DE1437311C - Information distributor, which forwards only one piece of information supplied by the inputs, for telecommunications equipment - Google Patents

Description

In telecommunications technology, distribution facilities are known to be used for various purposes, whose task is to feed at their inputs simultaneously or not at the same time To transmit information one after the other.

Such distribution devices also serve as coupling elements in data transmission technology in the distribution of incoming information.

There are now already known distribution devices that consist of electromechanical components are constructed. They accordingly have relay selectors, that is to say switching means, which in themselves have a low operating speed, which means that they are only slow Can handle distribution processes. This naturally becomes the scope of the distribution facilities limited in that they cannot be used even when high Distribution speeds are required. Another disadvantage of these electromechanical distribution devices is that they are relatively unreliable in operation and more require careful maintenance, which entails high costs.

There are also known electronic distribution devices which operate predominantly with electron tubes. Although they allow a greater speed in the handling of the distribution processes, however, require relatively high operating voltages and a high power supply and have also a considerable amount of space.

Possible known distribution devices constructed using transistors have complicated circuits. They are also only suitable for the distribution of information, for which no group-wise priority is provided.

So are z. B. Distribution facilities known (see "Yearbook of electrical telecommunications", 1958, pp. 100 to 102, especially Fig. 19), which as Folders serve for requirements of a marker. Such a marker belongs to a switching system, which is used in particular for telephony purposes, and controls within this switching system the handling of switching processes which are used to set up and clear connections serve between associated participants. The mentioned requirements are z. B. caused by incentives that arrive on lines for which a mediation process is to be carried out. One such distribution device has inputs and outputs. The ones mentioned meet at the entrances Incentives as information. A single piece of information is then sent via one of the outputs forwarded. In this way, multiple requirements are present at the same time the respective mediation process to be processed is selected for the processing of mediation processes.

Corresponding distribution facilities are also used to select intermediate lines or switching matrices used that are required for connection paths that run over a switching network belonging to a switching system (see e.g. German patent specification 1 048 956, in particular FIG. 3, 4 and 5 with the distribution facilities ZLDE, KVD etc.). For this purpose, the operating status of the intermediate lines or the Switching matrices are transmitted to the distribution facilities, with which the For the connection structure suitable intermediate lines or switching matrices are selected and combined, whereby at the same time If necessary, one is selected from several possible connection paths. With help of a The marker is then used to switch through the selected connection path via special command lines causes. The distribution institutions acting as voters are here with their entrances connected to path search wires of the lines belonging to the switching matrix, via their outputs setting wires are marked, which at the same time marks the selected sections of the route, over which the selected connection route leads. At the entrances of the distribution facilities serving as voters can route search veins also z. B. be connected in pairs (see e.g. German Patent specification 1 051 911, claim 4), provided it is is a switching matrix with three switching stages. The path search arteries belonging to a pair belong here to the intermediate lines from a given input of the switching network lead to a previously selected output.

The distribution device then provides an intermediate line pair to be used for the connection path definitely. For this purpose, one of the at the inputs of the distribution facility occurring pairs of intermediate lines associated with the information associated with this input Output forwarded. All of the above-mentioned distribution facilities used as voters are arranged centrally in the relevant switching systems.

Distribution facilities, which at their entrances at the same time or not at the same time Transmitting information one after the other is not only used in switching technology, but in general Applicable in communications technology (see e.g. German Auslegeschrift 1 039566, column 1, line 5 up to 16). Accordingly, they are not only used in systems for self-connecting telephone traffic and automatic ones Telex switching systems, but can also be used in remote control systems (see German Auslegeschrift 1077 264, column 1, lines 1 to 21). They can also be used in computers (see German edition 1 139 890, column 1, lines 1 to 23, in particular Line 6). In all these cases, such a distribution device is used as a selector circuit to select an element from a number of available selectable items according to a certain preferred order and then select one Submit notification of the selected selection. Such an element can be provided by a facility a line or by a character element of a character, which one of the mentioned Facilities · is assigned.

Thus, for example, in a known telephone system using call centers free connection line is selected in order to establish a connection with a subscriber line, so this is only an example of the very extensive applicability of a distribution device. In this example, the selected trunk is then the preferred one Free liaison with the subscriber line should be connected. In many cases, not all connection lines can be used with every subscriber line get connected. The preference for connecting lines can be given for the various lines

be different to the traffic load on everyone To distribute connecting lines.

A distribution device of the type provided can also be used to produce an electrical Character transmission path or data transmission path in a selective manner between a device from one group of facilities and another facility (see German Auslegeschrift 1033 266, column 1, lines 1 to 21). In particular, the establishment of an electrical character transmission path is more selective Manner between one of a number of message storage devices (registers) and one of them Storage devices for common message converting devices (converters) in telephone systems in question. For this purpose, namely a distribution device is used, so a device that a Multiple inputs and an equal number. of exits, each of which has a different assigned to the named inputs. It has a character appearing at an input to the assigned If necessary to transmit the output or to connect this input and this output. At the same time it has to prevent characters from being sent to two or more outputs at the same time appear or persist for more than a short period of time.

