DE1021418B - Circuit arrangement for phase-locked, even division of a pulse repetition frequency - Google Patents

Description

GERMAN

When transmitting messages with the help of pulses, especially with pulse modulation systems, the task often occurs to generate a voltage from a pulse train - e.g. B. a square wave voltage, a Sinusoidal voltage or some other pulse train - with a frequency lower than the original one Derive pulse repetition frequency phase-locked. Phase-locked frequency division is particularly suitable bistable multivibrators, because here the tilting oscillation at the working point of greatest steepness in a defined, tube-independent response potential is triggered; however, these circuits require two tubes. Flip circuits with only one tube

- e.g. B. Multivibrators with feedback between the screen grid and brake grid or blocking oscillator with transformer feedback, in which the grid bias is generated by an i? C element

- are less suitable for phase-locked frequency division, since the breakover time is very different from the Tube data, the operating voltages and the amplitude of the control voltage depends.

It has become known as a multiar barrier oscillator circuit with a tube that the Having time accuracy of a multivibrator circuit with two tubes. In this circuit, the feedback path opened or blocked by a rectifier in the control grid circuit. It was already proposed an additional feedback path for multiplying or dividing a pulse repetition frequency with a preferably on a harmonic or subharmonic of the pulse repetition frequency Provide a coordinated resonant circuit. As for locking and unlocking the tube negative and positive Control pulses are necessary, only the precisely timed locking process can be performed by a Pulse of the unipolar pulse train are triggered; the tube can be unlocked during the break between two control pulses due to the oscillation generated in the resonant circuit. So that the tube is safe is blocked by a control pulse and not by the natural oscillation, is the heavily damped Resonant circuit tuned to a slightly lower frequency compared to the output frequency. The one at the The square-wave voltage produced by the anode therefore has half-waves of unequal length, and only its one flank coincides with the timing of the control pulse. So there is no completely phase-locked link between the input pulse train and the output square wave voltage · or one derived therefrom Sinusoidal voltage.

Furthermore, a circuit arrangement has been proposed which has a strictly phase-locked halving a pulse repetition frequency allowed. It consists of a multi-circuit with two feedback paths, Circuit arrangement

to phase-locked, even-numbered

Division of a pulse repetition frequency

Applicant:

Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Wittelsbacherplatz 2

Dipl.-Ing. Hans-Martin Christiansen, Munich,
has been named as the inventor

which is opened by a rectifier in the control grid circuit and are blocked and one of which contains a differentiator; the one to be divided The pulse train is fed to the control grid circuit via a further differentiating element. There arises a rectangular anode current, both edges of which are timed by the input pulses, the steeply falling edge of the anode current coincides with the trailing edge of a control pulse and the slightly flatter rising edge of the anode current with the leading edge of the following Control pulse coincide in time. The duty cycle (pulse duration to pulse spacing) for the anode current is therefore somewhat greater than 1: 2, since the duration of the current flow is twice the duration of the control pulses is greater than the power break. The shape of the output square voltage and thus also its The phase position is therefore dependent on the duration of the input pulses.

The invention avoids this disadvantage; in addition, it also allows even-numbered division ratios greater than 2: 1. The circuit arrangement according to The invention uses a multi-circuit with a feedback path passed through a rectifier is alternately opened or blocked in the control grid circle of the multi-tube, and is marked by two connected to the multi-input, oppositely polarized and biased in reverse direction Paths containing rectifiers to which an incoming unipolar pulse train is fed in such a way that that these paths are fed with impulses of opposite sign, and by one of the two Because of the sawtooth or sinusoidal signals supplied with the same sign, derived from the multi-output

703846/161

Shaped selection voltage, the fundamental wave of which compared to the fundamental wave of the multi-output occurring square wave voltage is phase shifted by 90 °.

The invention offers the advantage that the tilting process of the multi-circuit circuit is effected solely by the leading edges the control pulse is triggered. The control pulses are generated with the help of a multiar output voltage derived selection voltage

which can easily be produced from the rectangular anode voltage. In the circuit arrangement according to FIG. 1, the square-wave voltage is tapped at the output resistor R7 and fed via the resistor R 3 to the capacitor C 3, at which a sawtooth voltage with an exponential rise and fall occurs. As can be seen from FIG. 2 from the voltage forms U21 and ("31), the fundamental wave is opposite to the sawtooth voltage

selected the incoming pulses. The anode- io of the fundamental oscillation of the square-wave voltage Ua or square-wave current of the multiar tube has now a key U 51 phase-shifted by 90 °.

