NO124698B - - Google Patents

Description

Automatic telephone exchange.

The present invention relates to an automatic telephone exchange where a number of subscriber lines are served by time division multiplex equipment, where a connection between the calling subscriber line and a desired subscriber line is established over two time division multiplex channels and a storage device, the calling subscriber line being repeatedly connected to the storage device at that time in the multiplex period that forms one of the two time division channels and the desired subscriber line is repeatedly connected to the storage device in the time position in the multiplex period that forms the other of the two time division channels and where the storage device is arranged to receive a modulated pulse from one of the lines at one of the two time positions, to store the modulated pulse in the time interval before the second of the two time positions occurs and to emit the pulse to the other of the lines at the second time position.

The peculiarity of the invention is that each subscriber line is equipped with a capacitor which can be connected to a common channel over a normally closed gate circuit, that when a subscriber line participates in a connection its capacitor will be charged by the signal sent while the gate circuit between it and the common channel is closed, that the storage device that participates in the aforementioned connection is a capacitor which is connected via another normally closed gate circuit to the common channel, that an inductive impedance is arranged between the subscriber line's gate circuit and the other gate circuit, that both the gate circuit for one of the lines and the other gate circuit are opened at the time position that forms one of the time-sharing channels over which a connection is established, that the size of the capacitors and the inductive impedance and the time period in which the gate circuits are open are chosen in such a way that the line capacitor is discharged practically completely to the capacitor which constitutes the storage device, so that a practically lossless energy storage conduction is provided from the capacitor of the line to the capacitor of the storage device, that both the gate circuit for the capacitor that constitutes the storage device and the gate circuit for the other of the lines are opened at the time position that forms the second of the time division channels over which a connection is established, so that a similar practically lossless energy transfer is recovered from the capacitor which forms the storage device of the second line capacitor, that the equipment is symmetrical so that modulated pulses can be sent over the storage device from the calling line to the desired line, as well as from the desired line to the calling line, and that each subscriber line is equipped with devices for providing a signal from the charges which are successively received by their capacitors.

The invention will be described in detail with reference to the accompanying drawings, where: Fig. 1 shows a connection circuit according to

to the invention.

Fig. 2 shows the connection circuit in fig. 1 more

detailed.

Fig. 3 shows in simplified form how the present invention can be used in an automatic communication center similar to that described in Belgian patent no. 515,605. Fig. 4 shows in more detail the parts used to set up a connection between two subscriber lines in a switchboard of the type shown in fig. 3. Fig. 5 shows an alternative form of the circuit in fig. 1. Fig. 6 is a simplified diagram showing a further alternative embodiment of the invention. Fig. 7 shows a modification of the circuit shown in fig. 6.

Introduction.

In time-division multiplex systems it is sometimes necessary to connect two circuits, e.g. a calling subscriber's line, and a called subscriber's line over two different time-sharing channels.

In known embodiments, such a connection has necessitated the provision of devices which demodulate the information received on one time division channel, and re-modulate the information on the other time division channel. Such demodulation and modulation devices considerably increase the scope and costs of a system where the connection must be set up over time division multiplex channels "in series".

The present invention performs the transfer from a modulated pulse in one time division channel to another using a storage device which is supplied to a modulated pulse train or a modulated pulse train which transmits the necessary voltages. Each pulse is stored in the storage device until the occurrence of the time position in which it is to be transferred and is then transferred to the storage device. It is pointed out that the storage device is capable of storing modulated pulses in an arbitrary time interval, at least equal to a multiplex period, with insignificant losses. That is the time the pulses are stored in the storage device is exclusively determined by the time the pulses are supplied, and by the time they are sent from there. It should further be noted that such a storage device can be used to connect two time division channels in multiplex systems with different frequency and/or number of channels.

In one embodiment of the invention, the storage device consists of a capacitor, and in another embodiment it consists of a ferrite core. According to a further embodiment of the invention, delay devices are used.

First embodiment.

(Fig. 1 and 2).

In this arrangement, a speech channel is received over line A, and therefore the instantaneous charge on capacitor CA, which terminates line A, represents the amplitude of the signal. Line A is connected to a common channel MH over a gate GA, and this gate is opened in a first time position in the multiplex period. When this happens, an amplitude-modulated pulse train where each pulse occurs at the time GH opens passes from line A to the common channel. This pulse train is applied over a common point shown in fig. 1 to the common channel MH, and is transferred from there via the self-inductances LI and L2 in series to a further port GS. The opening of this gate is repeated in the same timing as the gate GA, so that at each occurrence of the timing used to pass information from line A, the charge on capacitor CA is transferred across GA, LI and L2, and GS to a capacitor CS, which forms a storage device. The parameters of the circuit are such that the capacitor CA is fully discharged to CS while the gates are open. To achieve this, the resonance frequency of the circuit CA-L1-L2-CS must be such that the time the gates are open is equal to half a period of the alternating current at this resonance frequency.

