NO140327B - FINDELTE, FUNCTIONAL PARTICLES FOR USE IN DENTAL CARE - Google Patents

Description

Electronic automatic telephone system.

The present invention relates to automatic telephone systems and in particular such systems where the stationary circuits are operated electronically and use gas discharge tubes with a cold cathode.

The invention consists of an electronic automatic telephone system with several connections, each of which can be connected to two arbitrary subscriber telephones so that a connection channel is formed between them over the connection, where the speech circuit for each subscriber telephone is connected to each of the connections through a special cold cathode - gas discharge pipe and the device is such that when resting

any subscriber initiates a call to call another subscriber, e.g. by lifting the handset, it lights the tube connecting the voice circuit of the calling subscriber to one of the connections and when numbered or another identification code for the called subscriber is sent, it lights the tube connecting the voice circuit of the called subscriber to the same connection, and thereby ends the voice circuits between the subscribers through the two pipes that have lit up when the called subscriber answers, e.g. by lifting his handset, where each cold-cathode tube, which is connected between a subscriber's telephone and the connection,

has two trigger electrodes, of which one electrode in each tube is connected to the connections and receives a potential sufficient to light the tube when the subscriber connected to it is called by another subscriber, and the peculiarity of this installation consists in that a continuously acting

allocation circuit at intervals in turn prepares the second electrode in each pipe so that when a subscriber lifts his handset to call another subscriber and thereby causes a change in the potential across the pipes connected to the connections,

will the first tube prepared by the assignment circuit after the calling subscriber has lifted his microtele-

fountain to connect the calling subscriber with the connection that belongs to the pipe in question.

The allocation circle preferably consists of

a ring counter that includes an equally large an-

number of cold cathode tubes that are connected in the station, as each of these tubes controls the preparation of all the tubes that serve to connect all the subscribers to the connection that belongs to the respective counting tube.

An exclusion circuit is also provided

to prevent a subscriber attempting to make a call from being connected to a connection that is already busy, and to indicate to that subscriber that all connections are busy.

To take care of the finger disc pulses are

it arranged a number of registers for each connection, and each of the registers uses cold cathode tubes. In practice, each subscriber is in a station for up to 80 subscribers, to-

divided a number consisting of two digits, but the number 1 is never used as the first digit.

In this way, the danger is considerably min-

happened so that false pulses will cause disturbance in the station circuits and possibly cause a subscriber to be called. To take

separate from the finger dial pulses that represent the two digits in each number, two registers are arranged for each connection. The first register is equipped with a number of outputs equal to the number of digits used in the first digit of each number. The second register is divided into a number of equal sections or levels, equal to the number of digits used in the first digit of the subscriber number, and a level is connected to each of the outputs of the first register. Each level forms ten outputs that represent the ten ones 0 to 9 that form the second digit in the numbers whose first digit is represented by the corresponding output from the first register.

To deal with numbers that have more than two digits, additional registers are needed, but the working principle remains the same.

According to a further feature of the invention, the anodes in all the tubes connecting the different subscribers with any connection are connected by a common connection circuit containing a test point whose potential varies for the different levels according to successive conditions existing in the circuits under the sequence of operations that take place when a subscriber attempts to call another subscriber.

The potential at this test point is again applied to a connection control circuit which serves to control the circuits associated with this connection during the time between the lifting of the handset and the beginning of the call and the termination of this call, or of the calling subscriber's attempt to sit down in connection with the other subscriber.

The call control circuit contains devices that are energized when a subscriber lifts his handset and grabs a call, to prevent another subscriber from grabbing that call to make a call, and further devices that are energized at the end of a call, or when the caller subscriber stops trying to call another subscriber, to make the line unit available for that subscriber or for both subscribers and also to release the connection for use by any other subscriber. The connection control circuit is applied to two reference or opening potentials which enable each of two parts of the circuit to be energized at times determined by potential variations at the test point during the series of operations that take place when a subscriber attempts to call a other subscriber.

The telephone system is designed to work with normal telephone types where the microphone

is connected to the line by closing contacts when the handset is lifted, itself

whether other types of subscriber equipment that can perform the same functions can be used.

For example, the subscriber's equipment may contain an amplifier and loudspeaker for reproduction of other subscribers' speech and/or an amplifier which is connected to the microphone to amplify the calling subscriber's speech. Each telephone or equivalent subscriber equipment also includes a pulse sending device for sending pulses representing the number of a subscriber to be called to the register circuits in the station.

To explain the invention in more detail

reference must now be made to the attached drawings. Fig. 1 shows a block diagram for an embodiment of an automatic telephone system according to the invention. Fig. 2 shows a form for a subscriber-'

line unit.

Fig. 3 shows a diagram for a connection circuit. Fig. 4 shows a diagram of the first register. Fig. 5 shows a diagram of a level in it

other register.

Fig. 6 shows a diagram for the tone and pattern generators. Fig. 7 shows a diagram for the connection allocator. Fig. 8 shows a diagram of the exclusion circuit. Fig. 9 shows a diagram of the connection control circuit. Fig. 10 graphically shows the changes in the potential applied from the connection circuit to energize the connection control circuit. Fig. 11 shows a diagram for a network that produces some of the voltages needed in the equipment.

