DE2513606A1 - Data transmission network with data blocks switched between loops - uses reduction in loop address difference as switching criterion - Google Patents

Abstract

The data transmission network consists of a matrix of transmission paths connecting loops at the junctions where orthogonal paths meet. Data blocks are transmitted through the network by addressing these junctions. The data blocks are provided with loop address differences for path hunting and occupy arbitrary time slots, only the bits within a block having a fixed phase relationship. A reduction in the loop address difference is used as a criterion for the further switching of any data block. The advantage over other such loop networks lies in reducing the number of stores at the loop junctions and in simplifying block transfer from one loop to another.

Description

"Message transmission system for the transmission of messages between selectable terminals by means of a mesh network linked by network nodes "Die The invention relates to a message transmission system for the transmission of messages between selectable terminals by means of a mesh network linked by network nodes, being the basic structure of the network of elementary rings with nodes and between the node lying directional transmission lines is formed and on one Several elementary rings are connected to each node, in which the elementary Wrestling an address is assigned in each case, such that the amount of the ring address difference grows with the distance between the rings, in which in the transmission lines of each A large number of branches with at least one terminal are inserted in the ring, in which the branches are connected to them in free periods of time Transmission line in the outgoing direction Data blocks, provided with the address the receiving end station and the data blocks intended for their end stations based on the terminal address contained in the data block from a connected to it remove incoming transmission line.

The invention is based on a message system of the type mentioned at the beginning Art found in the work of R.L. Graham, H.O. Pollak, 3.S.T.J. 50, pp. 2495 to 2519, Oct. 1971, WOn the addressing problem for loop switching "is described.

However, this known system has the disadvantage that in each loop There is a rigid time frame that is in closed loops by means of elaborate Storage and controller runtime compensation is required for the time frames and that extensive buffers are also required in the network nodes, in order to achieve synchronicity of the time frames in multiple meshed networks. The network nodes are like this aws that data blocks are always in accordance with the Hamming distance in the optimal direction and, if that is not the case possible, must be cached in similarly complex memories.

The present invention is based on the object of the system of the type mentioned at the beginning. In particular, the extensive Memory in the network nodes can be saved. The transfer of the data blocks from one loop to the other should be simplified. Data blocks which on the optimal connection path due to the occupancy of a transmission line can be forwarded, if possible not get lost.

This object is achieved by the invention mentioned in claim 1.

It is now possible with a system of the type mentioned at the beginning to save the expensive memory in the nodes.

A running time adjustment within a loop is no longer necessary. The network can be easily expanded at any time. The data blocks are though as in the known system automatically from the node in the direction of the called party Terminal routed, but takes place when the transmission line is busy According to the invention, a forwarding of the data in blocks in the node on a bypass route / a other direction. their reduction The number of deletions carried along in the data block and the possibility / in the case of unfavorable forwarding has the advantageous effect that the messaging system does not use data blocks that are optimal when the network is busy Deviating way too far, being flooded.

Advantageous refinements and developments of the system are specified in the subclaims. In the embodiment of the invention according to claim 2 one has a network with transmission lines with high transmission capacity and the probability that a data block will not find the called terminal, is extremely low.

Various subscriber services, such as B. telephony, video telephony and data transmission can be connected.

The nodes of the system according to the invention are, in particular, in use integrated circuit technology, spatially so small that they branch off for the terminal (s) can be built in, so that the cost of the extension of the network stay low.

The number of incoming transmission lines becomes equal to the number of the outgoing transmission lines in the node ge.

selects, there is always an outgoing one for each incoming data block Transmission line available and forwarding of the data block is without longer intermediate storage or loss of the data block possible.

A larger number of terminals a @ can be closed at a junction and it is useful if connected to a branch between the Terminal a direct switching takes place, so that the exchange of messages this Terminals among each other do not burden the cylinder network.

In general, the various subscriber services have outputs with different data block lengths or data block sequences. For forwarding of the data blocks in the nodes, it is therefore advantageous if the data blocks have a Contain information about the data block length. However, this information can be saved when the different subscriber services work with the same data block length.

As a result of the different paths that the data blocks take between the end stations conducting a message exchange . ~ ~ lay / their running times are generally different. At greater distances between the terminals it is even possible that the original data block sequence get lost.

Therefore, an expedient development of the invention provides that the data blocks are numbered consecutively from the sending branch and from the receiving branch in the correct order and the correct time Be spaced.

In another embodiment of the invention, the messages in the form of long data blocks compared to the runtime of the individual data blocks sent with a long time lag. This is the respective data block spacing greater than the maximum expected run time fluctuations, the effort for the proposed numbering of the data blocks of the sending terminal and the There is no need to sort the data blocks in the receiving branch.

It is favorable in the proposed system in the branches Provide facilities to the running charges for the respective at the turnouts Count and save connected terminals. The fee office can then due to query the respective counter reading of a data block sent by it.

The fee for using the system is expediently not only proportional to the duration of the call, but also proportional to that of the sending party Branch determined ring address difference and the charge status of the Transfer the junction to the terminal and display it to the subscriber there.

By sampling lines, as they are, for example, in R. Schwarte "Zur Measurement of the curve shape once, at the same time in the subnanosecond range and millivolt range running processes by means of the sampling technique "Dissertation, T.K. Aachen 1972, are described, multiplexers and demultiplexers can be used for the ii Gbit / s range Branches can be realized.

A large number of terminals with conventional connection lines can connect in a simple manner to the system according to the invention, if complete Contribution rings locally, e.g. B. in an already existing exchange, concentrated are.

Claim 16 finally gives an expedient design of a node for the system according to the invention. In each node there is consequently runtime memory, Decision-making units, a controller and a logic circuit to link the incoming with one of the outgoing transmission lines.