In the prior art discussed above, provision is made for one or more of them To allow inputs of the distribution device serving as information pulses. After that a selection process is carried out by the relevant distribution facility, which then selects the The occurrence of a pulse at an output. The impulses occurring at the inputs form a total of a combination of impulses. The distribution facility can therefore also be used as a facility be understood, soft on the basis of a supplied pulse combination a selection process performs. Information of the same type, that is represented by pulses, can also be fed to the distribution device according to the invention.

The present invention solves the problem of creating a distribution device that allows forwarding a single such piece of information from a group of information that is opposite a second group of information is given priority, this priority being in particular is effective when information from both groups is supplied to the distribution facility at the same time will. With the help of such a distribution device, the priority of preferential connections and preferential forwarding of preferential information.

. If it is a distribution facility used as a folder for a marker, then with the distribution device according to the invention, the requirements, which connection incentives from correspond to a certain group of subscriber stations, are forwarded preferentially over other connection incentives. It is about a distribution device used to select intermediate lines or switching matrices, so can with the distribution device according to the invention, the assignments in the desired manner via the coupling. field, it can then namely a group of intermediate lines or switching matrices to be favoured.

As will be further shown, the present invention permits Invention the implementation of such a distribution device with the help of Ver. logic circuits. Essentially, only two types of such circuits are required here. The result is a distribution device which is simpler in structure than the previous ones thus comparable distribution facilities and which can be produced with little effort.

The subject of the present invention becomes

hereinafter referred to as the information distributor.

This information distributor has 2 m inputs and only forwards one piece of information supplied by the inputs. It is characterized in that m through channels are provided which are used to forward one of two groups of information, among which the information

2o: the second group compared to the information of the first group are given priority in terms of forwarding, and that each pass-through channel at Forwarding of information from the first group with all other through channels forwarding blocks information from the first group, but when information is forwarded to the second group for all other through channels the forwarding of information from both Groups locks.

Each through-channel of this information distributor is expediently made up of the following gate circuits built up:

a) from a first AND gate with an input for information from the first group and with an output that is connected to one input of an OR-not gate, the output of which is each connected to a special input of the other (m - l) the first AND gate and is connected to the distributor output of the through channel via an inverter;

b) from a second AND gate with an input for information from the second group and with an output, which is connected via an inverter with a special input for each of the remaining (m-1) second AND gate and is connected to the other input of the or-not gate.

Essentially only AND gates and OR gates are used for the construction. A negator can be understood as a special case of an or-not gate, namely a gate circuit, which has only one entrance.

As will now be shown, this information distributor can still be designed in such a way that privileges of information are also provided within the two groups of information are. It can also be made possible that the forwarding of information with the aid of blocking signals is blocked. Finally, it can be achieved that with the help of a fixation signal any currently existing distribution of a piece of information or none of the information can be maintained can. ·. ··.

In the various figures are the basic circuit an information distributor and circuits for its configurations are shown in detail.

F i g. 1 a shows a single through channel using a block diagram;

Fig. Ib ^- shows the structure of this through-passage of individual gate circuits;

F i g. Fig. 2 shows a blocking circuit for blocking the transmission of information via the through channels;

F i g. 3 shows a lock and fix circuit;

F i g. Fig. 4 shows a preference circuit for prioritizing. Information within the same Group;

F i g. 5 shows an example of an information distributor door, in which all the embodiments mentioned are provided;

F i g. 6 shows one information distributor, the three Has passage channels, the Fig. 1 b shown Through channel correspond.

It will now first be based on FIG. 1 a and 1 b explain the nature of a single passage channel in detail. After that, on hand the F i g. 6 describes the interaction of several through channels in an information distributor.

In Fig. La, the through channel CTi is shown as a block diagram. It has an input for the information E / l. which belongs to the first group of information, and an input for the information E / 2. belonging to the second group of information. One of these two pieces of information can be forwarded to the distributor output as an output signal Ui. Each through channel also has inputs to which group preference signals can be fed. The through channel CTi has inputs to which group preference signals labeled UhI and U «2 can be fed. It is also stated here that / z is not the same as /. which means that these group preference signals originate only from other through channels, but not from the considered through channel CTi itself. The delivery of group preference signals through a through channel is also indicated in the block diagram shown in FIG. Either only the group preference signal UiX or, instead, both the group preference signal UiX and the group preference signal U / 2 are supplied from this through signal. The first operational case is present. when information from the first group is forwarded, whereas the second operating case occurs when information from the second group is forwarded. The group preference signal UiX has the effect on the other through channels provided in each case that the forwarding of information from the first group is blocked there. The group preference signal U / 2, on the other hand, has the effect that on the through channels. to which it is supplied, the forwarding of information of the second group is blocked. When the through channels provided in each case work together, the information in the second group is authorized with regard to forwarding compared to the information in the first group. This will be explained in detail with reference to FIG. 6 will be described, in which an information distributor is ⁶ S shown from three through channels.

