NO149755B - INTEGRATED SELECTOR AND TRANSMISSION NETWORK - Google Patents

Description

The invention relates to an integrated selector and transmission network (IST network) with a number of wire groups (LG1 to LGn), which with a blocking-free, digital selector with mutually identical selector modules (SMx/y with 1 < x <<>£ n and 1 y ^ n) , via assigned line modules (LM1 to LMn) are connected to each transmitter (Tl to Tn) and each receiver (RI to Rn) and are connected via assigned time multiplex connections (lal, Lbl to Lan, Lbn), of which each comprises a first time multiplex line (La) and at least one second time multiplex line (Lb), to transmit digital communication and control information in time multiplex form from the transmitter (T) to the selector and from the latter to the receiver (R), where the selector performs channel switching in time and space.

In a telecommunications network, mutually similar selector modules are used to provide selectors which are easy to handle and which make it possible to expand the capacity of the network during normal operation. The network can only be satisfactorily expanded with selector modules, if a module is designed from the outset so that its properties can remain unchanged, regardless of the network's capacity. Selector modules, which are included in frequency multiplex telecommunications systems,

and which only make through-connections in space, have been known for a long time. Such analog selector modules form stages which are connected to each other via intermediate wire groups, which for an extension of the network are modified by the addition of additional modules. But selector modules included in time-multiplex systems are more difficult to manufacture, because channel transitions normally occur both in space and time during information transmission between subscriber equipment, which is connected to the time-multiplex selector and transmission network. In principle, identical modules can only be provided, if a module performs implementations in both time and space.

It is known to use time multiplex selectors, whose through-switching principles are designated as "time-space-time" or "time-space-space-time" or "space-time-space", and where this designation represents in an illustrative way in which order information entering the voter system in time multiplex form is transferred between time steps for carrying out cross-connections in time, and between space-steps for carrying out cross-connections in space.

A known module selector for time-division multiplexed digital information, which is described in "Colloque International de Commutation

Electronique", Paris 1966, pages 513-520, comprises essentially identical modules, each connecting a number of time-division input lines and a number of time-division output lines. Here, time-division format-for-feed, i.e., the number of time slots per frame, different for different line types, and the through-connections in rooms within a module are achieved using an internal multiplex format that has at least as many time slots as there are information channels, which are received by the module. Time multiplex lines that are arranged between the modules have the same function as the aforementioned intermediate line groups, each of which is formed by a single time multiplex line whose time multiplex format ensures that connections can be established without blocking.

In German Offenlegungsschrift 25 46 205 a "time-time" reconnection principle is described, which is achieved by means of input modules, which are connected to output modules via a single, common time multiplex line. Thanks to this common time-division multiplex line, a room step can be omitted. Compared to the former, known modular switch, improved handling options have thus been achieved. When a module fault occurs, the fault-loaded module is replaced by a fault-free one, without this affecting the other modules' pass-through capacity. In the event of an expansion of the network, additional input and output modules are connected with the aforementioned common time multiplex line, and this can also happen during operation if necessary.

Besides the above-mentioned points of view, which concern the division of the selector into modules, the way in which the through links are created through the selector, i.e. the selector's management, will play a major role in the reliability and capacity of the telecommunications network. known from the above publications to control a digital time multiplex selector by means of a central computer, which receives signals giving orders for the establishment of a connection from subscriber equipment or from a remote concentrator. On the basis of the aforementioned control signals, the computer finds the addresses, index, time slots, time multiplex line numbers, etc., which, depending on the chosen selector principle, must be sent to the selector's time and space steps and modules, in order for the ordered connection to be established. With the oldest time multiplex systems, for connecting computer machines

nen arranged a separate control signal transmission network. In modern and improved time multiplex systems, e.g. the digital

le "time-space-time" system which is described in DE-PS 23 06 301, a relief of the computer is sought, while at the same time the mentioned control signal transmission network is included to the greatest extent possible in the suitable time multiplex information transmission system.

