DE2606983C2 - Semiconductor component made from integrated transistors, in particular for control devices of telephone exchange systems - Google Patents

Description

7 8

according to the building block. So it is advantageous to F i g. 14 is an arrangement according to FIG. 13th

that in the case of a module, the work table belonging to at least four pairs;

from control inputs and signal outputs has a F i g. 15 and 16 show examples of the application

of further reversals via the other signal blocks for the transmission of signals to one

inputs with the help of specified input signals 5 multi-core busbar.

The module shown schematically in Fig.l has a certain predetermined signal value of the four control inputs £ 1, £ 2, £ 3 and £ 4, the four output signals appear at the same time at all signal outputs, that also one of further signal outputs A1, A1, A3 and A4, the four signal reversals with the help of other predetermined inputs In /, Pu, CEl and CEl and the reversing gear signals causes this particular pre-input Um. Furthermore, there are connections for the level signal value of output signals only to ground and for the operating voltage + t / l and -Ul a signal output occurs if the associated one is provided. A certain signal value also depends on these operating voltages, the control input and the sizes of the binary control signal supplied via the signal outputs, while, on the other hand, dependent on the signal voltages UL and UH . Has z. B. the other signal value of the relevant signal output 15 the operating voltage -1/2 the size -15 V and which is blocked with high resistance, and that finally one of the operating voltage + t / l the size + 15V, further reversals can cause all at the same time the signal voltages UL = -15V and UH = signal outputs are blocked with high resistance, which only receive + 15V. If, on the other hand, one has the operation with the aid of a single remaining control voltage + t / l = OV, then one obtains the signal value of the control ao voltage UH = OV lying in the signal path. One can also bring about a sub-signal. As will be explained later, different supply of modules with operation, through the first mentioned additional voltages when combining several modules control with relay couplers made of stick-on relays, the same arrangement can be effected for a particularly common reset of the stick-on relays. Exploit appropriate operation, such as B. by the further reversal 25 mentioned afterwards based on the F ig. 7 and 8, it can be ensured that the latching relays each return. The signals that are applied to the inputs that are to be placed on a certain column can have signal voltages such that line or a certain row line - by the voltage -15V the signal value L and are closed. The last specified by the voltage OV of the signal value // formed further reversal can finally block 30. The above operating information can also be found in line no. 25 of the work table Fig. 2. be effected. All these processes are still stated. There it is also stated that the character x, which is explained in more detail using application examples, is also contained in other lines of this work table. is, means that it is for the at a signal output

The invention and the associated electrical condition does not matter,

Examples and application examples are given below in the Signahvert L at the point marked with χ

explained in more detail with reference to several figures. or the signal value H is applied.

In the work table F i g. 2 are in lines I.

Fig.l a scheme for inputs and outputs up to 24 the relationships between the signal values L and other connections of a module with example 40 and H for the inputs of a module and the four pairs of control inputs and signal-signal voltages UL and UH for the signal outputs ; went indicated. Besides, there is still

F i g. 2 is a work table that shows the relationships when the signal outputs become high-resistance

between the signal values at the inputs and the are blocked, namely by the sign Ω. Since the

Signal voltages at the outputs of a 45 control inputs £ 1 ... £ 4 the signal outputs

Approximate example for the block Al ... A4 according to the invention are individually assigned, could in

indicates; of Table F i g. 2 the columns Ei and Ai set up

Fig. 3 and 4 show how such execution are, which the signals at the control inputs and

record examples with the aid of logic elements on the signal outputs and where the

can be built; the 50 letters / as a running index for the digits 1 ... A

Fig. 5 to 16 relate to application examples to be viewed. Which digits each for the book invention. Of which point rods / 'come into question, is denoted by /

Fig. 5 and 6, arrangements for controlling the nth column of the working table are given. In the

Neutral relays or latching relays with the help of a column Um, CEl, CEl, Pu, Inf are those at the

individual building block. 55 inputs with the same designation, if applicable

F i g. 7 and 8 show examples of how such signals are detected.

Relays each controlled with the help of two modules. Lines 1 to 16 contain the operating cases

can be; where the signal outputs AI ... A4 via di <

Fig. 9 and 10 show arrangements in which control inputs £ 1 ... £ 4 are individually tailored

several relays can be controlled together. 60 of the control signals with the signal values H and i

Fig. 11 and 12 show examples of how the high-resistance lockable or low-resistance electrical

Koppclrclais of relay couplers are each adjustable with the help of see state, with the signal

The signal voltages UL or UH aul can be controlled by several modules

(Matrix control); to step. These signal voltages are based on this

Fig. 13 shows the use of modules for 65 which input signal to the respectively assigned

Control of a relay coupler that has more line signal input. The signal input is In

Lines has as a single component signal from signal output A 1, signal input Pi / dei

has gears; Signal output A 2, the signal input C £ 2 the Signa

'10

output A3 and the signal input CEl the signal from line 21 still shows that under the same A4 assigned. The operating conditions relating to the signal output A 1 with the aid of an input signal Operation is shown in lines 1 to 4, since the index ι = - ■ 1 for this with the signal value L at one of the signal inputs lines, see the column / '. From each of the associated signal output high impedance these lines it can be seen that the signal outputs 5 is blocked, so that, therefore, then there is high impedance at the signal locked response A 1 when the input control signal applied //// is not weitergebbar, entry £ 1 a signal with the signal value L is applied, which is why the book is in this line in the column / «/. This is independent of whether χ is entered on the assigned members.

