DE1815823A1 - Circuit arrangement for automatic regulation of the frequency of an oscillator with respect to a reference frequency - Google Patents

Description

Circuit arrangement for the automatic regulation of the frequency M of an oscillator with respect to a reference frequency

The present invention relates to a circuit arrangement for the automatic control of the frequency of an oscillator with respect to a reference frequency, at which a search generator the frequency of the oscillator over a predetermined Frequency range controls until one is fed with the difference between the two frequencies when the capture range is reached Frequency discriminator the search generator switched off and the control of the oscillator by that of the frequency discriminator generated output signal is accepted.

In radar technology there is often the task of determining the frequency of an oscillator with respect to a reference frequency. This problem also arises, for example, if it applies, the frequency of the receiver ^ local oscillator in a radar device automatically a changeable transmitter

909842/1085

tracking frequency. Since the frequency tuning characteristics of the transmitter and the receiver usually do not match, the frequencies of these two devices cannot easily be can be adjusted by a common drive. It is therefore advantageous to adjust the frequency of the local oscillator Transmitter frequency automatically by means of a follow-up circuit to track.

However, since the capture range of such follow-up circuits is limited so-called search circuits are used, in which the frequency of the local oscillator is determined by a search generator continuously over a predetermined frequency range is controlled until a difference signal generated from the transmission and the local oscillator frequency in the intermediate frequency range of the frequency discriminator appears. At this point the search generator is activated by an in the intermediate frequency channel The existing discriminator circuit is switched off, which then also controls the local oscillator takes over.

There is a problem that the discriminator circuit responds, regardless of whether the generated intermediate frequency is derived from an oscillator frequency that is higher or lower than the transmission or reception frequency. For the follow-up circuit, however, only the desired one results Oscillator frequency a stable control state. But it it is possible for dermo.ch to stop the search process when reaching the unwanted oscillator frequency is disturbed.

909842/1085

'ff ■ *

In order to prevent this, the search range was limited to a range in which only the ge desired oscillator frequency is in circuits known so far. However, because of the scatter in the tuning characteristics of the oscillators, this circuit is only suitable for small frequency ranges.

In the case of circuits that are also known, the search procedure is from a predetermined range end in a predetermined direction started. This arrangement has the disadvantage that mechanically tunable oscillators require relatively long tuning times result, since the predetermined end position must always be approached first. The predetermined end position must also be controlled again if during the search process when crossing the target frequency for any reason the switchover of the stouertmg could not take place.

The purpose of the present invention is to provide a To create a circuit arrangement that eliminates the above disadvantages.

The circuit arrangement according to the invention is characterized in that that a bistable multivibrator is available, the two inputs of which each have an AND gate with the output of the Frequency discriminator are connected, that a marker is also connected to the input of the frequency discriminator is that in the presence of a in the capture range of the frequency discriminator lying input signal emits a voltage, and that one with the oscillator, the frequency discriminator,

909842/1085

the marker of the bistable multivibrator and the search generator connected control circuit is provided which when a discriminator output signal of predetermined polarity occurs, the oscillator continuously in a predetermined direction detuned and when changing the polarity of the frequency discriminator output signal while it is present a marker output voltage causes the oscillator control to switch to the discriminator output signal .

The new circuit arrangement has the advantage that it only responds at a predetermined oscillator frequency which is higher or lower than the reference frequency. By switching of the control sense of the control circuit, the other oscillator frequency can be set in a simple manner.

An exemplary embodiment of a circuit arrangement according to the invention is explained below with reference to the drawing.

Fig. 1 shows a circuit arrangement for automatic control the frequency of an oscillator with respect to a reference frequency. Fig. 2 shows the output signal of the frequency discriminator as a function of the oscillator frequency and with respect to a Reference frequency.

In Fig. 1, a circuit arrangement is shown for automatic Regulation of the frequency fo of an oscillator 1 with respect to the frequency fB of a reference signal source 2. The reference signal source 2 can e.g. B. represent the input of a recipient,

909842/1085

whose local oscillator frequency tracks the reception frequency shall be. However, the invention is not restricted to this exemplary embodiment.

