DE1512954C3 - Arrangement for route search in coupling fields of telecommunications technology - Google Patents

Description

It is the object of the invention to reduce the effort which is necessary to carry out such a route search procedure. According to the invention this is achieved by once in the route network at the formed in a known manner Nodes a coincidence switching means is present, which via its first input of a input available for each exchange group, via its second input from the inputs of the test circuit is controllable and that the path search potential is always via the one input of the test circuit connected inputs of the coincidence switching means is present. In each case, the inputs of each other corresponding nodes associated coincidence switching means in multiple switched and with connected to an input of the test circuit. In order to evaluate the coincidence, i. Hi. the simultaneous occurrence of the test potential, only a single test device. This test gate can also have a storage property and therefore also when searching for a route in two steps can be used in the so-called flipped grouping. In addition, the arrangement according to the invention has the advantage that the connection of the connections of the test gate to the connecting inputs and outputs of the coupling arrangement due to the low switching frequency with relays or contacts can take place.

To explain the invention, reference is made to FIG. 2, which is composed of FIGS. 2a and 2b pointed out, in an arrangement for route search in the switching systems described above is shown with coupling arrangements.

FIG. 2 shows a switching arrangement which consists of several exchange groups, which, as in FIG. 1, are denoted by AG. As is well known, an office group is understood to be an arrangement consisting of several switching stages, each of which in turn contains several switching matrices. The example explained here is based on the assumption that each exchange group is designed in three stages, ie that the entire switching arrangement has six stages. The coupling arrangement shown in the figure is drawn as a so-called unfolded grouping. This means that the connections to be connected to one another are marked on the left and on the right side of the coupling arrangement via the two allocators, which are labeled ZO1 and ZO2. In the example on which FIG. 2 is based, there are 10 office groups, which are designated with ^ 4Gl to AGIO on the left and., 4Cl to AG'10 on the right. On the right-hand side there are also extracts from the intermediate line contacts 1 and the decoupling rectifiers G, which are part of the route search network. The wiring of the route search network can also be seen in this part. From the figures contained in the figure it can be seen that the last stage of an exchange group, which is designated with the C stage, contains 100 switching matrices each, each having 10 outputs. Finally, in the lower part of the figure there is a test circuit labeled PS, which essentially contains a selection arrangement and a test gate labeled PG, which acts as a coincidence gate. As is known for routing networks, the outputs of the individual switching matrices of the exchange groups are combined to form nodes. In the example, the nodes on the left-hand side of the switching arrangement are labeled KPl, KPl , etc. to KPlOO for each exchange group. According to the invention, a coincidence switching means is assigned once in the route network to the nodes of the route search network. For the nodes selected in the example, these are the AND gates GIl for the first office group,

G12 GIlOO. Accordingly, the for. the

last office group AGIO existing AND gate

ίο designated with GlOl, G102 ... GlOlOO. While one input of this AND gate is connected to a control input AEl ... AElO that is present per exchange group, the other is connected. The input of the AND gate is connected to the inputs Έ1, El ... £ 100 of the test circuit. According to the invention, the AND gates assigned to the inputs of the corresponding crosspoints are in each case switched in multiple and connected to an input of the test circuit. For the case assumed here, this means that the second input of the AND gates GIl ... GlOl, which are assigned to the nodes KPl of each first coupling multiple, are connected in multiples and connected to the input El of the test circuit. In the same

"5 example, are assigned to the second inputs of the second switching matrices AND gate G12 ... G102 to the input of the test circuit connected El. The second inputs of the AND gates assigned to the last switching matrix of all exchange groups (GIOO ... GIOOO) are connected to the last input £ 100 of the test circuit PS . Assuming that, according to the known proposal mentioned, a free path is found via the path search network in that there is a free path over the intermediate lines in question from both one and the other connection, the path search potential is always over according to the invention the inputs of the coincidence switching means connected to an input of the test circuit are successively fed to the nodes of the route search network.

It should now be assumed that, corresponding to a first number Nl via the allocator ZOl in the office group AGl, the connection 1, via the access

45. folder Z02 corresponding to a second number Nl in the office group AG'10 the connection η is marked. These two points are the connections to be connected to one another. A connection takes place via three levels A, B, C of the office groups AG1 and y4G'10. According to the known proposal, there is a free path when there is a path via the intermediate lines of the intermediate line network from both the one connection and the other connection. Since the structure of the route search network corresponds to the link network, this statement also applies to the route search network. For the arrangement according to the invention, as shown in Fig. 2, this means that the path search potential successively via the inputs El, El etc. to £ 100 of the test circuit at the second inputs of the coincidence switching means GIl ... GlOl, G12 .. G102 etc. GIlO ... GlOlOO is present. So one could say that the test potential, ie the path search potential, is applied internally in this case. If, as assumed in this example, the office groups AGl and AG'10 to be connected come into question, the control group corresponding to the office group ./1Gl is

input AEl energized. One via one of the inputs El, El .;. FlOO of the test circuit PS occurring path search potential will then propagate via the path search network via one of the AND gates GIl, G12 ... GIlOO when one of the intermediate lines in question is suitable for connecting through circuit, ie when one of the intermediate line contacts is closed. In order to evaluate the coincidence of a path search potential occurring, the test gate PG is available, which can be connected to the marked connections of the office control unit via network switching contacts, which are designated with ak. When the first coincidence occurs, a stop command is transmitted to the selection device winder test circuit, which means it is shut down. At the same time, * 5 is about the. Outputs Al .V. > 4100 the corresponding line can be determined:: ^ ^ \,,. :

