DE1237632B - Electronic selection circuit - Google Patents

Description

Electronic selection circuit Addendum to additional patent: 1215 777 The electronic selection circuit described in additional patent 1215 77 7 is used to solve the task of designating the first free device in a defined order by supplying a potential from a plurality of devices, any of which can be occupied , which differs from the other equipment supplied potentials by its height. The selection circuit can thus take the place of known voters.

Your main advantage is that it can be used by anyone Dialing process always takes the same time, regardless of which position in the order of the devices that finally designated by the dialing process Establishment.

This electronic selection circuit includes one of the number on it connected facilities corresponding number of switching stages. Any facility supplies the level assigned to it with a potential, the level of which corresponds to the current occupancy the facility. According to the two possible states, namely free and occupied state, these potentials can therefore be assigned two values, namely as free and occupancy potential. As in the individual stages and in cooperation of the stages only potential differences are effective and evaluated no restrictive conditions regarding the absolute value of these potentials. These absolute values can thus be used jointly for all levels in accordance with the outer Conditions are specified under which the selection circuit has to work. The selection circuit leads to the designation of the device determined by a dialing process this institution has a potential for designation, which in its height differs from all other facilities supplied, neutral potential deviates.

Each switching stage has a test input to which the associated device transmits the potential indicating its current occupancy status, and one Designation output, which you can use to send your associated facility the supplies the potential used to designate them. In addition, each switching step has to have a coupling input and a coupling output, with the coupling input supplied potential the own switching stage can be influenced while it by means of the potential emitted via the coupling output is able to respond to others To influence switching stages. According to the two values that the Accept the test input supplied and the potential given by the designation output can, namely free and occupied potential or designation potential and neutral Potential, the potentials of the coupling input and the coupling output can also be used take two values each.

This switching stage is according to claim 2 of the additional patent mentioned above characterized by their mode of action as follows: The potential of the designation output only then takes a certain (designation potential) of the two values (designation potential, neutral potential) if the input to the test input and the coupling input Potentials have certain values (free potential, release potential); when occurring of the specific potential value (designation potential) at the designation output the potential occurring at the coupling output the complementary value (blocking potential) of the potential supplied to the coupling input (release potential); the potential the coupling output then assumes approximately the value of the potential of the coupling input, when the potential of the coupling input indicates the occurrence of the specific potential value (Designation potential) at the designation output preventing value (blocking potential) owns.

This characteristic behavior of a switching stage with respect to the It is also possible to emit potentials as a function of supplied potentials as follows schematically in the form of three criteria: 1. If the coupling input then has the release potential and the test input has the free potential the labeling output the labeling potential and the coupling output the blocking potential; 2. when the coupling input has the release potential and the test input has the occupied potential, then the label output has the neutral potential and the coupling output the release potential; 3. when the coupling input has the blocking potential then the designation output has the neutral potential and the coupling output the blocking potential, regardless of the potential of the test input.

As already mentioned, select circuits are daisy-chained formed by switching steps that are usually the same with one another, whereby apart from the basic function of designating a single free facility; also the desired defined designation sequence is obtained. If this naming order should be changed on a case-by-case basis, e.g. B. the same occupancy frequency as possible to be achieved for all facilities operated by the selection circuit, as already suggested to close the chain circuit to a ring circuit, which is separated by inserted contacts at a freely selectable point, whereby the original derailleur is achieved again. The location of each open Contact corresponds to the position of the zero point from which the designation sequence is to be calculated. To the often undesirable because of their relatively long response time To avoid contacts, it has already been proposed in the following to use switching stages to equip certain features with additional resources, which then make it possible to the zero point of the selection circuit in a simple manner with electronic and therefore to set practically inertial means.

To eliminate the hassle of these additional funds and instead to use funds already available for other reasons for this purpose, is the task of the switching stage described below. This switching step, the as mentioned, is a further development of the switching stage described at the beginning, has in addition, the additional feature that the possibly to be given at the coupling output, the delivery of the specific potential (designation potential) at the designation output preventing potential (blocking potential) from the coupling input supplied to the Release of the specific potential (designation potential); at the designation output enabling potential (release potential) through voltage drop at the transferable connection inserted between coupling input and coupling output is produced.

Switching stages that have this feature can be used with a wide variety of Realize means. First and foremost, as in the additional patent mentioned at the beginning explained in detail the ones known for the theoretical treatment of switching tasks "Basic logical building blocks" such as the "and" circuit, the "or" circuit, etc. are available.

