JP2004112176A - Information processor, its method, its program, recording medium with the program recorded, and reproducer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a reproducer for enabling information to be outputted by a simple constitution. <P>SOLUTION: A built-in CPU 342 separates audio data, video data and sub-picture data from digital stream data converted from information read from a DVD-Video, and stores them in an audio buffer 344A, a video buffer 344B and a sub-picture buffer 344C, one after another. In a fast-feed reproducing process, it stops an automatic AV synchronizing process and a sub-picture data decoding process performed in a usual reproducing process, and a video decoder 345B decodes the video data one after another and skips B-pictures to output videos. An audio decoder 345A decodes the audio data to be outputted the same as the usual reproducing process. When it cannot process the audio data to the end to result in that the buffer quantity of the audio buffer 344A would exceed a specified value, it cuts off at least a part thereof. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an information processing apparatus that processes information so that it can be output, a method thereof, a program thereof, a recording medium storing the program, and a playback apparatus.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, as an information processing device that processes information so that it can be output, for example, a reproducing device that processes music data so that it can be reproduced is known. Then, in the conventional reproducing apparatus, for example, when the user inputs a setting to switch the reproduction state, the user performs normal processing for reproducing in a tone that the user normally listens to, and music data in the same tone as the music data reproduced in the normal processing. High-speed processing for fast-forward playback is switched. Examples of such a reproducing apparatus include, for example, JP-A-2001-209395, JP-A-2000-339864, JP-A-2001-291342, JP-A-10-257433, JP-A-8-98146, and the like. The described arrangement is known.
[0003]
Japanese Patent Application Laid-Open No. 2001-209395 (Patent Document 1) extracts only an exponent part from a digital signal of an audio digital stream. It is determined whether or not the extracted exponent exceeds a preset threshold, and it is determined whether the audio digital stream is sound or not. Then, by recognizing a setting for reproducing the audio digital stream by fast-forwarding, the digital signal determined to be sound is decoded, and the fast-forwarding reproduction is performed in a reproduction state that is easy for the user to determine.
[0004]
Japanese Patent Application Laid-Open No. 2000-339864 (Patent Document 2) discloses a normal reproduction method in which audio data read from a disk medium is temporarily stored in a memory means, and the audio data is read out from the memory means and output. Processing and fast-forward playback processing for intermittently reading and outputting audio data can be switched as appropriate. When shifting from the normal reproduction process to the fast-forward reproduction process, the audio data for normal reproduction stored in the memory means is thinned out in the fast-forward direction, read out, output as the first reproduction output data, and fast-forwarded from the disk medium. A configuration is adopted in which audio data for reproduction is read out intermittently, stored as second reproduction output data in the memory means, and the second reproduction output data is output after the output of the first reproduction output data is completed. .
[0005]
Furthermore, the one described in Japanese Patent Application Laid-Open No. 2001-291342 (Patent Document 3) corresponds to a reproduction speed, and focuses on a sampling clock having a frequency corresponding to a normal audio reproduction speed from a high frequency side to a low frequency side. A sampling clock within a predetermined range is generated. When the user recognizes the request for fast-forward playback or slow playback from the user interface unit, the compressed video / audio information is decompressed and decoded based on the sampling clock of the controlled clock frequency corresponding to the requested playback speed, and fast-forward playback is performed. At the time of slow playback, audio is output together with video.
[0006]
Japanese Patent Application Laid-Open No. H10-257433 (Patent Document 4) discloses a first area for recording MPEG (Motion Picture Experts Group) data of an image compression system for normal reproduction on a track of a recording medium. A second area for recording fast-forward playback MPEG data is provided, and at the time of fast-forward playback, the fast-forward playback MPEG data recorded in the second area is read out, and the audio is fast-forward-played together with the video. Has been adopted.
[0007]
Further, Japanese Unexamined Patent Application Publication No. 8-98146 (Patent Document 5) discloses a group of pictures (GOP) consisting of h frames of a continuous image including video and audio, which is a group of a fixed number m. And stores a plurality of groups as video / audio files in synchronization with each frame. The GOP for video is skipped to a certain position and selected and read for each group according to the double speed. In the GOP for audio, a part of the GOP for video is made non-voice or noise so that the meaningful reproduction becomes possible. A configuration is adopted in which the video block of the selected video GOP and the audio block or audio-only block of the GOP in which the audio block is left are combined and played back, so that the video is fast-forwarded played back with a sound that makes sense. I have.
[0008]
[Patent Document 1]
JP 2001-209395 A (page 2, right column)
[Patent Document 2]
JP-A-2000-339864 (page 4, right column)
[Patent Document 3]
JP 2001-291342 A (page 4)
[Patent Document 4]
JP-A-10-257433 (page 4, right column to page 5, left column)
[Patent Document 5]
JP-A-8-98146 (page 4)
[0009]
[Problems to be solved by the invention]
However, the conventional reproduction described in, for example, JP-A-2001-209395, JP-A-2000-339864, JP-A-2001-291342, JP-A-10-257433, JP-A-8-98146, etc. In the device, it is necessary to design and manufacture dedicated hardware for fast-forward reproduction of information, and an example is a problem that the cost cannot be reduced.
[0010]
The present invention provides an information processing apparatus that processes such that information can be output with a simple configuration, a method thereof, a program thereof, a recording medium storing the program, and a playback apparatus, taking such points as one problem. The purpose is to do.
[0011]
[Means for Solving the Problems]
The invention according to claim 1 is an information processing apparatus that processes information recorded on a recording medium so as to be able to output the information, wherein the information read from the recording medium is temporarily stored and the information is sequentially stored. Storage means for sequentially outputting the information, processing means for sequentially processing the information stored in the storage means so that the information can be output, and control for causing the processing means to sequentially process the information stored in the storage means so that the information can be output And when the amount of information stored in the storage means is equal to or more than a predetermined amount, at least a part of the stored information is deleted without being output to increase an area in which the information can be stored. And control means for performing high-speed processing of the information.
