DE878513C - Arrangement for converting pulses into a pulse train of half frequency - Google Patents

Description

Arrangement for converting pulses into a half-frequency pulse train They are arrangements for converting a given sequence of alternating positives and negative electrical pulses in a corresponding half-frequency pulse train known with the help of a DC switch, in which to achieve To ensure that the DC flip-flop circuit is properly tilted, special delay means of such magnitude are provided that the duration of the tilting process is greater is than the duration of the control pulse. Such arrangements are known to have Disadvantage that the output pulse is generally longer than the input pulse, so that when several such arrangements work together in cascade connection larger retarders have to be used from stage to stage. From this results with a larger number, e.g. B. twelve, cascaded stages the need to increase the time constant of the delay means from stage to stage at most to double, while as is well known, a greater gradation of the time constants of the Delay means, for example in the ratio r: q., Recognized as particularly favorable has been. So in practice one is forced to choose the most favorable value of the ratio deviate from the time constants of the delay means and as a result: a lower one Reliability of the tipping process and thus the functioning of the entire facility to accept. So you already have a different path, au-oh in order to solve this problem, which consists in having the control the DC flip-flop circuit - via two grid-controlled rectifiers undertakes and -a second similar DC trigger circuit applies, which also is controlled via two grid-controlled straight lines, but by those Impulses which have the opposite direction as the impulses which have the former Affect the DC breakover circuit. Here, the control grids are controlled by the grid Rectifier sections from which the first DC flip-flop circuit is controlled, given by the second DC flip-flop circuit different potential while the control grids of the grid-controlled guide lines, from, the second DC flip-flop is controlled from the first Glei.chstromkippehaltung different potential is granted. This solution is characterized in that the tilting process is completely independent of the duration of the control pulses, so that nothing Requirements for the size -the ratio of the time constants of the delay means successive stages of cascade-connected arrangements of this type must be, d. H. that initially no delay means at all required are and that further: all stages of a cascade circuit are constructed in the same way can be. On the other hand, however, the solution has compared to the first-mentioned arrangements the great disadvantage that they at least double the amount of tubes and switching means conditional, which of course with a cascade connection consisting of a great number of stages felt to be particularly disadvantageous wind.

The invention relates to an arrangement for converting a given Sequence of alternating positive and negative electrical impulses in a corresponding one Pulse sequence half the frequency with the known aid of a DC flip-flop circuit: g, that consists of two high-vacuum electron tubes that are fed back to one another with direct current consists . and is controlled via two grid-controlled aligning lines that compared to the above-mentioned known arrangements of this type the essential advantage has that the Gleiehstrom'kippsohaltung does not contain any delay agent or does not require the double expenditure on tubes and switching means. The invention is compared to the known arrangements characterized by dabß. the grids of the two grid-controlled rectifier lines via delay elements from the DC electronic flip circuit can be controlled. A design is particularly advantageous of the invention in such a way that only the grids of the two grid-controlled rectifiers spread are controlled by the DC flip-flop circuit via delay elements that however, this nipple circuit itself has no delay means.

In the following, the invention is illustrated by means of three exemplary embodiments explained. FIG. 1 shows, as a first exemplary embodiment, one corresponding to the invention Arrangement in which the control grid of the grid-controlled rectifier sections via one resistor each with the grids of the corresponding electron tubes the DC tilting and over a capacity with a point of constant Potential, e.g. E. Earth, connected. Regarding the known mode of action of this DC flip-flop circuit should only be mentioned here, @ that as a result of the DC feedback with a suitable dimensioning of the coupling elements each a steady state is established in so far as one tube reaches its full anode current while the other tube is due to a voltage drop in a resistor caused negative grid bias is blocked. By supplying a suitable Impulse on one of the two grids of the tilting tubes can create this stable setting reverse themselves into the opposite, likewise stable attitude. -In the case of the invention Arrangement according to Fig. , i are the two electron tubes i and 2 via anode resistors 3 and 4. to the positive pole of a DC voltage source, e.g. B. anode battery, arclosed. The changes in the anode voltage of one tube are output via the the voltage divider formed by the resistors 5 and .6 the grid of the second tube and the anode voltage changes of the second tube via the voltage divider 7, 8 fed to the grid of the first tube. The two voltage dividers 5, 6 and 7, 8 are directly connected to their third pole, the grounded pole of the anode voltage source. The correct grid prestress for tubes i and 2 is determined by the voltage drop the anode currents of both tubes are generated in the common cathode resistor g.