Signal input InJ a signal with the signal value L With the help of the building block described above or H lies. If, on the other hand, there is an xo at the control input El , the signals fed to the signal inputs can be a signal with the signal value H, then the signal passed on at the signal input InJ that is passed on to the assigned signal outputs, this passing on via the control input signal values L or H to Signal output A 1 can be further controlled. In addition, it can be given with its help , since the signal voltage accordingly occurs there by utilizing the reversing input Um the UL or UH . The signals pending at the other signal inputs at the signal input InJ for an incoming CE1, CE1 and PU have signals pending or are distributed to a plurality of signal outputs. These do not have any influence on this, as the different working methods in this regard already make possible, details .v in lines 1 ... 4 emerge. Reversing input Um has a reversing signal with the turn. So he can z. B. to pass signals signal value L to lie. Through this Signahvcrt 20 can be used on a multi-core busbar , the above-described mode of operation of the building is set with the help of the high-resistance blockability of its stones. In lines 5 ... 8 is the output feedback can be avoided , speaking mode of operation for the signal output Al if the module is not activated. In addition , the control input El can be specified. In this case, it can be passed on to signal output A 2 , for example for distributing a specific signal present at signal input Pu, in a corresponding signal in several individual signals at its signal outputs. connected function relays can be used. A particularly great applicability at the signal inputs CE1, CE1 and InJ results when the input signals present on the signal take into account that further reversals of the output A 2 have no effect here. In a corresponding digital mode of operation by changing the manner in which the signal inputs Pu, CEl and CEl are located on the operation of the signal output A3 3 °, no output signals can be brought about at the signal inputs CEl, Pu and InJ. The resulting influence, see lines 9 ... 12, and the operating modes are also included in the work of the signal output AA , the signal inputs table F i g. 2 captured.

CEl, Pu and / n / no influence, see lines 13 ... 16. If, for example, the signal inputs Pu, CEl and To signal output A 3 are the signal at signal input CEl 35 CEl with the signal values // and to signal output A4 If that is the case, the result is that the signal voltage UL can be passed on to the signal at the signal input CE1 at the same time, the signal outputs A1 ... A4, specifically when the associated control occurs. The signal output relating to the signal output at the signal input InJ input by a signal with the signal value H and the signals present at the control inputs have no influence on its low-resistance 40 (see FIG. 2, line 24). With the help state is set. this mode of operation can, for. B. to the signal off via the reversing input Um is the digital went individually connected relays at the same time in the operating mode can be switched to the same operating state by a binary reversing signal. Should this be taxable. If this reversing signal has the signal value H instead of the signal voltage UL and thus the associated value L, the input signal at the predetermined signal value L of output signals is only a signal output, z. B. A 1, occur when using the one or more control associated control input, z. B. El, also eir inputs supplied control signal for each train-specific signal value, z. B. the signal value H, can be passed on from the ordered signal output. In this case, the binary control signal is connected to, while, on the other hand, through the relevant control input, the control signal has the other signal value /. the relevant signal output signal value II. Is blocked with high resistance at the other signal inputs Pu, gang, the lines 19 and 20 of the work table F i g in CE1 and CE1 at the same time have certain predetermined lines. 2 recorded input signals with the signal values /., / ■ / and II to use for operating modes. For delivery de lie. These operating cases are recorded in lines 22 and 23 signal voltage UL on one or more signals. There it is initially stated that the outputs at 55 have an input reversing input UM at the signal output CE1, the reversing signal with the signal with the signal value //, at the signal input CE '. Signal value // has to be. Input signals with an input signal with the signal value L and at signal values // also have an input signal with the signal CEl and CEl at the signal inputs Sigiuileingang Pu . At the signal crossing Pu has a value // to lie. Should the signal voltage UL ζ. Β on the other hand, an input signal with the signal value L to 60 is at the signal outputs A 1 and A3 , so are hi. The information in the columns Ei and Ai apply to the control inputs £ 1 and £ 3 a tax for any associated signal inputs and signal with the signal value II (see line 20 signal outputs, as in the column / by the book is present These control inputs are instead ei. Therefore, the signal lying on the previous control signal with the signal value L, so sin certain signal input In j can also use the signal outputs -41 and A3 to the power of signal values L and / - / to an or to several ohmig blocked (see line 19). The input signals at the signal input in signal voltages UL and Uli have no influence on any of the outputs, 4 1 ... / 44 in the form of the operating cases , such as i

on lines 19 and 20 is indicated by the letters χ .

It is also possible at the same time, all signal outputs Al ... A 4 are high impedance locked, namely aHein with the aid of a lying at the control input C £ l input signal with the signal value L. This operation case is shown in line 17 of the work table F i g. 2 captured. From the columns / and Ai it can be seen that all outputs are blocked with high resistance at the same time. The signals at the signal inputs CE2, Pu, Inf and at the control inputs £ 1 ... EA have no influence on this, which can be seen from the letter χ entered in the associated columns. The signal input CEl can therefore be used to enable or disable the module. The release with the aid of an input signal with the signal value H at the signal input CE1 can still be restricted (see line 18) in that input signals with the signal value L are applied to the signal inputs CE1 and Pm. For all reversals of the digital mode of operation due to changes in input signals that are applied to signal inputs, a reversing signal with the signal value H must be present at the reversing input (see lines 17 to 24).

