DE19845193A1 - Process for the introduction of audiovisual coded information into a predetermined, frame-structured transmission standard as well as terminals for this - Google Patents

Abstract

In order to integrate audiovisual coded information into a predetermined, frame-structured transmission standard, individual data streams are multiplexed into one or more data channels / channels of the frame-structured transmission standard. In addition, the capabilities of the communicating devices are exchanged.

Description

State of the art

Lower for the transmission of image and sound data Bit rates for multimedia communication are H.324 specification "Terminal for low bitrate multimedia commmunication "specifies a system for Video telephony applications is suitable.

Fig. 1 shows a block diagram of such a multimedia system according to the standard H.324. The modules that are specified in more detail in H.324 are accommodated in the block identified by reference number 1 . The video codec 2 is designed in accordance with the method according to ITU-H.263 / H.261. The audio codec 3 according to ITU G.723 is followed by a delay device 4 in order to compensate for any time differences between the image coding and the sound coding. The device 5 is used to process data protocols, e.g. BV14 LAPM etc., and device 6 processes control protocols according to ITU H.245. The codecs 2 and 3 are supplied with corresponding I / O (input / output) devices 7 and 8 audiovisual data. The devices for processing protocols 5 and 6 receive their input data via the devices 9 (User Data Applications) and 10 (System Control). The data streams of the codecs 2 , 3 and the protocol processing devices 5 and 6 are combined via the multiplexing / demultiplexing device 11 according to the H.223 standard. The downstream modem 12 provides V.34-compliant data for the combined data streams and V.25-compliant data for the system control data. The transmission network 13 connects to the block 1 with the associated network controller 14 .

Advantages of the invention

The method according to the features of claim 1 and the subclaims is suitable for integrating object-based coded information, in particular according to the MPEG-4 transmission standard, into a predetermined frame-structured transmission standard, in particular into an ITU standard, and thus enables the transport of the coded MPEG-4 data . Compared to conventional video coding methods such as the video method according to ITU-H.263 / H.261 and the audio codec according to G.723.1, the following advantages result in particular:

• - object-based coding of synthetic and natural visual objects as well as audio objects,
• - improved coding efficiency,
• - improved visual error robustness of the video Coding,
• - Own format to describe the arrangement audiovisual objects,
• - synchronization of different audiovisual objects,
• - Interaction with audiovisual objects.

The method according to the invention is two different concepts - in the following as concept A and B marked - based. Generally everyone is Concepts suitable for themselves the desired one Functionality - transmission of object-based coded audiovisual information - ensure, however, can Concept A with a large number of objects (i.e. a large number MPEG-4 data streams). Also one A combination of the two concepts is possible.

The process according to the invention therefore has the great advantage that

• - all MPEG-4 data streams - for example when using a large number of objects - using the MPEG-4 FlexMux specification packaged to a data stream be able to decode all the information contains (concept A), or or and
• A one-way communication based on the entire MPEG-4 functionalities can without the need for extensive additional adjustments to the MPEG-4 data to the formats of the communication standard would be required. This is made possible by consistent exploitation of that Multimedia communication standard H.324 provided Mechanisms (concept B).

Furthermore, when exchanging skills and opening the same data structures of a transmission channel used, the data stream types to be transmitted, the coding tools used and their parameters such. B. identify the data capacity.

By using data packets of constant length (at Concept A) or the use of the frame structure of the in H.324 anchored multiplex standards H.223 (for concept B)  the robustness of errors is increased. The synchronization in the data stream after an error is easily possible.

An encapsulation or a merger different systems, e.g. B. Combination of H.324 Platform and MPEG-4 platform is easy to do.

drawings

The invention is explained in more detail with reference to the further drawings. Show it:

• - Fig. 2a and 2b are block diagrams of MPEG-4 multimedia systems based on an H.324 terminal,
• - Fig. 3 shows the structure of a Flex-Mux protocol in Simple Mode constant length,
• - Fig. 4 shows the structure of a Flex-Mux protocol in Mux mode with constant length,
• - Fig. 5 is an adaptation layer frame according to ITU H.223,
• - Figure 6 illustrates the interleaving of the data of the logical ITU channels.
• - Figure 7 shows the header format.
• - Figure 8 is an example of a Multiplex Entry Descriptor.
• - Figure 9 the integration of packets of constant length in the ITU-adaptation-layer variable length..

