DE1211279B - Circuit arrangement for monitoring individual multi-digit codes in telecommunication systems, in particular telephone branch systems - Google Patents

Description

Circuit arrangement for monitoring individual multi-digit key figures in telecommunication, in particular telecommunication private branch exchange systems, in telecommunication, in particular Remote intercom systems, it is often necessary to enter certain multi-digit Monitor key figures so that certain switching operations when such key figures occur can be carried out. It is often desirable in private telephone extension systems, that participants who do not have long-distance dialing authorization do have certain long-distance dialing connections, that lead to very specific participants, for example because it is in In this case, it is a matter of connections to bodies that have been established with the owner of the relevant PBX are in a permanent business relationship. But it comes the reverse is also possible, in that participants who are actually authorized to dial remotely, must be prevented from making specific long-distance dialing connections. In these cases it is necessary that the individual phone numbers assigned to the Subscriber chooses to be monitored so when sending out a very specific one Call number the connection in question is either blocked or permitted.

In order to carry out such monitoring measures for individual multi-digit codes, arrangements are already known in which, with the aid of dialers that are wired in a suitable manner, the telephone numbers are monitored with the above-mentioned objectives. These arrangements are, above all, when it comes to multi-digit numbers, very extensive and thus expensive and have a further serious disadvantage in that changing the numbers or subsequent storage of other numbers to be monitored is very difficult.

The invention eliminates these disadvantages of known arrangements for monitoring individual multi-digit codes in telecommunication, in particular telephone extension systems, in that in a matrix formed from memory core, one of which is used to store the individual numerical values and the other coordinates to determine the value of these numerical values, the ever - Because indicators to be monitored are assigned and, through their guidance, the value of the individual digits of the assigned identification number are provided which, when a reset pulse is supplied for all cores of the matrix, only lead one or no reading pulse if all digits are one in the Matrix stored key figure are digits of a key figure to be monitored. The occurrence or non-occurrence of a reading pulse on the reading wires mentioned can then be evaluated to trigger a specific switching process, for example to disconnect or release a connection.

There are basically two options for guiding the reading wires. One is that the reading wires assigned to the key figures to be monitored are routed through all lines of the M-atrix that are not used to determine a digit value of the relevant key figure, while the other possibility consists in the storage of the individual digits A memory cores to be monitored in each row of the matrix with the reading wires routed through these cores and connected in parallel to a certain potential form the input line of an AND circuit, the output of which is only a potential indicating the storage of a code to be evaluated leads when the input potential of the AND circuit connected to the reading wire of one of the rows is not compensated for via the reading wires of other rows of the matrix. In the first-mentioned option, an additional memory core is expediently provided for guiding the reading wires, through which these wires are guided and which is switched to its memory state each time a code is stored, the reading pulse caused by this core on a reading wire being one or more reading pulses others, the storage of the digits of the relevant code number is not compensated or made ineffective.

If, for example, n codes with the same input digit or sequence of digits are to be evaluated, then n AND switching eyes are expediently formed, each consisting of a - the memory position of the gate circuit evaluating the first digit or sequence of digits and each - one of the remaining ones Assemble digit sequences assigned reading line. In this embodiment of the matrix according to the invention, it is not necessary that there are as many lines as the key figures to be monitored, but there is also the possibility of evaluating key figures whose number of digits exceeds the number of memory lines in a matrix, several through the Number of digits of the individual key figures monitoring switching means to provide successively activated reading wires and to lead them according to the respective digit values through cores of the same memory lines. In this way it is possible, for example, to> evaluate a 16-digit key figure to be monitored with the aid of a matrix which only comprises eight memory lines.

In the drawings, an embodiment of the invention is shown. -Fig * 1 shows the facilities necessary for storing key figures in the matrix , FIG. 2 the wiring of the individual none, F i g. 3 and 4 the guidance of a reading wire when blocking a single number, FIG . 5 the guidance of the reading wire when activating a single number, FIG . 6 the guidance of a reading wire when free; circuit of several numbers, F i g. 7 another possibility of guiding the reading wire when activating several numbers and F i g. 8 shows a circuit detail which becomes necessary when a number of reading capacities are assigned to a code to be monitored.

