SE517859C2 - Dynamic allocation of data streams in frames represented by frame descriptive indexes - Google Patents

Abstract

The present invention relates to a method of representing a number of carried streams (1a, 1b, and 1c) in a common carrying data stream (1). A so-called carried data stream is a sequence of mutually related stream elements. The carrying data stream (1) is organised in frames (11, 12) and each frame includes stream elements belonging to one or more different carried data streams. Respective frames (11, 12) include a frame descriptive index (111, 112). Mutually sequential frames can be used to transmit mutually different carried data streams and can include different large amounts of data information. Carried stream elements contained in a frame may be allocated spaces of mutually different size and thus include different amounts of data information. The frame descriptive index (111, 112) enables the contents of respective frames to be interpreted.

Description

517 859 2 work Architecture based on Fast Circuit Switching ", Department of Teleinformatics, KTH, Stockholm 1996. More information on this can be found in patent publications SE-460750, SE-506548, SE-508794 and SE-508889.

In data packet management, information to be sent from a sender to a receiver is divided into data packets. These include a head and a load. The main contains, among other things, addressing information and information about the size of the package. The load contains the information to be transferred. In the following description, therefore, for the actual information to be transmitted, data information will be referred to, while necessary information for addressing, etc., will be referred to in another way.

When processing data packets, the time interval between two packets as well as the size of different packets can vary.

An example of a protocol that handles data packets is the protocol used on the Internet, Internet Protocol (IP). Here, a packet from a sender is sent out on the Internet with a recipient address in the header and an information-bearing part that can vary in size from packet to packet. Two consecutive packets are processed in the network completely independently of each other and their mutual transmission time can vary completely randomly.

However, it is common for fixed packet sizes to be used, such as in Asynchronous Transfer Mode (ATM). Here, a so-called virtual channel is established through a telecommunication communication system where successive packets have a virtual address in the main, whereby all packets can be sent the same way according to the established channel and a more predictable transmission time can be offered.

It is also possible to divide a package of standardized size into smaller parts to provide an opportunity for a more flexible use of available space in the package.

Nodes in a network where packet management is used multiplex outgoing data packets by placing them in a queue specified by the packet's destination address. Data packets are picked from the queue and sent to the next node according to available transmission capacity.

Different levels of global or local addressing can be used, including different prioritization systems where high-priority packages can be allowed to take precedence over lower-priority packages. 15 20 30 517 859 3 Characteristic of data packet management is its unpredictable delay, which can be estimated statistically.

It should also be mentioned that in connection with real-time transmission, such as in voice communication, video conferencing, transmission of information where a recipient, for example, wants to browse through a material, the information age varies over time.

This irregular transmission need creates problems in combination with high loads.

In TDM, the bandwidth allocated to a channel for real-time communication must be adapted to the greatest transmission need, which means that the allocated bandwidth is not fully utilized.

There are a number of different publications that describe how different transmission protocols can be used in the transmission of data information.

Patent publications EP-A1-0 462 349, US-4 661 952, EP-A1-0 510 290, EP-A2-0 428 407, US-A-5 594 734, WO 97/10653, WO 97/36402, WO 97/24846 and WO 97/03526 can be considered to describe the state of the art.

In this description, the term homochronic transmission is used, by which is meant a time-preserving transmission, i.e. the time relationship between two transmitted signals is maintained upon receipt of these signals. This means that if a certain information is in the time interval between two signals, this information is retained when the signals are received.

This means that an isochronous transmission, where the time interval between two transmitted signals is equal to a unit interval or a multiple of a unit interval, can be a means of effecting a homochronous transmission.

Disclosure of the present invention Technical problems It is to be understood that each of the following problems is more pronounced within one of the principles of time sharing or data packet management. Thus, one principle is more suitable when requirements are set for information transmission, while it may be less suitable when other requirements are set. The present invention intends to offer a representation that enables a third principle in which all the following problems find a solution.

Taking into account the prior art, as described above, it is a technical problem to be able to combine a high utilization rate of available bandwidth with a guaranteed homochronic transmission as the bandwidth requirement varies over time.

When sharing time, it is a technical problem to be able to dynamically change a bandwidth available to an established channel during ongoing communication.

