DE1076750B - Circuit arrangement for identifying the group membership of multi-digit numbers - Google Patents

Description

The subject of the German patent 972 730 is a circuit arrangement for identifying the group or zone membership of multi-digit numbers. For this purpose, coincidence circuits are used in this circuit arrangement, the individual inputs of which are assigned to the digits of the characteristic numbers to be evaluated. They are connected to lines of local, in particular decadic, line groups on which marking potentials are distributed according to the number in question, through which the individual inputs of the coincidence circuit in question are activated, whereby an output potential occurs at its output which controls an evaluation element and thereby the group in which the number is located. According to the main patent, a special method is provided for the case that all numbers fall into the same group, in which only the digit of one digit of the number, preferably the last digit, varies. According to claim 3 of the main patent, this grouping problem is solved in that an input of the relevant coincidence circuit corresponds to several, preferably two, digits of the assigned number. Such a coicidal circuit is referred to below as a point coicidal circuit. In Fig. 1 a of the main patent, such a point coincidence circuit is included under the designation A ^ 325. In the accompanying description it is stated that because of the operating mode of the coincidence circuit N 325 selected in this way, all of the four-digit numbers to be grouped that begin with the number 325 fall into the group belonging to this coincidence circuit. Such a group of numbers, in which the numbers differ only in the last digit, is denoted in the following as a group of digits Tje.

With the intended application possibilities of this circuit arrangement, however, the case often occurs that, with a few exceptions, all the numbers belonging to such a digit group fall into the same group or zone. When using the coincidence circuits specified in the main patent, such a simple position coincidence circuit as the circuit N 325 cannot be used in this case. Instead, you could z. B. proceed as shown here in FIG. In this example, the grouping of numbers with the three digits Sl, S2, S3 is provided. The group of digits will now be considered, which contains all numbers, the. starting with the number 22. The number 221 belongs to the group with the evaluator Z1, all other numbers in this group of digits may then belong to the group with the evaluator Z2n . Accordingly, the evaluator Z1 is connected to the output of the coincidence circuit Kl , its circuit arrangement
to identify the group membership of multi-digit numbers

Addendum to patent 972 730

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Witteisbacherplatz 2

Dipl.-Ing. Alfred Mattem, Munich,

and Dipl.-Ing. Otto Kneigel, Gauting near Munich,

have been named as inventors

Inputs belonging to the digit line 2 and the point S2 which belongs to the number 1 line of the point ο of the members of the number 2 line of the point S ₁ * are fed. 3 In a corresponding manner, the coincidence circuits K 2 to Kn are connected to the lines belonging to the numbers 222 to 22 η. The evaluator Z 2 η is connected to their outputs, possibly via the decoupling directional conductors Gi to Gn , which means that the latter numbers are all assigned to this evaluator. It can of course also be the case that the evaluator Z1 is assigned more than one number, in which case more than one coincidence circuit would also have to be connected to it.

However, this method has the disadvantage that many coincidence circuits, namely η-ί , are required for the numbers 222 to 22 ", which means a great deal of technical effort. ■

The invention now brings great progress in that it significantly reduces this effort. The circuit arrangement according to the invention is characterized in that, for the purpose of excluding individual numbers from the group of digits, individual coincidence circuits with their own evaluators are provided for these numbers and that when these numbers are marked, blocking circuits are influenced via the outputs of the coincidence circuits in question, which the of the associated

909 758/121

3 4

Place coincidence circuits controlled evaluator of the npn transistor T and its base counteracting prevent. stand R used. If the polarities are interchanged In FIGS. 2 and 3, two different offsets of working and resting potentials would have to be used for such blocking circuits in accordance with a pnp transistor, which is known to interact with the coincidence circuits in the same way as an npn transistor , but also given, with an exception in each case from the reverse current direction. At the emitter of the number group is made. The transistor T is the output of the point coincidence - FIG. 4 shows a circuit where several switches KIn and the base series resistor R are made, so several individual outputs of the individual coincidence circuit K 1 coincidence circuits are present and where io is connected while Collector also feeds the evaluator the possibility of certain multiple switching Z2n. The internal resistances of the Auswerter Zl lines is indicated. and ZIw are large in this circuit example. FIG. 5 shows an exemplary embodiment for the circuit with certain coincidence potentials that precedes the source resistances of the quiescent and working circuits. If now at the emitter ground potential and circuits and blocking circuits. 15 is positive potential at the series resistor R , FIG. 2 shows a first exemplary embodiment for the method according to the invention as a result of the method according to the invention flowing through the resistor R. The same grouping plan as in FIG. 1 is present here again due to the injection current of the transistor, which is limited by it, so that the evaluator Z2n can respond. Accordingly, the coincidence circuit K is 1 in is now also connected to the connection point between the same manner to the lines such as 20 digits coincidence circuit Kl and the Vorwidervorher. In addition to the associated stand R, ground potential is at its output, so, since the emitter and evaluator Zl still have an input of the base used have the same potential, no injection blocking circuit Sl can be connected. This consists of current flowing and the transistor is blocked, which prevents an exclusive OR circuit with two inputs from responding to the evaluator Z2n . To walked and an exit. It has the property of ensuring that the transistor is blocked in the latter case safely at the working potential occurring at its inputs, one can still deliver the resistor Rv output if this is provided to only one at the base, via which the two to ground Inputs is fed. As a working negative reverse bias voltage - Uv in this case out potential is the ground potential and can act as a rest.

