FR2636482A1 - Method of synchronisation for the multiplexing of words in a fibre optics star communication network - Google Patents

Abstract

The method according to the invention is intended in particular to be implemented in fibre optics service networks in which communication between a central station 1 and a plurality of subscriber installations 3 is of the communal simplex type. In these networks, the subscriber installations are generally located at variable distances with respect to a node of the network and it is necessary to take into account a disparity in propagation delay time T1 between various words MM1 transmitted to the central station by the subscriber installations. According to the method of the invention, there is provided prior to the connecting of an installation 3, a measurement of the corresponding propagation delay time. From this measurement, a timespan DELTA tr is determined which is allocated to the subscriber installation. The timespan is used by the installation in order to delay a word to be transmitted MMr so that the said word coincides at the node of the network with a corresponding time interval of a message of multiplexed words PM transmitted to the central station.

Description

Synchronization method for multiplexing words in
a fiber optic comunication network
The invention generally relates to the multiplexing of communication signals transmitted to a central station through a single transmission medium such as an optical fiber by a plurality of terminal stations connected in a star and distant from different distances from the central station. More particularly, the invention relates to the collective multiplexed multi-sharing by means of optical fibers in a telecommunication network, for example of the ISDN type.

 In an optical fiber telecommunication network, the local communication of the communication signals between a local exchange and subscriber facilities is carried out by means of a star service network comprising several optical transmission fibers connecting the central office and the installations. subscriber respectively to different accesses of a passive optical fiber coupler constituting the central node of the star service network.

The covication between the central office and the subscriber facilities is of the collective alternating type. During the first periods of co-communication, the central transmits a downward packet to all the facilities of the abohn. The downlink packet consists of a plurality of multiplexed words for subscriber installations respectively. During second periods of the communication, the subscriber installations transmit batches intended for the central office respectively at different determined times. At the central node of the serving network, the words transmitted by the subscriber installations are inserted in respective time slots of an upstream packet destined for the exchange.

 In this type of service network there is a transmission synchronization problem between the different subscriber installations so that, at the central node of the network, the words transmitted by the subscriber installations coincide precisely with the corresponding time slots of the subscriber system. package amount and do not interfere with each other. This synchronization is difficult to obtain because the subscriber installations are located at different distances from the central node of the service network and it is therefore necessary to take account of a disparity of the propagation delay times.

 The present invention aims at providing a method for solving the synchronization problem set out above in the particular context of a local fiber optic and collective switching service network, but which is also generally suitable for all communication networks. starred conveying multiplexed communications.

 To this end, the synchronization method according to the invention for multiplexing on a single transmission medium such as optical word fiber respectively transmitted by a plurality of terminal stations and intended for a central station, said central and terminal stations being interconnected in a star communication network having transmission media of different lengths respectively connected to the different stations and to a central node of the communication network, is characterized in that a connection of a terminal station to the communication network is preceded by a measurement a propagation delay time between said terminal station and the central station and that according to said measured propagation delay time and a reference propagation delay time corresponding to the first terminal station connected to the network it is determined a delay time that is assigned to the station terminal so that it delays the transmission of its word of said delay time so that at the central node of the network said word is inserted in a corresponding time interval of a multiplexed word message transmitted to the station without interfering with the other message words transmitted by the other terminal stations.

The invention will be better understood on reading the following description of the method according to the invention with reference to the corresponding appended drawings in which
- the Pig. 1 schematically shows the structure of a fiber-optic alternating star-fiber grating for the implementation of the synchronization method according to the invention.
FIG. 2 shows diagrams of upstream and downstream packets exchanged between a central office and subscriber facilities connected to the communication network shown in FIG. 1; and
FIG. 3 is a timing diagram relating to upstream and downstream packet exchanges according to the method of the invention between the central office and the subscriber facilities.

 With reference to FIG. 1, a star-fiber type optical fiber alternating communication network for implementing the method according to the invention comprises, for example, a central unit 1 connected to J-12 subscriber installations 31 to 3J across a bidirectional optical fiber coupler 2 having a first access connected to the central 1 by an optical fiber 12 and J-12 second access respectively connected to the J-12 subscriber installations 31 to 3J through J = 12 optical fibers 231 to 23.

 The central 1 is located at a distance Do of the coupler 2. The distance D0 is typically between 0 and 10 km. This distance C 1 introduces into the signals transmitted through the fiber 12 a propagation delay time t 0. The subscriber installations at 33 are located respectively with respect to the coupler 2 at distances D1 to DJ typically between 0 and 100 m. At the distances D1 to DJ correspond, respectively, propagation delay times t1 to tJ between a minimum value tmini # 0 5 and a maximum value tmaxi # 0.5 ps.

 Packets are transmitted in collective alternation between the central 1 and the subscriber installations 31 to 3J. During the first periods of the communication, the central office 1 transmits PD downstream packets which are received by all subscriber installations 31 to 3J. During second periods of the connection, the subscriber installations 31 to 33 each transmit a data word intended for the central station 1. At the coupler 2 constituting the center of the star network, the different words transmitted by the subscriber installations coincide respectively with different time intervals and form a rising packet PH which is conveyed to the central 1 through the optical fiber 12. The first and second periods of the communication are alternated and during each period is transmitted a single packet.