Description of exemplary embodiments

Before the method according to the invention is described in detail, the standards used are briefly specified for better understanding:
The ITU-H.324 standard specifies a terminal which consists of a video codec according to H.261 / H.263, an audio codec according to G.723, a multiplexer according to H.223 and a control protocol according to H.245 consists. The structure and assembly of the individual components is described in this standard.

The ITU-H.223 standard specifies a package-oriented Multiplex protocol for multimedia communication with low bit rates. It gets lower for transmission Bit rates between two multimedia terminals or one Terminal and a multi-point unit used. The Protocol enables the transmission of any Combination of audio, video and data information about a single communication channel. The log records is characterized by "low delay" and low overhead. The necessary protocol procedures to implement the Multiplex protocols are specified in the H.245 standard.

The standard ITU-H.245 "Control Protocol for Multimedia Communication "specifies the syntax and semantics of Terminal information and messages as well as the procedures for establishing communication. The news enables that Exchange of terminal skills / capabilities, e.g. B. Terminal A signals Terminal B that there is video data can decode and what methods it supports.

Furthermore, a protocol is specified what the reliable transmission of audiovisual data by means of an acknowledge message allowed (Terminal A  Terminal B signals the correct reception of the Data packets).

The standard ITU-H.263 / H.261 specifies the Encoding of compressed video data for channels lower Bit rates.

The G.723.1 standard specifies the decoding of compressed audio data for low bit rate channels.

The following steps are required for the transmission of MPEG-4 data using the H.245 standard:

• 1. First, an exchange of skills (capability Exchange) of the communicating terminals take place to to enable mutual communication. The Data transmission takes place in the intended logical channel 0 according to H.245.
• 2. Furthermore it is necessary to use the MPEG-4 decoder configure. The necessary MPEG-4 specific Information like the Initial Object Descriptor either using H.245 especially the logical channel 0 or via a separate logical ITU channel transmitted, in particular unequal to a logical channel 0 according to the ITU-H.223 standard.
• 3. Then, using the H.245 standard, the individual, logical channels for the transmission of the audiovisual data streams are opened.

to 1 .: exchange of skills (capability exchange)

For the capability exchange, it is sufficient to define an MPEG-4 capability within H.245, which can look like this:

The individual fields of the above data structures are in the MPEG-4 documents (ISO / IEC 14496) explained in more detail. The advantage of this capability definition is based on the low data overhead and a reference to the Specification within the MPEG-4 standard and thus the Avoid overhead of additional definitions in the H.245 standard. The streamType defines the type (i.e. the content) of the data stream, the profiles indicator defines the decoding tools and the level that Parameters of these decoding tools. Inside are MPEG-4 including these parameters with the exception of Level indication, to be specified by MPEG.

The isl4496Capability is also used in Concept B using the "Data Type" field when opening a logical Channel with the H.245 function OpenLogicalChannel the in MPEG-4 data types transmitted on this channel.  

to 2 .: configuration of the decoder

After using the Capability Exchange Terminal capabilities are defined, the configuration the decoder by transmitting the initial object Descriptors or the Object Descriptors carried out. This is done either by means of a request / confirm Commands according to H.245, within which the initial object Descriptors can be exchanged or by opening of a new logical ITU channel, which is only the initial Object descriptor or the SL-packetized object Contains descriptor stream.

to 3 .: opening of the logical channels and data transmission

After configuration, the individual ITU channels are opened. In general:
The audio-visual coded information, in particular in accordance with MPEG-4, is processed into separate data streams. An encoder that generates an MPEG-4 compliant data stream already delivers several of these separate data streams at its output, in particular SL (synchronization layer) -packaged data streams. In Fig. 2a and Fig. 2b, the elementary data streams (El. Streams) on "Elementary Stream Interface" Sync (synchronization) layer are shown. It should be noted here that the header of the SL packets can also be configured to "NULL" - ie omitted. The elementary data streams are packaged within this "sync layer", which can then be tapped at the "Stream Multiplex Interface" for further processing.

