DE1122575B - - Google Patents

Description

QOC

GERMAN

PATENT OFFICE

INTERNAT. KL. H 03 k

H 40171 VIII a / 21 a ¹

ANM ELDETAG:

NOTICE THE REGISTRATION AND ISSUE OF THE EDITORIAL:

AUGUST 9, 1960

JANUARY 25, 1962

The invention relates to a control circuit for a bistable trigger circuit with two transistors. These A bistable multivibrator, referred to below as a flip-flop, can be an Eccles-Jordan circuit, for example. Instead of transistors you can also Electron tubes find use as transistors and electron tubes for the present Purpose equivalents are. The control circuit has the task of under the action of a control pulse the flip-flop from that of its two stable states, in which the flip-flop is when the pulse arrives, to the other of these To flip states.

The direction in which the flip-flop is flipped depends on which of the two is used stable states of the flip-flop is when the pulse arrives. Taking into account this State requires a short-term storage of each pulse. It is known to carry out this pulse storage by means of a capacitor. Circuits of this type have the disadvantage that the pulse duration does not exceed a certain limit allowed. To avoid this disadvantage, it is known to use an additional pulse storage device Use flip-flop as a control circuit. However, this increases the effort considerably.

The aim of the invention is to create a circuit of the type mentioned for its mode of operation no maximum duration of each impulse must be assumed and what the additional effort of a avoids additional flip-flops used for pulse storage.

For this purpose, the control circuit according to the invention has a bistable multivibrator Pair of magnetic cores with, in a manner known per se, approximately rectangular hysteresis loop and each Magnetic core a control winding with a number of ampere-turns sufficient to saturate the core, a Input winding with at least twice the number of ampere turns of the control winding and one Output winding. The input windings are connected in series and magnetize all cores in one direction under the action of each input pulse fed to the control circuit. The control winding of each magnetic core is in the controlled one Circuit of one of the transistors and magnetizes the core in the opposite direction to the action of the input pulses. The output winding of each magnetic core supplies a voltage that changes the flip-flop when the magnetization reversal is caused by your input pulse.

In this circuit, a reversal of magnetization occurs

Control circuit for a bistable multivibrator

Applicant:

Hasler A.-G., Works for Telephony and precision mechanics, Bern

Representative: Dipl.-Ing. Dr.-Ing. H. Idel and Dipl.-Phys. Dr. W. Andrejewski, patent attorneys, Essen, Kettwiger Str. 36

Claimed priority: ' Switzerland of August 11, 1959 (No. 76 772)

Dipl.-Ing. Rudolf Kühne, Bern, has been named as the inventor

one of the cores flipping the flip-flop off, and the cores are used for magnetic storage of each Impulse.

One field of application of the bistable multivibrator circuit according to the invention is in counting circuits. In In this sense, the invention also relates to a counting circuit for binary pulse counting. This circuit can be used to count in one direction (either for counting up or down) or for be carried out optionally up or down counting. The circuit has one of the number of Number of counting levels connected in a chain corresponding to binary digits.

In the counting circuit according to the embodiment of the invention, each counting stage consists of a bistable Flip circuit of the type according to the invention. In one embodiment, it has one-way counting each control circuit has two cores with input, control and output winding of the type mentioned The input windings of the magnetic cores of all counting levels are connected in series. The power supply to the control winding of one of the magnetic cores each Stage is led through the input windings of all stages following in the counting direction. the Power supply to the control winding of the other magnetic core of each stage is carried out directly. In the drawing are two embodiments of the bistable trigger circuit according to the invention and

109 787/287

two embodiments of the counting circuit according to the invention are shown. It shows

1 shows a bistable multivibrator,

Fig. 2 a counting circuit for binary pulse counting for upward counting, each counting stage from one Circuit according to Fig. 1 consists

3 shows an expanded embodiment of the bistable trigger circuit according to FIG. 1,

4 shows a counting circuit for binary pulse counting for either upward or downward counting, each counting stage consisting of a circuit; according to Fig. 3 consists.