The constructed according to the invention the circuit arrangement offers the advantage that, for evaluating the co-occurrence of Prüfpotentials ^zo Because of the temporal sequence of the individual test steps, only a single Prüfgatter needed. The AND gates required per coupling point are relatively simple and inexpensive components, i.e. they do not affect the economy of such an arrangement. The only relatively high quality switching element is the PG test gate. Another advantage of the arrangement is that the connection of the test gate PG to the connections of the office groups to be connected can take place via contacts, since only a low switching frequency has to be expected. This also has the advantage that only the test gate needs to be secured against interference pulses from the coupling network. The arrangement according to the invention is also used advantageously when, as in the example shown, a folded-over grouping is not selected, in which, as is known, the test gate must have a storing property. In this case, only a single switching element, namely the test gate labeled PG , needs to have a storing property.

For this purpose 3 sheets of drawings

Claims (6)

ίο patent claims: 1. Arrangement for the route search in coupling matrices of telecommunications technology, via which a unique route can be switched through between a certain input and a certain output and in which, in addition to a through-connection network, there is also a route search network containing intermediate line contacts and decoupling rectifiers, via which the free paths between the via labeled assignment switching means and are sequentially determined to be interconnected ports by detecting a free path to a desired input and a desired output by means of a test circuit, characterized in that in each case once a routing network to the formed in known manner intersections (KP) is a coincidence circuit means (Gil , G12 ... GlOlOO) is available, which can be controlled via its first input from an input (AEl ... AElO) available for each exchange group, and via its second input from the inputs (El ... £ 100) of the test circuit (PS) is and that there s Path search potential is always present via the inputs of the coincidence switching means connected to an input of the test circuit (PS). 2. Arrangement according to claim 1, characterized in that the inputs' of the corresponding nodes (KPl, KPI ... KlOO) associated coincidence switching means (GIl, G21 ... GlOl; G12, G22 ... G102, etc.) in Multiple switched and connected to an input ■ (El, El ... £ 100) of the test circuit (PS) . 3. Arrangement according to claim 1 and 2, characterized in that the test circuit (PS) has a selection arrangement (W) via which a test potential (search potential) successively reaches the inputs (£ 1 ... £ 100) of the test circuit (PS) and a coincidence switching means acting as a test gate, which can be connected to the inputs of the coupling arrangement marked as connections to be connected via the allocation switching means (ZOl, ZOl) , and that when a coincidence occurs, a pulse that stops the selection arrangement (W) and prevents the transmission of the path search potential comes to the selection arrangement ( W). 4. Arrangement according to claim 1 to 3, characterized in that the test gate (PG) when used has a saving property in a so-called flipped grouping. 5. Arrangement according to claim 1 to 4, characterized in that the test circuit (PS) has outputs (Al ... J4IOO) via which the intermediate line found is designated. 6. Arrangement according to claim 3, characterized in that the connection of the test gate ( PG) to the connections to be connected takes place via connection contacts (ak) controlled by the assignment switching means (ZOl, ZO2). The invention relates to an arrangement for WE ₁ looking in switching networks of telecommunications, ül between a particular input and a> particular output in each case a unique V, is switched through and in which in addition to a major switching network still a Zwischenleitungskonta and decoupling rectifier containing We is examined network exists, about the the free W; between the connections marked via assignment switching means and to be connected to one another: by determining a free path to a desired input and to a desired output one after the other by means of a test circuit. It is used for switching systems of the telecommunications operator nik, in which connections are established via coupling arrangements, known that the Wegesui serving route search network in its structure to design the switching network accordingly. A f ches route search network contains the route searchade in which the intermediate line contacts are located that are only open in the case of a busy line and then the spread of a search potential prevent over this line. For coupling arrangements in which more coupling stages are grouped together to form so-called office groups and a connection can be established via intermediate lines combined into interconnection bundles, groupings have become known, the main characteristic of which is that of each interconnection of an interconnection bundle between two specific headers both to each input and to jec. Exit of the coupling network is a clear path. For such arrangements, a route search has been proposed drive, which consists of all lines of a two for connection i circuiting suitable intermediate trunk group finding a free path to a gewünsch input in a first test step and fest development of a free path to a desired /. This means that use is made of the uniqueness of the Wt between the lines of an intermediate cable bundle and the inputs and outputs of the coupling connection. The basic structure of the path search network in which this method is used is shown in FIG. Switching arrangement via which a connection can be established: is built, contains the office groups AG there, in each of which three switching fields A, B and C are summarized. The connections to be connected have only switching means marked with ZOl and ZO2 corresponding to the connections to be connected with the numbers Nl and Nl mark The route search network is symbolized by the wiring running between the As groups, check points PSt that exist once per node in the route search network are here at the left S of the coupling arrangement provided. According to the known proposal, an F-circuit can be connected to these test centers. The invention described below also assumes that free V a free path to ei between connecting connections marked via allocation switching means desired input and a desired / gang can be determined by means of a test circuit