When time sharing, it is also a technical problem to offer a large bandwidth spectrum, such as from 8 kbit / s to fl era Gbit / s, where channels with completely different bandwidth requirements can be carried by a common transmission medium and where these channels can be dynamically allocated different bandwidths over this entire bandwidth spectrum.

In data packet management, it is a technical problem to be able to keep the utilization rate of available bandwidth high pre-transmission of data information and low for transmission of information regarding addressing and format of Transmitted information, especially when using short data packets, such as when transmitting isochronous information with requirements for short delay time.

In the case of time division, it is a technical problem to transmit a change in the structure of a channel allocation, both in terms of allocated bandwidth and the introduction of a new one or the removal of a significant channel, homochronically with the change itself.

When processing data packets, it is a technical problem to guarantee a homochronic transmission, especially at high loads.

It is a technical problem to apply data packet management recursively and it is not possible to apply time sharing recursively.

It should also be understood that it is a technical problem to be able to offer a method for representing a number of data streams so that when transmitting these there is a simultaneous and common solution to all the above problems, namely how to get a dynamic bandwidth allocation , how to do this over a large bandwidth spectrum, how to obtain a high utilization rate for the transmission of data information, how to offer a homochronous transmission, and how to offer a recursive multiplexing, by means of one and the same method.

The solution In order to be able to solve one or more of the above-mentioned technical problems, the present invention is based on a representation which is here called frame multiplexing, which means that a number of carried data streams in a common supporting data stream, where a here referred to as carried data stream is a sequence of associated current elements, wherein the supporting data stream is organized into frames, and wherein each frame comprises current elements belonging to one or more different supported data streams.

Based on such a method, and with the intention of offering an opportunity to dynamically adapt allocated bandwidth to the respective data stream, the present invention indicates that each frame comprises a frame descriptive index, that successive frames can be used to represent different data streams, that successive frames may comprise different amounts of data information, that carried current elements included in a frame may be allocated different sizes of space, and thus comprise different amounts of data information, and that the frame descriptive index offers an opportunity to interpret the contents of a frame.

In order for the frame descriptive index to require as little space as possible, and thus offer an opportunity to make maximum use of allocated bandwidth for the transmission of data information, the present invention indicates that the frame descriptive index consists of a reference to a position within a frame descriptive table. , which position constitutes a local description of the frame structure used by the sender and receiver, respectively.

In order to provide an opportunity to interpret the contents of these dynamically changing frames, the present invention directs that the local description of a frame structure indicates the position of each carried current element within the current frame, the size of each current element, and to which carried data current and current elements. ment hear.

According to the present invention, the frame descriptive table comprises a local description of each available frame structure that can be used for the load-bearing data stream between the sender and the receiver at a certain time.

With the intention of offering the sender an opportunity to dynamically use available transmission capacity, the present invention indicates that the choice of frame structure takes place dynamically according to the temporary need for information transmission for the respective carried data stream.

This dynamic choice is large because according to the present invention, one and the same data stream can be assigned current elements in two or more different frame structures.

According to the present invention, it may be appropriate in some cases, such as in the case of homochronous transmission of a data stream, to use an isochronous carrier. 20 25 517 859 e This means that the time ratio between two current elements belonging to a homochronically carried data stream is maintained since the time ratio between transmitted frames is constant.

In such an application, data information belonging to an isochronically carried data stream shall be assigned current elements within each successive frame or within frames with a constant number of intermediate frames. Other space within a frame can be distributed in a dynamic way between different data streams as previously described.

If the space for the included current elements differs from the extent of the frame, the present invention indicates that each frame comprises unused area.

With the intention of offering a possibility to use an inventive method recursively, the present invention indicates that a load-bearing data stream can constitute a first load-bearing data stream, which constitutes a carried data stream, of one or your other carried data streams, in a second load-bearing data stream. It is also possible that this second supporting data stream may be a carried data stream, of one or more second supported data streams, in a third supporting data stream, and so on.

Advantages The advantages that can mainly be considered to be characteristic of a method according to the present invention are that it offers an opportunity to represent a number of carried data streams in a common load-bearing data stream where the bandwidth of different carried data streams can be dynamically adapted to prevailing transmissions. where only a very small part of the transmission capacity is needed to communicate how the received load-bearing data stream is to be interpreted.