potential to assume the potential + U. Accordingly, if from a group of digits there are several expressions at its second input that are to be taken, then the digit coincidence circuit KIn can also be used on its output and the evaluator 7,2η for the group of digits described above can also be used on its output z. B. between the outputs of the connected. In this embodiment, the evaluators are individual coincidence circuits and the one example with a connection to the positive input of the exclusive OR circuit a tive pole + U of the operating voltage source. The mixer puts, which at its output work other connection must therefore, in order to deliver it to the response potential, if at one of its inputs, the connected coincidence work potential occurs. In this circuit, however, a negative potential is added to the circuits - also the response of the evaluator for which is led, as which here the ground potential 4 ° point coincidence circuit prevents if one of the is used. At rest, the LEI must individual coincidence circuits is activated, therefore obligations to the pole of the operating voltage source Fig. 3 shows another embodiment are that the potential U + is, and they must for The inventive method. It is here also for the purpose of generating the marking potential at ground if the same grouping plan is available as in the. The execution of this marker 45 Fig. 1 and 2. The coincidence circuits Kl and, since they in this context irrelevant KIn are not specified exactly as before closer to the Leitungsgrupist. If both inputs pen connected. At the output of the individual coincidence circuit KIn ground potential coincidence circuit if 1 is the input of the delay, it forwards this potential to an amplifier and inverter / 1 and at its output the input of the OR circuit vS "l. If the indi- 5 ° Evaluator Zl connected to one terminal, virtual coincidence circuit Kl not activated. The amplifier and inverter Jl causes the Verden is, is at the second input of the OR circuit swap of the polarity of rest and work the positive potential - \ - U. In In addition, it has the OR circuit S1 at the output. Work-like amplifier properties that the potential provided by it, that is, ground potential, whereby the potential delivered is different from that of a significant Z2n to respond However, if the coincidence circuit puts the output potential through the line, the number to be excluded 221. Because of its inversion If the property leads to the groups has been marked, the second connection of the evaluator Z1 in this circuit-associated individual coincidence circuit Kl is activated to the other pole of the operating voltage source. Both inputs of the OR circuit receive ^ ⁰ as in Fig. 1, here to the ground pole and there ground potential as working potential, which is why at their to the pole with the potential + U. Except for the Koin output, rest potential, i.e. the potential + U, occurrence circuit K 1 is still the coincidence circuit occurs. The evaluator Z2 η cannot respond, KIn available. It has only two inputs and is only the evaluator Zl. With this, the effect desired only on the line belonging to number 2 has been achieved. ^{With 5} 5 Si and connected to the line belonging to number 2 of this circuit, the effort is considerably less than that of the one in point S2 . It is indicated by marking fig. 1 specified. potentials activated, the numbers 221 to 22 «ent in Fig. 2 is also an example of the speak. In all of these cases, it delivers an out-of-realization of an exclusive OR circuit output potential, which the evaluator Z2n specifies as it is required here. There will be ⁷⁰ speak for it. Now, however, the opposite

