JP3804676B2 - Disc playback method and disc playback apparatus - Google Patents

Description

The present invention relates to an apparatus for recording and reproducing compressed video and audio signals on a medium such as an optical disk.

Non-patent document 1 describes in detail the compression of video and audio signals. Further, as an example of the optical disc, it is described in detail in Non-Patent Document 2.

  Non-Patent Document 1 describes a video and audio signal compression method and a multiplexing method thereof. Non-Patent Document 2 describes a signal recording format of a CD-ROM in which a CD for recording an audio signal is used for data application. However, even if compressed video and audio signals are recorded, and user data for computers is recorded as a data application, a method for efficiently recording on media, and playback There was no mention of facilitating the search method.

"Latest MPEG textbook" supervised by Hiroshi Fujiwara, August 1, 1994, issued by Ascii Publishing Bureau Kenji Hayashi “CD-Audio to PC” July 25, 1990, Corona Publishing

Video and audio signals compressed in a data stream format having a 188-byte transport packet as described in "Latest MPEG Textbook" are recorded on a CD-ROM which is a data recording medium for computers. In this case, one sector of the CD-ROM = 2048 bytes and the basic data capacity unit of the medium as in other computer recording media is a power of 2, and the user area is used to increase the recording efficiency. If all are recorded, a transport packet divided between different sectors is generated, so that the reproduction process becomes complicated, and for ease of processing, a plurality of transport packets are recorded in one sector. If the fraction is invalid data, there is a problem that the recording efficiency is lowered. Further, when reproducing a recorded CD-ROM, the boundary of a picture or a group of pictures can be determined by reproducing a data stream and judging the transport packet and packet header information. However, when recording a signal on a medium, in order to improve error tolerance, interleaving processing and error correction coding processing specific to normal media, and framing by adding a synchronization signal and sub information are performed. . For this reason, when the boundary of the picture or the group of pictures is judged by playing the data stream and judging the header information of the pack and the packet, the position of the pickup or the like that is already playing the data from the media is shifted. ing. For this reason, when searching or editing in units of pictures or groups of pictures, complicated control is required to find the position of the boundary part of the picture or group of pictures on the media. There is a problem that it takes time.

The above problem is that a sector unique to the media is formed, and the capacity of the sector is equal to the sum of the integral multiple of the capacity of the transport stream, the sector synchronization signal, the sector header, and the error detection code for each sector, and The integral multiple of the capacity of the transport stream is approximately equal to the power of 2 and is realized by not exceeding the capacity.

  In addition, a media-specific sector is composed of a plurality of transport packets, and when the sector data is divided into minimum units of the media-specific data structure and framed for transmission or recording, the media-specific sector is used. A frame for transmitting or recording information indicating whether or not a picture or picture group boundary exists and a picture number or picture group number in the frame of the medium, when performing framing specific to the medium. This is achieved by describing the sub information part in the signal.

Since a certain number of transport streams are always added to each sector, an essential sector sync signal, a sector header, and an error detection code for each sector are added to form a media-specific sector. Can be efficiently recorded on media. In addition, since the transport stream is not divided across two sectors, the reproduction process can be facilitated. Also, the sub information is completed in the same cycle as the sector, and when searching or editing for each picture or group of pictures, it is described in the sub information part in the frame signal specific to the media reproduced from the media. By reading the information indicating whether there is a picture or picture group boundary in the media-specific sector data, the picture or picture group number, and making a decision, Thus, the reproduction position on the medium for reproducing the boundary portion of the picture or the picture group can be accurately and easily detected. Also, since the picture number can be used to find the position of the boundary of the picture or picture group on the medium, complicated control is not required, so that the boundary of the picture or picture group can be searched at high speed.