In FIG. 3 shows the circuit of an exemplary embodiment for a module which has the functions in the work table F i g. 2 has the working methods shown. Here, each signal output is preceded by a digital conversion circuit for converting two binary signals present there at the same time into the intended output signals with signal voltages UH and UL and into the high-resistance blocking of signal outputs. The digital conversion circuit from the amplifier Kl, the UN Οίο elements KH and KIl and the NOT element M are connected upstream of the signal output A 1. This conversion circuit has the conversion inputs / 1 and £ 12. The other three conversion circuits accordingly have the conversion inputs / 2, £ 21. / 3, £ 31, IA and £ 41. These conversion inputs are connected to inputs £ 1 ... £ 4, Ji: f. CEI, CEl, Pu and Um of the module via several logic elements, which include AND elements, OR elements and NOT elements. These links can be constructed in a manner known per se. Logic functions according to the following equations occur between the inputs of the block and the conversion inputs, in which the binary signals have the same designations as the associated inputs:

IA = C £ l · C £ 2 ■ Um · Inf- Pu · EA V Um · CEl
/ 3 = C £ l · C £ 2 · Um ■ Inf ■ Fu · £ 3 V Vm- CEl Il = C £ l ■ C £ 2 ■ Um ■ Inf · Pit ■ El V Vni · Pu
/ 1 = C £ l ■ C £ 2 · Um ■ Inf · P ~ ii ■ El V ÜTn ■ Inf

Signal 2

£ 41 = C £ l · C £ 2 ■ By ■ (£ 4 V Pu) V £ 4 · (Around VCEl- Pu) £ 31 = C £ l · C £ 2 ■ By ■ (£ 3 V Ph) V £ 3 · (him VC £ l - Pu) Eil = C £ l · C £ 2 · Um ■ {El V Pi /) V £ 2 · (Um VC £ l · Pu) £ 11 = C £ l · C £ 2 · Um ■ (£ 1 V Pk) V £ 1 · (Um V CEX · Pu)

Signal 1

Signal 3

The conversion circuits are all set up in the same way. In the conversion circuit upstream of the signal output A 1, the AND element KIl is connected directly to the two conversion inputs / 1 and £ 11 and the AND element KIl is connected via the NOT element Nl . The inputs to the two outputs of the AND gates kiii and Kil - + and of the latchable connected Kl amplifier having the output signal Al. The amplifier Kl can be controlled via the AND gates KH and A'12 according to the following work table:

exit exit exit AND element AND element amplifier With without - signal output NOT member NOT member - ■ - - input 4 entrance amplifier amplifier Signal value H Signal word L signal voltage UL Signal value /. Signal value // signal voltage VIl Signal value L Signal word /. high resistance locked

The combination of the signal values H and // does not occur because of the presence of the NOT element.

The lockable amplifier can, for. B. be built with the help of known transmission gates (see z. B. McMOS Handbook, Mototrola Semiconductors, First Edition, October 1973, pages 3.9 to 3.11). In the case of the FIG. 3 shown embodiment are the signal inputs Inf, Pu, Cl'2, CEl, the control inputs £ 1 ... £ 4 and the Ui control input Um the Schmitt trigger ST ;.:

tet. They are used in well-known WVi-f Keep interference pulses away from the module.

In FIG. 4 is a slightly different circuit i'ur such a module is shown. Here the 1 in gears of the block are also Schmitt trigger S /

6a upstream. However, this Schmitt trigger each have an output with negation effect, which is indicated there by a negation point most ... / 4 and £ 11 ... £ 41 lying arrangement of logic gates is between these outputs with negation effect and Umsetzeingängen Il differently than in the case of the building block according to FIG. 3. It contains OR elements, such as the OR element Λ- / 1 and AND elements, each with an input without

13 14

Negation effect and an input with negation can be operated, which initially each have the effect, to which the AND element UX belongs. The input with negation effect is supplied by a reduced holding current in each case. The block Bl marked a negation point. In addition, the operating voltage + 1/11 has the voltage - {- 15 V, it still contains NOT elements like the NOT-5 and as the operating voltage -i / 21 the voltage element Nm. The signal outputs Al ... A4 pros -15 V. The block Bl, however, has as Betriebsge:; clialteten conversion circuits are voltage just up - | - U 12, the voltage 0V and as operating built as the building block according to F i g . 3. Between voltage - (/ 22 the voltage -15 V. The Andean signal inputs Inf, Pu, CEl, CEX, the control speech winding / a neutral relay is at the inputs £ 1 ... EA and the reversing input Um io signal output AW of the block 51 and connected to the one hand and the Umsetzeingängen ... IX / 4 and signal output .412 of the block Bl. EW ... £ "41 are signals according to the already pre between these two Signalausgängcn can encrypt with standing specified logic functions Help the signal voltage UH at signal output A 11. On lines 1, 2 and 3, the signal voltage UL and the signal voltage UL at module B1 have the following signals with the same designation, which also contain an excitation voltage of 30 V for this claim in the equations already given with development /. If the output is specified: A 12 is blocked with high resistance and at output Λ22,

to which the winding II of the relay is still connected

Signal 1 = CEX ■ CEl- Um is, the signal voltage UH = 0 V is set.