 The structures of the falling packets and PD and PM amounts are shown in FIG. 2.

 A downstream packet PD includes J + 1-I3 time intervals including N-J = 12 time slots of data word IT1 to ITN 12 of the same duration IT and a time interval of ITSD service word. The time intervals 1T1 to ITN contain downlink data words MDj, where j is between 1 and J, specifically intended for subscriber installations 31 to 35. The time slots 1T1 to ITN are not allocated respectively and definitively to the subscriber installations 31 to 3J. Their assignment is specified in each PD packet by a service word MS contained in the ITSD time slot. The time intervals IT1 to ITN are for example allocated by the central office 1 as a function of the connection order of the subscriber installations 31 to 3J. Thus, if, for example, the subscriber installation 38 is the first to be connected, the time slot IT1 is allocated to it throughout the duration of the call and contains a downlink data word MD8 intended for the installation of subscriber 38.

In general, a connected subscriber installation 3 is assigned a time slot IT whose index n is between 1
n and N = J = 12 represents a connection rank of the 3j installation
In addition to the function of specifying the assignment of the time slots from packet 1T1 to ITN to the different connected subscriber installations, the service word MS also has the function of cyclically authorizing connection requests from the subscriber installations 31 to 35 and possibly transmitting connection commands from the central office 1.The service word MS of a downstream packet PD contains a connection order or a connection request authorization specifically intended for one of the subscriber installations 31 to 3J . After the transmission of J = 12 PD downstream packets from the central office 1, all the subscriber installations 31-35 were selected and received either an order or a connection request authorization.

From a falling packet PD, a rising packet PM is composed of J + 1 "13 time intervals of which N = J = 12 time slots of data word 1T1 to ITN, 12 of the same duration IT and a time slot of word The time intervals IT1 to ITN of a packet PH contain upstream data words MM transmitted by the subscriber installations 31 to 3 and destined for the central office 1. The data batches MDj and NHj occupy respectively in the packets. PD and PM time intervals
ITn of marne rank n.The ITSM service word interval possibly contains a DC connection request word. The DC connection request word is transmitted by a subscriber installation 3j in response to the reception of a connection order or a connection request authorization sent by the central office 1. The position of the connection request word DC in the time interval ITSM is variable and depends on the distance Dj corresponding to the installation 3 as well as the distribution configuration of the data words in the data word time intervals IT1 to ITN as it will appear more clearly by the after.

 With reference to FIG. 3, packet transfers occurring between the central office and subscriber installations are now described in accordance with the method according to the invention and in a communication configuration such as for example several installations 36, 31, 36, 36. 31, ... 3 are connected to the network and in communication with the central office 1 and a connection request is made by a non-connected installation 3k in response to a connection request or authorization issued by the central office. 1, r and k being indices between 1 and J.

The subscriber installations 3r, 36 31, ... 3j are assumed to be connected to the network in the corresponding order and consecutively the data words WMr, MM6, MM1, ... MMj that they deliver occupy respectively the time intervals IT1,
IT2, IT3, .. .ITn PM packet amounts.

not
Min to facilitate the reading of the chronograwme shown in FIG.

3, the packets and words transmitted by the central office and the subscriber installations are represented on lines marked by the letter T.

The packets and words received by the central office and the subscriber facilities are represented on lines marked with the letter R.

 As shown at a first line T at the top of FIG. 3, during a first communication period a first downward packet PD1 is transmitted by the central 1 at a time origin t.

The packet PD1 is received by the subscriber installations 3r '36 31, --- 3j, and 3k respectively with delay times Tr = to + tr,
T6-t0 + t6, t1, ... Tj Tj = t0 + tj and Tkstotk. After the end of receiving the packet PD1, during a second communication period, the subscriber installations 3r, 36 31, --- 3j transmit the data words MMr MM6, MMI ,. ... MMj respectively under deadlines #tI + 0.IT, At6 + 1.IT, # t1 + 2.IT, ... # tj + (n-1) .IT. These deadlines include components
#r. # t6, # t1, ... Atj which are determined so as to compensate for the propagation delay time differences so that at the level of the coupler 2 the data words MM ,, MM6, MM1, ... MMj coincide
J with the corresponding time intervals IT1,. IT3, IT ...
1T1, 1T2, n to form a PM1 upstream packet.

 According to the method of the invention, in order to determine the delay components At to be allocated to the subscriber installations, the central office 1 performs, before the actual connection of each subscriber installation, a measurement of the propagation delay time corresponding to the subscriber installation.

