DE1001343B - Circuit arrangement for setting the oscillation frequency of an oscillator - Google Patents

Description

The invention relates to a circuit arrangement for setting the oscillation frequency of an oscillator to a desired value by means of an automatically controlled tuning device and one that checks the generated frequency and if it passes a deviation from the preferably selectable transmitter frequency a control of the tuning device in a corrective sense effecting control device. Application of the invention gives particular advantages in the remote control of the tuning process for an oscillator of adjustable Frequency. An arrangement required for this is simplified and made cheaper by the invention and allows the controlled oscillator to be reliably set to a plurality of predetermined ones selectable frequencies within an extended frequency range, with the selected Frequency is automatically maintained at the desired value with great accuracy until a new setting is made is made on a different frequency.

An arrangement of the specified type is already known for solving the same problem (US patent specification 2 490 500), in which an electronic counter is used to count a number of the Count the oscillation periods executed by the oscillator and thereby determine the time interval, in which a predetermined number of periods expires on which the counter is set. After every When such a number of periods has elapsed, the counter emits an electrical pulse. The temporal The intervals between these pulses correspond to the mentioned time interval to be determined and form a measure for the duration of a period, i.e. for a quantity that is reciprocally related to the frequency. In a corresponding manner, a pure pulse is derived from the oscillation of a normal frequency generator. The principle of the known arrangement consists in that by certain circuit parts known to the person skilled in the art from the two pulse series a resulting pulse series is derived, which depends on whether the to be controlled by the Oscillator-derived pulse of its series occurs earlier or later than the associated normal frequency pulse, contains a positive pulse in the first case and a negative pulse in the second case. By electrical Integration of the resulting pulses becomes one in a limited range of the frequency error according to the direction and size of the corresponding controlled variable obtained, which on the afflicted with the frequency error Oscillator is brought into effect in a corrective sense.

A major disadvantage of this known arrangement is that the oscillator, the frequency of which is to be controlled, is already set up by the user
the oscillation frequency of an oscillator

Applicant:

Marconi's Wireless Telegraph
Company Limited, London

Representative: Dr.-Ing. B. Johannesson, patent attorney,
Hanover, Göttinger Chaussee 76

Claimed priority:
Great Britain 23 December 1952 and 26 August 1953

Thomas Theodore Brown, Epping, Essex

(Great Britain),
has been named as the inventor

must be set almost to the desired frequency for the automatic control to take effect. The controlled variable is not in a monotonic but rather in a periodic relationship over a wider range with the positive or negative frequency error. All values of the controlled variable are repeated after a frequency error determined by the pulse spacing of the series mentioned is exceeded. In the event of an arbitrary initial detuning of the oscillator to be controlled, the automatic control cannot easily be activated by setting the desired frequency on the counter. It is also necessary to tune the oscillator at least roughly to the desired frequency, so that the pulses derived from its oscillation via the counter are almost twice as far apart from the pulses derived from the normal frequency. The known arrangement is therefore not readily usable for fully automatic voting, especially for remote voting.

The above-mentioned disadvantage of the known arrangement is avoided by the invention. In a Circuit arrangement for setting the oscillation frequency an oscillator to a desired value by means of an automatically controlled tuning device and one that checks the generated frequency and compares it if there is a deviation

609 767/299

the preferably selectable setpoint frequency a control of the tuning device in a corrective sense effecting control device in which to count a number of the executed by the oscillator Oscillation periods a known electronic counter, preferably in decadic Graduation, is provided and the counter is made effective during a time interval of a specified duration, is brought into connection, for example, with the oscillator, according to the invention, the Counter be designed such that the counting result as a change in the electrical state of a certain or several specific ones from a

Output of the counter appearing counting result and that indicated by the position of the switch Result operated the motor in such a way that the oscillator on the disappearance of the mentioned Difference is set.

