Patent Document

FIELD OF THE INVENTION 
       [0001]    This application relates to a method of generating in real-time an audio-video transport stream from a sequence of audio-video data fragments, a method of generating metadata associated with said audio-video transport stream, use of said methods in a game engine, a method of submitting a digital signal in real time by means of a data stream, a method of playback in real time of a received digital signal. The application also relates to an apparatus for generating an audio-video transport stream in real time, an apparatus for generating metadata associated with said audio-video transport stream, a broadcasting system for submitting a digital signal and a playback system for receiving and playing back a digital signal. 
       BACKGROUND OF THE INVENTION 
       [0002]    New forms of consumer electronics are continually being developed. Many efforts have been focused on the convergence of Internet and home entertainment systems. Important areas are interactivity and enhanced functionality, by merging broadcasted audio-video content with locally available audio-video content. Several industry discussion forums in the area of Digital Video Broadcast (DVB) like the European MHP (Multimedia Home Platform) or the US Dase Platform disclose the use of Internet resources to enhance functionality. 
         [0003]    For example, it is envisioned that next generation optical disc players/recorder, for example such as Blu-ray players/recorder, will have the functionality that audio and video data can be streamed from a studio web server, to be displayed on the TV by the BD-ROM player. This streaming happens by dividing the video data into many small files on the server, and then downloading these files individually via HTTP requests. After being played, these small files optionally can be deleted again. Said streaming method is also known in the art as ‘progressive playlist’. 
         [0004]    Data Structures: 
         [0005]    A preferred encoding method for encoding audio-video content is variable rate encoding, as it allows higher levels of compression for a given encoding quality level. Consequently, in order to allow trick-play, metadata with respect to the video and audio information is stored on optical disc in addition to the audio-video content. For example, in the case of Blu-ray read-only optical disc (BD-ROM) metadata about the video multiplex is stored in separate files on the disc. Most important is that metadata corresponding to the characteristic point information is stored is separate files known as clip files. The characteristic point information comprises a mapping between points on the time axis for playback and offsets in the transport stream file. The characteristic point information is used to support trick-play modes, and cases where playback has to start from a particular point on the time axis. For transport stream files video data, the characteristic point information mapping usually contains one entry for each I-frame. For transport streams with audio data only, the mapping usually contains entries at regular intervals. For complete playback of the video, the ‘playback engine’ needs three levels of files: playlist, clip and transport stream. 
         [0006]    More information about the data structures as envisioned for Blu-ray application can be found in the following white papers: “Blu-ray Disc Format: 2a-logical and audio visual format specifications for BD-RE” and “Blu-ray Disc Format: 2b-logical and audio visual format specifications for BD-ROM”, to be inserted herein by reference. The white paper on the recordable format (BD_RE) contains detailed information about the structure and the contents of the clip information files, which is also applicable to the BD-ROM format. 
         [0007]    Data Structures and Playlists 
         [0008]    In  FIG. 1 , said three levels of files that are required for playback are illustrated, for example, corresponding to the case of a movie trailer that should be streamed with the ‘progressive playlist’ method. There is one playlist file on the top row, corresponding to the full movie trailer, describing many small parts. In the middle row are clip files comprising metadata used for playback of each small part, at the bottom there are transport stream files for each small part. 
         [0009]    To ease the player implementation, it is necessary that the playlist and clip files are ALL made available to the playback mechanism before playback is started. These files are small anyway, so downloading them all does not delay the start of playback too much. However, there is a problem in the case of live streaming, because: 
         [0000]    a) the clip files have to comprise pointers to exact byte positions inside the transport stream files; while
 
b) the higher-number transport stream (mt2s) files are not available yet, because they still have to be recorded.
 