The purpose of the present invention is to provide an easy-to-handle and easily expandable IST network (Integrated Switching and Transmission), whose blocking-free "space-time" selector includes mutually identically executed selector modules,

which is controlled in a decentralized manner without a special control-information transmission system and completely without a centrally arranged control unit or computer. The proposed integrated selector and transmission network (IST network) has been created using the features stated in claim 1. An advantageous continuation of the invention appears in claim 2.

The provided IST network shall be explained with the help of design examples shown in the drawings.

Fig. 1 shows the principle diagram of the IST network.

Fig. 2 shows a synchronization clock.

As parts of a selector module, fig. 3 a time step, fig. 4 three signal receiving units and fig. 5 and fig. 6 each with its own signal

conversion unit.

Fig. 1 shows n line groups LGl-LGn, between which telecommunication connections are provided by means of n link modules LMl-LMn and a digital selector comprising at least n<2->n selector modules SM. Each line group, for example LG1, is assigned to a link module LM1, which comprises a transmitter Tl and a receiver Ri respectively, which are connected via a time multiplex link Lal and Lbl respectively in fig. 1 selector modules SMI/1 - SMl/n respectively shown column wise selector modules SMI/1 - SMn/1. Said time multiplex link transmits in time multiplex form digital communication and signal information from the link modules to the selector and vice versa.

That in fig. 1 shown IST network is intentionally simplified to the extent that only such network parts are symbolized as are needed to simplify the present invention. For example, the IST network's time multiplex synchronization is indicated by means of a single clock CL, which is connected to all selector modules, so that said receiver Rl-Rn receives the information coming from the selector during synchronous repetition frames. Within each joint module, a frame synchronization is performed so that the information transmitted from said transmitter Tl-Tn to the selector is also synchronous. In practice, the synchronization conditions are not so ideal, as phase shifts and so-called plesiochronous information transfers to the selector occur, which is why in larger grid link modules each clock is assigned. It is, however, a known technique to synchronize the information received by the voter, for example by means of the fastest clock for the occasion, and to arrange phase equalization circuits and so-called "pulse stuffing" devices in the joint modules to avoid information loss. Furthermore, it can therefore be assumed that said joint modules, joint connections and selector modules form an ideal synchronized system.

As is known, a time multiplex format is defined mainly by its frame frequency, for example 8 kHz, and by the number of time slots per frame period, for example m 32 time slot groups. Within each time slot, an information unit is transmitted, which in a digital system consists of a digital word consisting of a number of bits, for example eight. Most time slots within a frame period are allocated to the actual communication information, but a small number of time slots, for example two of a 32 time slot group, are reserved for synchronization and signaling purposes. In the proposed IST network, it is assumed that the synchronization does not require a time slot in each frame period , but that so-called idle signals, which indicate that there is no need for signaling for the respective time slot group, are also used as synchronization signals, so that the said few time slots can practically be used for digital signals and signal messages, which will be described in more detail and which concern respective 32 time slot group communication channels, which must be intended partly for pulse code modulated voice transmissions and partly for data communication.

It is known within an IST network to use both parallel and serial information transmission and vary between time multiplex format with different multiples of thirty-two time slots. For that in fig. 1 shows, it is assumed that the same format and transmission principle is used for the aforementioned paragraphs La, Lb. Any necessary known "parallel-series" or "series-parallel" converters are included in the network's link and selector modules and are not shown in fig. 1. Similarly, necessary analog/digital and digital/analog converters, which can be arranged either in the subscriber equipment or in the joint modules, are omitted, because they do not affect the invention. Nor are any otherwise known concentrators included in the link modules, which are necessary if a line group includes a larger number of subscriber equipment than there are time slots in the time multiplex format chosen for the link connections, not shown.

