DE1152441B - Circuit arrangement for message processing systems, in particular for telephone systems, for the implementation of input information - Google Patents

Description

The invention relates to a circuit arrangement for message processing systems, in particular for telephone systems, for the implementation of input information in each assigned Output information, the input information in the form of information first or second Type and in the respective other type are to be implemented.

In each case information of the first type and information of the second type are permanently assigned to one another. The information of the same type is assigned to one of this group of information Output switched on again and again in a certain order. The different from each other Associated information is in each case in a certain period of time at about the same time at different Outputs switched on.

In a known method for converting input information into respectively assigned A continuously rotating drum store is used for output information. In this procedure the angular position of the drum in relation to the reading heads of the drum memory is used to the input information written on the drum from the input information corresponding to the given angular position To determine information as output information. Conversely, for input information, which is written on the drum, the associated angular relationship as output information certainly. However, if there is information available, it must first if it is a the information stored on the drum, this predetermined information with that on the drum standing information can be identified. Is now the one corresponding to the information given Information on the drum is determined, so is the one on the drum Information to determine the angular position corresponding to the end of the specified information to be able to determine associated information. So there are two processes to determine one of the information assigned to predetermined information is required. The angular position is determined by one of the The device associated with the drum determines the per group of information stored on the drum is provided. In order to be able to evaluate the information read, this information must be cached. In the known technology are so for Implementation of both special reading and special storage arrangements required.

The object of the invention is to avoid the disadvantages of the known arrangement and to implement the

Circuit arrangement

for message processing systems,

especially for telephone systems,

for the implementation of input information

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Dipl.-Ing. Otto Kneisel, Gauting near Munich,
and Dr. Kurt Fischer, Munich,
have been named as inventors

entry of an input information into this information assigned other information in a simple manner in such a way that the necessary for the implementation The arrangement to be provided can also be appropriately attached to central control devices can.

This is achieved according to the invention in that a generator is provided which supplies the information of the first type in a certain sequence, in particular a counter, which outputs this information of the first type (e.g. connection identification) to the input of a corrector, and this corrector converts the information of the first type into the associated information of the second type (z. B. subscriber identification) and delivers this to the output of the corrector, and that a comparator arrangement is provided, which removes the information at the output of the generator and at the output of the corrector compares with the input information of the first or second type pending at the comparator arrangement and, in the case of an identification of the information of one type, connects the information of the other type to an output as output information.
As a result, a device, in particular a counting device, which supplies certain information of the first type to the control devices of a centrally controlled telephone system, is expedient.

309 650/210

also wise for determining the storage locations of the in a certain order to certain outputs of a corrector connected information of the second type is also used. This information provided The first type and the second type are also each used for comparison with input information first or second kind used. By offering both the information first Kind as well as the information second. Kind is extra-

information or the account number of this customer using the address as input information can be determined as output information.

For example, it can also be used as input information on the basis of a specific item of goods it can be determined which customers (output information) ordered these goods (input information) to have. Conversely, the type of goods ordered can also be based on the name of the customer

which an acceleration of the revaluation can thereby be determined 10. This example for booking possible, that the input information, independent systems, can of course be expanded at will, of whether these are of the first or second kind, cyclical. Also for translation machines, an application is compared are possible with the embodiments of the invention referred to. One can for example went pending information. As a translator based on certain words of one language as for the inventive circuit arrangement 15 input information the corresponding words of can easily determine all static memories other language as output information, (e.g. magnetic core memory) or vice versa.

