DE807697C - Circuit for synchronizing an oscillator with the aid of an alternating synchronizing voltage - Google Patents

Description

The invention relates to a circuit for synchronizing an oscillator, in particular a crystal oscillator, with the help of a synchronizing alternating voltage at which the synchronizing signal is supplied via a circuit containing the crystal.

In such circuits, there is a phenomenon that the amplitude of the generated by the oscillator Oscillation increases as the frequency of the AC synchronizing voltage increases approaches the natural frequency of the oscillator. In addition, when a crystal oscillator is synchronized, in which the synchronization signal is supplied via a circuit containing the crystal, still the following disadvantage.

If the frequency of the synchronization signal is equal to or almost equal to the natural frequency of the crystal oscillator, the alternating current passing through the crystal can be considerably stronger than is the case with free oscillation. This increase in current is greater, the greater the quality factor Q of the crystal.

This greater current strength has the consequence that the crystal is exposed to an increase in temperature is. If the synchronization voltage is now switched off, the result of the temperature increase is the Natural frequency of the oscillator shifted. The usual frequency value returns only after cooling down of the crystal, which is particularly long when the crystals are arranged in a vacuum can last.

In this way, the frequency stability is impaired as a result of the synchronization.

The invention is based on the knowledge that

the greater the frequency difference, the greater the amplitude of the synchronizing signal must be between the frequency of the synchronizing voltage and the natural frequency of the oscillator. Is this If the frequency difference is zero, no synchronization signal needs to be supplied.

The circuit according to the invention has the feature that the amplitude of the oscillator synchronizing signal supplied according to the

ίο Difference between the natural frequency of the oscillator and the frequency of the synchronizing AC voltage is regulated.

This regulation takes place according to an embodiment of the circuit according to the invention preferably wise in such a way that if the frequencies mentioned are the same, the oscillator does not receive a synchronization signal is fed.

With such a control, the amplitude of the oscillations generated by the oscillator remains Almost constant over the entire synchronization range, and when using the aforementioned type of synchronization of a crystal oscillator is also the alternating current passing through the crystal in this area almost constant.

The synchronization range can be extended significantly since there is no abnormal increase in temperature or even cracking of the crystal is to be feared.

The circuit according to the invention and its further embodiments are based on the in Fig. ι and 2 illustrated embodiments explained in more detail.

In the circuit according to FIG. 1, the Synchroiiisierwechselspanmfng the terminals 1 and 2 of the primary winding of the transformer 3 are supplied. The secondary winding of this transformer is in series with a resistor 4 in the control grid circuit the tube 5 added. The output voltage of this tube is via a phase rotating Xetzwerk that the secondary winding of the transformer 6, the variable resistor 7 and the Contains capacitor C, fed to the control grid of the tube 8.

The transformation ratio of the transformer 3 and the operating voltages of the tube 5 are on known manner chosen so that the output voltage of the tube 5 within wide limits is almost independent of the amplitude of the voltage at terminals 1, 2. Resistance 4 in the control grid circuit of the tube 5 serves to limit the control grid current that occurs.

The output voltage of the tube 8 is fed to the resistor 10 via a transformer 9 and the series connection of the contact A ₁ of the changeover contact relay A and the contact S _{1 of} the switch S.

This resistor 10 is included in the circuit of a crystal oscillator, the tubes and includes crystal 12. The crystal 12 is in series with the variable capacitor 13 in FIG added the control grid circuit of the tube 11, and parallel to this series circuit is the Series connection of a capacitor 14, a choke coil 15 and a resistor. The series connection the choke coil 15 and the resistor is used to form a DC circuit for the Tube n, since the cathode lead contains another capacitor 16. In the cathode lead the tube is connected to the primary winding of a transformer 17, and to the secondary winding a resistance lamp 18 is connected, creating a stabilizing negative feedback arises.