In contrast, fig. 1 that each joint module comprises at least one control unit CU, which is assigned to a wiring subgroup. Each control unit controls the allocation of a number of time slots on respective link pairs Lax/Lbx, for example one of the aforementioned m 32 time slot groups, in order to transmit the subgroup's communication information and thus coherent signal information to and from the selector. In fig. 1 shows a system developed so far that a single control unit is arranged at each link module except for the link module LM2, which includes m control units CU2,1 - CU2,m and that the line group LG2 consequently includes m subgroups LSG2,1 - LSG2,m. Mentioned

m control units each have their own 32 time slots

group, i.e. together over all the time slots of the joint pair La2/Lb2. The joint module LM2 comprises a in fig. 1 concentrator not shown if one of the said cable subgroups includes >30 subscriber equipment, because with the help of the assigned control unit, a maximum of 30 equipment can be connected simultaneously in time multiplex form, e.g. to joint connection La2.

One in one joint module including control unit is designed so that it controls connection connections within its own wiring subgroup. If it is assumed that the joint module only comprises a single control unit, the selector does not in itself need to include a selector module, which mediates between the time slots of the pair of joints connected to this joint module, but the joint module can in this case itself contain an internal selector to provide subgroup internal connections . If it is further assumed that this sub-group's subscriber equipment each has its own separate connection to the joint module, said internal selector is made up of a room stage. The advantage of the internal selector consists in the fact that the communication connections within the sub-group burden the respective pairs of links neither the time slots calculated for communication nor the time slots calculated for signal information. You thus get an increased mediating capacity. Since, on the other hand, the subgroup's communication information is in all cases transformed into time-multiplexed digital information, which is conveyed via the selector to other link modules, and since the internal selector required in the link module in most cases cannot be constructed simpler than a selector module, the greatest possible uniformity is achieved in The IST network if the selector includes n 2 identical selector modules. Selector modules, for example SM2/2, which are connected via each joint pair La2/Lb2 to each joint module LM2, must however always be arranged, if the joint modules include > 1 control units, for connections between subgroups belonging to the same wiring group, e.g. between LSG2,1 and LSG2,m, can only be connected via the selector. With the one in fig. 1 shown selector omits the modules SMI/1, SMn-l/n-1 and SMn/n, and it is assumed that the joint modules LM1, LMn-1 and LMn contain internal selectors not shown.

A control unit included in a link module is further designed so that it, together with other control subgroups' control units, controls the selector by connecting external connections between its own subgroup and said other subgroups, the previously mentioned time slots calculated for signal information being used. In other words, this means that the entire IST network's control intelligence is distributed among the decentralized control units. Each of the selector's modules comprises a time step TS and a signaling logic SL, which are completely passive and without their own intelligence. In addition to said clock CL to provide synchronism, each module is connected on the input side exclusively to one of said transmitters Tl-Tn and on the output side to one of said receivers RI-Rn. The voter is therefore not provided with any intelligent central control unit. Ledd modules' decentralized control units get their intelligence, for example, using programs stored in memories. The program memory controlled control units do not need to be described in detail in connection with the present invention. When connecting the aforementioned external connections, the proposed IST network's control units have the following most important functions, which are carried out with the help of computers programmed in a similar way, known per se, for example Motorola's microcomputer M6800, and which functions relate to signaling either between two control units or between a control unit and the selector.

The signaling between two control units is intended to exchange messages, which are coded for example according to a signaling system with the CCITT designation X-25. The structure of the signal system does not need to be described in detail for the understanding of the present invention, as it is sufficient to mention that each message unit is coded so that the receiving control unit knows when the entire message unit, which consists of an individual number of digital words, has been received. The structure of the signaling system is further such that a replacement of message units in both traffic directions leads to both control units knowing that a communication connection should not be connected via the selector or connected or disconnected using addresses and time slots, which have been achieved due to a completed signaling between two control units. In the proposed IST network, the signaling system's messages are transmitted

during one of the aforementioned time slots calculated for signal information,

hereafter called time slot 16. To transfer a message unit, for example, from control unit CU2,m to control unit CU1

the selector module SM2/1 must perform a change in time from time slot 16 within the 32-time slot group assigned by control unit CU2,m to time slot 16 within the 32-time slot group assigned by control unit CU1, a so-called 16-16 changeover. The selector module's working method will be explained later. Before control unit CU2,m starts sending said message unit, it must know that neither the selector module SM2/1 on orders from, for example, control unit CU2,1 nor one of the selector modules SM > 2/1 on orders from one of control units CU > 2 performs any 16- 16 time switch to transmit another message to the control unit CU1.