In this case, it may be useful to switch through frequently To give priority to transmission lines. This can happen based on experience a fixed assignment can be made or by the controller depending on the statistical Distribution of optimal connections can be determined and controlled accordingly.

To discharge + lng the system through messages over long distances remote nodes can also be routed through additional transmission lines are directly connected to each other for both transmission directions.

The system can also be designed in an advantageous manner that Terminals with important messages establish a connection even with heavy message traffic can produce with each other.

For this purpose, facilities are provided in their branches that provide the Give data blocks from these terminals a higher number of deletions than usual.

Also the adjustability of the barrier for deleting a data block in the nodes on values> 0 is favorable for keeping clear certain important communication routes. The system is therefore extremely flexible and will now be explained in more detail on the basis of exemplary embodiments. They show: figure 1 Basic topological structure of the mesh network with nodes, rings and on them connected branches.

Figure 2 Topological basic structure of the loop network with an additional one Connection between two nodes.

Figure 3 Extension of a ring by several ring lines.

Pigur 4 Extension of the network by adding more rings to one elemental ring.

Figure 5 structure of a data block.

Figure 6 block diagram of a node.

Figure 7 is a block diagram of a junction with a terminal.

Figure 1 shows the topological basic structure of the Easch network. In this simple 3-example it consists of ele-entary rings with four each Nodes and directional transmission lines located between the nodes. On one Four elementary rings are connected to each node. Every elementary pjng is assigned a binary address in such a way that the amount of the ring address difference with the spacing of the rings grows. The augmentation of the rings is chosen so that there are four elementary rings in a common node, for example Node 23, are combined to form a ring of the first order. This 1st order ring thus includes in the selected example the elementary rings 0010, 1010, 0110, 1110 and its lines go through nodes 12, 13, 14, 24, 34, 33, 32, and 22.

The xage of the four elementary rings within the 1st order ring becomes indicated by two binary digits, the first of which is the horizontal and the second indicates the vertical position of the elementary ring of the 1st order. With the two on the left Elementary rings, the first bit is therefore a 0 for the two right-hand elementary rings the first bit is 1. The second bit is a for the two upper elementary rings 0, for the two lower ones a 1.

Four rings of the first order now become a ß ng 2 in the same way. Linked order. In the example shown, it extends between elementary rings the game using notes 10 to 14, 24, 34, 44, 54, 50 to 53, 40, 30 and 20. The For example, ring address Oi = 0 0 11 belongs to the left, corresponding to the first zero the second zero to the upper elementary ring of the (corresponding to the third standing 1) right and (corresponding to the fourth position 1) lower 1st order ring of a ring that can be localized even more closely using the following bits second order.

Real networks do not have to be geometrically, only topologically must be identical to the network shown in Figure 1.

In particular, it is generally not the case that the two transmission lines running in the opposite direction of a branch of the same route follow. Since the two transmission lines belong to different rings and different Branches with their terminals are connected to it, the transmission lines run also spatially separated.

From the target ring address, i.e. the address of the ring on which the Branch of the called terminal is, and the ring address of the ring in which the message is currently located, the direction can be determined, which for the Forwarding of every message arriving at a node is optimal. According to illustration 1 is the address of each elementary ring through a bit sequence a0b0a1b1a2b2 ...... Anbn (1), where the bits identified by a0, a1, ..... at (2) are the horizontal Position and the bits identified by bo, b1, ..... bn (3) the vertical position of the ring in a ring higher than the nth order.

The binary digits a0 .... an become in the binary number A = 20a0 + 21a1 + ........ 2nan (4) combined. Likewise, B = 20b0 + 21b1 + 22b2 + ........ 2nbn applies (5) If the largest structure is a ring (n + 1) th order, then the pair of numbers gives (A, B) exactly the position of an elementary ring within the first-order ring.

The abbreviation C should be used for the pair of numbers (A, B). C. is called a ring coordinate pair. The ring coordinate difference between two ring coordinates Ci and Dij = (A, B) = Ci - Cj (6) is defined by the fact that with Ci = (Ai / Bi) and Cj = (Aj / Bj) A '= Ai - Aj (7) B' = Bi - Bj applies. You can now everyone on the network Assign the message a coordinate difference DZX = CZ - CX (9), where CZ is the pair of coordinates of the target ring and the coordinate pair of the elementary ring in which the Message is currently located. DZX consists of the pair of numbers (AZ - AX, BZ - the end Eq. (9) are followed by the important properties DXX = (0, 0), (10) DXY = -DYX, (11) Dzy + DYX = DZX (12) The coordinate difference is called the ring address difference of each message running in the network. The transition from ring X to ring Y becomes the coordinate difference Dxx or the The coordinate difference DXY is added and according to Eq. (12) thereby the new coordinate difference DZY as ring address difference. / From Eq. (9) it follows that the change in the coordinate difference, that carries the message, between two rings, that of a message only depends on the addresses of the two rings and not on the The way the message got from one ring to the other. So it will be a Message given in the ring S and is the target coordinate difference to the target ring Dzs, so will the message if it is after a time in any elementary Ring X is located, carry the coordinate difference DZX with them, which is independent of the Is the way on which the message got from ring S to ring X.

A metric is now impressed on the coordinate differences in such a way that that each coordinate difference DYX is assigned a distance #YX and that the conditions An - O (13) #YX = #XY #ZX # #YX + #ZY are fulfilled. hyZ is real, not negative Number. The distance can be set using #ZX = AZ - AX + BZ - BX or #ZX = (AZ - AX) 2 + (BZ - BX) 2 (17) or in any other way that complies with G1. (13), (14) and (15) fulfilled, defined, a message running in the network will be in the node transferred in such a way that the distance #ZX is reduced because the message runs to the goal. The message is forwarded in each node on the basis of this local decisions.