[0012]
The invention according to claim 3 is an information processing apparatus for processing each paired information recorded on a recording medium so as to be able to output the information, wherein the information read from the recording medium is temporarily stored. A pair of storage means for sequentially outputting the information in the order in which they are stored, a pair of processing means for sequentially processing each of the information stored in the storage means so as to be able to output each of the information, and the one processing means Along with controlling the information to be processed so that it can be output as a series of new information by thinning out part of the information, the other processing means sequentially processes the information stored in the storage means so that it can be output to the other processing means. When the amount of information stored in the storage unit that stores information to be processed becomes a predetermined amount or more, at least a part of the stored information is deleted without being output. An information processing apparatus characterized by comprising a control means for high-speed processing of information forming the pair with the control to increase the storable area the information Te.
[0013]
According to a tenth aspect of the present invention, there is provided an image storage unit for temporarily storing compressed image data read from a recording medium and sequentially outputting the image data in the order in which the compressed image data is stored, and image data read from the recording medium. Audio storage means for temporarily storing the compressed audio data associated with the image data and sequentially outputting the audio data in the order in which they are stored, and sequentially decoding the image data stored in the image storage means Image decoding means for performing decoding processing, audio decoding means for sequentially decoding the audio data stored in the audio storage means, image data decoding processing by the image decoding means, and the audio decoding means The decoding process of the audio data is performed so that the processed image data and the processed audio data are output in synchronization. Processing, the image decoding unit performs a decoding process by thinning out part of the image data, and an amount of the audio data stored in the audio storage unit while sequentially processing the audio data by the audio decoding unit. Control means for appropriately switching and controlling high-speed processing for deleting at least a part of the stored voice data and increasing an area where the voice data can be stored when the predetermined amount is equal to or more than a predetermined amount. It is an information processing apparatus characterized by the following.
[0014]
The invention according to claim 11 is an information processing method for processing information recorded on a recording medium so that the information can be output by an arithmetic unit, wherein the information read from the recording medium is temporarily stored by the arithmetic unit. Then, the stored information is read in the stored order and sequentially processed so as to be output, and when the amount of the stored information becomes a predetermined amount or more, at least a part of the stored information is deleted. And performing high-speed processing to increase the area in which the information can be stored.
[0015]
The invention according to claim 12 is an information processing method for processing a pair of information recorded on a recording medium and associated with each other so that the information can be output by a computing unit, wherein the information is read from the recording medium by the computing unit. Each pair of information is temporarily stored, and the stored information is read in the order in which it is stored, the one information is partially thinned out, and sequentially processed so that it can be output as new information. When the amount of the other information stored becomes a predetermined amount or more while sequentially processing the information so that it can be output, at least a part of the stored other information is deleted to store the other information. This is an information processing method characterized by performing high-speed processing to increase the number.
[0016]
14. The information processing method according to claim 13, wherein the compressed image data recorded on the recording medium and the audio data associated with the image data are processed so as to be output by an arithmetic unit. And temporarily storing the audio data, sequentially reading and decoding the stored image data, and sequentially reading and decoding the stored audio data, the processing of the processed image data and the processing Normal processing to be performed in a state in which the output audio data is output synchronously, processing for sequentially reading the stored image data and thinning out a part of the stored audio data, and sequentially reading and decoding the stored audio data. When the amount of audio data to be stored is equal to or more than a predetermined amount, at least a part of the stored audio data is An information processing method and controlling by switching between dividing fast increase storage region capable of the audio data processing as appropriate.
[0017]
According to a fourteenth aspect of the present invention, there is provided an information processing program for causing an arithmetic unit to execute the information processing method according to any one of the eleventh to thirteenth aspects.
[0018]
According to a fifteenth aspect of the present invention, there is provided a recording medium storing an information processing program, wherein the information processing program according to the fourteenth aspect is recorded so as to be readable by an arithmetic unit.
[0019]
The invention according to claim 16 is a reading means for reading information recorded on a recording medium, and the information read by the reading means is output from a reproducing means and processed to be reproducible. And an information processing device according to (1).
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described below with reference to the drawings. In this embodiment, a reproducing apparatus that reproduces data recorded on a DVD-Video (Digital Versatile Disc-Read Only Memory) as a recording medium will be described. The target recording medium is not limited to DVD-Video, and various recording media can be applied.
[0021]
[DVD-Video structure]
First, a schematic structure of a DVD-Video will be described with reference to FIG. FIG. 1 is a schematic diagram schematically showing a schematic structure of a DVD-Video as a recording medium reproduced by a reproducing apparatus according to an embodiment of the present invention.
[0022]
The DVD-Video 1 is formed in a disk shape having a substantially circular center hole (not shown) at a substantially center, and one surface thereof is an information recording surface. The information recording surface is provided with a lead-in area (not shown) in which a lead-in code indicating the start end is recorded on the innermost side, and a lead-out code indicating the end is provided on the outermost side. A recorded lead-out area (not shown) is provided. As shown in FIG. 1, a volume space 2 which is a data recording area is provided between the lead-in area and the lead-out area.
[0023]
The volume space 2 includes a space for volume and file structure information (Volume / File structure area 3: Volume and File structure), and a DVD video zone (DVD-Video) which is a space for DVD standard applications. zone 4) and another recording zone (DVD others zone) 5, which is a space for applications other than this standard.
[0024]
The volume / file structure area 3 corresponds to, for example, a management area defined in ISO9660 and a universal disk format bridge. The volume / file structure area 3 describes the contents for storing a part of the data described in the DVD video zone 4 in a system memory of a playback device described later.