Signal ~> - Signal 1 · Pu Inf ^{20 licgt re 'nenscna' do} g ^{of the two} relay windings

_ * 1 and II at an excitation voltage of 15 V. The

Signal 3 = Um V CEX ■ Pu compared to the previous operating case

Much less flowing current can then be used

Based on the F i g. 3 and 4 are used when the relay is used. The winding II has been described for this purpose, as the invention 25 can also be replaced by a resistor. According to the circuit-wise module, for example, a holding contact can be built up in this circuit technique. The neutral relay used for this purpose is not required, logic elements and amplifiers can in per se. In the FIG. 8 shows another application example of known integration technology for semiconductors, each showing how two modules are used for this in one and the same module, e.g. B. from bipolar 30, neutral relays and latching relay transistors are formed. To control such a building block. However, MOS transistors can also be included at the signal output A'll of the module. BX and to the signal output Λ 12 of the block Bl with the help of F i g. 5 and 6 are examples of a latching relay is connected, and are shown on the signal connection of the neutral relay and latching relay output / 131 of the module BX and to the Signalan Signalausgangsc of a module. The 35 output / 132 of the block Bl is a neutral relay in F i g. 5 is connected as an operating voltage. As the operating voltage UlX of the construction ■! i / l the voltage - | -15 V and as the operating voltage block BX and -Uli of the block Bl is the voltage

- Ul the voltage -15 V applied. This applied at -15 volts. If the consequence for the two modules is that the signal voltage + (/ 11 and + (/ 12 uses the voltage UH = +15 V and the signal voltage UL 40 voltage +15 V at the signal outputs), then the relay stands for Er -

- —15 V are available. A voltage of 30 V can therefore be used. Neutral relays controlled via the signal outputs Used as operating voltage + (/ Il and +1/12 die If the operating voltage 0 V is applied to their free connections, the excitation voltage is used Voltage I 15 V or the operating voltage -15 V to the voltage 15 V is available.

is laid. Such neutral relays are to the Sign.'l- <5 The above circuit examples show that

outputs Al and A3 connected individually. On which the blocks operate in different ways

Signal output A 1 is connected to a latching relay that can be used by relays, whereby different

whose free connection is connected to ground. With the help of borrowed operating conditions can be achieved. It is

the electrical adjustable at a signal output each with the help of input signals and control

States Uh - + 15 V, UL = -15 V and high- 50 signals at the relevant signal outputs

This adhesion mechanism can be ohmically blocked in the one suitable signal voltage UH, UL or the high-impedance one

or other direction can be energized to set the lock state. Are in one and the same

and thus several relays connected to one and the same winding operated module, so they can

will. Here, latching relays with an exciter can be used independently of each other via the relevant

voltage of up to 15V can be controlled. The signal input assigned to 55 signal output and the

the signal outputs A1 and A3 connected to the newly assigned control input can be controlled.

Central relays can have an excitation voltage of up to In the F i g. 9 and 10 are application examples

Have 30 V. At the in F i g. 6 shown building block in which it is provided several on itself

the operating voltages + t / l = OV and -Ul module connected relays are to be controlled together

- - 15 V applied. The there at the signal output A 1 60 It can be a latching relay or a newly connected neutral relay, the free connection of which is a tral relay. In the F i g. 9 and 10 are connected to ground, an excitation voltage can therefore have an excitation voltage of up to 15 V individually connected to the signal outputs. The same excitation saving relay /? shown. The control inputs Et, El and E3 can also be connected to the signal output Al , which have the signal outputs AX, Al and A3 in building relays, at the free end of which —15 V 65 stone BX are assigned, are connected to one another. and they can jointly send the control signal EN]

In Fig. 7 an application example is shown in which are supplied. The signal outputs AX, A '* unc the neutral by means of two blocks relay and A3 associated signal inputs Inf, Pu

I '£ 2 are supplied individually with the input signals TV1, INI and / N3, which can therefore have different signal values. The devices connected to the Signaluisgiinge Al, Al and -4 3 relay R then .verden according simultaneously set the signal values of said input signals, when the control signal ENL is supplied with the signal value H. The reversing signal with the signal value L is present at the reversing input Um. This circuit technology has the advantage that the relays in question can all be set in one operation. However, an output voltage is also applied to those relays that do not have to change their operating status. The correct input signals for these relays must therefore also be created here. The relays to be set together can also be connected to different modules. So here z. B. the relays to be set according to the input signals IN 4, / W5 ... / JV / i-3, which are connected to the modules Bl, B2 ... Bk , can be set together with the aid of the setting signal EN2 . Independently of this, two relays connected to the BAr module can be set using the .ETTVAr setting signal.

In the case of the FIG. The application example shown in FIG. 10 is not fed the same control signal to a plurality of control inputs, but instead the same input signal is fed to a plurality of signal inputs together. In this way, the signal inputs Inf, Pu and CEl connected to one another are fed together with the input signal INI . This can have the signal value H or L. Accordingly, the devices connected to the associated signal outputs of Al, Al and A3 of the block Bl relay R can be set when the associated control inputs £ 1, £ 3 El and the control signals enl, ENL be supplied and £ JV3. It is possible to only energize those relays that are supposed to change their state. The setting signal must therefore assume the signal value H for these relays. Depending on the signal value of the input signal / Nl, the relevant latching relays are either attracted or thrown off. The reversing signal with the signal value L has to be at the reversing input Um of the block Bl. With the help of the control signals EN 4, ENS ..., the control inputs of the modules JSl, Bl ... can be supplied, additional latching relays connected to these modules can be set according to the input signal / JV 2. Combinations between all the tax types described above are also possible for one or more modules. In the case of module Bk , signals with the signal values H, H, H and L are present at the inputs Um, CEl, CEl and Ph. 2 specified operating cases are exploited. If at a control input, e.g. B. £ 1, there is a control signal with the signal value L , then the associated signal output is, ζ. B. Al, high resistance. If, on the other hand, a control signal with the signal value H is present at a control input, the input signal / JVA: present at the signal input Inf is transmitted to the associated signal output. Such operating cases are also described in connection with other application examples.