         [0010]    In other words, the problem is how to align the pointers in the clip files, which have to be available from the start, with the data in the transport stream files, which is not available yet because they still have to be recorded. 
       SUMMARY OF THE INVENTION 
       [0011]    It is an object of the invention to provide a solution to the above-mentioned problem. This object is achieved by generating in real-time an audio-video transport stream characterized as recited in claim  1 . The term ‘real-time’ is used somewhat loosely in the art. With respect to this invention, we define ‘real-time’ as a time period, which starts after the point in time at which both presentation time lengths and bit lengths, as described below, have been pre-determined. 
         [0000]    An audio-video transport stream is generated in real time by assembling together a sequence of audio-video data fragments of variable bit length and predetermined presentation time length in the order said fragments are generated or received. The generation is performed such that parts of the audio-video transport stream (i.e. a transport stream containing either audio, or video, or both) corresponding to subsequent audio-video data fragments are separated by padding data. The amount of the padding data between subsequent parts is chosen such that a distance between locations of a start of the subsequent parts corresponds to a predetermined bit length. Adding padding data as described hereinabove leads to an audio-video transport stream comprising a sequence of parts of predetermined presentation time lengths and predetermined bit lengths. The presence of parts of predetermined presentation time lengths and predetermine bit length in an audio-video transport stream according to the invention carries the advantage that the associated metadata required for playback is predictable and can be computed and made available to the playback mechanism in the player before all the audio-video data fragments are made available. Consequently, if such associated metadata is computed and made available to the player, real-time playback of ‘live’ audio-video content, i.e. content containing data bits that were created during the real-time period, is made possible. 
         [0012]    In an advantageous embodiment, the predetermined bit length is constant, i.e. the same for all fragments, the value of the constant being chosen such that it is larger than a maximum expected bit length of a audio-video data fragments. The audio-video data fragments can advantageously have a constant predetermined presentation time length; therefore the expected maximum bit length can be predicted based on the used compression parameters. One has to ensure that the amount of padding data required to reach the predetermined bit length of a part is positive. If there is at least one audio-video data fragment whose bit length exceeds the predetermined bit length, the associated metadata cannot be generated before the full sequence of audio-video fragments is generated or received. 
         [0013]    In an advantageous embodiment, the audio-video transport stream is generated by further assembling audio-video data from a second audio-video transport stream together with the received or generated audio-video data fragments. Preferably, in the case of video multiplexing, the filler data takes the form of null packets. 
         [0014]    The invention also relates to a method of generating metadata associated with an audio-video transport stream that can be generated from a sequence of audio-video data fragments, the generation of the audio-video transport stream taking place according to inventive method described hereinabove. The method is characterized by the metadata comprising at least information about the location of a beginning and about a presentation time of a part of the audio-video transport stream corresponding to an audio-video data fragment, and the metadata being generated before at least one of the audio-video data fragments is generated or received. Such a method of generating metadata carries the advantage that the metadata can be made available to a playback device before all the audio-video data fragments is generated or received, therefore enabling real time streaming. 
         [0015]    The invention also relates to a method of submitting a digital signal in real time by means of a data stream, the data stream comprising an audio-video transport stream being generated from a sequence of audio-video data fragments according to the corresponding inventive method described hereinabove and associated metadata being generated according to the corresponding inventive method described hereinabove. 
         [0016]    The invention also relates to a method of submitting a digital signal in real time by means of a data stream, the data stream comprising a sequence of audio-video data fragments being generated according to the corresponding inventive method described hereinabove and associated metadata being generated according to the corresponding inventive method described hereinabove. 
         [0017]    The invention also relates to a digital signal either comprising an audio-video transport stream generated according to the corresponding inventive method describe hereinabove or comprising metadata associated to an audio-video transport stream, the metadata generation taking place according to the corresponding inventive method describe hereinabove. 
         [0018]    The invention also relates to the use in a game engine of the method of generating in real-time an audio-video transport stream according to claim  1  or of the method of generating metadata associated with an audio-video transport stream according to claim  5 . With a game engine, we mean a system that does not generate audio-video content by recording something in the real world, but that generates audio-video content by computational means, to represent a simulated or virtual reality, e.g. a reality inside a game. 
         [0019]    The invention also relates to an apparatus for generating an audio-video transport stream according to claim  16 . 
         [0020]    The invention also relates to an apparatus for generating metadata associated with a sequence of audio-video data fragments. 
         [0021]    The invention also relates to a broadcasting apparatus comprising an apparatus according to the invention for generating an audio-video stream. 
         [0022]    The invention also relates to a broadcasting apparatus comprising an apparatus according to the invention for generating metadata associated with a sequence of audio-video data fragments. 
         [0023]    The invention also relates to a playback apparatus for receiving and playing back a digital signal according to the invention. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0024]    The features and advantages of the invention will be appreciated upon reference to the following drawings, in which: 
           [0025]      FIG. 1  illustrates schematically the three levels of files: playlist, clip, and transport stream required by a playback apparatus in order to be able to playback an audio video transport stream; 
           [0026]      FIG. 2  illustrates schematically method of generating an audio-video transport stream and a method of generating metadata associated with said audio-video transport stream according to an embodiment of the invention; 
           [0027]      FIG. 3  illustrates schematically a transmission system comprising a broadcasting apparatus and a playback apparatus according to an embodiment of the invention; 
           [0028]      FIG. 4  illustrates schematically a broadcasting apparatus according to an embodiment of the invention; 
           [0029]      FIG. 5  illustrates schematically a playback apparatus according to an embodiment of the invention. 
       