In Fi g. I b shows the structure of a Diirchgangskiinals from individual linkage cliallungen. Each through channel CT / contains the first AND-grid AiX. The information EiX of the first group can be fed to one of its inputs. The output of the AND gate AiX is connected to one input of the OR-not gate TiX . Its output supplies the group preference signal 17/1 if necessary. In addition, its output is connected via the inverter Til to the distributor output of the through channel, which optionally supplies the information Ui. The second AND gate AU is also provided. The information E / 2, which belongs to the second group of information, is fed to one of its inputs. Its output is connected to the other input of the or-not gate TiX . In addition, the group preference signal 17/2 is optionally supplied from this output via the inverter T / 3. The first AND gate AiX and the second AND gate AU each have further inputs to which group preference signals are fed. .

It will now be the F i g. 6 considered, which an information distributor with the through channels CTl. CT2 and CT3 shows. Each through channel is constructed in the same way as that in FIG. 1b shown. The passage channels are connected to one another in accordance with the regulations already given. So the output of the AND gate is T; 13 of the through. input of the second AND gate / 122 of the through channel CT2 and to an input of the second AND gate, 431 of the through channel CT3. The output of the inverter T23 is connected to an input of the second AND gate A 12 of the through channel CT1 and to an input of the second AND gate / 113 of the through channel CT3. The output of the inverter T33 is connected to an input of the second AND gate A 12 of the through channel CT1 and to an input of the AND gate / 122 of the through channel CT2. In a corresponding manner, the outputs of the Odcr non-gates TIl. T21 and T31 each connected to the inputs of two ■ first AND gates of two through channels each. As a result, when several items of information from the first group are supplied, only one of these items of information is passed on to a distributor outlet. When several pieces of information from the second group are supplied, only one of these pieces of information is passed on to a distributor output. If information from both the first and the second group is fed to the information distributor, only one item of information from the second group is forwarded to a distributor output in each case because of the preference provided.

It may z. B. the information £ 11 of the first group can be passed on as information Cl Then the group preference signal I'll get from the output of the or-not flag TIl to the two first AND gates .4 21 and .4 31 and prevents information from these AND gates be given. If, therefore, afterwards the information E21 and E31, the first group of information belonging to are supplied, the existing forwarding of the information EH changes not.

If the information of the / while group EX2 via ikw through channel CTl as output information

mation (71 is passed on, the group preference signal U 11 is again supplied by the output of the or-not gate TIl. The information £ 21 and £ 31 of the first group that may be supplied can therefore not be passed on via the other two through channels If £ 11 of the first group is additionally fed to the through-channel CT1, nothing changes in the existing state either. When the information £ 12 of the second group is forwarded, a group preference signal, namely the group preference signal (712), is also supplied by the inverter T13 second AND gates A22 and Λ 32 and prevents the possibly supplied information £ 22 and £ 32 of the second group from being forwarded via these AND gates via the associated through-channel another piece of information from the second n group as well as forwarding information from the first group.

Let us now go back to the operational case described first. There it was stated that the forwarding of information from the first group prevents the forwarding of other information from this group. However, it does not prevent the forwarding of information from the second group In this operating case, let us assume that the information £ 22 is also fed to the second AND gate / 4 22. This information is passed on by this AND gate, since no group preference signal is fed to its other inputs Through channel CT2 as output signal (72. At the same time, the group preference signal t / 21 is supplied from the output of the OR-not gate T21 and the group preference signal (722 from the output of the inverter T21. These two signals are sent to the AND gates A 11, A 12, A 31 and A32 and therefore prevent the forwarding of information about the two en other through channels, i.e. the through channels CT1 and CT3. The output signal (71 originally occurring at the distributor output of the through channel CT1 therefore disappears again. It has thus been confirmed that the information of the second group really has priority over the information of the first group.

The first and second AND gates of the through channels shown in FIGS. 1b and 6 have not yet mentioned inputs to which signals labeled Bn and Bh are fed. be able. These are control signals that can be used to prevent information from being passed on via these AND gates. If these control signals are not supplied, all inputs of these AND gates are supplied with the signals required for forwarding. These control signals are expediently supplied by a blocking circuit, as shown in FIG. 2 is shown. This blocking circuit contains the or-not gate TA. the output of which supplies the control signal Bn for forwarding information from the first group. The blocking signal Bl / ur blocking of the forwarding of 'information of the first is given to one input of this or-not gate

Group and the other input of this or-not gate, the blocking signal B2 is fed to block the forwarding of information from both groups. The blocking signal B2 is also fed to the inverter T5, the output of which supplies the control signal Bh for forwarding information from the second group. The occurrence of signals at the outputs of the first and second AND gates can therefore be prevented with the aid of the blocking signals B \ and B2

ίο be. When in Fi g. 1 b, these latter signals with (7/1 and (7/2 designated. The dependence of these signals on the blocking signals can be determined from the switching algebra describe the following relationship:

UH = f (B ± vB2) = f (B \ & B2) 17/2 ■ = / (Bl).

The mode of operation of the information distributor can also be explained in a different way than before.