FIG. 1 shows an embodiment of the present invention and shows a method for transmitting or recording information. Reference numeral 1 denotes a process for converting the compressed data into a transport packet, 2 denotes a signal processing specific to the medium, and 3 denotes a medium for transmitting or recording information. 4 is a process for collecting the transport packet data into a media-specific data structure (sector), 5 is an addition of an error detection code and a sector header, 6 is an addition of an error correction code, an interleave, etc. 7 is a process for extracting information indicating whether each sector includes a boundary between picture groups when time-series data of transport packets are collected into media-specific sectors, and 10 is a frame signal specific to the medium. 8 is a process for adding sub-information to a frame signal, 9 is a process for adding a synchronization signal for each frame of the frame signal, and 11 is a video input or a data application input. This is a process for generating an identification code for identifying. In the following, with reference to FIG. 1, in the compressed data transport packetization processing 1 described for the method of transmitting information or recording signal according to the present invention, compressed video data, compressed audio data, The independent data is packetized by adding a packet header indicating the head of the packet independently. Next, each packet is divided into time series after collecting one or more packets for each data type, and further indicates a transport packet header indicating the beginning of the transport packet and a reference time. Information is added to form a 188-byte transport packet. In the media-specific signal processing 2, first, the transport packet data is grouped in units of 11, and sectors that are media-specific data units are configured. To the sector data, a 4-byte sector header indicating the sector number and the sector data type, a 4-byte error detection code, and a 12-byte sector synchronization signal indicating the head of the sector are added. This is 2088 bytes. When this sector is formed, information extraction processing is performed to indicate whether picture-number or picture-group number and picture group boundaries are included. The sectorized transport packet data is divided into 18 units of 116 bytes in accordance with the signal processing format specific to the media, and a 12-byte error correction code is added, interleaved, etc. to enhance error tolerance. Signal processing is performed. Next, in order to transmit or record the signal-processed data, a framing process according to a frame format unique to the media is performed. In the framing process, 1-byte sub information and a synchronization signal indicating the head of the frame are added to the data subjected to the media-specific signal processing to generate a frame signal. In the present invention, the sub-information is completed in units of 18 bytes and is equal to the sector period. The sub-information of this frame signal is information that indicates which sector, which is unique to the media, includes a picture group boundary. And a picture or picture group number and an identification code indicating whether a video signal is recorded or user data for data application such as a computer is simultaneously inserted during the framing process . Further, if the channel signal has a channel code unique to the medium, channel code modulation according to the modulation rule is performed. If there is no channel code, data is transmitted or recorded by the medium as it is. As described above, according to the present embodiment, the information indicating whether the head of a certain unit of compressed video data (for example, a picture group) is included in the minimum unit of the media-specific data structure, Transmission or recording can be performed using an area for transmitting or recording sub-information different from an area for transmitting or recording main information in a frame signal unique to the medium. In addition, a sector is always composed of 11 transport packets, and both sub-information and sectors are completed in units of 18 frames. Therefore, the relationship between the compressed stream constituent units and the media data configuration is an integer. Thus, the reproduction process can be facilitated. In addition, since the sector, which is a data configuration unit of media, has a configuration in which a minimum amount of attached information is added to a plurality of transport packets, there is no invalid area and recording efficiency on the media can be improved.

  FIG. 2 shows another embodiment of the present invention, and shows a method for transmitting or recording information. Reference numeral 21 denotes user data input, 24 denotes a process of dividing or integrating the input user data into 2048 bytes, and 25 denotes a user who has performed the division or integration. The process of adding dummy data such as fixed data to the data is shown, 22 is a signal processing specific to the medium, and 3 is a medium for transmitting or recording information. is there. 3, 5, 6, 8, 9, and 11 are the same processes as in FIG. Hereinafter, a method of transmitting information or generating a recording signal according to the present invention will be described with reference to FIG.

  In the user data input processing 21, data from a computer or the like is input. In the media-specific signal processing 22, first, the user data is in units of 2048 bytes. The data is divided, 20 bytes of fixed data (for example, all “0”) is added, and one sector of data is a sector that is a unit of data unique to the media so as to be equal to 11 transport packets. Is configured. To the sector data, a 4-byte sector header indicating the sector number and the sector data type, a 4-byte error detection code, and a 12-byte sector synchronization signal indicating the head of the sector are added. This is 2088 bytes. As in FIG. 1, the sectorized user data is divided into 18 units of 116 bytes in accordance with the signal processing format unique to the media, and a 12-byte error correction code is added to enhance error tolerance. Signal processing such as addition and interleaving, and framing processing in accordance with a media specific frame format for transmitting or recording data are performed. The framing process is the same as that shown in FIG. 1, but the sub-information includes the information specific to the medium, which indicates the boundary of the picture group, and the picture- or picture-group number. Only the difference is not. Further, if the channel signal has a channel code unique to the medium, channel code modulation according to the modulation rule is performed. If there is no channel code, data is transmitted or recorded by the medium as it is. As described above, according to the present embodiment, since the user data is 2048 byte units, compatibility with the current CD-ROM can be easily achieved, and the embodiment shown in FIG. Since the processed data is common, it is possible to easily process video signals and computer data compressed by the same recording device and the same playback device. In this embodiment, the capacity of the user data is 2048 bytes, but if it is a power of 2, many computer devices handle the data in units of power of 2, so that the connection Has the effect of easy. In this embodiment, in order to match the sector data capacity of the CD-ROM with the data capacity of 11 transport packets, 20 bytes of fixed data are added in units of sectors. However, priority is given to recording efficiency. Thus, the user data may be 2068 bytes, or the sub information of the sector may be recorded instead of the fixed data.