The circuit arrangement is structured as follows: The outputs of the oscillator 1 and the reference signal source 2 are fed to a mixer 3. A frequency discriminator h and a marker 5 are connected to the output of the mixer 3. The output of the frequency discriminator h is connected to an input of two AND gates 6 and 7 each. These M AND gates 6 and 7 are provided for signals with different polarity. A voltage + U or -U is applied to the second input of each AND gate 6 or 7. The output of each AND gate 6 or 7 is connected to an input of a bistable trigger circuit 8. This flip-flop 8 emits a signal at the output in one position, which signal is fed to a control circuit 10. The control circuit 10 consists of a first relay 11, a second relay 12 and a motor 13 coupled to tuning elements of the oscillator 1 and limit switches 1 ^ which is connected to a voltage U on the work side via a changeover contact 11-2 of the first roller relay 11 and on the rest side a changeover contact 12-2 of the second relay 12 can be connected. The rest side of this changeover contact 12-2 is connected to the output of a search generator 9 and its working side is connected to the output of the frequency discriminator h . The first relay 11 is connected to the output of the toggle circuit 8 and the second relay 12 is connected to the output of the marker 5 via normally open contacts 11-1 and 12-1 connected in parallel to the first and second relays 11 and 12.

'* "9 0 ³ 9 8 i 2/1 0 8 5 ORIGINAL INSPECTED

The limit switches 14 are in the end positions of the oscillator spacing imine learn te operated. The engine is thereby when reaching the end position and automatically in the opposite one D> rehrich1ning put into operation again.

The circuit now works as follows: From the signals emitted by the two signal sources 1 and 2 with the frequencies fo and fB, a signal component is generated in the mixer 3 in a known manner, which has the difference between the frequencies of the two signals supplied and is correspondingly designated with fD . Depending on the size of this signal, it would be necessary to amplify it in a subsequent "amplifier, for which purpose a selective amplifier tuned to the difference frequency fD would advantageously be used. The difference signal is ^{fed on the one hand to the frequency discriminator 1} '+ and on the other hand to the marker 5", Der Frequency discriminator k has a frequency / voltage characteristic corresponding to the diagram in Fig. 2i. The structure of the frequency discriminator k and the requirements placed on it with regard to use for a frequency approximation are sufficiently known, which is why it is not discussed further from a selective amplifier, the bandwidth of which corresponds to the Föngbereiclides; frequency di skr imina'tors 4. This -Marker 5- has the task of L, U by outputting an output voltage aril the: Control cha 1 tion 1 O the presence of a - Dif erenzsdghals f ma rki he eil. J 3 ria ehd era ", whether he ü frequency di skriinlnai or h emits a positive or negative signal UF, i is> from gate 6 or 7 the applied voltage + ¥ ^T or -XJ to - the corresponding

909842/1085

Input of the bistable flip-flop 8 switched through, whereby this tilts in one position or the other.

The control circuit 10 is used to use the signals emitted by the bistable multivibrator 8 and the marker 5 to form the criteria for controlling the oscillator 1 and to carry out the control itself. The one given here Circuit is only one of the possible solutions.

The criteria for controlling the oscillator frequency fo are the following:

1. If there are no output signals at the outputs of the frequency discriminator k and the marker 5, the oscillator 1 is controlled by the search generator 9 alternately in one or the other direction over a predetermined frequency range.

2. The occurrence of a negative discriminator output signal UF corresponds to the information that the current oscillator frequency fo lies between the frequency values fo1 and fo2, both of which would generate a difference frequency fD corresponding to the frequency discriminator k (FIG. 2). This negative output signal UF causes the oscillator frequency fo by the motor 13 in a predetermined direction (given by the polarity of the voltage U at the normally open contact 11-2) in the direction of the selected setpoint frequency, e.g. B. fo2 is adjusted. .

909842/1085,

3. Changing the polarity of the discriminator output signal UF to "plus" during the predetermined detuning of the oscillator 1 against the setpoint frequency and the presence a marker output voltage causes the discriminator output signal UP takes over the control of the oscillator frequency fο.