In Fig. 11 a relay coupler is shown from neutral relays, which has the row lines rl ... z4 and the column lines si ... s4 . At each crossing point between a row line and a column line, a relay with an upstream rectifier is connected, such as the rectifier G and the relay R, as indicated by the arrow pointing downwards to the left. The row lines zl ... z4 are connected to the signal outputs All ... A41 of the module ßl, while the column lines si ... s4 to the signal outputs A 12 ... A 42 of the

ίο modules Bl are connected. The signal inputs InfI, Pul, CEIl and C £ ll as well as the reversing input UmI of the module ßl are supplied here with signals that have signal values as shown in the work table F i g. 2 are given in line 23. It is therefore possible via the signal outputs All ... A41 row lines zl ... ζ 4 can be applied to signal voltage UH if control signals with the signal value H are fed to the respectively assigned control inputs £ 11 ... £ 41. If, instead, an input signal with the signal value L is fed to such a control input, the relevant signal output is blocked with high resistance. It is then namely in line 21 of the work table F i g. 2 specified operating case. With the help of the control signals Zl ... Z4 which can be fed to the control inputs £ 11 ... £ 41, the signal voltage UH can therefore be applied individually to the row lines zl ... z4 . In a corresponding manner, the signal voltage UL can be applied individually to the column lines si... S4. This is because input signals with signal values are applied to the signal inputs / n / 2, Pul, CEIl and C £ 12 and to the reversing input UmI of the module β2, which correspond to the in line 22 of the work table F i g. 2 correspond to the operating case specified.

As a result, the signal voltage UL can be set at the signal outputs All ... A41 of this module with the help of the control signals Sl ... S 4. If these control signals S1 ... S4 have the signal value H, then the signal voltage UL occurs at the signal outputs mentioned. If these control signals have the signal value L, the signal outputs are instead blocked with high resistance. So have z. If, for example, the control signals Zl and Sl have the signal value H, the relay connected at the intersection of the row line zl and the column line si is energized. The signal inputs C £ ll and C £ 12 are connected to one another at the circuit point MA. It was previously assumed that an input signal with the signal value H was also located there. If this input signal assumes the signal value L , the result in line 17 of the work table F i g. 2, that is, all outputs of module ßl and module ß2 are blocked with high resistance. The circuit point MA can therefore be used to enable or disable the control of the relay coupler, which can be controlled via the modules ß1 and ß2.

FIG. 12 shows an example of an application of modules for controlling a relay coupler made up of latching relays. As an additional control task compared to controlling a relay coupler with neutral relays, it is still necessary to reverse the direction of the current. For this purpose, the signal input Inf I of the block ßl and the signal input Inf 2 of the block Bl are used . These two signal inputs are connected via the NOT element Λ ', the input of which is supplied with the input signal / JV. Similar to a relay coupler, individual relays are connected from neutral relays.

709 651/365

controls. However, the row lines of the relay coupler each have two wires. The row guard zftie two wires zll and rl2. A latching relay is connected to such wires via differently polarized coupling rectifiers and to one column line each. So, that's the ReIa. : R connected via the two decoupling rectifiers G to the two wires; 21 and; 22 of the line wire r2. This enables the latching relay to be controlled by currents in different directions. The cores are each a time division of the block B 1 is connected individually to signal outputs .411 ... A 41, while the Spaltenle.tungen individually connected to the signal outputs AU ... ΑΛ the block Bl. The control signals for controlling relays are applied to control inputs £ 11 ... E41 of module 51, which are connected in pairs, and to control inputs E12 ... E41 of module B1 . The paired connection mentioned corresponds to the belonging together of the connected cores of row lines. To control the relay Λ, the control signal Z2 is applied to the control inputs £ 31 and £ 41 and the control signal S1, which is also required, is applied to the control input £ 12. The one shown in FIG. 12 relay shown, 5 coupler is similar to that in F 1 g. 11 g ^ezel 8 «using the control signals Zl, Zl and 51 ... i4 controllable. In this case, those in lines 21, -2, -J and 17 of the work table F i g. 2 specified operating cases. Compared to the control of the relay coupler according to Fig. That of the relay coupler Bfi according to Fig. 12 is supplemented by the fact that the bignai inputs Infl and In / 1 are supplied with input signals which have different signal values for attracting than for throwing off latch relays. The mutually connected signal inputs CEIl and CMZ can also be used here to enable or disable the control of the relay coupler.

B; i the application examples described above for relay couplers, the number of row lines and column lines was given by the number of the signal outputs of the blocks used. These blocks can now also be used for coarser Relay couplers are used that have, for example, more row lines than a single component Has signal outputs. It s, nd then to control. For the row lines in the same way as several modules instead of a building block. This technique can also be modified (see Fig. 13). there are those belonging to such a relay coupler like this

Hold-open relay Λ1, Rl ■ ■ ■ together with the required building blocks BU ... Bpk are shown. This relay coupler has the row line zl, z2, r3 r4. . . zh and the column lines s \. .. sp. So many building lines are provided here per column line that all relays assigned to a column line can be individually connected to a signal output of one of these rough contacts. So for the column line 5I de Baustem, BlI ... ÄH- are provided, to whose S-gnalausgange ^ 1, AXA 3. ^ 4 ... the relays RX are connected. The control signals Zl. Z2. . . Zn. De the control inputs of the relevant modules BU, BIl ... / toil added to wcrucn, ^ etc., ...