Fig. 1 shows a time diagram for the telephony operating in a certain after, interrogated in a certain sequence, the time division multiplex system. This facility, e.g. B. a counter 20 system provided pulse phases; tion, which determines the storage locations in the memory, is Fig. 2 shows an overview of the facilities in many cases, for example in a telephone system operating according to the time division multiplex system described in the embodiment, time division multiplex system operating telephone system, for control and storage tasks already available. on the basis of which the functional relationship of the single control and storage tasks required for the method according to the invention through the use of this device and at other times for the directions is described below; Corrector is achieved that the corrector is synchronized with FIG. 3 shows the details of a converter device, which are important for understanding the invention, without additional effort. The following example assumes that a static memory, for example a magnetic core memory, is used for the converter, with a continuously revolving counting chain as a magnetic core memory, which has more value than a mechanically rotating one through a permanent one Circulating counter in memory (drum memory) has the advantage that a specific sequence is queried and thus the circulation can be stopped at will. This stop z. B. the same information occurs every 100 milliseconds, for example when converting an input 35 at its output. This means that the output information for evaluating this information counting device, for example a ring counter, is assigned to information when for the off each clock a different information of the first type, evaluation in the control device more time than for example a connection number, on its The recognition of the information in the corrector is required and thus the connection of the. In this way, in the case of static memories 40, related information of another type, e.g. B. Rufno intermediate storage, the numbers in drum storage, authorization information, etc., which are often required in the required. Due to the continuous magnetic core memory, for example, offering the various information in parallel, a corresponding coding of the information is initiated in the case of secured information at corresponding outputs. The memory used as a corrector, which is given by the counting device, is permanently monitored. Information of the first type is not only accessible. This makes it possible to determine the mood of the storage locations in the magnetic core memory, errors immediately and not only when the information is requested, but also as so-called addresses for the incorrect information. For the circulating memories Ua, Ub and the comparator arrangement shown in FIG. 2, the remote central control device Si is also used. Are the comparators used in the intercom, which are also used for 50 memories, for example, a thousand different information for free and busy checks? mations of the second type are stored, which are each assigned to a When converting input information in the intercom, the counter output information must be perfect in itself, z. B. ring counter, every 100 microseconds (irrespective of what information it is. Speaks pulse repetition frequency 10 kHz) another In the exemplary embodiment, the comparison of call formation of the first type, z. B. port number, one and port numbers of connection points, z. B. Call station both the corrector as well as the subscriber lines, a telephone system written circulating memory and the central control device. Which are supplied in particular with reference to FIG. 3.

Written arrangement for the revaluation of input To now an input information with the from the

information in the respectively assigned output information 60 counter and the information provided by the corrector

However, it is a must to be able to compare information, for example, with information given in the booking

systems, e.g. B. for large department stores and shipping an input information either for the duration of

houses, applicable to queue for 100 milliseconds based on the information or in a busy

of a kind the corresponding information was corrected the second particular cycle every 100 microseconds

Type or vice versa in a simple manner. 65 offered again and again _{at the relevant entrance}

For example, is a customer's account number
given encoded as input information, then an
Hand this account number the address as output ^ ·

will. In the embodiment that is based on a
Time division multiplex system for a telephone system, the same input information is used every 100 minutes

microseconds is switched on at the input for a period of, for example, one microsecond.

In the time division multiplex system under consideration, every call station that wants to establish a connection is when lifting the handset, a certain pulse phase is assigned as a so-called conversation phase. While the entire connection establishment and for the entire duration of the call with a second intercom then this intercom station is assigned this pulse phase. In the time division multiplex system under consideration there are a hundred pulse phases intended. A pulse phase is specified again every 100 microseconds, for example. The information from a call station is thus given a specific one for the duration of the call being processed Pulse phase.

In FIG. 1, the hundred pulse phases of a phase cycle are shown in a time diagram. The pulse phases P1 to P 94 are provided as so-called conversation phases and are each allocated to the connections for the entire setup time and conversation time. The pulse phases P 95 to FO are control phases. A pulse phase P1 assigned to a connection is therefore repeatedly specified after each cycle Z1 or ZI or Z 3, that is to say every 100 microseconds. At the point in time at which the pulse phase P1 is present, all information from the call stations involved in the connection that is assigned to this pulse phase, if the connection number of the calling call station is specified by the counter at the same time, is collected and evaluated depending on the respective switching state. The determination of the predetermined pulse phase, e.g. B. Pl, to the port number specified by the counting device for the duration of 100 microseconds takes place within a processing cycle VZ. So if a pulse phase, z. B. Pl, determined, it means that the station, which is assigned to this connection number, is involved in a connection or conversation. If the information available at the specified point in time contains new information that was not yet available during the previous processing cycle, then a renewed evaluation of the information ascertained is necessary. This evaluation takes place in an operational cycle following the processing cycle. The counter is then switched to the next connection number only after the operation cycle has ended. If no operating cycle is required, the counter is switched to the next connection number after the processing cycle of 100 microseconds, so that another processing cycle follows.