In order to achieve reliable message communication, control unit CU2,m first sends a call signal addressed to control unit CU1 during the second of its time slots calculated for signal information, hereafter called time slot 0. The address of control unit CU1 also defines the only selector module SM2/1, via which the call signal must be transmitted. A control unit sends the call signals one at a time, which means that the transmission of the calculated message unit must be completed before this control unit sends a new call signal.

On the basis of call signals, which a control unit has received during its allocated time slot 0, this control unit sends response signals during its time slot 0 one at a time, which again means that the transmission of the message unit calculated using the respective call signal must be completed before this control unit sends a new answer signal regarding another call signal. In the assumed signaling example, according to the aforementioned "one at a time" rule, control unit CU1 sends a response signal addressed to control unit CU2,m. The address of control unit CU2,m also defines the only selector module SMI/2, via which the response signal must be transmitted.

The "one at a time" rule mentioned for calls and responses enables the following acknowledgment operations: A call signal is repeated continuously until the corresponding response signal has been received. When the received call signal ceases, the called control unit knows that its response signal has reached the calling control unit. Likewise, a response signal is repeated until at least the first word of the message unit has been received. When the response signal ceases, the calling control unit knows that said 16-16 connection is working reliably. However, maximum times are introduced for how long the call and answer signals are sent. If after the respective maximum time no response signal or no message word has been received, the waiting control unit generates an alarm signal.

When the called control unit, according to the example control unit CU1, has received the entire message unit during its time slot 16, it sends to the calling control unit, according to the example control unit CU2,m, during its time slot 0 a signal, the content of which expresses that the message unit is either correct received or must be forwarded. Said "correctly received" and "retransmit" signals are modified response signals, which have the common property that they do not need to contain the address of the called control unit, because due to the "one at a time" rule, the calling control unit knows that such response signals must come from the called control unit. Said acknowledgment principle is also used to reliably terminate the message unit's transmission. The called control unit continuously repeats said "correct received signal. The calling control unit responds by itself continuously sending a "correct received signal to the called control unit. When the called control unit receives the "correctly received" signal, it terminates its "correctly received" transmission. When the calling control unit no longer receives "correctly received" signals, it also terminates its transmission.

Said signaling sequence results in a single message unit being transmitted reliably in one traffic direction. In order to provide a message exchange, a similar process is repeated for the other traffic direction, whereby the two control units switch roles.

In addition to the aforementioned "one at a time" rule, a first priority rule applies according to which a control unit must answer received call signals before the calling control unit initiates, or continues, a message exchange. Said first priority rule prevents an excessive accumulation of unanswered call signals. The maximum time mentioned for call signals is determined with regard to the fact that a control unit can be called by all of the IST network's other control units in the same frame period. You get queuing problems not only with the called control unit itself but also with the affected selector modules and the affected joint connection to transmit the call signals from the selector to the called control unit. In the queuing of signals addressed to a control unit, the aforementioned response signal types also participate, but due to the "one at a time" rule, at most one signal of the response type occurs together with several call signals. The solution to the aforementioned queuing problem will be described in what follows.

In frame periods, which are neither taken up to transmit the previously explained call and response type signals nor in connection with this explained uplink and downlink signals, time slots 0 are used on the IST network's link connections to transmit the previously mentioned idle signals.

in

The signaling between the control units and the selector has a purpose

to connect and disconnect partly the mentioned 16-16 connections between the control units and partly ml, tl-m2, t2 connections, which are included in communication connections between the subscriber equipment. This means that the selector makes changes in time partly from the time slot 16, which is assigned to a transmitting control unit, to the time slot 16, which is assigned to a receiving control unit, and partly from the time slot ten which belongs to a relevant 32-time slot group ml, during which time slot ti relevant communication information is received by the selector, to the time slot t2 belonging to a relevant 32-time slot group m2, during which time slot t2 the selector transmits said communication information.