■ ineansen of modules can be created that belong to the column line. Here z. B. the control signal 51 via the column line * 1 to the control signal j CElIk of the modules 511

^SLGN Sran5egf Mit'Hilfe an input signal, the m "t ⁸ eina ^g Direction associated inputs relevant

- “ί ,, ΠΙ of all modules BIl ... Bpk zuge -SSrf w'rd, the current direction in the latching relay can be controlled. This process is carried out in the same way as in FIG. 12 shown Haftrela.skoppler Z st-inde brought. The input signal MA, which the sand? connected signal inputs C £ lll ... Sl blocks BU ... Bpk can be fed, via which you can set the signal outputs Al ... high resistance blockable or low resistance, can also be used here to make the control of the blocks effective and thus to enable or disable the control of the Haftrc aiskopp-Ks. A control signal with the signal value // is sent to the reversing inputs tA «ll ... of all modules. are. The input.gna is connected to the signal inputs Λ, Η .. aSer blocks BIl ... Bpk! PU can be supplied, with the help of which the latching relay e.ner can be dropped from a cell line determined by a control signal and a column line determined by a control signal. Have z. B at the same time d, e control SaIe MA Sl and Zl and the input signal PU the signal value H, the signal voltage UL is fed to the relay controllable via the row line -1 and the relay controllable via the column line ^ l so that these relays are dropped together . All of these processes are dealt with here alone. Ai application of building blocks brought about according to the invention. No special decoupling rectifiers connected upstream of the relay windings are required here. In a corresponding modification, neutral relays can also be controlled instead of the latching relay. In addition, electronic crosspoint contacts can also be controlled in the manner indicated. ,,., ..,.

In the work table F ι g. 14 are he i according F s de various operating cases for the relay Kopp. 13 detects. The columns of this table show the control signals and input signals and, immediately below, the respective module inputs that are influenced by them. In lines 1 to 9, see the respective effective signal values of these signals. If the input signal MA has the signal value L , the control of the relay coupler is blocked (see line 1). The signal outputs are blocked with high resistance (see column A). The control signals 51 un Zl and the input signals PU un i /.VF therefore have no influence, which is indicated in this Ze.le with the aid of the letter .r. If the input signal MA the signal value H has, however, you are not all high resistance types blocked signal outputs in each case. As can be seen from line 2 of the work table · Fig . 14 7ü. are then only the shark! relay inactive, the un. ■ s are connected to which signals mi ■. are fed. Becomes one of the lines with the signal value / ■ / trains

the at d.e column wise ve

bound concerned

19 20

If the signal value is H, the settings of coupling relays in specially controlled latching relays via a row line can easily be avoided in the signal voltage UL (see DT-OS explains why they are thrown off (see line 4). 23 48 453, especially p. 1 to 4 and DT-PS What signal value the input signal INF has, 17 62 055). The dropping of relays in this feed does not matter. If this is related to a column line, it is also referred to as cleaning. If this input signal carries the signal value H, the relevant abbreviations therefore remain in column A, the latching relays in work table F i g that can be controlled via this column line. 14 used, which refer to the inactive in each case, since the signal outputs to which they are connected and achieved line-by-line function are used,
are, are blocked with high resistance as long as the input As already indicated, a module example signal PU can have the signal value L (see line 5). If, on the other hand, the io also has the signal value H for the forwarding of input signals, the input signal PU , the signal inputs En /, Pu, CEl which are present on the relevant column line control and C £ l are used. When passing on such compatible latching relays thrown off (see line 6), since they output signals on a multi-core busbar can be connected to the signal voltage UL . Even if the transfer is then controlled by control signals, the last two operating cases will be played, the z. B. at interconnected control, the signal value of the input signal INF does not matter. inputs are created.

The operating cases are recorded in lines 7 and 8. As an example for this application, a specific latching relay is shown in FIG. The dropping bus with four cores can be supplied with signals. or response is determined by the signal value of the input 20 These are signals that each determine four bits of the input signal INF. If this signal value is L, then include. Such a signal INF is sent to the signal if the latching relay in question is dropped, the inputs Inf, Pu, CEl and C £ l are applied. Its signal value is H, so it is made to attract. The relay is passed on with the help of the control signal ENl, which acts on the relevant latching relay, which is applied to the interconnected control signal voltage UL and the 25 inputs £ 1 ... £ 4 to attract it. Applied to the reversing signal voltage UH . The input Um has a reversing signal with the input signal PU to have the signal value L. To lie at the signal value L. Signals with operating mode are connected to one and the same collective row line and to the column line via which the rail can be used to control a plurality of such modules in this relay in question. The block is to be at the signal value H. Is z. B. at the signal 30 can also be used to convert unipolar signals output Al of the block ßll connected adhesive to bipolar signals. An example of this is to be controlled in relay ßl, so have the control signal Zl F i g. 16 shown. The unipolar signal INF with two and the input signal Sl the signal value H at the same time Biis is to have the signal inputs Inf and CEl directly at the same time. Has applied the input signal at the same time. Via the NOT elements W , the signal value H is also PU , so all of the lines are still applied to the signal inputs Pi / and C £ 1. line zl and the column line si controllable adhesive The transmission of the applied signal INF is thrown off with relays, as caused by the control signal £ N1 from line 9 of the work table, which is sent to the FIG. 14 emerges. Control inputs £ 1 ... £ 4 can be created in the same way. The most also have a different combination of each Umsteuereingang order lying reversal signal of a row line and a column line control signal value 40 L. has dropped When passing of the unipolar cash relays simultaneously. The signal / »/ occurs on the four cores of the busbar. Possibility of using the modules in a relay bus to generate a bipolar signal. Each bit of the original coupler stick-on relay can now be represented by two bits , is very beneficial as each technique has different values. The busbar bus shown lately for the operation of relay couplers 45, FIG. 16, can also have gained great importance over a period of time, since it means that faulty modules are supplied with signals of this type