With reference to FIG. 2, the functional relationships are now briefly described for a telephone system operating according to the time division multiplex system. The telephone system shown in FIG. 2 as an example is a telephone private branch exchange with the telephone stations Nl to Nx and with the trunk lines ALI to ALx. The speech stations Nl to Nx can be connected via the speech switches SNl to SNx to be controlled and the exchange transmissions AUeI to AUeχ through the speech switches SA 1 to SAx with the speech multiplex point , which is denoted by SM. The speech switches are controlled by control pulses, which are supplied with the help of the circulating memory Ua and Ub. The speech switch SN1 assigned to the speech station Nl is closed every 100 microseconds when the pulse phase P1 is present, if this speech station is assigned, for example, the pulse phase P1. The addresses, that is to say for example the connection numbers, of intercom stations with outgoing traffic run in the circular memory Ua and in the circular memory Ub the

ίο addresses, ie for example phone numbers or connection numbers (depending on the switching status), of intercom stations with incoming traffic. As already mentioned above, addresses belonging to a connection each have the same circulating phase (corresponds to the pulse phase), so that these addresses are output at the same time at the outputs of the circulating memories. So-called decoders Da and Db are connected to the outputs of the circulating memory Ua, Ub-. Each decoder has as many outputs as there are microphone units and trunk transmissions. Each of these outputs is therefore assigned either to a call station or to an exchange transmission. Each speech switch is connected both to an output of the decoder Da and to an output of the decoder Db . Inserted OR gates, not shown, prevent the decoders from influencing one another. If the address, e.g. B. connection number is supplied to a call station, a pulse is emitted at the output that is assigned to this call station. This impulse is then used to control the speech switch assigned to this call station. If a pulse (for the pulse phase assigned to the connection) occurs at the two decoders at the two outputs assigned to the different speech stations, the speech switches allocated to these two speech stations are temporarily closed. This means that the two call stations are connected to one another during this time. This state repeats itself periodically, ie every 100 microseconds, with the circulation period of the addresses circulating in the circulating memories Ua, Ub , z. B. Port Numbers. This creates the intended connection between the respective microphone units.

It is assumed that in order to establish a connection, for example between the speech stations Nl and Nx of the private branch exchange shown, the subscriber of the speech station Nl lifts the receiver. The counter AZ (address counter) switches, as has already been described, an address one after the other for 100 microseconds, e.g. B. the connection number of a call station at output A 2 and checks the switching status for the call station corresponding to the present connection number. If the counter AZ switches on the connection number of the call station Nl after a certain time at the output A 2, the loop status of this call station Nl is first checked for the interrogation pulse address PO connected by the clock generator TG. The Teihiehmerschleife is now closed at the actual time, so that is not shown on the subscriber circuit Tl and the signal multiplexing line SMN a, the line circuit Π connected with this signal multiplex line SMN switch the message it $ loop closure for. B. by forwarding