[0025]
In the other recording zone 5, other information unrelated to the data described in the DVD video zone 4 can be recorded. In addition, the recording zone 5 is not an essential space, and may not be provided when not used.
[0026]
In the DVD video zone 4, as shown in FIG. 1, a video manager (hereinafter, referred to as VMG) 41 and one or more video title sets (hereinafter, referred to as VTS # i (i is a natural number and a maximum value) Is 99).) 42.
[0027]
The VMG 41 stores a video manager information (hereinafter, referred to as VMGI) file 45 that is control data, a video object set for a video manager menu (hereinafter, referred to as VMGM_VOBS) file 46, and a backup VMGI file 47. It is configured. The VMGI 45 describes a search pointer table for searching for data. The backup VMGI file 47 has the same contents as the VMGI file 45.
[0028]
Each VTS #i 42 has a video title set information (hereinafter, referred to as VTSI) file 51 as control data, a video object set (hereinafter, referred to as VTSTT_VOBS) file 52 of a video title set tile, and a backup VTSI. A file 53 is provided.
[0029]
The VTSI file 51 describes the content for reproducing the data described in the VTSTT_VOBS file 52, and the like. Also, the backup VTSI file 53 is configured so that the playback device can read the contents of the VTSI file 51 even when the information recording surface is damaged such as a scratch.
[0030]
The VTSTT_VOBS file 52 includes one or more video object (hereinafter, referred to as VOB # l (l is a natural number)) files 55. Each VOB # 155 includes one or more video title set cells #m (m is a natural number) 56. Further, each cell # m56 is composed of one or more video object unit (hereinafter referred to as VOBU # n (n is a natural number)) file 57. These VOBSU # n57 include one or more navigation-pack (hereinafter, referred to as NV_PCK) files 61 as control information and one or more video-pack (hereinafter, referred to as V_PCK) files as image data. 62, an audio-pack (hereinafter referred to as A_PCK) file 63 which is one or more music data, and a sub-picture-pack (hereinafter referred to as SP_PCK) file 64 which is sub-picture data such as subtitle data. Are mixed. The plurality of V_PCK files 62 constitute an I picture, a P picture, and a B picture as image data of the MPEG (Motion Picture Experts Group) standard, which is an international standard for image compression.
[0031]
[Configuration of playback device]
Next, the configuration of a playback apparatus that plays back DVD-Video 1 having the above-described structure will be described with reference to block diagrams shown in FIGS. FIG. 2 is a block diagram showing the internal configuration of the playback device. FIG. 3 is a block diagram showing the internal configuration of the AV decoder.
[0032]
In FIG. 2, reference numeral 100 denotes a reproducing apparatus. The reproducing apparatus 100 is capable of mounting a DVD-Video 1 and performs processing for reading and reproducing data recorded on the mounted DVD-Video 1.
[0033]
The playback device 100 includes a reading unit 200 that reads information recorded on DVD-Video1, and an information processing unit 300 as an information processing device that processes the read information to be playable.
[0034]
The reading unit 200 includes, for example, an optical pickup 210, a rotation driving unit 220, a feed motor (not shown), and a reading control unit 230. The optical pickup 210 reads data recorded on the information recording surface of the DVD-Video 1 using light. In addition, not only light but also magnetism may be used.
[0035]
Further, the rotation drive unit 220 drives the DVD-Video 1 mounted at a predetermined position of the playback device 100 to rotate at a constant linear velocity or constant angular velocity. The rotation drive unit 220 includes a turntable 221, a clamper (not shown), and a spindle motor 222. The turntable 221 is engaged with the center hole of the DVD-Video1, and puts the DVD-Video1 on a predetermined position of the playback device 100 to be rotatable. The clamper holds the DVD-Video1 between the turntable 221 and the DVD-Video1. The spindle motor 222 drives the DVD-Video 1 to rotate at a constant linear velocity or angular velocity. The spindle motor 222 is provided with an output shaft 222A. The tip of the output shaft 222A is connected to the turntable 221. The driving force of the spindle motor 222 is transmitted to the turntable 221 via the output shaft 222A, and rotates the DVD-Video1 at a constant linear velocity or angular velocity.
[0036]
Further, the feed motor moves the optical pickup 210 parallel to the information recording surface and along the radial direction. Further, the playback device 100 is provided with a detection unit (not shown) for detecting that the DVD-Video 1 is mounted at a predetermined position.
[0037]
The read control unit 230 includes a first memory 231, a first CPU (Central Processing Unit) 232, a decode & servo control unit 233, and the first memory 231, the CPU 232, and the decode & servo control unit 233. And a first data bus 234 to which is connected.
[0038]
The first memory 231 stores various programs for appropriately driving the optical pickup 210, the rotation driving means 220, the feed motor, and the like. The first CPU 232 reads various programs from the first memory 231 and appropriately processes the programs, controls the decode & servo control unit 233, and appropriately drives the optical pickup 210, the rotation driving unit 220, the feed motor, and the like. , And controls the entire reading means 200. The decode & servo control unit 233 reads signals from the optical pickup 210, the rotation drive unit 220, the feed motor, and the like as appropriate, and controls the optical pickup 210, the rotation drive unit 220, the feed motor, and the like as appropriate to operate. Further, the decode & servo control unit 233 converts information recorded on the DVD-Video 1 read by the optical pickup 210 into digital stream data.
[0039]
The information processing means 300 of the reproducing apparatus 100 includes a second memory 310, a second CPU 320 which also functions as an information switching recognition means, a track buffer 330, and an AV (Audio-Visual) decoder as information processing means. 340, a digital-to-analog converter (DAC) 350, a TV encoder 360, a second data bus 370, an audio output terminal 380, and an image output terminal 390. .