The series connection of the transformers 19 and 20 is in the output circuit of the tube 11 recorded. The load 21 connected to the secondary winding of the transformer 19, which is shown here schematically by a resistor, are those generated by the oscillator Vibrations supplied.

A part of the output voltage is via the transformer 20 of the phase comparison device 22 supplied, the purpose of which will be explained in more detail.

The synchronization signal appearing at resistor 10 reaches the grid via the series connection of the capacitor 13 and the crystal 12 the tube 11, here it is filtered by the crystal 12.

In the case of synchronized oscillators, the phase difference is between the synchronizing voltage and the current in the output circuit of the oscillator from the difference between the natural frequency of the Oscillator and the frequency of the synchronization signal.

This property is now used to regulate the amplitude of the synchronizing signal accordingly the mentioned frequency difference is used.

The output signal of the oscillator is for this purpose via the transformer 20 in push-pull fed to the rectifiers of the phase comparison device 22 designed as a modulator circuit, and a synchronizing voltage is taken from a third winding 23 of the transformer 6, which is fed to the rectifiers of the modulator circuit in common mode.

If the oscillator were to oscillate freely, which is the case when the contact S 1 of the switch 8 is closed, i.e. the synchronization signal is fed to a resistor 24, an alternating voltage would arise between the output terminals 25, 26 of the modulator circuit, the frequency of which is equal to that The frequency difference between the synchronizing voltage and the natural frequency of the oscillator is.

When the oscillator is synchronized, with the contact S ₁ closed, however, a direct voltage occurs between the terminals 25, 26, the magnitude and polarity of which is dependent on the phase difference of the voltages supplied to the modulator.

This voltage is fed via a resistor 27 to a rectifier 28, to which a capacitor 29 and a resistor 30 are connected in parallel.

The rectifier 28 is connected in such a way that the end 31 of the resistor 27 is only a negative one

Can accept potential. This end is with the center tap of winding 32 of the transformer 6 connected. As a result, the voltage appearing across the capacitor 29 is across the resistor 7 acts as a negative control voltage on the control grid of the tube 8, and the gain of this tube becomes according to the phase difference regulated between the voltages supplied to the modulator.

Fast output voltage changes of the modulator circuit are made possible with the help of the resistor 27 and the capacitor 29 are flattened.

The polarity and the magnitude of the voltages fed to the modulator are now selected in such a way that the tube 8 does not amplify if there is no phase difference between these voltages, and the amplification only begins to occur at a phase difference of about 75 ° and its full value at about 85 ° Value reached. The phase rotation of the network 7, C is set such that when the frequencies are the same and the control is switched off, ie when the voltage supply from the secondary side of the transformer 9 to the resistor 10 is interrupted, the phase difference between the input voltages of the modulator is almost zero. In this manner is effected in that during the synchronization, the phase shift is slightly smaller than about 90 ^0, so that the synchronizing bit, as required for synchronization, is higher.

Because the gain of the tube 8 corresponds to the frequency difference between the natural frequency of the oscillator and the frequency of the synchronization voltage is regulated, is the anode current of the tube depends on this frequency difference.

The anode direct current of the tube 8 flows through the series connection of the excitation winding of the relay A and the milliammeter 33. After the milliammeter has been calibrated, the frequency difference can thus be read off directly from it.

The relay A can be set so that it is energized at a certain current strength, whereby the contact A ₁ opens and the contact A ₂ closes. The resistor 24 is then connected to the output circuit of the tube 8, and the synchronization of the oscillator is interrupted.

The relay A can also be provided with further contacts with which an alarm circuit or the 'switching apparatus can be operated to another oscillator.

The relay A is effective with a delay, which can be carried out in a known manner by thermal, electrical or mechanical means.

As a result, any short interruption does not cause an alarm, and there is also another advantage: if the synchronization is interrupted if the frequency difference is too great, the modulator supplies an alternating voltage whose frequency is equal to this frequency difference, so that the anode current of the tube 8 in this rhythm fluctuates. As a result, the relay A would always be ^{energized 1} and drop out again. If the delay of relay A is chosen to be sufficiently large, contact A ₂ remains closed as long as the frequency difference is too great, and contact A _{1 is} only closed again when the frequency difference falls within the synchronization range.