7 8

a pulse is given to the control device St. number or connection number is written in, the direct current code characters from the digits Tl to Tn and from the office transmissions Λΐ-Σ / βΊ receiver MM to the circular memory Ub, which is provided for the criteria given up to A-Uex , are provided according to the incoming connection, from the various subscriber circuits, transmitted successively by the counter ZA upstream 5 In the circulating memory Ub addresses run given addresses (terminal numbers of speech (telephone numbers or port numbers) of the telephone station and the office transfers) and post-filters to which the stations with ankomeinander at the respective signal multiplex line mendem traffic are involved in connections. The 5MiV or SMA open and do not interfere with each other's addresses from one and the same connection. ίο belonging call stations run in phase in each case. It is first determined whether the calling is in the two circulating memories Ua and Ub . At speech station 2Vl, the decoder Db is already connected to a circulating memory, ζ on any pulse phase in the circulating memory Ub. B. Ua or Ub, already included, which has the same structure as the Dewritten. It should be mentioned briefly that apart from coder Da and its outputs, the circulating memories Ua and Ub are not provided with the circulating memories shown in the same way as the outputs of the decoder Da with the circulating memories shown. The call stations or office transmissions belonging statement that the call station Nl are neither connected in the switch-speech switch, running memory Ua nor in the circulating memory Ub one of the circulating accumulators, e.g. B. Ua and Ub, registered circulating memory Ua assigned circular memory in the benen addresses (connection number or call number). Digit receiving device MM the same circulation-If the call station JVl is not yet written in, time as the circulating memory Ua has, in each case at which this call station Nl is still a free pulse time (phase) at which the address of the call phase, z. B. P1, assigned to the call station at the output of the circulation for the connection to be established. The memory Ua occurs upstream of the counter ZA. With this registration the given address, e.g. B. connection number, the desired address (phone number) are now written to a calling station Nl in the control device, not shown, the same memory Ua . Checked in this circular stream code character. Through the writing memory Ua run to the occupied phases of the address of the desired station to the registered addresses z. B. in the form of arrival 30 point in time at which the decoder As the circulation number for speech stations that are involved in outgoing memory Ua the address of the calling station connections occurs with a certain, it is guaranteed that the speed written to cyclically. At the outputs of the address (call number) of the call station circulating memory Ua , therefore, the addresses per decoder Db appear periodically at the time with the repetition frequency of the pulse phases. The decoder Da is connected at 35 points, which are connected to the pulse phase of these outputs. the calling station is assigned the pulse phase. B. Pl, matches.

point, for example the pulse phasePl, the address of the incoming As for the further processing not the now in the calling station 2Vl supplied. This call number, decoder, written in the circulating memory Ub , is sent to the associated 40 but the connection number is important, the speech switch SNl is fed and is used to control its call number in the corresponding connection number. This has the effect that during the reevaluated and instead of the call number the relevant pulse phase P1, the relevant speech termination number is written in the circulating memory Ub , connect 2V1 to the speech multiplex point SM. The reevaluation will be explained below. The addresses is bound. 45 (connection numbers) of the call station 2V1 after writing the address (connected call stations appear at the same time at number) of the calling call station 2V1 around the outputs of the decoders Da and Db , so that memory Ua is used by the pending Require the relevant speech switches 2Vl and Nx to be made permeable at the same time as a free digit receiver Zi occupied. The connection and also the address of the intercom station 2Vl in a 5 ° between the intercom stations 2Vl and 2Vx is thus, not shown circulating memory of the digits as already described, written in pulses (every 100 micro-receiving device MM . The digits seconds) to the corresponding pulse phase Pl Receiver Zi is switched through at the same time as the. The speech station 2Vl is thus switched on via speech station 2VlandenSpeechmultiplexpunkt5M via the speech switch 52Vl, the speech multiplex point the switch Zi . The digit receiver 55 SM and via the speech switch 52Vx receives the phase from the participant of the speech station, e.g. Pl, connected to the speech station2Vx for each pulse. Nl sent by key selection in multifrequency code. Any changes in the switching state of the digits, and these are implemented in the digit binding by one of the microphone units involved in the existing receiving device MM in binary direct current binding. With the central control characters, it is determined at the point in time at which device St is now queried whether the selected counting device has the address of the corresponding address already in a circular memory on the call station that emits the identifier or not. This is switched on based on a gear of the counter. Depending on the switching comparison of the status of the comparators RA, AA, RI ? , the processing cycle AB is then followed by an operating cycle and the counting device determines the information. After it has been established that the next address in circulation is not switched to the selected address (call number) until the operation cycle has been completed. The determination, Ua still in the circulating memory Us as RuE- which state is present, sets the control

9 10

facility St must be fixed for the given address. However, since these are decimal digits and there are sixteen of the sixteen present in the binary code during the operating cycle

corresponding commands. Only ten license plate combinations were used. To the

The connection is deleted by simplifying the illustration in FIG. 3 are pro

put the handset of the calling or called 5 output, z. B. Al, only two of the example

Intercom station shown after evaluating the existing twelve output lines

Switching state by the central control device and wired.