The amplitude-modulated pulse that occurs in the time position used to transmit information from line A is thus stored in the storage device which is made up of the capacitor CS.

The common channel MH is connected via a port GB with a line B, in a similar way to line A. At the time when information is to be sent to line B, the ports GS and GB are opened simultaneously. Consequently, when this timing occurs, the storage circuit formed by capacitor CS is connected to line B across gate GS, self-inductances L2 and LI and gate GB. The charge on capacitor CS is therefore transferred with insignificant loss to a capacitor CB, which, in a similar way to CA, terminates its line. From the series of pulses supplied to capacitor CB, the information originally received over line A is recreated by the low-pass filter which includes CB so that the information has been transferred to line B from line A.

The component values are chosen so that the circuits consisting of capacitor CA, gate GA, self-inductors LI and L2, gate GS and capacitor CS are symmetrical. Similarly, the circuit consisting of capacitor CS, gate GS, self-inductances L2 and LI, gate GB and capacitor CB is also symmetrical. This embodiment therefore allows signaling in both directions, and thus a two-way connection can be established between line A and line B.

In the circuit shown in fig. 1, the common symbols indicate that more than two lines are connected, each through individual ports such as GA or GB, with a common channel. It is therefore obvious that there are several possible connections that can be set up. To allow more than one connection to be set up at a time, additional storage devices must be provided, each with its own ports. Such an additional gate with capacitor GS, — CS', is shown by dashed lines. As many units as are assumed to be necessary to transmit the expected traffic must be provided. When a connection is set up, it is therefore necessary to select a free storage device, and this can be done by one of several well-known methods. The arrangement of selecting a free storage device is of course such that only one at a time can connect to the same free storage device.

It appears from the more detailed drawing in fig. 2, that the gates GA, GB, GS, GS' are transistor gates with symmetrical layer transistors. The controlled circuit in such a gate is the emitter-collector circuit, and because the transistors are symmetrical, it is a two-way circuit. That is, the functions of emitter and collector can be switched. The set of gates GA, GB.... are all controlled by a control circuit CCA, which includes a storage device per time slot in the multiplex period. When a line is to be connected to the main road at a given time, the identity of this line is registered in the storage device at this time. In the event of a loaded time position, the gate corresponding to a line whose identity is registered in the time position for this warehouse will therefore be opened.

Answering the call state on a line, seizing a free time-sharing channel for this, receiving the called number and seizing a free slot for a desired line can be carried out in a known manner, and is therefore not described.

The transistor gates are normally held closed by the potential applied to their base electrodes from a known bias source, shown for simplicity as a battery B1. When a gate is to be opened, a potential is supplied to the base circuit and this counteracts the bias sufficiently to open the gate. One of the advantages of such transistor gates is that a relatively small effect on the base electrode of the transistor can control a relatively large effect in the emitter-collector circuit.

The gates GS, GS' associated with the storage capacitors CS, CS', respectively, are controlled in a linking manner as the gates GA, GB,..., and similarly share a common bias source B2. A free storage device is selected either at the same time as the calling line's time division channel is occupied, or at the same time as the desired line's time division channel is occupied. The control circuit CCB is generally of a similar type to the circuit CCA. The most significant difference is that when the storage device and port are in use, the identity of this port will be recorded in the storage device for two of the time positions in the multiplex period because each port must be opened twice during the period.

Ambiguity in setting up calls in a switchboard that uses the circuit in fig. 1 and 2 are avoided by setting up one call at a time. Because this takes place at "electronic speed", it causes no significant delay.

The invention described above is obviously applicable to a P.A.B.X. like for example. has 200 subscribers and is served by a time division multiplex system which provides a number of channels sufficient to transmit the desired number of simultaneous connections. There will therefore be a number of gate capacitor circuits of the GS-CS type equal to the number of simultaneous connections.

An important application of the present invention is to a telephone switchboard as described in Belgian patent no. 515,605.

A telephone exchange that is analogous to it

above mentioned is shown in simplified form in fig. 3.

