DE1150408B - Pulse storage circuit with an amplifier and a charge storage device - Google Patents

Description

Pulse storage circuit with an amplifier and a charge storage device The invention relates to a pulse storage circuit having an amplifier and a Charge store, which is connected to the input of the amplifier and the charge pulses be supplied via a charge transfer circuit, which is controlled by a feedback circuit is connected to the output of the amplifier.

A pulse storage circuit of the aforementioned type is already known. However, only pulses can be used in the charge storage device of this known pulse storage circuit are stored with a very specific polarity, d. H. the circuit is suitable only as a counting circuit in which the charge storage device responds to a control pulse an amount of charge that is independent of the size of the charge already stored is fed. The charge stored in the charge storage device can be checked with the help of a suitable short-circuit switch must be removed.

The present invention is based on the object of a pulse storage circuit of the type mentioned in such a way that control pulses of any polarity can be processed, d. H. when a control pulse of one polarity occurs a certain amount of charge is supplied to the charge storage device and when a Control pulse of opposite polarity the same amount of charge from the charge storage can be removed. With the pulse storage circuit to be created should therefore not only add control pulses of the same polarity, but also control pulses opposite polarity can be subtracted.

In the case of a pulse storage circuit, this task is now the one at the beginning The aforementioned type is solved by the fact that the charge transfer circuit has two charge transfer lines contains, on which, depending on the polarity of the control pulses occurring, charge the charge storage device is supplied or discharged from the charge storage. This also includes the feedback loop two feedback lines, each with the corresponding charge transfer line connected is.

The charge store of the pulse circuit according to the invention is each when a control pulse (charging pulse) occurs, a certain amount of charge is supplied, while each time a control pulse of opposite polarity occurs (Discharge pulse) the same amount of charge is removed from the charge storage device. Ever depending on the polarity of the applied control pulse, there is either a constant amount of charge fed to the charge store or the same constant amount of charge from the charge store removed. The invention is now. explained in more detail with reference to drawings in which Fig. 1 shows a block diagram. an embodiment of the invention, Fig.2 a Circuit diagram of an embodiment of the invention, FIG. 3 different signal forms to explain the operation of the circuit according to FIG. 2 and FIG. 4 is a circuit diagram an embodiment of the invention equipped with tubes.

Fig. 1 shows a. Block diagram of an embodiment of the invention. Control pulses are fed to switches 10a and 10b. The switch 10 a is connected to a coupling circuit 20 a and the switch 10 b is connected to a coupling circuit 20 b. It is assumed, for example, that the coupling circuit 20a is used to reduce the value of the signal in the storage element 30 and the coupling circuit 20b is used to increase the value of the signal in the storage element 30. The output signal of the storage element 30 is fed to two feedback circuits 40. The feedback circuit 40a is connected to the coupling circuit 20a, whereby the energy level in the coupling circuit 20a is reduced to a predetermined value lying below the energy level of the storage element, so that the storage element during. the same amount of energy can be drawn from each discharge penode. The coupling circuit 20b is connected to the feedback circuit 40b, whereby the energy level of the coupling circuit 20b by one. is substantially constant amount above the energy level of the storage element 30, so that during. the same amount of energy can be supplied to the storage element 30 each charging period.

It can of course only be one. Charging circuit or a discharging circuit alone be built, d. H. the circles marked with the letter a can be separated for discharging the storage element 30 or designated by the letter b Circles can be used to charge the storage element 30.

In the circuit diagram shown in FIG. 2, the switches 10 of FIG. 1 consist of transistors. The transistor T "of the switch 10a is an npn transistor, which provides a designated A negative output pulse when it is actuated by a positive pulse. The transistor Tb of switch 10 b is a pnp transistor having a positive output pulse indicated at B when actuated by a negative input pulse.

The pulse A is the coupling circuit 20 a and the pulse B the coupling circuit 20 b supplied. The two coupling crises each have a capacitor 21 to hold back: the cargo. Using a capacitor to hold the charge in the coupling circuits 20 enables the energy signal in the storage capacitor 31 of the memory element 30 to increase. The capacitors 21 are in series with Impedances 23, which are shown as resistances. The time constants of the circles 20 a and 20 b are by the series impedances 23 a and 23 b and by the capacities 21 a and 21 b.