Si at the point in time at which the counting device AZ is set as a corrector for the shown correcting device to the address (connection number) of the calling device, all known static memory addressing stations can be set. io orders are used. The connection of the from the above shows that the counting device AZ recorded in a memory word for the control and storage devices at the corresponding outputs is of central importance for each device, since the counting device queries, for example, through a counting device initiate the synchronization of all switching processes. It should also be pointed out that the unambiguity of the switching operations required for each connection does not guarantee all information for interrogation at input E. The description of the corrector needs to be available,
further switching operations, e.g. B. Manufacture of official In the following embodiment, it is connections, is omitted for simplicity. it is assumed that a magnetic core is used as the memory in FIG. 3, the devices of the corrector memory is used, which is represented in a specific way by a counting device continuously revolving with the details 20 important for understanding. The cycle indicated symbolically in FIG. 3 is queried and z. B. all 100 MiIIi gate circuits are set as generally known advance seconds (if there is no operating cycle). For the sake of general understanding, only the same information is offered. This means, pointed out, that in the following only from the that the counting device, for example a ring inputs or outputs of the gate circuits 25 counter, with each clock a different information, connected yes-no markings are mentioned z. B. connection number, at output A 2 and is. With a yes marking, for example, the associated information, e.g. B. Rufein positive potential and in the case of a no identification number, authorization information, etc., the manung, for example, a zero potential at the input gnetkernspeicher, for example, stored in parallel or the output of the respective gate is switched on. 30 pieces of information at the corresponding outputs (A, A 3 after the formation of a gate is switched on by the to An) . The use of a magnetic connection of appropriate markings to the core memory with a counting device has the advantage that inputs of a gate of this gate are "blocked" or that as counting device one in such a system is "conductive". In the case of the "blocked" gate, the so-called address gates required at the output are always indicated for other purposes for other purposes, for example for the output, and the "yes" indication for the "conducting" control unit St. counter can also be used. In Fig. 3, the corrector under the address counter and the magnetic core mentioned are also a counting device AZ (e.g. ring counter), stores a memory UM, two comparators (RB and AB), each associated with each other Evaluation device AE, the switching means 40 to speaking outputs.

DS1 to DS 12, DS'1 to DS'12 and the output order, for example, the connection setup to switching means A Gl to AG 12 is shown. Record the call number of the call station - Each call station is assigned several different types of call station information (71 to Ii) desired for the call station. As an exception, this call number is to be converted into an example of information of the first kind, 45 connection number. It is still considered to be second kind, third kind, and so on. A speech conclusion of the conversation, e.g. B. for a charge point each type of information is to be printed, again required, the stored connection is arranged, z. B. / 1.1 and / 2.1. To convert this information number into a phone number. These are then firmly assigned to each other. For each group revaluation must accordingly be seen both from the first item of information of the same type as an output into the second item of information. For the similar information / 1,1 second information in the first information erbis Jl, n is the outputs of the corrector Um and can follow.

For information of the same type / 2,1 to J2, n the A conversion output A 2 is provided for establishing the connection. To simplify information, e.g. B. call number, required, so the exemplary embodiment assumed that it is the 55, this information is fed as input information to the two groups of similar information / 1,1 to input £. Assume that there are Jl, n and / 2.1 through I2, n . Each piece of information is a three-digit number in the phone number and each digit is identified by a specific code. If each of these numbers consists, for example, of a three-digit borrowed code Yes or No (for example number, each digit of this number is for example 60 positive potential or zero potential) on the respective four lines at output A1 through under output different characters (yes and no) are identified in a binary code over four lines. For the three-digit number are shown. For the three-digit number, twelve lines are to be provided on the expressing the code, for example at the input passage A1, via which these lines Z? 1.1 to £ 1.12 so different code number is coded. Connected to the four line characters (yes or no). Since there are lines that are intended for a digit, the specified number can be a call number, after the binary code sixteen different codes are also applied to the input E 2 with combinations of characters (yes and no), e.g. a yes code is switched on . Herewith

11 12

both the number and the type of memory are clearly the same, i. i.e., the given number

Number marked. The information (call number) corresponds to the number present at output A 1, as already mentioned above, is a match. At the output A 2 of the counter ZA

correct pulse phase assigned as conversation phase, in the assumed case there is a not associated with the call

and the information is sent every 100 microseconds to the number corresponding to the number of the connection number.