[0040]
Various programs and the like for processing information are stored in the second memory 310. The second CPU 320 reads various programs from the second memory 310, processes the programs as appropriate, and controls the entire information processing unit 300. In addition, the second CPU 320 acquires a signal based on a user's setting input from an input unit provided in the playback device 100, and appropriately controls the entire operation of the playback device 100 in response to the setting input. The track buffer 330 temporarily stores digital stream data read by the reading unit and converted by the decode & servo control unit 233.
[0041]
The AV decoder 340 separates the digital stream data stored in the track buffer 330 into audio data and image data and processes them. As shown in FIG. 3, the AV decoder 340 includes a built-in memory 341, a built-in CPU 342 as control means, a stream buffer 343, a sound buffer 344A as sound storage means as storage means, and a sound buffer as processing means. An audio decoder 345A as a decoding unit, a video buffer 344B as an image storage unit as a storage unit, a video decoder 345B as an image decoding unit as a processing unit, a sub-picture buffer 344C, and a sub-picture decoder 345C. , A display processor 346 and a third data bus 347 to which these are connected.
[0042]
The built-in memory 341 stores various programs for processing digital stream data to be reproducible. The built-in CPU 342 reads out various programs stored in the built-in memory 341, processes the programs as appropriate, and controls the entire AV decoder 340. The stream buffer 343 temporarily stores digital stream data temporarily stored in the track buffer 330 so as to sequentially process the digital stream data.
[0043]
The audio buffer 344A temporarily stores the compressed audio data constituting the digital stream data. That is, the built-in CPU 342 appropriately separates digital stream data, for example, analyzes a pack head constituting VOB # 155 in which image data and music data are mixed, and analyzes the A_PCK file 63, the V_PCK file 62, the SP_PCK file 64, and the NV_PCK file. 61, and stores the separated audio data. Similarly, the video buffer 344B temporarily stores the compressed image data constituting the digital stream data, for example, the V_PCK file 62. Similarly, the sub-picture buffer 344C temporarily stores sub-picture data such as subtitles constituting the digital stream data, for example, the SP_PCK file 64. The NV_PCK file 61 is appropriately stored in the built-in memory 341 and processed by the built-in CPU 342 as appropriate.
[0044]
The audio decoder 345A sequentially expands the audio data stored in the audio buffer 344A in the order in which they are stored. The decompressed audio data is output to the DAC 350 as appropriate. The video decoder 345B sequentially expands the image data stored in the video buffer 344B in the order in which they are stored, and generates, for example, MPEG I pictures, P pictures, and B pictures. The sub-picture decoder 345C sequentially expands the sub-picture data stored in the sub-picture buffer 344C in the specified order. The display processor 346 performs an overlay or the like to reproduce the image data and the sub-picture data processed by the video decoder 345B and the sub-picture decoder 345C. The image data and sub-picture data processed by the display processor 346 are output to the TV encoder 360 as appropriate.
[0045]
The DAC converts the audio data expanded by the audio decoder 345A into an analog signal and outputs the analog signal to an audio output terminal. The sound output terminal is connected to a sound generating means (not shown) for generating sound data such as an amplifier and a speaker to reproduce the sound data.
[0046]
The TV encoder 360 appropriately combines the image data and the sub-picture data processed by the display processor 346 and outputs the resultant to an image output terminal. This image output terminal is connected to a display device (not shown) for performing a reproduction process for displaying image data, such as a liquid crystal monitor or a CRT (Cathode-Ray Tube).
[0047]
Then, based on the setting input from the user, the information processing means 300 converts the digital stream data read and converted from the DVD-Video 1 by the reading means 200 into audio data which is appropriately separated and decompressed by the AV decoder 340, and A normal process for synchronizing the image data and the sub-picture data with the built-in CPU 342 as appropriate and reproducing at a normal reproduction speed, and a high speed for reproducing the image data at a frequency at which the image data is reproduced at a fast forward speed and the audio is reproduced at the normal reproduction speed. Switching between processing and processing.
[0048]
[Information processing operation of playback device]
Next, the operation of the information processing in the reproducing apparatus will be described with reference to the drawings. Here, as the information processing, a reproduction process of DVD-Video1 will be described as an example. FIG. 4 is a flowchart showing the operation of the reproduction process. FIG. 5 is an explanatory diagram showing the relationship between the video to be played back during the normal playback processing and the buffer amount in the audio buffer. FIG. 6 is a flowchart showing the operation of the decoding process in the video decoder during the fast-forward playback process. FIG. 7 is an explanatory diagram showing the situation of the decoding process of the image data at the time of the fast forward reproduction process. FIG. 8 is a flowchart showing the operation of the decoding process in the audio decoder during fast-forward playback. FIG. 9 is a graph showing the buffer capacity of the audio buffer during fast-forward playback.
[0049]
(Normal playback processing)
When the DVD-Video 1 is mounted at a predetermined reproduction position, the first CPU 232 of the reading unit 200 controls the decode & servo control unit 233 to appropriately drive the feed motor, and the reading light of the optical pickup 210 is read from the DVD-Video 1. At the innermost circumference of. Further, the spindle motor 222 is started to drive the DVD-Video1 to rotate at a constant linear velocity.
[0050]
Then, the first CPU 232 acquires, for example, information for automatic reproduction recorded on the DVD-Video1, or inputs a setting input of a normal reproduction request for information recorded on the DVD-Video1 by an input operation of the user. When acquired from the means, as shown in the flowchart of FIG. 4, a stream input process for reading information recorded on the DVD-Video 1 by the optical pickup 210 and converting the information into digital stream data by the decode & servo control unit 233 is executed ( Step S1). The digital stream data converted in step S1 is temporarily stored in the track buffer 330 of the information processing means 300.