The oscillation of the oscillator to be controlled is expediently in a fixed phase position compared to that of the local oscillator. This can be achieved, for example, in that a harmonic generator synchronized by the local oscillator is provided, which within the Working frequency range of the oscillator to be controlled is a spectrum of oscillation frequencies at the mutual distance of the frequency of the auxiliary

The closest is taken along with your own vote. More expedient

number of electrical charge carriers is recorded

and that an oscillator is generated on the aforementioned charge carriers and one of which generates this harmonic

direction with two voltages containing the niches in the event of their excitation to the control

Tuning device in the opposite sense controlling oscillator is fed in such a way that it is controlled by

the electrical working groups connected to his

is that if the count is too large, the oscillator harmonics

frequency lowering, if the counting result is too small, the auxiliary oscillator is equipped with a crystal control

the working circuit increasing the oscillator frequency.

is excited. In an advantageous embodiment of the invention, the counter contains a cascade circuit. In this counter, which in contrast to the known cascade circuit, the first discharge order does not count a predetermined number of periods path of a subsequent counter tube with the last and as a result determines the time interval required for the expiry of this period discharge path of a preceding counter tube counting, but rather the bound one, so that when using 10-stage counting, each of the individual periods is determined in a decimal gradation in a number of periods. Already the
Exceeding or falling below the desired number of vibrations by a counted unit solves the rule

effect for correcting the number of oscillations im

in relation to the preceding counts.

In such an arrangement with several counter tubes assigned to the individual decimal places, the correct sense, which can be set to the selectable frequencies, consists of. The control effect remains up to 35 switch arrangements (frequency selector) from an arbitrarily large error ", because the control variables speaking number of individual switches, from monotonous with the positive and negative errors, each of which is a variable with an associated counter tube and no reversal points work together. Each switch contains one of the number or ambiguities.The circuit of discharge paths of the associated counter tube arrangement according to the invention can therefore be formed from the corresponding number of the output electrodes that - regardless of the size of the contacts individually connected to the discharge paths Error - if the count result is too large, always the one and also at least two other concurrent oscillator frequency lowering, if the number is too small, preferably segment-shaped contact result always the part increasing the oscillator frequency, one of which is that group of counter working circuits is being excited. L ^T m to achieve this, the 4-5 outputs are connected to a working group, in the mentioned working groups containing device which a change of state occurs when the count is too small to the mentioned, the counting result electrically fixed result, and the other connected to the corresponding holding charge carrier . Connection between the other working group and

The invention is intended preferably for the remote that group of counter outputs in Tuning the controlled oscillator uses 5 ° whichever

will. In one embodiment of the invention the tuning of the oscillator to be controlled is effected by a motor drive, and it is a Facility provided, which from the output of the

sine change of state if the count result is too large entry. Each switch preferably also contains a third one, running concurrently with the two

The first-mentioned adjustable contact part, via which a connection from an oscillator, which is mentioned with a correct counting result, has an oscillation frequency influenced counter output to a third work line, which is produced in a predetermined, by an arithmetic circuit, which expresses the controlling effect of the table relationship to the
generated oscillator frequency. Furthermore, a preferably frequency-stabilized auxiliary oscillator is provided

interrupts the other working groups.

In this embodiment of the invention, the three working circuits can each have a relay for switching on

seen, of its output ^{oscillation a switching 6o} of the moving the tuning means of the oscillator

organ is controlled, which applies the oscillation derived from the oscillator oscillation for a certain period of time and in periodic repetition to the electronic counter. In connection with the electronic counter , at least one adjustable switch is also provided, the individual positions of which correspond to a plurality of mutually different selectable frequencies, as well as a further switching device which

Electric motor in one direction or the other and another relay to shut down the Motor included in case of correct tuning. The excitation coils of the three relays are similar connected to the aforementioned three adjustable contact parts of the switch, the relay which is connected to the contact part indicating the correct counting result, in the event of its excitation the connections of all three relay coils on the three

depending on the difference between the contact parts of the switch corresponding to 70

the following decade of counting advances. In this next one Counting decade which has a lower ordinal number than the preceding one (for example the ordinal number of the group of hundreds if the previous decade of counting of the group of thousands belonged to), if there is a detectable error in this group, one of the the first two working groups to control the tuning device in a correcting direction set until the error is smaller than one counting unit of this group and the third working group or the relay present in this when it responds at the same time as the one in operation interrupts the first two working groups and all three working groups to the associated three contact parts * 5 of the selector switch or counter tube of the next lower ordinal number (for example the Group of ten) advances and so on until the lowest order count is reached.