The symbols used in switching algebra are used, which represent binary signals and information that can assume the values 0 and 1. In the following formulas: Ei = forwarded input signal, Ui = output signal,

(71 ν U2v ... Um = \ / Un,

Ui & U2 & ... Um = & Un.

The function of the information distributor is such that the output signal present at the distributor output can be specified by the following relationship:

Ui = Ei & B <$ K / (7n v \ / Un vC & Ui.

H = I Π = f + I

If privileges are provided in descending order, i.e. if Ei has priority over E (i + 1), this relationship takes the following form:

Ui = Ei & B & \ / Un vC & Ui.

η = I

The information E / l, which belong to the first group of information and which are fed to the information distributor (see FIG. 5) , all have the same authorization. It is therefore not necessary to give them a preference. In contrast, the information E / 2 has priority and therefore has a different rank.

It should be noted that the meaning of the expressions C & Ui given in the above relationships (1) and (2) will be explained later. ·

In view of the above assumptions and taking into account the circumstances. that everyone Through channel information of different ranks is supplied, it is to be assumed that the at least the output signal C / off occurring at the distributor output of the relevant through channel one of two signals is obtained which are derived from the two output signals K / l and / {/ 2.

109 628/58

These two signals mentioned are denoted by UiI and UiI . The function of the information distributor can then be described with the aid of a table which indicates when the output signal Ui = 1 is delivered at a distributor output. The following terms are used here:

Blocking signal for non-priority input signals,
Bl = blocking signal for all input signals,

ίο

£ / 1 = non-priority input signals,
Urgent = priority input signals,
Un 1 = group preference signals sent to the relevant through channel to block the forwarding of non-preferred input information,
UnI = group preference signals fed to the relevant through channel to block the forwarding of preferred input information.

Bt £ / 1 Hurry η = / -! η = m / i = i-I / I = m. B \ \ y ^Uni \ y / UnY \ y Un2 0 1 0 n = I / i = i + l / I = I. η = i + I O 0 0/1 1 0 0 0 0 0/1 0/1 0/1 , 0. 0

The top line of the table shows the values for the various signals that have to be present when the non-privileged input information £ / 1 = 1 supplied to an input is to be forwarded. The bottom line of the table shows the values for the various signals when the input information Eil = 1 is fed to the information distributor

will. This input information does not have to suppress priority input signals. She may for their part are not blocked by group preference signals, which merely did not have priority Have to block input information. Different of the occurring signals can therefore both assume binary values. '

From the table above, the following relationship can be seen, which is the two lower lines this table shows:

I = / I

η = i - I

Ui = Eil & BI & B1 & \ / Un 1 & \ / Unl & \ / Unl & \ / Unl υ Eil & Bl & \ / Unl & \ / Unl. (3)

η -] .W = IfI / I = I π = ι -f- I n = l ii = / +!

The above relationship gives the function Taking into account the theorem of

of a through channel. To be dealt with later, De M ο r g a η (see ETZ-A, Bd. 80, Issue 15, 1.8.59,

Delusive fixation measures are here except for p. 488, right column), the above Bc-

calmly. drawing can be given the following form:

Ui = Eil & .BI & B1 && UnI && UnX && UnI && UnIv Eil & Bl & & UnI && UnI. (4)

Taking into account the fact already mentioned that the signal Ui can be obtained from the signal UiI or the signal UiI , it also follows that Un = UnI ν UnI. From this it follows according to DeMorgan's theorem

Vn = Uni υ UnI = Urä & Üh ~ 2. - (5)

Taking this relationship into account, the relationship given under (4) can also be as follows to be written:

/ I = II η = m π - ι I η ~ m ,

-Ui = Eil & ΙΪ & Β2 && Un && Ün ν <Eil & ΒΪ & & Ϊ7 «2 && UnI. (6)

/ I = I / ι = / + I / I = I / i = i + l

This relationship gives rise to the effort for the Uiid gates to which the input information is supplied will decrease significantly.

The through channel CTi fio shown in Fig. La looks. It should also be noted that the relation (6) carries out the function indicated by the relation (6) is to be changed when a precedence among the tion is carried out. He is using AND Gallern is information to be considered express the pros and Or-Not gates built when the schicdencn through channels are fed. Negators as a special case of or-not gates Hs then result in the following relationship:

/ 1 = 1- 1/1 = m η = i - I

Ui = Eil & ΙΪ & B2 && Un & & Unυ Eil & Bl & & Ünf. ·

π = I η = i + I (I = I

An information distributor was discussed above which has inputs for two groups of information. It also has inputs to which blocking signals can be fed to block the forwarding of information. In many cases, it is also desirable to provide an input to which a fixation signal can be fed, which serves to maintain the currently existing distribution of any or no information. This fixation signal is denoted by C in the following. The currently existing distribution status is therefore to be maintained unchanged when the signal C is supplied, even if no information is being forwarded by the distributor at the relevant point in time, ie if all information Eil and EU have the value 0. It should be noted that in the above relations (1) and (2), the fixation by the term C & Ui is taken into account. ^: . ,