The horizontal and vertical differences can be found in the message be carried nested in one another or consecutively in the form a0a1 ..... anan + 1 b0b1 ..... bnbn + 1 The forwarding and the changes the ring address differences of a data block should now be based on a simple Example and Figure 1 are explained. For simplification, let the data block run within a first-order ring, since then only four binary digits for a ring address is sufficient to explain the procedure. For example, be a Data block, which is sent out in the ring CO s 0 0 0 0 from the branch Ao, for a terminal in the ring C5 - 1 0 0 1 is determined.

For this purpose, junction Ao provides the data block with the ring address difference, which it determines from the ring addresses C) and C0 as follows: For CO = (A0 / B0) aO = bo = a1 = b1 s 0, so C0 = (o, o).

For C5 = (A5 / B5), a0 = 1, b0 = a1 = 0, b1 = 1 and thus according to the equation 4 with binary notation A5 = 1 + 0 = 1 The other elements a2b2 ... are omitted, because in this simple example the connection within a first order ring is explained and thus a 4-digit binary number is sufficient for finding the way.

According to Eq. (5) is in binary notation B5 I 0 + 10 = 10 and thus 5 = (A5 / B5) = (1.10) According to Eq. (9) is now the ring address difference determined by branch A0 D50 = C5 - C0 = (1/10) - (0/0) = (1/10) This is added to the data block as a binary number, for example in the form 0 1 1 0.

According to FIG. 1, the data block arrives at node 21. There are available Further training rings with the addresses C0 = 0 0 0 0, C1 = 0 1 0 O, C2 P 1 0 0 0 and C3 = 1 1 0 0 available.

These addresses are located in the node according to Eq. (4) and (5) as ring coordinate pairs C0 = (0/0), C1 = (0/1), C2 = (1/0), C3 = (1/1) before and depending on the incoming and outgoing Transmission line, the node can determine the ring coordinate differences at the respective Reconciliation according to Eq. Determine (6) to (8).

So is z. B.

XY = D12 = C1 - C2 = (-1,1) or DC0 = C0 - C0 = (0,0 D10 = C1 - C0 = (0.1) The facilities of the node now form with the ring address difference D50 = (1/10) of the data block the respective distance #ZY according to Eq. (16), where is #ZY = D50 - DXY and get the binary values: # 50 = D50 - DC0 = 1 - 0 + 10 - 0 = 11 # 51 = D50 - D10 = 1 - 0 + 10 - 1 = 10 # 52 = D50 - D20 = 1 - 1 + 10 - 0 = 10 # 53 = D50 - D30 = 1 - 1 + 10 - 1 = 1 # 53 has the smallest value. Hence the data block into the ring with the address C3. (1/1) forwarded. Before that, however, is in the knot 21 its original ring address difference D50 = (1/10) according to Eq. (12) into a new ring address difference D53 changed.

D53 = DZY = DZX - DYX = D50 - D30 = (1/10) - (1/1) D53 = (0/1) as Binary number 0 0 0 1 for the data block.

With this ring address difference, the data block according to FIG 1 the node 31. There are the paths in the rings C1 = O 1 0 0, C3 = 1 1 0 0, C4 = 0 0 0 1 and C5 = 1 0 0 1 are available. Are written as ring coordinate pairs C1 = (0/1), C3 = (1/1), C4 = (0/10), C5 = (1/10).

The transition coordinate differences are D13 = (1/0), D33 = (0/0), D43 = (1.1), D53 = (0.1), and the distances to the target ring with the new ring address difference D 53 = (0/1) of the data block: D53 - D13 = 0 + 1 + 1 - 0 = 2 D53 - D33 = 0 - 0 + 1 - 0 = 1 D53 - D43 = 0 + 1 + 1 - 1 = 2 D53 - D53 = 0 - 0 + 1 - 1 = 0 The data block is consequently transferred from node 31 to destination ring C5 there has the ring address difference 0 and runs in ring C5 until it is taken from a junction of the ring.

If the overall network is an nth order ring, then for the horizontal and vertical ring address differences a maximum of 2 (n + 1) bits are required, namely 2n bits for the amounts of the difference and 2 bits for the sign.

In the event that the message and its destination are in the same ring m-th order, 2 (m + 1) bits are sufficient to represent the address difference the end. Since two terminals in a common ring are essential for local connections are lower than the nth order, it is better to first determine the number of digits of the Ring address difference and then transfer its 2m + 2 digits. The message will expediently transmitted in blocks as a data block, a data block u. a. from an address part made up of the ring address difference and the address the end point exists within the target ring. When dialing the number of the desired The terminal is already the ring address difference in the branch of the calling terminal formed between the target ring address and the ring address of the calling terminal and the Data block including the message given. During the run of the data block the ring address difference is continuously reduced until the data block is in the target ring only the terminal address and the message that are valid within the target ring carries with it.

The terminals E are connected to a transmission line of the message transmission system according to Figure 1 each via branches A, each in a transmission line are inserted, connected. In the transmission lines of each ring can a large number of junctions with at least one terminal can be inserted. At the branches can provide various subscriber services, such as telephony, Video telephones or data transmission devices must be connected. Using the example of Node 31 is shown that this is designed as a junction and at the same time in this junction formed as a node several incoming and just as many outgoing transmission lines open.

With the network structure according to Figure 1, a data block in the network can only be passed on via adjoining elementary rings. To the network not additionally burdened by data blocks that are routed over longer distances should be, it is useful to between individual nodes that are further away of the network additional VS transmission lines for both transmission directions to introduce. topological basic structure of such a mesh network with a Figure 2 shows the additional connection between two nodes. The two are there distant nodes K1 and E2 by one each transmission line connected for both transmission directions. This, through the additional transmission lines formed network branches require, if no terminals are connected to them, no own addresses. It is important that the number of the transmission lines arriving at a node are the same as those from the node outgoing transmission lines is.