In this telephone exchange, the serviced subscribers are divided into groups P.Q V with e.g. 200 subscribers each. Each line in a group is connected via a port, e.g. 3G1 to the main road Hl in a time division multiplex system serving this group. There are thus gate circuits that provide routes from all lines in their group to the main road Hl. This port network acts as a combined line finder/selector for the lines in its group. It thus works either as an incoming switching arrangement or as an outgoing switching arrangement since it is desirable.

The main roads, e.g. Hl, each is connected via ports, e.g. G2, with inter-group connections, e.g. LP. The connection LP is used for calls ending in group P, the connection LQ is used for calls ending in group Q, etc. The port network that includes port 3G2 thus acts as a group selector for calls originating from group P. It also acts as an incoming selector for calls which enters group P.

Each connection is equipped with a number of port condenser units, of which one per connection is shown, 3G3 and CP serving the connection LP. The number of such units units is naturally determined according to the traffic density to be served.

When a connection is to be established, a call detector circuit (not shown) for the group which includes the calling subscriber occupies a free channel in the multiplex system which serves this subscriber's group. The identity of the calling subscriber within this group is now recorded in the storage circuit serving the calling subscriber's group in a section of the storage circuit assigned to the covered channel. Each time the time slot corresponding to this channel then occurs, the line finder/line selector is set to connect the calling subscriber to the trunk Hl by opening the port, e.g. 3G1, for this subscriber at this time position.

A register (not shown) is now covered, and a dial tone is sent back to the calling subscriber by amplitude modulation of the pulses corresponding to the covered channel. The calling subscriber now sends the number for the desired subscriber, and as soon as enough digits for selecting the desired group have been sent, this group's identity is registered in a storage circuit (not shown) connected to the group selector which is connected to the calling subscriber's main road. This registration is made in a section of the storage circuit that belongs to the already covered channel. The register now selects a free slot in the multiplex system that serves the desired group, and sets the incoming selector for the desired group to the slot that has just been occupied. The management of this selector is analogous to the management of the group selector.

The digits 1 and the desired number that identify the desired subscriber within their group are used to control the line finder/line selector in their group, as the arrangement now acts as a line selector. This control is carried out at the time setting corresponding to the occupied channel in the called subscriber's group.

To explain how the circuit according to the present invention fits into the system just described, we assume that a subscriber in group P is to be connected to a subscriber in group V. The reception of the numbers identifying group V from the calling subscriber in group P, port 3G4 opens periodically at the time position in the multiplex period corresponding to the covered channel. Main road Hl and connecting line LV are cyclically connected in the occupied time position.

As described above, a time position corresponding to a free channel in the multiplex system that uses main road H2 is now occupied, and the incoming voter is directed out of this time position. This works so that gate 3G5 is opened in the time position just covered and H2 and LV are cyclically connected in this time position.

Simultaneously with or just after the above operations, a free gate-capacitor unit is selected, and it is assumed that this unit consists of 3G6 and CV. Then, at each occurrence of the time positions of the channel in use on the main path H1, gates 3G4 and 3G6 are open, and at each occurrence of the time positions of the channel in use on the main path H2, the gates 3G5 and 3G6 are to open. It should now be noted that the self-inductances corresponding to L1 and L2 are omitted in fig. 3. Furthermore, both in fig. 1 and 3 circuits where there are several gate capacitor circuits in parallel, share the self-inductances LI and L2 (or a simple self-induction corresponding to LI and L2 as shown in 1 fig. 2) because only one of them at a time can use these self-inductances.

It is assumed that the subscribers x and y are connected and that x is the caller. When the call is set up, ports 3G1, 3G4, and 3G6 are repeatedly opened at the time position of the occupied channel of the multiplex system serving group P, and ports 3G7, 3G5, and 3G6 are repeatedly opened at the time position of the occupied channel of the multiplex system serving group

V.

Follow 4 is a more detailed representation, analogous to the circuit shown in fig. 2, of the elements used in the connection described in the paragraph above. Due to the descriptions already given in fig. 2 and 3, it is believed that no further detailed description of fig. 4.

In the alternative embodiment of the invention shown in fig. 5, there is a core 51K of magnetically hard ferromagnetic material, which has a substantially rectangular loop whose initial state is in a predetermined one of its remanent states. It is assumed that the normal state of the nucleus is 1 its positive remanent state. If an electric current flows in a gain on this core, with a direction so that it changes the magnetic state towards the negative direction, but with a value insufficient to saturate the core, the magnetic state of the core will be changed until it assumes a value that depends on the size of this current. When the current pulse ends, the core of this pulse will be set to a new magnetization state which is essentially directly proportional to the amplitude of this pulse. Such a pulse can be supplied to the core above this top winding. Consequently, the core forms a storage device for an indication of the amplitude of the pulse.