1 U / D / OU

side influencing of the potentials present at the output of the coincidence circuit KIn via the inserted directional conductor G 1 must be taken into account. It will be shown that the purpose aimed at by the invention is achieved with the aid of the amplifier and inverter / I and the directional conductor Gl. As in FIG. 1, the evaluator Z2n is made to respond by ground potential. This potential occurs when marking potential = ground potential is present on the lines connected to the inputs of the coincidence circuits KIn. If the coincidence circuit Kl is activated at the same time, it also supplies ground potential at the output, and the amplifier and inverter / I supply positive potential at its output, which is via the directional conductor G 1 because of its appropriately chosen polarity to the input of the evaluator Z 2 η enforced and therefore prevents the response of the evaluator Z2n in this case, which is also desirable. At the same time, the evaluator Z1 responds. The amplifier property of the amplifier and inverter / 1 has the effect that the positive potential supplied by it asserts itself against the potential output by the coincidence circuit KIn despite its load by the evaluator Z1. Of course, it must also be ensured that any positive potential present at the output of the coincidence circuit / CIm does not cause the evaluator Z1 to respond incorrectly. However, this is prevented by the directional conductor Gl, which in this case is stressed in the reverse direction. This proves that this circuit arrangement can perform the required function. Only two coincidence circuits and an amplifier and inverter are required here. The evaluator Z1 could of course also be connected, for example, to the connection point between the associated coincidence circuit Kl and the amplifier and inverter J1, with the potential + U having to be at its second connection. In this case, of course, the directional guide G1 can be omitted, since its task is no longer necessary. With this circuit, the source resistances of the resting and working potentials do not need to be small compared to the internal resistances of the evaluators.

The circuit arrangement shown in FIG. 4 does not differ in terms of function from that in FIG Fig. 3 shown. However, some additions have been made to the arrangement here, whose possible application is to be shown.

First of all, when assigning the digit group to a group of numbers, two exceptions are made to one in the previous case. The number 221 belongs to the evaluator Zl and the number 222 to the evaluator Z2, while the remaining numbers 223 to 22 η of the digit group 221 to 22n belong to the group of numbers with the evaluator Z3 η . The evaluator Z3w is here, for example, also connected to the associated digit coincidence circuit KIn via an amplifier and inverter / 3, whereby the symmetrical structure of the circuit with similar components has an advantageous effect, especially if there are 7, uh \. & Ii different digit number groups in the same group of numbers fall. In order to prevent the evaluation of the evaluator Z 3 η from responding to the two exceptions provided, the outputs of the amplifiers and inverters 11 and / 2 are connected to the input of the to evaluator Z via the two directional conductors G12 and G 22, which also act as decoupling conductors here 3 η belonging amplifier and inverter / 3 connected. This ensures that when the marking potential is distributed on the lines corresponding to the numbers 221 and 222, the response of the evaluator Z 3 η in the manner already described with reference to FIG. 3 is prevented. In these cases, therefore, only the associated evaluator Z1 or Z2 responds. In this circuit arrangement, directional conductors are also provided between the coincidence circuits and the connected amplifiers and inverters. These are the directors GIl, G 21 and Gn. In addition, multiple circuit symbols have been indicated at the inputs of the amplifiers and inverters. At these points, because of the directional conductors connected in front of them, which then act as decoupling directional conductors, other coincidence circuits for certain numbers or groups of digits can be connected via further decoupling directional conductors, if they fall into the group of the evaluator connected to the relevant amplifiers and inverters. In this way, the numbers can be grouped according to any given grouping plan.

FIG. 5 shows a more detailed embodiment of the circuit as it is shown in FIG. Star connections made up of directional conductors and one resistor each were used as coincidence circuits. So the coincidence circuit Kl correspond to the holding elements G 13, G 14 and 2? 13, the coincidence circuit K 2 the switching elements G 23, G 24 and R23 and the coincidence circuit Klη the switching elements Gl and RIn. The amplifiers and inverters consist of transistor amplifier stages with one transistor and two resistors each. The amplifier and inverter / I corresponds to the transistor Tl with the resistors .RIl and i? 12, the amplifier and inverter J 2 corresponds to the transistor Γ 2 with the resistors R 21 and 2? 22 and the amplifier and inverter J 3, the transistor T 3 with the resistors R 31 and 2? 32. The marking potentials are distributed with the aid of the selector arms d 1, d2 and dZ . So that, for example, from the switching elements G 13, G14 and 2? 13 existing coincidence circuit has working potential, i.e. ground potential, at its output , the selector arm dl must be set to position 2, the selector arm d 2 to position 2 and the selector arm d 3 to position 1, and afterwards the make contacts pI ₁ p2 and pZ are closed, whereby the connected lines and thus also the inputs of the relevant coincidence circuits are connected to ground potential and the associated evaluator Z1 is made to respond. If the working contacts pl, p2 and /> 3 are not closed, the inputs of the coincidence circuit Kl via the resistors R 12, 2? 22 and 2? 31 the positive potential + U, i.e. rest potential, is supplied. The potential present at the output of a coincidence circuit is converted with the aid of the connected amplifier and inverter. The mode of operation of an amplifier and inverter is illustrated using the amplifier and inverter with the transistor T 1 and the resistors 2? 11 and 2? 12 explained. The emitter of the transistor Tl is connected to the positive potential + U and the collector is connected to ground via the associated evaluator Z1. If the associated coincidence circuit supplies rest potential, then at the ends of the resistor R 11 and 2? 12 formed voltage divider, at whose tap the base voltage for the transistor Tl is taken, the positive potential