In Fig. 1 it is assumed that the arrangement is connected to a tracking device ML of a telephony private branch exchange, by means of which the individual series of current impulses emitted by a subscriber are recorded and recoded. In addition, the respective end of a pulse train is determined in the tracking device ML or in the office transmission occupying this tracking device, which is reported to the arrangement shown via the lines! Reg and CTL6. The monitoring of certain key figures' resp. - The triggering of switching processes in the connected private branch exchange, ie in the follow-up mechanism ML or in the associated exchange transmission, takes place by the supply of negative pulses to the line K on the part of the device shown.

The storage of the individual digit values -a incoming call number in the tracking device ML takes place in the four-way code over the lines a 1, a 2, a 3 and a 4. As a result, the matrix has four column lines, while the number of rows in this matrix is determined by the number of digits highest possible phone number is determined. If it is assumed that only one reading wire is assigned to each telephone number to be monitored, then the number of memory lines corresponds to the number of digits in the telephone number. If, on the other hand, two reading wires are assigned to each telephone number to be monitored and activated one after the other, the matrix only needs to have half the number of memory lines.

It is assumed in the following that the device ML is already occupied by an exchange connection set and the first pulse line is transmitted to the exchange. At the end of this series of pulses, a positive pulse occurs with a delay of about 8 msec at point! Reg, so that the counting chain ZK, which consists of the bistable multivibrators F1, F2 and F3, is advanced by one step. Through this counting chain ZK, the binary counting of the number of the individual rush series is carried out, and each time the counting chain is incremented, a corresponding command is given to the recoding device UC, through which the binary code provided by the counting chain ZK, which reflects the number of the rush series just entered, is transferred to the code 1 is converted from n in order to make the corresponding row line of the matrix effective. By means of the potentials of the counting chain ZK, the recoder UC is set in a preparatory manner so that when a pulse arrives via the line n 1, the respectively provided driver station U1 'to U7 is actuated. After running the first impulse series thus takes place an operation of the driver stage Ul by the coming via the input pulse n1. This pulse connected to input n1 is generated from the positive pulse edge of the pulse appearing at input CTL6, about 8 ms after the pulse edge occurs at input! Reg. If this positive pulse edge arrives at input CTL6, a pulse with a duration of around 10 Rsee is generated in block Y. This pulse reaches the gate circuits G 1 and G 2. The gate circuit G 1 is permeable when the counting chain ZK is switched to the positions 1 to 7 , ie. H. while the first to seventh digits of a code to be recorded are being saved. The storage driver ETR is actuated via the AND circuit G 1 and sends a strong current pulse of negative polarity to the resistors Rh 1 to Rh 7 at its output n1. This pulse also reaches the resistors Rvl to Rv4 via the Zener diode D5 and makes the driver stage Ul effective via the recoding circuit UC.

The cores K11 to K74 are always switched to the respective storage position by two adding half currents. The half-currents flowing in the horizontal storage wires are generated with the aid of the digit counting chain ZK by the driver circuit U1 to U7, as already mentioned. The resistors Rh 1 to Rh 7 are dimensioned in such a way that just half of the storage current required for the relevant storage wire flows in the horizontal storage wire. Likewise, the resistors Rv 1 to Rv4 are dimensioned so that half the storage current also flows in the vertical storage wires. If the half-currents mentioned flow through a certain storage core in the horizontal and vertical direction, the relevant core is tilted into its storage position. This applies to all None Kll to K74. The No KO is wound in such a way that it can be tipped into its storage position just by the horizontal injection stream.