To read the state of the core, it is necessary to apply a pulse which brings the core back to its original state of positive remanence. Consequently, a pulse is supplied to the core above the lower winding, and this pulse has such an amplitude and direction that it saturates the core 51K magnetically in the positive direction, regardless of the state the core was in when the pulse was received. When the pulse ends, the core automatically returns to its positive remanent state. However, the change in the state of the pulse is proportional to the change in the magnetization state to which the previous pulse brought the nucleus. This change in flux produces a pulse across an output winding, the amplitude of which is proportional to the change in magnetization of the core and therefore proportional to the amplitude of the original pulse.

In the circuit in fig. 5, the top winding 51W serves both as input winding and output winding. The input pulse is supplied to winding 51W from terminal 51X across a gate 51G which is normally closed and which can be opened in time position, e.g. PG1, in a multiplex period, at which an electrical state to be stored is assumed to occur at 5IX. The winding 51W is connected to a terminal 52X across another port 52G, which is normally closed and which can be opened in a time position such as PF3.

The circuit in fig. 5 thus acts as a storage device which stores a state for a time which can be controlled by the PG and PF pulse trains. Thus, gate 51G is opened by pulse PG1, and the voltage then present at 51X causes current to flow through gate 51G and winding 51W for the duration of pulse PG1. This changes the magnetic state of the core 51K from its positive remanent state to a new remanent state. The properties of the device are such that the change of state produced is essentially proportional to the magnitude of the current flowing in winding 51W as long as it does not saturate the core.

At a subsequent period defined by pulse PF3 in the example shown, gate 52G is opened and a pulse is supplied from terminal 54X to winding 52W across gate 53G. This pulse has such an amplitude that it brings the core back to positive saturation, from where it returns to remanence at the end of the pulse. Because the values of the magnetization at remanence and saturation are very close to the same for materials whose sheath resistance loops are right-angled, the change at the end of the pulse is relatively small. To drive the core to saturation, however, the pulse must change the core's magnetic state from the state the pulse above 51G put it in. The magnitude of this change will obviously be proportional to the amplitude of the first pulse. This change produces a pulse across winding 51W, which serves both as an input winding and as an output winding. The amplitude of the pulse is essentially directly proportional to the amplitude of the first pulse.

At the same time as the pulse supplied from 54X decays, the pulse PF3 opens gate 51G to connect winding 51W to terminal 52X. Accordingly, a pulse is sent from 5IX to 52X with a time delay determined by the difference between the timings of applied control pulses, and the pulse that occurs at terminal 52X has an amplitude that is essentially directly proportional to the pulse that occurred at terminal 51X.

The circuit shown in fig. 5, can be used as a delay storage element in a time division multiplex system in which signaling takes place in both directions over the same main road as in the system described in connection with fig. 3. Thus, when gate 51G is opened, a pulse at 53X occurs for a portion of the time that 51G is open, causing a pulse representing the state to which the core was set to be emitted across 51G. Then, during the second part of the opening time of 51G, a pulse to be delayed is applied across 5IX and 51G to 51W to affect 51K.

During the first part of the pulse that opens 52G, a pulse is applied to terminal 53X to read the stored pulse, and during the second part of this pulse, a pulse to be stored passes over 52G to 51W to affect 51K according to its amplitude.

Fig. 6 shows a further method according to the invention for connecting different channels in two time-sharing multiplex systems in a telephone exchange on lik-

in the same way as in Belgian patent no.

515,605.

This system is largely analogous to

that in fig. 3, so that no detailed description is necessary. An an-

calling line is connected over the elec-

tronic line selector LS to the multiplex trunk Hl in a time position for a free channel on it. The sent number dial impulses are stored in a register where-

of part y governs the final selection. A test is now carried out under the control of the register in order to

see if the already occupied slot is available on main road H2 that serves the desired

sheath line. If this is free, the connection is established in the usual way,

as in the aforementioned Belgian patent on the elec-

tronic group selector GS and rest mode

the one on the electronic voter B. GS has a number of positions per secondary multiplex,

whose purpose will appear later.

If the already selected time position

is not free on main road H2, a free slot is selected on this, and a code representing this slot is stored in part x of the register. This directs selector B to fire in a certain number of delay devices each introducing a delay equal to one multiplex timing position.