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
       [0030]    In  FIG. 1  the three levels of files required by a playback apparatus in order to be able to playback an audio-video transport stream are illustrated. For example this may correspond to a movie trailer that should be streamed according to the ‘progressive playlist’ method. There is one playlist file  11  on the top row, in the above-mentioned example corresponding to the full movie trailer to be streamed, the playlist file  11  describing many small items. Associated with this playlist file  11 , clip files  12 ,  15  corresponding to each small item are illustrated in the middle row. 
         [0031]    At the third level, to each clip file  12 ,  15 , a corresponding transport stream file  13 ,  14  is associated. In the case of live streaming; the hashed transport stream files  14  are not yet available to the playback apparatus, i.e. they have not yet been received and/or generated). The problem is that the playback apparatus requires that the clip files  15  associated with these non-available transport stream files  14  to be available before the playback is started. 
         [0032]      FIG. 2  illustrates schematically method of generating an audio-video transport stream and a method of generating metadata associated with said audio-video transport stream according to an embodiment of the invention that overcome the above-mentioned problem. 
         [0033]    For example, a camera  102  makes a live recording of a director  101  commenting a movie. The recording takes the form of a transport stream  103  comprising a sequence of audio-video data fragments of unequal bit lengths but of equal presentation time lengths. For example, a single fragment  105  comprises a corresponding characteristic point  104 . Because of the unequal sizes of the fragments  105 , these characteristic points  104  appear in the transport stream  103  at unequal offsets  109 , in the example illustrate in  FIG. 2 , the offsets being 0, 30, 60, 80. The clip file  106  corresponding to a fragment  105  needs to comprise information about these characteristic points, that is it should comprise the list of all offsets. Such list of offsets associated with the transport stream  103  cannot be generated before the full transport stream  103  is available. In contrast, in a method of generating associated metadata according to the invention, pointers  107  are added in the clip file  106  at widely spaced playback offsets  110 . In a method of generating an audio-video transport stream  121  according to the invention, padding data  108  is inserted between the individual fragments  111  in the generated audio video transport stream  121 . Before the audio video transport stream  121  is supplied to the playback engine, it is ensured that the playback offsets  110  in said transport stream  121  match corresponding pointers  107  in the clip file  106 . Therefore metadata associated with a transport stream  121  according to the invention can be predicted and generated in advance before the actual data fragments are generated. Consequently the associated metadata can be downloaded before the beginning the process of playback of video, as required by the player. 
         [0000]    
       
         
               
               
               
             
               
               
               
             
           
               
                   
                   
               
               
                   
                 Presentation Times (PTS) 
                 Source packet number 
               
               
                   
                 sequence (seconds) 
                 (SPN) 
               
               
                   
                   
               
             
             
               
                   
               
             
          
           
               
                 Known TS (103) 
                 0 s, 0.5 s, 1 s, 1.5 s . . . 
                 0, 30, 60, 80 . . . 
               
               
                 Inventive TS (121) 
                 0 s, 0.5 s, 1 s, 1.5 s . . . 
                 0, 100, 200, 300 . . . 
               
               
                   
               
             
          
         
       
     
         [0034]    For example, in the case of Blu-ray disc (BD) media and players, the clip info files comprise information with respect to the presentation times (PTS) and file positions (SPN, source packet number) of I-frames. In practice, pre-determined spacing between fragments should be larger than shown in table 1 above, to handle worst-case group of picture (GOP) length for the recording. Moreover, besides creating fixed I-frame locations, padding might also be used to get fixed locations for some other SPN references in clip info file. If the streamed data is to be kept for a long time on local storage, then padding data can be removed to save space. In that case, new clip (CPI) info files, containing SPN locations of un-padded TS files, may be used. 
         [0035]      FIG. 3  illustrates schematically a transmission system comprising a broadcasting apparatus and a playback apparatus according to an embodiment of the invention; Further references will be made to the audio transport stream  121  according to the invention and the associated metadata  106  according to the invention, as disclosed with respect to  FIG. 2 . 
         [0036]    For example a recording that is made live by a camera  102  is made available in real time as a transport stream (TS 2 ) by a broadcasting apparatus, for example a studio web server  300 . The transport stream TS 2  is received or downloaded by a playback apparatus  400 , for example a Blu-Ray disc (BD) player. Usually a control layer ( 401 ), in the case of Blu-Ray disc (BD) player a Java program running on a Java Virtual Machine, is controlling the download of the transport stream TS 2 . 
         [0037]    Preferably, though not essentially, the transfer of the recorded data  103  is done before the padding data  108  is added. The padding data  108  is preferably added on the player  400  side, by the Java program  401  that controls the downloading process. This Java program  401  therefore needs to have: 
         [0000]    1) the recorded data, i.e. the sequence of audio video fragments  103  (which may be retrieved over the network, preferably in the form of files requested via HTTP);
 