This provides a representation that offers a dynamic bandwidth allocation, over a large bandwidth spectrum, with a high utilization rate for information transmission, with a possibility of a homochronic transmission, and with a possibility of a recursive multiplexing, by one and the same method .

What can primarily be considered to be characteristic of a method in accordance with the present invention is stated in the characterizing part of the following claim 1. 15 20 25 30 517 859 7 Brief description of the figures A method, showing the peculiarities associated with the present invention, will now be described in more detail in the exemplary purpose with reference to the accompanying drawing, in which; Figure 1 shows schematically and very simplified the transmission of a number of data streams from a sender to a receiver, Figure 2 schematically shows a number of successive frames, Figure 3 schematically shows two frames with different frame structures, Figure 4 schematically shows a frame descriptive table Figure 5 schematically shows a series of frames of the same size, Figure 6 schematically shows a recursive application of the present invention, Figure 7 schematically shows another recursive application of the present invention, and Figure 8 shows schematically and very simply an embodiment where the sending respectively the receipt of information consists of writing and reading the information to and from a memory, respectively.

Description of now proposed embodiments With reference to Figure 1, a method is thus shown for representing a transmission of data information from a sender A to a receiver B. The figure shows that the information consists of a plurality of carried data streams referred to herein, some of which , b, c, d, are shown in the figure, which are transmitted by means of a common supporting data stream 1, and then a ', b', c ', d' are recreated on the receiving side B.

According to the present invention, the supporting data stream 1 is to be organized in frames, which in Figure 2 are schematically shown as frames with the different frame structures 11, 12, 11, 15, 1n having each other. These are transmitted sequentially one after the other, but not necessarily in time directly after each other. The designation of a frame refers to the structure that the frame has, successive frames can thus be assigned to different structures and the same structure can be repeated for different frames.

Figure 3 shows two frames with different frame structures 11, 12. A data stream a carried here is a sequence of associated current elements 1a, 2a. A sequence of carried current elements 1a, 1c, 1d, 1n from different carried data streams a, c, d, n is organized in the supporting data stream in frames 11 and in positions 11a, 11b, 11c, 517 859 a 11n within each frame, where each frame 11 thus comprises current elements belonging to one or more different supported data streams a, c, d, n.

The following terms will be used in the description of the present invention, where n is a number and x is a letter: 1: a first supporting data stream, x: a carried data stream, 1 n: a nth frame structure useful within the first supporting the data stream, nx: the nth current element belonging to the x'th carried data stream, for example 1a is the first current element belonging to the carried data stream a, 1 nx: the x'th position of a current element within the nth frame structure in the supporting data stream 1.

Each carried current element thus contains data information belonging to a specific carried data stream. In the figure it is shown, for example, that the carried current element 1c comprises data information belonging to the carried data stream c, and this current element 1c is assigned a position 11b in the frame structure 11 belonging to the supporting data stream 1. The frame structure 12 comprises the carried current element 2d in position 12a data information belonging to the carried data stream d, the current element 1b in position 12b comprises data information belonging to the carried data stream b, the current element 2a in position 12c comprises data information belonging to the carried data stream a, and so on according to the clock.

Different frame structures 11, 12 can thus be used to represent mutually supported data streams and they can also comprise different large amounts of data information.

It is also possible to assign different current elements included in a frame structure to different sized spaces, whereby they can comprise different amounts of data information between them. Figure 3 shows that the two frame structures 11, 12 are of different sizes from each other and that they carry partly different data streams between them. The figure also shows that the size of the current element 1a, 2a for a carried data stream a can vary between different frame structures 11, 12, which is illustrated in the figure in that the current element 2a in position 12c of the carried data stream a is smaller in the frame structure 12 than the corresponding current element 1a in position 11a for the same carried data stream a in the frame structure 11. The frame structures 11, 12 also comprise a frame descriptive index 111, 121.

The frame descriptive index 111, 121 offers an opportunity to interpret the content of the frame upon receipt of the frame.

