NO160279B - PROCEDURE FOR AA TRANSFER INFORMATION FROM A DIGITAL TELECOMMUNICATION NETWORK AND NETWORK FOR SUCH TRANSMISSION. - Google Patents

Description

The present invention relates to a method

to transfer information via a digital telecommunications network and a .digital communication network for application of the method. The telecommunications network comprises digital exchanges, mesh-like interlaced using two-way time-division multiplex (TDM) connections. In this case, there is a mesh network when there is the possibility of path selection for the transfer of information between two network centers. The proposed network consequently comprises at least three exchanges, each of which is provided with connection points for connecting a number of said two-way connections. The centers each include a generator for the generation of

a clock pulse and synchronization signal pattern, and a digital TDM switch connected to an associated subscriber equipment group, the first <p>g second switch terminals being used to transmit information respectively coming from the group and going to the group.

For the transmission of information via a mesh network, path selection principles have so far been used, which have the common task of utilizing the network's total transmission capacity,

i.e. the avoidance as far as possible of traffic congestion. According to the principle described in US patent 3,111,595, each call connection is started by scanning the occupancy status of all paths for the desired information transfer between two exchanges, and the first detected free path is used for that. the connection. With program memory-controlled mesh network systems, route selection is controlled using centralized or decentralized route selection units, which select, e.g. according to US patent 3,231,676, the most suitable way for the relevant information transfer. The route selection process is here more complicated than the subsequent call connection process.

In telecommunications systems with a total traffic density that is rarely greater than the traffic capacity of a connection between two stations, the highly sophisticated routing functions of a mesh network are avoided by arranging from the beginning a circular loop instead of the mesh network,

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as all the central units in the system are connected to the loop. The conversations are connected here with the help of simple control functions, but traffic blocking is achieved when all information transmission channels in the loop are already busy. Loop systems are more vulnerable than mesh systems.

If a single unidirectional loop is installed, the entire system will fail due to a single loop failure. The vulnerability decreases if spare loops are arranged, and decreases further if the formation of a composite loop is made possible by fault-free parts in different original loops. Conventional loop systems are offered, e.g. by the Inter-national Business Machines Corporation under the designation "IBM 8100 Information System", but users, such as police, military services, airports, petrochemical plants, etc., who require a telecommunications system that is as little vulnerable as possible, have until now had to base itself on conventional mesh-shaped networks with complicated control functions for route selection and call connection, even if the information transmission capacity for a loop system would be sufficient.

When using the information transfer method

and the telecommunications network according to the invention, robust properties that characterize a mesh-shaped network are achieved there in combination with the simple distributed central control functions that characterize information transmission using a digital loop system. At the same time, the above-mentioned disadvantages of conventional mesh nets and risks of accidents with conventional loop nets are avoided.

The main inventive concept is to first build up a mesh-shaped network, but then to start each operating period

by creating a known in and of itself one-way round-trip TDM loop, which connects all the network's exchanges

in series, and by means of which information is transferred between different subscriber equipment groups during this period of operation

In the event of changes in the mesh network due to the relocation of a switchboard, the arrival of a new switchboard, or an error that occurs in a TDM connection that is part of the existing loop, a new operating period is started by means of the creation of a new loop. It is possible to perform a reconfiguration. ration of the loop during ongoing information transfer without changing the associated connection data that defines for this transfer the relevant subscriber equipment and the TDM channel used on the loop. Such a reconfiguration, which is carried out practically without disturbances, is achieved according to the invention by continuously monitoring all the TDM connections in the network.

The characteristic features of the invention are stated in the patent claims.

The invention will now be described in detail with reference to the attached drawing which shows two-way TDM connections 1-5, which interweave digital exchanges 6-9 in the form of a mesh.

Each of the exchanges is connected to a subscriber equipment group 12 and comprises a TDM converter 13, a generator 16 for generating a clock pulse and synchronization signal pattern,

a coupling unit 17 and a control unit 18.