The circuit shown in Fig. 1 has a flip-flop with two transistors 1 and 2, the emitters of which are grounded. In this circuit, the i, base of each transistor 1, 2 is in its controlling circuit, the collector in the controlled circuit, while the emitter is both in the controlling and in the controlled circuit of the transistor. The emitters of the transistors 1 and 2 are grounded together via a resistor 19. Each base of the transistors 1 and 2 is connected to ground via a resistor 15 (or 16) and connected to the collector of the other transistor via a resistor 14 (or 13). a

The control circuit for the trigger circuit shown in Fig. 1 contains two ring-shaped magnetic cores 3 and 4 made of ferromagnetic material with an approximately rectangular hysteresis loop. Each of the magnetic cores 3 and 4 carries an input winding 7 or 8, an actuating winding 5 or 6 and an output winding 9 or 10.

The control winding 5 (or 6) of the magnetic core 3 (or 4) is on the one hand to a negative voltage - Uc of about -6 to -12 volts, on the other hand via a resistor 17 (or 18) to the collector of the transistor 1 ( or 2) connected. The control winding 5 (or 6) is therefore in the controlled circuit of the transistor 1 (or 2). The number of ampere turns of the control winding 5 (or 6) is sufficient to saturate the core.

Each input winding 7.8 has at least twice the number of ampere turns of the control winding 5 or 6. The direction of winding of the windings 5 and 7 (or 6 and 8) is such that the currents flowing in these movements have opposite magnetic effects on the Have core 4 (or 5).

The output winding 9 (or 10) of each of the cores 3 and 4 lies on the one hand at the emitters and; on the other hand via a diode 11 (or 12) on the base electrode ( i.e. in the input circuit) of transistor 2 (or 1), whose collector circuit (output circuit) contains the control winding 6 (or 5) of the other core 4 (or 3) . Each of the diodes 11 and 12; is polarized in such a way that it only transmits a voltage in the negative direction to the base electrode of transistor 2 or 1, respectively.

The output winding 9 (or 10) has such a sense of turns and such a number of turns that each input pulse of the circuit flowing through the coil 7 (and coil 8) , if it remagnetizes the core 3 (or 4) , at its output winding 9 (or 10) induces a voltage which briefly shifts the potential of the base electrode of transistor 2 (or 1) negatively in such a way that this previously blocked transistor becomes conductive and thus the flip-flop flips.

The operation of the circuit according to FIG. 1 is described below. It is assumed that the flip-flop is in that of its two stable states in which transistor 1 is conductive and transistor 2 is non-conductive. The impulse line 20 is initially de-energized. No current flows in the output windings 9 and 10.

The collector current of the transistor 1 flows in the control winding 5. The core 3 is magnetic under the effect of this current. The direction of this magnetization is assumed to be positive. The control winding 6 is de-energized. The core 4 is remanently negative magnetic. This state of the flip-flop corresponds to the number "1" when counting binary.

If a pulse Io occurs in the line 20 , which magnetizes both cores negatively, no voltage arises at the output winding 10 because the core 4 was already remanently negative magnetic before the pulse arrived. However, the previously positive magnetic core 3 is remagnetized, since the number of ampere turns of the input winding 7 is at least twice as large as the number of ampere turns of the control winding 5 . With this reversal of magnetization, a current surge occurs at the output coil 9 , for which the diode 11 is permeable. During this current surge, the transistor 2 is conductive. The resulting collector current of transistor 2 generates a voltage drop across resistor 18. As a result, the base electrode of transistor 1 becomes more positive (relative to the emitter), transistor 1 blocks, its collector current is practically negligible. There is no longer a voltage drop across the resistor 7 , as a result of which the base electrode of the transistor 2 becomes more negative (relative to the emitter), and the transistor remains conductive even after the end of the induction current surge of the output winding 9. The flip-flop is now in the other of its two stable states. This other state corresponds to the number "0" in binary counting.

After the end of the pulse Io , the core 4 is positively magnetized by the collector current of the conductive transistor 2 flowing through the control winding 6. The core 3 remains remanently negative magnetic.