The Zener diode D 5 has the task of allowing a current to flow through the vertical storage wires only when a sufficiently positive potential is applied to points a 1 to a 4 to identify the individual numerical values in the tracking device ML. The negative potential, on the other hand, which indicates that no information is stored, is falsified by a few volts in the voltage value by a relatively high-resistance voltage divider. In order to prevent small fault currents from flowing in the vertical storage lines as a result of this falsified negative potential, the Zener diode D5 is provided. In addition, each of the inputs a1 to a4 is also equipped with a circuit arrangement which consists of the resistors R 1 to R4, the capacitors C1 to C4 and the diodes D 1 to D 4. The capacitors C 1 to C4 have the task of storing the potential that is connected to the points a 1 to a 4 by the follower ML. The resistors R 1 to R 4 are so dimensioned that on one hand the function of the counting device in Mitlaufwerk ML is not impaired and on the other hand, the capacitors Cl to C4 within the - delay time of 8 msec, the potential of the points a 1 to a 4 assumed with sufficient precision to have. In addition, the capacitors C 1 to C 4 still have to be dimensioned in such a way that they approximately hold their charging voltage during the approximately 10 #tsec storage current pulse. The diodes D 1 to D 4 serve to decouple the vertical storage wires from one another.

If the seventh digit has been recorded in the counting chain ZK, the amplifier stage UO is actuated via the outputs of the individual flip-flops Fl to F3 and the AND circuit G3 , so that the pulses from the timing element Y no longer reach the AND gate G 1 can happen. The AND gate G2 is now turned on by the AND gate G3 , so that a positive pulse edge at the point CTLö can reach the storage driver ATr via the pulse stage Y and the AND gate G2 . This driver ATr supplies a strong current pulse to the reset line R, which is looped through all cores from KO to K74 with the same number of turns. Every saved none generates a read pulse during the reset process. The read pulses generated in the stored cores are generated with the aid of FIG . 1 not shown, but in the F i g. 3 to 7 reproduced reading wires and diode combinations are used to recognize whether the combination of numbers stored in the matrix is identical to a marked, activated or blocked combination of numbers.

As already mentioned, in FIGS. 3 to 7 different matrices are shown separately again, the saved none being strongly drawn out for reasons of clarity.

In Fig. 2 shows a single No Kn, on the basis of which the current and voltage directions of the cores K 11 to K 74 can be read. The No K n in Fig. 2 has a horizontal storage line TS-h and a vertical storage line TS-v. If both injection lines carry the half-current required in each case, the core K n is transferred to its storage position. If a reset pulse is now on the line R, the No Kn is tilted back, and as a result of this tilting back, the read line L carries a read pulse. The current arrows are drawn in such a way that current flows from + to - . At point L, a negative pulse arises due to the restoring current pulse, which is identical to the interrogation current pulse, if the core has been previously stored.

The F i g. 3 shows the blocking of the number 1671815. The reading wire is led through the additional core KO and in the individual memory lines through all those none that are not used to store the specified sequence of digits. It is assumed that the individual digit values are stored in a four-digit code, so that four memory cores are provided in each memory line, with the exception of the first memory line, which still has the additional core K0.

If the reset pulse is sent to the line R in FIG. 1 , the tilting back of the core K 0, which is in any case unstored, results in a negative pulse, while none at the cores K12, K13, KI4 to K72 when the aforementioned blocking number is stored Counter-pulses arise so that the negative voltage of the core K 0 extends to a decoupling diode DK 1 in FIG. 1 reproduces. The corresponding reading pulse thus arrives at input K of the tracking device ML and there causes the connection in question to be blocked. If one of the weakly drawn lines had not been tipped over when the mentioned sequence of digits was stored, a positive pulse from the relevant core would have reached the corresponding reading wire in addition to the negative pulse of the core K 0, which would have compensated for the pulse of the core K 0, so that in this case no evaluation pulse could have appeared at the input K of the tracking mechanism ML. If several none were stored through which the read line is looped, the negative pulse of the core K 0 would have been converted into a positive pulse, which, due to the diodes DK1 and DSW, could not have influenced input X either.