Let the tube be live at time t = 0; a small grid current flows through R5 and the grid-cathode section, so that the grid potential is approximately equal to the cathode potential (Ugz & Uk). The cathode resistance RA causes the cathode to have a positive potential to earth. The transformer T 2, whose time constant is large compared to the period of the anode voltage, transforms this

3 shows a circuit arrangement for the phase-locked voltage with the opposite sign in the grid division a pulse repetition frequency with a higher circle, so that the voltage at the cathode of the

Rectifier Gl 3 is positive against the voltage at its anode: the rectifier (7/3 is therefore blocked.

The pulse 1 of the incoming pulse train i / 11 is superimposed on the selection voltage in the two ways of the selection circuit with different signs, so that the sum voltages U 21 and (731 arise (Fig. 2). Only the one on the apex of the

Multi-circuit typical switching elements. The 30 voltage U 21 seated negative pulse overcomes the primary winding of the feedback transformer T 2 the reverse voltage of the rectifier GIl and can instead be in the anode lead also in the cathode lead of the tube located in the control grid circuit of the multi-tube. To adjust the resistance i? 6 (voltage t / 41). The equation of a positive cathode potential to earth serves as rectifier GI2 remains blocked. Due to the negative resistance RA in the cathode lead, the impulse at R6 , the rectifier (7/3 is conductive, which bridges a capacitor C4t . The voltage caused by the grid voltage Ug of the tube is negative

ratio of exactly 1: 2.

The invention is explained in more detail below with reference to the drawings using two examples explained. The drawings show in

1 shows a circuit arrangement for the phase-locked division of a pulse repetition frequency in a ratio of 2: 1,

FIG. 2 shows the temporal processes in the circuit arrangement according to FIG. 1,

Ratio as 2: 1,

FIG. 4 shows the time processes in the circuit arrangement according to FIG. 3 for a division ratio from 6: 1.

In the circuit arrangement according to FIG. 1, which is particularly suitable for phase-locked halving of a pulse repetition frequency, the rectifier (7/3 and the feedback transformer T 2 are used for the

Anode voltage source is connected between + Al and earth; the control grid of the tube is connected via the resistor R 5 to a voltage source -f- A2 which is positive with respect to the cathode.

The multi-circuit is preceded by a pulse selection circuit that consists of the incoming unipolar impulses selects the impulses required to control the multi-tube and them with

Values decrease and the feedback path via the transformer T2 is opened; this causes an instantaneous blockage of the tube.

The Follow.de pulse 2 of the incoming pulse sequence £ 711 sits with positive polarity on the apex of the selection voltage U 31; it therefore opens the rectifier (7/2 while the rectifier G / 1 remains blocked. The pulse therefore arrives with a positive

alternating positive and negative polarity to the 45 polarity at the resistor R 6 (voltage U 41),

Control grid circuit supplies. The selection circuit, whereby the rectifier G / 3 is blocked again, holds two paths with two oppositely polarized
Rectifiers GIl and G / 2 to which the

incoming impulses via the input transformer T1

The grid voltage Ug rises to positive values and the tube conducts electricity again. The increase in current is a little slower than the decrease in current, because during

with two identical secondary windings with different increases, the feedback is ineffective, with a decrease the sign is reached. Between the two, however, is effective. If R5 is not selected too large, the secondary windings are resistor-capacitor - so almost equally steep ascending and descending combinations of i? L-Cl and R2-C2, the leading edges can be achieved. This means that the reverse voltage for the two rectifiers is cycled through. It is easy to see that they all serve un-G / l and Gl2. At the connection points of the 55 even-numbered pulses with negative polarity in the resistors R1-R2 and the capacitors C1-C2 control grid circuit arrive and thus a blocking is the effect of the tube derived from the multi-output voltage, while all even-numbered Im selection voltages are applied, which consequently have the same - Pulse as positive control impulses open the tube. There is a sign on the two paths. So there is a rectangular anode current Yes