Input E switched on again. because in general the number of a speech

If the number specified at input Zs via the input unit does not match the lines E 1.1 to £ 1.12 assigned to this intercom unit (eg connection number is identical.
Call number) with the identifier (binary code) switched on at the output A 1 or A 2 of the At inputs 17 and 18 of the coincidence memory via lines 1 to 12 or 1 'to 12' ίο gatters K25, as assumed above match, a yes indicator is switched on at the same time, so that an incentive can appear from the corresponding comparator at the output 19 of the coincidence gate K 25, likewise via the output to the evaluation device AE, a yes indicator. At the entrances 20 will give. However, this incentive is only effective if and 21 of the coincidence gate K26, in which in each case, if the corresponding input is connected to the input line £ 2, a yes indicator is also activated to identify the call number, so that is turned on. a no indicator appears at output 22. this

It is assumed that at input £ an means that a yes indicator is connected to input 19 of mixing gate M 13 input line E 1,1 and to a yes indicator and thus a no indicator 20 to input line E 1,12 Output 23 also shows a yes indicator, and furthermore a yes indicator Da at input E 2 at input 24 of coincidence gate K 47 and at output A 1 of memory UM at the yes indicator and at input 25 a no line 1 also a yes indicator and the indicator is switched on, a no indicator appears at the output line 12 is switched on. 26 of this coincidence gate K 47 a no-identification over the input line E2 is indicated by connection 35. At the input 27 of the coincidence gate K48, the yes indicator further indicated that an inverter is connected in each input, it is a yes indicator at the predetermined number over the input and at input 28 a gang £, for example Number is. No flag switched on, so that at the output it is still assumed that at output A 2 of the coincidence gate K 48 a no flag counting device ZA of line 1 'and at 30 appears. As a result, a yes indicator appears at the output 29 of the line 12 ', so mixing gate M 24 has a no indicator. In this case, the traps are not triggered in the comparators RAIRB, AAIAB at all inputs of the following switching processes. Coincidence gate K 50 Yes indicator switched on.

At the inputs 2 and 3 of the coincidence gate That is, the input information (number) Kl is also not turned on at the particular conversation 35 with the present at the output A 2 Informa phase yes Plate ,, so that at tion (number = Port number).
Output 4 of this gate Kl also a yes- From the above it can be seen that it is only switched on at the identifier. At the inputs 5, output 30 of the coincidence gate K49 of the supply and 6 of the coincidence gate K 2 , a yes indicator is also switched on at the same time RAIRB, a yes indicator is switched on at the same time, so that 40 is switched on. This means that only the coincidence gate Output7 is given a no indicator. This means that AE1 of the input selection device AE indicates that a yes indicator is supplied to input 4 of the mixing gate M1. Since the Yes indicator and at the input 7 a Neia identification input information (number) is turned on to a call number character. At the output 15 of the mixed trade, a yes identification gate Ml is connected to the input line E 2 and thus connected to the input 15 of the coin 45 sign. This yes indicator is zidenzgatters Jt49 so that a yes indicator is only activated at input 31 of the coincidence gate ^ 4El, sam. So there both at entrance 30 and at

As to the considered Gespräehsphase to the input 31 of the coincidence gate AEI a yes-Kean-

Inputs S and 9 of the coincidence gate K 23 a sign is switched on, appears at the output 32 of the

No flag is switched on, a yes flag also appears on the 50 coincidence gate AE1.

Output 10 of the gate K 23 is a no flag. Since at the input 33 of the coincidence gate AE 2 of the

At the inputs 11 and 13 of the coincidence gate selection device AE a yes indicator and on

K2A, in which an inverter is connected to each input. Input 34 of this coincidence gate AE2

is switched on, a no indicator is switched on, if the indicator is switched on, appears at the output

that a yes indicator appears at output 14. 55 35 a no flag.