For the intermittent connection of the frequency to be controlled to the counter input is a provided by the preferably crystal-controlled auxiliary oscillator driven switching element, which in a predetermined repetition period and for a predetermined, a fraction of this period amounting Duration of the oscillation of the oscillator to be controlled or one derived from it Lets oscillation to the electronic meter. Besides this for the passage of those to be checked Vibration to the counter provided locking switch, the switching element contains another, synchronous with the first-mentioned driven switch, which is switched into the anode circuit of the counter tubes and its anode current for a short period immediately before each pass interval of the former Switch interrupts.

The invention is explained with reference to the drawings, in which in the form of a basic circuit diagram and only as an example of a possible embodiment, two arrangements according to the Invention are shown. To clarify the description are also practically usable Values of the frequencies given, but it should be assumed that the invention is in no way based on the Application of any specifically specified frequencies is intended to be limited.

In Fig. 1, the main oscillator, which is to be set to a desired frequency and kept as precisely as possible, the tube Vl. The oscillator can be connected in any suitable manner known per se, as shown in the drawing; it has a frequency-determining tuned oscillating circuit LC, the tuning of which can be changed accordingly by changing the capacitance of the capacitor C. This change is effected by the electric motor M which is controlled in a manner to be described later and which drives the capacitor via any suitable mechanical transmission, which is indicated by the broken line CD . The main oscillator, whose tuning range in this example may be between Γ and 2 MHz, emits its output oscillations to any consumer via the indicated line O UT .

The oscillation frequency of the main oscillator is converted to a suitable lower frequency range by frequency division, e.g. B. to 10 to 20 kHz. The frequency divider FD within the broken line labeled accordingly is used for this purpose. The frequency divider may be of any known type and is assumed in the drawing to be a series connection of a number of frequency divider stages, only one of which is shown with the double tube V 2. The output frequency of 10 to 20 kHz, reduced according to the division ratio, is intermittently passed to the counter, for which purpose the synchronous switch SWC is provided with the pair of brushes SWB 1 and SWBI, which slide on a drum-like, rotating contact ring. The contact ring and the brushes are designed so that the brushes are connected to one another by the contact part of the switch SWC for a period of one tenth of a whole drum revolution and that they are isolated from one another for the remaining nine tenths. The switch drum is driven at one revolution per second in a manner to be described later. On the same switch axis together with the switch mentioned above, a second synchronous switch is provided, which has a contact ring with the contact element 2SWC , which makes up a little more than nine tenths of the entire circumference and on which a pair of brushes 2 SWBl and 2SWB2 slides. The brushes are arranged in such a way that the connection otherwise existing between them (via the contact ring) is interrupted for a little less than a tenth of a revolution. The action and position of the contacts SWC and 2SWC is chosen so that the connection between the brushes 2 LSWB1 and 2 SWB 2 is interrupted shortly after the end of each period of ^9/10 see duration during which the brushes SWB1 and SWB 2 from each other were separated. The brush 2 SWBl is connected to an anode voltage source, not shown, and the brush SWB 2 leads to the anodes DAA, DBA, DCA of the three electronic counter tubes DA, DB, DC. The counter tubes can be of the type known under the designation "Dekatron". In this way, the anode voltage of the counting tubes is switched off once with each rotation of the switch with the contact ring 2 SWC; during the remaining time of a revolution period, as long as the brushes 2 SWB1 and 2SWB 2 are connected to one another, the circuit is closed. The counter tubes are all identical to one another and each have ten cathodes, numbered 0 to 9, each working with an anode, DAA, DBA, DCA , as well as a control electrode within the same gas-filled vessel. When anode voltage is applied to the anode of a counter tube, a discharge occurs between the cathode 0 and the associated anode. When the control electrode is supplied with a pulse, the discharge migrates over to the discharge path between the cathode 1 and the anode; a second pulse fed to the control electrode results in a further migration by a further step, ie onto the discharge path between the cathode 2 and the anode, and so on. The discharge is maintained in the counter tube as long as the anode voltage is uninterrupted, starting from a cathode, which is determined by the number of pulses that have meanwhile reached the control electrode of the counter tube and which therefore shows the number of these pulses through its ordinal number.

The output voltage of the frequency divider FD is fed intermittently from the brush SWB 2 to the counter tube DC. Let it be the cathode 9 of this counter tube with the Kat | ipde_ 0 of the counter tube DB

connected and correspondingly the cathode 9 of the counter tube DB also with the cathode 0 of the counter tube DC.

