DE3703447A1 - Selective switching mechanism for one for several telephones - has logic circuit responding to engaged-reset state of sets to open-close MOSFET gating circuitry - Google Patents

Abstract

The switching system has digital control loqic (F) fed over an input line (La,Lb) responding not only to the rest-condition of the telephone, but also to the engaged state via the cradle switch. On the output lines in the rest-stage of all sets there is a digital 'O', but in the engaged state of a set, only the relevant lines retain this value, the engaged lines having a digital '1'. A switch line (41,41') is switched by a single enhancement mode N-channel MOSFET (D1). Each other switch (D2) consists of two series such transistors, one of which is reverse biassed. In each switch (D1,D2) between the switch lines, a further such transistor is coupled as a potential transistor via pre-switch resistance. The gate potential of the switch transistors by the potential transistor, having its gate terminal connected to the control loqic output. A diode is coupled to the first switch at the potential transistor line.

Description

The invention is directed to a switching device the type mentioned in the preamble of claim 1.

The known switching device allows only two remote operate speech devices on a common connection line, why comparatively expensive and space-consuming construction elements required are. Each switch includes a bi stable relay with two relay contacts each and its own Set circuit as well as its own reset circuit for Relay. The time constants of these set and reset circuits as well as the limited pull-in speed of the relays itself in a disturbing interruption of the connecting line in the document state, which in practice 5 to 10 msec. be can carry. This leads, especially to private branch exchanges, So with in-house systems, with a conversation transfer from one telephone set to another in some Cases of a "loss of conversation". The one for the named Switching speed relevant time constants are in the rest depends on the loop current occurring, which is why the line interruptions mentioned by the respective company hang out. Finally, the known ones Relays for custom designs, one accordingly require expensive production.

The invention has for its object a störunan mature, fast-working and inexpensive switching device in the upper Concept of claim 1 type for any Number of telephones to develop despite higher, may occur on the connecting lines the voltage fluctuations and also in the event of an exchange the polarity remains operational. Just one of the featured telephones should be reliable with the connection  be connected while a parallel connection with all other telephones with certainty closed is. One should thereby without external energy supply supply and when the system is in the idle state Call to all telephones. For polarity dependent Switching the speech channels through may be permitted if Polarity no semiconductor diodes are in the speech path, as these would introduce a non-linear, dynamic resistance. This object is achieved in the characterizing part of claim 1 achieved measures, which have the following importance is coming.

In the invention, the switches are all in the idle state Telephone sets switched through. With that, from the front the conversations to all devices come in and choice wise on a telephone set with which a so-called "document status" occurs. This operation becomes via the associated input line was reported by the fork switch to the control logic their outputs controls the digital signals so that the im The telephone set is switched through remains, but all other devices are switched off. This results from the special structure of the invention Switch where the respective potential transistor blocks, so long over the assigned control line output Gate connection the one digital signal, namely the "low" Receives signal and, accordingly, the associated one or more Makes switching transistors conductive. This applies to rest condition with all telephones or in the voucher condition only in the counter of the relevant apparatus. In receipt condition with all other switches the other digital signal, e.g. 1, namely the "high" potential given off now makes the associated potential transistor conductive, whereby at least one of the switching transistors blocks and therefore the supplied switches off the audible telephone set. Such a situation of the digital  signals on the outputs remain saved if additional Lich the handset of another telephone set should be lifted. Because the control logic on the one and switching off the individual fork switches responds, is not an additional loop detection circuit required. Both outputs are via the w wire of the Telephones won. The control logic is thus controlled and stored from the telephone sets the switching state. After a possible short line Interrupted, the conversation is immediately restored sets because the associated switch both at rest and is always switched through even in document status. In the end is a quick switch between to transfer the call the individual telephone sets guaranteed.

If the polarity of the two wires of the connecting cable is reversed remains the first switch due to the then entering reverse operation of its potential and switching transistor switched through, which is why a conversation about the associated Telephone set is possible. Lock all other switches but because the diode has a current flow at the potential transistor prevented and thereby the now polarity operated blocks a switching transistor. A call now arriving cannot signali in these other telephones be settled. At the first switch there is a small one Quiescent current of approx. 0.6 mA, which is far below that for acti crossing of the switching system necessary Value. With both correct polarity and reverse polarity is a parallel operation between the to first switch belonging to the telephone set and each another apparatus at the expense of the power of the connecting line effectively prevented.  