The alternating positive and negative ones fed to the arrangement Pulses are sent to the cathodes of two grid-controlled rectifier sections io, in fed to these cathodes are through a resistor, ii2 with a point of constant Potential, e.g. B. with the cathodes of the tubes z and 2 connected. The anode of the rectifier line io is with the grid of the tube i and the anode of the alignment -e i i connected to the grid of tube a. The grid of the rectifier .io is through the resistor 13 with the grid of the tube i and through the capacitor '15 with the grounded pole; connected to the anode voltage source, and the grid of the rectifier @i i is in a corresponding manner via the resistor 14 with the grid of the tube 2 and connected via the capacitor. 16 to the grounded pole of the anode voltage source. The half-frequency pulse train can now be the anode current or the anode voltage either the tube r or the tube 2 z. B: can be taken from the capacitor 17. Taking half the frequency of the pulse train from the anode current would result in known #Meise the primary winding of a transformer in the anode circuit one of the two Rö: hreii i and - or the two primary coils of a G @ egenta! httransformer insert into the anode currents of these two tubes, while on the secondary winding of the transformer, the pulse voltages are taken.

The inventive arrangement of the two rectifier lines according to Fig. I acts as follows: From the to the chewing balls of the rectifier sections io impulses, alternating positive and negative signs, can those positive signs do not have any current in the rectifier sections io, i i cause, because it is incandescent, cathode rode, while the impulses are negative Sign, depending on the potential state of the same anodes and polarizers: lattice, can cause a current to flow in the rectifier sections. We are going now initially on the assumption that the DC electronic flip-flop is in the state find that the tube carries an anode current, that is, its grid opposite the cathode has approximately the same potential, while the tube -2 is blocked and their Grid has a negative potential compared to the cathode. According to this AnnaJime the anode and grid of the rectifier path i i also have a negative potential of the cathode, while the anode and grid have the same rectifier path approximately have the same potential as the cathode. Avoid the impact of a negative impulse on the cathodes of the two rectifier sections io and ii is therefore preferred a current is brought to flow in the rectifier section io, so that the pulse first. only transfers to the grid of the tube i and thus initiates the tilting process. As soon as the state is reached in the course of the tilting process, in which the grid of tubes i and 2 and thus also the anodes of the two rectifier lines io and ri have the same pontential, the momentum current would spread in the same way distribute both rectifier sections and thus interrupt the tilting process, if not the grids of the two rectifier sections io un: d ii as a result of the delay effect of the capacitors 1, 9 and 16 would be held at the same potential as long as that they had before the start of the tilting process, until the input pulse died away is. Due to the delay in the recharging process of the two capacitors i 5 and 16 it is achieved that the tilting process, regardless of the duration of the input pulse, with the speed peculiar to the DC flip-flop circuit up to can expire to the end.

In the event that in the initial state the tube: 2 conducts current and the tube i is blocked, the process is completely symmetrical to the one just now described from. From the sequence of alternating positive and negative impulses So first of all, the rectification results in a sequence of half the frequency of pulses only one sign generated; by the fact that these impulses have the same sign alternately the tilting from one stable state to the other let it tip over. an alternating positive sequence appears in the output of the circuit and negative impulses half of the time.

In some cases, resistors 13 and 14 can be used Size give that already the self-capacitance of the grid-controlled rectifier tubes itself causes the delay effect and that no additional capacities are provided in the external circuit of these tubes.

In the second embodiment shown in Fig. 2 are Control grid of the bit-controlled rectifier sections i, o and? i about one each .Widerstand 13 and 14 with the grids of the corresponding electron tubes the DC flip-flop circuit and one capacity each, i5 and 16 with the anodes of the respective corresponding electron tubes. The mode of operation of the synchronous electronic flip-flop itself is the same here as in the first embodiment shown in FIG. Also the type of setting of the rest potential of the grid of the equilibrium hrichterstreck is the same. However, there is a difference in the mode of action that the not me, as in the first embodiment of Fig. i, the pontentials of the Correctional grid during the tipping process and for a certain time afterwards be obtained, but it will be during the actual tilting process on the Capacitors 15 and 16 provide additional voltage pulses from the anodes of the trigger circuit tubes brought up to the equation grid, so that for a certain short time until the capacitors, i and v6 see through the resistors 13 and @ 14 have discharged, the grid potentials of the two rectifiers extend even more strongly from one another are different than in the idle state, which increases the safety of the control process of the input pulse to the direct current lpp circuit is increased considerably.

The arrangement shown in Fig. 3 as a third embodiment is according to the invention characterized in that the control grid of the grid-controlled Equalibrium: stretch across a resistor 13 and -1.4 with a point of constant potential, e.g. cathode resting potential, and each with a capacity 15 and 16 are connected to the anodes of the respective electron tubes. The mode of operation of the flip-flop is also the same here as in the exemplary embodiment according to Fig. i. However, this is in contrast to those shown in FIGS Embodiments, the rest potential of the two rectifier grids is the same, namely, for example, equal to the cathode potential, while in the course of the actual Tilting process, as well as in the arrangement according to FIG. 2, voltage pulses via the Capacitors 15 and v6 from the anodes of the tilt tubes i and 2 to the grids of the corresponding rectifier sections ia and i i are transmitted in each case. The history the control process can be explained with this arrangement as follows: True have at rest the grids of the two rectifier sections io and! i i have the same potential, but the anodes of the two Gleidhz.ichterstangen ii, o and -s i different potential, because they are connected to the grids of the tilting tubes 1 and 2 are galvanically connected. A negative voltage pulse acting on the cathodes is therefore an electron stream preferably in that 'rectifier path to flow, the anode of which has the relatively more positive potential. Hence will the tipping process initiated; being immediately sufficient via the capacitors i @ 5 and @ 1.6 Control pulses are brought up to the Glei.eirichtergitter, so that the tilting process can expire without delay.

