DE10102110A1 - Method for bidirectional signal transmission in a distributed network - Google Patents

Abstract

The invention relates to a method for a bidirectional signal transmission in a distributed network with a point-to-multipoint connection, wherein the signals from the multipoint stations in the direction of the point stations are combined to form a TDMA (Time Division Multiple Access) signal, and the point station assigns a transmission capacity (dispatch rate) in the network to the multipoint stations. DOLLAR A It is provided that the assignment of the dispatch rate (r) to the multipoint stations (16) is dependent on a delay time resulting from a queue length (q) of demand requests (24) and a processed quantity of demand requests (24) (d) linked estimated rate (ERFD).

Description

The invention relates to a method for bidirectional signal transmission in a distributed Network with those mentioned in the preamble of claim 1 Features.

State of the art

Distributed networks for a bidirectional signal in which a so-called point station Multipoint station connection is known. Networks distributed in this way can be used, for example, as optical networks, radio networks or wired Networks (Ethernet) should be formed. Distributed this Networking is common to both the point station as well as multipoint stations on a common network access. To a coordinated bidirectional To ensure signal transmission, access must be controlled on this network. Here is once a signal transmission from the multipoint stations (terminal, leave) to the point station (head office) as Control back channel (upstream) while on the other hand the signal transmission from the point station to the  Multi-point stations to control as downlink (downstream) is. For the upstream there is a distributed tax required while control for the Downstream can be completely done in the headquarters can.

From the communication technology are so-called in general MAC (medium access control) protocols for coordinating Control access to a common network known.

Especially for intelligence services with statistical fluctuating requirements from pro Time unit to be transmitted signals, such as wise data services, video services, ATM (asynchronous transfer mode) services can be provided by a dynamic Control a high and thus effective utilization of the common distributed network.

Such dynamic control takes place by means of Logs where the timeline is in so-called Frame (TDMA (time division multiple access) frame) is divided, according to the requirements changes of the multipoint stations within this This frame in fixed places or relative to the frame a transmission capacity is allocated. in this connection are required in the individual multipoint stations requirements - that is, the multipoint stations want to send messages or data packets and thus need to use the common Network - collected in a queue, that cannot be processed immediately. This  The state of the multipoint station is considered a requirement tion (request) communicated to the point station. by virtue of knowledge of all status information of the More the point station tries the capaci distributed network to the multipoint stations to allocate as fairly as possible. The point station distributes grants to the multipoint stations by means of which these are precisely defined Access points to the shared distributed network can.

The demand transmitted by the multi-point stations Requirements include new arrivals, for example of messages or data packets since the last Status message, a queue length from which then the number of new ones by forming the difference Arrivals, that is, the required transfer capacity a local counter reading is determined an exact but unknown level of a control room queue determined or via arrival pattern from Nach align and packets of data in a transmission frame at the point station. Because of this need The controller determines how many messages or data packets (cells) to be transmitted and via takes the allocation of grants. With these known The disadvantage of this process is that it a corresponding message to the central Control is to be given. This will, because the Requirement requirements also about the common distributed network are transmitted, its about carrying capacity minimized.  

Advantages of the invention

The method according to the invention with the in claim 1 In contrast, the features mentioned have the advantage that in a simple way a traffic-dependent tax Transfer capacity at statistical fluctuating requirements is possible. As a result of that the allocation of the transmission capacity to the More point stations depending on one of one Queue length of requirements requests and a processed set of requirements resulting handling rate is advantageous possible, the transmission capacity of the requirements changes to the shared distributed network to mini lubricate, since not every need requirement now individual, but as a sum information of the respective can be transmitted to the point station. Furthermore, the central control of capturing the conc th number of incoming requirements and the concrete number of requirements processed relieved.

Further preferred configurations of the invention result from the rest, in the subclaims mentioned features.

drawings

The invention is in one embodiment example with reference to the accompanying drawings purifies. Show it:  

Fig. 1 shows schematically a signal transmission in an optical network and

Fig. 2 shows schematically the control of the signal transmission according to the invention.

Description of the embodiment

In Fig. 1 is a topology of an optical network 10 is shown. A point station 12 (OLT-optical line termination) is connected via a distributed optical fiber network 14 to multi-point stations 16 (ONU optical network unit). The glass fiber network 14 comprises at least one passive optical splitter, by means of which a tree-like branching of the network 10 is achieved.

In the distributed network 10 there is a signal transmission in the downstream direction 18 and in the upstream direction 20 . Furthermore, the transmission of signals in the upstream direction 20 , that is to say from the multipoint stations 16 in the direction of the point station 12 , is dealt with.

At this point it should be noted that the embodiment on an optical network refers. Of course, the invention is not limited to optical networks, but can be also to radio networks and wired networks wear.  

Fig. 2 shows schematically the control of the signal transmission by means of a built-in point of the central station 12 controller 22. Otherwise, identical parts in FIG. 1 are provided with the same reference symbols in FIG. 2 and are not explained again.

In the multipoint stations 16 , the messages or data packets to be sent are collected as cells 24 in a queue 26 . Corresponding to the inflow of cells 24 to the queues 26, these have a queue length q. This can fluctuate according to the statistically fluctuating requirements for the transmission of messages or data packets per multipoint station 16 , that is to say they can be of different lengths.