As will be apparent from the explanation of the selector's passive functions, the aforementioned call signals are used to connect the aforementioned 16-16 connections. To connect an ml, tl-m2, t2 connection, a control unit sends, e.g. CU2,1, whose nl number is 2, a connection signal during its assigned time slot 0, which at the same time defines the control unit's 32 time slot group ml=1. The connection signal contains partly a connection code and partly an n2 number.

for example n2=2, to address a single incoming selector module, according to the example selector module SM2/2, partly said time slots ti and t2 and partly an m2 number, for example m2=2, to indicate the receiving subscriber equipment subgroup and its 32 time slot group which includes said time slot t2. According to the example, the connection signal relates to a unidirectional communication connection from a subscriber equipment of the subgroup LGS2,1 (nl=2, ml=1) to a subscriber equipment of the subgroup LGS2,2 (n2=2, m2=2). The signaling logic of the receiving selector module SM2/2 transforms the connection signal into maneuver signals, with the help of which the time step of this selector module connects the calculated connection. Due to its n2 number, the connection signal does not affect any other time step of another selector module. In this elegant way, the selector's changes in space are provided without conventional space steps and without special space change signals.

To disconnect an ml, tl-m2, t2 connection, a control unit sends during its assigned time slot 0 a disconnection signal defined by means of a disconnection code, which differs from a connection signal only in that a tl time slot information is redundant. The downlinking of a 16-16 connection is signaled to the selector either by means of the aforementioned "correct receivef acknowledgment signal" or by means of a downlink signal containing t2=16.

Said signals generated by the control units, like the signal system's message units, each comprise their own code and relevant variables such as the aforementioned ni, n2 and ml, m2 numerical addresses and ti, t2 time slots. In the case of a larger system with, for example, 8 link modules, each of which includes 32 control units, in order to transmit blocking-free between approx. 8,000 subscriber equipment, the signals cannot be defined using a single digital word comprising 8 bits. In the IST time multiplex system, so-called multiframes are introduced to transmit signals comprising such several words, as multiframes with a constant or varying number of frame periods occur. In connection with the description of the voter's working method, the aforementioned known multi-frame technique will be touched upon to the extent necessary.

In what follows, principles that apply to the passive working method of a signaling logic in one of the proposed IST network's selector modules are described. The signaling logic includes reception units, which only respond to the own n2 number address and respective signal code, as well as conversion units, which convert incoming signals to the selector module into said maneuver signals and into outgoing signals from the selector module. The conversion units for processing call signals determine, according to a simple second priority rule, which of the call signals received at the same time and addressed to the same receiving control unit is to be converted into a maneuver signal for connecting the respective 16-16 connection to this control unit, as well as converted into a call signal outgoing to this control unit . The conversion units for processing signals of the aforementioned response types have a simpler design than the call conversion units. Due to the above-mentioned "one at a time" rule, it is sufficient if the receiving control unit receives the answer code itself, while a reformed call signal must notify from which control unit at which joint module the call comes. The processing of the response signals does not require a priority rule.

It is achieved that a receiving control unit, for example CU2,2, which receives signals from in fig. 1 column-wise displayed selector modules SMl/2 - SMn/2, at the same time can be called via all selector modules of the respective column (n2=2) and receive a response via one of the column's selector modules. If the receiving control unit is connected to said column of selector modules by means of a common time multiplex link, according to the example and fig. 1 subsection Lb, 2, a multi-frame must be established regarding the receiving control unit's time slot 0.. Within this multi-frame, for example, the column's selector modules and thus the calling link modules are each assigned an nl frame period to transmit call signals as well as a common frame period for all selector modules in the column to transmit response-type signals. Said common frame period is not needed if said call and response conversion units are modified so that an answer signal inhibits a call signal. Each selector module then sends during a time slot 0 only one signal, either an answer type signal or a call signal. If, for the selector modules, a separate time multiplex link is also arranged for information transmission to the respective link module, the aforementioned multi-frame formation for signals originating from the selector is completely avoided. In an IST network modified by means of said separate links, which will be explained in connection with fig. 6, a faster signaling sequence is achieved with shorter maximum times than with that in fig.