[0051]
Specifically, the TT_SRPT of the search pointer table recorded in the VMGI file 45 of the VMG 41 shown in FIG. 1 is read. Based on the read TT_SRPT, the data is sequentially read and sequentially stored in the track buffer 330 as continuous digital stream data.
[0052]
Then, the digital stream data stored in the track buffer 330 is sequentially taken into the stream buffer 343 of the AV decoder 340 of the information processing means 300. Further, the built-in CPU 342 of the information processing means 300 appropriately separates digital stream data sequentially stored in the stream buffer 343 into audio data, image data, and sub-picture data. Then, the separated audio data is sequentially stored in the audio buffer 344A, the image data is sequentially stored in the video buffer 344B, and the sub-picture data is sequentially stored in the sub-picture buffer 344C.
[0053]
Thereafter, the built-in CPU 342 performs a decoding process as a decoding process based on the clock information that is a timing for starting the decoding that associates the audio data and the image data included in the digital stream data with each of the decoders 345A, 345B, 345C. Specifically, the decoding process is started when the number of clocks reaches a predetermined count based on a predetermined clock frequency generated by the built-in CPU 342. Then, a decoding process of expanding the image data by the video decoder 345B and a decoding process of expanding the audio data by the audio decoder 345A are performed.
[0054]
By the decompression process by the video decoder 345B, new image data in which an I picture, a P picture, and a B picture are continuously continuous as shown in FIG. 5A is generated. Then, the decompressed image data and sub-picture data are subjected to overlay or the like in the display processor 346, appropriately synthesized by the TV encoder 360, and output from the image output terminal 390. The decompressed audio data is converted into an analog signal by the DAC 350 and output from the audio output terminal 380. The audio data is output and reproduced as sound by the sounding means, and the image data and subpicture data are output and reproduced as video on the display device, and the video and audio are reproduced in a synchronized state.
[0055]
At the time of the normal reproduction process, the built-in CPU 342 performs an automatic AV synchronization process. In other words, when audio data and image data are decoded, if the reproduced video and audio are shifted due to, for example, a data acquisition error, the video may be skipped or the same video may be displayed. And sound are reproduced in a synchronized state.
[0056]
Then, since the information sequentially read from the DVD-Video 1 is sequentially processed and output, audio is output corresponding to the video. For example, as shown in FIG. 5, the buffer amount of the audio buffer 344A, that is, the stored audio The data storage amount is almost constant.
[0057]
(High-speed playback processing)
On the other hand, when the second CPU 320 obtains a setting input requesting high-speed playback, for example, fast-forward playback, from an input unit by an input operation of the user, as shown in FIG. Is stopped (step S2). That is, the process of synchronizing the reproduced video and audio is stopped. Further, the second CPU 320 controls the built-in CPU 342 to stop the sub picture decoder 345C from decoding the sub picture data (step S3). For example, by not outputting the separated sub-picture data from the stream buffer 343 to the sub-picture buffer 344C, not storing it in the sub-picture buffer 344C, or deleting sub-picture data stored without being decoded by the sub-picture decoder. Then, the decoding process of the sub-picture data is stopped. Then, in this state, the second CPU 320 controls each of the decoders 345A, 345B, and 345C so as to perform a decoding process on the image data and the audio data (Step S4).
[0058]
In the decoding processing of the image data in step S4, the decoding processing of the image data is performed based on the time information under the control of the built-in CPU 342, as described above. Then, as shown in the flowchart of FIG. 6, when it is determined by the decoding process that the generated image data is a B picture (step S411), the B picture is skipped without being output, and the image data is sequentially decoded. Processing is performed (step S412). By the decoding process by the video decoder 345B, as shown in FIG. 7, new image data in which the B picture of the image data newly generated by the decoding process in the case of the normal reproduction process is deleted is generated.
[0059]
Further, in the decoding process of the audio data in step S4, the audio data is decoded based on the time information under the control of the built-in CPU 342, as described above. Then, as shown in the flowchart of FIG. 8, the built-in CPU 342 proceeds with the decoding process until the buffer amount of the audio buffer 344A becomes a predetermined amount, for example, almost full (step S421).
[0060]
In this step S421, when the built-in CPU 432 determines that the buffer amount is almost full, it performs processing to delete all the audio data stored so far in the audio buffer 344A (step S422).
[0061]
For example, when the buffer amount of at least one of the audio buffer 344A and the video buffer 344B becomes full, the stream buffer 343 does not newly acquire digital stream data from the decode & servo control unit 233.
[0062]
Here, the image data is sequentially decoded as shown in FIG. 7 and output as a video, while the audio data is sequentially decoded as shown in FIG. 9 in the same manner as the normal reproduction process. For this reason, the image data is gradually delayed, and the amount of the buffer gradually increases without being able to complete the processing. Therefore, if the decoding process is continued, the buffer amount of the audio buffer 344A becomes full, so that new digital stream data cannot be obtained, image data cannot be obtained, and fast-forward reproduction cannot be performed. Accordingly, a control is performed to delete a predetermined amount, for example, substantially, of the stored audio data when the buffer amount of the audio buffer 344A is almost full (at the point A in FIG. 9). After the deletion, the audio data is sequentially stored from the stream buffer 343 again.
[0063]
When the built-in CPU 342 recognizes that the audio data has been stored up to one frame, which is the minimum unit of audio reproduction, as indicated by the area from B to C in FIG. 9 (step S423), As shown in the area from C to A in 9, the audio data is sequentially decoded and output (step S424). That is, as shown in FIG. 9, the audio buffer amount, which is the amount of audio data to be stored, is represented by a line graph.