According to concept B, a logical channel is opened with the OpenLogicalChannel Message defined in H.245.  

When the respective logical channel is opened, the "portNumber" field serves to signal the assigned elementary data stream identification (ES_ID), by means of which the data streams are referenced on the MPEG-4 side. With the "streamType" field, to which the value of an Isl4496Capability is assigned (the same data structures as for the Cpability Exchange can be used), the content of a logical channel (ie the MPEG-4 object type) is explicitly specified . In concept B, the actual - then subsequent - data transmission involves tapping each individual SL-packetized MPEG-4 data stream at the "Stream Multiplex Interface" and transmitting it in a logical ITU channel. For this purpose, the SL-packetized MPEG-4 data streams are further processed by the H.223 AdaptationLayer as AL-SDU packets and multiplexed using the H.223 standard (exemplary embodiment according to FIG. 2a). This transfer of the MPEG-4 framing of the data into a framing according to H.223 (SL-PDU: = AL-SDU) increases the robustness of the error and allows simple resynchronization if a packet was transmitted incorrectly. This also avoids any otherwise necessary adaptation of the MPEG-4 data format to the format of the multiplexer. Concept B enables the (later) dynamic addition of further MPEG-4 data streams.

For the implementation of concept A, the individual data streams are multiplexed into a total of only one data stream by means of the MPEG-4 FlexMux and transmitted in a total of one logical ITU channel (exemplary embodiment according to FIG. 2b). For this type of transmission of MPEG-4 data streams using FlexMux, additional descriptors are defined that enable the connection to be established. Only with these is it possible to recognize the individual MPEG-4 data streams. These MPEG-4-specific data streams are multiplexed using the MPEG-4 Flexmux tool. This defines the use of packets of constant length, which increases the robustness of errors. The synchronization in the data stream after an error is possible.

Concept A is described in detail below.

As FIG. 2b shows, the following logical MPEG-4 objects (SL-packetized data streams) can be multiplexed into a transmission frame using the MPEG-4 FlexMux tool and transmitted in a logical ITU channel AL1:
SL audio,
SL video,
SL-OCR (Object Clock Reference),
SL-OD (Object Descriptor),
SL-OCI (Object Content Information).

In a slight modification of Concept A, it is too possible to use data of the same type only (e.g. either only SL audio or only SL video) into a logical one Multiplex the channel using the FlexMux tool, d. H. the The entirety of the MPEG-4 data streams in turn in several (albeit less than with Concept B) logical ITU- Channels. This would u. May be an easier one Separation and decoding of the multiplexed data in the Allow recipients. In the following, however, again the original concept A, i.e. the multiplexing of all MPEG data streams in a logical ITU channel using the FlexMux tools considered.

Concept A (like Concept B) enables Transmission of several MPEG-4 data streams of the same type, such as B. the transmission of multiple audio streams for one Image accompanying sound in different languages.  

For the process according to concept A it is necessary MUXCODETABLE_Entry during the initialization phase to configure the MPEG-4 FlexMux.

Ultimately, the MPEG-4 decoder must be the one made Assignment of the individual ES currents to the ones to be multiplexed Data are communicated. This is done using a channel Map table (also called stream map table) reached.

These two pieces of information are next to the object Descriptors required for decoding.

In order to insert the additional information MUXCODETABLE_Entry and Channel Map Table in the Initial Object Descriptor, the definition of new descriptors is necessary. These are inserted in the form of extension descriptors in the initial object descriptor.

The bold part shows the newly defined part Descriptor.