  Next, the details of the recording format used in the embodiment shown in FIGS. 1 and 2 will be described with reference to FIG. FIG. 4 shows a CD-ROM format, and the compatibility of the recording format shown in FIG. 3 with the CD-ROM format will be described. In FIG. 3, reference numeral 31 denotes a structure of a frame unique to the medium, SY is a frame synchronization signal added in the process 9, SUB is 1-byte sub information added in the process 8, and main is 18 pieces. The divided sector data C1 and C2 are 6-byte error correction codes which are added twice in the process 6. 32 indicates sub-information for 16 frames, S0 and S1 are 1-byte synchronization signals each indicating the head of the 16-frame period, and Q CODE is 10 bytes (80 bits) common to the CD-ROM. Sub information, and P No. Is a 3-byte picture- or picture-group number, and PCT includes information identifying whether it is a compressed video or a computer application and information indicating that the boundary of the picture- or picture-group is in the corresponding sector. The byte code, CRC, is a 2-byte (16 bits) error detection code added to the data excluding S0 and S1. 33 indicates that one sector is composed of 116 bytes of main data 18 frames. Reference numeral 34 denotes the configuration of one sector when a compressed video signal / audio signal is recorded, and reference numeral 35 denotes the configuration of one sector in the case of a computer application. SYNC, HEADER, and EDC are common to both 34 and 35, SYNC is a 12-byte synchronization signal indicating the head of the sector, and HEADER is a 4-byte sector header indicating the sector number and the type of sector data. Yes, EDC is a 4-byte error detection code. 34 PACK1 to PACK11 indicate 11 188-byte transport packets. USER DATA indicates 2048 bytes of user data when used in a computer application, and DUMMY indicates 20 bytes of fixed data. On the other hand, in FIG. 4, which shows the format of the current CD-ROM, 41 indicates the structure of the CD-ROM frame, SY is the frame synchronization signal, SUB is 1-byte sub information, and main is Sector data C1 and C2 are each a 4-byte error correction code. 42 indicates sub-information for 98 frames, S0 and S1 are 1-byte synchronization signals indicating the head of the 98-frame period, and P to W CODE are sub-information of the CD-ROM, Q CODE is composed of 80-bit data and a 16-bit error detection code added thereto. Reference numeral 43 denotes the structure of one sector composed of a 24-byte main data 98 frame. In 43, SYNC is a 12-byte synchronization signal indicating the head of the sector, HEADER is a 4-byte sector header indicating the sector number and sector data type, etc., and EDC is a 4-byte error detection code. USER DATA indicates 2048-byte user data when used in a computer application, DUMMY indicates 20-byte fixed data, and ECC indicates a 276-byte error correction code.

  The effect of the processing based on the format of the present invention shown in FIG. 3 will be described below. First, the total of main, C1, and C2 is 128 bytes, and in the case of the CD-ROM shown in 41, it is 32 bytes. Therefore, extending the code length reduces the code redundancy. Improvement of data reliability is realized. At the same time, the code length is exactly 4 times, which is common with the CD-ROM of the circuit that performs interleave processing. Next, at 32, the Q CODE common to the CD-ROM is recorded to maintain compatibility with the CD-ROM, and the information for facilitating the retrieval of the picture and the video information or the data application are identified. A sign is added to facilitate retrieval of video information. The CRC is configured to maintain the commonality of the processing circuits by using a generator polynomial common to the CD-ROM. The above effect can be obtained even if the number of bytes of PNo and PCT is not as shown in 32. Next, in 34, since one sector is composed of an integer number (11) of transport packets in SYNC, HEADER, and EDC common to the CD-ROM, most of the synchronization detection and error detection processing circuits are used. In addition to the common use with a CD-ROM, a compressed video signal can be recorded efficiently without wasting a recording area. In addition, since the capacity of 11 transport packets is almost equal to the USER DATA capacity shown in 34, which is only 20 bytes larger, the user data of one sector of the CD-ROM is used when data is applied. Even if it is compatible with the capacity, it is possible to record with little waste. In addition, the error correction code that is further added in units of sectors in the CD-ROM is not added, and the increase in C1 and C2 improves the code efficiency while maintaining the same reliability as the CD-ROM. ing. As described above, if the recording process is performed according to the format shown in FIG. 3, the commonality with the CD-ROM is high, and the recording of compressed video signals and the application of data are also possible. High-efficiency recording with little waste in the recording area is possible.

