DE19548284A1 - Method and device for the asynchronous multiplexing and demultiplexing of microcells for the optimization of the transmission means of an ATM network - Google Patents

Description

The invention relates to a method and a front direction for asynchronous multiplexing and demultiplexing of microcells for the optimization of the transmission means of an ATM network.

The invention relates to the field of telecommunications tion and especially in the field of digital broad band networks with integrated services in English terminology called "Broadband ISDN", d. H. on multi-service networks with a wide range of Transmission rates from the transmission of television signa len can range up to short spoken messages, for example for civil or military applications which the language using the methods of linear Prediction is encoded.  

For digital broadband networks with service integration an international conference called ATM (Asynchronous Transfert Mode) called asynchronous transmission mode captured. The information to be transmitted is in cells subdivided with constant length, to which a header was added is added, which enables routing in the network. A sol che cell is with a useful information field a length of 48 bytes and a header field of 5 bytes educated. The need to wait for the Source has generated 48 bytes of information before the cell is in the network can be sent, the quality of it brought service adversely because of the delays network increases in an unacceptable manner. This This is particularly the case for sources with binary reduced over transmission rate critical, for example with vocoders that use 2400 bit / s work. The solution, which is that Only partially fill the user data field of each transmitted cell len has the consequence that the actual exploitation degree of transmission means of the network accordingly redu is decorated. When these are scarce, like tactical military networks must be between the two a conflicting conditions will.

This disadvantage is to be remedied with the aid of the invention will.

The method according to the invention is intended to enable the total transmission delay of the Information through the network and the degree of utilization of the Network supporting means of transmission for those with lower Transfer rate and real-time services to opti lubricate. This procedure is fully compatible with the Architectural principles of the ISDN broadband network, and he therefore enables connection to other ATM networks that if necessary, are called to transport the information mation from the beginning to the end. On the other hand, accept if the Multi is on the same transmission connection  plexing low-speed services and in real time with all other types of services, for example wise for data with different times, Dien most with continuous transfer rate etc.

For this purpose, according to the invention, a method for asynchronous multiplexing and demultiplexing of micro cells for the optimization of the transmission means of an ATM Network characterized in that on the one hand receiving egg tig on a connection of the ATM network which is located inside a normalized micro cell demulti be plexed to generate ATM cells of normalized size witnesses that no longer contain just one microcell, the cells then in a switching device of the normalized ATM cells are entered, and on the other hand a standardized ATM cell with as many micro cells as possible Lich is filled up in the output cells of the mediator device of the standardized ATM cells who found the.

In addition, the invention relates to a device for through implementation of this procedure.

The method enables the retention of ATM cells in the standardized format both in the exchange as well on the transmission links, which has the advantage that ATM networks can be traversed by the microcells not knowing.

The invention and further features and advantages result clearer from the following description, in the reference is made to the accompanying figures of the drawing. The drawing shows:

Fig. 1 shows the structure of a normalized cell with two micro-cells,

FIG. 2 is a diagram showing the construction of an inventive ago direction,

Fig. 3 is a functional diagram of the processing of cells from the transmission link by the microcells demultiplexer of the inventive device,

Fig. 4 is a functional diagram of the processing of cells from the standard switching center of the ATM cells by means of the microcell multiplexer of the device according to the invention and

Fig. 5 is a functional diagram which summarizes the processing carried out on the cells ended via a connection by the device according to the invention.

The problem addressed here is already in the fran applicant's patent 2 635 242 with the Title "Proc´de et dispositif de transmission en mode asyn chrone mettant en oeuvre des microcellules " been. The method according to the invention differs by the fact that the microcells we are talking about is, here directly from the information source or through the Device for adaptation to the ATM network, if such exists, be generated and that the proposed pre direction no new segmentation of the informa treated tion, but only statistical multiplexing tion / demultiplexing and a translation of Leitinfor mations in a header of the microcells and the be acted cells is present. On the other hand, they have over the connections transmitted cells still do that for that ATM network standardized format.

The following description is based on a typical implementation Example of the process in which at most two micro cells can be loaded into a conventional ATM cell.  

Fig. 1 shows the schematic structure of an ATM cell, are loaded into the two microcells. If the latter are chosen with an overall length that is smaller than the length of the normalized cell, more could be accommodated in it without questioning the method. The front of the normalized ATM cell is labeled OH, and its hanging is 5 bytes in this example. A control field K enables, inter alia, the coding of the number of microcells transported in the cell in question. It may also contain other information, for example related to the priority of the cell when it is sent or its priority if it is lost. It is therefore an essential parameter, the subsequently described functions.

Two functions are defined that apply to it are:

• - K is the number of those transported through the ATM cell Microcells, and
• - K and OH are the priority for sending for the microcell or the ATM cell.

The fields E₁, E₂ and I₁, I₂ denote the prefix fields or the useful information fields of the first microcell or the second microcell. Transport the fields OH and E. the main information of the news. It should be noted that the actual structure of the interior of the ATM cell is different can be, depending on how the information introduced here cations.

Then the conventional ATM cells without micro cells called cells of type C0, cells with only a microcell are called type C1 cells, and cells that contain two microcells are called cells of type C2.  

Fig. 2 shows the structure of the device according to the invention. It contains in the receiving direction of the cells on a first connection A 1 , a micro cell demultiplexer 1 , whose output is coupled to the input of a conventional ATM cell switching device 2 , and on a second connection A 2 , a micro cell multiplexer 3 , which is connected to the output of the switching device 2 . The multiplexer / demultiplexer units are physically mounted in the interface cards of the switching devices with the connections.