A MuxCodeTableEntryDesccriptor can be constructed similarly:

The bold part shows the newly defined part Descriptor. The data field numberofMuxCodeTableEntries  enables the transfer of the maximum of 16 MuxCodeTableEntries. Using the constantLengthFlag and the The FlexMuxLenth field signals to the recipient that the FlexMux packages of constant length with the package size FlexMuxLenth + 2 can be transferred.

The FlexMux packets defined in MPEG-4 are transmitted on the one hand in the simple mode according to FIG. 3 and on the other hand in the MuxCode according to FIG. 4.

By using packages of constant, odd length, here 127 bytes, can be the upper 7 bits of the length field can be used for synchronization.

This increases the robustness of errors and allows one Resynchronization if a length field of a packet is faulty.

These FlexMux packages must now be integrated in an ITU frame. In Fig. 5, an adaptation layer (AL) frame in accordance with ITU-H.223 is shown with an AL-PDU (Protocol Data Unit) payload Field. Due to the variable length of a FlexMux package, it would no longer be possible to find a new FlexMux package after an error in the length field. This is particularly harmful if several MPEG-4 elementary streams (e.g. BIFS, OD, and video) are transmitted in one ITU channel.

By using constant lengths within the MPEG-4 FlexMux packages, according to the invention, are now again possible.

The individual AL-PDU packets of variable length are now packed by means of the multiplexer.

The structure of the multiplex layer and the basic one Integration of the MPEG-4 FlexMux data stream will be short explained.  

A MUX Protocol Data Unit (MUX-PDU) consists of a header and an information field, in which the data of the individual logical ITU channels are nested. Fig. 6 shows the structure.

The header consists of individual fields, which are shown in FIG. 1.

The 4-bit multiplex code points to one via H.245 transmitted MultiplexEntry, of which a maximum of 15 different can be defined.

The header error control field is a 3 bit CRC Field that allows error detection in the header.

The 1-bit packet marker field marks the end of a MUX SDU of a segmented logical channel.

The information field shown in FIG. 6 is configured using the multiplex table transmitted in H.245.

The information field can be closed at any time with a closing flag be terminated at an octet boundary, however a MUX-SDU from a non-segmentable channel to be interrupted.

The MultiplexEntryDescriptor configures the H.223 multiplexer and is transmitted in the initialization phase ( Fig. 8).

In this figure, LCN means: LogicalchannelNumber, RC: RepeatCount, UCF: UntilClosingFlag.

The advantage is clear in FIG. 9:
If several MPEG data are transmitted in one ITU channel and MPEG-4 packets of variable length are used, then all subsequent FlexMux packets can no longer be decoded. The clever use of the length field as a synchronization marker allows the synchronization of the receiver.

The sending terminal signals the receiving one Terminal the packet length using the one defined here MuxCodeTableEntryDescriptors represented by a flag is marked, which indicates the use of FlexMux Packets of constant length are signaled and still on Contains a field that defines the length to be used. This is associated with great flexibility great robustness against errors.

The invention can of course not only for MPEG-4 data used, but also for other audiovisual encoded information into a standardized The transmission frame must be integrated and its decoding should be simple and robust.

The method presented can of course in the transmitter and receiving devices can be implemented. For the Integration on the transmitter side must have the appropriate means for Processing or delivery of audiovisual coded information can be provided as well as corresponding Means for multiplexing the data streams, for exchanging the Skills and signaling. For the receiving end Evaluation are means of decomposing the multiplexed Data channels and means for exchanging skills and their evaluation and evaluation of the signaling necessary. Because usually worked in dialogue subscriber terminals are for both the transmitting and also equipped for reception.

Claims (15)

1. A method for integrating audio-visual coded information into a predetermined frame-structured transmission standard with the following steps:

• 1. the audiovisual coded information is processed into separate data streams or is delivered in the form of separate data streams,
• 2. the individual data streams are multiplexed into one or more data channels / channels of the frame-structured transmission standard,
• 3. the capabilities, in particular the coding and decoding capabilities, of the communicating terminals are exchanged after a connection has been set up,
• 4. data structures of a coding standard are used for signaling, the information about the data type used, the decoding tool to be used and the coding parameters such as B. contain the data capacity.