The embodiment of a telephone system according to the invention shown in fig.

1 consists of a 20-line station with three

connections or voice circuits over which conversations can be conducted between any of the twenty subscribers associated with the station. Only connection No. 1 is shown in detail, but it is clear that the design of connection No. 2 and No. 3 is similar to that shown for connection No. 1. For clarity, only four of the twenty line units are also shown LU which is connected to the subscriber telephones over the lines L.

Each subscriber has a number that contains two digits and to essentially avoid the danger of energizing the station circuits in the event of false pulses, the number 1 is not used as the first digit of any subscriber number. In this embodiment, the twenty subscribers therefore have two-digit numbers 20-29 and 30-39. Only the line units for numbers 20, 21, '30 and 39 are shown and of these units only numbers 20 and 39 show the connections from the outputs of the other registers.

The three separate connections comprise a switching circuit CC which is common to all line units and also a connection control circuit LC. To take care of the finger disc pulses, each connection also includes a first register FR and a second register SR, the last of which has two equal sections designated "level 2" and "level 3". The first register determines which of the levels in the second register is to be prepared depending on the first digit sent. Thus, if the first digit is 2, level 2 of the second register is prepared to respond to the finger dial pulses of the second digit, but if the first digit is 3, the first register will prepare level 3 of the second register to respond to the finger dial pulses in the second digit. The ten outputs from level 2 in the second register are led to the line units for the subscribers with numbers 20 to 29, and the ten outputs from level 3 in the second register are led to the line units for the subscribers with numbers 30 to 39.

The connection circuit includes a test resistor, and changes in the potential across this resistance caused by changes in the potential on the connection during the sequence of operations when calling from one subscriber to another, as well as ringing for both subscribers when the call is terminated, are impressed on the connection control circuit LC to control the operation of the station equipment.

Two opening potentials serve as reference potentials and opening 1 and opening 2 respectively are applied to the connection control circuit to help control its operation. The connection control circuit briefly comprises a first opening amplifier Gl which is applied to the opening potential 1 and also variations in potential from the test resistance, and itself emits energy to an opening pulse reversal stage GP which in turn emits energy to a finger dial pulse shaping circuit DP which emits the finger dial pulses to the first and the other register. The stage GP also provides output energy to the assign and exclude control stage AL. An output from the inverter stage GP is also connected to preparation pulse amplifier CP1 and a latch circuit CL. The output of the amplifier CP1 is connected to the latch circuit, the main preparation circuit MC and a register preparation tube RC. The output power from the main setup circuit MC is used to setup the connection at the end of a call and the register setup circuit RC is used to setup the registers and also the busy tone control circuit ET which controls the supply of busy tone to a calling subscriber if the number he is calling is busy. The circuit G2 for opening 2 is supplied with opening potential 2 and also variations in potential from the test resistor in the switching circuit and energizes the preparation pulse amplifier CP2 which in turn energizes the register preparation tube RC. The amplifier PA for positive pulses amplifies positive potentials from the switching circuit CC and supplies them to the preparation pulse amplifier CP2.

The station also includes a ring generator RG for supplying ring current to each of the twenty line units, as well as a busy tone generator EG and a ring pattern generator PG which also emits its energy to each of the twenty lines -units. The output energy from the busy-tone generator EG is passed across each switching circuit CC to a calling subscriber if a called subscriber is busy. The transmission of the busy tone to a subscriber over the connection to his line unit is controlled by means of the exclusion circuit LO when all connections are busy. Finally, the allocation circuit AO makes it possible to prepare each of the subscriber units LU in turn so that they can be connected one after the other to the three connections.

It is clear that the description of fig. 1 which has now been given, only constitutes a brief outline of an embodiment of the plant, and the various circuits which form the plant will be described below in detail in order to show quite clearly how the effect is. The various blocks or sections in fig. 1 also shows the tubes V and/or transistors T which are contained there, and which form elements in the circuits which will now be described in detail.

The line unit.

Fig. 2 shows the circuit for one of the twenty line units arranged to connect each of the twenty subscribers to each of the three connections. Each of the line units consists primarily of three cold cathode tubes VI, V2 and V3 and a switching transformer Tri. The subscriber telephone is connected by means of the lines L to the primary side of the transformer TRI, the secondary side of which is connected to the cathodes of the three tubes VI, V2 and V3. The anodes in these tubes are each connected with their own connection and the corresponding connection circuit, fig. 3, through clamp 21 and from there also to the anodes in the corresponding tubes in each of the other nineteen line units.

It will now be described how the pipe VI which is connected to connection no. 1 works, as it is clear that the pipes V2 and V3 which are connected to connection no. 2 and connection no. 3 respectively work in a similar way. The trigger in tube VI, which is shown on the right, is sequentially prepared together with the corresponding triggers for tubes V2 and V3 by means of pulses supplied from the connection allocator, fig. 7, above terminal 3. The right triggers for the corresponding pipes in each of the line units are connected in parallel so that all the pipes in the line units connected to connection no. 1 are prepared, then all the pipes connected to connection no. 2, then all the pipes connected to connection no. 3, and so on in order. The left trigger in tube VI receives, via terminal 31, an output pulse from the second register, fig. 5, when the subscriber associated with this line unit is called by another subscriber and is free to take an incoming call. The amplitude of the pulse applied to terminal 31 is sufficient to light the tube.