In the following, an exemplary embodiment of a Switching stage described with the feature mentioned, which is characterized by particularly low Effort.

With this switching stage, the one-way transmission is possible Connection between coupling input k1 and coupling output k2 by a directional conductor G 1 produced. An additional resistor R 1 is connected to the coupling input k 1 Input n switched, which is provided for supplying a potential, the two Can assume values and to determine the zero point of these switching stages built-up selection circuit is used. The collector is one at the coupling output k2 pnp transistor T1, whose base is connected to the test via a resistor R 2 and designation terminal p and via a resistor R 3 to the positive pole of a Voltage source U1 is performed. The emitter of this transistor T1 is via a Resistor R 4 connected to the negative pole of a voltage source U2; to him the base of a second pnp transistor T2 is placed, the emitter of which is directly to the negative pole of a voltage source U3 and its collector via a resistor R 5 is led to the negative pole of a voltage source U4. An additional Designation output z is connected to the collector of transistor T2.

For the explanation of the operation of this embodiment it is sufficient to prove that and in what way they have the aforementioned three criteria are sufficient, since such a switching stage is then readily available with similar ones Switching stages can be interconnected to form a selection circuit.

For the sake of simplicity, the following two values which can assume any potential, referred to as "positive" and "negative" potential. These two terms always refer to one of the two values forming mean value, which is interdependent with others of the switching stage supplied potentials, such as B. transistor biases, is to be selected; they are therefore to be regarded as relative values. As a borderline case, one of the two can also Potential values disappear, which means that the relevant input or Output does not receive or result in a defined potential at all. But since this one Borderline case only represents a simplification in terms of arrangement and always on the case of a suitably defined potential, it does not form any Exception.

In the exemplary embodiment explained below with regard to its mode of operation the release potential, the free potential and the neutral potential are negative; the blocking potential, the occupied potential and the designation potential are corresponding positive. The additional input to determine the zero point, if applicable n potential to be supplied is negative and corresponds to the release potential; otherwise no potential is fed to this input n.

The base bias of the transistor determined by the voltage source U1 T1 is chosen so that this transistor T 1 is blocked in the idle state. That through the voltage source U3 fixed emitter potential of the transistor T2 is more negative as its base potential determined by the voltage source U2, with which the Transistor T2 is blocked in the idle state. The additional input, if applicable to be supplied, used to determine the zero point and the release potential corresponding potential is chosen so that the current-carrying transistor T1 essentially aivs the resistors R 1 and R 4 formed voltage dividers the base of the transistor T2 feed a potential which, based on the through the Voltage source U3 defined emitter potential, is negative. So that's that too Release potential at the coupling input k 1 is determined with respect to its value. The others Potential relationships are based on the following description of the mode of operation of the Switching step out.

If the coupling input k 1 is supplied with the negative release potential and the test input p is supplied with the negative free potential, the positive base bias of the transistor T 1 supplied via resistor R 3 is first reduced by the free potential so that this transistor T 1 is switched to the current-carrying state will. Due to the current flow in the transistor T 1, its emitter potential is shifted in the negative direction due to the resistor R 4. According to the above-mentioned prerequisite for the size of the release potential, the collector potential of the transistor T1 and thus also the base potential of the transistor T2 is now more negative than the permanently supplied emitter potential of the transistor T2. The transistor T2 is thus also switched to the current-carrying state, as a result of which the negative potential of the designation output z, which has been determined by the voltage source U4 and acting as a neutral potential, rises to the value of the collector potential acting as the designation potential. Furthermore, the current flow in transistor T2 also shifts its base potential in a positive direction. The rise in the emitter potential of the transistor T1, which is identical to the base potential of the transistor T2, means that the collector potential of the coupling output k2 also rises in the positive direction because of the practically constant voltage drop across the emitter-collector path of a current-carrying transistor. It reaches a value which deviates from the positive potential supplied by the voltage source U3 by the sum of the voltage drops at the emitter-base path of the transistor T2 and at the emitter-collector path of the transistor T1 in the negative direction. This deviation is small in terms of amount. This potential of the coupling output k 2, which is positive compared to the release potential by the amount of the voltage drop at the directional conductor G 1, acts as a blocking potential.

If the coupling input k1 has the negative release potential and the test input p has the positive occupied potential, then the transistor T 1 remains through the positive base bias by the voltage source interacting with the occupied potential U1 blocked. As a result of the unchanged emitter potential of this transistor T1 thus also the transistor T2 remains blocked, whereby that of the voltage source U4 supplied negative potential at the designation output z as a neutral potential occurs. Since the transistor T1 remains de-energized, no voltage occurs at the directional conductor G1. i voltage drop, whereby the release potential fed to the coupling input k1 also appears as a release potential at the coupling output k2.

