) A first decoding unit 220, a second decoding unit 240, a display video generation unit 260, a display control unit 280, an operation reception unit 300, and a control unit 320.

  The optical disc 140 is a storage medium that uses laser light for reading and writing data, and specifically, is a DVD or Blu-ray Disc (registered trademark). The optical disc 140 includes those in which main video data of a plurality of angles are recorded, and those in which sub-video data is recorded in addition to the main video data of the plurality of angles. For example, if the sub-picture data is an optical disc on which a movie is recorded, a video different from the main movie such as a making video or a commentary video of a performer / director is applicable. It is assumed that the switching order between main video data of a plurality of angles is determined in advance.

  The operation input unit 160 inputs a user instruction to the video playback device 100. In the present embodiment, the operation input unit 160 is configured by an input device such as a touch panel or a remote controller disposed on the surface of the display 180, for example. The display 180 receives and displays the video data output from the video playback device 100.

  The video data reading unit 200 determines whether or not the sub-video data needs to be decoded in the second decoding unit 240 by checking whether or not the sub-video data is recorded on the optical disc 140. . Then, the video data reading unit 200 notifies the display video generation unit 260 and the control unit 320 of the determination result.

  When the video data reading unit 200 determines that the second decoding unit 240 needs to execute the decoding process of the sub-video data, the video data reading unit 200 receives the control from the control unit 320 and selects the default video data from the main video data at a plurality of angles. Main video data of an angle specified by the user or an angle designated by the user (hereinafter referred to as a specific angle) is read from the optical disc 140 and output to the first decoding unit 220, and sub-video data is read from the optical disc 140 and the second decoding unit 240. Output to.

  When the video data reading unit 200 determines that the second decoding unit 240 does not need to perform the decoding process of the sub video data, the video data reading unit 200 receives the control of the control unit 320 and outputs the main video data of a plurality of angles. The main video data of one angle is read from the optical disc 140 and output to the first decoding unit 220, and the main video data of another angle is read from the optical disc 140 and output to the second decoding unit 240. Further, the video data reading unit 200 confirms the content of the video data recorded on the optical disc 140 and outputs angle number information indicating the number of angles of the main video data recorded on the optical disc 140 to the control unit 320.

  The first decoding unit 220 decodes the main video data output from the video data reading unit 200 among the main video data of a plurality of angles recorded on the optical disc 140, and generates the decoded main video data as a display video. Output to the unit 260.

  When the sub video data is recorded on the optical disc 140, the second decoding unit 240 decodes the sub video data output from the video data reading unit 200, and outputs the decoded sub video data to the display video generation unit 260. To do. Further, the second decoding unit 240 decodes the main video data output from the video data reading unit 200 among the main video data of a plurality of angles when no sub-video data is recorded on the optical disc 140, and performs the decoding. The main video data is output to the display video generation unit 260.

  When the display video generation unit 260 receives a notification from the video data reading unit 200 that the second decoding unit 240 needs to execute the decoding process of the sub video data, the display video generation unit 260 outputs the decoded video output from the first decoding unit 220. The main video data is displayed on the display 180 in full screen, and the video data for displaying the decoded sub video data output from the second decoding unit 240 on the sub screen on the display 180 is generated. Video data is output to the display control unit 280.

  In addition, when the display video generation unit 260 receives a notification from the video data reading unit 200 that the second decoding unit 240 does not need to perform the decoding process of the sub video data, the setting information output from the control unit 320 Referring to (described later), the main video data output from the decoding unit (first decoding unit 220 or second decoding unit 240) set as a full screen display target by control unit 320 is displayed on display 180 in full screen. In addition, video data for displaying main video data output from the decoding unit (the first decoding unit 220 or the second decoding unit 240) set as a sub-screen display target by the control unit 320 on the sub-screen on the display 180. And the generated video data is output to the display control unit 280.

  The display control unit 280 controls the display 180 to display a display video based on the video data output from the display video generation unit 260. The display video generation unit 260 and the display control unit 280 correspond to the display control unit of the present invention.

  The operation receiving unit 300 receives an angle switching operation for switching the angle of the main video data displayed on the display 180 via the operation input unit 160. In this case, the operation reception unit 300 notifies the control unit 320 that the angle switching operation has been received.

  When the second decoding unit 240 receives a notification from the video data reading unit 200 that the second decoding unit 240 needs to execute the decoding process of the sub-video data, the control unit 320 reads the main video data of a specific angle from the optical disc 140. The video data reading unit 200 is controlled to output to the first decoding unit 220 and to read the sub video data from the optical disc 140 and output to the second decoding unit 240.