The decision as to whether a data block that ranks in node K1 should be in an elementary ring adjacent to the node K1 is forwarded or via the additional connection line to node K2 continues, is a local decision of the facilities in node K1 and can for example be taken in the following way will: The ring address difference between target ring address and Momentary ring address of the data block that enters the node K1 with the Sum of the ring address differences from node K1 to node K2 and from node E2 compared to the target ring.

According to Eq. (i5) is the sum of the ring address differences from the node K1 to node K2 and from node E2 to the target ring always greater than the direct ring address difference. However, there is the forwarding of the data block via the additional connection line is more favorable, a constant amount is allowed by which the sum of the ring address differences from node X1 to node E2 and from node K2 to the target ring may be greater than the direct ring address difference from node K1 to the destination ring.

As long as this amount is not reached, it is cheaper to use the data block to be routed via the additional connection line. The network can go through entire hierarchies different lengths of additional connecting lines expanded in the manner shown will.

At each elementary ring there is a larger number of terminals above Branches can be connected. Reaches the number of terminals at an elementary level If the ring is no longer justifiable, the network must be expanded. An expansion option is, for example, that not all possible ring addresses are initially assigned to specific rings.

If a 1st order ring is chosen as the lowest ring order, then leave it later four rings of the zeroth order are formed from this and so in this area accommodate four times the number of terminals.

But it is also possible to leave every fourth ring of each order unoccupied allow. Then three rings of the zeroth order are combined into a ring of the first order, three rings of 1 order to a ring of second order and so on. Must be the network in one If a certain area is expanded, further rings of the zeroth order are initially created introduced, then further rings of the 1st and later higher order.

Another way to expand the network is according to Figure 3 insert additional rings in an elementary ring. In this case it will when a ring of the zeroth order is fully utilized, the ring through four rings - 1st order replaced etc. With this procedure, not only do the highest glide, but also the lowest digits of the ring address, which is why of the digits of the ring address the highest and lowest with position in the data block K7E must be transmitted. This can for example in a manner known per se by the length of the Binary number and the position of the decimal point. The network is following this procedure Can be expanded as required without a pre-planned reserve.

Is the number of digits in the terminal addresses within a ring not specified, the number of terminals in a ring / üDer die Number of digits of your address can be expanded as required. A ring is then expedient expanded so that several parallel transmission lines, as Figure 4 shows, as Ring to be relocated.

If a data block has reached the target ring, it has the target ring address difference already lost when entering the target ring. The branch of the called subscriber recognizes when the data block enters the junction on the basis of the data block given terminal address the data block intended for it, loops it from the incoming transmission line and forwards it based on the terminal address continue to the called terminal.

The branches can be in any order in an elementary Be inserted ring. Are as shown in Figure 4 1 several transmission lines Laid in parallel in a ring, it is advantageous to also include them in the terminal addresses to bring a system that enables the data block to move within the ring to reach the desired end point as quickly as possible.

In Figure 4, four transmission lines are arranged in a ring. The ring is divided into real segments by accounts K3 to K10, with the nodes the transition from each of the four transmission lines to every other transmission line of the ring is possible. In the nodes K31 E5, E7 and K9 there is also a transition to other rings possible.

It now first knows the segments, then the transmission lines and finally the terminals of a ring are numbered consecutively. The terminal addresses are then composed of a segment address, one assigned to the transmission line Address and the actual participant address together.

The addresses are expediently metrized in such a way that due to local decisions in the nodes K3 to K10 the data blocks in the cheaper of the two transmission directions in the target segment and when entering the target segment to the target line to which the branch of the desired terminal is connected is being directed.

For example, if the data block runs into the target segment on a transmission line at which the junction you are looking for is not located, since the junction is on a oppositely directed transmission line is, the data block passes through first the transmission line of the target segment to the next node and will diverted from this to the desired destination line.

The data blocks are completely asynchronously from the branches into a elementary ring fed and also run throughout the message according to the invention transmission system completely asynchronous. Only within each data block there are fixed phase relationships between the individual bits of the data block. the However, data blocks themselves can have an arbitrary time slot relative to one another. at the regeneration of the data blocks in line repeaters, which are in the directional transmission lines are switched on, the repeater clock is based on the first pulse of each incoming Data blocks triggered.

The bit rate of the data blocks is in the network, apart from one approved tolerance, uniform. The phase position of the bit raster that is used by the different However, data blocks originating from terminals are arbitrary.

The ring address difference carried by the data block becomes the Entry of the data block into a node the Hirarc: called the cheapest transmission lines intended for forwarding the data block.

It may now be the case that the optimal transmission line is already in use is. In this case, the data block is transmitted via the second or third cheapest transmission lines forwarded. To ensure trouble-free linking of the incoming transmission lines to ensure with the outgoing, each data block in the node must have a runtime memory be directed.

Such a runtime memory has a delay that is the same or greater than the maximum length of a data block.

Figure 5 shows the block diagram of a node that four incoming transmission lines L1 to L4 with four outgoing transmission lines B5 to L8 linked. The node contains four runtime memories S1 to S4, each between an incoming transmission line L1 to L4 and a logic circuit V are connected. The inputs of the runtime are also each memory via a Decision unit E1 to E4 connected to a controller St. Because of the The decision units determine the ring address difference carried along with the incoming data blocks the cheapest Direction for forwarding the respective data block and signal this to the controller. controls by means of the connection circuit then the controller forwarding the data blocks to the cheapest outgoing transmission line.

Normally, every incoming transmission line is permanent in the node connected to any outgoing transmission line.