In FIG. 3 shows an example of an embodiment for the information distributor which enables both the blocking of the forwarding of information and the maintenance of the currently existing distribution, that is to say the intended fixation. The in F i g. The blocking and fixing circuit shown in FIG. 3 comprises the blocking circuit shown in FIG. A two-or-not gate is provided for each through-channel, one input of which is connected to the output of the or-not gate of this through-channel and the other input of which the fixation signal C is fed via the inverter T6. In FIG. 3 shows only one of these two-or-not gates, namely gate 777, which is assigned to the through- channel CTi . This through channel is shown in FIG. (b is shown and has already been described in detail. The relevant input of the two-or-not gate T / 7 is accordingly to be connected to the output of the or-not gate TiI of the through channel CTi . Gate Ti 7 is connected to an additional input of the mentioned or-not gate T / l of the relevant through channel, here the through channel CTi , as well as to an input of an inverter T / 3 that replaces the associated second AND gate / 4/2 two OR-NOT gate connected. the g in F i. plywood and shown 3 fixing circuit further has the aND gate / 13, one input of which the fixing signal C are supplied, may whose other inputs lind separated to the outputs of Or One of its inputs is connected to the OR gate T / l of the through channel CTi . The output of the AND gate A3 is each connected to an input of two further OR Nic ht gates belonging to the locking and fixing circuit are connected. These two or-not gates are shown in FIG. 3 labeled T4 and TS. Finally, the blocking and fixing circuit also has the further two-or-not gate TS , one input of which is connected to an output of the inverter T6 and the other input of which is connected to the output of the further or-not gate T5. The two-or-no gate TS supplies the control signal Bn for blocking the hamlet line of non-preferred information. The output of the two-or-not gate T8 is connected both to an input of the one further or-not gate TS and to an input of the other further or-not gate T4. The other inputs of the OR gate T5 Not the blocking signals can schillings and Bl are fed. The or-not gate T 4 also has an input to which the blocking signal ΒΪ for blocking the forwarding of information from both groups can be fed.

The signal supplied by the output of the AND gate A 3 is shown in FIG. 3 labeled W. The conditions under which this signal occurs can be specified as follows:

W = C & &

η = 1

π = I.

(9)

If the signal W is evaluated in parallel with the blocking signal B1 , the distribution can be fixed even if no information is passed on. A non-existing blocking state is simulated here. The output of the two-or-not gate T / 7 supplies a signal which is denoted by C & Ui. It shows the forwarding of information in the relevant passage channel at the time the distribution is fixed. The cooperation of the in F i g. 3 with several others. Passage channels will be shown later on the basis of Fi g. 5 explained in detail.

So far, in the course of the priority, it was only provided that the information of the second group is given priority over the information of the first group. It is also possible, however, to give priority to information within the groups. This can be achieved using a special preemption circuit shown in FIG. 4 is shown. Such a preemption circuit can be inserted in each through-channel of the distributor. It also has the task of ensuring that only a single piece of information is passed on from the information distributor if several signals arrive at the information distributor at the same time. For this purpose, all non-preferred through channels are to be blocked at the same time. Because the relevant through channels are each provided with a priority circuit, they are accordingly given a priority order, with a through channel preceding in the order of priority being given priority in terms of forwarding information over the through channels following in the order of priority. This can be done e.g. B. achieve the following circuit measures. In the case of the through channels, the outputs of the first and second AND gates, to which information to be passed on can be fed, are each followed by two inverters in series. Preferential signals can then be picked up between these inverters. Furthermore, the associated inverters AND gates are connected downstream of the relevant through-channels, to which the (m-I) preference signals supplied by the other through-channels are additionally fed. These preference signals are in each case influenced by that information which belongs to the same group as that which is passed on via these AND gates. 4 shows in detail how the second AND gate .4 / 2 of the through channel CTi shown in FIG.

Gates are to be connected downstream. The AND gate AiI are followed by the two series Ncgators T / 9 and Ti 10. The preference signal XiI can be picked up at the output of the inverter T / 9. The output of the inverter T / 10 is connected to an input of the additional AND gate A '74. This AND gate also has further inputs to which the preference signals are fed, which are supplied by the second AND gates of the other through channels. These are the preference signals c ΛΊ2 ... ^ (/ - 1) 2. In the given case, the output of the AND gate A ″ i4 supplies the signal YiI, which is supplied to the two-or-no gate replacing the inverter T / 3 of the through channel CTi Through channels shown, this inverter is replaced by a two-or-no gate, these are gates TT 13 and TT63.

In a corresponding way, two negators and an additional AND gate are each also the first AND gates connected downstream of the relevant through channels. In the case of the not privileged in the order of precedence However, the through-channel does not have the two additional AND gates, since this through-channel does not have to be fed with preference signals. Accordingly, the through-channel shown in FIG. 5 has CTl only the first and second AND gate downstream on negators.

The following formulas can be specified for the function of the priority circuit:

1 // 2 = K / 2

»1 = 1-1

YiI = XiI & & YnI.