[0064]
By the decoding processing in step S4, the sound is reproduced in the same manner as the normal reproduction so that the B picture is thinned out and follows the video that is fast-forward-reproduced, and the sound is gradually delayed from the fast-forwarded video. Then, the buffer amount of the audio buffer 344A becomes almost full, and the audio data is deleted. After this deletion, the audio reproduced by continuing the decoding processing of the audio data stored sequentially is reproduced synchronously so as to catch up with the fast-forwarded video. Thereafter, the situation in which the audio is reproduced with a delay with respect to the video is repeated. The timing at which the audio gradually delays with respect to the video is appropriately set by setting a threshold value serving as a condition of the buffer amount of the audio buffer 344A or the buffer amount to be deleted. Then, it is preferable to set the situation of being late for the video so that the user does not feel uncomfortable.
[0065]
Then, for example, when the second CPU 320 acquires a setting input for requesting normal reproduction by stopping fast-forward reproduction as high-speed reproduction from the input unit by an input operation of the user, as shown in FIG. The CPU 320 starts the automatic AV synchronization process again. (Step S5). Further, the second CPU 320 controls the built-in CPU 342 to stop the process for fast-forward playback (step S6). That is, the built-in CPU 342 stops the video decoding process shown in the flowchart of FIG. 6 and the audio decoding process shown in the flowchart of FIG. 8, clears the audio buffer 344A, the video buffer 344B, and the sub-picture buffer 344C, and deletes the digital stream data. Control to stop memory.
[0066]
Thereafter, similarly to step S1, decoding of video data, audio data, and sub-picture data is started, and information recorded on the DVD-Video 1 is read by the optical pickup 210 under the control of the second CPU 320, and decoding & The servo controller 233 performs a stream input process for converting the data into digital stream data (step S7), and the video and the audio are normally reproduced (step S8).
[0067]
As described above, in the above-described embodiment, as the information processing means 300 for processing information recorded on the DVD-Video 1 so that the information can be reproduced and output, the audio data read from the DVD-Video 1 is temporarily stored and this information is stored. The audio buffer 344A sequentially outputs the audio data in the order in which the audio data is output, the audio decoder 345A sequentially processes the audio data stored in the audio buffer 344A so that the audio data can be output, and the audio data stored in the audio buffer 344A by the audio decoder 345A. In addition to performing control to sequentially process the audio data so that the audio data can be reproduced and output, when the buffer amount, which is the amount of audio data stored in the audio buffer 344A, becomes equal to or greater than a predetermined amount, at least a part of the stored audio data is converted to audio. The audio data is deleted without being output to the decoder 345A. And a control to increase the storable area and structure in which the built-CPU342 for high-speed playback processing is fast-forward reproducing audio data.
[0068]
As a result, when the buffer amount of the audio buffer 344A becomes equal to or larger than a predetermined amount without being processed by the audio decoder 345A, the stored audio data is deleted and the stored audio data is deleted in the same manner as the normal reproduction processing. In this case, the audio data is decoded and reproduced as audio. Therefore, by using the configuration for normal reproduction processing as it is, fast-forward reproduction processing can be performed in a state where the user can recognize the reproduced audio satisfactorily.
[0069]
Further, in the above-described embodiment, the image data and the audio data read from the DVD-Video 1 are used as the information processing unit 300 that processes the paired image data and the audio data recorded on the DVD-Video 1 so as to be able to reproduce and output the data. A pair of video buffer 344B and audio buffer 344A for sequentially outputting image data and audio data in the order in which they are stored while temporarily storing data, and image data and audio stored in these video buffer 344B and audio buffer 344A. A pair of a video decoder 345B and an audio decoder 345A for sequentially processing the data so as to be able to reproduce and output the data, respectively, and controlling the video decoder 345B to thin out a part of the image data so as to process the data as a series of new image data. When the audio decoder 345A sequentially decodes the image data stored in the audio buffer 344A so as to be able to reproduce and output the audio data, at least one of the audio data stored when the buffer amount for storing the audio data to be processed becomes a predetermined amount or more. And a built-in CPU 342 for performing control to increase the area in which audio data can be stored by deleting the portion without outputting the audio data to the audio decoder 345A and performing high-speed reproduction processing of fast-forward reproduction of paired image data and audio data. Configuration.
[0070]
As a result, the image data is decoded to enable reproduction and output by thinning out a portion of the image data, and the image data is subjected to a fast-forward reproduction process, which is a high-speed reproduction, and the audio data stored with a buffer amount of a predetermined amount or more is decoded. Until the audio data is deleted without being deleted, the audio data is sequentially decoded so that they can be reproduced and output in the same manner as in the normal reproduction processing. Therefore, by using the configuration for the normal reproduction processing as it is, the related image data and audio data are used. Can be fast-forwarded and reproduced while the user can recognize the voice well.
[0071]
The second CPU 320 recognizes a setting input for switching between normal reproduction processing, which is a user's request for switching of information processing, and fast-forward reproduction processing, which is a high-speed reproduction processing, from the input unit. For this reason, by using the configuration of the AV decoder 340 for performing the so-called normal speed normal reproduction process, the fast forward reproduction process can be easily performed.
[0072]
In the case of the normal reproduction processing, for example, the image data is skipped and reproduced by the automatic AV synchronization processing or the image data is reproduced in synchronism by the processing for reproducing the image data redundantly. In this case, the automatic AV synchronization process is stopped, and the image data and the audio data are respectively decoded. Therefore, it is possible to easily obtain a configuration in which the high-speed reproduction process is performed with the normal reproduction sound that can be easily heard by the user by using the configuration of the AV decoder 340 for performing the normal reproduction process. That is, even when decoding processing for thinning out a part of image data during high-speed reproduction processing, the synchronization processing with the audio by the automatic AV synchronization processing is stopped to prevent the audio from becoming fast-forward reproduction. Even when the AV decoder 340 for normal reproduction processing is used, fast-forward reproduction processing can be easily performed.