It is advantageous if each incoming transmission line is interchangeably linked with each outgoing transmission line. In order to explain It is assumed that this method is coming from a ring with the address Ci Transmission line initially connected to the transmission line leading to ring C. is. If a data block runs from ring C., which is to be routed into ring Ck, so, if the transmission line leading to the ring Ck is currently free, the transmission line coming from ring Ci connected to it. Was originally the from the ring C1 coming transmission line with the transmission line leading to the ring Ck connected, the transmission line coming from ring C1 is now connected to the to Ring Cj connected leading transmission line.

If, however, the transmission line leading to the ring Ck is straight is not free because a data block coming from ring C1 is arriving there, see above is a swap of the from Ring C. ko = end transmission line connected outgoing transmission line with the one for forwarding the Data blocks next lower transmission line attempted.

Is a swap with a cheaper outgoing transmission line not possible, the data block coming from ring C. can definitely be in the same Run on the ring.

In some parts of the network it will be convenient, everyone in one Node incoming transmission line on a specific outgoing transmission line give priority for forwarding the data block. If not then It is possible to redirect the data block in a more favorable direction, see above the data block can definitely continue in the direction in which the incoming transmission line has priority.

The priorities can be set arbitrarily in each node. This can be B. be done so that in a network according to Figure 1 on all elementary Wrestling has priority, i. i.e., da3 a data block for which no other transmission line is free, revolves in the elementary ring in which it is currently located. If so should prevail within an elementary ring priority is, for example the transmission line L1 arriving from the ring C1 (see FIG. 5) has priority on assigned to the outgoing transmission line B5 in the ring C1.

It must now be ensured that, as soon as a data block, the runtime memory leaves, the transmission line on which it has priority is safely free. This is done when, for example, a signal from the ring of address C1 to the input of the transit time memory S1 and thus also to the input of the decision unit E1 enters the outgoing transmission line in the same ring with address C1 L1 for all data blocks arriving later on other transmission lines L2 to L3 locked, The lock is only released when it is certain that the The data block of the ring with the address C1 run into another, cheaper ring can, or, if the data block enters the same ring again as soon as the Data block has completely entered the memory S1, because then one on one other transmission line incoming data block only after the data block of the ring of address C1 can flow into the logic circuit.

Further. but can also forward the file blocks with variable Priorities. For this purpose, the incoming transmission lines receive the outgoing transmission lines are assigned a variable priority, which is expediently so controlled depending on the statistical distribution of the optimal connections that the frequency that the optimal connections also have priority, is as large as possible.

In the more or less busy network, the individual data blocks are not and are therefore not forwarded in the optimal direction in all nodes reach their goal at unequal time intervals. At high data block frequencies and long distances between the terminals can be even in some cases of Da data blocks sent out later to one terminal point earlier to the other terminal point reach. The data in blocks must therefore be returned to the destination in the correct order to be brought. Advantageously, everyone from the sending branch is used for this purpose sent data block is given a consecutive number, with the help of which the receiving outgoing.

branch can put the data blocks in the correct order. If x binary digits are used for this numbering, the Numbering according to 2x data blocks.

If T is the time interval in which a branch sends, the receiving branch Fluctuations in the arrival time of the data blocks by one Mean around + T. Balance 2x 1.

A memory for 2x incoming data blocks is used in the branches for this purpose with random access on the input side (random access memory) read into the memory location corresponding to their consecutive number and then read out in serial order at regular time intervals.

Another method to overcome the difficulties of different maturity to meet is to long in the branches before sending the message To form data blocks and to send them out at such a great distance that they are in spite of the different Runtimes reach the receiving junction in the correct order. For this a memory is required in the branches in which the messages to be sent first be saved and then in the form of compared to the running time of each Data blocks long data blocks are sent with a large time interval. In the incoming transmission line of the branches required for receiving such long data blocks are equipped, then another memory is to be provided, from which the data blocks are slowly and continuously read.

In heavily used network parts it can happen that a data block is often forwarded in an unfavorable direction, causing him to achieve the target needs an above-average duration. The delay one such data blocks can then be transmitted by the in the incoming transmission line lying memory of the receiving branch no longer: be balanced and such a data block is therefore worthless. To an undesired occupancy of the network Avoid using such data blocks, it is therefore of great advantage to everyone Data block to be given a deletion number, which in the node in the event of an unfavorable forwarding is reduced and with favorable forwarding, depending on the design of the nodes, is increased again. According to the invention, a data block with the erase number zero is created on the next unfavorable forwarding, controlled by the controller of the node, in which the last unfavorable forwarding takes place is no longer issued and turned off.

When a connection is established, the branch sends the calling terminal Data blocks that, apart from the ring address difference for route finding, instead of the Information the address of the calling terminal including its ring address contain.

As soon as the called subscriber answers, the junction is formed the called end station from the received ring address of the calling end station Ring address difference for the connection in the opposite direction and sends data blocks with this ring address difference and your message.

For example, to ensure a smooth exchange of messages The structure of the data-like blocks shown in FIG. 6 expediently. / FIG. 6 shows a data block is made up of several parts.

Part A contains the ring address difference. Your amount will be zero when the data block enters the target ring.

Part B contains the address of the receiving end station within the Target ring. The branches thread on the basis of the address comparison with this sub-block B the data blocks intended for them from the ring connected to them.

Part C contains the erase number.

Part D consists of a single flag that indicates whether it is to establish a connection or a connection that has already been established acts. In the following, the identification bit = 1 when establishing the connection and for one already established connection the flag = 0.

T, il E contains the address while the connection is being established the calling terminal. If the connection is established, then in part E the The consecutive number is transmitted, which is used to transfer the Data blocks in the receiving branch back into the correct order bring.