When a subscriber wishes to make a call, he lifts his handset and thereby completes the circuit through the primary side of the transformer TRI and the telephone lines L and thereby causes current to flow in this circuit and thus a corresponding voltage drop which lowers the potential on the cathodes of VI, V2 and V3 to approx. -30 volts. This potential change is such that when the next preparation pulse is received on the right trigger in any of tubes VI, V2 and V3, the prepared tube will light and thereby connect the calling subscriber to one of the connections. After ignition, the cathode potential of the tube rises to approx. + 50 volts, and as the potential on the cathodes in the other two tubes also rises, the allocation-preparation potential is now not sufficient to light these other tubes. When, during the subsequent emission of the number pulses, the loop through the primary side of TRI is broken, the tube that has lit is kept conductive by means of the resistance RI.

The pipe V4 controls the supply of ring current to the subscriber being called. The anode in this tube is connected to terminal 8, which is supplied with a 17-period ring current superimposed on a positive DC voltage. A pulse train which forms the ringing pattern and has a period of one second on, one second off, is fed to the trigger in tube V4 above terminal 11 from the tone and pattern generators, fig. 6. The diode MR1 in series with the trigger in V4 normally locks the trigger firmly to earth, when the subscriber's handset is hung up. When he is called, however, one of the connecting tubes VI, V2 or V3 will have ignited and raised the cathode voltage on the rectifier MR1 so that the locking of the trigger in V4 is disengaged, and the ringing pattern can ignite the tube and carry ringing current over the telephone line L to the called subscriber. When he lifts his handset to answer the call, diode MR2 conducts to supply a negative voltage to the trigger in tube V4 to prevent it from carrying more ring current. At the same time, the capacitor Cl is charged to a negative potential so that when the subscriber hangs up his handset at the end of a call, the negative charge on the capacitor Cl which is carried to the trigger in the tube V4 is sufficient to keep the tube non-conductive until the station circuits are made ready.

Diode MR., is energized to suppress negative finger dial pulses and transient currents, but not speech, while diode MR, in series with resistor R, serves to suppress positive transient currents in finger dial transmission, but is blocked for speech frequencies by means of the voltage across the transformer. The diode MR5, the capacitor C2 and the resistor R5 form a network which should prevent oscillation, should a tube be energized on the negative part of its characteristic. The capacitor C2 also disconnects the resistors in series with the secondary side of the transformer TRI for the speech frequency when the microphone is lifted off.

The diode MR6 blocks the positive outputs of the ring current to prevent energization of the transistor reversing stage T7 in the connection control circuit, fig. 9, which is connected to the connection circuit via terminal 6, thereby preventing the preparation circuit V30, V31 and V33 in the connection control circuit from being energized with ringing current.

The network R4, R5, C3, C4 connected to the left trigger of each of the tubes VI, V2 and V3 forms a time-constant circuit to prevent anode/trigger breakdown of these tubes at the end of a call, when a subscriber puts back his handset , and also prevents the tubes that are not needed from firing as the finger dial pulses pass them during finger dial transmission.

Diodes MR7 and MR8 are normally biased by the positive voltage on the cathodes of tubes VI, V2 and V3 when one of these tubes is lit, thereby preventing the supply of a busy tone to a subscriber through these diodes while he is associated with one of the connections. However, the diodes conduct to carry the busy tone to a subscriber if all connections are busy, as will be described in connection with the exclusion circuit, fig. 8.

The switching circuit.

The connection circuit is shown in fig. 3. It is arranged for each of the three connections and comprises a resistor R6, the so-called test resistor, in series with a transformer TR2 through which high voltage is passed across terminal 21 to the anodes in the tubes in the subscriber line units that form the speech circuit - the connections to the associated connection. The connection point between the resistor R6 and the transformer TR2 is called the test point P. The switching circuit is also connected to the first register, fig. 4, through the clamp 16, with the tone and pattern generators, fig. 6, above the clamp 29 and with the connection control unit, fig. 9, above terminals 6 and 15. Other components of the connection circuit shall be discussed below in connection with the description of other parts of the system.

First register.

The first register, which is shown in fig. 4 and of which one is arranged for each connection, as explained above, reacts to the finger dial pulses representing the first digit of a subscriber number to be called, and determines which level in the second register is to be prepared for to receive finger dial pulses representing the second digit of the number for the called subscriber.

The circuit consists of six cold cathode tubes of which V5 is self-extinguishing, V6—V9 form a broken ring counter and V10 forms a control tube. Fingertip pulses are supplied to the grids in V6—V9 across terminal 4. The trigger in tube V6 is prepared across terminal 7 from the anode in the main preparation tube V31 in the connection control circuit through a network comprising R7, R8, C5 and MR9 forming a time constant circuit with fast discharge, slow charge. This connection ensures that the bias potential is removed from V6 when the preparation circuit is energized to thereby prevent false triggering of V6 due to transient currents during preparation.