  Next, other effective numerical examples for the format shown in FIG. 3 are shown in FIGS. FIG. 5 shows an example in which one sector is composed of 11 transport packets, and FIG. 6 shows an example in which one sector is composed of 22 transport packets. Note that the numerical example of FIG. 1 is the same as the numerical example shown in FIG. 5 and 6, frame 1 (byte) is the total number of bytes of the main data 31 and the error correction codes C1 and C2 in FIG. 3, and C1 (byte) is the first error correction. The number of bytes of the code C1, C2 (bytes) is the number of bytes of the second error correction code C2, and frame 2 (bytes) is the number of bytes of the frame 1 minus the number of bytes of C1 and C2. The sector (frame) indicates how many frames each sector is composed of, and the sector (byte) is indicated in units of bytes. Note that the present invention has the same effect even if the distribution of the number of bytes of the error correction code to C1 and C2 is different from that shown in the table. Next, the sector (packet) indicates the relationship indicated by 34 in FIG. 3, and indicates how many transport packets each sector is composed of. SYNC (byte), header- (byte), and EDC (byte) indicate the numbers of bytes of SYNC, HEADER, and EDC in 34 and 35 in FIG. It should be noted that the same effect as the numerical examples described in the table can be obtained even if the numerical distribution of SYNC (byte), header- (byte), and EDC (byte) is changed.

  Next, another embodiment of the present invention will be described with reference to FIG. FIG. 7 shows a reproducing apparatus according to the present invention. In this embodiment, the playback apparatus of the present invention is applied to a system having the data structure and frame format shown in FIG. In FIG. 7, 51 is an optical disc, 52 is a signal processing unit specific to the medium, 53 is a subcode determination unit, 54 is a pickup control unit, 55 is a pickup, 56 is a memory, 57 is a write address generation unit for the memory, 58 Is a read address generation unit, 59 is an address comparator, 60 is an output time adjustment unit for time-series data of transport packets, 61 is a reference clock, 62 is a media-specific clock, and 63 is an interface with a host computer. The face is shown.

  First, a case where a compressed video signal is reproduced will be described. The frame signal reproduced from the disc 51 is input to the signal processing unit 52 specific to the media, and the subcode and the main information are separated based on the synchronization signal in the frame signal. The subcode is input to the subcode determination unit 53 to determine whether it is a compressed video signal or data application. In FIG. 3, a code identifying whether the video signal is a compressed video signal or data application is added to each sector, but the disk 51 is added to a subcode of a specific area of the disk 51 (for example, the innermost circumference of the disk). If the identification codes for all the areas are recorded, the status of the entire disc can be known in advance, so that the processing is facilitated. The processing after the video signal is determined continues. First, the operation during high-speed search will be described. During the high-speed search, the frame signal reproduced from the disk 51 is input to the media-specific signal processing unit 52 during the data reading period, and the subcode and main information are separated based on the synchronization signal in the frame signal. To do. The subcode is input to the subcode determination unit 53, where it is determined whether or not it is a picture group boundary. If it is not the boundary of the picture group, the pickup is moved at high speed via the pickup control unit, and the determination by the subcode is repeated. If it is a picture group boundary, playback is performed. In this way, a search can be performed on a picture group basis.