Part F contains the actual message.

Figure 7 shows the block diagram of a junction with a terminal, in this case a telephone with connection 717 for handset and blade and connection 720 for the microphone of the telephone. The one from the incoming transmission line Lij incoming digital data blocks are first in an amplifier 701 amplified and then pass through a delay line 703. At the same time, the Data block aa, a narrow-band filter 704.

The bit rate of the data block is filtered out in the filter. Although have all data blocks have the same bit clock frequency, but their phase relation to one another is different different. Therefore, the bit clock regeneration must be performed for the individual data blocks take place independently of each other.

While the data block grows from the amplifier 701 into the run time line 703 comes in, / at the output of the filter 704 an oscillation with the bit clock frequency and the phase position belonging to the data block. The narrow-band filter causes an averaging over the phase position of several bits of the data block.

The clock regenerator 708 connected downstream of the filter 704 is before the data block leaves the delay line 703, is triggered and provides the clock for the regeneration of the data block in the signal generator 707, which is at the output the delay line 703 is connected. In the signal generator, amplitude and Edge time of the data bits brought to the setpoint.

Furthermore, the parallel read-in process of the from the signal generator Exiting data blocks are controlled by the clock regenerator 708 in a shift register 712. As soon as the data block has been completely read into the shift register 712, Via the return line from the shift register 712 to the clock regenerator 708, the clock regenerator stopped and the address comparison in the unit 229 activated.

From the unit 229 for address comparison, if the ring address difference Is zero and at the same time the content of part B of the data block with the address of the subscriber agrees between the shift register 712 and the address comparison unit 229 activated memory 713 which contains parts D, E and F of the data block takes over.

While the connection is being established, part D contains a binary one One, whereby the content of the block parts E and F as the address of the calling party is identified and a restoring of the address of the calling subscriber in the destination address memory connected to the memory 713 as well as the automatic Establishing the opposite connection to the calling subscriber is initiated.

As soon as the calling subscriber receives a callback, he sends in the part D of the data block a zero instead of the one, in block E a consecutive number and in block 11 the message. Blocks E and F are then stored in memory 713 in the memory 714 relocated. The memory 713 works as a fast intermediate memory. The memory 714 has a large storage capacity and is used for recovery the correct message sequence if the data block sequence is due to different ways the various data blocks was disturbed.

If the consecutive number in part E x has binary digits, so the memory 714 must have a storage capacity of 2x words the length of the part F of the data block. The memory 714 has any access on the input side. The message bits from part F of the data block are stored in the memory location with the number specified in part E of the data block. Reading out the message words from the memory 714 into the D / A converter connected to it 715 takes place in the order of the memory locations via the word clock generator 702. The Word clock works in all branches with quartz accuracy. Once the store 714 is half full, the read-out process from the memory to the D / A converter begins 715 synchronous to the word clock.

Is entered into shift register 712 after a data block has been completely entered is determined in the address comparison unit 229 that either the ring address difference of part A of the data block f is zero or / subscriber address within the Ring, which can be found in part B of the data block others Participants heard, the forwarding of the data block to the outgoing Transmission line Lik initiated. For this purpose, the address comparison unit 229 the parallel inputs of the shift register 711 are activated.

The parallel outputs of the shift register 712 are always with connected to the parallel inputs of the shift register 711.

By activating the parallel inputs of the shift register 711 the parallel restoring of the data block from the shift register 712 takes place to the shift register 711. At the same time, the address comparison unit 229 a clock generator 728 is triggered and from it the clock for the serial readout process of the data block from the shift register 711 for the outgoing transmission line Lik generated. The clock generator 728 generates only as many clock pulses as there are to shift out of the data block from the shift register 711 are required.

It is designed so that it generates the clock until the next trigger adjusts.

When sending messages that have their output from the shown subscriber device a distinction must be made between two cases. Either the participant calls or he was called and establishes the opposite connection itself.

If the subscriber calls, the address of the called subscriber is displayed first is entered into the destination address memory 726. The entry is made using the dialing keys 725 of the telephone set. Subsequently, by forming the difference with the im Destination address memory 726 permanently programmed own ring address the ring address difference educated. The memory 710 connected to the destination address memory 726 serves as a Buffer for the data block to be sent and is according to the clock of the word clock generator 702 are loaded in parallel. The contents of the memory 710 are after of the charge in the shift register 711 at the next possible point in time and output serially to the outgoing transmission line Lik.

The memory 710 is required, datom the microphone 720 resp.

Analog signal from A / D converter 709 coming from audible tone generator 706 must be scanned periodically with the word clock, for the Aussencung the data block but a point in time must be awaited at which on the incoming transmission line L no data block arrives.

The memory 710 is so large that it contains parts A to F of the Can record data blocks. The parallel inputs for the Parts h and B are connected to the destination address memory 726.

Part C of the data block always contains the erasure number. The erase number is depends on the ring address difference and is in the case of a larger ring address difference also larger, so that the message block, which has a longer way to the destination, also a greater number of inconvenient redirects is allowed before the data block is deleted.

The deletion numbers for participants with higher priority are expedient selected larger, so that the connections desired by these participants also will certainly come about in the heavily loaded network.

A transmission control 727 is activated by the selection keys 725, from from control lines to the memory 710 to a switch 719 for switching from audible tone generator 706 and microphone 720 to a charge meter and to another Switch 716 for switching the handset from the ringing tone generator 718 to the D / A converter 715, lead.

of the memory 710, At the parallel input of the memory location / the dem Part D of the data block is assigned, there is a one if the transmission control 727 is in the "Call" position. In all other cases this position will be used set to zero.