η = 1

(10)

So that the intended priority is more effective than the mutual blocking of the forwarding of information, it must be ensured that the preference signals are delivered more quickly than the group preference signals. So it must z. B. the signal XiI can be delivered earlier than the signal 1 // 2. This is ensured by the fact that the preference signals in the relevant through-channel can be removed at a point which, in the course of the forwarding of information, lies before the point at which group preference signals can be removed.

As already mentioned several times, FIG. 5 shows the structure of an information distributor in which all of the circuit arrangements mentioned above are also used. The passage channel CT1 and the passage channel CT6 of this information distributor are shown in detail. A plurality of further through-channels, not shown, are located between these two through-channels. The blocking and fixing circuit CBC is also shown. It should be noted that in this locking and fixing circuit only two two-or-no gates are shown which supply signals C & Ui. They are labeled T17 and T67 and assigned to the through channels CT1 and CT6. The number of such gates is just as large as the number of through channels belonging to the information distributor. The gates assigned to the through channels, which are not shown, are therefore also not shown here. ,

It now becomes the mode of operation of this information distributor in the various operating cases of interest explained in detail.

a) Simultaneous supply of information
the first group

It is assumed that the information belonging to the first group £ 11 and £ 61 will be allocated to the concerned

ίο inputs of the AND gates, 411 and A61 are created. This means that a signal with the binary value 1 appears at the output of these AND circuits. A signal with the binary value 0 then appears at the output of the inverter ΤΊ9. The latter output is connected to inputs of AND circuits of all subsequent channels. It is therefore also connected to an input of the AND circuit A'64 . Since the respective input of the AND gate A6T, in turn, the information £ 61 is supplied to the, the AND gate A also occurs at the corresponding input '64 to a signal having the binary value. 1 The signals coming from the AND gate / 4 61 are passed on there via the inverters T'69 and T'610.

Since, however, as already stated above, the AND gate A '64 was fed a signal with the binary value 0 from the through channel CT1, namely the preference signal X 11, a signal with the occurs at the output of the AND gate A'64 binary value 0. A signal with the binary value 0 thus also occurs at one of the inputs of the OR-not gate T61. However, signals with the binary value 1 occur at the other two inputs of this or-not gate. This in turn has the effect that a signal with the binary value 1 appears at the output of the or-not gate T61 and therefore at the one with it via the inverter. The distributor output connected to T62 sends a signal with the binary value 0.

The through-channel CT1 is now considered again. At the output of the inverter ΤΊ9 occurs as already mentioned, a signal with the binary value 0 occurs. At the output of the inverter T'110 occurs therefore a signal with the binary value 1, which is sent to one of the inputs of the or-not gate TIl is passed on. The other two inputs of this or-not gate TIl are signals with fed to the binary value 0. This has the consequence that at the output of the or-not gate TIl a A signal with the binary value 0 occurs, so it reaches the distributor output via the inverter T12 of the through channel CTl a signal with the binary value 1. This means that the information £ 11 is passed on as output signal t / l. The information. £ 61, on the other hand, was sent via the through channel CT6 not forwarded.

b) 'Simultaneous supply of information from the first group and information from the second 6ο group

It is assumed that the information distributor £ 11, which belongs to the first group, and the information £ 62, which belongs to the second group, are supplied at the same time. A signal with the binary value 1 then occurs at the output of the AND gate A62. This signal is given by the inverter 7 "69 as a signal with the binary value 0. Iis then also reaches the inverter

T "610, from which a signal with the binary value 1 is passed on to an input of the AND gate A" 64 . A signal with the binary value 1 then results at the output of the AND gate A "64. This signal reaches an input of the two-or-not gate TT63 as well as an input of the or-not gate T61. An Signals with the binary value 0 therefore occur at the outputs of these two or-not gates.

The group preference signal 1/62 supplied by the output of the two-or-no gate TT63 reaches all the second AND gates of the other through channels, that is to say also to the AND gate All of the through channel CT1. Signals with the binary value 0 therefore appear at the outputs of these second AND gates. The output of the OR-not gate T61 is now connected to the inputs of the first AND gates of the other through channels. It is therefore also connected to an input of the AND gate All . A signal with the binary value 0 therefore also occurs at the outputs of these AND gates. As a result, a signal with the binary value 0 also occurs at the distributor output of the through channel CT1. In contrast, a signal with the binary value 0 occurs at the output of the or-not gate T61 of the through channel CT 6. A signal with the binary value 1 is therefore passed on to the associated distributor output by the inverter T62. The information £ 62 is passed on via the associated through-channel CT6 as output signal U 6 . The information urgent, however, is not passed on via the associated through-channel CT1. So only the privileged information, as it was intended, is passed on.

c) Blocking in case of operation b)

If a blocking is to be carried out in the operating case described under b), the blocking signal B1 is fed to the information distributor. At the output of the OR Non gate T5 "then enters a signal with the binary value 0 to it arrives at all the first AND gates of the various passageways, so the AND gates / 111 ... / _161.. This The forwarding of information of the first group is blocked for these through channels As a result, the signal with the binary value 1 is still maintained at the distributor output of the through channel CT6, so the information £ 62 is still forwarded as output signal U 6.