This means that at the input of the mixing gate by switching on the Yes-Kennzeicheneas on the Aqs- M 12, a yes-flag is switched on and thus the output 32 of the coincidence gate AEt the selection at the output 16 of the mixing gate M 12, ie also the device AE appears at the outputs of the at the input of the, coincidence gate K 49, a yes- identification switch-through coincidence gate DS'1 to DS'12 a yes sign appears. If at each input of the 60 identifier, at the inputs of which a yes identifier appears via the off coincidence gates K 49, output lines of the output A2 of the memory UM, this means that a yes identifier is switched on at all input. In the assumed line El ,! £ 1.12 to the input £ ISIN menen Betriebsfali appears both are turned on are characteristic for which the output line an'den Γ as well as on the output line 12 'output lines of the output of Al. memory 65, a Yes-Keonzeichen. Agree to the prevalence rate. In the case under consideration, if gate DS'l is correct, the output information is supplied via the inputs 36 and 37 for the lines shown, so that. ana output mation with the information z. B. at the output A 1 of 38 of this coincidence gate DS'l also a yes

License plate appears. Entrances 39 and

40 of the switching coincidence gate Z> S'12 Yes indicator supplied, so that also at the exit

41 of this coincidence gate DS'12 a yes indicator can appear. With this, the revaluation of the specified call number in the connection number has essentially already been carried out. This result is fed via output still mixing gate AGl to AG 12 outputs the common A'L to ΑΊ2 the Umwerteeinrichtung. It will appear by the above conversion to the output wires 42, ..., 43 of the mixing output gate ^ IGL to AG 12 Yes plate, which are supplied to the control device St. A corresponding evaluation is thus controlled in this control device which has requested the connection number.

The conversion of a given connection number into a telephone number takes place accordingly the switching operations described above and ao is, since they are based on the above-described can be derived in a simple manner from FIG. 3, not further described.

It should be pointed out again that according to the above description for the as selected code only two of the twelve code lines are shown. So it appear at the common Output lines 42, ..., 43 yes-no indicators (e.g. positive potentials and zero potentials), which identify the port number in a binary code.

The exemplary embodiment described above for a time division multiplex system in a telephone system can also be applied to other systems in which corresponding conditions are set.

In the exemplary embodiment under consideration, which relates to a time division multiplex system for a telephone system, a call station is provided, for example, not only with the information assigned to one another in the form of connection numbers and call numbers, but also, for example, authorization information (work authorization, activation authorization, etc.), status information (free, busy, not connected, etc.) and other information (e.g. hunt group, forwarding call) assigned. Certain lines are also assigned additional information, for example, which identifies the type of connection (exchange line, operational line, cross-connection line) or the operating mode (directional or non-directional line). This information, which is not all used to query other information, can, for example, be connected to corresponding outputs, 4 3 to A η .

The information associated with the call stations or line connections is sometimes changed in telephone systems. In conventional systems, this changeable information is determined by the wiring and can only be changed by re-soldering the wiring. Centrally controlled systems offer the possibility of storing information in a central memory UM . The information permanently assigned to a call station or line can then be deleted from this memory UM from a central point, for example by selecting a specific memory location, and changed to other information by subsequently dialing a code number. In this way, you can offer a subscriber new services which, without the aforementioned central corrector, are only possible with great effort or not at all.

Since all information relating to a call station, with the arrangement described above are immediately available for every request, such information need not be requested from other institutions if necessary. This considerably simplifies the circuits.

It should also be mentioned that the comparators RAIAA , like the comparators RBIAB for which the switching operations are described, can convert first information into second information, and vice versa.

Since the information (call number or connection number) circulating in the circulating memory Ua and in the circulating memory Ub for this plus phase is pending for each pulse phase at the corresponding inputs E and E ' (FIG. 2), the input information pending at these inputs is also used for this pulse phase revalued. For each pulse phase, the input information, that is to say the information pending in the form of information of the first (for example call numbers) or second (for example connection numbers) type, is converted into the other type in each case. A cyclical comparison of the respective output results of the comparators RAIAA and RBIAB can now also be used to determine whether information of the same type has already been written to the circulating memory Ub for the corresponding phase in the circulating memory Ua . This is important, for example, for free and busy testing and takes place via the cores rlva , rlvb (Fig. 3) and the cores alva, alvb (Fig. 2) in the central control device St.