The cathodes 0 to 9 of each individual counter tube are individually connected to the ten contacts CO to C 9 of one of the three selector switches SSA, SSB, SSC via associated output resistors. Each of these switches has three contact parts on the output side, labeled X, Y and Z. The contact part Y can be set arbitrarily to any of the contacts C0 to C9, the result of the arrangement being that the contact part X is then connected to the group of all contacts which are assigned a higher count than that of the contact part Y. Correspondingly, the contact part Z is connected to the group of all those contacts to which a smaller counting result belongs.

The circuit used in the arrangement for frequency stabilization contains a crystal-controlled auxiliary oscillator with the tube VS ₁ which oscillates at 1 kHz and is stabilized by the piezoelectric crystal PX , whose resonance frequency is 1 kHz. The output oscillation of this oscillator drives a synchronous motor which contains a so-called phonic wheel, ie a gear wheel PM with a corresponding number of teeth, which in turn sets the switch axis S in motion to drive the switch at one revolution per second. The output oscillation of the local oscillator is also fed to the input electrode of a harmonic generator which contains the double tube V 4 and generates pulses whose leading edge has a duration of approximately half a microsecond at a repetition frequency of 1 kHz. In this way, the pulse generator generates a grid of harmonic frequencies at intervals of 1 kHz, the amplitude of which remains approximately the same up to approximately 2 MHz and beyond. The output oscillation of the pulse generator is fed to the control grid circuit of the main oscillator, which is consequently carried along by the harmonic which is its own down-tuning, so that it oscillates in phase-locked connection with the harmonic generator.

Before describing the control circuit for the motor, let us consider the operation of the parts of the system already described, assuming that the main oscillator is to be tuned to its desired frequency of 1,735,000 Hz. The switches SSA, SSB and SSC are then brought into the positions shown in the drawing, with the contact part Y of the first-mentioned switch set to the contact element C 7 ', the contact element Y of the second switch to C 3 and that of the third switch to C 5 is. When the main oscillator generates the desired frequency, the set frequency of 735 pulses is sent from the brush SWB 2 to the counter during one tenth of a second of a revolution of the lock switch SWC. The first ten pulses cause the ten discharge paths between the cathodes and the anode of the counter tube DC to ignite in succession; the impulse that occurs when the discharge of the cathode 9 is extinguished ignites the discharge path from the cathode 1 to the associated anode of the counter tube DB. Each subsequent group of ten pulses shifts the discharge in the counter tube DB upwards by one step from one cathode to the next until the discharge at the cathode 9 is extinguished and the discharge transfers to the cathode 1 of the counter tube DA . In this way, the Dekatron DA counts hundreds of pulses (corresponding to 100 kHz each), the Dekatron DB counts tens of pulses (corresponding to 10 kHz each), and the Dekatron DC counts individual pulses (corresponding to each

1 kHz). If 735 pulses arrive in a switching period of V10 see, the discharge is in the counter tube DA between the cathode 7 and the associated anode, in the counter tube DB at the cathode 3 and in the counter tube DC at the cathode 5. These discharges are for the rest Maintain part of the switching period corresponding to the rotation of the switch shaft for about ⁹ / io see until the common anode circuit between the brushes

2 SWBl and 2 SWB 2 is interrupted. When the selector switches SSA, SSB, SSC are brought to the position shown in the drawing, there is a continuous connection to the output-side switching elements Y of the three switches via the counter tubes. If the counting result deviates from the number determined by the switch (assuming 1735), there is a connection to one of the other two working groups via the counter tubes, depending on the extent and direction of the error. It should be noted that in the arrangement described, the thousands of the pulse number are not counted. If you wanted to do this as well, a further counter tube stage would be required. However, since the frequency range under consideration only extends from 1,000 to 1,999 MHz, there is no need to count the thousands. If the number of counted pulses in the hundreds is too large, the counter tube DA closes a connection to the output-side contact element X of the switch SSA. If the result is too small, the counter tube accordingly closes a connection to the contact element Z of the switch SSA. In the same way, if the count is too high or too low in the tens digit, a connection to the associated contact element X or Z of the switch SSB is established via the counter tube DB , and a result that is too high or too low in the ones digit results in one Connection via the counter tube DC with the corresponding contact elements X or Z of the switch SSC.