The proposed method for transferring information between subscriber equipment belonging to different subscriber equipment groups via a mesh-shaped telecommunications network is particularly suitable when, parallel to the need for information transfer within a group, there is a global need for information transfer between the groups, which is covered by transfer the capacity of a TDM connection. During the construction of the network, each subscriber group forms an individual digital central unit for internal group calls, and the central units lay out the TDM connections between them. The drawing shows a digital network, the construction of which has reached the point where five two-way TDM connections 1 - 5 mesh-likely intertwine four digital exchanges 6-9. The exchanges are provided with connection points 10 and 11 to connect the TDM connections for the direction of information transmission which respectively departs from the exchange and arrives at it. The subscriber equipment groups 12 are indicated in the drawing, and each of these is associated with its respective exchange 6 - 9, and is connected to a digital TDM switcher 13, which is equipped with a first switcher terminal 14, via which information coming from the associated subscriber unit is transmitted rs group, and with a second exchange terminal 15, via which information is transferred that goes to the group. The drawing does not show how the switches 13 are controlled in a conventional way for connecting internal group calls and global calls that pass through the terminals 14 and 15.

The proposed telecommunications network comprises mainly similar modules, each of which is arranged in a switchboard and comprises, in addition to the TDM converter 13 mentioned above, a conventional generator 16 for generating a clock pulse and synchronization signal pattern, a switching unit 17 which is connected to the connection points 10 and 11 , to the converter terminals 14 and 15, and to the generator 16 in the exchange, and also includes a control unit 18 to control said switching unit in cooperation with the remaining such control units in the network. The connection unit 17 is arranged to connect the generator 16, on the basis of instructions obtained from the control unit 18, to one of the connection points 10 belonging to the transmission direction emanating from the exchange, for connection of the first and second converter terminals 14 and 15 to only one of the connection points 10 and 11 which belong to the transmission direction which respectively originates from and arrives at the exchange, and to interconnect pairs of the connection points which are not connected to the exchange terminals, in such a way that the points belonging to different TDM connections and different transmission directions form pairs.

The drawing shows only the module included in the exchange 6 in detail, and shows an embodiment according to which its switching unit 17, due to instructions received from its control unit 18, has connected its generator 16 to two of its connection points 10 belonging to the TDM connections 1 and 4, has connected its converter terminal 14 and 15 to its connection point 10 and 11 which belong to connections 1 and 4 respectively, and has connected its connection point 11 which belongs to connection 1 to its connection point 10 which belongs to connection 2.

It is also indicated on the drawing that the switchboard \ 1 has

its exchanger 13 connected for both transmission connections to the TDM connection 1, that the exchange 8 has its exchanger terminals 14 and 15 connected to connections 3 and 2 respectively, and that the exchange 9 has its exchanger terminals 14 and 15 connected to connections 4 and 3 respectively.

Consequently, according to the drawing, the network's control units have established a one-way round-trip TDM loop, which connects all the TDM converters 13 in the exchanges in series, the loop from the exchanges 7 to the exchange 8 going via the switching unit in the exchange 6. The TDM generator in the loop consists of the generator 16 in the exchange 6. Already during the laying out of the connections, i.e. during the construction of the mesh-shaped network, but before the creation of the loop, in each exchange, the control unit 18 sends or receives network signals via its connection points, respectively 10 and 11. The network signaling to provide cooperation between the control units is performed conventionally on the signal channels for the TDM connections, and does not require any synchronization of the generators. Each exchange transmits its own network signals using the TDM clock signal generated by its own generator. In conventional TDM systems, there are also synchronization channels in addition to channels for call transmission and the aforementioned signal channels. The connection of the associated generator 16 and the TDM converter 13 to the central connection points 10, 11 is carried out by means of the switching unit 17 for a central, are conventionally permanent for the synchronization channels and the conversation channels. For clarity, the conventional connections between the generator 16 and the control unit 18 are omitted from the drawing, as well as the conventional signal and synchronization channel lines between the control unit 18 and the connection points 10 and 11 for the TDM connections.