In the embodiment described, the first digit in a subscriber number is either 2 or 3, and two parts are therefore arranged for the second register, one of which is designated "level 2" and the other "level 3". The cathode of tube V7 is connected to level 2 across terminals 14, 12 and 18, and the cathode of tube V8 is connected to level 3 across terminals 24, 22 and 28. It is clear that if there had been more than twenty subscribers, it would have been necessary to provide a greater number of levels to the second register, one for each additional first digit used for the subscriber number, and also that additional pipes, one for each additional digit, would be contained in the ring counter in first register between C8 and V9.

It will now be seen how the circuit works when sending the number 1, 2, 3 or a number greater than 3 for the first digit using a finger dial.

Sending of 1:

When the finger dial pulse is applied to the trigger in V6 from terminal 4, this tube will ignite and charge the time constant circuit R9, C6 which, when charged, ignites tube V5. This tube is arranged in a self-extinguishing circuit and produces a pulse on its cathode, which is pressed to extinguish tube V6. The circuit is made ready again within 0.2 seconds. No output voltage • is produced in the first register. This is also the effect of the circuit in response to transient pulses.

Shipment of 2:

The first finger disc pulse turns on tube V6 in the manner described above, and the second pulse turns off V6 and turns on V7. The second pulse arrives 100 milliseconds after the first, i.e. before the timer circuit R9, C6 is sufficiently charged to light V5. V7 remains on and the output voltage is taken from its cathode across terminal 14 to prepare the trigger in Vil in second register level 2.

Shipment of 3:

The first two pulses ignite V6 and V7, as described above, and the third pulse ignites V8. The time constant circuit RIO and C7 in the cathode circuit for V7 serves to prevent the first tube in level 2 from firing when the finger dial pulses pass through V7. When V8 fires, an output voltage is taken from its cathode across terminal 24 to prepare the first stage 3 tube.

Sending a number greater than 3.

If the number 4 or a larger number is sent, the first three pulses will affect the circuit as described above, and the fourth pulse causes the ignition of tube V9. The time constant circuit Ril, C8 in the cathode circuit of tube V8 prevents the first tube in level 3 from firing when the pulses pass through it. The ignition of tube V9 will in turn ignite V10 through MR10 which causes the switching off of tube V9.

The cathode capacitors C7 and C8 for the tubes V7 and V8 are connected to the cathodes of the first tube in the corresponding level in the second register via terminals 12, 22 respectively, instead of to the ground terminal of the first register. This has been done to prevent the tubes in another register from igniting again after they have been extinguished due to the charge on the capacitors.

The subsequent finger dial pulses representing another digit in the number of a called subscriber affect the selected level in another register. The first pulse will also light tube V8 or V9 depending on which level is selected, and also tube V10 will light when the first tube in the selected level in another register is lit, either through R12 to the left trigger in V10 for level 2 or through diode MR11 and R13 on the right trigger for level 3. When tube V10 is lit, a DC voltage is applied to the common cathode line through MR27 to keep the cathodes in tubes V6—V9 sufficiently positive to prevent V6 from being lit again on reception of subsequent pulse trains representing the second digit. V10 is turned off by means of a pulse received on terminal 20 from the cathode of V32 in the connection control circuit.

The tube V10 also works together with the diode MR12 which is connected to its anode and across terminal 16 with the associated switching circuit, to control the transmission of the busy tone to a calling subscriber. The diode MR13 in the switching circuit, fig. 3, is normally not conductive due to the positive bias that is applied through MR12, and therefore the busy tone that is passed from the tone and pulse generator via terminal 29 is not normally passed on to the subscriber. If, however, a busy number is sent, tube V10 in the first register is not extinguished, as tube V32 in the control circuit is not lit, and therefore no pulse is supplied to prepare the first and second registers. MR12 is not conductive and the potential on the cathode of rectifier MR13 in the switching circuit is lowered sufficiently for it to become conductive and carry the busy tone through the transformer to the calling subscriber.

Terminal 5 is connected to the cathode of register preparation tube V32 in the connection control circuit and receives a pulse which is applied across terminals 18, 28 respectively to prepare level and level 3 in the second register.

Other register.

Fig. 5 shows a level in another register comprising tube V1-V20 which is arranged in a ring-counter circuit. A similar circuit is arranged for each of the two levels in another register, and the circuits are connected by out-

the gang terminals from V7 and V8 respectively in the first register.

As already explained, the trigger in Vil in the ring counter is set above terminal 14 or 24 by means of the voltage obtained from the cathode of the associated tube V7 or V8 in the first register, when this tube fires. Finger dial pulses representing the second digit in a subscriber number and which are supplied via terminal 4, will now light the tubes in the ring counter one after the other until the tube representing the second digit is lit by the last pulse. If e.g.

5 is the second digit, will pulse as follows

successively, light Vil, V12, V13, V14 and V15 in succession, the last tube staying lit. The ignition of pipe V15 will in turn light the associated connection pipe in the called subscriber's line unit, which is connected to the connection where the calling subscriber works provided that the called subscriber is not busy. The pulse from the tube in the second register that is not lit is transferred via terminal 31 to the left trigger in the correct connecting tube in the line unit. If the called subscriber is busy, the arrangement is such that a busy tone is sent from tube V10 in the first register to the calling subscriber as described above in connection with fig. 4.

Tone and pattern generators.