2) additional instructions that specify how filler data should be added to the recorded data, in order to produce transport stream files that are aligned with the clip files.
 
         [0038]    These additional instructions could be: 
         [0000]    a) sent over the network (in which case it preferably takes the form of a list of offsets and lengths), as illustrated in  FIG. 2  or in table 1;
 
b) might also be stored on the disc, or be encoded in the Java program itself. In this latter case, the data preferably takes the form of instructions of how to parse (recognize certain markers) the downloaded recorded data, and how to act when encountering certain markers.
 
         [0039]    Another, less preferred solution is that the padding data is added at the studio web server side, after which the file is compressed, before being transferred over the network. The file is then decompressed in the player after it was received. 
         [0040]    The locally generated or the downloaded clip file is stored in a storage space  403  (either memory or on disc). 
         [0041]    Note that, although the figures and the text of the application focus on live streaming of audio/video data, in other cases just an audio track could be streamed live, without any video. A special example of this latter case is a live event where the director speaks audio commentary while controlling the playback of the movie that is stored on the disc in the BD-ROM player. That way, the director can respond to questions by showing a part of the movie, while speaking in a voice-over. 
         [0042]      FIG. 4  illustrates schematically a broadcasting apparatus according to an embodiment of the invention; 
         [0043]    Input means ( 301 ) receive the audio-video content to be streamed. A compressor ( 302 ) compresses the audio-video content into an MPEG2 stream (MPEG2). The compression preferably comprises variable bit compression rate. Optionally, a scrambler ( 303 ) may scramble the MPEG2 stream by encrypting it under the control of a content key, and then it delivers the MPEG2 stream to a multiplexer ( 304 ). In addition to the MPEG2 stream, the multiplexer ( 104 ) may also receive one or more scrambled or non-scrambled data streams (DS) and further digital signals from a controller ( 305 ). The multiplexer ( 304 ) assembles by time-multiplexing the scrambled or unscrambled MPEG2 stream and the one or more data streams (DS) into a transport stream (TS 1 ) comprising a sequence of audio-data fragments of fixed presentation time length and variable bit length. The scrambling and multiplexing may be performed in separate units, and if desired, at different locations. As such a transport stream (TS 1 ) comprises one or more types of streams, also known to the person skilled in the art under the name services, each service comprising one or more service components. A service component is also known as a mono-media element. Examples of service components are a video elementary stream, an audio elementary stream, a subtitle component, a Java application (Xlet) or other data type. A transport stream is formed by time multiplexing one or more elementary streams and/or data. 
         [0044]    A broadcasting apparatus according to the invention may comprise padding means ( 307 ) for adding padding data to the transport stream (TS 1 ) and generating a padded transport stream (TS 2 ) according to one of corresponding methods described with reference to  FIGS. 2 and 3 . Such padding means ( 307 ) may be implemented as a separate hardware unit or preferably may be integrated in the controller ( 305 ) by means of suitable firmware. The broadcasting apparatus according to the invention may further comprise a metadata generating means ( 306 ) for generating associated metadata according to one of corresponding methods described with reference to  FIGS. 2 and 3 . Such metadata generating means ( 306 ) may be implemented as a separate hardware unit or preferably may be integrated in the controller ( 305 ) by means of suitable firmware. The generated metadata is either provided by the controller  305  to the multiplexer  304  to be inserted in as a component of either of the two streams or directly supplied in form of a separate file to a transmitter ( 308 ). 
         [0045]    The transmitter ( 308 ), which, for example, may be a web server, generates the live signal (LS) to be distributed. Depending on the specific embodiment, the transmitter ( 308 ) may receive either the audio video stream (TS 1 ) comprising the sequence of audio data fragment (the preferred embodiment) or the padded audio video stream (TS 2 ). The transmitter may also receive the associated metadata from the controller  305 . 
         [0046]      FIG. 5  illustrates schematically a playback apparatus according to an embodiment of the invention; 
         [0047]    Typical examples of playback apparatuses  400 , where the invention may be practiced, comprise set-top-boxes (STB), digital television units equipped with Digital versatile Disc (DVD) and/or Blu-ray Disc (BD) playback abilities, or computer based entertainment systems, also known under the name Home Media Servers. While not necessary for practicing our invention, the playback apparatus  400  may comply with a defined open platform like the European MHP (Multimedia Home Platform) or the US Dase Platform. These public platforms define several types of applications that may be recognized and executed by the end user system. For example, the European MHP platform specifies that applications may be included as Java™ applications. Such applications are also known to the person skilled in the art under the name Xlets. 