In addition 11 sheets of drawings

Claims (14)

Patent claims: / 4 == C £ l · CEl ■ Um · Inf ■ Pu · £ 4 V Um- CEl
/ 3 == C £ l · CEl ■ Um · Inf ■ Fu ■ £ 3 \ J TJm ■ CEl Il - ■ = CEl ■ CEl ■ Um -Inf ■ Fi- El V Um · Pu Il == C £ l · CEl ■ Um ■ Inf -Fu-El \ l ~ Um- Inf £ 411 = C £ l ■ CEl - Um ■ (E4 V Pu) V E4 ■ (Um \ J CEl ■ Pu) £ 311 = C £ l · CEl · Um ■ (£ 3 V -P ") V E3 ■ ( Um \ J C £ i ·· Pu) Eil = CEl- CEl ■ Um - (El \ / Pu) \ / El ■ (Um \ l CEl ■ Pu) £ 11 = CEl ■ CEl ■ Um ■ (El \ J Pu ) \ J El ■ (Um \ J CEl ■ Pu) 4. Module according to claim 3, characterized in that an AND element (KU) directly and an AND element (KU) via a NOT element (Nl) to the two conversion inputs (e.g. II, Eil) of a conversion circuit is connected that to the two outputs of the AND gates (JfIl, KU) the inputs (-, +) of a blockable amplifier (Yl) are connected to the relevant Signal output (A)) has that the amplifier can be controlled via the AND gates (ATlI, K 12) according to the following work table: exit exit exit AND element AND element amplifier with NOT member without = Signalai jgang NOT member = - input = + Input amplifier amplifier Signal value H
Signal value L
Signal value L Signal value L
Signal value H
Signal value L Signal voltage UL Signal voltage UH high resistance
locked 5. Module according to one of the preceding claims, characterized in that the signal inputs (/ n /, Pu, CE2, CEl), the control inputs (El ... EA) and the reversing input (Um) Schmitt trigger are connected upstream. 6. Block according to one of the preceding claims, characterized in that it is bipolar Contains transistors. 7. Building block according to claim 6, characterized in that that it contains MOS transistors. 8. Application of blocks according to one of the preceding claims, characterized in that the signal outputs (Al ... A4) latching relays (R) are connected, which are caused by different output signal voltages (UL, UH) to lean or to drop that to the signal inputs (Inf, Pu, CEl, CEV) individual input signals (INI ... IN4) to determine the operating status of the latching relays (R) are applied and that the control inputs (e.g. £ 1 ... £ 3) for such relays, which are to be confirmed jointly by a control signal (ENl) are connected (FIG. 9). 9. Application of modules according to one of claims 1 to 7, characterized in that the signal outputs (Al ... A4) latching relays (R) are connected, which are caused to attract or throw off by different output signal voltages (UL, UH) that the control inputs (EI ... E4) individually control signals (ENl. ..EN4) for actuating the latching relays (R) are applied and that those signal inputs (e.g. Inf, Pu, CE2) are connected that are Relays are assigned for which the same operating state is determined jointly by an input signal (Fig. 10). 10. Use of building blocks according to one of claims 1 to 7, characterized in that the signal outputs (A 11 ... A 41) of a first block (51) the row lines (ZL .. .z4) and (at the signal outputs All .. .Α4Ϊ) of a second block (52) the column lines (sl ... i4) are connected a relay coupler from the neutral relay (R), for energizing a relay (R) those signal outputs: (eg. A 41, and Λ12), to which the row line (z4) belonging to the relay (R) and the associated column line (il) are connected, are controlled with low resistance, so that the reversing inputs (UmI; UmI) and the The relevant signal inputs (InfI, Pul, CEIl; Inf2, Pul, CEIl) output signal voltages deliverable via signal outputs (Λ41 with UH; A12 with UL) become effective, so that those signal inputs (C £ ll, C £ 12) of the two modules (Sl, Bl), via which all signal outputs (A 11 .. ./142) can each be set to high-resistance or low-resistance at the same time, are used to make the control of the two modules effective, and that for a relay coupler that has more row lines and / or column lines has, as each component has signal outputs, more than two components are used accordingly (Fig. 11). 11. Application of blocks according to one of claims 1 to 7, characterized in that at two signal outputs (All, All; Λ31, Λ41) of a first block (Sl) each of the two wires (zll, zl2; z21, z22) one Row line (zl; ζ2) of a relay coupler with latching relay (R) are connected, each via a decoupling rectifier (G) with different polarity and connected to such cores (zll, zl2; r21, z22) as well as via a column line (jl ... i4 ) can be controlled by currents in different directions, that the column lines (sl ... s4) are individually connected to the signal outputs (AU .. ./141) of a second module (52), that the control signals for controlling latching relays (R) are connected Control inputs (£ 11, £ 21; £ 31, £ 41) of the first module (oil) and control inputs (£ 12 ... £ 42) of the second module (52) connected in pairs are connected to corresponding connected cores of row lines that to the relevant signal input (/ n / l) of the e First component (oil) via a NOT element (N) and an input signal (IN) to determine the current direction is applied directly to the relevant signal input (/ m / 2) of the second component (52), so that the signal inputs (C £ ll, C £ 12) of the two modules (oil, Bl), via which all signal outputs (All .. .A 14, Λ12 ... Λ42) can be set to either high or low resistance, are used to control the two modules to make effective and that the operation of the modules is reversed via the reversing inputs (UmI, Um2) and the relevant signal inputs (PmI, C £ ll, Pu2, C £ 12), and that for a relay coupler that has more row lines and / or column lines has, as a block each has signal outputs, more than two blocks can be used (F i g. 12). 12. Application before. Components according to one of Claims 1 to 7 for a latching relay coupler which has more row lines than a single component has signal outputs, characterized in that as many components (BIl .. .BIk) are provided for each column line (e.g. 51) of the latching relay coupler, that all latching relays (Rl) assigned to a column line can be individually connected to a signal output (Al ...) of one of these modules, that the control signals (z. B. Zl) that the control inputs (£ 111, E121 ... Elpl ) the relevant modules (511, 521 ... Ö / J1) are supplied, control the energization of latching relays line by line, where it is associated with input signals (e.g. 51) z. B. the control of flip-flops and collective effects, which are connected to the column-wise electronic cross-point contacts (see DOS for the relevant Signalcingangc (CT211 ... 