This circuit shown in fig. 6, consists of two cold-cathode tubes V21 and V22 and a transistor Tl. Tubes V21 and V22 are connected in a free-running multivibrator circuit which produces a series of square pulses with a duration of one second on, one second off, which form the pattern that controls ringing - the power generator. This ringing pattern is transmitted over terminal 11 to each of the subscriber line units. Seventeen period ring current is transferred to terminal 8. An output voltage is also taken from the anode of tube V21 through terminal 17 to the allocation circuit for tripping purposes as will be explained below.

The pulse pattern produced by V21 and V22 is also used to control the busy-tone oscillator Tl. The arrangement is such that when V22 is on and the potential is falling at its anode, transistor Tl conducts and oscillates, but when tube V22 is off, it rises its anode potential and biases the transistor Tl. The output voltage from the oscillator Tl is passed through transformer TR3 and terminal 29 to the switching circuit for each connection in order for the busy tone to be passed to a calling subscriber, when the number he is calling is busy, by the action of the tube V10 in the first register as already described. A further winding of the transformer TR3 is connected across terminals 2 and 30. Terminal 2 is connected to the base of the transistor T3 in the exclusion circuit, and terminal 30 is connected to the anode of the rectifier MR8 in each of the twenty subscriber units. This circuit is used to carry the busy tone to a subscriber if all connections in the station are busy, as will be described in connection with the exclusion circuit, fig. 8.

As the trigger electrode in tube V22 is supplied with energy via a circuit with a very large time constant consisting of R14 and C9, the trigger potential will rise very slowly and there is a danger that corona breakdown will occur in the tube between the trigger and the cathode. If this occurs, the tube will be prevented from igniting properly between anode and cathode, as the current drawn through! resistor R14 connected in series with the trigger will cause a voltage drop that prevents the trigger electrode from ever rising high enough to allow sufficient transfer current to flow to cause anode-to-cathode breakdown. To avoid the danger of this undesirable condition occurring, part of the seventeen period ring voltage is applied through capacitor CIO as a superimposed voltage on the DC voltage applied to the trigger in tube V22. This prevents corona breakdown occurring between trigger and cathode in the tube, as the superimposed voltage produces a sufficiently rapid rate of rise of the trigger potential to cause the tube to ignite correctly between anode and cathode.

Association assigns.

The connection allocator shown in FIG. 7, shall apply a preparatory voltage in sequence to the higher triggers in the three groups of twenty connecting tubes in the line units to prepare these tubes so that they are ready for ignition if any subscriber wishes to call another subscriber. The circuit comprises three tubes V23, V24 and V25 arranged in a closed ring counter and a starting tube V26. A positive pulse supplied across terminal 17 from the anode of V21 in the pattern generator is applied to the trigger in tube V26 to light this tube, and a positive pulse on its anode is transmitted to the right trigger in tube V25 to light this tube. V26 stays lit to prevent subsequent pulses applied across terminal 17 from having any effect on the ring of tubes V23, V24 and V25. When V25 fires, it charges capacitor Cll through resistor R15 and fires tube V23. A pulse from the cathode in V23 is applied through the capacitors C11, C12 and C13 to extinguish the tube V25. When C14 is charged through R16, tube V24 lights and in turn tube V23 goes out. The charging of C15 through R17 again turns on V25 and turns off V24. The tubes are therefore lit in turn and positive potentials appear one after the other on the cathodes of the tubes V23, V24 and V25. These positive potentials are in turn used to switch off the three clamping diodes MR14 which are connected to the terminals 19 which in turn are connected to the diode MR19 in each of their associated connection control circuits and from there to the right triggers in the twenty tubes in the line units which is connected to the associated connection through terminal 3. As each locking diode MR14 is broken out, the potential on the right trigger in each of the twenty tubes in the line units connected to this connection will prepare these tubes. However, the arrangement is such that the positive voltage can only become effective to prepare the pipes which are connected by a connection if V27 in the connection control circuit, fig. 9, is also lit. At other times, when V27 is off, terminal 19 is locked to ground potential and is actually held at 20v by rectifier MR19 in the control circuit. V27 in the control circuit is switched off when a connection is seized to prevent further preparation of pipes in this connection. However, the distributor turns further and produces the positive potentials one after the other on the cathodes of V23, V24 and V25.

The exclusion circuit.

This circuit, which is shown in fig. 8, has the task, when the three connections are already occupied and a further subscriber lifts his microphone, to prevent lowering the cathode potential of the connection tubes in his line unit to a value which would otherwise allow one of these tubes to ignite, when it leads finger disc pulses further, thereby ending