The memory locations for parts E and F of the data block have the at least two groups of parallel entrances. In a third group of parallel entrances For example, the recording of charges for the subscriber station can be carried out will. Which of the input groups is activated depends on the status of the transmission control away. If the transmission control is in the "Calling" state, those parallel inputs are the Memory 710 activated, which is connected to the outputs of the read-only memory 722 for the Subscriber address are connected. If the send control is in the "Send" state, so those inputs of the memory 710 are activated, which are connected to the charge counter 721 and the A / D converter 709 are connected. The outputs of the read-only memory 722 are both with the parallel inputs of the memory 710 to the memory locations for the Part E as well as connected to those of part F of the data block. The outputs of the Billing meter 721 with the part E belonging to the outputs of the A / D converter 709 are connected to the parallel inputs of the memory 710 belonging to part F.

As soon as the caller receives the address when a connection is established of the called subscriber enters with the keypad 725, the transmission control 727 brought to the "" Call "state. With a fixed number of digits for all call numbers or, if there is a connection between the content of the phone number and its number of digits, these characteristics can be evaluated in order to control the transmission in the state Bring "calling".

Otherwise, after entering the phone numbers with an additional Press the command for the transition to the "Call" state to the transmitter control give.

If the transmission control is in the "Call" state, each word clock pulse the contents of the destination address memory 726, the erase number memory 723 and the subscriber address memory 722 is read into memory 710 in parallel. The same happens with every word clock pulse the transmission start unit 730 is activated.

A line testing unit 705 is at the output of the amplifier 710 connected, the output of which is in the logic state one, if at least no signal occurred for an entire data block length at the output of amplifier 701 is. As long as no signal occurs at the output of amplifier 701, the remains exit of the line test unit 705 in the logic state one. Otherwise it goes Output to the logic state zero.

The transmit start unit 730 activated by each word clock pulse gives if a logical one occurs at the output of the line testing unit, immediately following the word clock pulse, emits an output pulse. However, is the exit of the line test unit in the zero state, the transmission start unit only gives after the transition of the line testing unit to the logic state one Impulse off. The pulse of the sending start unit is only in each word clock interval triggered once and due to the described functionality at the next possible Point in time at which the transmission line is free at least one data block length is. The transmission start pulse activates those parallel inputs of the shift register 711, which are connected to the outputs of the memory 710.

As a result, the contents of the memory 710 are transferred to the shift register 711 accepted.

At the same time, the clock generator 728 is triggered by the start pulse, a clock pulse train for the duration of a data block length generated and the contents of the shift register 711 to the outgoing transmission line Lik outputs serially.

With the called subscriber, who in the case of a telephone connection has the same branch and subscriber station as shown in Figure 7, the branch goes into the state immediately after receiving a data block "Send" via. As soon as the address comparison unit 229 of the calling party a data block with the ring address difference zero in part A and the subscriber address of the calling subscriber in part B of the data block, the transmission control device 727 of the calling subscriber switched from the "running" state to the "sending" state.

If a subscriber station is in the "calling" or "sending" state, it speaks the address comparison unit 229 only responds to data blocks with a flag zero. As soon as the connection is established, the calling subscriber can only from Data blocks of the called subscriber can be reached. For all other data blocks, also for those in which in part B of the data block the subscriber address of the calling party Subscriber is included, the calling subscriber is busy.

The callback is automatically produced as follows: Receives a calling subscriber whose transmission control unit 727 is in the idle state is a data block with the identifier 1 from a calling subscriber, the address of the calling subscriber contained in parts E u- + d F & es data block Restored into the destination address memory 726 via the memory 713. In the destination address memory the ring address difference is also formed. At the same time the address comparison unit gives 229 a pulse to the transmission control 727, which is a transition of the transmission control unit from the idle state to the "Send" state.

During the connection, the transmission control units are both participants in the "Send" state.

If one of the two participants terminates the connection, his will go Send control to idle mode and the junction does not send any data blocks more. If the turn off of the other participant during a specified period of time does not receive any data blocks, its transmission control unit also goes to sleep above.

As soon as the branching of the calling subscriber to establish the connection Sends out data blocks, its transmission control unit 727 switches a ringing tone generator 718 to his handset 717.

The branch of the called subscriber receives a data block of the calling subscriber, then in the subscriber station of the called subscriber an elingel character, triggered by its transmission control, which connects a call, current generator Cin Fig. 7 not visible) / generated and the return connection is as already described.

As long as the called subscriber does not pick up the receiver, is in both Subscriber stations of the audible tone generator 706 from the respective transmission control unit switched on and the branches send data blocks with the audible tone as a message in part F of the data block. After the automatic production of the callback goes the transmission control unit 727 of the called subscriber from the "calling" state in FIG the "Send" state.

In the "Send" state, the calling subscriber receives the audible tone as long as which is sent out by the audible tone generator of the called subscriber until the called subscriber has lifted the handset.

The recording of charges in the message transmission system according to the invention can either be done centrally or in the branches of the participants. In the latter case, it can be queried centrally.

If the charges are recorded in each junction, then is in each branch a charge meter shown in the exemplary embodiment in FIG 721

The billing can expediently be carried out in the following manner will. When the transmission control unit changes from the "Calling" state to the "Send", the target ring address difference becomes the content with each word clock pulse of the memory of the billing meter. Querying the status of the billing meter takes place at certain time intervals by toll offices, which are in arbitrary places of the network can be connected to a ring. The fee office automatically a call to the respective participant triggered and the facilities at the participant establish the return connection, as with a normal call. Appropriately the address of the responsible fee office will appear in the branches of the participants stored in a read-only memory. This helps establish the reputation of the toll office from other calls and not a normal callback cause.

Instead of the content of the A / D converter 709, the Contents of the charge counter 721 in the memory 710 in the part F of the data block umfflesaved. The subscriber address is entered in part E of the data block. The data block thus formed is sent back to the toll office.