Claims (10)

Patent claims: 1. Circuit arrangement for message processing systems, in particular for telephone systems, for the implementation of Eißgabeinformationen in each assigned output information, the input information in the form of information of the first or second type and are to be implemented in the other type, characterized in that one in a certain order the generator supplying the information of the first type, in particular a counter (AZ in FIGS. 2 and 3), is provided which outputs this information of the first type (e.g. connection identification) via its output (A 2) to the input of a corrector (UM) , and this corrector (UM) converts the information of the first type into the associated information of the second type (e.g. subscriber identification), delivers this to the output (A 1) of the corrector, and that a comparison device (RBIAB) is provided which the information that can be removed at the output (A 2) of the generator (AZ) and at the output (A 1) of the corrector (UM) with the input information (at input E) of the first or second type pending at the comparator arrangement (RBIAB) and, in the case of identification of the information of one type, to an output (e.g. B. 42, ..., 43) turns on the information of the other type as output information. 2. Circuit arrangement according to claim 1, characterized in that the corrector (UM in Fig. 3) is queried by means of a counter (AZ) in a specific sequence. 3. Circuit arrangement according to claim 1, characterized in that the input information on a group of input lines (£ 1.1 to E 1.12 in Fig. 3) in a first code which identifies information (e.g. number), and is connected to a further group of input lines (EZ) in a second code, which identifies the type (first or second) of the information, at a specific phase of a phase cycle in a specific sequence. 4. Circuit arrangement according to claim 2 and 3, characterized in that the information of the first type at the output (A 2) of the counting device (AZ) and the information of the second type at the output of the corrector (UM) on the corresponding output lines (z. B. 1 'to 12' and 1 to 12 in Fig. 3) appear in a specific sequence specified by the counting device (AZ) in a code that identifies the information (e.g. number) and appear at these outputs (A 1 , 12) that all information of the first or second type appearing in the mentioned phase cycle at the input (E) can be compared with the corresponding information of the same type present at the respective output (A 1 or A 2). 5. Circuit arrangement according to claim 3, characterized in that on an input line (El, l in Fig. 3) of a group of input lines (El, l to £ 1.12) connected indicators of input information certain of this line (£ 1.1) assigned gates (Kl, K2, K25, K26) of different comparators (RBIAB) are fed to a comparison arrangement. 6. Circuit arrangement according to claim 5, characterized in that an indicator which is connected to an output line (1 in Fig. 3) of a group of output lines (1 to 12) of an output provided for similar information (e.g. A 1) , only the gate (Kl, K2 ) assigned to this input line (£ 1,1) of a comparator (RB) provided for similar information is fed to a comparator arrangement. 7. Circuit arrangement according to claim 6, characterized in that when a match is established between the input lines (£ 1.1 to £ 1.12 in Fig. 3) of said group of input lines (£ 1.1 to £ 1.12 ), which identify the information, and the identifier (coded number) output in code form via the output lines (1 to 12) of an output (A1) provided for similar information via the gates (Kl or K2 to K23 or K24, Ml, £ 49) of the comparator (RB) of a comparator arrangement assigned to this output (A 1), the delivery of an incentive to an evaluation device (AE) takes place. 8. Circuit arrangement according to claim 7, characterized in that the stimulus given by the comparator (RB in Fig. 3) and the stimulus given to an input line (£ 2) in a code which characterizes the type of input information via a gate ( AE1) the evaluation device (AE) is given an incentive to circuit switching means (DS'1 to DS'12), which with the output (A 2) of the input information of one type (first or second type) assigned information of another type (second or first Art) is assigned. 9. Circuit arrangement according to claim 1, characterized in that the information of a particular type assigned to the input information and not provided as input information is supplied to a control device (St) at each conversion via a special output (A 3 to A n) of the corrector (UM). 10. Circuit arrangement according to claim 1, characterized in that the generator delivering the information of the first type in a certain order, in particular a counter (AZ), feeds this information to the input of the corrector (UM) to prepare for the conversion and via a gate (Gl) a Circulating memory releases in preparation for certain storage processes. 1 sheet of drawings © 309 650/210 7.63