If the positive blocking potential is fed to the coupling input k1, only the blocking potential can also occur at the coupling output k2 i, since the switching stage contains no means, a negative potential fed to the coupling input k 1 Change direction. Furthermore, in the switching stage depending on the The potential applied to the test input p has two different potential ratios adjust themselves, however, with regard to the output from the designation output z Potential have the same effect. If the test input p has positive occupied potential is supplied, then the transistor T1 remains due to the interaction of the occupied potential and the positive base bias voltage supplied by the voltage source U1 blocked, whereby the transistor T2 remains blocked and at the designation output z that negative potential supplied by voltage source U4 as neutral potential occurs. If the test input p is supplied with the negative free potential, then the base bias of the transistor T 1 drops so far that this transistor T1 carries current and its emitter potential under the influence of resistor R 4 one with respect to the positive potential supplied by the voltage source U2 negative value decreases. This value differs from the blocking potential of the coupling input k1 by the sum of the voltage drops at the directional conductor G 1 and at the emitter-collector path of the transistor T 1 in the positive direction. Since, as mentioned earlier, the blocking potential in turn from the positive one supplied by the voltage source U3 Potential deviates only slightly in the negative direction, it follows that im essentially due to the voltage drop across the directional conductor G 1, the emitter potential of the Transistor T1 from the potential supplied by the voltage source U3 in positive Direction deviates. This means that the transistor T2 remains blocked and that of the voltage source The negative potential supplied to U4 occurs at the designation output z as a neutral potential on.

From this explanation of the mode of operation as an exemplary embodiment The switching stage described shows that it meets the three criteria mentioned at the beginning fulfilled and therefore without further ado with similar switching stages to a selection circuit can be interconnected. If this selection circuit with always constant The sequence of names, i.e. should work with a fixed zero point, is the interconnection make so that all switching stages form a chain circuit in which the coupling input k1 of each switching stage with the exception of the first to the coupling output k2 of the respective previous switching stage is switched on. The additional entrance n of the first switching stage is a release potential corresponding to the coupling input k 1 To supply potential. If, in deviation from this, there should be the possibility of using the Changing the order of the names at will turns this chain connection into a To close the ring circuit, including the coupling input k1 of the original first stage is to be switched to the coupling output k2 of the originally last stage. Laying down the zero point of this selection circuit is exclusively the additional input n the switching step that should be the first in the sequence of names, to supply a potential corresponding to the release potential at the coupling input.

If with a simple chain circuit or a closed-loop chain circuit of such switching stages the test input of a switching stage remote from the zero point Free potential is supplied, the collector current of the transistor T1 flows this Switching stage via the guide G1 of one's own switching stage and the Directional conductor G 1 of all previous switching stages at which voltage drops appear. However, since the resistance values of the resistor R 4 this first with Free potential provided switching stage and the resistor R 1 of the first switching stage (as in all other switching stages) large compared to the sum of the forward resistances the directional conductor G 1 through which current flows, place themselves in the first with Switching stage provided with free potential, regardless of its distance from the zero point, always practically the same potential relationships.

As can be seen from the description above, at current-carrying transistor T1, the potential supplied to the coupling input k 1, regardless of whether release potential or blocking potential, in order to reduce the voltage drop when the Transistor T1 also shifted current-carrying directional conductor G 1 in the positive direction and thus the blocking potential is generated or passed on with a changed value. That means that in a chain connection of such switching stages the blocking potential as a result of the summation of these voltage drops from level to level, the release potential increases deviates. Least of all, namely by the amount of the voltage drop across one Blocking potential deviating from the release potential occurs with a single directional conductor G1 at the coupling output k2 of the switching stage that just emits designation potential. In the following stage, the blocking potential is only important if this switching stage Free potential is supplied and thus your transistor T 1 carries current, which also at the directional ladder G 1 of this level and thus a total of two directional ladders G 1 Voltage drop occurs. This explains the requirement mentioned earlier for the relationship between release potential and voltage drop on a directional conductor G 1 and emitter potential of the transistor T2, in which the voltage drop is at least two directors is named. Even if the transistor is in the following switching stage T1 carries current, then the voltage drops on three directional conductors add up etc.