This frame descriptive index 111 consists, according to Figure 4, of a reference or a pointer 111a to a position FDT1 within a frame descriptive table FDT, which consists of a local A, B description of a frame structure that can be used by sender A and receiver B, respectively. This local description consists of a number of positions FDT1, FDT2, F DTn within the frame descriptive table, in the figure shown as columns in the table FDT. The frame description table FDT is stored in a memory Am, Bm at sender A and receiver B (fi gur 1).

The pointer 111a only needs to be an address, or a reference to an address, to the memory Bm of the receiver B, which means that it only needs to take up a very small space within the frame structure 11.

The respective position FDT1 within the frame description table FDT comprises a plurality of items F DT1a, FDT1b, F DT1c, FDT1n, where there is one item for each position 11a, 11b, 11c, 11n in the frame structure 11. These items FDT1a, FDT1b, FDT , FDT1n indicates the position of the respective current elements 1a, 1c, 1d, 1n within the frame, the size of the respective current elements, and to which data stream a, c, d, n respective current elements 1a, 1c, 1d, 1n belong. There is a position FDT1, FDT2, F DTn within the frame description table FDT for each frame structure 11, 12 which can currently be used in the communication between the sender A and the receiver B.

Figure 4 shows another position in the frame descriptive table, FDT7, here exemplified by position number 7, which is designated 171a by the frame descriptive index 171 for the frame structure 17. This position comprises entries FDT7a, F DT7b, FDT7c, FDT7d pointing to positions 17a , 17b, 17c, 17d within the frame structure 17.

Because item FDT7b designates position 17c and item FDT7c designates position 17b, it is also shown here that the order of the items in the frame description table does not necessarily have to correspond to the order of the positions designated in the frame structure concerned.

The frame structure is selected dynamically by the sender A according to the temporary need for information transmission for the respective data stream a, b, c, d by selecting one of the locally available Am frame descriptive tables, structuring the frame according to the selected frame descriptive table. and enter the corresponding frame descriptive index in the formed frame.

One and the same carried data stream a can be assigned current elements in two or olika your different frame structures. Figure 3 shows that the carried data streams a and d are assigned current elements 1a, 2a and 1d, 2d, respectively, in both frame structures 11 and 12, while the supported data streams b and c are assigned only one current element 1b and 1c, respectively, in the one of the two frame structures 11, 12.

According to a proposed embodiment of the present invention, which is illustrated in Figure 5, the sequence of frames may be isochronous, i.e. successive frames 11 ', 12', 13 'are transmitted sequentially with a constant time interval t between the frame starts. , where the time interval t between transmitted frames can be considered as a primary interval.

Since the time ratio between transmitted frames is constant, this means that the time ratio between two current elements belonging to a carried data stream is maintained.

This in turn means that a time interval t1 between two successive carried current elements 1'a, 2'a, carried in positions 11'a and 13'a, belonging to one and the same carried data stream a is maintained, which enables a homochronic transmission of and carried data stream.

It should be understood that when a frame is received on the receiving side B, all carried current elements within one and the same frame are considered to be received simultaneously without mutual time difference, which means that possible transferable time intervals t1 for a homochronous data stream are discreetly divided into multiples of the used the primary interval t.

In such an embodiment, the possibility is also offered of transmitting data information belonging to an isochronically carried data stream c, which information constitutes a current element 1'c, 2'c, 3'c within each transmitted frame, shown here with the frame structures 11 ', 12 ', 13', or within frames with a constant number of intermediate frames.

The structure 11 ', 12', 13 'of the frames may otherwise differ between the respective frames so that each frame can transmit current elements belonging to the same or different supported data streams.

However, this can lead to a void between successive frames and according to the present invention each frame can thus comprise unused area if the space for input current elements 1'a, 1'b, 1'c differs. 517 859 11 from the scope of a frame structure 11 '. The figure shows an unused area at position 11'd. the figure shows this unused area as gathered to a part of the frame, but there is nothing to prevent this unused area from being divided between two or more different current elements in the frame.

When representing different carried data streams in a common load-bearing data stream, there may be applications where it is desirable to be able to handle a load-bearing data stream as a carried data stream together with one or andra your other carried data streams, and thus to apply the method recursively.

Figure 6 is intended to show schematically how this is possible by allowing the above-described supporting data stream 1, which carries the carried data streams a and b in the figure, to constitute a first supporting data stream, which in turn constitutes a carried data stream, of one or more several other carried data streams 2, 3, in a second supporting data stream 4.