2. The method according to claim 1, characterized in that the data structures involved in sharing skills and be used when opening a transmission channel, are chosen equal. 3. The method according to claim 1 or 2, characterized characterized that for example for object-based Audiovisually encoded information with a small number of objects the corresponding data streams using a multiplexer,  especially a multiplexer according to the H.223 standard, be packetized and in individual transmission channels, especially ITU channels according to the H.245 standard, be transmitted. 4. The method according to claim 3, characterized in that to assign the individual packages within them assigned transmission channels, a data field ("portNumber" field) is used with an MPEG-4 Transfer an identification of the individual elementary Contains data streams (ES-ID). 5. The method according to claim 3, characterized in that the data format of the MPEG-4 Output data streams (SL-PDUs) is taken over directly, see above that no further reformatting is necessary. 6. The method according to claim 3, characterized in that Object descriptors, especially the "Initial Object Descriptor "according to MPEG-4, for audio-visual coded Information in a separate channel, especially one logical channel not equal to 0 according to ITU-H.223 Standard to be accommodated. 7. The method according to claim 3, characterized in that for object-based audiovisually coded information - for example, with a large number of objects - the corresponding ones Data streams multiplexed into a common data stream and in a transmission channel, especially in an ITU channel. 8. The method according to any one of claims 1, 2 or 7, characterized characterized in that in addition to the multiplexed data streams in the transmission frame of the frame-structured Transmission standards a signaling information  is housed, which indicates that multiplexed Information packets of constant length are transmitted, due to which a synchronization, especially with faulty data packets, is feasible. 9. The method according to any one of claim 1, 2 or 7, characterized characterized in that object descriptors, especially the "Initial Object Descriptor" according to MPEG-4, for audiovisual encoded information in an additional channel, in particular the logical channel 0 corresponding to the ITU H.245 standard. 10. The method according to any one of claims 1, 2, 7 or 8, characterized in that mapping data between the separate data streams, especially SL packetized MPEG-4 Elementary data streams and the multiplexed data in the additional channel, in particular logical channel 0 according to the ITU-H.245 standard. 11. The method according to any one of claims 1, 2, 7, 8 or 9, characterized in that for the Signaling information data fields are provided which on the one hand the constant length and the package size of the mark multiplexed information packets. 12. The method according to any one of claims 1, 2, or 7-10, characterized in that encoded as audiovisual Information MPEG-4 data are used that lead to Flex-Mux Packets of constant length are prepared, and that this Flex mux packets of constant length in one Transmission frames are multiplexed, the one Transfer possible according to ITU standard H.324. 13. The method according to any one of claims 1 to 12, characterized characterized that within the "adaptation layer"  variable length according to ITU standard H.324 several MPEG-4 Data housed in data packets of constant length are, whereby in the beginning of these data packets each a length field is provided, which as Synchronization identifier, in particular for Synchronization of a receiver that can be used. 14. Terminal for integrating audiovisual coded information into a predetermined frame-structured transmission standard with the following features:

• 1. means for processing the audiovisual coded information on separate data streams to the terminal or for delivery in the form of separate data streams to the terminal,
• 2. Means for multiplexing the individual data streams into one or more data channels / channels of the frame-structured transmission standard,
• 3. means for exchanging the capabilities, in particular the coding and decoding capabilities, with further terminals, in particular after a connection has been set up,
• 4. Means for signaling using data structures that contain information about the data type used, the decoding tool to be used and the coding parameters such as the data capacity.

15. Terminal for evaluating audiovisual coded information at the receiving end in a predetermined frame-structured transmission standard with the following features:

• 1. means for splitting one or more multiplexed frame-structured data channels of a transmission standard into individual audiovisual data streams,
• 2. Means for exchanging the capabilities, in particular the coding and decoding capabilities, with further terminals, in particular after a connection has been set up,
• 3. Means for signaling using data structures that contain information about the data type used, the decoding tool to be used and the data capacity.