DE1018100B - Circuit arrangement for phase-locked halving of a pulse repetition frequency - Google Patents

Description

When transmitting messages with the help of pulses, especially with pulse modulation systems, the task often occurs to convert a pulse train into a square wave voltage, a sinusoidal voltage or a other pulse train with a frequency lower than the original pulse train frequency phase-locked derive. In particular, bistable multivibrators are suitable for phase-locked frequency division, since the Tilting oscillation at the working point of greatest steepness with 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 point is strong here depends on the tube data, the operating voltages and the amplitude of the control voltage.

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. Since 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 from it Sinusoidal voltage.

The invention shows a simple way, in the event of the frequency halving of a pulse train to achieve complete phase rigidity. The invention is through a multi-circuit with a differentiating and a non-differentiating reverse circuit arrangement for phase-locked halving of a pulse repetition frequency

Applicant:
Siemens & Halske Aktiengesellschaft,

Berlin and Munich,
Munich 2, Witteisbacherplatz 2

Dipl.-Ing. Walter Arens,

Dipl.-Ing. Hans-Martin Christiansen

and Dipl.-Ing. Hermann Pfeifer, Munich,

have been named as inventors

Coupling path marked, which is opened and blocked by a rectifier in the control grid circuit are, and by an input differentiator, via which the pulse train to be divided is fed to the control grid circuit, the time constants of the Feedback paths and the input differentiator are chosen such that the multi-tube is alternately opened and blocked by successive input pulses.

The invention will be explained in more detail with reference to the drawings using an exemplary embodiment. The drawings show in

1 shows a circuit arrangement for phase-locked halving of a pulse repetition frequency,

2 shows the time processes when halving the frequency.

In the circuit arrangement of FIG. 1, the rectifier Gl and the differentiating feedback transformer Tl (cathode grids) are typical of the Multiarschaltung switching elements. A second feedback path (anode grid) is formed by the non-differential transformer T 2. It is also possible to connect the primary windings of the two feedback transformers in series and place them either in the cathode or in the anode lead. The pulse train to be divided reaches the control grid circuit via b and the differentiating element Cl, Rl. The output voltage can be increased / decreased at the external resistance i? 4. For setting a positive cathode potential

709 757/101

The resistor R 2 in the cathode lead, which is bridged by a capacitor C 2, is used against earth. The anode voltage source is connected between + Al and earth, the grid of the tube receives a positive potential (+ A2) against the cathode via the resistor RZ.

To explain the operation of the circuit arrangement, the current and voltage waveforms at the indicated as points in Fig. 2 DAR constant of the differentiating the transformer T 1 is chosen such that it is small against the distance of the input pulses, however, after all, still so large that the switching pulses transformed into the grid circle (Fig. 2, line k) decay sufficiently slowly, and the time constant of the differentiating element Cl, Rl has such a size that the differentiated pulses swing through only a little below their zero line, so that at the time of the pulse return edge U2 > U1 is

posed. The respective state of the rectifier Gl io (Fig. 2, lines «? And c). With the right attitude

- permeable or blocked - is in the bottom line by a closed or open switch indicated.

The tube is initially live; The cathode voltage Uk flows with the aid of the resistor R2 . In any case, it can be achieved that the tube remains energized until it is blocked again by the trailing edge of the following pulse 3

via R3 and the grid-cathode segment a less than 15 (point in time i3). A cycle has now been run through. Grid current, so that the grid potential is approximately. A rectangular anode current is created

UK). - -

with half the pulse repetition frequency of the control pulses. The steep sloping flank of the is correct in terms of time Anode current with the trailing edge of a control

is equal to the cathode potential (Ug ä * Uk). Of the
Cathode resistance R 2 causes a positive potential (Uk) of the cathode to earth. The sum of the
voltages occurring in the grid circle at point e 20 pulse and the slightly flatter rising edge is positive and outweighs the cathode voltage Uk of the anode current with the leading edge of the following (Fig. 2, lines e and g) ; the rectifier Gl is therefore the same as the control pulse. The pulse duty factor (pulse blocked, duration to pulse spacing) for the anode current is the time constant Cl-Rl of the differentiating element located at input b is slightly greater than 1: 2, since the duration of the current flow is in the order of magnitude, which is twice the duration of the control pulses tion of the duration of the incoming pulses, so that as the current break.