The first network signals that the exchanges send during the development of the network are identity requests. Already at the beginning of the network's installation, i.e. in connection with laying out the TDM connections, one of the exchanges is designated as the main exchange. The other exchanges are slave exchanges. The main appointment can be made manually or automatically. With automatic main designation, the switchboard that first receives an identity request from another switchboard designates itself as the main switchboard before another switchboard has answered its own request. Only the main switchboard can assign identity numbers to itself and to the slave switchboards. Via the TDM connections connected to the master exchange, the master exchange then, by means of a conventional handshake, informs the slave exchanges of its own identity number and those of the slave exchanges.

Before the above-mentioned one-way circular loop is

been established, each generator 16 is connected by means of the associated connection unit 17 to the synchronization channel for all associated connection points 10 for the outgoing transmission direction. A conventional synchronization signal pattern is used, which is identical for all mains generators. The state of the mesh is monitored by means of the signal patterns received by the central control units via the synchronization channel at their connection points ril for the incoming transmission direction. The condition of a TDM connection is graded into a number of transmission quality levels, depending on how many errors a controller detects in a received synchronization signal pattern.

In general, network signaling is carried out in a manner known per se so that each exchange retransmits a received signal if this signal has not already been transmitted.

A rapid spread of the network signals is achieved, with the help of which the exchanges first notify each other of theirs

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identity number and then about the transmission quality levels of the installed TDM connections. Each control unit includes data memories for storing identity and state data for the entire telecommunications network, which have been determined by

the network signaling. In principle, therefore, each central station is capable of creating a one-way round-trip TDM loop.

In practice, the main exchange specified in connection with the identity number determines the allocation, a suitable loop configuration, and orders the creation of this loop with the help of the network's connection units. Each control unit stores all data for the relevant loop configuration in its data memory.

Creation of the loop also includes that only one of the network's generators, preferably the central exchange's generator, determines the TDM clock pulse for the entire loop. Monitoring of the transmission quality for the TDM connections is not complicated by the creation of the loop, if the clock pulse received along the loop is used to synchronize the other generators, preferably the generators of the slave centrals, each of which then sends to the synchronization channel for the loop a newly generated signal pattern at the received clock pulse rate. Each exchange judges incoming synchronization signal patterns, regardless of whether the pattern arrives via the loop or via parts of the connections that are not part of the loop. In the mesh network and loop configuration chosen in the drawing, with the switchboards 6 as the main switchboard, the slave switchboard 8 receives, for example, the loop synchronization signal pattern from connection 2, which originates from the generator in the slave switchboard 7, and also the pattern from connections 3 and 5 which are generated by the generators in the slave switchboard 9 respectively and 7. The control unit in the main center 6 receives the loop pattern originating from the generators in the slave centers 7 and 9 and also the pattern from connection 2, which originates from the generators in the slave center 8. The centers 6-9 evaluate their received patterns and notify each other of the thus determined transmission quality level.

However, after the creation of the loop, the above-described network signaling between the control units in the central office, which is used during the construction of the network, ceases. Only the voice channels and the signal channels on the one-way round-trip TDM loop are used to conventionally transfer call information between different subscriber equipment groups or transfer control information between exchanges for connecting or disconnecting calls. In this situation

tion, the main switchboard distributes the loop's call channels, but current call data is stored in all switchboards' data memories. Quality data for the TDM connections are also communicated on the circular loop signal channel to all exchanges after the loop has been established.

If a TDM connection is laid out between a newly added switchboard and a slave switchboard that is part of an established loop, during the construction of the mesh network, the slave switchboard receives the request signal coming from the new switchboard, as this signal is then communicated by the slave switchboard via the loop signal channel to all of the other centers in the network. The central exchange gives the new exchange its identity number and orders a reconfiguration of the loop, on the condition that the transmission quality of the newly established TDM connection is acceptable. As has been mentioned at the outset, loop reconfigurations are made during ongoing global information transfer without changing the call connection data used.