[0073]
Further, at the time of high-speed reproduction processing, decoding processing is performed at a timing when a certain amount of audio data of information recorded on DVD-Video1 is accumulated. In general, since the video and the audio are dispersed and multiplexed, the audio data remaining after removing at least a part of the stored audio data when the buffer amount of the audio buffer 344A becomes a predetermined amount or more. When the newly stored audio data is decoded and output, it is almost synchronized with the previously reproduced video. Even in the configuration using the AV decoder 340 of the normal reproduction process, the video is not reproduced during the high-speed reproduction process. A reproduction state in which the sound and the sound are almost synchronized apparently can be easily obtained.
[0074]
In addition, since the playback apparatus 100 performs playback processing on a DVD-Video 1 on which image data of an image compression method based on the MPEG (Motion Picture Experts Group) standard and compressed audio data are recorded, the compressed image data and audio The configuration of the AV decoder 340 necessary for processing data can be used as it is, and is particularly preferable.
[0075]
(Modification of the embodiment)
The present invention is not limited to the above-described embodiment, but includes the following modifications as long as the object of the present invention can be achieved.
[0076]
In the above-described embodiment, as described above, the recording medium is not limited to DVD-Video1, and various recording media, for example, DVD-ROM, CD-DA (Compact Disk-Digital Audio), CD-ROM (Compact) Disc-Read Only Memory), DVD-Audio, DVD-ROM (Digital Versatile Disc-Read Only Memory), DVD-R (Digital Versatile Disc-Recable), DVD-Raw Digital Vecto, etc. Magneto-optical (MO) disks, magnetic disks such as hard disks, or magnetic disks Tape, memory card, IC (Integrated Circuit) card, etc. can also be applied.
[0077]
The information to be processed to be outputable is not limited to image data and audio data, and may be configured to process any information such as character data. Furthermore, for example, a configuration in which only audio data can be output, such as a CD-DA, and a configuration in which audio data can be reproduced and output while at least partially clearing (deleting) the audio data with a predetermined buffer amount, for example, are adopted. However, the present invention is not limited to the configuration for processing paired information.
[0078]
In addition, the present invention is not limited to image data of the image compression method according to the MPEG standard, but may be configured to process any compression method, and further, to output uncompressed information.
[0079]
Although the image data and the audio data associated with each other based on the time information have been described as the paired information, any other configuration may be used as the association.
[0080]
In the fast forward reproduction, the B picture generated by the decoding process of the image data is skipped. For example, only one of the B pictures is skipped, or one B picture is skipped for a plurality of frames. The output state of the image data to be fast-forward-reproduced can be changed and set as appropriate, such as a state in which only the I-picture is output, and any method can be used. The output state of the image data may be variably controlled.
[0081]
As the reproducing means, any means such as a sound generating means and a display device, and an integrated structure capable of generating and displaying both a TV and the like can be used. As the reproducing apparatus, a reproducing apparatus having a structure provided with reproducing means can be applied.
[0082]
In addition, the present invention can be applied to any device form, such as a computer-readable program serving as an arithmetic means, and operating the computer to process the information recorded on a recording medium mounted on the computer so that the information can be output. The arithmetic means in the present invention includes, for example, one personal computer, a configuration in which a plurality of computers are combined in a network, an element such as a microcomputer, or a circuit board on which a plurality of electronic components are mounted.
[0083]
The present invention is not limited to the above-described embodiment and the modifications of the embodiment, and various other applications are possible without departing from the object of the present invention.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing a schematic configuration of a DVD-Video according to an embodiment of the present invention.
FIG. 2 is a block diagram showing an internal configuration of a playback device according to the embodiment.
FIG. 3 is a block diagram showing an internal configuration of an AV decoder of the playback device according to the embodiment.
FIG. 4 is a flowchart showing an operation of a reproduction process in the embodiment.
FIG. 5 is an explanatory diagram showing a relationship between a reproduced video and a buffer amount in an audio buffer in a normal reproduction process according to the embodiment.
(A) Conceptual diagram showing video to be played
(B) Graph showing buffer amount of audio buffer
FIG. 6 is a flowchart showing an operation of a decoding process in a video decoder at the time of fast-forward playback processing in the embodiment.
FIG. 7 is an explanatory diagram showing a situation of a decoding process of the image data at the time of the fast-forward reproduction process in the embodiment.
FIG. 8 is a flowchart showing an operation of a decoding process in an audio decoder at the time of fast-forward playback in the embodiment.
FIG. 9 is a graph showing a buffer amount of an audio buffer at the time of fast-forward playback according to the embodiment.