  Thereafter, when the control unit 320 receives a notification that the angle switching operation has been received from the operation receiving unit 300, the video data reading unit 200 grasps the angle of the main video data currently being read from the optical disc 140, and then the video. With reference to the angle number information output from the data reading unit 200, it is determined whether or not main video data of the angle next to the grasped angle exists. When determining that the main video data of the next angle exists, the control unit 320 controls the video data reading unit 200 to read the main video data of the next angle from the optical disc 140 and output the main video data to the first decoding unit 220. . On the other hand, when the control unit 320 determines that the main video data of the next angle does not exist, the video data reading unit reads the main video data of the first angle from the optical disc 140 and outputs it to the first decoding unit 220. 200 is controlled.

  In addition, when the control unit 320 receives a notification from the video data reading unit 200 that the second decoding unit 240 does not need to execute the decoding process of the sub-video data, the control unit 320 has a plurality of angles recorded on the optical disc 140. The main video data of one angle among the main video data is read from the optical disc 140 and output to the first decoding unit 220, and the main video data of another angle is read from the optical disc 140 and output to the second decoding unit 240. The video data reading unit 200 is controlled.

  Further, when the control unit 320 receives a notification from the video data reading unit 200 that the second decoding unit 240 does not need to execute the decoding process of the sub-video data, the control unit 320 first or second decoding unit 220 or 240. Among them, one is set as a full screen display target and the other is set as a sub screen display target, and setting information indicating the setting contents is output to the display video generation unit 260.

  Thereafter, when the control unit 320 receives a notification that the angle switching operation has been received from the operation receiving unit 300, the control unit 320 sets the decoding unit set as the sub-screen display target before the angle switching operation as the full-screen display target. At the same time, the decoding unit set as the full screen display target before the angle switching operation is set as the sub screen display target, and setting information indicating the setting contents is output to the display video generation unit 260.

  In addition, when receiving a notification from the video data reading unit 200 that the second decoding unit 240 does not need to execute the sub-video data decoding process, the control unit 320 operates the notification that the angle switching operation has been received. When received from the receiving unit 300, the angle number information output from the video data reading unit 200 is referred to determine whether or not the number of angles of the main video data recorded on the optical disc 140 is two. When the controller 320 determines that the number of angles of the main video data recorded on the optical disc 140 is 2, nothing is performed. When the control unit 320 determines that the number of angles of the main video data recorded on the optical disc 140 is not 2 (that is, 3 or more), the decoding set as the sub-screen display target before the angle switching operation Whether the main video data of the next angle of the grasped angle exists by referring to the angle number information output from the video data reading unit 200 after grasping the angle of the main video data output from the unit. judge.

  When the control unit 320 determines that there is main video data of the next angle of the main video data output from the decoding unit set as the sub-screen display target before the angle switching operation, the control unit 320 selects the main video data of the next angle. The video data reading unit 200 is controlled so as to read the video data from the optical disc 140 and output it to the decoding unit set as the sub-screen display target. When the control unit 320 determines that there is no main video data of the next angle of the main video data output from the decoding unit set as the sub-screen display target before the angle switching operation, the first The main video data of the angle is read from the optical disc 140 and the video data reading unit 200 is controlled so as to be output to the decoding unit set as the sub-screen display target.

  Next, an example of angle switching in the present embodiment will be described. FIG. 2 is a diagram showing an example of angle switching when sub-picture data is recorded on the optical disc 140 in addition to the main video data of a plurality of angles in the present embodiment.

  The control unit 320 receives a notification from the video data reading unit 200 that the second decoding unit 240 needs to execute the decoding process of the sub-video data, and as shown in FIG. 1st angle) main video data is read from the optical disc 140 and output to the first decoding unit 220, and the sub video data is read from the optical disc 140 and output to the second decoding unit 240. To control.

  Then, the first decoding unit 220 decodes the main video data of the first angle output from the video data reading unit 200, and outputs the decoded main video data to the display video generation unit 260. The second decoding unit 240 decodes the sub video data output from the video data reading unit 200 and outputs the decoded sub video data to the display video generation unit 260.

  The display video generation unit 260 receives a notification from the video data reading unit 200 that the second decoding unit 240 needs to execute the decoding process of the sub-video data, and receives the first output from the first decoding unit 220. The main video data is displayed on the full screen on the display 180, and the video data for displaying the sub video data output from the second decoding unit 240 on the sub screen on the display 180 is generated, and the generated video data is displayed. The data is output to the control unit 280. As shown in FIG. 2B, the display control unit 280 displays a display video based on the video data output from the display video generation unit 260 on the display 180.