In Fig. 4 shows the blocking of the same number 1671815 with the help of a diode link. Diodes connected to an AND gate are led through each stored none. The No Kll is wired with a resistor instead of a diode. If the core Kll goes back to its zero position when the reset pulse is supplied, the negative pulse thus produced can only then pass unhindered to the decoupling diode DK in FIG . 1 arrive when all the heavily drawn diodes in FIG. 4 are blocked. But this is only the case, although all heavily subscribed nuclei were reversed in their storage location based on the recorded number blocking. If this is not the case, the negative pulse of the core Kll is compensated for by one of these diodes and as a result cannot reach the diode DK and thus the input N of the follow-up mechanism ML. The blocking of a certain number is therefore possible with two different read loop wirings, whereby preference will always be given to the circuit with the less effort.

A very similar arrangement results when a certain number is activated, which is shown in FIG. 5 is shown. In Fig. 5 it is again assumed that the very number in the matrix of FIG. 1 is stored that is to be activated. The reading media would then be pulled through the cores K 11, K 13 to K74, which were not in their memory position due to the stored number 0810225. If - now on the reset wire R of FIG. 1 given a reset pulse, no pulse reaches the 'Entkopplunisdiode DK- of the reading wire L in FIG . 5, so that the MT drive ML is not stimulated to block the connection in question. With this * wiring of the matrix, no read wire is passed through the core KO.

In an arrangement according to FIG. 5 it is, however. not possible, -. to thread through several reading loops to the free-opening function, - d. H. several multi-digit telephone numbers to be connected must be provided. If several such reading loops were to be threaded through, this would lead to false triggering of connections through mutual linking.

The arrangement # according to F i. G. 7, on the other hand, allows any number combinations, for example starting with 0 , to be activated, whereby several reading loops L l> L2 and L 3 can be drawn through. The wiring of the cores K12 and KI4 in the. first Speicherieile indicates that # is the number 0 in principle locked in the first place, with a ## Sperrverdralitun analogous F i Z. 4. The negative inhibit pulse from the cores KI2 and K14, however, by the reading loops L 1, L 2 or L 3 is then compensated if no read pulse is induced in one of these read loops by a memory core tilting back, i. H. if the corresponding digit of the number to be activated has been stored in each memory line. In Fig. 7 , the reading loop is routed through the kernel in such a way that it only runs through none that have not been stored in the present blocking number. The negative impulse that is induced in the cores K12 and K14 is thus dissipated to earth via the reading loop Ll and can therefore not take effect.

The activation - the number 0810225 - can, however, also with the aid of a circuit arrangement as shown in FIG . 6 is shown, to be made. At the same time, the core KO »delivers a negative read impulse. This negative read pulse can only not for decoupling diode DK and damitzum input 9 of the Mitlaufwerkes ML reach when to K, a positive pulse is produced in all strongly drawn cores K 12, K 14 73 just cancels or more than compensated for the negative pulse.

It is possible to use the matrix of FIG. 1 or the corresponding versions of wire F i g. 3 to 7 to be used several times, for example in such a way that the in F i g. 1 is used to block a 14th number. It is also necessary that a separate reading wire or a separate link is made for the first to seventh digits and for the eighth to fourteenth digits. In the circuit arrangements of FIG. 3 to 7 , earth potential was always applied to one side of the reading wire. It is now possible to apply the earth potential to the respective reading wires via a switch that is controlled as a function of the number of incoming current impulse series. This can be done in such a way that, as shown in FIG. 1 is drawn in dashed lines, to the counting flip-flops F 1, F2 and F3 , another flip-flop F4 is switched on, which - after going through the digit counting chain Fl to F3 once is actuated and the first reading loop is disconnected and the second reading loop - turns on.

If more than one combination of digits is to be blocked or activated, then the reading loops can no longer be connected by the flip-flop F 4, as this would lead to ambiguities. In this case it would be all combinations of the first part of wired numbers together with all second parts of wired numbers marked in corresponding white.