To explain the mode of operation of the circuit 60 with half the pulse repetition frequency of the input arrangement, the current and voltage pulses Uli are shown in FIG. Since the leading edges of the input pulses trigger the toggle process, the pulse duty factor for the rectangular anode current is exactly 1: 2. When switching on, the following processes are played out in the multiarröhre's circle in the bottom line through 65: The multiarcircuit is dimensioned so that it indicates a closed or open switch. Without control pulses according to the time constant of the ES, the steady state of the transformer T 2 with a significantly lower Fre-voltages and currents should first be considered. With a small division oscillation, a freely selectable voltage is suitable as the sequence for the pulse repetition frequency to be divided. This immediately creates a selection ratio of 2: 1, above all a sawtooth voltage, 70 voltage that becomes one with incoming pulses

run at the marked points. The respective state - permeable or blocked - of the rectifier Gl 3 in the control grid

Selects control pulse, so that the following tilting operations are now from the selected pulses being controlled.

If, instead of the square wave, its sinusoidal fundamental wave is to be picked up at the output, the output resistance R7 is to be replaced by a filter arrangement with a characteristic wave resistance that is as frequency-independent as possible.

A pulse train with any pulse duration can also be derived from the rectangular anode current if, for. B. the anode resistor R7 is partially replaced by a current-fed pulse-shaping network.

If the division ratio is greater than 2: 1, a sinusoidal selection voltage is expediently used so that the pulses to be selected and located on the voltage peak differ sufficiently in amplitude from the neighboring pulses. In the circuit arrangement according to FIG. B. the sinusoidal selection voltage with the help of the divided frequency tuned series resonant circuit R 8, L, C 5 derived from the output square wave voltage. The other parts of the circuit arrangement correspond in their mode of operation exactly to those of FIG. 1, they therefore have the same designations. 4 shows the current and voltage curves when the pulse repetition frequency is divided in the ratio 6: 1. The pulses 1, 7, 13, etc., which sit on the lower apex of the selection voltage U 22 , reach the control grid circuit via the rectifier GIl with negative polarity and block the tube. On the other hand, the pulses 4, 10, 16 etc. open the tube because they sit on the apex of the selection voltage U 32 and reach the control grid circuit with positive polarity via the rectifier G12. Otherwise, the statements made with regard to FIG. 1 apply analogously here as well.

Reference should also be made to a circuit variant that can be used for both circuit arrangements according to FIGS . 1 and 3: the rectifier GIl can also be connected directly to the control grid of the multi-tube instead of the earth-side end of the secondary winding of the feedback transformer T 2.

Claims (5)

45 claims: 1.Circuit arrangement for phase-locked, even division of a pulse repetition frequency using a multi-circuit with a feedback path that is alternately opened or blocked by a rectifier in the control grid circuit of the multi-tube, characterized by two rectifiers connected to the multi-ar input, oppositely polarized and reverse-biased (Eq 1, G12) containing paths, to which an incoming unipolar pulse train is fed in such a way that these paths are fed with pulses of opposite sign, and through a sawtooth or sinusoidal selection voltage that is fed to the two paths with the same sign and derived from the multi-output, its fundamental oscillation is phase shifted by 90 ° with respect to the fundamental oscillation of the square-wave voltage occurring at the multi-output output. 2. Circuit arrangement according to claim 1, characterized in that at a division ratio of 2: 1, a sawtooth voltage is used as the selection voltage, which occurs on a capacitor (C 3) which is in series with a resistor (R3) connected to the multi-output. 3. A circuit arrangement according to claim 1, characterized in that at division ratios greater than 2: 1, a sinusoidal voltage is used as the selection voltage, which is obtained with the aid of a series resonant circuit (RS, L, C 5) matched to the divided frequency. 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the incoming pulse train is ^{fed to the two paths via a transformer (T 1} I) with two identical secondary windings, that between the two secondary windings resistor-capacitor combinations (Rl, Cl ; R2, C2) to generate the reverse voltage for the rectifier (GIl, Gl 2) and that the selection voltage is applied to the connection points of the capacitors and resistors. 5. Circuit arrangement according to one of claims 1 to 4, characterized in that for Filtering out the sinusoidal fundamental oscillation from the square-wave anode voltage Filter arrangement with as constant a characteristic impedance as possible is used. 1 sheet of drawings © 709 845/161 12.57