  Thereafter, when the control unit 320 receives a notification that the angle switching operation has been received from the operation receiving unit 300, the angle (first angle) of the main video data currently read from the optical disc 140 by the video data reading unit 200 And the number-of-angle information output from the video data reading unit 200 is referred to, and it is determined whether or not main video data of the next angle (second angle) of the recognized angle exists. When it is determined that the main video data of the next angle exists, the control unit 320 replaces the main video data of the second angle with the main video data of the second angle, as shown in FIG. The video data reading unit 200 is controlled to read from the optical disc 140 and output to the first decoding unit 220.

  Then, the first decoding unit 220 decodes the main video data of the second angle output from the video data reading unit 200, and outputs the decoded main video data to the display video generation unit 260. The display video generation unit 260 displays the second main video data output from the first decoding unit 220 on the full screen on the display 180 and displays the sub video data output from the second decoding unit 240 on the display 180. Video data to be displayed on the screen is generated, and the generated video data is output to the display control unit 280. The display control unit 280 displays a display video based on the video data output from the display video generation unit 260 on the display 180, as shown in FIG.

  FIG. 3 is a diagram showing an example of angle switching when only main video data of two angles is recorded on the optical disc 140 in the present embodiment. As shown in FIG. 3A, the control unit 320 receives a notification from the video data reading unit 200 that the second decoding unit 240 does not need to execute the decoding process of the sub-video data, and receives a specific angle (for example, (First angle) main video data is read from the optical disc 140 and output to the first decoding unit 220, and second main video data is read from the optical disc 140 and output to the second decoding unit 240. The video data reading unit 200 is controlled.

  Then, the first decoding unit 220 decodes the main video data of the first angle output from the video data reading unit 200, and outputs the decoded main video data to the display video generation unit 260. The second decoding unit 240 decodes the main video data of the second angle output from the video data reading unit 200 and outputs the decoded main video data to the display video generation unit 260.

  The control unit 320 sets the first decoding unit 220 as a full screen display target, sets the second decoding unit 240 as a sub screen display target, and sets setting information indicating the setting contents to the display video generation unit 260. Output. The display video generation unit 260 refers to the setting information output from the control unit 320, and displays the first main video data output from the first decoding unit 220 set as a full screen display target by the control unit 320 on the display 180. In addition, the second main video data output from the second decoding unit 240 set as a sub-screen display target by the control unit 320 is generated to be displayed on the sub-screen on the display 180. Then, the generated video data is output to the display control unit 280. As shown in FIG. 3B, the display control unit 280 displays a display video based on the video data output from the display video generation unit 260 on the display 180.

  Thereafter, when receiving a notification from the operation accepting unit 300 that the angle switching operation has been accepted, the control unit 320 displays the second decoding unit 240 that has been set as a sub-screen display target before the angle switching operation on the full screen. The first decoding unit 220 that has been set as a target for full screen display before the angle switching operation is set as a sub screen display target, and setting information indicating the setting contents is output to the display video generation unit 260 To do.

  The display video generation unit 260 refers to the setting information output from the control unit 320, and displays the second main video data output from the second decoding unit 240 set as a full screen display target by the control unit 320 on the display 180. In addition, the first main video data output from the first decoding unit 220 set as a sub-screen display target by the control unit 320 is generated to be displayed on the sub-screen on the display 180. Then, the generated video data is output to the display control unit 280. As shown in FIG. 3C, the display control unit 280 displays a display video based on the video data output from the display video generation unit 260 on the display 180.

  After that, when receiving a notification from the operation accepting unit 300 that the angle switching operation has been accepted, the control unit 320 displays the first decoding unit 220 that has been set as the sub-screen display target before the angle switching operation on the full screen. The second decoding unit 240 set as a target for full screen display before the angle switching operation is set as a sub screen display target, and setting information indicating the setting contents is output to the display video generation unit 260 To do.

  The display video generation unit 260 refers to the setting information output from the control unit 320, and displays the first main video data output from the first decoding unit 220 set as a full screen display target by the control unit 320 on the display 180. In addition, the second main video data output from the second decoding unit 240 set as a sub-screen display target by the control unit 320 is generated to be displayed on the sub-screen on the display 180. Then, the generated video data is output to the display control unit 280. As shown in FIG. 3D, the display control unit 280 displays a display video based on the video data output from the display video generation unit 260 on the display 180.