1 showed a system with said common link Lb.

Fig. 2 shows the selector's common initially mentioned clock CL to produce a time multiplex format comprising 32 time slot groups with 32 time slots each. A frame period with f = 125 us comprises 32 x 32 time slots of p<*122ns. The time slots are denoted using two numbers 0 ^ ra t 31 - 0 — t — 31. The time slot 0-0 begins a frame period, precedes the time slot 0 - 1 and joins the previous frame's last time slot 31 - 31. The clock defines the time slots by using in fig. 2 showed

pulse series, which are produced in a known manner, for example by means of a shift register. The IST network is assumed to use the parallel transmission principle, therefore no bit division occurs within the time slots. In contrast, the clock is provided with an output 0, which according to fig. 2 sends a pulse series which within each time slot includes a pulse and a pause. The Ø pulses are needed to avoid coincidence in the known manner in the below explained write and read operations in connection with the time changes. The clock is driven by an oscillator OS, whose fundamental frequency is 2^<+5+5+1>kHz «16 MHz.

Fig. 3 shows an in and of itself known time step for carrying out changes in time within said 32 x 32 time multiplex format. The time step mostly comprises an information memory IM and an address memory AM. The information memory's write inputs are via an AND gate Gl and via 32 x 31 AND gates G2 connected to link La, ni for incoming information. During a frame's Ø pulses, communication and message information that arrives during the time slots m-l to m-31 is written in each memory location of the information memory, while during the time slots m-0 incoming signals are not registered in the information memory. It is achieved that the communication and message information transmitted on link La, nine is registered in all the selector modules connected to the link, as in fig. 1 forms a series. The address memory

AM has its read outputs via 32 x 31 AND-gates G3 connected to a time switching decoder TDEC, which during the Ø pauses addresses the information memory for reading to the output from the selector module' link Lb,nl/n2. The ni and n2 designations define, according to fig. 1 the transmitter Tnl and receiver Rn2 connected to the time step.

In fig. 3, it is assumed that the time switching decoder receives the addresses 31-1 and 0-16 respectively during the time slots 0-31 and 31-16 respectively, while during the other time slots addresses m-0 are transmitted, which addresses do not occur in the information memory. It is achieved that the communication information ki registered during time slot 31-1 in the information memory is transferred during time slot 0-31 to link Lb,nl/n2, and that the message information mi registered during time slot 0-16 is conveyed to time slot 31-16, but the rest in information registered in the information memory is not transferred to the outgoing link. The address memory AM has its write inputs via a maneuver decoder ODEC and via AND gates G4 activated during the Ø pulses connected to the time step's maneuver inputs 01 and 02.

Fig. 4 shows signal reception units SRU-C, SRU-A and SRU-E,

which is included in the signaling logic of a selector module SMnl/n2 and which receives call, answer and connection signals which are registered with a signal register SREG. For the above-mentioned downlink signals and response-type signals, the signaling logic comprises additional receiving units, which correspond to the n<y>th receiving units SRU-E and SRU-A and are therefore not shown in fig. 4.

Said signal register SREG registers by means of an OR

port G5 and an AND port G6 during the time slots m-0 from section La,ni incoming idle, call, answer and up- and respectively downlink signals. Each call or answer signal consists of two digital words, the first of which contains, in addition to the respective code C or A, an n2 number to address the selector module SMnl/n2, of which the second word contains an m2 number to address one of the receiving control units connected to this selector module.