The drive direction of the motor M is reversible. The circuit indicates that it is driven in one direction or the other, depending on whether it is supplied with current from one or the other of the two current sources FB or RB of opposite polarity via the contacts of the relays RWF and RWR. When the former relay operates, the motor is driven in such a direction that the tuning frequency of the circuit LC is increased, and when the relay RWR picks up, the motor rotates in the opposite direction. A third relay called RWS is also provided. The excitation coils of these three relays can be connected to the output-side contact parts XYZ of the three switches SSA, SSB, SSC , whereby the relay RWS serves to switch these connections from one switch to the switch of the next lower ordinal number as often as it comes into operation. When the arrangement for controlling the drive motor, as shown, is connected to the contact parts X, Y and Z of the switch SSA and the relay RWS comes into operation, the connections to the contact elements X, Y and Z of the switch SSB are switched over in this way . The next time the RWS relay is actuated, the connections migrate

9 10

over to the contact parts X, Y, Z of the switch electronic switches are used at this point

SSC, and on the further following actuation.

the connections return to the switch SSA. In the embodiment according to FIG. 2, parts corresponding to one another are denoted by the same reference numerals for relays and contacts and the necessary 5 as in FIG. The frequency divider and a circuit element for the motor control can, in the counting stage of Fig. 1, are omitted. In this any suitable manner and arrangement, the output oscillation of the main will be self-evident to those skilled in the art, so that no further explanation is required for the oscillator to the input of a mixing tube VM. The requirements for this are purely related to the output circuit C2L2 of a second pulse generator of a structural nature and are therefore derived for the purpose of connecting the tube V 5, which is a harmonic simplification of the illustration in Fig. 1, omitted from the grid from each other around 100 kHz, provides distant frequencies, which extends over the At the end of each switching period, which corresponds to a single range from 1 to 2 MHz (the tuning range of the counting process, the position of the discharges gives 15 main oscillator). By matching the hundreds, tens and capacitors C 2 and C 3 in the three counting tubes to one of the pulses that have arrived within these circuit-coupled circuits of the pulse generator from the period. At this point, any desired harmonic can be taken from the control circuit for the drive motor to the tube V 5, with a step-by-step tuning connected to ten switches SSA . If now the result is provided in 20 steps, which is effected by the same one of the hundreds group higher or lower than the tuning motor M , in such a way that in each case it corresponds to the setting of the switch SSA , the tuning position of the circle CL runs along with the aforementioned Motor on and changes the tuning of the coupled circuits in the output of the tube V 5 circuit LC until the error in the hundreds group is that of the tuning of the main oscillator next smaller than a counting unit. By pulling in the 25 harmonic frequency from the generated RWS relay, the control circuit of the motor will then select the grid. The tube of the pulse generator is switched to the switch SSB , and when one is in it is controlled at 100 kHz; this control is the group of ten detectable errors, sets the tuning of the auxiliary oscillator with the tube V 3 via one of the motors again in such a way that the circuit for selecting the corresponding harmonic or error causes below the limit of the niches in the group of ten 30 . In the circuit according to the drawing a determinable size is brought, whereupon the relay is the oscillation circuit 5 LC on the 5th harmonic RWS again picks up and the motor control circuit is tuned according to 5 kHz, and it advances to it on the switch SSC. Here the voltage that occurs is two subsequent stages of the motor, in turn, tuning to disappearance with the double tube V 6, one of which is the fault in this group, and if thereupon 35 first has an anode circuit 25 LC , the relay RWS at 25 kHz picks up again, the motor is tuned, and the second anode circuit control is switched back to the switch SSA . 100 LC which is tuned to 100 kHz. Immediately before the start of a new counting period, the last-mentioned circle is the control for the tube F5, the anode chip is removed for a brief moment. The upper or lower side frequencies of the counter tubes by interruption between 40, which result from the mixture, are removed by the brushes 2 SWB1 and 2 SWB 2 a suitable filter (not shown), so that the discharges go out and the and through a low-pass filter LPF with the cut-off frequency counting tubes for the reception of the pulses of the next at 50 kHz on the lock switch with the contact period are made ready. Put in the connection ring SWC and the brushes SWB 1 and SWB 2 from the contact element Y of the switch SSC to 45. The intermittent motor control via this switch can expediently be a defeated oscillations are fed to the two decastand or another switching element switched on to the counter tubes DCH and DC5 , which in this stage reduces the speed of the first-mentioned counter tube DCH steps of the motor This causes the motor to run at half a kHz and the second counter tube DC 5 to run more slowly when the tuning counts in dependent 50 steps of 5 kHz each. The range of the low-pass filter controlled by the counting result of the units stage, in which the superposition frequencies. It goes without saying that these are fully allowed to pass, ranging from 0 to 50 kHz. constant result of this automatic tuning steps of 100 kHz are set by the circuit LC itself - for example after selecting a certain harmonic by means of the readjustment of the switches SSA, SSB and SSC ■ - 55 from the tube V 5-fed selection circuits. Each does not take place in a single count period of the counter tube is provided with a switch SSH and SSS lag occurs rather in discrete steps, as related to which each switching period of the motor in the direction of Fig. 1 fully correspond to the switches SSA, SSB and SSC and also starts up depending on the correct coordination and has three output-side contact elements during each. In order to simplify the drawing in such a way that the switching period is also stopped again, these switches are repetition, so that the correct adjustment is only partially shown in Fig. 2, in the case of the sohalation. The counter tubes can also be ters SSH through just a few contacts. The electronic meter of another type can be replaced, such as the control circuit for the motor, which as in Fig. 1 three they are known per se; other relays can also be included, is not shown in Fig. 2; the suitable embodiments of frequency dividers can only be applied by a rectangle, and if so desired, can be indicated. The control circuit can, however, also be designed in the same way as the mechanical drive of the rotating switch as in Fig. 1 and also work in the same way in the ters through the phonic wheel through others. The step-by-step coordination of synchronously switching elements replaces the capacitors C2 and C3 with the motor M. For example, purely known per se 70 is shown in Fig. 2 purely schematically by the broken line