  FIG. 4 is a diagram showing an example of angle switching when only main video data of three angles is recorded on the optical disc 140 in the present embodiment. As shown in FIG. 4A, the control unit 320 receives a notification from the video data reading unit 200 that the second decoding unit 240 does not need to execute the decoding process of the sub-video data, and receives a specific angle (for example, (First angle) main video data is read from the optical disc 140 and output to the first decoding unit 220, and second main video data is read from the optical disc 140 and output to the second decoding unit 240. The video data reading unit 200 is controlled.

  Then, the first decoding unit 220 decodes the main video data of the first angle output from the video data reading unit 200, and outputs the decoded main video data to the display video generation unit 260. The second decoding unit 240 decodes the main video data of the second angle output from the video data reading unit 200 and outputs the decoded main video data to the display video generation unit 260.

  The control unit 320 sets the first decoding unit 220 as a full screen display target, sets the second decoding unit 240 as a sub screen display target, and sets setting information indicating the setting contents to the display video generation unit 260. Output. The display video generation unit 260 refers to the setting information output from the control unit 320, and displays the first main video data output from the first decoding unit 220 set as a full screen display target by the control unit 320 on the display 180. In addition, the second main video data output from the second decoding unit 240 set as a sub-screen display target by the control unit 320 is generated to be displayed on the sub-screen on the display 180. Then, the generated video data is output to the display control unit 280. As shown in FIG. 4B, the display control unit 280 displays a display video based on the video data output from the display video generation unit 260 on the display 180.

  Thereafter, when receiving a notification from the operation accepting unit 300 that the angle switching operation has been accepted, the control unit 320 displays the second decoding unit 240 that has been set as a sub-screen display target before the angle switching operation on the full screen. The first decoding unit 220 that has been set as a target for full screen display before the angle switching operation is set as a sub screen display target, and setting information indicating the setting contents is output to the display video generation unit 260 To do.

  The control unit 320 refers to the angle number information output from the video data reading unit 200, and determines the second angle output from the second decoding unit 240 set as the sub-screen display target before the angle switching operation. It is determined whether or not main video data of the next angle (third angle) of the main video data exists.

  The control unit 320 determines that the main video data of the third angle exists, and instead of the main video data of the third angle instead of the main video data of the first angle, as shown in FIG. The video data reading unit 200 is controlled to read from the optical disc 140 and output to the first decoding unit 220 set as a small screen display target.

  Then, the first decoding unit 220 decodes the main video data of the third angle output from the video data reading unit 200, and outputs the decoded main video data to the display video generation unit 260. The second decoding unit 240 decodes the main video data of the second angle output from the video data reading unit 200 and outputs the decoded main video data to the display video generation unit 260.

  The display video generation unit 260 refers to the setting information output from the control unit 320, and outputs the main video data of the second angle output from the second decoding unit 240 set as a full screen display target by the control unit 320. For displaying the main video data of the third angle output from the first decoding unit 220 set as the sub-screen display target by the control unit 320 on the sub-screen on the display 180. Video data is generated, and the generated video data is output to the display control unit 280. As shown in FIG. 4D, the display control unit 280 displays a display video based on the video data output from the display video generation unit 260 on the display 180.

  After that, when receiving a notification from the operation accepting unit 300 that the angle switching operation has been accepted, the control unit 320 displays the first decoding unit 220 that has been set as the sub-screen display target before the angle switching operation on the full screen. The second decoding unit 240 set as a target for full screen display before the angle switching operation is set as a sub screen display target, and setting information indicating the setting contents is output to the display video generation unit 260 To do.

  The control unit 320 refers to the angle number information output from the video data reading unit 200 and determines the third angle output from the first decoding unit 220 set as the sub-screen display target before the angle switching operation. It is determined whether or not main video data of the next angle (fourth angle) of the main video data exists.

  The control unit 320 determines that the main video data of the fourth angle does not exist, and the main video data of the first angle is used instead of the main video data of the second angle as illustrated in FIG. Is read from the optical disc 140, and the video data reading unit 200 is controlled so as to be output to the second decoding unit 240 set as a sub-screen display target.

  Then, the first decoding unit 220 decodes the main video data of the third angle output from the video data reading unit 200, and outputs the decoded main video data to the display video generation unit 260. The second decoding unit 240 decodes the main video data of the first angle output from the video data reading unit 200 and outputs the decoded main video data to the display video generation unit 260.

