DE19727547A1 - Method for signal transmission in a network - Google Patents

Abstract

The invention relates to a method for transmitting a signal in a network with a point-to-multipoint connection, wherein the signal is transmitted according to a TDM/TDMA method. TDM signals are sent by a head station in point-to-multipoint direction and burst signals are sent by individual multipoint stations in multipoint-to-point direction. The signals for the head station are coupled into a TDMA signal in at least one splitter while the burst signals in the TDMA signal are classified by ranging. The invention provides that the running time of individual burst signals (18) deviating from a given set time are detected by the head station (OLT) during every transmission and the detected running time deviations are immediately communicated to the corresponding multipoint station (ONU).

Description

The invention relates to a method for a signal transmission in a network with the in the preamble of Claim 1 mentioned features.

State of the art

From Journal of Lightwave Technology, Vol. 13, NO. 5, May 1995, pages 947 to 953 is a topology for the connection of a head-end station to other stations (multipoint stations), a point-to-multipoint Connection, known in which a signal transmission through a TDM / TDMA (Time Division Multi plex / time division multiple access). In Direction from the head-end station to the multipoint station A TDM signal is transmitted by all Multipoint stations is received. In the direction of the multipoint stations to the headend are from burst signals are sent to the multipoint stations, leading to a TDMA signal for the head-end station be put together. For distributing and assembling of the signals are passive optical elements, at for example, splitter provided.  

In order to be able to combine the burst signals of the multipoint stations to form the TDMA signal, a transit time of the signals between the head station and the multipoint stations must be averaged by a range. The ranging involves arranging the burst signals of the multipoint stations in the TDMA signal, with a distance between the individual thirst signals being maintained. To perform this ranging, the thirst signals contain guard and run-in bits. The guard bits prevent two thirst signals 18 from being superimposed and determine the transmission gaps between the thirst signals 18 .

Since the transit times between the head station and the multipoint stations during the operation of the op table network, it is necessary repeat the ranging process before a run time change interferes with the transmission of the burst signals. To be able to make these corrections, the gaps between the transmissions of thirsty Si gnale of the individual multipoint stations so large be chosen that no over between the corrections transmissions of other thirst signals overlap. The for Gaps to be kept between the transfers are not available for signal transmission Available.

Advantages of the invention

The inventive method with the in claim 1 mentioned features offers the advantage that the Lüc between the transmissions of the thirst signals  individual multipoint stations to a necessary min least can be reduced so that the period maximum usable for the transmission of user data is. The fact that a runtime deviation of individual Thirst signals from a target runtime from the head office tion is determined during each transmission, and the determined runtime deviation the corresponding Multipoint stations communicated immediately is a immediate reaction of the multipoint stations to the cor correction of the runtime possible. In particular, with the runtime deviation determined by the head-end station the time bases of the multipoint stations be compared so that a next transfer of the Thirst signals from the affected multipoint stations can take place again at the target time. A debit time deviation is thus kept to a minimum during the Transmission limited so that adding up more Target time deviations from a total target time softening, which is a correspondingly large gap between claimed two transmissions of the thirst signals, is excluded.

Further advantageous embodiments of the invention result from the rest, in the subclaims mentioned features.

drawings

The invention is in one embodiment example based on the associated drawing, the one Procedure of the signal transmission in an opti network shows, explained in more detail.  

Description of the embodiment

In the figure, a topology of an optical network is shown. A head-end station OLT (Optical Line Termination) is connected via a distribution network 10 to multi-point stations ONU_1, ONU_2 to ONU_n (Optical Network Work Unit). The distribution network 10 has at least one splitter 12 , by means of which a branching of the distribution network 10 is achieved. Above the head-end station OLT there is a frame 14 in which TDM signals TDM-S are transmitted to the multipoint stations ONU. The frame 14 begins with a so-called overhead OH, which is followed by the data for the individual multipoint stations ONU. The frame 14 is transmitted via the distribution network 10 to all multipoint stations ONU, the multipoint stations ONU transmitting the signals intended for them get out of the frame 14 .

In the opposite direction, ie from the multipoint stations ONU to the head station OLT, the multipoint stations ONU send the thirst signals 18 shown below them. The thirst signals 18 are combined by the splitter 12 to form a frame 20 of TDMA signals TDMA-S, as is shown below the head station OLT. The frame 20 contains a measuring window 22 and the arranged burst signals 18 of the individual multipoint stations ONU.

The thirst signals 18 contain guard and run-in bits 26 . The guard bits prevent two burst signals 18 from being superimposed, while the run-in bits are used for synchronization in the receiver of the head-end station OLT.

The burst signals 18 are sent at a certain target time, which is specified for each multipoint station ONU. This desired point in time is selected so that the classification in the frame 20 can take place via the guard and run-in bits 26 . Between the individual thirst signals 18 within the frame 20 remains a transmission gap 28 , which serve to equalize the target time deviations of a runtime of the burst signals 18 from a multipoint station ONU to the head station OLT. The gaps are chosen so that when they are combined in the frame 20 an overlay of burst signals 18 of several multipoint stations ONU is prevented.

Each time frame 20 is received in head station OLT, runtime deviations from a target runtime of thirst signals 18 from multipoint stations ONU to head station OLT are determined. This runtime deviation of the target runtime is returned via the frame 14 to the multipoint stations ONU as information. Within the multipoint stations ONU, this information is fed to a time base which determines the time of transmission of the thirst signals 18 of the respective multipoint station ONU. The fact that any eventual runtime deviation is determined immediately with each transmission and is returned to the multi-point station ONU, an immediate comparison of the target time of transmission of the thirst signals 18 can take place. Overall, the gaps 28 within the frame 20 can thus be reduced to an absolute minimum, since runtime deviations are immediately compensated for. Overall, a larger time span is thus available within the frame 20 for the transmission of the useful data of the thirst signals 18 .

Claims (3)

1. A method for signal transmission in a network with a point-to-multipoint connection, in which a signal transmission is carried out by a TDM / TDMA method, wherein in the direction of point-to-multipoint from a head-end station TDM signals and in the direction of multipoint -to- point of individual multi-point stations, thirst signals are transmitted, which are combined at least one splitter to form a TDMA signal for the head-end station, and a classification of the thirst signals into the TDMA signal takes place by means of a ranging, thereby characterized in that a runtime deviation of individual burst signals ( 18 ) from a target time from the head station (OLT) is transmitted during each transmission and the determined runtime deviation is immediately communicated to the corresponding multipoint stations (ONU). 2. The method according to claim 1, characterized in that that in the multipoint stations concerned (ONU) Runtime deviation with a time base of multipoint Stations (ONU) is adjusted. 3. The method according to any one of the preceding claims, characterized in that the runtime deviation is communicated to the multipoint stations (ONU) in a frame ( 14 ) of the TDM signals (TDM-S).