When a further pulse arrives, a current surge is induced in an analogous manner at the output winding 10, as a result of which the transistor 1 becomes conductive, which in turn makes the transistor 2 non-conductive. As a result of the non-conductive transistor 2 , the transistor 1 remains conductive even after the induction current of the output winding 10 has decayed. The flip-flop has flipped back into the stable state assumed above as the initial state (corresponding to the number "1"). And after the end of the pulse Io , the core 3 is positively magnetized by the collector current of the conductive transistor 1 flowing through the control winding 5 , while the core 4 retains its negative magnetization obtained from the pulse Io.

As can be seen, the control of the flip-flop by means of the two cores requires only a small amount of circuitry, and the duration of the pulse Io has no influence whatsoever on the flip-flop toggling process.

The counting circuit according to Fkj2 is for the binary up-counting of pulses up to a 4-digit number binary number determined. The first digit of this number

is the counter stage 2 °, the second location is the stage 2 ² and the fourth location associated with the stage 2 ³ Stage 2 ^1, the third location. Each stage consists of a bistable multivibrator circuit according to FIG. 1. The input windings 7 and 8 of the first stage 2 °, the input windings 7 'and 8' of the second stage 2 ¹ and the corresponding input windings (not shown in FIG. 2) third and fourth stages 2 ² and 2 ³ are connected in series. At the right end of this row in the drawing is the voltage - Uc placed. This tension - Uc the actuating winding S of the first stage 2 °, the actuating winding 5 'of the second stage 2 ¹ and the corresponding actuating winding (not shown in FIG. 2) of the third and fourth stage 2 ² and 2 ^{3 are} supplied directly. The voltage - Uc is the control winding 6 of stage 2 ° and the corresponding control winding of the other stages in each case via the input windings of all stages higher atomic number supplied, d. H. for example the tension - Uc is the control winding 6 on the Input windings of stages 2 ¹ , 2 ² , 2 ³ , the voltage - Uc is fed to the control winding 6 'via the input windings of stages 2 ² and 2 ³ .

This way of supplying the voltage -Uc to the control windings 6 and 6 'of stages 2 ° and 2 ¹ and the corresponding setting windings of levels 2 ² and 2 ³ , the following is achieved:

In the case of binary up counting, a counting stage should only then be activated by an input pulse tilt, d. H. change their value when all stages, which lower rankings are assigned, are in the "1" state. If a stage is now in the "0" position, it flows Collector current of the conductive transistor in this position across all input windings of the stages higher control value and prevents damtt. that the cores of these stages are made by the actuating current will. This also prevents the input pulse from being reset and the flip-flop from tilting.

If the control windings 5, 5 'and the corresponding control windings of stages 2 ² and 2- ^s are connected to the line 20 as shown in Fig. 2 for the control windings 6 and 6 ', and the control windings 6 and 6' and the corresponding control windings of stages 2 ² and 2 ³ so to the voltage - Uc are applied, as shown in Fig. 2 for the control windings 5 and 5 ', then the described counting circuit counts down instead of up.

The "jn ^ Ejjg _ss ^ larrepresented embodiment of the bistable flip-flop is different from that 1 shown in that the control circuit for the flip-flop has two additional magnetic cores 103 and 104, which also consist of ferromagnetic material with an approximately rectangular magnetization curve. The core 103 is the core 3, the Core 104 is assigned to core 4. Each of the cores 103 and 104 carries an input winding 107 or 108, an actuating winding 105 or 106 and an output winding 109 or 110. The Amperewindungs- the number and the direction of the winding of each of these windings is as above for the input, control and output windings 7, 8; 5, 6 and 9, 10 of the cores 3 and 4 indicated.