When the blocking signal B1 is supplied, a signal with the binary value 0 occurs both at the output of the OR-not gate TS and at the output of the OR-not gate T4. This signal is therefore fed to all first and second AND gates of all through channels. As a result, the forwarding of all information, that is to say of information from the first group as well as information from the second group, is blocked for all through channels.

d) Fixing the distribution when forwarding information from the second group via a

Through channel

If, for example, information from the second group is forwarded, i.e. if the information £ 62 is fed to the relevant input of the information distributor, then a signal with the binary value 0 occurs at the output of the or-not gate T61, which also corresponds to the two-or -Not-gate T 67 arrives, at the output of which a signal with the binary value 1 occurs, which in turn is passed on to an input of the two-or-non-gate TT63 and to an input of the OR-non-gate T 61. It follows that if the information £ 62 is missing and the .Fixiersignal C is supplied at the same time, a signal with the binary value 1 is still obtained at the distributor output of the through channel CT6. In this case, a signal with the binary value 0 is present at the output of the AND gate A "64 , which is sent both to an input of the or-not gate T 61 and to an input of the two-or-not gate TT63, but since a signal with the binary value 1 is still fed to the second input of the two-or-not gate TT63 from the two-or-gate T 67, the signal remains at the output of the or-not gate T 61 The binary value 0 is retained, and consequently the signal with the binary value 1 is retained at the distributor output of the through channel CT6. The information £ 62 continues to be passed on via the through channel CT6, as required -Or-not-gate T63 continues to receive the transmitted signal with the binary value 0, that is the group preference signal U 62. It reaches all first and second AND-gates of all other through-channels information about these other through channels is therefore prevented.

e) fixing the distribution,. ,

if no information is passed on '

In this case, the fixing signal C is fed to the information distributor. It arrives at the input of the inverter T6 and from there in negated form to the two-or-no gates T17 ... T67. Signals with the binary value 1, which are supplied by the outputs of the or-not gates TIl ... T61, arrive at the second inputs of these two-or-not gates. As a result, signals with the binary value 0 appear at the outputs of the two-or-not gates T17 ... T67. These signals are passed on to one input each of the two-or-not gates TT13 ... TT63 of the pass-through channels CT1 .. CT6 and at the same time are also fed to inputs of the or-not gates T11 ... T61. The signals U 12 ... V 62 still appear at the outputs of the two-odd-odd gates TT 13 ... TT63. The binary values of the signals occurring there also do not change at the outputs of the or-not gates TIl ... T61. The fixation signal C now also reaches one of the inputs of the AND gate A3 at the same time. In this case of operation, the other inputs of the AND gate 43 have signals with the binary value I. At the output of the AND gate A3 there is therefore a signal with the binary value 1 that corresponds to one of the inputs of the or-not- Gattcrs T4 and one of the inputs of the Or-Not-Ciattcrs 7'5 is supplied. At the other inputs of the mentioned or-not gates

10962β'58

there are signals with the binary value O. A signal with the binary value 0 now occurs at the outputs of these two or-not gates. These signals reach the first and second AND gates of the through channels, i.e. the AND gates All, All ... / 461, / 462. As a result, there is no information about this AND gate. can be passed on, so that any information subsequently arriving at the inputs of these AND gates cannot result in any change in the signals present at the distributor outputs. The latter signals all have the binary value O.

0 Fixation of the locking circuit

The blocking and fixing circuit CBC is constructed in such a way that the state of this blocking circuit itself can also be fixed. This operational case is now dealt with. For this purpose, the blocking signal B2 is fed to the or-not gates TS and T4. A signal with the binary value 0 therefore occurs at the outputs of these or-not gates, which causes the blocking of all first and second AND gates in the various through channels, i.e. AND gates A 11, A 12 ... A 61 , A 62. If the fixation signal C is now fed in, a signal with the binary value 0 results at the output of the inverter T6, which is passed on to the two-or-non-gate T8, the second input of which is that of the output of the OR -Non-gate T5 supplied signal with the binary value 0 is fed. A signal with the binary value 1 therefore occurs at the output of the two-or-not gate T8 and is fed to both the or-not gate T4 and the or-not gate T5. If the blocking signal B2 is no longer supplied, the signal with the binary value 1 that occurs at the output of the or-not gate T4 and at the output of the or-not gate T5 is still retained. This is because a signal with the binary value 1 is still fed to these two or-not gates from the two-or-not gate T8. A signal with the binary value 0 therefore still occurs at the outputs of the OR-not gates T5 and T4, which still causes the first and second AND gates that belong to the through channels to be blocked, i.e. der And-Gatler AU, All ... / 161, / 162.

The information distributor described above and all of its configurations are only below Constructed using a few types of gate circuits. Such gate circuits are expediently with the help of semiconductors, such as diodes and / or transistors and resistors, built up (see e.g. ETZ-A, Vol. 80, Issue 15 from 1.8. 1959, pp. 487 to 492, especially p. 489).