• this subscriber to one of the busy connections. The circuit mostly consists of three transistors T2, T3 and T4 and an Eller circuit comprising three diodes MR15, MR16 and MR17 which are connected to the base of the first transistor. As long as any of the three junctions is available, a positive potential is passed across terminal 1 from the cathode of V27 in the junction control circuits and through at least one of the diodes to the base of transistor T2. The emitter is at only + 20 volts, and this transistor is therefore broken and the cathode in the connecting tubes of any line unit can become negative, when a subscriber

lifts his handset to make a call. If, however, all the connections are busy, the positive potential supplied from the seed band control circuits will not be present, as tube V27 is switched off, so that transistor T2 can conduct so that the upper end of resistor R18 is locked to ground due to diode MR18 . If a subscriber now lifts his handset to make a call, the cathode lead of his connecting tube cannot become completely negative, as the diode MR18 is conducting. However, a slight negative voltage is applied across terminal 2 from terminal 30 in the subscriber's line unit and through the winding of transformer TR3 in the busy-tone generator, whereby the base of transistor T3 becomes negative in relation to the emitter and this transistor becomes conductive. The negative voltage on the cathode of the subscriber's connecting tubes VI, V2 and V3 makes the diodes MR7 and MR8 in the subscriber's unit conductive so that they pass the busy tone on to the subscriber from the winding of transformer TR3 connected to terminal 30. It is clear that none of the subscriber's connection tubes are set using the allocation circuit, as all connections are occupied and none of the tubes VI, V2 or V3 will therefore light.

When T3 conducts, it cuts off the transistor

T4 which was previously leading. The negative 55 V potential on the collector of transistor T4 now keeps the base of transistor T2 negative and the circuit constants have been chosen so that even if a connection should now become vacant, thereby making one of the diodes in the or circuit conductive, the base of transistor T2 will still is kept negative, as transistor T4 is blocked. The subscriber attempting to make a call can therefore only seize the free connection by first hanging up his handset again to cut off transistor T2 and allow T4 to conduct again. If, therefore, a calling subscriber receives a busy tone, when he picks up his handset, he must first hang up again before he can again try to seize a connection to make a call.

Samband governing body.

Fig. 9 shows the connection control circuit which is affected by changes in potential sorr

occurs across the test resistor R6 in the switching circuit, fig. 3, and which itself controls the state of the circuits in the connection with which it is connected. Largely included

the circuit seven cold cathode tubes V27—V33 and fine transistors T5—T8. When the circuit is switched on and at rest, i.e. when all subscriber microphones on this connection are at rest, tubes V27 and V29 are lit, and transistor T6 is non-conductive.

Opening potential 1 is applied to the emission electrode in transistor T5 and opening potential 2 is applied to the emitter in transistor T8. This last potential is also applied to the emitter of transistor T6, but in this case it only constitutes a suitable potential for the emitter. Both opening potentials are derived from the voltage supply network in fig. 11.

It will now be explained how this circuit works, with reference to fig. 10

which shows the changes in potential across the test resistor R6. It must be assumed that the connection to which the control circuit belongs is free when a subscriber picks up his handset.

The voltage at the test point P in the connection circuit in fig. 3 then falls below the first opening potential and is passed across terminal 15 from the connection circuit to the base of transistor T5. As this transistor has the first opening potential applied to its emitter, it will now conduct and in turn block transistor T6 which was previously conducting. The collector potential in transistor T6 now drops to a value determined by the resistors R19, R20 and R21 which causes the tubes V27 and V29 whose anodes are connected to this collector to turn off. When the tube V27 is turned off, the preparation voltage controlled by the connection allocator circuit on terminal 19 is no longer applied to the right triggers in these connection tubes in other line units which

is connected to this connection, as has already been described in connection with the allocation circuit, fig. 7, then rectifier MR19 conducts and keeps terminal 19 at +20 volts. This

device avoids the danger of anode-trigger breakdown in a connecting pipe if any other subscriber completes

on another connection at this moment. The V29 is a locking tube which, when it fires, prevents the V30 from firing.

When the calling subscriber starts using his finger dial, the pulses <;> cause potential changes in the test point which bring the voltage at the base of transistor T5 above opening potential 1 so that this transistor is alternately switched on and off, and transistor T6 is therefore switched off and on ; in accordance with finger disc pulse-i ne. Pipe V28 teeth in accordance with

- the switching on of transistor T6, and the finger disc pulses are led out from the cathode in this in a tube to terminal 4, from where they are led to the circuits in the first and second register, fig. 4 and 5. in Diode MR20 serves to stop the various tips in the negative direction on the collector - in transistor T6. The network of R22, MR21 and C16 - forms a time constant circuit with slow r charging and fast discharging which prevents V30 from firing during the finger dial pulses by preventing an exponential rise in the potential of the left trigger in tube V30. After completion of the series of finger dial pulses, the called subscriber's connection pipe will light up, point XI in fig. 10, provided that the called subscriber is free, and his bell will ring as described with reference to fig. 2. The ignition of his connecting tube reduces the voltage at the test point P to below opening potential 2, and this further reduction in voltage is transferred from terminal 15 to the base of transistor T8 whose emitter is connected to opening potential 2. Transistor T8 now conducts, and collector potential rises and presses on the right

trigger in tube V32 which ignites and produces a positive pulse on its cathode, which across terminal 5 is used to extinguish control tube V10 in the first register. This also produces a preparation voltage for the right trigger in V33. An output voltage is also taken from the cathode of V32 across a terminal 20 to extinguish the tube in the second register which was lit after completion of the train of finger dial pulses in the called subscriber's | number. Tube V32 is self-extinguishing.

When the called subscriber lifts his

handset to answer the call, point X2 in fig. 10, the potential at the test point P falls even more, but this has no further effect on the connection control circuit, as the potential has already previously fallen below the second opening potential.