The electronic switching elements do very little Energy drawn from the connection line and still one quick and trouble-free effectiveness of the switches the control logic reached. Despite high voltage fluctuations, can take the peak values of +145 V and -425 V, the switching device according to the invention can operate stably, even if the tension in the document state is between values 6.5 to approx. 25 V drops. The switch switch according to the invention direction can also easily be a permanent exam voltage of 110 V rms. withstand at 50 Hz as well Voltage peaks of 2000 V, for which in the description provide protection diodes.

Due to the shunt transistors mentioned in claim 2, who lead in the document state, becomes a simple Crosstalk attenuation achieved that can be greater than 80 dB can and therefore the value prescribed by the post office enough. In any case, this value is larger than the one with crosstalk to be achieved with a single-pole shutdown Damping. The aforementioned, at rest as well as document state Occurring functioning will both work properly Polarity as well as a polarity reversal reached, because with The first switches swap the two shunt transis only function in the idle state: one of the two shunt transistors is blocked.

The desired operating conditions are simple Way through the power supply mentioned in claim 3 achieved a constant with low energy consumption Operating voltage for the downstream control logic provides. If the polarity is reversed, the diode prevents energy from being supplied the power source, which is then also unnecessary because of how already mentioned that to the one telephone set belonging to the first switch even with polarity reversal  remains ready and all other switches are locked. These Energy supply is characterized by a small construction effort and space savings. By the constant current supply in the idle state is the switching according to the invention Setup ready for use immediately. The entire electricity supply consumption is very low, namely less than 50 µA. Kick it no problems caused by loop current pulses in the Document status when dialing on if, when operating the numbers disc, the wires of the connecting cable short-circuited who the, because the switches according to the invention are in the idle state switched through even without external energy supply.

Through the measures of claim 4, the auxiliary condenser briefly deliver a higher current to the output and ensure a low impedance of the voltage regulator. A protective diode connected in parallel to the auxiliary condenser sator also prevents reverse operating voltage itself from the various switches mentioned above speakers could result.

In the simplest case, where only two telephones optionally connected to a common connection line it is advisable to use the in Claim 5 to use the flip-flop circuit which both digital signals already mentioned in claim 1 due to the switching reported by the two fork switches states. Such control logic can be done if one modified them accordingly, easily to more than two Telephone connectable to a common connection line expand equipment. Because of their low energy consumption the flip-flop circuit can be designed according to claim 6.

In the drawings, the invention is in one embodiment example shown. The invention is directed to everyone new features from the description below and the circuit shown in the drawings, even if this are not expressly stated in the claims. The The drawings show:

Fig. 1 is a block diagram of the switching device according to the invention with two telephones and

Figs. 2 and 3, in two complementary parts, a concrete embodiment of the circuit of FIG. 1.

According to the basic structure shown in Fig. 1, a protective circuit A is first connected to the two wires La, Lb , behind which the lines 10 , 11 lead on the one hand to a power supply B and on the other hand are in two lines 41 , 41 'or 42 , 42 'fork and lead to two switches D 1 , D 2 , which are connected to the corresponding wires a 1 , b 1 and a 2 , b 2 of two telephones E 1 , E 2 . From the power supply B , a supply line 13 goes to a control logic F , from which two output lines 32 , 32 'lead to the two switches D 1 , D 2 mentioned . The control logic F also has two input lines 30 , 30 ', which come from the two telephone sets E 1 , E 2 , as shown in FIG. 3, the w 1 or w 2 wires of the associated hook switch 24 , 24 'are.