Claims (8)

Patent claims: 60 I. Information distributor with 2 m inputs, which in each case forwards only one of the inputs supplied information, characterized in that m through channels (CTi) are provided, which are used to forward one of two groups of information, among which the information {express ) of the second group are given priority over the information (Eil) of the first group with regard to forwarding, and that each transit channel (CTi) when forwarding information from the first group for all other transit channels (CT1, CT2 ... CT / -1, CTi +1, ... CTm) blocks the forwarding of information from the first group, but blocks the forwarding of information from both groups when forwarding information from the second group in all other through channels (FIG. 1 a). 2. Information distributor according to claim 1, characterized in that each through channel is made up of the following gate circuits: a) from a first AND gate (AiI) with an input for information (Eil) of the first group and with "an output that is connected to one input of an OR-not gate (Tit) , the output of which is connected to each a special input of the remaining (m-1) first AND gates (All, All ... A (i - l) \, A (i + l) \ ... AmI) and via an inverter (T / 2) is connected to the distributor outlet of the through channel; b) from a second AND gate (AiI) with an input for an item of information (£ / 2) of the second group and with an output, which is connected to the other (m - l ) second AND gate (A 12, A 22 ... A (i -1) 2, A (i + 1) 2 ... Am 1) and with the other input of the or-not gate (T / l ) is connected (Fig. 1 b). . 3. Information distributor according to claim 2, characterized in that the first and second AND gates (Ail, AH) additional inputs are provided to which control signals (Bn, Bh) are supplied, the absence of which is the forwarding of information from one group or the other locks. 4: Information distributor according to Claim 3, characterized in that the control signals (Bh, Bh) are supplied by a blocking circuit which contains an or-not gate (T4), the output of which is the control signal (Bn) for forwarding information (E / 1) of the first group and one input of which supplies a blocking signal (Bl) to block the forwarding of information (E / 1) of the first group and its other input a blocking signal (B2) to block the forwarding of information (E / 1, E / 2) is fed to both groups, and that the latter blocking signal (B2) is also fed to an inverter (T5), the output of which supplies the control signal (Bh) for forwarding information (E / 2) to the second group (F i g. 2). 5. Information distributor according to one of claims 2 to 4, characterized in that it has a blocking and fixing circuit, the blocking signals (Bl, B2) for blocking the forwarding of information (E / 1, Eil) of one or the other group and a Fixing signal (C) can be supplied to maintain the currently existing distribution of any or no information and has the following gauging circuits: a) for each through channel (CTi) a two-or-not gate (Ti 7), one input of which is connected to the output of the or-not gate (T (I) of this through channel, the other input of which is connected via an inverter (T 6) the fixation signal (C) is fed and its output with an additional input of the mentioned OR-rNot gate (Ti 1) of the mentioned through channel (CTi) and with an input of an inverter connected to the associated second AND gate (AU) (T / 3) replacing two-or-not gate (T Ti 3) is connected; b) an AND gate (A 3), one input of which can be supplied with the fixing signal (C), the other inputs of which are connected separately to the outputs of the or-not gates (T / 1) of the through channels and whose output is connected to each an input of two further or-not gates (T4, T 5) is connected; . c) a further two-or-not gate (T8), one input of which is connected to an output of the inverter (T6) and the other input of which is connected to the output of another or-not gate (T5), which carries the control signal (Bn) to block the forwarding of non-privileged information and the other inputs of which the blocking signals (Bl, B2) can be fed, while the output of the further two-or-non-gate (T8) both with an input of another or Non-gate (T5) as well as to an input of the other further or-not gate (T 4) is connected, which also has an input to which the blocking signal (B 2) for blocking the forwarding of information mations of both groups can be supplied (Fig. 3). 6. Information distributor according to one of claims 2 to 5, characterized in that the relevant through-channels are provided with a priority circuit (T / 9, TiIO, A "i4) , through which they receive a ranking, with a preceding through-channel (CTl ) is given priority over the following through channels (.. .CT6) with regard to forwarding.! 7. Information distributor according to claim 6, characterized in that in the through channels (CTl ... CT6) the outputs of the .Und- 'gates (Ail, AH), to which information to be forwarded can be fed, each two negators in series (ΤΊ9 -ΤΊ10, T " 19 - T" 110; ... T 69 - T 610, T " 69 - T" 610) are connected downstream, between which preference signals (ATIl, XU; ... X61, X 62) can be removed, that with the relevant through channels (CT6) the associated inverters (T 69 - T'610, T " 69 - T" 610) and gates (A '64, A "M) are connected downstream, which are additionally each of the others Through channels (CTl ...) supplied m / 2 -1 preference signals (X \ 1 ... X 51; X \ 2 ... XS2) are fed, which are influenced by the information that belongs to the same group as those soft via these AND gates (A '64, A " 64) are forwarded. 8. Information distributor according to one of claims 2 to 7, characterized in that the used gate circuits made of semiconductors, such as diodes and / or transistors, and of resistors are constructed. For this purpose 2 sheets of drawings