  Next, the operation at the time of reproduction after the search is completed will be described. The reproduced frame signal is input to a media-specific signal processing unit 52, and after subcode and main information are separated based on a synchronization signal in the frame signal, the main information is error-corrected and deinterleaved. Thus, data having a sector structure, which is a data structure unique to the medium, is reproduced. The sector structure data is temporarily stored in the memory 56 in accordance with a media-specific clock and a write address generated based on the reference clock. The data stored in the memory is read according to the read address generated based on the reference clock, and the data in the transport packet format is input to the output time adjustment unit 60. The write address and read address of the memory are always compared by the comparator 59, and when the write address value is separated from the read address value by a certain value or more, the pickup 55 is controlled via the pickup control unit 54 to pause the reproduction. . The data read rate from the disk is always higher than the data transmission rate of the time-series data of the pack, and the playback control described above is performed, so that the transport to which the output of this playback device is connected is performed. It is possible to absorb the excess or deficiency of data with the packet decoding device. The data read from the memory is corrected on the time axis in the output time adjustment unit of the data in the transport packet format. In the transport packet data output time adjustment unit, the time axis is corrected according to the reference time described in the transport packet of the data read from the memory.

  Next, the reproducing operation in the case of data application will be described. As in the case of reproducing the video signal, the subcode determination unit 53 determines whether the compressed video signal is applied to the data. The reproduced frame signal is input to a media-specific signal processing unit 52, and after subcode and main information are separated based on a synchronization signal in the frame signal, the main information is error-corrected and deinterleaved. Thus, data having a sector structure, which is a data structure unique to the medium, is reproduced. The host interface 63 performs control such as instructing the start and end of the write address and the start and end of the read address in accordance with a data request from the host. The sector structure data is temporarily stored in the memory 56 in accordance with a write address generated in accordance with a request of the host interface based on a media-specific clock and a reference clock. The data stored in the memory is read according to the read address generated according to the request of the host interface based on the reference clock, and sent to the host via the host interface. In the search, the subcode has the same Q code as that of the CD-ROM, and the capacity of the user data of one sector is also common with 2048 bytes. -Can easily be done with cans.

As described above, according to the present embodiment, the boundary between picture groups can be searched at a high speed, and a compressed video signal and recording using data can be played back using a recording area effectively. There exists an effect that an apparatus can be comprised.

The figure which shows the transmission or recording method of the information by this invention. The figure which shows the transmission or recording method of the information by this invention. FIG. 4 is a format diagram used in the information transmission or recording method according to the present invention. A conventional format diagram used in information transmission or recording methods. Numerical examples of formats used in the information transmission or recording method of the present invention. Numerical examples of formats used in the information transmission or recording method of the present invention. An information reproducing apparatus according to the present invention.

Explanation of symbols

2 ... Media-specific signal processing unit, 3 ... Media recording processing unit, 4 ... Transport packet integration processing unit, 7 ... Information extracting unit indicating picture group boundary, 8 ... Sub information adding unit, 51 ... Optical disk 52... Media specific signal processing unit 53. Subcode discrimination unit 54. Pickup control unit 55. Pickup 56. Memory 60. Output time adjustment unit 63. Host interface

Claims (4)

A method for reproducing a disc in which a plurality of fixed-length units not having dummy data in which a plurality of fixed-length transport packets including compressed video data and reference time information are collected is recorded,
Detecting the reference time information;
Adjusting the output time of the transport packet at the time indicated by the reference time information, and outputting it;
A disc reproducing method comprising: The disc playback method according to claim 1,
The compressed video data is data obtained by compressing a part of a group of pictures consisting of several pictures,
Information indicating whether or not the first picture of a group of pictures is present in the fixed length unit is recorded on the disc,
Detecting information indicating whether the leading picture exists;
Identifying the unit of fixed length indicated by the information indicating whether the leading picture exists;
Selecting the identified fixed-length unit and playing the first picture;
A disc reproducing method comprising: A disc playback apparatus for playing back a disc in which a plurality of fixed-length units not having dummy data in which a plurality of fixed-length transport packets including compressed video data and reference time information are collected is recorded.
Reference time information detecting means for detecting the reference time information in the previous period;
Output time adjusting means for adjusting the output time of the transport packet at the time indicated by the reference time information,
A disc reproducing apparatus characterized by that. The optical disk apparatus according to claim 3,
The compressed video data is data obtained by compressing a part of a group of pictures consisting of several pictures,
Information indicating whether or not the first picture of a group of pictures is present in the fixed length unit is recorded on the disc,
Detecting means for detecting information indicating whether the leading picture exists;
Identification means for identifying the unit of the fixed length indicated by the information indicating whether the leading picture exists;
Playback means for selecting the identified fixed-length unit and playing the first picture;
A disc playback apparatus comprising:

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