Transistor T7 which forms the inverting amplifier stage is normally conducting and its base is across terminal 6 and capacitor C17 in the switching circuit connected to test point P. Whenever a positive pulse is applied to the base of transistor T7, the negative pulse produced is on its collector impressed the cathode of V33. This is a self-extinguishing tube prepared by means of transistor T8, when this is made conductive and fires upon receiving a negative pulse at its cathode from transistor T7 to produce a positive output voltage at its cathode, which is applied to ignite tubes V30 and V31. The tubes V30 and V31 are also self-extinguishing tubes.

Now when a conversation between two subscribers to the connection has ended, and one of the subscribers hangs up their handset again, point X3 in fig. 10, the voltage at the test point P moves in the positive direction and produces a negative voltage on the collector of T7, which is applied to fire V33 if the left trigger is already prepared by means of T8, as this transistor is conducting. The positive pulse on the cathode in V33 is applied to the right trigger in tube V30 which ignites and in turn ignites V31 which produces a main preparation pulse which, via terminal 21, is applied to the anodes in all the connection tubes in the line units connected to this connection, and serves to prepare the line devices for both subscribers. However, unless both subscribers hang up at about the same time, one of the pipes in the line unit of the subscriber who has not hung up again will light up to seize a connection. After this subscriber has hung up, point X4 in fig. 10, the potential in the test point P rises above opening potential 1 and T5 is therefore blocked, and T6 is made conductive, so that V27, V29 and V30 again ignite, point X5 in fig. 10, to return the circuit to the initial state. V29 fires only after V27, as V27 provides the bias voltage to trigger V29. The locking tube V29 cannot therefore lock the trigger in V30 to prevent it from firing until after V27 has fired.

If a subscriber should attempt to send his own number or the number of a busy subscriber, tube V10 of the first register fires and provides a potential across terminal 20 and the circuit R23, C18 with a long time constant, which is longer than the time it takes to send 0 with finger dial, right, trigger in tube V33. When the subscriber hangs up; and thereby moves the voltage at the test point in a positive direction, a negative output voltage from the transistor amplifier T7 will ignite tube V33 and thus tubes V30, V31 and V32 to effect the preparation of the circuits.

Voltage supplies.

Fig. 11 shows a voltage supply network for supply to some of the circuits in the station and which consists of a number of potentiometers inserted between the positive high-voltage line and the ground line.

Resistors R24 and R25 form a potential-?

meters from which a positive 50 v voltage is applied to the connection control circuits. Towards^

stands R26 and R27 form a potentiome-.

ter from which + 20 volts is applied to the exclusion circuit. Resistors R28 and R29 form a potentiometer from which + 20 v setting voltage is derived and fed to diode MR19 in the connection control circuit. Zener diodes MR22 and MR23 in series with resistor R30 and in parallel with capacitor C19 provide err voltage representing opening potential 1, while Zener diodes MR24, MR25 and MR26 in series with resistor R31 and in parallel with capacitor C20 provide opening potential 2.

The system can also include a preparation monitoring circuit which will remove the preparation voltage from all the connections,

at any time a preparation takes place at rest

any connection whatsoever. This prevents a connection from being seized again in the event of a micro-

phone jumps in its seat when hung up

again. The circuit may include a diode to

terminated each connection, which is normally blocked, but which is made conductive for a short time, e.g. 1.5 sec., during a preparation to lock the preparation circuit for each con-

ties to earth in this time. No connection can thus be prepared during this period

1.5 sec., but this does not affect the

band that would already be in use and only causes a delay of up to 1.5

Sec. in that a connection is seized in the event that a subscriber attempts to make a call,

while this watch circle is in operation.

In a modification of the exclusion circuit, the emitter of transistor T2 is connected to ground and the base of transistor T4 is connected to the f 20 volt supply. The diode MR18 is also directly connected to the base of transistor T3. This modified device provides a more positive exclusion, especially if several subscribers pick up their handsets at the same time, while all connections are busy.

In a modification of the first register circuit,

the preparation of V6 no longer takes place

taken from the connection control above terminal 7.

Instead, V6 can be prepared using a

simple voltage divider from the high-voltage supply or alternatively from the anode in V10.

An additional pipe can also be arranged in the circuit

to ensure smoother operation if any subscriber attempts to call another subscriber who is already busy. It also

stra tube is ignited from V10, which itself is ignited by means of the first finger dial pulse in the second digit, via a circuit which causes a delay longer than the time required for the finger dial to send rest-

ket any number in the second register. The additional pipe is self-extinguishing and emits a ready pulse to the other registers to ensure that they are made ready at the end of the call already in progress. A rectifier is needed to stop this pulse from the extra tube,

so it doesn't go through the registry and to-

bake and thereby prepare V10.