  The display video generation unit 260 refers to the setting information output from the control unit 320, and outputs the main video data of the third angle output from the first decoding unit 220 set as the full screen display target by the control unit 320. For displaying the main video data of the first angle output from the second decoding unit 240 set as the sub-screen display target by the control unit 320 on the sub-screen on the display 180 while displaying the full-screen on the display 180. Video data is generated, and the generated video data is output to the display control unit 280. As shown in FIG. 4F, the display control unit 280 displays a display video based on the video data output from the display video generation unit 260 on the display 180.

  Thereafter, when receiving a notification from the operation accepting unit 300 that the angle switching operation has been accepted, the control unit 320 displays the second decoding unit 240 that has been set as a sub-screen display target before the angle switching operation on the full screen. The first decoding unit 220 that has been set as a target for full screen display before the angle switching operation is set as a sub screen display target, and setting information indicating the setting contents is output to the display video generation unit 260 To do.

  The control unit 320 refers to the angle number information output from the video data reading unit 200 and determines the first angle output from the second decoding unit 240 that has been set as the sub-screen display target before the angle switching operation. It is determined whether or not main video data of the next angle (second angle) of the main video data exists.

  The controller 320 determines that the main video data of the second angle exists, and instead of the main video data of the second angle instead of the main video data of the third angle, as shown in FIG. The video data reading unit 200 is controlled to read from the optical disc 140 and output to the first decoding unit 220 set as a small screen display target.

  Then, the first decoding unit 220 decodes the main video data of the second angle output from the video data reading unit 200, and outputs the decoded main video data to the display video generation unit 260. The second decoding unit 240 decodes the main video data of the first angle output from the video data reading unit 200 and outputs the decoded main video data to the display video generation unit 260.

  The display video generation unit 260 refers to the setting information output from the control unit 320, and the main video data of the first angle output from the second decoding unit 240 set as a full screen display target by the control unit 320. For displaying the main video data of the second angle output from the first decoding unit 220 set as the sub-screen display target by the control unit 320 on the sub-screen on the display 180. Video data is generated, and the generated video data is output to the display control unit 280. The display control unit 280 displays a display video based on the video data output from the display video generation unit 260 on the display 180 as illustrated in FIG.

  Next, the operation of the video playback apparatus 100 according to the present embodiment will be described. FIG. 5 is a flowchart showing an operation example of the video reproduction apparatus 100 according to the present embodiment. First, the video data reading unit 200 confirms whether or not the sub video data is recorded on the optical disc 140, thereby determining whether or not the second decoding unit 240 needs to execute the sub video data decoding process. Determination is made (step S100).

  If the video data reading unit 200 determines that the sub-picture data needs to be decoded in the second decoding unit 240 (YES in step S100), the video reproduction device 100 includes the sub-video data. The video reproduction process is executed (step S120). On the other hand, when the video data reading unit 200 determines that the second decoding unit 240 does not need to execute the decoding process of the sub video data (NO in step S100), the video reproduction device 100 does not have the sub video data. A video reproduction process using the main video data is executed (step S140). When the process of step S120 or S140 is completed, the video reproduction device 100 ends the process in FIG. Details of each processing in steps S120 and S140 will be described using the flowcharts of FIGS.

  First, the details of the video reproduction process in step S120 of FIG. 5 will be described. FIG. 6 is a flowchart showing an operation example of video playback processing (with sub-video data) of the video playback device 100 according to the present embodiment. First, the control unit 320 reads the video data so that the main video data of the first angle among the main video data of a plurality of angles recorded on the optical disc 140 is read from the optical disc 140 and output to the first decoding unit 220. The reading unit 200 is controlled (step S200). Next, the control unit 320 controls the video data reading unit 200 to read the sub-video data recorded on the optical disc 140 and output it to the second decoding unit 240 (step S220).

  Next, the first decoding unit 220 decodes the main video data output from the video data reading unit 200, and outputs the decoded main video data to the display video generation unit 260 (step S240). Next, the second decoding unit 240 decodes the sub video data output from the video data reading unit 200, and outputs the decoded sub video data to the display video generation unit 260 (step S260).

  Next, the display video generation unit 260 displays the main video data output from the first decoding unit 220 on the full screen on the display 180, and displays the sub video data output from the second decoding unit 240 on the display 180. Video data to be displayed on the screen is generated, and the generated video data is output to the display control unit 280 (step S280). Next, the display control unit 280 performs control so that a display video based on the video data output from the display video generation unit 260 is displayed on the display 180 (step S300).