In the circuit according to FIG. 2 , the regulation of the amplitude of the synchronizing signal ^{1 takes place} in a different way. Here, the fact is used that the amplitude of the alternating occurring in the oscillator ⁷ ^ seiströme and AC voltages is dependent on the frequency difference between the natural frequency of the oscillator and the frequency of the input synchronizing signal.

In the circuit according to FIG. 2, the synchronizing AC voltage is fed via the terminals 34, 35 to the primary winding of the transformer 36, the secondary winding 37 of which is included in the control grid circuit of the tube 38. The synchronization voltage for the crystal oscillator, which occurs at the resistor 40, is taken from the output circuit of the tube 38 via a transformer 39 and the switch T.

The circuit of the crystal oscillator corresponds essentially to that of FIG. 1. It is of it only different to the extent that a transformer 42 is added to the cathode line of the tube 41 is, with a resistance lamp 43 connected to part of the secondary winding and the voltage across the winding of a rectifier circuit with a resistor 44, capacitor 45 and rectifier 46 is supplied.

The DC voltage appearing across the capacitor 45 is in series with that from the battery 47 originating DC voltage of opposite polarity serving as the threshold voltage, with negative polarity is applied to the control grid of the tube 38.

The resistance lamp 43 has a stabilizing effect in the first place, as a result of the negative feedback that is brought about.

The size of the rectified voltage depends on the frequency difference mentioned. the Threshold voltage (battery 47) ensures that when the normal amplitude of the generated Vibrations to the control grid of the tube 38 no negative voltage is applied.

Claims (1)

PATENT CLAIMS: ι. Circuit for synchronizing an oscillator, in particular a crystal oscillator, with the help of a synchronizing alternating voltage, at iao to which the synchronizing signal is supplied via a circuit containing the crystal, thereby characterized in that the amplitude of the synchronizing signal supplied to the oscillator corresponding to the difference between the natural frequency of the oscillator and the frequency frequency of the synchronizing AC voltage is regulated. 2. Circuit according to claim i, characterized in that that if these frequencies are the same, no synchronization signal is fed to the oscillator will. 3. A circuit according to claim ι or 2, characterized in that the synchronizing AC voltage is fed to a control grid of a discharge tube and the output circuit of this tube is fed to the oscillator Synchronization signal is taken and that the gain of the tube as a function of the mentioned frequency difference is regulated. 4. A circuit according to claim 3, characterized in that part of the synchronizing AC voltage and a part of the output voltage of the oscillator are fed to a circuit, the * output voltage of which is from the Phase difference between the two supplied voltages is dependent, and that this the latter output voltage is a negative control grid voltage for the discharge tube is removed. 5. A circuit according to claim 4, characterized in that the synchronizing AC voltage is limited in amplitude and then a control grid via a phase rotation network with adjustable phase rotation is supplied to the discharge tube. 6. Circuit according to claims 3, 4 or 5, characterized in that the output AC voltage the discharge tube via the contacts of a delayed changeover contact relay fed either to the oscillator or to a load impedance and the excitation winding The output direct current of the discharge tube flows through the relay. 7. A circuit according to claim 3, characterized in that the gain of the discharge tube is regulated with the help of a control voltage, which is dependent on the amplitude of the oscillations generated by the oscillator. 8. A circuit according to claim 7, characterized in that in the cathode line one The discharge tube (41) received in the oscillator circuit has the primary winding of a The transformer is switched on and in parallel with part of the secondary winding one of the Amperage-dependent resistance is switched and that occurring across the secondary winding Voltage is rectified, whereupon the rectified voltage in series with a positive threshold voltage as control voltage a control grid of the amplifier tube for the Synchronizing AC voltage (38) is supplied. 1 sheet of drawings 762 6. 51