The following is a general operational case like that z. B. at the moment the device is switched on, considered:

It is assumed that at the moment under consideration the oscillator 1 oscillates at a frequency fo corresponding to point A in FIG. 2. The reference signal has the frequency fB. It is now the task of the circuit arrangement to readjust the oscillator frequency fo to the setpoint frequency fo2 assumed in this example. At point A, the oscillator 1 oscillates outside the range of the frequency discriminator h and that of the marker 5i, which is why these do not emit any output signals. The relays 11 and 12 have initially dropped out, which is why the output of the search generator 9 is switched through to the motor 13. According to a further assumption, the search generator 9 is polarized at the moment in question in such a way that, with the motor 13, it drives the oscillator 1 against lower frequencies, i.e. Ii. adjusted in the direction of fo1. As soon as the oscillator frequency fo has exceeded the capture range of the frequency discriminator k, at point B, it emits a negative signal UF at the output. As a result, the AND gate 7 switches the applied voltage -U through to one input of the bistable multivibrator 8. This tilts it into the position

909842/1085

in which it emits an output signal and thus pulls the relay 11 of the control circuit 1O. The changeover contacts 11-1 and 11-2 are switched over. The motor 13 is now connected to the voltage U and receives a supply voltage U, which causes the oscillator 1 to move in a predetermined direction towards the setpoint frequency; fp2 is adjusted. When the capture range of the frequency discriminator k is reached at point 0, it emits a negative signal UF. However, this has no effect because the bistable flip-flop is already in the flipped position. The marker 5 are in Fangbe ^ * M area of the Frequenzdiskriminätors 4 also, a Ausgangssi- * gnal from, which relay is drawn 12th Switching the changeover contact 12-2 is initially ineffective. The motor 13 accordingly continues to rotate in the same direction until the setpoint frequency fo2 is reached. When the same threshold is exceeded, the polarity of the output Signa Is UF of the frequency discrete.natQrs 4. The positive signal UF causes the AND gate 7 to be blocked and the AND gate 6 to be opened. The positive voltage + Ü reaches the input of the bistable trigger circuit 8 * This now tilts back to the original position), so that its output signal disappears and the relay 11 drops out. The motor 13 is now connected via the fallen k -2 contact 11 and the contact 12-2 reared to the output of Frequenzdiskriminätors. With the latter switching operation, the oscillator frequency control was switched over to the discriminator output signal UF. Due to the closed normally open contact 12-1, the relay 12 is kept in the open state as long as on

909842/1085

Marker 5 has an output signal. The bistable Toggle switch 8 has a pre-pulse rate switching threshold, so that it does not tilt and undesirably in the event of small deviations in the oscillator frequency fo compared to the setpoint fo2 turns the viewing process back on. ,

March 21, 1968
Sck / Luh

903842/1085

Claims (3)

'Ί 81 58-23 claims 1. Circuit arrangement for the automatic control of the frequency of an oscillator with respect to a reference frequency, at which a search generator controls the frequency of the oscillator over a predetermined frequency range until the search generator is switched off when the capture range of a frequency discriminator fed with the difference between the two frequencies is reached and the control of the oscillator is switched off is over- ύ nomrnen by the output signal generated by the frequency discriminator, characterized in that a bistable multivibrator (8) is present, the two inputs of which are connected to the output of the frequency discriminator (4) via an AND gate (6 or 7) that a marker (5) is also connected to the input of the frequency discriminator (4), which emits a voltage when an input signal (fD) is present in the capture range of the frequency discriminator (k) , and that one with the oscillator (i), the frequency discriminator (k), the marker (5) of the bistable toggle circuit (8) and the search generator (9) connected control circuit (1 θ) is provided which, when a discriminator output signal (UF) of predetermined polarity occurs, the oscillator (1) continuously detuned in a predetermined direction and which when the polarity of the frequency discriminator output signal ( UF) causes the oscillator control to switch to the discriminator output signal (UF) while a marker output voltage is present. 909842/1085 2. Circuit arrangement according to claim 1, characterized in that that the control circuit (1O) consists of a first relay (ii), a second relay (12) and one with the tuning elements the oscillator (i) coupled motor (13) consists of a changeover contact (i1-2) of the first Relay (11) on the work side to a voltage (Xl) and on the rest side can be connected to a changeover contact (i2-2) of the second relay (12), the rest side of which is connected to the output of the Search generator (9) and the working side of which is connected to the output of the frequency discriminator (4), and that the first relay (ii) at the output of the flip-flop (8) and the second relay (12) connected in parallel Working contacts (11-1, 12-1) of the first and second relays (11, 12) connected to the output of the marker (5) is. 3. Circuit arrangement according to claim 1, characterized in that that one AND gate (6) is provided for input signals with reversed polarity with respect to the other AND gate (7) is. 909842 / 108S