In order to carry out the measurement of the propagation delay time T k corresponding to the subscriber installation 3ks, the central unit initialises at the instant of origin ti a counting device whose content is incremented cyclically under the control of determined frequency clocks. . At the end of receiving the packet.PD1, the subscriber installation 3k immediately transmits the DC connection request word. The beginning of the reception of the DC connection request word is detected by the central unit which blocks the counting device in response to this detection. The content of said counting device is then representative of a duration Ta passed between the corresponding time ti at the beginning of the packet transmission
PDI and the start time of reception of the DC connection request word transmitted by the installation 3k The duration Ta is expressed by the following equality
Ta = 2Tk + DP, (1) where DP represents the fixed duration of a falling packet PD. From this equality (I) and the measured duration Ta, the central calculates the propagation delay time Tk
It is now considered the words MM and MMj transmitted by
rj any two subscriber installations 3 and 3j .The coincidence of these words MM and MMj at the coupler 2 with the corresponding time intervals 1T1 and IT is effective at
n condition that the following relationship is satisfied
2T + DP + At - 2Tj + DP + # tj, hence the equalities
At a At +2 (T-T) (2)
#tj = # tr + 2 (Tr-Tj)
#tj = # tr + 2 (tr -tj)
- #tr +2 (tr-tj)
The equality (2) is used by the central office 1 to determine the delay component Atk to be assigned to the subscriber installation 3k
The Atk delay component is given by the equality
Atk - Atr +2 (TrTk) (3)
The delay component At r and the propagation delay time T corresponding to the first subscriber installation 3
rr connected to the network are stored by the central office 1 and are used as reference values for the calculation of the other components of delay At as the other subscriber facilities are connected.

 The delay component At assigned by the central office 1 to the first subscriber installation 3 connected to the network must be determined so as to respect two functional conditions.

A first functional condition is expressed by the following relation
#tr # 2 (tmaxi) -t)
Atr a maxi mini (4)
This relation (4) is deduced from the equality (2) by considering that a delay component A j must be positive or zero and this whatever the indices j and r between 1 and J.

A second functional condition arises from the fact that the delay component At must be such that the end of the reception
r of the DC connection request word transmitted by the subscriber installation 3k occurs before the start of receiving the MM data word transmitted by the installation 3r, to avoid any
r possibility of interference in the reception of the words DC and MM
The following relation must therefore be satisfied:
Tb a> Ta + D (5) where Tb and D respectively represent the time elapsed between the initial time ti and the start time of reception of the data word MM and the duration of the DC connection request word.

Hence, given the equality (1) and the equality
Tb has 2Tr + DP + Atr, it comes the following relation: #tr> 2 (tk-tr) + D (6)
To satisfy this relation (6) whatever the indices k and r between 1 and J, the second following functional condition must be satisfied.
#tr> 2 (tmaxi (7)
This condition (7) encompasses the first functional condition (4) and is therefore sufficient on its own.

 The delay component #tk and the rank n + 1 corresponding to the subscriber installation 3k are included by the central office I in the service word MS of a downstream packet PD2 transmitted by the central office during a first period of time. communication following the receipt of the PMl amount packet. The delay component #tk and the rank n + 1 are detected by the installation 3k in the service word MS of the packet PD2 and are stored for the duration of the communication. The subscriber installation 3k transmits the data word NNk after an Atk + n.IT delay after the PM2 packet has been received. At coupler 2, the word thus coincides with the corresponding time interval IT; +1 of a PM2 uplink packet transmitted to central office 1.

Claims (3)

 1 - Synchronization method for multiplexing on a single transmission medium such as optical fiber of words transmitted respectively by a plurality of terminal stations to 3J) and intended for a central station (1), said central and terminal stations (1, 31 to 3J) being interconnected in a star-shaped communication network having transmission media (12, 231 to 23j) of different lengths respectively connected to the different stations (1, 31 to 3j) and to a central node (2) of the communication network. communication, characterized in that a connection of a terminal station (3k) 8U communication network is preceded by a measurement of a propagation delay time (Tk) between said terminal station (3k) and the central station (1). ) and that according to said measured propagation delay time (Tk) and a reference propagation delay time (firing) corresponding to the first terminal station (3r) connected to the network, it is determines a delay time (htk) which is allocated to the terminal station (3k) so that it delays the transmission of its word of said delay time (btk) so that at the central node (2) of the network said word (MMk) inserts in a corresponding time interval (ITn + 1) of a multiplexed word message (PH) transmitted to the central station (1) without interfering with the other message words (MMj) transmitted by the other terminal stations (33).  2 - Process according to claim 1, characterized in that the delay time (Atk) allocated to a terminal station (3k) is equal to the s-se of a reference delay time (btr) corresponding to the first terminal station (3r) connected to the network and twice the difference between the reference propagation delay tapa (Tr) and the measured propagation delay tqps (tek) corresponding to said terminal station  3 - Method according to claim 2, characterized in that the reference delay time (#tr) is at least equal to the sum of twice the difference (tmaxitmini) between a maximum propagation delay time and a time of minimum propagation delay corresponding respectively to a terminal station closest to the central node (2) of the network and to a terminal station furthest from the central node (2) and of a determined duration (D) corresponding to a request word connection (DC) possibly transmitted to the central station (1) by a terminal station