GS is set up so that it introduces a vari-

able number of damping units. This ensures that the attenuation between H1 and H2 is constant regardless of the introduced delay between them.

For speech passing in the opposite direction

ning, i.e. from the called subscriber to the

calling subscriber, the voters are controlled from re-

registered at the times that are in use on the multiplex main road H2.

Fig. 7 shows a modified circuit to

connect GS and B where two-way voice trans-

guidance appears. For pulses going from left to right, gates 7G3 and 7G6 open, and for pulses going from right to left, gates 7G4 and 7G5 are opened. The intermediate conductor may include an amplifier

which is shown dashed at 7A7.

It is assumed that 1 the designs that are de-

described in detail, where the storage device

is used to connect channels in two multiplex systems, the two systems are analog

Lodge. However, as already stated, the invention is also applicable to multiplex systems which are not the same, i.e. where they include different numbers of time division channels.

Claims (3)

1. Automatic telephone exchange where a number of subscriber lines are served by time division multiplex equipment, where a connection between a calling subscriber line and a desired subscriber line is established over two time division multiplex channels and a storage device, the calling subscriber line is repeatedly connected to the storage device at the time position in the multiplex period which forms one of the two time division channels and it. desired subscriber line is repeatedly connected to the storage device 1 the time position 1 multiplex period which forms the second of the two time division channels and where the storage device is arranged to receive a modulated pulse from one of the lines at one of the two time positions, to store the modulated pulse in the time interval before the second of the two time positions occurs and to emit the pulse to the other of the lines at the second time position, characterized in that each subscriber line is equipped with a capacitor (e.g. CA, CB, fig. 1) which can be connected with a common channel (e.g. MH, Fig. 1) over a normally closed gate circuit (e.g. GA, GB; Fig. 1), that when a subscriber line participates in a connection its capacitor will be charged by that signal which is sent while the gate circuit between this and the common channel is closed, that the storage device participating in the next connection is a capacitor (e.g. CS, Fig. 1) which is connected across another normally closed gate circuit (e.g. GS , fig. 1) to the common channel, that an inductive impedance (e.g. LI—L2, Fig. 1) is arranged between the subscriber line's gate circuit and the other gate circuit, that both the gate circuit for one of the lines and the other gate circuit are opened at the time position which forms one of the time-sharing channels over which a connection is established, that the size, of the capacitors and the inductive impedance and the period of time in which the gate circuits are open are chosen in such a way that the line's capacitor is discharged practically fully capable of withstanding the capacitor that forms the storage device, so that a practically loss-free energy transfer is provided from the capacitor of the line to the capacitor of the storage device, that both the gate circuit for the capacitor constituting the storage device and the gate circuit for the other of the lines are opened at the time position forming the second of the time division channels over which a connection is established, so that a similar practically lossless energy transfer is established from the capacitor , which constitutes the team organization one to the second line capacitor, that the equipment is symmetrical so that modulated pulses can be sent across the storage device from the calling line to the desired line, as well as from the desired line to the calling line, and that each subscriber line is provided with means to provide a signal from the charges that are successively received by their capacitors. 2. Automatic telephone exchange according to claim 1, characterized in that it is equipped with a number of storage devices (e.g. CS, CS', fig. 1), the number being determined by the exchange's desired traffic capacity, that each storage device is connected to the common channel (e.g. MH, Fig. 1) over individual normally closed gate circuits) e.g. GS, GS', fig. 1) and that devices are provided for, at the start of a call by a subscriber, to assign this call to one of the storage devices. 3. Automatic telephone exchange according to claim 1, characterized in that the multiplex equipment comprises a number of individual multiplex devices (e.g. Hl, H2, fig. 3) each of which serves a different group subscriber lines, that a number of storage devices (e.g. CV, CP, fig. 3) are provided where each set can be used for connection between lines in a pair of the groups, that when a line in a first group is to be connected to a line in another group, the line in the first group will be repeatedly connected at a first time position over normally closed gate circuits (e.g. 3G1, 3G2, 3G3, fig. 3) and the main path (e.g. Hl) in the multiplex arrangement which serves this group, with a storage device (e.g. CP) and the storage device is repeatedly connected at a different timing across normally closed gate circuits (e.g. 3G3, 3G5, 3G7, Fig. 3) and the main path (e.g. H2 , fig. 3) in the multiplex device that serves the second group, with the second line and that the first time position corresponds to a time division channel in the multiplex device that serves the first group of lines and the second time position corresponds to a time division channel that serves the second group of lines.