There is nothing to prevent one or more of these other carried data streams 2, 3 from constituting a supporting data stream for additional carried data streams.

It is obvious to a person skilled in the art that this can be applied recursively in further levels so that, for example, the second supporting data stream 4 can constitute a carried data stream, of one or more other carried data streams 5, 6, in a third supporting data stream 7, and so on. further according to 7 gur 7.

When receiving information, it is not always possible for the recipient to handle the information directly, but it may happen that the information is buffered upon receipt. This can be done by storing the information on some kind of storage medium, such as a buffer memory, to be read out at a later time.

This means that information read out from this storage medium must be interpreted according to an available framework description table.

Figure 8 is intended to show that a storage of information can thus also take place according to the previously described representation, where the sending of the information can be seen as a writing 81 to a storage medium 8 and the reception of the information can be seen as a reading 82 from the storage medium 8. The transmission can here be considered to take place in time instead of in the room, where the sender sends 81 information at a first time and the receiver receives 82 the information at a second time, which may, but not necessarily, take place at the same place. in the room. Thus, there is nothing to prevent the storage medium 8 from being moved in the space between writing 81 and reading 82 of the information. An isochronity can also be obtained with a possibility of a homochronic transfer in the case where the sending 81, i.e. writing to a storage medium 8, takes place isochronically, and if the reception 82, i.e. the reading from the same storage medium 8, takes place isochronically with the same primary interval as at enrollment 81.

The invention is of course not limited to the embodiment specified above as an example, but may undergo modifications within the scope of the invention concept illustrated in the appended claims.

Claims (13)

15 20 25 30 517 859 13 PATENT REQUIREMENTS A method of representing a plurality of carried data streams in a common load-bearing data stream, wherein here-called carried data stream is a sequence of associated current elements, wherein said supporting data stream is organized in frames, and wherein each frame comprises current elements belonging to one or more different carried data streams, characterized in that each frame comprises a frame descriptive index, that successive frames can be used to represent different carried data streams, that successive frames may comprise different large amounts of data information, that carried current elements include in one frame different spaces can be allocated, and thus comprise different large amounts of data information, and that the said frame descriptive index offers an opportunity to interpret the content in said frame. Method according to claim 1, characterized in that said frame descriptive index consists of a reference to a position within a frame descriptive table, and that each position within said frame descriptive table constitutes a local description of a frame structure used by said sender. and said recipients. Method according to claim 2, characterized in that said local description of a frame structure indicates the position of each carried current element within the current frame, the size of each current element, and to which carried data current and current elements belong. Method according to claim 3, characterized in that said frame-describing table comprises a local description of each available frame structure that can be used for said supporting data stream between said sender and receiver at a certain time. Method according to one of the preceding claims, characterized in that the choice of frame structure takes place dynamically according to the temporary need for information transmission for the respective carried data stream. l5 20 25 30 517 859 14 Method according to one of the preceding claims, characterized in that one and the same carried data stream can be assigned current elements in two or two different frame structures. Method according to one of the preceding claims, characterized in that the sequence of frames is isochronous. Method according to claim 7, characterized in that data information belonging to an isochronically carried data stream is assigned current elements within each successive frame or within frames with a constant number of intermediate frames. Method according to Claim 7 or 8, characterized in that the respective frame comprises an unused area if the space for the included current elements differs from the extent of the frame. Method according to any one of the preceding claims, characterized in that said supporting data stream constitutes a first supporting data stream, that said first supporting data stream constitutes a carried data stream, of one or more of its second carried data streams, in a second supporting data stream, that said second supporting data stream may be a carried data stream, of one or andra your other supported data streams, in a third supporting data stream, and so on. Method according to any one of the preceding claims, characterized in that the sending of information constitutes a writing to a storage medium, and that the reception of information constitutes a reading from said storage media. Method according to claim 11, characterized in that a sender of information transmits information at a first time, and that a receiver of said information receives the information at a second time, which may, but not necessarily, take place in the same place in the room as the said transmitter of the information. 517 859 15 Method according to claim 11 or 12, characterized in that said sending takes place isochronously, and that said receiving takes place isochronically with the same primary interval as in said sending.