The arrangements corresponding to the invention can also be designed in this way turn, d, ate in place of the negative pulses, as in the three exemplary embodiments shown, the positive pulses are used for control. It will then in a corresponding manner when connecting the rectifier sections io and ia, respectively Cathode and anode interchanged, in which case the connections to the grid of these rectilinear lines are to be interchanged.

According to the invention, it may be appropriate to either .die two in the DC flip-flop circuits or the two grid-controlled rectifier lines or to combine these two pairs of tubes in a common vacuum vessel, d. H. to use so-called multiple tubes. It is not essential to the invention required that the two tubes or make the two grid-controlled rectifier sections identical in pairs are; even. the characteristics of these pairs of tubes do not need to match, because one by corresponding inequality in the choice of each other on both sides external switching elements corresponding to the circuit compensate for such differences can. As a result, the two parts also need when using multiple tubes not to be uniform.

According to the invention, it is particularly useful in cascade connections of this type expedient, all current and voltage supply parts of the arrangements according to the invention to connect in parallel. In the event that a count or the like. Are made can be used for the purpose of displaying the position of the individual flip-flops in the output circuit at least one of the two electron tubes of the counting '' DC flip-flop a relay, a glow lamp or a so-called magic Insert eye. It is also useful for all high vacuum electron tubes of the DC flip-flop circuits to provide combined electron-electron beam tubes, so-called magic eyes. If .die electron beam paths have a special control electrode that can be connected separately, so it is advantageous for the purpose of a sharper Under-separation of the luminous phenomena of the two magical eyes the circuit to be chosen in such a way that a control electrode is used in each individual Gleidh current flip-flop circuit of the electron beam part of each magic eye with the control grid of the amplifier part the other tube is connected.

Claims (6)

CLAIMS: 1. Arrangement for converting a given sequence of alternating positive and negative electrical impulses into a corresponding one Pulse train half frequency with the help of a DC flip-flop circuit, that consists of two high vacuum electron tubes coupled back to one another in direct current fashion exists and is controlled via two grid-controlled rectifier sections, thereby characterized thatt the grid of the two grid-controlled rectifier sections (io, 1i) via delay elements (13, 14, 15, 16) from the dc trigger circuit being controlled. 2. Arrangement according to claim i, characterized in that only the grids of the two grid-controlled rectifier sections (io, ii) via delay elements (13, 14;: 15, 116) can be controlled before the DC flip-flop circuit, which do not Has delay elements. 3: Arrangement according to claim i and z, characterized in that that the control grid of the grid-controlled rectifier sections (1o, 1i) over each a resistor (i'3, 14) with the grids of the respective corresponding electron tubes (1,: 2) the Glelchstromkippaltung and each one capacitance (15, 16) with one Point (io) of constant potential, e.g. B. earth, are connected (Fig. I). 4. Arrangement according to claim 3, characterized in that the self-capacitance (the grid-controlled Rectifier tubes themselves produce the delay effect and that no additional Capacities are provided in the external circuit of these tubes. 5. Arrangement according to claims 1 and 2, characterized in that .the control grids of the grid-controlled Gleichridhterstrec ken (io, i i) each via a resistor (13, 14) with the grids of the respective corresponding electron tubes (i, 2) of the DC tilting circuit and each via a capacity (15, 16) with the anodes of the respective corresponding electron tubes (i, 2) are connected (Fig. 2). 6. Arrangement according to claim z and 2, characterized in that that the control grid of the grid-controlled rectifier lines (no, .1i) over each a resistor (13, 14) with a point of constant potential, e.g. B. Resting cathode potential, and each via a capacitance (15, 16) with the anodes of the respective corresponding electron tubes (i, 2) are connected (Fig. 3). 7: Arrangement according to claim a to @ 6, characterized in that that either the two tubes (1, 2) in the dc trigger circuit or the two grid controlled Rectifier tubes (io, i i) or these two pairs of tubes are each combined in a common vacuum vessel (Multiple tube). B. cascade connection of several arrangements according to claim, i to 7, characterized in that all current and voltage supply parts of this Arrangements are connected in parallel. G. Arrangement according to Claims 1 to 8 for counting purposes Od. Like., characterized in that in the output circle at least one of two electron tubes: (1,: 2) the counting DC trigger circuit a relay, a glow lamp or a so-called magic eye switched on as an indicator is. ok Arrangement according to claims i to g, characterized in that for all high vacuum electron tubes the DC trigger circuit combined electron-electron beam tubes, so-called magic eyes are provided. i i. Arrangement according to claim i (o, characterized in that that in each individual DC flip-flop a control electrode of the electron beam part from each magical eye with your control grid of the amplifier part of the other Tube is connected.