A reconfiguration is also motivated if the transmission quality deteriorates in a part of the loop, or if newly laid out connections in the mesh network enable the creation of a new loop that includes, to a lesser extent, entire two-way connections. According to the embodiment in the drawing, a reconfiguration will be motivated to provide a direct transmission via connection 5 from central 7 to central 8 if connection 5 has good quality.

Just as only the main exchange is allowed to order the initial loop establishment, the kurl main exchange is allowed to order loop reconfiguration. However, as all exchanges store all data about the current state of the network, any slave exchange can take over the main function at any time.

Claims (4)

1. Method for transmitting information via a digital telecommunications network, which comprises digital exchanges which are mesh-shaped interlaced by means of two-way time division multiplex (TDM) connections, said exchanges each being provided with connection points for connecting a number of said two-way connections, and each comprises its own generator for generating a clock pulse and synchronization signal pattern and its own digital TDM converter connected to an associated subscriber equipment group, a first and second converter terminal in said TDM converter being used to transmit information which respectively comes from or goes to said group, characterized by that it is possible in each switchboard, by means of basically identical control functions, to connect a) said generator to one of the connection points belonging to the transmission direction departing from the switchboard, b) said first and second converter terminal to only one of the connection points belonging to the transmission direction as respectively departs from and arrives at the exchange, c) mutual pairs of connection points that are not connected to the exchange terminals, in such a way that points belonging to different TDM connections and different transmission directions form pairs, and that the exchanges cooperate in such a way that, with the help of said switching functions, a one-way round-trip TDM loop is created that runs between all exchanges in the network, the TDM clock pulse for the loop being determined by only one of the mentioned generators, and since the loop is used to transmit info tion between subscriber equipment belonging to different subscriber equipment groups. 2. Method for transmitting information as specified in claim 1, characterized in that the generators in the exchanges generate similar synchronization signal patterns and are mutually synchronized with the help of the loop's TDM clock pulse, and that the generator in each switchboard is connected to all connection points belonging to the transmission direction that departs from the switchboard, and that the exchanges use the signal patterns, received via the connection points for the incoming transmission direction, to continuously monitor the operability of the TDM connections. 3. Method for transmitting information as stated in claim 2, characterized in that the one-way round-trip TDM loop is reconfigured when necessary to achieve an improved information transmission quality. 4. Digital communication network for information transmission as stated in claim 1, and comprising digital exchanges (6-9) which are mesh-shaped interlaced by means of two-way time division multiplex (TDM)' connections (1-5), said exchanges each being provided with connection points (10, 11) for connecting a number of said two-way connections, each comprising its own generator (16) for generating a clock pulse and synchronization signal pattern and its own digital TDM converter (13) connected to an associated subscriber equipment group (12 ), in that a first and a second switcher terminal (14 and 15) at said TDM switcher (13) are used to transmit information that respectively comes from and goes to said group, characterized in that the telecommunications network contains essentially the same modules for network synchronization and selection of ways for information transmission between subscriber equipment that belong to different subscriber equipment groups, as the aforementioned modules are each part of a central and each about comprises, in addition to said converter (13) and generator (16), a connection unit (17) to connect a) the generator (16) to one of the connection points (10) belonging to the transmission direction departing from the exchange, b) said first and second converter terminals (14 and 15) to only one of the connection points (10 and 11) belonging to the direction of transmission which respectively departs from and arrives at the switchboard, c) pairs of connection points that are not connected to the exchange terminals, in such a way that points belonging to different TDM connections and different transmission directions form pairs, as well as a control unit (18) which controls said switching unit and which is connected to the connection points (10, 11) in the exchange for cooperation with the other control units in the network, the control units cooperating so that the switching units for the exchanges create a one-way round-trip TDM loop between all exchanges in the network, as the TDM clock pulse for the loop is determined only by one of the aforementioned generators, and the loop is used to transmit information between different subscriber equipment groups.