23 48 411, pp. 13 to 15 and DOS 23 48 453, especially-C7 ' 212) of modules (BW ... BIk) can be created, p. 1 to 4). in a corresponding manner, which belong to the same gap line (.si), 5 relay couplers can be made from neutral relays or from Haitdaß an input signal (INE) that controls the milcin relay. In control devices of other connected signal inputs in question telephone switching systems are now known (//// '1I) of all modules (BIl ... Bpk) supplied z. B. very many mechanical or electronic, the current direction controls that an input relay to control, whereby it is a relay in coupling signal (MA) that the interconnected io devices or function relays are sfgnaleiningang (CfHl ... ) of all building blocks can. (/ ill .. .Bpk) can be supplied, via which the signal If it is now possible to create a semiconductor component from output (A 1 ...) high-resistance blockable or low-integrated transistors, which on the one hand can be ohmic adjustable, is used for this purpose which is designed in such a way that it can be used for various types of control of the modules that 15 control tasks can be used and at the same time via the reversing inputs (UmW ...) of all building blocks also several signal lapses controlled via inputs (BW .. .Bpk ) has the common way of working, then there is a universal module that is also reversed and that because of its good applicability in large quantities that are not yet connected to one another can be produced and thus the signaling inputs mentioned (PuW ... ) of all modules 20 the application advantages also has the advantage of being relatively cheap vcr- [BW .. .Bpk) an input signal (PU) can be supplied. The invention is based on is. with the help of which the latching relay one by one of this task. Accordingly, it relates to a control signal (z. B. Z1) determined row line semiconductor component made of integrated transistors with and a control signal (eg 51) when several signal inputs for binary input signals can be dropped (FIG. 13). 25 and with several control inputs for binary control 13. Application of a block according to one of the signals via which the digital mode of operation of the construction claims 1 to 7, characterized in that the stone can be reversed, and with several signal outers for the transmission of input signals that go to the ones that are either blocked with high resistance or Siiinaicingängcn (in / Pu, CEl, CEX) bear, a predetermined two contrast niedcrauf a multicore bus (bus) is used, 30 ohrnig electrical states have to binary, the said disclosure z by control signals (including. for example, output signals. this block is controlled INS ENL), determines the switching systems supplied via another comparable particular for control devices of Fernspreclibundenc Sleuercingänge (EI ... E4). He became thereby (Fig. 15). indicates that the control inputs carry the signal 14. Application of a module according to claim 35 outputs are assigned individually that the Signai-13. characterized in that it is used to convert output via the control inputs individually from unipolar signals to bipolar signals, according to which the control signals can be blocked with high resistance or that a unipolar signal can be set to a non-ohmic electrical state for this purpose. Sicnal input (e.g. Inf) directly and to one so that the signal output can be Second signal input (Pw) via input signal in NON-ordered signal input Limb (W) is applied (Fig. 16). in the case of the low-resistance state of the relevant signal output via this signal output it can be passed on that the digital Mode of operation by a binary reversing signal like this 45 is reversible that the F. input signal lying at a single predetermined signal input with Fs are already very many different semiconductor aid of each one or more Stcucreinbaustcine from integrated transistors known, the fermented control signal supplied and in each case zuehrere signal inputs for binary input signals ordered signal output can be passed on if on and. have multiple signal outputs. It is also known to the other signal inputs at the same time that there are control inputs for given input signals in such modules, and that binary control signals are also to be provided via which the respectively assigned signal output can be reversed by the functional principle of the module. The relevant optionally supplied control signal high-FiTmdung now relates in particular to those that can be ohmically blocked. and that further reversals of such modules, which have signal outputs, which are blocked by changes in the digital mode of operation either with high resistance or a non-resistance electrical signal given by the other signal inputs on the other hand, are effective. Fin such house stones can have Irish states that belong to binary output - advantageously because of the intended changeover signals (see /. B. RCA Solid State Datenerur.gen e.g. either fin the control, from coupling book 74 series, COS / MOS Integrated digital switchgear relays in relay couplers or also, for example, for power input, p. 214,? L>: MoM (IS Handbook, Motorola) can be used by function relays. For semiconductors, First Edition October 73 P. 0.20, also be used in I innelii ungen, which SigiiaU 6.21, 14.29; Siemens microprocessors and micro- on a busbar have to deliver. Such uiu computers by Hans-Peter Ί. Ο h: neyer-B Other examples of instructions are given in the following pages, pages 28, 29. Such modules can be explained in more detail with the aid of figures.
borrowed for many different Stcucning.sau (V;: b. <i mi '\ will see / own that! certain other universities are used, in which the special characteristics of the digital working method, especially in front of the signal outputs, play a role play. Da / u i'-ilhafi -md. as they are the applicability of the crfindiim ".