  Next, the control unit 320 determines whether or not the reproduction of the video data recorded on the optical disc 140 is completed by checking whether or not the video data reading unit 200 has read all the video data from the optical disc 140. (Step S320). If the control unit 320 determines that the reproduction of the video data recorded on the optical disc 140 has ended (YES in step S320), the video reproduction device 100 ends the processing in FIG.

  On the other hand, when control unit 320 determines that the reproduction of the video data recorded on optical disc 140 has not been completed (NO in step S320), control unit 320 provides a notification that the angle switching operation has been accepted. It is determined whether or not the operation has been received from the operation reception unit 300 (step S340). If control unit 320 determines that notification of accepting the angle switching operation has not been received from operation accepting unit 300 (NO in step S340), the process transitions to step S240.

  On the other hand, when control unit 320 determines that a notification indicating that an angle switching operation has been received from operation receiving unit 300 (YES in step S340), control unit 320 outputs the angle output from video data reading unit 200. With reference to the number information, the video data reading unit 200 determines whether there is main video data at the next angle of the main video data currently read from the optical disc 140 (step S360).

  If the control unit 320 determines that main video data of the next angle exists (YES in step S360), the main video data of the next angle is read from the optical disc 140 and output to the first decoding unit 220. In this manner, the video data reading unit 200 is controlled (step S380). Thereafter, the process proceeds to step S240. On the other hand, when control unit 320 determines that main video data of the next angle does not exist (NO in step S360), the main video data of the first angle is read from optical disc 140 and output to first decoding unit 220. The video data reading unit 200 is controlled so as to be performed (step S400). Thereafter, the process proceeds to step S240.

  Next, details of the video reproduction process in step S140 of FIG. 5 will be described. FIG. 7 is a flowchart showing an operation example of video playback processing (no sub-video data) of the video playback device 100 according to the present embodiment. First, the control unit 320 sets the first decoding unit 220 as a full screen display target, sets the second decoding unit 240 as a sub screen display target, and sets setting information indicating the setting contents to the display video generation unit 260. Output (step S500).

  Next, the control unit 320 controls the video data reading unit 200 so as to read the main video data of the first angle from the optical disc 140 and output it to the first decoding unit 220 (step S520). Next, the control unit 320 controls the video data reading unit 200 so as to read the main video data of the second angle from the optical disc 140 and output it to the second decoding unit 240 (step S540).

  Next, the first decoding unit 220 decodes the main video data output from the video data reading unit 200, and outputs the decoded main video data to the display video generation unit 260 (step S560). Next, the second decoding unit 240 decodes the main video data output from the video data reading unit 200, and outputs the decoded main video data to the display video generation unit 260 (step S580).

  Next, the display video generation unit 260 refers to the setting information output from the control unit 320, and displays the main video data output from the decoding unit set as the full screen display target by the control unit 320 on the display 180. In addition, the video data for displaying the main video data output from the decoding unit set as the sub-screen display target by the control unit 320 on the sub-screen on the display 180 is generated, and the generated video data is displayed. It outputs to the control part 280 (step S600). Next, the display control unit 280 controls to display a display video based on the video data output from the display video generation unit 260 on the display 180 (step S620).

  Next, the control unit 320 determines whether or not the reproduction of the video data recorded on the optical disc 140 is completed by checking whether or not the video data reading unit 200 has read all the video data from the optical disc 140. (Step S640). If control unit 320 determines that the reproduction of the video data has ended (YES in step S640), video reproduction device 100 ends the processing in FIG.

  On the other hand, when control unit 320 determines that reproduction of video data has not ended (NO in step S640), control unit 320 has received notification from operation accepting unit 300 that an angle switching operation has been accepted. It is determined whether or not (step S660). If control unit 320 determines that a notification indicating that an angle switching operation has been received has not been received from operation receiving unit 300 (NO in step S660), the process transitions to step S560.

  On the other hand, when control unit 320 determines that notification of accepting the angle switching operation has been received from operation accepting unit 300 (YES in step S660), control unit 320 displays the sub screen display target before the angle switching operation. Setting information indicating the setting contents of the decoding unit set as the full screen display target and the decoding unit set as the full screen display target before the angle switching operation as the sub screen display target Is output to the display video generation unit 260 (step S680).

  Next, the control unit 320 refers to the angle number information output from the video data reading unit 200 and determines whether or not the number of angles of the main video data recorded on the optical disc 140 is 2 (step S700). ). If control unit 320 determines that the number of angles of main video data recorded on optical disc 140 is 2 (YES in step S700), the process transitions to step S560.