With positive polarity incoming pulses at the target instead of the square wave at the output

Point c the voltage shown in FIG. 2, line c, whose sinusoidal fundamental oscillation is obtained. If the quasi-differentiated pulse 1 is loaded, the anode resistance i? 4 has the effect that the voltage at point e first rises.

and then falls, namely it falls below the cathode voltage Uk (FIG. 2, lines e and g) because of the falling pulse roof. As a result, the rectifier Gl becomes conductive and opens the two feedback paths, whereby the tube is immediately blocked. At this point in time ti of the pulse trailing edge, the following voltages occur: The transformer T 2 transforms the anode voltage Ua with the opposite sign into the grid circle, where it is replaced by a pending wave resistance.

A different from the rectangular anode current can also be used. Pulse sequence with any pulse duration can be derived if a current-fed pulse-forming network is set in place of the anode resistor RA. The desired pulses are advantageously obtained from the steep cut-off edges of the anode current.

If a pentode is used instead of a triode,

When the quasi-differentiated pulses 40 are superimposed, their braking grid is expediently produced on the screen with a voltage form as shown in Fig. 2, line d, grid potential. This gives a small one for is reproduced. The transformer transforms the power output of the tube mainly inside the blocking impulses occurring at the cathode (Fig. 2, resistance R _iL ; in addition, a high anode line causes £) in-phase into the grid circuit, so that resistance is created by limiting the residual current of the anode and by superimposing the voltage on Point d gives the voltage waveform drawn in FIG. 2, line e, which is largely independent of the tube data. Anode square voltage. Via the conductive rectifier Gl , g
a large negative voltage spike, which the
causes rapid blocking of the tube. Since the time constant of the transformer T 2 is large compared to the Im- ₅₀
pulse spacing is selected, the voltage remains on
Point d and thus also the grid tension up to
Arrival of the next impulse sufficiently negative, so
that the tube cannot unlock itself.

When pulse 2 arrives at time i2, the tube is unlocked again, in the following way: The leading edge of the pulse results in an increase in the grid voltage to positive values, so that anode current begins to flow. Since the voltage at point e exceeds the voltage at grid g , the rectifier Gl and thus also the two feedback paths are blocked. Since the feedback is ineffective when the current rises and is effective when the current falls, the steepness of the leading edge of the anode current pulses is also somewhat less than the steepness of the trailing edge.

So that the trailing edge of pulse 2 does not immediately block the tube again, the voltage at point e must not drop below the cathode voltage Uk. This can be prevented as follows: The time con-

Claims (4)

Patent claims: 1. Circuit arrangement for phase-locked halving of a pulse repetition frequency, marked by a multi-circuit with a differentiating and a non-differentiating Feedback path, which is opened and blocked by a rectifier in the control grid circuit, and by an input differentiator via which the pulse train to be divided is sent to the control grid circuit is supplied, the time constants of the feedback paths and the input differentiator are chosen such that the multi-tube by successive input pulses is alternately opened and locked. 2. Circuit arrangement according to claim 1, characterized in that the feedback takes place by means of a transformer and that the time constant of the differentiating transformer (Tl) is small, the time constant of the non-differentiating transformer (T 2) is large compared to the spacing of the input pulses. 3. Circuit arrangement according to claim 1 and 2, characterized in that the output pulses derived from the steep cut-off edges of the anode current with the help of a pulse-forming network will. 4. Circuit arrangement according to claim 1 and 2, characterized in that for sieving out the sinusoidal fundamental oscillation from the square-wave anode voltage a filter arrangement with as constant a wave resistance as possible. 1 sheet of drawings