A connection signal consists of four digital words, of which the first contains, in addition to the connection code E, an n2 number to address the selector module SMnl/n2, and of which words the second, third and fourth respectively contain the previously explained m2-, t2-res-spective tl - connection information.

The signal reception units each comprise their own code registers CREG, AREG and EREG respectively to constantly store said C-n2, A-n2 and E-n2 information respectively. The signal receiving units further each comprise a comparator CC, AC and EC respectively, one input of which is connected to said code register CREG, AREG and EREG respectively and whose other input is connected to said signal register SREG. Said comparators have their outputs connected to each of 32 AND gates Gl, which are activated during each test pulse, according to fig. 4 time slots 0-20, 1-20 ... 31-20, and whose outputs are each connected to the first shift step of the shift register SH which is step-shifted using clock pulses 0-0, 1-0...31- 0. In accordance with the word count of the signals, said shift register comprises two and four shift stages respectively. One achieves that, for example, the other shift steps are activated between the second and third 0-pulse after the test pulse during which the connected port G7

is activated. The second, third and fourth shift stages of said shift register SH are each connected to the first input of an AND gate G8, whose second input is connected to the signal register SREG and whose third input is activated coincident with the gate G7, which is connected to respective shift register. The outputs of said ports G8 constitute the outputs of the signal receiving units CM2, AM2,

EM2, ET2 and ETI, from which the aforementioned m2, t2 and ten numbers of the signals depart. The receiving unit SRU-A for answer signals is provided with a common output AM2, while the receiving units SRU-C and SRU-E for call and connection signals are provided with separate outputs CM2 and EM2, ET2, ETI, which are each assigned using a ml - number defined sending control unit. The receiving unit SRU-E for connection signals is also provided with outputs M, which are activated by AND gates G9 during a first maneuver pulse, which occurs after the respective test pulse and which, according to fig. 4 is made up of the m-30 pulse, which coincides with the activation of the fourth shift stage of the respective shift register.

Fig. 5 shows a conversion unit for connection signals, which comprises first maneuver register 0REG1 and AND gates G10. Said first maneuver register is connected to said outputs EM2, ET2 and

ETI at the receiving unit SRU-E, but also includes register parts to constantly store the respective sending control unit's ml number. Said respective ml numbers belonging to gates G10 have their inputs connected to said output M of the receiving unit SRU-E and to said first maneuver register 0REG1 and have their outputs connected to said maneuver inputs 01 and 02 of the time step in such a way that the ml-tl maneuver information is written under the Ø pulse of said first maneuver pulse in memory locations of the time step's address memory AM, whose addresses are defined using the m2-t2 maneuver information.

Fig. 6 shows a combined conversion unit for call and answer signals. The m2 numbers received from the reception unit SRU-A for response signals via said output AM2 are decoded by means of a response decoder ADEC and "l" set bistable flip-flops FF. An "l" set flip-flop indicates that the associated m2 control unit should receive a response signal and activates the first input of a same m2 number associated AND gate Gil, if the second input is activated during the same m2 number's time slot 0, and if the third input is connected to a response register REG-A which constantly stores a response code A. The "0" setting of the flip-flops is provided by means of respective m2-number associated reset pulses, according to fig. 6, 10 pulses. The outputs of said ports Gil are connected to that from the selector module outgoing link Lb,ni/n2.