  On the other hand, when control unit 320 determines that the number of angles of the main video data recorded on optical disc 140 is not 2 (that is, 3 or more) (NO in step S700), control unit 320 displays the video data. Whether there is main video data of the next angle of the main video data output from the decoding unit set as the sub-screen display target before the angle switching operation with reference to the angle number information output from the reading unit 200 It is determined whether or not (step S720). If the control unit 320 determines that main video data of the next angle exists (YES in step S720), the main video data of the next angle is read from the optical disc 140 and set as a sub-screen display target. The video data reading unit 200 is controlled to output to the decoding unit (the first decoding unit 220 or the second decoding unit 240) (step S740). Thereafter, the process proceeds to step S560.

  On the other hand, when control unit 320 determines that main video data of the next angle does not exist (NO in step S720), main video data of the first angle is read from optical disc 140 and set as a sub-screen display target. The video data reading unit 200 is controlled so as to be output to the decoding unit (the first decoding unit 220 or the second decoding unit 240) (step S760). Thereafter, the process proceeds to step S560.

  As described above in detail, in the present embodiment, the second decoding unit 240 determines whether or not it is necessary to execute the sub-picture data decoding process, and there is no need to execute the sub-picture data decoding process. When the determination is made, the first decoding unit 220 performs control so that the main video data of one angle is decoded, and at the same time, the second decoding unit 240 executes the decoding processing of the main video data of another angle. . When an angle switching operation is performed, the main video data of one angle decoded by the first decoding unit 220 and the main video data of another angle decoded by the second decoding unit 240 are switched to display. 180 is displayed.

  According to the present embodiment configured as described above, the second decoding unit 240 is also used for the decoding process of the main video data when the second decoding unit 240 does not need to execute the decoding process of the sub-video data. . Then, while the main video data decoded by one of the first decoding unit 220 and the second decoding unit 240 is displayed on the display 180, the main video of the angle to be switched next in the other decoding unit. Data decoding is performed in the background. Therefore, for example, when switching from one angle to another angle, there is no need to start decoding of main video data of another angle from the start of the switching process. Further, since the angle switching process as described above is performed using the second decoding unit 240 originally provided in the video reproduction apparatus 100 for decoding the sub-video data, a dedicated video decoder is newly prepared. It is not necessary to increase the cost.

  In the present embodiment, before the angle switching operation is performed, the main video data of the current angle is displayed on the full screen, and the main video data of the angle to be switched next is displayed on the sub-screen. . In this way, the user can confirm in advance the content of the main video data displayed when the angle switching operation is performed next without performing the angle switching operation.

  In the above embodiment, whether or not the sub-picture data needs to be decoded in the second decoding unit 240 is determined by checking whether or not the sub-picture data is recorded on the optical disc 140. Although examples have been described, the present invention is not limited thereto. For example, the second decoding unit 240 executes the decoding process of the sub video data by confirming whether or not the user has set an instruction to display the sub video data to the video playback device 100 using the operation input unit 160. You may make it determine whether it is necessary to do. As a result, even if the sub-picture data is recorded on the optical disc 140, if the display of the sub-picture data is set to OFF, the second decoding unit 240 performs the decoding process of the main picture data at other angles. Therefore, angle switching can be performed at high speed.

  In the above embodiment, when sub-video data is recorded on the optical disc 140 in addition to the main video data of a plurality of angles, the main video is decoded by the first decoding unit 220 every time the angle switching operation is performed. Although the example which switches data in order from the 1st angle was demonstrated, this invention is not limited to this. For example, the user can specify a desired angle during an angle switching operation, and the main video data to be decoded in the first decoding unit 220 is switched to the main video data of the specified angle. good.

  Further, in the above embodiment, the example in which the main video data of the current angle is displayed on the full screen before the angle switching operation is performed, and the main video data of the angle to be switched next is displayed on the sub-screen has been described. However, the present invention is not limited to this. For example, before the angle switching operation is performed, the main video data of the angle to be switched next may be decoded in the background, and only the main video data of the current angle may be decoded and displayed.

  In addition, each of the above-described embodiments is merely an example of implementation in carrying out the present invention, and the technical scope of the present invention should not be construed in a limited manner. That is, the present invention can be implemented in various forms without departing from the gist or the main features thereof.