The connection with the toll office is during some word clock periods maintained so that the data blocks can be safely and clearly evaluated by the toll office be received by this.

The charge meters in the junctions do not generally need to be postponed. However, the fee payers should then definitely be secured against power failure.

This can be done, for example, by transferring the fee unit to a mechanical counters happen. Advantageously, the fee status can be from the branch into the or ina the branch connected subscriber station (s) are transferred and displayed there.

Claims (23)

Claims 1. Message transmission system for the transmission of messages between selectable terminals by means of a mesh network linked by network nodes, wherein the basic structure of the network of elementary rings with nodes and between the Node-lying directional transmission lines is formed and at a node in each case several elementary rings are connected, in the case of which the elementary rings an address is assigned in each case, such that the amount of the ring address difference grows with the spacing of the rings, at which in the transmission lines of each A large number of branches with at least one terminal are inserted in the ring, in which the branches are connected to them in free periods of time Transmission line in the outgoing direction Data blocks, provided with the address the receiving end station and the data blocks intended for their end stations based on the terminal address contained in the data block from a connected to it incoming transmission line, characterized in that the data blocks additionally with a ring address difference used to find the path of the data block are provided that the data blocks can be entered asynchronously from the branches; are, such that only within each data block fixed phase relationships exist between the individual bits of the data block, but the data blocks relate to each other arbitrary time slot that the criterion for the direction of the forwarding can have of a data block is the reduction of the ring address difference, where in each Node from the ring address difference carried along by the data block through logical and algebraic operations in a control circuit set the direction for the forwarding is determined and, if the transmission line is busy, the data block is forwarded in a different direction that occurs each time the data block is forwarded over a node in another ring of the network changed the ring address difference in this way that it is the current difference between the current ring address and the target ring address contains that each data block contains an erasure number which is unfavorable in the node Forwarding is reduced, with a data block with the erase number O in the next unfavorable forwarding is deleted. 2. System according to claim 1, characterized in that for signal transmission optical transmission channels with a bit rate above 1 Gbit / s, with a glass fiber as a transmission line, a modulated injection laser as a transmitter and a Photodiode are provided as a receiver. 3. System according to claim 1 or 2, characterized. Junction: en that different subscriber services are connected to the /. 4. System according to claim 1, characterized in that in branches all / several incoming and the same number of outgoing transmission lines open and the branches are designed as nodes at the same time. 5. System according to one of the preceding claims, characterized in that that in the event that a larger number of terminals are connected to the branches is a direct switch between the terminals connected to this branch he follows. 6. System according to claim 3, characterized in that the message transmission takes place between different subscriber services with different data block lengths and each data block contains information about the data block length. 7. System according to claim 3, characterized in that the message transmission between different subscriber services with the same data block length, but different Data block sequence takes place. 8. System according to one of the preceding claims, characterized in that that the data blocks are consecutively numbered by the sending branch and from the receiving branch in the correct order and the correct time Distance by first entering one of the consecutive numbers of the Storage space of a memory arranged in the junction allocated to data blocks read in with random access on the input side (random access memory) and then read out serially from the memory at regular time intervals. 9. System according to claim 1 to 7, characterized in that in the Branch a memory is provided in which the messages to be sent first be saved and then in the form of compared to the running time of each Data blocks long data blocks are sent with a large time interval, whereby the respective data block spacing is greater than the maximum expected transit time fluctuations. 10. System according to one of the preceding claims, characterized in that that a toll office is connected to a ring, that facilities in each branch Provided are the ongoing charges for each, to the junction connected terminals count and save and that on a request from the toll office on the basis of a data block sent by the toll office with a toll office address the meter reading of the memory assigned to the respective terminal to the toll office is transmitted. 11. System according to claim 10, characterized in that the fee is proportional to the duration of the call and the ring address difference. 12. System according to claim 11, characterized in that the fee status continuously and without resetting in a memory protected against power failure is stored. 13. System according to claim 12, characterized in that the fee status is transmitted from the junction to the subscriber terminal and displayed there. 14. System according to claim 2, characterized in that in the node and branches for further processing of the data blocks after the photodiode and for processing the data blocks Samplin lines in front of the optical transmitter are connected. 15. System according to claim 1, characterized in that on individual Make complete loops of the network locally concentrated and from these are led from direct connection lines to a variety of terminals. 16. System according to claim 1, characterized in that in the node Runtime memory (S) are provided which have a delay equal to or greater than the maximum length of a data block and each between an incoming Transmission line and a logic circuit (V) are connected that the Inputs of the runtime memory each via a decision unit (E) with a Control (St) are connected, the decision units based on ring address difference calculations determine the most favorable direction for forwarding a data block and this report to the controller and that the controller is forwarding the data blocks controls the outgoing transmission lines by means of the logic circuit. 17. System according to claim 16, characterized in that the controller is set so that every incoming transmission line has priority on one its assigned outgoing transmission line is assigned. 18. System according to claim 1, characterized in that in the node every incoming transmission line can be interchanged with every outgoing transmission line is linked. 19. System according to claim 17, characterized in that the priority from the control as a function of the statistical distribution of optimal connections is controlled. 20. System according to claim 1, characterized in that between individual more distant nodes of the system for additional transmission lines both directions of transmission are provided. 21. System according to claim 1, characterized in that branches in Un certain terminal facilities are vorgeder see the data blocks / certain Send terminals with a higher number of deletions into the network. 22. System according to claim 1, characterized in that the barrier for the number of deletions in the nodes can be set to values> 0. 23. System according to claim 1, characterized in that during the Call process which is only ended when the opposite connection is established, in the data blocks instead of the information, the address of the calling terminal is transmitted. L e r s e i t e