The queue length q is passed through a delay element 28 , by means of which a delay time d can be determined, which corresponds to a number of TDMA frames to be waited in the upstream direction 20 . Correspondingly, a dispatch rate r is allocated to the multipoint stations 16 by the central controller 22 , by means of which a defined number of cells 24 per TDMA frame can be transmitted in the upstream direction 20 .

There is a connection between the queue length q, the dispatch rate r and the delay time d for the last demand request (cell 24 ) within the queue 26

The sampling rate r is therefore based on an estimate of the so-called rate ERFD (Estimate Rate to Fulfill Delay) considered necessary for the corresponding delay d. This estimated rate ERFD is proportional to the respective queue length q, so that by controlling the central control 22 via the rate ERFD in accordance with Little's law of message traffic theory, the delays that result for the respective multipoint stations 16 during processing are constant and the long-term sampling rate r adapts to the cells 24 offered .

In the event that the sum of the demand requirements of all multipoint stations 16 of the distributed network 10 exceeds the total capacity C of the network 10 , the capacity can be divided in proportion to the ERFD rates of the individual multipoint stations 16 , whereby the handling rate applies

where Σ ERFD is the sum of the individual ERFD of all multipoint stations 16 in the network 10 .

As a result, the proportionality of the relationship remains the handling rate r for the respective queues length q unchanged.

The ERFD rate for each multipoint station 16 can be calculated either in the respective multipoint stations 16 or centrally in the central control 22 .

As explained, the delay time d flows into the Determination of the ERFD rate. To calculate the desired delay time d are uncertainties and to take statistical fluctuations into account that the delay time d should be less than the required maximum value of the delays occurring stanchions d.

The central controller 22 can achieve the same delay in the provision of the dispatch rates r for all multipoint stations 16 (delay fairness) with any traffic distribution from the various multipoint stations 16 with maximum use of the distributed network 10 . In this case, no fixed delay value is triggered, but this is relative. Since the achievable delay for the provision of the dispatch rate by the central control 22 is not known, the delay time d of the respective multipoint stations 16 can be chosen to be small in order to minimize the delay in the provision of the dispatch rate r.

In order to ensure an effective signal transmission, the so-called overhead of each transmission frame for the transmission of the required messages from the multipoint stations 16 , which consists either of the queue length q or the ERFD rate, should be minimized. For this purpose, coding or decoding into one byte per multipoint station 16 can take place. The queue length q and a priority class of the ERFD rate can be taken into account here.

When coding, the numerical value (numerical value for the queue length q or numerical value for the ERFD rate) is shifted to the right until the remaining number can be represented with the bits available for the mantissa, the least significant bit being lost per shift operation goes. Together with this shifted number, the number of shift operations must be transmitted. This is listed as an exponent. Using such a method, small values are coded precisely - since there are no shifts - while inaccuracies result for larger values depending on the size of the value to be coded. If the values are encoded in one byte (corresponds to 8 bits), the following value ranges result:
5 bit mantissa (remaining number) and 3 bit exponent (number of shift operations) of 3968 and for 4 bit mantissa and 4 bit exponent of 497520. The value 0 is always represented by 0.

The method according to the invention also offers the possibility of defining static priorities for the requirements of the multipoint stations 16 . The delay time d per ERFD rate can be adjusted according to defined priority classes. For services with a high real-time requirement (for example voice transmission), a high priority, that is to say a small delay time d, is selected. For services with weak demands on the delay, the delay time d is chosen to be higher, while for services with the lowest priority, for example best-effort services, the delay time d can be chosen to be the highest. For each multi-point station 16, the need message must be made separately for each priority class and per ERFD rate. Likewise, the dispatch rate r is specified separately for each priority class by the central controller 22 per multi-point station 16 .

Claims (6)

1. A method for a bidirectional signal transmission in a distributed network with a point-to-multipoint connection, wherein the signals from the multipoint stations in the direction of the point stations are combined to form a TDMA (Time Division Multiple Access) signal, and the point station to the multipoint stations allocates a transmission capacity (dispatch rate) in the network, characterized in that the assignment of the dispatch rate (r) to the multipoint stations ( 16 ) is dependent on a queue length (q) of demand requests ( 24 ) and a processed amount of Requirement requirements ( 24 ) resulting, with a predetermined delay time (d) linked, estimated rate (ERFD). 2. The method according to claim 1, characterized in that the assignment of the dispatch rate (r) for each multi-point station ( 16 ) is proportional to the ERFD rates of all multi-point stations ( 16 ). 3. The method according to any one of the preceding claims, characterized in that the ERFD rate is determined in the respective multipoint station ( 16 ). 4. The method according to any one of claims 1 to 2, characterized in that the ERFD rates for all multipoint stations ( 16 ) are determined in a central controller ( 22 ) of the network ( 10 ). 5. The method according to any one of the preceding claims, characterized in that the dispatch rates (r) from the controller ( 22 ) of the multipoint stations ( 16 ) are allocated taking into account prioritized delay rates (d). 6. The method according to any one of the preceding claims, characterized in that the transmission of the for the determination of the clearance rate (r) necessary Information (queue length (q), ERFD rate) coded.