The input windings 107 and 108 of the additional cores 103 and 104 are connected in series and independently of the input windings 7 and 8 of the cores 3 and 4. The control windings 5 and 105

(or 6 and 106) of the associated cores 3 and 103 (or 4 and 104) are in series with the Resistor 17 (or 18) in the collector circuit of transistor 1 (or 2). The series connection of the output winding 109 (or 110) of the core 103 (or 104) with a diode 111 (or 112) is parallel to the series connection of the output winding 9 (or 10) of the assigned core 3 (or 4) with the diode 11 (or 12). The diodes 11, 111, 12, 112 have the same polarity.

The counting circuit according to Fi ^ ₁ 4-i st for binary, optional forwards, - f) r] e, r Riirlrwärts ^ hlpn up to a 4-digit binary number. The first digit of this number is assigned the counting level 2 ° *, the second digit is assigned the counting level 2 ¹ *, the third digit is assigned the counting level 2 ² * and the fourth digit is assigned the counting level 2 ³ *. Each stage consists of a bistable multivibrator according to FIG. 3.

The input windings 7 and 8 of stage 2 ° *, the input windings 7 'and 8' of stage 2 ¹ * and the corresponding input windings (not shown in FIG. 4) of stages 2 ² * and 2 ³ * are connected in series. There is tension at the end of the row on the right in the drawing - Uc placed. The input windings 107 and 108 of the stage 2 ° *, the input windings 107 'and 108' of the stage 2 ¹ 'and the corresponding input ^{windings of the stages 2 2} * and 2 ³ * are also connected in series, and this series is parallel to the series of the Input windings 7, 8, 7 ', 8' etc. switched. The voltage - Uc is fed to the in-line control windings 5 and 105 of the cores 3 and 103 of the stage 2 ° * assigned to one another via the input windings 107 ', 108' of the stage 2 ¹ * and the corresponding input windings of the stages 2 ² * and 2 ³ *. The corresponding in series control windings 5 'and 105' is the voltage - Uc ^{via the input windings of the stages 2 2} * and 2 ³ * corresponding to the input windings 107 and 108 (not shown in FIG. 4). The tension is similar - Uc ^{to the windings of level 2 2} * corresponding to windings 5 and 105 (not shown in FIG. 4) ^{through the windings of level 2 3} * corresponding to windings 107 and 108 (not shown in FIG. 4).

The other cores of each stage, connected in series, of cores corresponding to one another are the Tension - Uc fed through the input windings of the first-mentioned cores of all stages of higher ordinal number. For example, the tension is -Uc the control windings 6 and 106 through the input windings 7 ', 8' of stage 2 ¹ * and the corresponding (not shown in Fig. 4) windings of stages 2 ² * and 2 ³ *.

The output windings 9, 10, 9 ', 10' and the corresponding output windings of stages 2 ² * and 2 ³ * are at their end facing away from the diode (e.g. 11, 12) via a switch to a switch connecting the emitters of all transistors Line laid. The switch is not shown in detail in FIG. 4 and is designated by 21. In the same way, the end of the output windings 109, 110, 109 ', 110' and the corresponding output windings of stages 2 ² * and 2 ³ * facing away from the diode (e.g. 111, 112) is connected via a switch to the line connecting the emitters of all diodes placed. This switch is labeled 121. Transistors can serve as switches in units 21 and 121.

Claims (7)