In this case, instead of the flip-flop F 4, a circuit arrangement according to F i g: 8 is to be inserted. This arrangement essentially consists of a marking flip-flop M-FF which, in the idle state, connects ground potential to the first reading wire of the relevant number via the resistor RE with the aid of the storage capacitor CS. This reading wire activates the marker # flip-flop M-FF via the diode DSW, which is switched as a threshold value. The resistor RE and the capacitor CS are used to store the position of the marker flip-flop M-FF. This intermediate storage is necessary because a flip-flop memory cannot supply the potential for its own switching. The marking flip-flop M-FF also contains a clear input GL6. If the marking flip-flop M-FF was actuated by a pulse from the first reading wire, it switches ground potential to the second reading wire via the diode D 8. The second reading wire finally leads via a corresponding link to a decoupling diode DK.

The wiring, the memory matrix according to FIGS. 3 to 6 can of course also be done in another way. In particular, there are switching combinations from a mixture of the switching principles of FIG . 3 to 7 conceivable.

It can also be useful to let the read pulses become effective at input K only during a specific point in time. For this purpose, it would be necessary to connect an IM pulse stage downstream of the reset pulse driver A Tr so that the read pulse at input K can only become effective after a certain set delay time, which depends on the core material selected.

Claims (1)

Claims: 1. Circuit arrangement for monitoring individual multiple key figures in telecommunications, especially telephone extension systems, d a -. Characterized in that in a matrix formed from memory cores (Kll, K12 ...), one of which is coordinates for storing the individual numerical values and the other coordinates are these digit values to determine the place values, the respectively to be monitored indicators assigned and -the by their reference value of each item of the respective associated code characterizing sense wires are provided which, when the supply of a RückstelEmpulses for all the cores of the matrix only a or do not lead a read pulse if all digits of a code number stored in the matrix are digits of a code number to be monitored. 2. Circuit arrangement according to claim 1, characterized in that the reading wires assigned to the characteristic numbers to be monitored are passed through all of the rows of the matrix which are not used to define a digit value of the characteristic number in question. 3. Circuit arrangement according to claim 1 and 2, characterized in that the read wires are guided through an additional memory core (KO) switched into its memory state each time a code is stored, and the read pulse caused by this core (KO) on a read wire by one or multiple read impulses from other cores that store the digits of the relevant code number are compensated or made ineffective. 4. A circuit arrangement according to claim 1, characterized in that the storage cores used for storing the individual digits of a code to be monitored in each row of the matrix with the reading wires routed through these cores and connected in parallel to a certain potential line the input line of an AND circuit form, the output of which only leads to a potential indicating the storage of a code to be evaluated if the input potential of the AND circuit connected to the reading wire of one of the rows is not compensated or rendered ineffective via the reading wires of other rows of the matrix. 5. A circuit arrangement according to claim 4, characterized in that by the individual lines of the matrix depending a formed by the sense wire of the respective cores in conjunction with an isolator partial path control of a lock gate in the way the various items of an associated monitoring at the code memory cores, that all partial paths are blocked only when all digits of a code to be monitored are stored and that the resulting non-appearance of an output pulse at the time of the evaluation marks the storage of a code to be evaluated. 6. The circuit arrangement according to claim 4, characterized in that formed for the evaluation of n key figures with the same input numeral or -ziffernfolge n AND circuits, each composed of a memory location of the first digit or sequence of digits evaluating gate and one each to each Assemble the read line assigned to the remaining digit sequences. 7. A circuit arrangement according to claim 1, characterized in that for the evaluation of codes, the number of digits of which exceeds the number of memory lines in a matrix, a plurality of switching means monitoring the number of digits of the individual codes is provided one after the other and the respective digit values corresponding to none of the same memory lines are led. 8. A circuit arrangement according to claim 7, characterized in that the switching from one reading wire to another is carried out by the switching means detecting the respective number of positions by means of a bistable switching device, the respective switching state of which is maintained by special storage means until the switchover is completed.