Usually one makes the time constant of circle 20 two to five times greater than the pulse period. This ensures that the charge transfer rate with small changes in the resistors 23 or the capacitances 21 not significant changes. The current foot during charge transfer can be more or less exponential take place. However, this is of no further significance for the mode of operation of the invention. The current course depends in detail on the actual values of the time constant defining components. It is an important feature of the invention that the shape of the exponential current during the pulse interval does not depend on the The size of the charge stored in the capacitor 31 depends. Of course, this is only possible within the permitted output signal range.

In each coupling circuit 20 there is a diode 25. The diodes are arranged so that the charge can flow in the correct direction. The diode 25 a is used for discharging and the diode 25 b for charging the capacitor 31. The capacitor 31 is only charged and discharged with the signals B and A , otherwise the diodes 25 essentially block. Since the output circuit 50, which acts through the feedback circuits 40c and 40b , tries to keep the diodes 25a and 25b essentially at a bias voltage of i 0 volts (assuming that the base-emitter gradient for the transistors 51 and 52 is 0 volts), the transistors normally block.

The output signal of the storage capacitor 31 is fed to the output circuit 50. The two "transistors 51 and 52 of the output circuit 50 form the known emitter follower circuit. The output signal of the transistor 52 is applied to the inputs of the feedback circuits 40. Each feedback circuit 40 consists of a diode 41 connected in parallel to an impedance 43. The parallel impedance is shown in the circuit diagram as The diodes 41 are arranged so that the associated capacitor for retaining the charge changes its energy level with the output signal coming from the capacitor 31 when the diodes 25 block. The capacitor 21 a for retaining the charge (when the transistor T, is switched off) is discharged through the diode 41a to a level at which the signal at the junction between the capacitor 21 and a diode 25 in a, is substantially equal to the signal level at the capacitor 31st

When the transistor TU is switched off, the capacitor 21b is similarly charged to hold back the charge via the diode 41b at the connection with the diode 25b to a level which is substantially equal to the level of the storage capacitor 31. If the output voltage of the output stage 50 is reduced by the action of the circuits 10a, 20a and 30, the voltage at the junction of the capacitor 21b with the diode 25b decreases as a result of the impedance 43b. If the output voltage of the output stage 50 increases due to the action of the circuits 10b, 20b and 30, the voltage at the junction of the capacitor 21a and the diode 25a increases in the same way due to the impedance 43a .

The through the collector resistance of each transistor and the associated one. The time constant formed by resistors 23 and 43 and capacitor 21 is so small d'ass the above mentioned connection points the greatest possible average Changes in the output voltage of the output circuit 50 can follow. That means, da.ß the diode 41 after transfer of the charge to the capacitor 31 the charge at the capacitor 21 is restored, but that as a result of the resistor 43 the capacitor 21 is charged relatively more slowly, whereby the voltage on the diode 25 is held at 0.

The mode of operation of the embodiment shown in FIG The invention will now be described with reference to the waveforms shown in FIG. The waveforms A and B correspond to the input pulses A shown in FIG and B. In addition, the signal generated at the capacitor 31 and that at the connection point are still present C of the circle 20b generated signal shown. It can be seen from this how that Energy level of the circuit with the level of the capacitor 31 changes.

When a charging pulse B is sent through the transistor Tb, energy is supplied to the capacitor 31 from the circuit 20b and is thus charged. If the diodes 25 did not have a voltage drop in the forward direction, there would be no positive pulse at C. If one assumes that the original voltage at the diode 25 b is 0 , then the voltage at point C actually only increases by an amount which is equal to the voltage drop of the diode 25 b in the forward direction. The voltage drops between the base and emitter of the transistors 51 and 52 can be set equal to 0 with this consideration.

At the end of the charging pulse period, the level of the capacitor 31 remains constant, since the diode 25 b is blocked and therefore no more current can flow to the capacitor 31. Since the voltage on the capacitor 31 increases slightly during the charging time and the voltage on the capacitor 21b decreases slightly, there is a slight counter voltage across the diode 25b after the B pulse. The charge removed from capacitor 21b is then replaced at a rate equal to that by the collector resistance of Tb. the resistor 23 b and the time constant determined by the capacitance 21 b is determined. The voltage at the diode 25 b, which is regarded as an ideal semiconductor, then becomes 0 again. At the end of the charging pulse period, the feedback circuit 40 b causes the potential at point C in circuit 20 b to be increased in accordance with the potential of the capacitor 31. The potential of the wave C thus approaches the potential of the storage capacitor 31. As a result of a gain of the stage 50 which is below 1.