In Fig. 3, only the essential for the invention construction parts of the two telephones E 1 , E 2 are shown. Between their connecting wires a 1 , b 1 and a 2 , b 2 , an alarm clock 47 and 47 'and a capacitor 48 , 48 ' are connected in series in a known manner. Between the one connection wire a 1 or a 2 on the one hand and the mentioned wires w 1 , w 2 , the already mentioned fork switch 24 , 24 'is connected, which, as shown, is closed as long as the handset is on the hook. This characterizes the so-called "idle state" of the telephone set E 1 , E 2 . In this case, the above-mentioned input lines 30 , 30 ', with correct polarity of the two wires La, Lb , the mass potential of La via line 41 or 41 ' via the hook switch 24 , 24 'to the associated input line 30 or 30 'Delivered and thus reaches the control logic F. However, if the handset of one or the other telephone set E 1 , E 2 is lifted, there is a so-called "busy status" in the respective set. In this case, the hook switch 24 and 24 'are opened and the associated apparatus impedance Z and Z ' switched on.

The resulting different effects are in connection with the description below of the individual modules explained in more detail.

Protection circuit A

The protective circuit has the task of protecting the switching device according to the invention against impermissibly high voltages and thereby preventing malfunctions or damage. To suppress high-energy, but relatively slow voltage increases, a varistor 53 is connected in parallel with the two wires La and Lb. It is a voltage-dependent resistance that decreases when the effective voltage exceeds a certain limit voltage. In parallel, a surge limiter 54 (transient voltage protection) is connected, which is designed here as a voltage-limiting semiconductor switch in the form of an IC and is effective for fast but low-energy pulses if they exceed a certain limit voltage. The structure of this IC in the limiter 54 is illustrated by two antiparallel Zener diodes. The two wires La, Lb are each connected via lines 10 , 11 to the inputs of the subsequent power supply B , which has the following structure.

Power supply B

An N-channel MOSFET transistor of the depletion type T 9 is connected to the input line 10 and is already conductive in the idle state and forms the component of a current source 46 framed by dash-dotted lines in FIG. 2. For the purpose of voltage limitation, two anti-parallel Zener diodes 17 are arranged in parallel with transistor T 9 , namely between its source and gate connection. Also connected in parallel is a protective capacitor 18 for suppressing vibrations and for eliminating steep pulses. At the gate or source connection, a resistor 15 , 16 is arranged and connected to an output line 45 , which leads to a voltage regulator 12 designed as an IC. From this current source 46 , a charging capacitor C 1 is fed, which is connected to the other input line 11 of the power supply B. The charging voltage of the capacitor C 1 is determined by a parallel connected Zener diode 19 . In the operating case, the current source 46 supplies an operating voltage of approximately 12 V to the voltage regulator 12 via the output line 45 .

The input line 11 is connected to the one wire La of the connection line, which, according to the symbols M, is at ground potential. A voltage divider 21 equipped with two resistors of approx. 1 or 3 M Ω between the output 13 of the voltage regulator 12 and the input line 46 supplies an actual voltage to the voltage regulator 12 via a sensor input 20 . The voltage regulator 12 ensures that there is always a constant voltage of approximately 5 V at its output 13 . The current source 46 is protected against reverse polarity of the wires La, Lb by a diode 14 connected in the input line 10 , which is why the current source 46 does not supply any energy if the polarity is incorrect. The voltage regulator 12 has a particularly low intrinsic current consumption, which is approximately 4 μA. The aforementioned output voltage of approximately 5 V at the output slope 13 remains constant as long as the current drawn is on average smaller than the current flowing through the input line 10 , which is approximately 25 μA in the selected dimensioning.

Between the output line 13 and the one input line 11 , an auxiliary charging capacitor C 2 is connected in parallel with the high-resistance voltage divider 21 , which can briefly output a higher current and ensures a low impedance of the voltage regulator 12 . Furthermore, a protective diode 23 is connected in parallel, which prevents reverse operating voltage in the case of reverse-polarity connection wires La, Lb , which, although it cannot occur because of the diode 14 lying in the input line 10 , but because of a reaction of the switch D belonging to the system according to the invention 1 , D 2 could be possible.

Control logic F

The output line 13 of the power supply B is connected to a control logic F , which here comprises a flip-flop circuit 31 with four in their heath branch lines 49 , 49 'mirror-image-linked NAND gates 55th These can be formed from a commercially available CMOS IC.