Because by adding up the voltage drops at an increasing number of directional ladders, the blocking of the labeling potential release is becoming more and more pronounced is, the principle of the invention of blocking potential generation for selection circuits use with any number of stages.

Claims (11)

Claims: 1. Switching stage for the supply of potentials a test input and a coupling input and a designation output for the delivery of potentials and has a coupling output whose supplied and released potentials are essentially can assume two values and in which the delivery of a designation potential on Designation output only when the release potential and free potential are supplied to the Coupling input and test input take place with simultaneous delivery of the designation potential delivery preventing blocking potential at the coupling output, using one only in certain Direction of transferable connection between coupling input and coupling output according to claim 3 of patent 1215 777, characterized in that the optionally The output of the specific potential (designation potential) to be output at the coupling output (k2) at the designation output (z) preventing potential (blocking potential) from the coupling input (k 1) supplied, the release of the specific potential (designation potential) at the designation output (z) enabling potential (release potential) through voltage drop at the transferable between coupling input (k 1) and coupling output (k 2) inserted connection (G 1) is generated. 2. Switching stage according to claim 1, characterized in that as a connection which can be transmitted in a certain direction A directional guide (G 1) is provided between the coupling input (k1) and the coupling output (k2) is. 3. Switching stage according to claim 2, characterized in that switching means (T1) are provided that when the certain potential (free potential) is supplied to the Test input (p) independent of the potential fed to the coupling input (k1) (Release potential, blocking potential) at which the connection between the coupling input (k1) and coupling output (k2) forming directional conductors cause the voltage drop. 4. Switching stage according to claim 3, characterized in that in series with the directional conductor (G 1) forming the connection between coupling input (k 1) and coupling output (k 2), if necessary, switching means (T1) causing the voltage drop are connected and between these switching means ( T1) and a voltage source (U2) connected to it, a resistor (R4) is inserted, the resistance value of which is large compared to the forward resistance of the directional conductor (G 1). 5th switching stage according to claim 4, characterized in that the voltage drop, if any on the directional conductor (G 1) causing switching means (T1) with its controlling input is switched to the test input (p). 6. Switching stage according to claim 5, characterized gekeiinze7clinet, that, .in «ci @: e: es, for the delivery of the specific potential (designation potential) at the designation output (z) serving switching means (T2) is provided, which of the possibly the switching means causing the voltage drop at the directional conductor (G 1) (T1) is controlled. 7. Switching stage according to claim 6, characterized in that a first transistor (T1) is provided, the collector of which is connected to the coupling output (k2), des-en base via a resistor (R2) to the test input (p) and via a Resistor (R3) to the positive pole of a voltage source (U1) and its emitter Connected via a resistor (R 4) to the positive pole of a voltage source (U2) is that a second transistor (T2) is provided, the emitter of which is connected to the positive Pole of a voltage source (U3), whose base is connected to the emitter of the first transistor (T1) and its collector directly to the designation output (z) and via a Resistor (R 5) is connected to the negative pole of a voltage source (U4), and that the emitter potential (U3) of the second transistor (T2) is chosen so that this transistor (T2) only when reducing the output of the certain potential (Designation potential) enabling potential (release potential) at the coupling input (k1), but not when reducing the delivery of the specific Potential (designation potential) preventing potential (blocking potential) at Coupling input (k1) around the voltage drops at the directional conductor (G1) and the first transistor (T 1) can be controlled in the energized state. B. Switching step after one of the preceding claims, characterized in that an additional input (n) is provided, which is connected to the coupling input (k1) via its own means (R1) is. 9. Switching stage according to claim 8, characterized in that the additional Input (n) is connected to the coupling input (k 1) via a resistor (R1), whose resistance value is large compared to the forward resistance between the coupling input (k1) and coupling output (k 2) inserted connection (G 1). 10. selection circuit, Containing switching stages according to one of Claims 1 to 7, with a fixed zero point outgoing designation sequence, characterized in that the coupling input (k1) of each switching stage with the exception of the first to the coupling output (k2) of the respective previous switching stage is switched and that the coupling input (k 1) of the first Switching stage is connected to a voltage source via a resistor, the potential of which corresponds to the potential (release potential) that is applied to the coupling input (k 1) of a switching stage the output of the specific potential (designation potential) at the designation output (z). 11. Selection circuit, containing switching stages according to claim 8 or 9, with starting from an arbitrarily definable zero point Labeling order, using a facility similar to the additional The input of a single switching stage supplies a potential that defines the zero point, characterized in that the switching stages are permanently interconnected to form a ring circuit are.