For counting up, the switch of the unit is made conductive and the switch of the unit 121 is blocked. Then the circuits of windings 9, 10, 9 ', 10' and the corresponding windings of stages 22 * and 23 * are connected, and the circuits of windings 109, 110, 109 ', 110' and the corresponding windings of stages 22 * and 23 * not connected. These latter windings (109, 110, 109 'etc.) then do not supply any voltage to the transistors, and the circuit operates as described in connection with FIG. To count down, switch 21 is blocked and switch 121 is made conductive. Then only the output windings 109, 110, 109 ', 110' supply control voltages to the transistors, and the circuit counts down, as described in connection with FIG. It is sufficient if the switch or the transistor acting as a switch of the relevant unit 21 or 121 is closed for the duration of the pulse emanating from the output windings, that is a few microseconds. These switches can be controlled by the forward or backward dialing pulses. By means of appropriate connections between the stages and additional windings, circuit units of the type shown in FIGS. B. decadic, are counted. Sehiebemgijter can also be built up with the described bistable "circuitry". 1. Control circuit for a bistable trigger circuit with two transistors, characterized in that the control circuit is a pair Magnetic cores (3, 4) with, in a manner known per se, an approximately rectangular hysteresis loop and each magnetic core has an actuating winding (5, 6) with a winding sufficient to saturate the core Number of ampere turns, an input winding (7, 8) with at least twice the number of ampere turns of the control winding and an output winding (9, 10) has that the input windings are connected in series and below The action of each input pulse fed to the control circuit magnetizes all cores in one direction, the control winding each Magnetic core is in the controlled circuit of one of the transistors (1, 2) and magnetizes the core in the opposite direction to the action of the input pulses and the output winding of each magnetic core when it is triggered by an input pulse caused reversal of magnetization supplies a voltage that tilts the flip-flop (FIG. 1). 2. Control circuit according to claim 1, characterized in that a diode (11, 12) is located in the circuit of each output winding (9, 10) (Fig. 1). 3. Control circuit according to claim 1 or 2, characterized in that each of the two Magnetic cores (3, 4) an additional magnetic core (103, 104) with an approximately rectangular hysteresis loop and with an input (107, 108), one Control (105, 106) and an output winding (109, 110) of the type mentioned is assigned, the input windings of the additional Magnetic cores are connected in series in a circuit that is independent of the input windings of the first-mentioned cores, the control windings Cores assigned to one another are connected in series and the output windings are supplied to one another ordered cores in a common circuit lie (Fig. 3). 4. Control circuit according to claim 3, characterized in that in the circuit of each output winding (109,110) of the additional magnet cores (103, 104) a diode (111, 112) is located (Fig. 3). 5. Counting circuit for binary pulse counting with a number of counting stages connected in a chain corresponding to the number of binary digits, thereby ao characterized in that each counting stage consists of a bistable multivibrator according to claims 1, 2, 3 or 4 consists. 6. Counting circuit according to claim 5 for binary pulse counting in one counting direction under Veras turning a bistable flip-flop circuit according to claim 1 or 2 in each counting stage, characterized in that the input windings (7, 8, 7 ', 8' ...) of the magnetic cores ( 3, 4, 3 ', 4' ....) Of all counting levels (2 °, 2 ¹ , 2 ² , 2 ³ ) are connected in series , the power supply (- Uc) of the control winding (e.g. 6) of a magnetic core (4) each stage (2 °) through the input windings (7 ', 8' ....) Of all stages of greater importance and the power supply to the other control windings (5, 5 '...) Is carried out directly (Fig. 2 ). 7. Counting circuit according to claim 5 for binary pulse counting for either up or down counting using a bi-stable flip-flop circuit according to claim 3 or 4 in each counting stage, characterized in that the input windings (7, 8, 7 ', 8' ..., 107, 108, 107 ', 108' ....) Of all magnetic cores (3, 4, 3 ', 4'..., 103, 103 ', 104'...) Are in a common circuit, the power supply to the in series control windings (e.g. 5, 105) two cores (3, 103) assigned to one another of each counting stage (e.g. 2 ° *) via the input windings (107 ', 108'. ..) of one toroidal core pair ( 103 ', 104'...) results of all counting stages of higher atomic number and the current supply of the actuator coils (eg 6 in series, 106) of the other two ring cores (4, 104) of each stage (z. B. 2 ° *) on the in series input windings (7 ', 8' ....) of the other toroidal core pairs (3 ', 4'...) of all stages of higher ordinal number is performed and that the circuit of the output windings (9, 10, 9 ', 10' ....) Of all the first-mentioned magnetic cores (3, 4, 3 ', 4'. . .) via first switching means (21) and the circuit of the output windings (109, 110, 109 ', 110'. ..) of all additional magnetic cores (103, 104, 103 ', 104'. ..) via second switching means (121) is closed (Fig. 4). 1 sheet of drawings 787 / 2Ϊ7 1.62