DESCRIPTION OF SYMBOLS 100 Image reproduction apparatus 140 Optical disk 160 Operation input part 180 Display (display part)
200 Video data reading unit (determination unit)
220 first decoding unit 240 second decoding unit 260 display video generation unit 280 display control unit 320 control unit

Claims (12)

A first decoding unit for decoding main video data of one angle among main video data of a plurality of angles recorded on the optical disc;
When sub-picture data is recorded on the optical disc, the sub-picture data is decoded, and when the sub-picture data is not recorded, main video data of another angle among the plurality of angles is decoded. A second decoding unit,
A determination unit that determines whether or not it is necessary to execute a decoding process of the sub-picture data in the second decoding unit;
When the determination unit determines that the second decoding unit does not need to execute the decoding process of the sub-picture data, the first decoding unit executes the decoding process of the main video data of the one angle. At the same time, a control unit that controls the second decoding unit to execute decoding processing of the main video data of the other angle,
When a user angle switching operation is performed on the operation input unit, the main video data of the one angle decoded by the first decoding unit and the main video data of the other angle decoded by the second decoding unit And a display control unit for controlling the display so as to be displayed on the display unit. The video playback apparatus according to claim 1,
The determination unit determines whether it is necessary to execute the decoding process of the sub-video data in the second decoding unit by confirming whether an instruction to display the sub-video data is set A video reproduction apparatus characterized by: The video playback apparatus according to claim 1,
The determination unit determines whether or not the sub-picture data needs to be decoded in the second decoding unit by checking whether or not the sub-picture data is recorded on the optical disc. A video reproducing apparatus characterized by that. The video playback apparatus according to claim 1,
The display control unit displays the main video data of the one angle decoded by the first decoding unit on the display unit before the angle switching operation is performed, while the angle switching operation is performed. In this case, the video reproducing apparatus is controlled to display the main video data of the other angle decoded by the second decoding unit on the display unit. The video reproduction apparatus according to claim 4, wherein
The display control unit displays the main video data of the one angle decoded by the first decoding unit on a full screen on the display unit before the angle switching operation is performed, and the second decoding unit The video playback apparatus is controlled to display the main video data of the other angle decoded by the above-mentioned display on a sub-screen on the display unit. The video reproduction apparatus according to claim 5, wherein
When the angle switching operation is performed, the first decoding unit decodes main video data having an angle different from the other angles,
When the angle switching operation is performed, the display control unit displays the main video data of the other angles decoded by the second decoding unit on the full screen on the display unit, and the first decoding unit A video playback apparatus, wherein the main video data having a different angle from the other angles decoded by the control is controlled to be displayed on a sub-screen on the display unit. The video reproduction apparatus according to claim 4, wherein
When the angle switching operation is performed again, the first decoding unit decodes main video data having an angle different from the other angles,
When the angle switching operation is performed again, the display control unit controls to switch to main video data having an angle different from the other angles decoded by the first decoding unit and display the main video data on the display unit. A video reproduction apparatus characterized by: The video playback apparatus according to claim 7, wherein
The video playback apparatus characterized in that an angle different from the other angles is the one angle. The video playback apparatus according to claim 7, wherein
The video playback apparatus characterized in that the angle different from the other angle is another angle different from the one angle. The video playback apparatus according to claim 7, wherein
The display control unit displays the main video data decoded by the second decoding unit on the full screen and decoded by the first decoding unit before the angle switching operation is performed again. A video playback apparatus that controls to display main video data of an angle different from the other angles on the display unit in a sub-screen. The video playback apparatus according to claim 7, wherein
The second decoding unit, when the angle switching operation is performed again, decodes the main video data of an angle different from the angle different from the other angles,
When the angle switching operation is performed again, the display control unit displays main video data of an angle different from the other angles decoded by the first decoding unit on the full screen on the display unit, and A video reproducing apparatus, wherein the main video data of the further different angle decoded by the second decoding unit is controlled to be displayed on the display unit in a sub-screen. A first decoding unit that decodes main video data of one angle read from an optical disc in which main video data of a plurality of angles is recorded; and sub video data when the sub video data is recorded on the optical disc. A video playback method in a video playback device comprising a second decoding unit for decoding video data,
A first step of determining whether or not the sub-picture data needs to be decoded in the second decoding unit;
When it is determined in the first step that the second decoding unit does not need to execute the decoding process of the sub-video data, the first decoding unit executes the decoding process of the main video data of the one angle. And at the same time, a second step of controlling the second decoding unit to execute a decoding process of main video data of another angle;
When a user angle switching operation is performed on the operation input unit, the main video data of the one angle decoded by the first decoding unit and the main video data of the other angle decoded by the second decoding unit And a third step of controlling to display the image on the display unit.

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