Lines CCD indicated, which are intended to denote any mechanical drive. Ten settings are indicated in the IOP to indicate that the tuning can take place in stages by means of a suitable arrangement in which the tuning capacitor engages in ten positions. As in Fig. 1, the main oscillator is phase-controlled by a pulse generator with the tube Vi , the circuit parts required for this being indicated by a rectangle in Fig. 2. . In place of the pulse generator V 5 and the harmonic selector in Figure 2, a further controlled by the local oscillator oscillator could be provided, could have the ten crystals having mutually different by 100 kHz _frequencies: wherein these frequencies is from 1 to 2 MHz on distribute the working frequency range. These crystals could then be switched on as required by a switch moved by the motor.

The main advantages of the invention are as follows:

1. For the control of the frequency setting practically only DC-carrying circuits are needed. The motor M can be connected to the relay contacts of the relays RWR, RWS and RWF, which are used to switch it on, via lines of any length, since these only carry direct current. Therefore, there is no difficulty in performing remote control over any desired distance.

2. There is a practically continuous monitoring of the frequency in the illustrated embodiments once a second.

3. Only a single piezoelectric crystal is required, namely one in the local oscillator.

4. There is no risk of the main oscillator turning on an undesirable harmonic frequency connected.

5. There is no tendency to generate interference frequencies or mixture products.

6. The number of circles tuned is few, and these circles do not need to be of high quality just as their coordination does not have to be very precise.

7. The setup and the adjustment are easy and can be carried out in a few simple steps.

8. The power consumption is low, especially when using decadic counter tubes, which are not need heated cathodes.

Claims (13)