In the two branches 49 , 49 'a small current of approx. 5 µA flows in the idle state, namely via a first resistor 25 or 25 ', via protective diodes 27 or 27 'and via resistors 22 , 22 ' to those already mentioned Input lines 30 , 30 '. In the branch lines 49 , 49 'are behind the connection points 52 and 52 ' each have a further resistor 26 , 26 'before the flip-flop circuit 31st From the flip-flop circuit 31 lead two output lines 32 , 32 ', which go to an associated, already mentioned switch D 1 , D 2 .

In the idle state, the ground potential of the core La is passed to the connection points 52 , 52 'already mentioned above via the input lines 30 , 30 '. This "low" potential will be briefly referred to below with the binary symbol "0". In the busy state, on the other hand, if the receiver of the telephones E 1 or E 2 is lifted and consequently the two hook switches 24 , 24 'are open, instead stands on the mentioned resistors 25 , 25 ' at the connection points 52 , 52 ' a "high" potential, which will be briefly referred to below with the binary symbol "1". The control logic F is now constructed so that, depending on the points at the connection 52 , 52 'accumulating potential "0" or "1", on the output lines 32 , 32 ' digital signals "1" or "0" according to the following The table shows:

As can be seen, in the idle state of both devices E 1 , E 2 on the output lines 32 , 32 'the digital signal "0" occurs, as a result of which the associated switches D 1 , D 2 are switched through, as will be described in more detail below. In Dokumentzu stood the apparatus E 2 , which is characterized by the potential "1" at the connection point 52 ', the digital signal "0" remains on the associated output line 32 ', but E 1 appears on the output line 32 of the other apparatus the digital signal "1", which is why this switch is now blocked, which will be explained in more detail. If the handset of the other set E 1 is also lifted when the set E 2 is already in use, then, as is illustrated in the last line of the table by the symbol "X" , the output line 32 ', as before, remains on the digital signal "0" and the output line 32 on the digital signal "1". The control logic stores these states. The conversation conducted by the device E 2 is consequently not disturbed and the device E 1 remains blocked.

Switch D 1

The ground potential "0" applied to the output line 32 in the idle state acts on the gate connection of an N-channel MOSFET transistor of the enhancement type T 4 , which is connected via a series resistor 43 between two switch lines 41 connected to the wires La and Lb , 42 is switched. This transistor will hereinafter be referred to as "potential transistor T 4 " for short. In the idle state, the potential transistor T 4 is blocked. A line 35 connected to its drain connection is then at the positive potential of the switch line 42 .

In a switch line 41 connected to the other wire La , a further N-channel MOSFET transistor T 1 of the enhancement type (enhancement) is connected, which is to be called "switching transistor T 1 " for short. Via the aforementioned line 35 and a first resistor 37 of a voltage divider 36 , 37 , the positive potential is fed to the gate terminal in the idle state, which is why the switching transistor T 4 is now conducting. A Zener diode 33 between the gate and source connection of T 1 serves to limit the voltage. The voltage divider 36 , 37 is not agile, because in the idle state a high voltage is present between the wires La, Lb and thus the switch lines 41 , 42 .

In the switch D 1 there are two P-channel MOSFET transistors T 2 , T 3 connected in series with one another to the enrichment type (enhancement), whose gate connections in the idle state also receive the positive potential via line 35 , two further resistors 38 , 39 act as a voltage divider. A zener diode 34 between the gate and source connection serves to limit the voltage. These transistors T 2 , T 3 will be referred to below as "short circuit transistors". The transistor T 3 is reversed with regard to its source and drain connection and remains conductive in this idle state, but the other shunt transistor T 2 , which is switched correctly, blocks. Consequently, the two shunt transistors T 2 , T 3 are not short-circuited in the idle state. The switch D 1 is therefore switched through in the idle state and an incoming call can immediately reach the telephone set E 1 . A protective resistor 40 is connected between the source connections of the shunt transistors T 2 , T 3 .