The m2 numbers received from the reception unit SRU-C for call signals via said outputs CM2 are decoded by means of call decoders CDEC, which are assigned separate ml numbers for transmitting control units. Said call decoders have their outputs connected to prioritization devices PD-0 to PD-31, which are each assigned a separate m2 number for receiving control units. According to the aforementioned second priority rule, each prioritization device selects one of the control units which, during a repetition frame, calls the assigned receiving control unit. Each prioritization device is provided with outputs CMI, which are assigned to each ml number and which consequently at most one is activated between two successive priority pulses, which occur after the test pulse at time slot group m=31 and which, according to fig. 6 consists of 31-30 pulses. Said outputs CMI are connected to each AND port G12 and each AND port G13. Said ports G12 transmit outgoing call signals in the activated state via AND ports G14 to the link Lb,nl/n2 originating from the selector module SMnl/n2. Said outgoing call signals, which in addition to a call code C contain the calling control unit's ML number, are constantly stored in call register REG-C. Said gates G13 transmit, in the activated state, ml-16 maneuver information via AND gates G15 to the time step's maneuver input 01. Each m2 assigned priority device PD also has all its outputs connected to an OR gate G16, whose output is connected to the first input of an AND gate G17, which in the activated state transfers m2-16 maneuver information to the time step's maneuver input 02. Said maneuver information ml-16 and m2-16, which is constantly stored in the second maneuver register 0REG2, is used for connection of the 16-16 message -ses connections. Both inputs at a port G12 or at a port G13 are assigned the same m-number. Furthermore, said ports G17 each have a second input connected to that of said second maneuver register 0REG2, which stores an m-number corresponding to the m-number of the respective prioritization device.

Said ports G14 are opened during the respective receiving control unit's time slot 0 on the condition that a call but no response is to be transmitted to the receiving control unit. If an outgoing call signal is transmitted to the receiving control unit, the respective m2 number assigned gates G15 and G17 are opened during a respective time slot group belonging to the second maneuver pulse, according to fig.

6 m2-5 pulse.

Said ports Gil and G14 are controlled without the aforementioned multi-frame formation, as it is assumed that said link Lb,nl/n2 separately connects the selector module SMnl/n2 to the link module defined by means of the n2 number. Because of the separate link Lb,nl/n2, the outgoing call signals do not need to contain the nl number assigned to the sending link module.

Claims (2)

1. Integrated selector and transmission network (IST network) with a number of wire groups (LG1 to LGn), which with a blocking-free, digital selector with mutually identical selector modules (SMx/y with K. x < n and 1 <y < n) , via assigned line modules (LMl to LMn) are connected to each transmitter (Tl to Tn) and each receiver (RI to Rn) and are connected via assigned time multiplex connections (Lal, Lbl to Lan, Lbn), each of which comprises a first time multiplex line (La) and at least one second time multiplex line (Lb) to transmit digital communication and control information in time multiplex form from the transmitter (T) to the selector and from the latter to the receiver (R), where the selector performs channel switching in space and time, characterized by that each in a first group of selector modules (SMx/y with x ^ y) is assigned to a pair of line modules, where its input via the mentioned time multiplex connections is connected to the transmitter (Tx) in one (Lx) and its output is connected to the receiver (R y) in the second (ly) of the pair of line modules, that each selector module (SMx/y with x ^ y) for information transfer from the transmitter (Tx) to the receiver (Ry) includes a time step (TS) known per se , that each selector module' (SMx/y with x ^ y) comprises a logic circuit (SL), which transforms control signals coming from the transmitter (Tx) into maneuver signals for controlling the associated time step (TS) and into control signals for the receiver (Ry), that no connections are arranged between the output of one and the input of the other selector module (SMx/y), and that each wiring module (LMl to LMn) comprises a control unit (CU1 to CUn) for establishing communication connections within assigned wiring group (Lg 1 to LGn) and, in connection with the control unit for another wiring group, to control the selector when establishing a communication link between the own and the other wiring group. 2. Integrated selector and transmission network as stated in claim 1, characterized in that each of a second group of selector modules (SM 2/2) is assigned to a line module (LM2), its input is connected to the transmitter (T2) and its output to the receiver (R2) via the time multiplex connection (La2, Lb2), and that the wiring group (LG2), which is connected to this wiring module (LM2), comprises at least one wiring subgroup (LSG2,1 to LSG2,m), which is connected to a control unit (CU2 ,1 to CU2,m) included in this wiring module (LM2) for establishing communication connections within the assigned wiring subgroup (LSG2,1 to LSG2,m) and, in cooperation with the control unit for another wiring subgroup, for controlling the selector when creating a communication connection between the own and the other wiring subgroup.