         [0048]    A demultiplexer  501  splices the received live signal (LS) into a data stream  502  and audio  503 , video  504 , and subtitle  505  streams. The audio, video and subtitle streams ( 503 , 504 , 505 ) are fed to a controller  506 , which via a specific operating system controls all the software and hardware modules of the playback apparatus  400 . The audio/video content may also be passed through a conditional access sub-system (not shown in  FIG. 5 ), which determines access grants and may decrypt data. The controller  506  provides the audio  503  and video  504  and subtitle  505  streams to a playback/recording engine  518  that converts them into signals appropriate for the video and audio  519  rendering devices (for example display and speakers, respectively). 
         [0049]    The functioning of the playback apparatus is under the control of a general application controller  509 . For example, in the case of BD players, this corresponds to an abstraction layer, known in the art under name the Application Manager, being present between any application to be executed by the playback apparatus and the specific system resources of the playback apparatus. The data stream  502  outputted by the demultiplexer  501  is fed to the Application Manager  509 . Any application comprised in the data stream  502  will be executed by the Application Manager  509 . 
         [0050]    As discussed above with respect to the broadcasting apparatus  300 , the data stream comprised in the received live signal according to the invention should comprise either associated metadata or instructions how to generate the associated metadata. Consequently the Application Manager  509  may comprise means  521  for generating metadata. The Application Manager  509  may generate or transmit the metadata, for example in the form of clip files, to metadata storage means  517 , which may correspond to a memory or a suitable storage media. 
         [0051]    The controller  506  may further comprise assembling means  507  for receiving several audio, video and subtitle streams and assembling them into an audio video transport stream. Padding means  508  ensure adding padding data according to the invention, as disclosed with reference to  FIGS. 2 and 3 . Such assembling means  507  and/or padding means  508  may be implemented as a separate hardware unit or preferably may be integrated in the controller  506  by means of suitable firmware. The assembling means  507  and the padding means  508  may be controlled by the Application manager  509 . 
         [0052]    The playback apparatus comprises means  511  for reading and/or writing from/onto a record carrier  510 . Such reading and/or writing means  511  are known in the art and will not be detailed further. The apparatus may comprise demultiplexer  512  for de-multiplexing audio-video content that is read from the record carrier  510 . Although shown as different blocks in  FIG. 5 , the two demultiplexer  501  and  512  for de-multiplexing the live stream (LS) and the audio-video content that is read from the record carrier  510  may be embodied by a single demultiplexer able to handle multiple input streams. 
         [0053]    The assembling means  507  may assemble the received streams ( 503 ,  504 ,  506 ) or parts thereof with the stream ( 514 , 515 , 516 ) read from the record carrier  510  or parts thereof. This happens, for example, in the previously discussed example of a live event where the director speaks audio commentary while controlling the playback of the movie that is stored on the record carrier. 
       Additional Considerations 
       [0054]    The methods described here are not restricted to MPEG-2 files, but are also applicable to files made with other codecs. It can also be applied to audio files (e.g. in the case of pre-recorded video from a disc is mixed with streamed audio files). Also, the methods are not restricted to transport streams; they can also be used for systems with program streams or other audio-video data packing methods. 
         [0055]    It is noted that the above-mentioned embodiments are meant to illustrate rather than limit the invention. And those skilled in the art will be able to design many alternative embodiments without departing from the scope of the appended claims. In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. Use of the verbs “comprise” and “include” and their conjugations do not exclude the presence of elements or steps other than those stated in a claim. The article “a” or an” preceding an element does not exclude the presence of a plurality of such elements. The invention may be implemented by means of hardware comprising several distinct elements and/or by means of a suitable firmware. In a system/device/apparatus claim enumerating several means, several of these means may be embodied by one and the same item of hardware or software. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.

Technology Category: 5