In the receiving direction of the connection A1, the cells are of the type C0, C1 or C2 according to their source. The microcells are separated in the normalized ATM cells generated by the demultiplexer 1 so that they are in a state isolated from their input point. In the ATM cell switching device 2 , cells of type C0 and C1 no longer appear. At the exit of the switching device 2 , at point X2, only cells of types C0 and C1 appear. The task of the multiplexer 3 is to transmit a maximum of cells of type 2 mixed with unprocessed cells of type C0 and a minimum of partially filled cells of type C1 to the connection A2. Its task is therefore to maximize the degree of utilization of the transmission connection.

Fig. 3 shows a functional diagram of the processing by the demultiplexer 1 on the cells of the type C2, which arrive at A1. The cells of type C0 are transferred to connection A1 without any further action. The cells of the type C2 are divided into two cells of the type C1, which are denoted by A and B, by applying previously saved translation rules to them in the demultiplexer 1 , which are designated Trad₁, Trad₂ and Trad₃ and defined as follows are:

• - OHA = Trad1 (OH, K, E1)
• - E1A = Trad2 (OH, E1)
• - Priority (KA) = Trad3 (K, E1)
• - Number (KA) = 1

The scheme for creating cell B is identical. The cells A and B are entered into the switching device 2 in such a way that the order of the microcells in the incoming cell is maintained. For proper functioning, the physical transmission rate at point X1 is twice as high as that at point A1.

The processing of type C1 cells is the same as the creation of a cell A without the creation of a cell B. The operation is thus reduced to a pure over settlement.

Fig. 4 shows a functional diagram of the processing performed by the multiplexer 3 on cells coming from the ATM cell switching device 2 . The transfer rate at point X2 is greater than the transfer rate at point A2, since the switching is asynchronous and there should be the possibility that several cells from different connections are routed to the same output at the same time. For this purpose, a first waiting file F1 lies between the switching device 2 and the multiplexer 3 . This enables the input and output transmission rates to be adjusted.

A second waiting file F2 for transmission rate adaptation is arranged between the output of the multiplexer 3 and the transmitter 4 of the cells to the compound, wherein the multi-plexer 3 ensures the translation of the microcells.

The first wait file F1 is emptied at a rate greater than that of the connection. In the example described below, four cells are considered, although this number may also differ. The following processing operations are carried out:
In a first stage, the four cells are transmitted to the multiplexer and translator 3 when the first waiting file F1 is filled sufficiently. In the opposite case, there are two possibilities, namely that the multiplexer 3 only takes into account the number of cells present in the first waiting file F1 or that it waits for the arrival of further cells. This choice makes it possible to parameterize the compromise between runtime and transmission efficiency. The cells are cells of type C1 or C0; they are designated in Fig. 4 with I to IV.

In a second stage, the microcells located in the interior of the ATM cells are classified into groups of two in cells of type C2 by maintaining their removal order from the first waiting file F1 and applying translation rules previously stored in the multiplexer 3 . In the scheme proposed as an example, cells I and III, each containing only one micro cell, are merged into a single one, labeled "a", which contains two micro cells. Cell IV is translated into cell "b" of type C1. In this example, the microcells have priority over the normal ATM cells of type C0, and cell III is translated into a cell "c" which is the last to be entered in the second waiting file F2. This waiting file F2 is then emptied by the transmitter 4 in time with the connection A2.

Since it can happen that in the first waiting file F1 only C0 type cells are present, the transmission rate at point D2 be the same as at point D1.

Fig. 5 shows a functional diagram summarizing the processing operations performed on the cells prior to their transfer to connection A2. The Trad1 translations, with i = 1 to 3, are carried out by applying rules previously stored in the multiplexer 3 . A typical example is given below:

• - OH.a = Trad1 (OH.I, OH.III, K.I, KIII, E: I, E.III)
• - E.a1 = Trad2 (OH.a, E.I)
• - E.a2 = Trad3 (OH.a, E.III)
• - Priority (K.a) = Max (Priority (K.I), Priority (I.III))
• - Number (K.a) = 2

The Trad1 functions listed above have no relationship with the functions also designated, which are used for loading of the demultiplexer were introduced.

There are of course numerous configurations regarding the size selected for the microcells and the respective Length of your user information fields and your guiding principle imaginable. The structure of the latter can also be according to different criteria.

Claims (4)

1. A method for the asynchronous multiplexing and demultiplexing of microcells for the optimization of the transmission means of an ATM network, characterized in that on the receiving side on a connection of the ATM network which are located inside a standardized ATM cell, the microcells are demultiplexed, to produce normalized size ATM cells that no longer contain just one microcell, the cells are then input to a mediator of the normalized ATM cells, and on the other hand, a normalized ATM cell is filled with as many microcells as possible , which are found in the output cells of the switching device of the normalized ATM cells. 2. The method according to claim 1, characterized in that the header of the microcells and the header of the trans porting cells parameters for the in these microcells data stream to be transmitted included.   3. A device for performing the method according to claims 1 and 2, characterized in that it on the connections of the network, which are intended to transmit in real proportions with low transmission rate in real proportions, adapter circuits ( 1 , 3 ) contain at least one of the ends of a connection between at least two switching devices which effect the multiplexing, the demultiplexing and the conversion of the micro cells carried in the ATM cells into the standardized format. 4. The device according to claim 3, characterized in that the adapter circuits ( 1 , 3 ) on the interface cards of the switching devices with the connections are introduced.