In a change of the samband board

the transistor circuit T7 is arranged to ar-

both as pulse shapers rather than as a transmitter, and it is not normally conductive on

due to a circuit with low impedance between

lom the emitter and base. Its collector is grounded across a load impedance, and po-

sitive output pulses are obtained and fed to the trigger electrode of V33 to ignite this tube, instead of the device that is be-

written earlier where a negative pulse is fed to the cathode in this tube. The emitter and base

Claims (9)

in the transistor pulse shaper is connected to the direction point P via delay circuits, the time constant for the base circuit being substantially longer than the time constant for the emitter circuit. No output voltage can occur if the test point moves in a negative direction, and any transient positive pulse will be blocked, as the integration of the pulse on the emitter by means of its time constant circuit prevents an output pulse from occurring in the collector circuit. When the voltage at the test point becomes positive, the emitter briefly becomes positive in relation to the base and the transistor will conduct until equilibrium is again established. Thereby, an output pulse will appear on the collector. In a further change, V28 is prepared from the anode of V31 through a circuit with a long time constant which provides a better readiness of the circuits if a subscriber attempts to send his own number or the number of a busy subscriber. 1. Electronic automatic telephone system with several connections which can be connected to any two subscriber telephones at will, so that a communication channel is created between them over the connection, where the voice circuit for each subscriber telephone is connected to each of the connections through a special cold cathode gas outlet charging tube and the arrangement is such that when any subscriber starts calling another subscriber, e.g. by the calling subscriber lifting his handset, the tube connecting the voice circuit for the calling subscriber to one of the connections is lit and when the called subscriber's number or other identification code is sent, the tube connecting the voice circuits for the called subscriber with the same connection lit whereby the voice circuits between the subscribers are completed through the two lit pipes when the called subscriber answers the call, e.g. by lifting his microphone, where each cold-cathode tube, which is connected between a subscriber's telephone and the connection, has two trigger electrodes of which one electrode in each tube is connected to the connections and receives a potential sufficient to to light the tube when the subscriber connected to it is called by another subscriber, characterized in that a continuously operating assignment circuit at intervals in turn prepares the second electrode in each tube so that when a subscriber lifts his microphone to call another subscriber and thereby causes a change in the potential across the pipes connected to the connections, the first pipe prepared by the allocation circuit after the calling subscriber has lifted his handset will light up to connect the calling subscriber to the connection belonging to that pipe. 2. Installation as stated in claim 1, characterized in that the allocation circuit consists of a ring counter that includes as many cold cathode tubes as there are connections in the station, each such tube controlling the preparation of all the tubes that serve to connect all the subscribers to it connection that belongs to the meter tube in question. 3. Installation as stated in claim 2, characterized in that the allocation circuit contains an initiation tube for initiating the work of the ring counter and to isolate it from the influence of external pulses once the counter has started to work, and a special locking diode which is inserted between each of the pipes in the meter and the trigger electrodes in all the pipes that serve to connect the subscribers to the connection that belongs to the relevant meter pipe. 4. Installation as stated in claims 1-3, characterized in that all the pipes that connect the different subscribers with any connection have their anodes connected to a common connection circuit that contains a test point whose potential varies for different levels according to successive conditions that prevail in the station circuits during the series of operations that take place when any subscriber attempts to call another subscriber and the potential at the test point is applied to a connection control circuit which acts to control the circuits connected to this connection at the time which takes place between lifting the handset of any subscriber to initiate a call and the termination of that call, or of the attempt to connect with another subscriber. 5. Installation as stated in claim 4, characterized in that the connection control circuit is applied to two reference or gate potentials which control two parts of the circuit so that each of them operates at times determined by the potential variations in the test point during the series of operations which takes place when a subscriber attempts to call another subscriber. 6. Installation as stated in claim 5, characterized in that one of the opening potentials makes part of the circuit ready to operate when a calling subscriber seizes a connection to prevent <:>which preferably another subscriber shall seize this connection to 'make a call and also cause the control circuit to return to its original standby state after the last subscriber has replaced his handset at the termination of a call between two subscribers, or after a calling subscriber has stopped trying to call another subscriber, and the second opening potential prepares the other part of the circuit to, after the called subscriber's number has been sent with the finger dial and his line unit has been connected to the connection, to prepare the register circuits and that this other part of the circuit also helps to achieve arming of both subscribers at the end of a conversation between two subscribers, after the first of the subscribers has hung up their handset. 7. Apparatus as set forth in claims 1-6, wherein an exclusion circuit is also provided to prevent a subscriber attempting to make a call from being connected to any of the connections when they are already busy and to indicate to that subscriber that all the connections are occupied, characterized by the fact that the exclusion circuit includes as many diodes as there are connections and is connected to each connection and also forms an "OR" circuit that controls a transistor circuit so that as long as any connection is free and available to a subscriber to make a call to another subscriber, a potential is applied through one of the diodes to keep the transistor circuit in one state, but when all the connections are occupied, the potential is no longer applied through the OR circuit and the transistor circuit changes its state for to prevent connection of any further subscriber with the connections. 8. Plant as stated in claim 7, characterized in that the diodes that form the OR circuit are arranged so that as long as a connection is available, a positive potential is applied to the base of a transistor to keep it blocked, but when all the connections are occupied , the positive potential is removed from the base of the transistor so that it can conduct, thereby making a latch diode conductive whereby any further subscriber now attempting to make a call will not be connected to a connection. 9. An arrangement as set forth in claim 7 or 8, characterized in that the exclusion circuit, even if any of the connections becomes idle while any further subscriber has his handset off-hook, can only be returned to allow a subscriber to be connected with a connection if the subscriber's handset is first switched back on so that the transistor circuit is returned to its initial state.