tial + U and the even more positive potential + Uv, so that the base is more positive than the emitter and the transistor is blocked and the evaluator Zl in its main circuit cannot respond. If, on the other hand, the coincidence circuit supplies working potential, that is to say ground potential, the transistor is made conductive, since its base potential is lowered below the emitter potential via the voltage divider R11-R12. The resistors of the voltage divider are used to properly dimension the base voltages. When the transistor is conductive, its collector has almost the positive potential + U. The voltage applied to the base has also been inverted. The evaluator Zl responds, and in addition, the input of the amplifier and inverter / 3 consisting of the transistor T 3 and the resistors R31 and R32 is supplied via the directional conductor G12 with such a large positive potential that the transistor T 3 can in no way be made conductive , even if there is ground potential at the inputs of the coincidence circuit of the components GXn and RIn belonging to this amplifier and inverter. The derivation of the positive potential is prevented by the resistor RIn and the directional conductor GIk, which in this case is stressed in the reverse direction.

Claims (7)

PATENT CLAIMS: 1. Circuit arrangement for identifying the group membership of multi-digit numbers below Use of coincidence circuits, the inputs of which are assigned to the digits of the relevant number and on lines of local, in particular decadic, line groups are connected to which marking potentials are determined for the purpose of determining the group membership of a number are applied, which control an evaluator via the output of the corresponding coincidence circuit, with its response the group in question is identified, with certain coincidence circuits as digit coincidence circuits are thereby assigned to a corresponding digit number group that a Input of the relevant digit coincidence circuit several of the last digits, preferably assigned to the last two, according to patent 972 730. characterized in that for the purpose of taking individual numbers from the digit group for these numbers individual coincidence circuits (KI ₁ K 2) with associated evaluators (Zl, Z 2) are provided and that when these numbers are marked via the outputs of the relevant coincidence circuits (Kl, KZ) blocking circuits (Sl; II, Gl) are influenced, which prevent the from the associated position coincidence circuits (KIn) controlled evaluators (Z 2 «, Z 3 m) from responding. 2. Circuit arrangement according to claim 1, characterized in that the blocking circuit (J? 1) consists of an exclusive "OR" circuit with two inputs, at which an individual coincidence circuit (Kl) and a position coincidence circuit (KIn) and at the output of the Evaluator (Z2n) for the digit coincidence circuit is connected. 3. Circuit arrangement according to claim 2, in which the source resistances of the rest and working potentials are small compared to the internal resistances of the evaluator, characterized in that the exclusive "OR" circuit (Sl) consists of a transistor (T) with a base series resistor (R) exists, whereby the individual coincidence circuit (Kl) is connected to the free connection of the series resistor (R), the position coincidence circuit (KIn) is connected to the emitter and the evaluator (Z 2 «) for the position coincidence circuit (KIn) is connected to the collector. 4. Circuit arrangement according to claim 1, characterized in that the blocking circuits each consist of the series connection of an amplifier and inverter (/ 1) and a directional conductor (Gl) permeable to the working voltage output by this, with an individual coincidence circuit (Kl) at the input an amplifier and inverter (/ 1) and the free pole of the associated directional conductor (Gl) is connected to the connection point between the position coincidence circuit (KIn) and the associated evaluator (Z2n) . 5. Circuit arrangement according to claim 4, characterized in that the respective evaluators (Z 1) are connected directly to the individual coincidence circuits (Kl) . 6. Circuit arrangement according to claim 4, characterized in that the evaluator (Zl) belonging to the individual coincidence circuits (Kl) at the connection point between the associated amplifier and inverter (/ I) and directional conductor (Gl). are connected. 7. Circuit arrangement according to one of claims 4 to 6 ,. characterized ^ that as amplifier and inverter (II, 12) each have a transistor amplifier stage. (Tl, RIl, R12; TZ ₃ R21 ^ .R22) is used in emitter circuit. 1 sheet of drawings ® 909 758/121 2.