If there is a polarity reversal of the connecting line, where the two wires La, Lb are mirror images of each other, the potentials on the two switch lines 41 , 42 are of course interchanged. In this case, because of the then occurring reverse operation, the potential transistor T 4 , the switching transistor T 1 and the one shunt transistor T 2 are conductive, but the other shunt transistor T 3 is blocked because it is now polarity correct is operated. For this reason, the two switch lines 41 , 42 are not short-circuited via the shunt transistors T 2 , T 3, and consequently a conversation is possible, even with polarity reversal. The shunt transistors T 2 , T 3 have interchanged their blocking function with respect to the correct polarity. A small quiescent current of approximately 0.6 mA flows via the potential transistor T 4 , which is far below the value required to activate the switching system. The auxiliary circuit transistors T 2 , T 3 are connected between the one switch line 42 and that one, behind the switching transistor T 1 continued line section 56 of the other switch line 41 .

If, with the correct polarity connection to the telephone set E 2, the occupancy status is established by picking up the handset, then the output line 32 'assigned to the switch D 2 there remains the digital signal "0" which is already decisive in the idle state, which is why the switch D 2 is switched through is, but on the output line 32 belonging to the first switch D 1, the other digital signal "1" occurs via the control logic F. At the Gatean circuit of the potential transistor T 4 appears "high" potential and makes it conductive. The conductive potential transistor T 4 now in turn brings the "low" potential of the switch line 41 to the control line 35 on the one hand to the switching transistor T 1 and on the other hand to the two shunt transistors T 2 , T 3 . This leads to the following effects:

The switching transistor T 1 is blocked. Both shunt transistors T 2 , T 3 conduct because they receive negative potential with respect to source at the gate connection.

As a result of the blocked switching transistor T 1 , the switch D 1 is blocked in the busy state of the other telephone apparatus E 2 . The associated telephony device E 1 is therefore switched off. The shunt transistors T 2 , T 3 ensure an increase in crosstalk attenuation to a very favorable high value, namely greater than 80 dB.

If the handset is replaced in the telephone set E 2 , the flip-flop circuit 31 is reset again via the control logic F. The digital signal "1" appears on the output line 32 . Thus, the ratios of the idle state are again present, where the switching transistor T 1 and the potential transistor T 4 block. About the resistors 43 , 36 , 37 flows a low quiescent current in the switch D 1 , which is about 7 uA in the selected dimensioning and with a loop voltage of about 60 V between the two wires La, Lb.

Switch D 2

The switch D 2 is designed in many ways similar to the switch D 1 , which is why the same reference numerals have been used to designate the corresponding components, but to distinguish them, see with a dash (') ver. In this respect, the previous description also applies. It is enough to deal with the differences.

Between the two switch lines 41 ', 42 ', a potential transistor T 8 is also connected here via the series resistor 43 ', namely an N-channel MOSFET transistor of the enhancement type (enhancement), but there is one with the correct polarity before its drain connection Diode 51 pointing in the direction of current flow. In the switch line 41 'in this switch D 2 two Schalttran sistors T 5 , T 6 are connected in series, of which the one transistor T 5 is operated in reverse. Between the scarf line 41 'behind the two switching transistors T 5 , T 6 continuing line 56 ' and the other switch line 42 'is only a shunt transistor T 7 connected to the switch D 2 , which in turn consists of a P-channel MOSFET transistor the enhancement type is formed. The switching transistors T 5 , T 6 consist of an N-channel MOSFET transistor of the enhancement type.

In the idle state of both telephones E 1 , E 2 , as already mentioned, on the output line 32 'of the control logic F, the digital signal "0". Consequently, "low" potential reaches the gate terminal of the potential transistor T 8 again and blocks it. Via the corresponding control line 35 'then "high" potential reaches the gate terminals of the two switching transistors T 5 , T 6 , whereby both transistors become conductive. The transistor T 5 , although it is closed on, is operated in the linear region because its gate potential is positive with respect to its source. Thus, in the event of a possible occupancy of E 2, a current flows through the linear resistance of transistors T 5 and T 6 . The "high" potential conducted via the voltage divider resistors 38 'to the gate terminal of the shunt transistor T 7 causes a blocking because the shunt transistor becomes conductive only at a negative potential with respect to its source. The Zener diodes 33 'and 57 ' serve to limit the voltage between the gate-source connections. An incoming call stream can reach the associated telephone set E 2 unhindered by the switch D 2 . The quiescent current consumption of switch D 2 , similar to D1, is approx. 7 µA.