[Explanation of symbols]
1 DVD-Video as a storage medium
100 playback device
200 reading means
300 Information processing means as information processing apparatus
320 Second CPU that also functions as information switching recognition unit
340 AV decoder as information processing means
342 Built-in CPU as control means
344A Audio buffer as audio storage means as storage means
344B Image buffer as image storage means as storage means
345A Audio decoder as audio decoding means as processing means
345B Video decoder as image decoding means as processing means

Claims (16)

An information processing apparatus that processes information recorded on a recording medium so that the information can be output,
Storage means for temporarily storing the information read from the recording medium and sequentially outputting the information in the order of storage,
Processing means for sequentially processing the information stored in the storage means so that the information can be output;
The processing unit controls the information stored in the storage unit to be sequentially processed so that the information can be output. At least one of the information stored when the amount of information stored in the storage unit is equal to or more than a predetermined amount. Control means for performing a control to increase the area in which the information can be stored by deleting the information without outputting the part, and to process the information at a high speed;
An information processing apparatus comprising: The information processing device according to claim 1,
An information switching recognition unit that recognizes a switching request for information processing;
The control means recognizes the switching request by the information switching means, and causes the processing means to process the information read from the recording medium and sequentially stored in the storage means so that the information can be sequentially output. An information processing apparatus characterized by switching between normal processing for control and processing. An information processing apparatus that processes each pair of information recorded on a recording medium so as to be associated with each other,
A pair of storage means for sequentially outputting the information in the order in which they are stored while temporarily storing the information read from the recording medium,
A pair of processing means for sequentially processing the information stored in these storage means so as to be able to output each;
The one processing unit controls the information to be output as a series of new information by thinning out part of the information, and the other processing unit sequentially processes the information stored in the storage unit so that the information can be output. When the amount of information stored in the storage unit that stores information to be processed by the other processing unit is equal to or more than a predetermined amount, at least a part of the stored information is deleted without being output. Control means for performing control to increase the area in which information can be stored and performing high-speed processing of the paired information;
An information processing apparatus comprising: The information processing apparatus according to claim 3,
An information switching recognition unit that recognizes a switching request for information processing;
The control means recognizes the switching request by the information switching means, and synchronizes high-speed processing and information sequentially read from the recording medium and stored in the storage means by the pair of processing means. An information processing apparatus characterized in that the processing is switched between normal processing and sequential processing in which output is sequentially performed. The information processing apparatus according to claim 4,
The control means controls the synchronization processing for processing the paired information processed so as to be output by the pair of processing means so as to be output synchronously during the normal processing, and performs the processing for high-speed processing. An information processing apparatus, wherein the synchronization processing is stopped and the information is processed so that each of the information can be output. The information processing apparatus according to claim 4, wherein
The control means performs processing such that the paired information can be output at a synchronized timing based on time information relating the paired information of the information recorded on the recording medium during high-speed processing. An information processing apparatus characterized by the above-mentioned. The information processing apparatus according to any one of claims 3 to 6,
The paired information is image data in which a plurality of pieces of image information are continuous and audio data corresponding to the image data,
The control unit controls the one processing unit to thin out a part of the image information of the image data, generate a new series of image data, and process the image data so that it can be output, and the other processing unit performs the processing. When the amount of information stored in the storage unit that stores the audio data while processing the audio data stored in the storage unit so that the audio data can be sequentially output is at least a predetermined amount, at least a part of the audio data stored in the storage unit is processed. An information processing apparatus characterized by performing high-speed processing by controlling deletion. The information processing apparatus according to any one of claims 1 to 7,
The information has been compressed,
The information, characterized in that the storage means sequentially and temporarily stores the information read from the recording medium in order to decode the information read from the recording medium so that the information can be output by the processing means. Processing equipment. The information processing apparatus according to any one of claims 3 to 6,
The one information is image data of an image compression system according to the MPEG (Motion Picture Experts Group) standard, the other information is audio data,
The one processing means performs a decoding process so that the image data can be output as a video,
The information processing apparatus according to claim 1, wherein the other processing unit performs a decoding process so that the audio data can be output as audio. Image storage means for temporarily storing the compressed image data read from the recording medium and sequentially outputting the image data in the order in which they are stored,
Audio storage means for temporarily outputting compressed audio data read from the recording medium and associated with the image data and sequentially outputting the audio data in the order in which they are stored;
Image decoding means for sequentially decoding the image data stored in the image storage means,
Audio decoding means for sequentially decoding the audio data stored in the audio storage means,
The decoding of the image data by the image decoding unit and the decoding of the audio data by the audio decoding unit are performed so that the processed image data and the processed audio data are output in synchronization. A normal process and a process of thinning out part of the image data by the image decoding unit and performing a decoding process, and sequentially processing the audio data by the audio decoding unit while processing the audio data stored in the audio storage unit. Control means for appropriately switching and controlling high-speed processing for deleting at least a part of the audio data stored when the amount is equal to or more than a predetermined amount and increasing an area in which the audio data can be stored,
An information processing apparatus comprising: An information processing method for processing information recorded on a recording medium so that the information can be output by an arithmetic unit,
By the calculating means,
Temporarily storing information read from the recording medium,
The stored information is read in the stored order and sequentially processed so as to be output, and when the amount of the stored information is equal to or more than a predetermined amount, at least a part of the stored information is deleted. An information processing method, comprising: performing high-speed processing to increase an area in which the information can be stored. An information processing method for processing a pair of information recorded on a recording medium and associated with each other so that the information can be output by an arithmetic unit,
By the calculating means,
Each pair of information read from the recording medium is temporarily stored,
The stored information is read in the order in which it is stored, and one of the pieces of information is partially thinned out and sequentially processed so that it can be output as new information. When the amount of information to be stored is equal to or more than a predetermined amount, high-speed processing is performed in which at least a part of the other stored information is deleted to increase an area where the other information can be stored. Information processing method. An information processing method for processing compressed image data recorded on a recording medium and audio data associated with the image data so as to be output by arithmetic means, respectively.
Temporarily storing the image data and the audio data,
The state in which the processed image data and the processed audio data are output in synchronization with the processing of sequentially reading and decoding the stored image data and the processing of sequentially reading and decoding the stored audio data. A normal process to be performed, a process of sequentially reading the stored image data and thinning out part of the data, and a process of sequentially reading and decoding the stored audio data and storing the audio data while the amount of the audio data is equal to or more than a predetermined amount. An information processing method comprising: appropriately switching and controlling high-speed processing for deleting at least a part of the stored audio data to increase an area in which the audio data can be stored. An information processing program for causing an arithmetic means to execute the information processing method according to any one of claims 11 to 13. A recording medium recording an information processing program, wherein the information processing program according to claim 14 is recorded so as to be readable by an arithmetic unit. Reading means for reading information recorded on a recording medium;
The information processing apparatus according to any one of claims 1 to 10, wherein the information read by the reading unit is output from the playback unit and processed to be playable.
A playback device comprising:

Images