PATENT CLAIMS: 1.Circuit arrangement for setting the oscillation frequency of an oscillator to a desired value by means of an automatically controlled tuning device and a control device that checks the generated frequency and, if there is a deviation from the preferably selectable setpoint frequency, a control of the tuning device in a correcting sense, in which for counting a number the oscillation periods executed by the oscillator a known electronic counter, preferably in decade increments, is provided and the counter is made effective during a time interval of a predetermined duration, for example brought into connection with the oscillator, characterized in that the counter is designed in this way that the counting result is recorded as a change in the electrical state of a specific one or more specific ones from a plurality of electrical charge carriers and that an on Direction with two in the case of their excitation the tuning device in the opposite sense controlling electrical working circuits is connected in such a way that if the count result is too large the oscillator frequency lowering, if the count result is too small the oscillator frequency increasing working circuit is excited. 2. Arrangement according to claim 1, characterized in that the working circuits to the counter via a counting result that can be set to the expected frequency at the desired frequency (setpoint frequency) Switch arrangement (frequency selector) are connected. 3. Arrangement according to claims 1 and 2, characterized in that the frequency selector contains a switch (SSA) with at least two synchronously adjustable, preferably segment-shaped contact parts, one of which (X) connects that group of counter outputs with a working circuit in which a change of state occurs if the count result is too small, and the other (Z) establishes the corresponding connection between the other working group and that group of counter outputs in which a change in state occurs if the count result is too high. 4. Arrangement according to claim 3, characterized in that the switch has a third, coinciding with the first two mentioned adjustable contact part (F), over which a connection from a counter output influenced by a correct counting result to a third working group is established, which has the controlling effect of the other two working groups interrupts. 5. Arrangement according to claims 1 to 4, characterized in that the counter contains a cascade connection of decadic counter tubes (DC, DB, DA) , in which the first discharge path of a subsequent counter tube is connected to the last discharge path of a preceding one. 6. Arrangement according to claims 3 to 5, characterized in that the frequency selector contains one of the number of decadic counter tubes corresponding count of switches (SSA, SSB, SSC) , each of which has a number of corresponding to the number of discharge paths of the associated counter tube the output electrodes of the discharge paths individually connected contacts and three contact parts that can be adjusted simultaneously with respect to the individual contacts and continue to the working groups mentioned. 7. Arrangement according to claim 6, characterized in that the three working groups at the beginning of a counting or control process via the three-part selector switch with the counter tube of the highest decadic ordinal number (DA), for example the tube for the thousands group, are connected, so that if there is a detectable error in this group via one of the first two working groups, the control of the tuning device (Q comes into operation in a correcting direction until the error is less than a counting unit of this group, and the third working group when responding at the same time interrupts the active of the first two working groups and switches all three working groups to the associated three contact parts of the selector switch (SSB) or counter tube (DS) of the next lower ordinal number, for example the hundreds group, from where the working groups after the correction has been made Any errors detected when the third working group responds again to the counting level (SSC or DC) of the next lower ordinal number, etc., until the lowest order counting level is reached. 8. Arrangement according to one of claims 1 to 7, characterized in that a frequency-stabilized, preferably crystal-controlled auxiliary oscillator is provided, from the oscillation of which the control of a switching element is derived, which in a predetermined repetition period and for a predetermined, a fraction of the period amounting duration Vibration of the oscillator to be controlled (VV) or an oscillation derived therefrom from a frequency with a predetermined arithmetic ratio to the original frequency passes to the electronic counter. 9. Arrangement according to claim 8, characterized in that the vibration of the to be controlled The oscillator is brought into a fixed phase position with respect to that of the auxiliary oscillator is. 10. The arrangement according to claim 9, characterized in that one of the auxiliary oscillator (V3) synchronized harmonics - generator (V 4) is provided, which generates a spectrum of oscillation frequencies at a mutual distance from the frequency of the auxiliary oscillator and within the operating frequency range of the oscillator to be controlled from which a voltage containing these harmonics is fed to the oscillator (Vl) to be controlled in such a way that it is carried along by the harmonic closest to its own tuning. 11. The arrangement according to claim 8, characterized in that the switching element for the controlled passage of the oscillation to be controlled to the electronic counter is a synchronous with the oscillation of the auxiliary oscillator driven locking switch (SWC) , which is the current path to the counter for a small fraction makes the repetition period of the switching process permeable and which is connected to another switch (2 SWC) , which is switched on in the anode circuit of the counter tubes and interrupts the anode current for a short period of time immediately before each pass interval of the first-mentioned switch. 12. The arrangement according to claim 7, characterized in that in each of the three working groups a relay (RWR, RWF) for switching on a tuning means of the oscillator to be controlled moving electric motor (M) in one direction or the other and a relay (RWS) for Shutdown of the motor and switching of the working groups to the next counting level are switched on. 13. Arrangement according to claims 1 to 12, characterized by the application for remote voting of the controlled oscillator. Considered publications:
U.S. Patent No. 2,490,500. 1 sheet of drawings © 609767/299 1.57