If the other device E 1 is in the busy state, then, as already mentioned, the output line 32 'receives the digital signal "1", which results in a "high" potential at the gate connection of the potential transistor T 8 . The potential transistor T 8 conducts. The gate connections of the two switching transistors T 5 , T 6 then, like the shunt transistor T 7, receive a "low" potential. The switching transistor T 6 blocks and the shunt transistor T 7 conducts. The switch D 2 is consequently in the off position and its telephone set E 2 is switched off.

In the case of a reverse polarity connection line, the previously reversely operated switching transistor T 5 has the correct polarity and blocks in the idle state because negative potential reaches its gate terminal via the resistor 43 '. T 8 is then operated in reverse, but diode 51 impedes current flow. This prevents "high" potential from reaching the gate of the switching transistor T 5 , which would then make it conductive. If the polarity is reversed, the shunt transistor T 7 is in reverse operation, but this has no effect because it is connected in series with the two switching transistors T 5 , T 6 , of which, as already mentioned, the one switching transistor T 5 is blocked . A current flow through the switch D 2 is not possible. This means that if the polarity is reversed, the telephone set E 2 cannot go into busy state; an incoming call cannot be signaled.

If the switching device according to the invention is operated with more than two telephone sets E 1 , E 2 , these are equipped with switches of the present type D 2 , the switch lines 41 ', 42 ' are linked in the manner described with the input lines 10 , 11 . The w-wires belonging to these other telephones are again input lines for a correspondingly modified control logic F , which works in the manner shown in the table above, only with the difference that now also a number of output lines corresponding to the number of telephones 32 'is present, which are connected in the manner shown in FIG. 3 with such further switches D 2 .

• 10 input line 11 input line 12 voltage regulator 13 supply line for F 14 diode 15 resistor 16 resistor 17 protective diode 18 protective capacitor 19 Zener diode in B 20 sensor input in B 21 high-resistance voltage divider 22, 22 ′ resistor in F 23 protective diode in B 24, 24 ′ Fork switch from E 1 , E 2 25, 25 ′ potential resistor 26, 26 ′ potential resistor 27, 27 ′ protective diode from F 28, 28 ′ capacitor 29, 29 ′ protective diode 30, 30 ′ input line from F 31 flip-flop circuit from F 32 , 32 ′ output line from F 33, 33 ′ Zener diode from D 1 , D 2 34 Zener diode from D 1 35, 35 ′ line in D 1 , D 2 36, 36 ′ voltage divider resistor in D 1 , D 2 37, 37 ′ voltage divider resistor in D 1 , D 2 38, 38 ′ voltage divider resistor in D 1 , D 2 39 - 40 protective resistor in D 1 41, 41 ′ switch line in D 1 , D 2 42, 42 ′ switch line in D 1 , D 2 43, 43 ′ series resistor in D 1 , D 2 44, 44 ′ resistor in D 1 , D 2 45 output line from 46 46 current source in B 4 7, 47 ' alarm clock in E 1 , E 2 48, 48' capacitor in E 1 , E 2 49, 49 ' branch line in F 50, 50' resistors in D 1 , D 2 51 diode in D 2 52, 52 ' connection point in F 53 varistor in A 54 surge limiter 55 NAND gates 56, 56 ′ continuation of switch line 41, 41 ′ 57 ′ Zener diode A protective circuit B power supply C 1 charging capacitor C 2 auxiliary charging capacitor D 1 , D 2 switch E 1 , E 2 telephone set F control logic La, Lb core of the connecting line M ground potential Z, Z ' apparatus impedance in busy condition T l switching transistor in D 1 T 2 shunt transistor in D 1 T 3 shunt transistor in D 1 T 4 potential transistor in D 1 T 5 in D 2 switching transistor T 6 in D 2 switching transistor T 7 shunt transistor in D 2 T 8 potential transistor in D 2 T 9 N-channel MOSFET transistor, depletion

Claims (6)