With the next charging pulse B, the potential at point C becomes exact again increased by the same amount of the charge pulse. To charge the capacitor 31 is so exactly the same energy as in the previous charging process is available. This means, that the capacitor 31 during the pulse period B by the same amount as before being charged. At the end of this second charging process, the capacitor 21 b is again supplied so much energy that the point C has approximately the same potential as the Has storage capacitor 31.

A discharge pulse A has the opposite effect via the circle 20a. In this case, however, the negative pulse A occurs at point D in the circle 20 cc and causes the capacitor 31 to discharge will.

From the description it can be seen that in the transmission circuit according to the invention the transmission red regardless of the size of the already in the storage element transmitted energy is. In the example just given, every change to the stored in the capacitor 31 signal a corresponding change in the capacitor 21 to hold back the charge, so that for further charge change existing energy remains constant and consequently also the energy transfer rate is constant.

Many embodiments of the invention are of course possible. For example Not only transistors (Fig. 2), but also tubes can be used as input switches (Fig. 4) can be used. Either semiconductor diodes (Fig. 2) can be used as diodes or tube diodes (Fig. 4) can be used. Furthermore, the impedance of the Circle 20 will not always be a resistance, but it is also conceivable that at AC operation an inductor can be used.

The most varied of embodiments of the output circuit are also possible. The cathode amplifier circuit shown in circle 50 in FIG. 4 corresponds to the emitter amplifier circuit shown in circle 50 in FIG. FIG. 4 also shows a separate output stage 60, which is separated from the feedback circuit 40. This arrangement has the advantage that the feedback circuit is separate from each consumer circuit connected to the output of stage 60. The circuit shown in Fig. 4 was used in a device which serves to convert digits into the corresponding analog values. The memory element 30 is used to store the analog values corresponding to the numbers. The numbers are converted in a separate circuit and the charge and discharge pulses are fed to the circuit according to the invention. The voltage of the capacitor 31 is fed to a further separate circuit via the separate output stage 60. Since the feedback circuits 40 draw current when the capacitors 21 are charged, they load the output of circuit 50, as can be seen from FIG. 2 Feedback loops at the output of circuit 50 arise. Oscillations occur in a closed loop in which the charging and discharging pulses are generated as a function of the output signal of the circuit according to the invention. This is avoided by using a separate output stage 60. The invention can. can therefore also be used in a closed circuit.

Claims (7)

PATENT CLAIMS: 1. Pulse storage circuit with an amplifier and a charge store which is connected to the input of the amplifier and the Charge pulses are supplied via a charge transfer circuit, which is through a Feedback circuit connected to the output of the amplifier, characterized in that that the charge transfer circuit contains two charge transfer lines which, depending on the polarity of the control pulses that occur, charge the charge storage device is supplied or discharged from the charge storage. 2. Pulse memory circuit after Claim 1, characterized in that the feedback circuit has two feedback lines each of which is connected to the corresponding charge transfer line is. 3. Pulse storage circuit according to claim 1, characterized in that in a directional conductor is connected in series to each charge transfer line. 4th Pulse storage circuit according to Claim 3, characterized in that the directional conductors are polarized opposite to one another in the charge transfer lines. 5. Pulse memory circuit according to claim 2, characterized in that a directional conductor in each feedback line is switched on in series. 6. Pulse storage circuit according to claim 5, characterized characterized in that the directional conductors connected in the feedback lines are polarized opposite to each other. 7. Pulse storage circuit according to claim 3 and 6, characterized in that the directional conductors in the charge transfer lines and the feedback lines are arranged such that from the output of the amplifier to the charge store at the input of the amplifier and also in the opposite direction Electricity can flow. B. Pulse storage circuit according to any one of the preceding claims, characterized in that the charge store eire Capacitor connected between the input of the amplifier and a reference potential is. Publications considered: German Auslegeschrift Nr: 1051943; Book "Millm: an and Taub, Pulse and Digital Circuits", New York-Toronto-London, 1956, Pp. 350 to 352.