1. switching means for the selective connection of one of several telephone sets (E 1; E 2) to a common connecting line (La, Lb) on a front of each apparatus; associated switches (E 1 E 2) (D 1; D 2),
with a control assigned to the switches ( D 1 ; D 2 ), which is connected to the w-wires of the apparatus ( E 1 ; E 2 ) and to the switch-on position of the respective fork switch ( 24 ; 14 ′) in the associated apparatus (idle state) appeals to
marked by
a digitally operating control logic ( F ) with an input line ( 30 ; 30 ') coming from the fork switch ( 24 ; 24 ') of each apparatus ( E 1 ; E 2 ) and with output lines ( 32 leading to each switch ( D 1 ; D 2 ) ; 32 ′),
wherein the control logic ( F ) from a via the connection line (La, Lb) powered power supply ( B ) be operated and not only the switch-on position (idle state of the apparatus E 1 , E 2 ), but also on the switch-off position (document state of the Apparatus E 1 ; E 2 ) the fork switch ( 24 ; 24 ') responds,
by its output lines ( 32 ; 32 ') at rest all devices ( E 1 ; E 2 ) have a digital signal ("0"), but in the busy state of a device ( E 2 or E 1 ) only the associated output line ( 32 'or 32 ) maintains this digital signal ("0"), while the output lines ( 32 or 32 ') assigned to all the other devices in the idle state ( E 1 or E 2 ) assign the other digital signal ("1") preserved, this position of the digital signals ("0", "1") being retained, even if one or more other devices ( E 1 or E 2 ) change to the document state,
that in the switch line ( 41 ; 41 ′) connected to the wire (La) of the connecting line
in the first switch ( D 1 ), as a switching transistor ( T 1 ), only an N-channel MOSFET transistor of the enhancement type (enhancement) is connected,
but for all other switches ((D2) two such switching transistors ( T 5 , T 6 ) are connected in series, of which one switching transistor ( T 5 ) is operated in reverse,
that in each switch ( D 1 , D 2 ) between the switch lines connected to the two wires (La, Lb) of the connecting line ( 41 , 42 or 41 ', 42 ') via a series resistor ( 43 or 43 '), as Potential transistor ( T 4 or T 8 ), another N-channel MOSFET transistor of the enhancement type (enhancement) is arranged,
which determines ( 35; 35 ' ) the gate potentials of the switching transistors ( T 1 or T 5 , T 6 ) located in this switch ( D 1 ; D 2 ) and its gate connection with the associated output line ( 32 ; 32 ') the control logic ( F ) is connected,
and that, with the exception of the first switch ( D 1 ), a diode ( 51 ) is connected to the drain of the potential transistor ( T 8 ). 2. Switching device according to claim 1, characterized in that between the connection lines connected to the two wires (La, Lb) of the connection line ( 56 , 42 )
at the first switch ( D 1 ), as shunt transistor ( T 2 , T 3 ), two P-channel MOSFET transistors of the enhancement type (enhancement) are connected in series, one of which (T 3 ) is operated in reverse,
but with all other switches ( D 2 ) only such a shunt transistor ( T 7 ) is provided,
and in that the respective switch; potential transistor located (T 4, T 8) at the same time, the gate potential or the associated shunt transistors (T 2, T 3 or T 7) is determined (D 1 2 D) of the. 3. Switching device according to claim 1 or 2, characterized in
that the power supply comprises a current source ( 46 ), which is fed via a diode ( 14 ) from the one wire (Lb) of the connecting line, from an N-channel MOSFET transistor of the depletion type ( T 9 ),
and the current source ( 46 ) is connected via resistors ( 15 , 16 ) to an IC acting as a voltage regulator ( 12 ) and feeds an input-side charging capacitor ( C 1 ),
which is connected ( 11 ) to the other wire (La) of the connecting line. 4. Switching device according to claim 3, characterized in that
that between the output ( 13 ) of the voltage regulator ( 12 ) and the other wire (La) of the connecting line, an auxiliary charging capacitor ( C 2 ) is connected and
a protective diode ( 23 ) is arranged in parallel with the auxiliary charging capacitor ( C 2 ). 5. Switching device according to one or more of claims 1 to 4, characterized in that for two telephones ( E 1 ; E 2 ) put out control logic ( F ) from a flip-flop circuit ( 31 ) with four mirror-image-linked NAND -Gattern ( 55 ) exists. 6. Switching device according to claim 5, characterized in that the flip-flop circuit ( 31 ) consists of a CMOS IC.