HU176237B - Method and device for tuning thr resonant circuit/s/ of a r.f. apparatus - Google Patents

Description

The present invention relates to a method for tuning and performing a tuning circuit (s) of radio frequency equipment. The invention can be advantageously applied in cases where several tuned circuits need to be tuned together and form a typical application in the so-called. lane-changing equipment. The need for the new method is therefore illustrated for use in band-transmitting equipment, but the applicability of the invention is not limited to this application, but may be advantageous for any radio frequency equipment where the tuning circuit or tuning circuits of the input channel are tuned to first tuning the receiver to be serviced to the desired (desired) frequency, then continuously tuning the tuner circuit (s) and possibly other tuner circuit (s) connected to the receiver input, either directly or indirectly, until the signal level at the receiver output does not record what is typical of the tuned state,

As is known, the pre-selectors, which can only be mechanically tuned and continuously tuned, have been omitted from the input of advanced RH and UHF receivers because they have not been able to solve sufficiently fast operation of electronic tuning based only on electronic devices. The disadvantages of omitting the pre-selectors have been addressed by using high-dynamic, down-stream mixers and selection is only ensured by the fixed crystal filter (s) used in the KF channel (s). However, this did not increase the reception, it only reduced the size of the device, increased its reliability and made it possible to adjust the frequency of the oscillator signal to the first mixer only, which can be solved in a modern way with a synthesizer.

Continuous or decadently tunable pre-selectors are used to further improve reception, with a high degree of selectivity. However, the standard tuning mechanism of the pre-selectors - rotating capacitors - is time consuming, not reliable enough, and its weight and volume are also significant,

In order to extend the operating range of the equipment under more favorable conditions, it is customary to connect multiple input channels, which are sensitive to different frequency bands, to high quality reception in a limited frequency band, and therefore expensive, of course, so that the information content of the received signal does not change and there is no significant distortion during the conversion. so e.g. the reception range of a first-class receiver in the band 3-30 MHz can be extended such that

The 30-60 MHz range is subdivided into zones of 10 MHz each (30-4 (1, 40-50, 50-60), and one input channel is selected to select the incoming signals in these areas, and the incoming signals are different for each input channel. using another local frequency, it is transposed into the 15-25 MHz band, and the incoming signal thus transposed is applied to the antenna input of the receiver operating in the 15-25 MHz band with a suitable gain (e.g., about 10 dB).

Such bandwidth transducers are made with many tuning circuits and are usually tuned in tandem. If such a device is to be configured to be in a self-discovery mode, it must be provided with a tuning control current that interacts with all or a portion of the tuned circuits of the device. The structure of such a known radio frequency transmitting device is schematically illustrated (greatly simplified for ease of reference) in Figure 2.

The exemplary apparatus is for transmitting three frequency ranges into the reception band. Of course, a similar design can serve two districts or more than three districts (usually N districts). In our example, we start from N = 3 without limiting the application to this case.

The exemplary apparatus has an input A (e.g., an antenna input) having three input channels, one of which is illustrated in more detail, for different frequency ranges but otherwise identical. In the input channel 1, the first tuned-circuit stage 11 with two tuning circuits, the preamplifier 12, the second tuned-stage filter 13 which is the last tuned stage 13 of the input channel 1 and the RF interface amplifier which in this embodiment are connected in series. Last 14 amplifiers of 1 input channel. Each of the input channels 1 is connected in series by a converter channel 2. The converter channel 2 comprises a first mixing stage, a medium frequency tuning stage and a second mixing stage 23 connected in series. Each converter channel 2 can be connected via switching relays to the channel output B, which is connected, directly or indirectly, to the antenna input terminal of the receiver 4.

In fact, the receiver 4 is understood to be various devices and units necessary for the operation of the band transmitter, which are adapted according to the state of the art for the application according to the invention, therefore the whole complex is assigned to the notion 4 of the receiver. For the purpose of the present invention, only two aspects of the complex are relevant. One is that, as already mentioned, the output signal of the respective converter channel 2 must reach the antenna input of the receiver 4. On the other hand, the mode control units of the receiver 4 output two types of control signals to the self-tuning tuning control unit 5: one initiates the tuning operation and the other stops. (This is also interpreted as the input channel itself is part of a receiver complex, whereby the downstream part of the input channel is regarded as a receiver 4, since in this case, the signal is received at the input 4 of the receiver without the pre-selector. )

The two control signals are applied to the C input of the tuning control unit 5, which can of course be a selective single-channel input and a dual-channel input. Tuning the frequency-determining elements of the band-shifting equipment is a delicate operation and rotary capacitors are generally still used today. These rotary capacitors are rotated by a motor started or stopped by the actuator 51 of the tuning control unit 5, the mechanical forced connection between the motor and the rotating capacitors is symbolized by dashed lines, the system nozzle is considered as a system control output of the tuning control unit 5 the point connected to the motor connection is considered to be the control input F of the actuator. Of course, local signals must be generated for the first and second mixing stages 21 and 23, respectively, which are to be given to input D of these stages. Local signals can be produced in many ways, mostly synthesizing them, and the signal generator 3 performing the synthesis generally uses the signal of the base oscillator of the receiver 4, but this is not necessary, so the signal generator 3 providing the local signal to D inputs is included. In the known embodiment, the transmitting device also includes an auxiliary oscillator 6, in which the pitch 61 and amplifier 62 are coupled to an oscillator in a known manner, and the frequency determining element of this tuning circuit 61 is tuned from the control input F of the actuator.

With the network described, self-tuning is performed as follows. When the tuning mode is switched, the auxiliary oscillator 6 is connected to the channel output B, so that the antenna input of the receiver 4 receives the signal of the auxiliary oscillator 6. When the tuning start signal is received at the C input 5 of the tuning control unit, the actuator 51 switches power to the motor and rotates all rotating capacitors connected to the dashed lines in sync, i.e., assuming the same characteristics, tunes to a receiving frequency providing the same output frequency. When the signal frequency of the auxiliary oscillator 6 is the same as the preset - converted - frequency in the receiver 4, the reception level suddenly jumps and a signal stops tuning to the C input of unit 5 from the corresponding output of the receiver 4. The motor stops, all capacitors remain in the current position, which in principle means that at all tones it is tuned to the frequency to be converted (which of the 3 gets into the receiver, depending on the circuit switched on).

The self-tuning tuning procedure described above has several disadvantages. Of these, it is to be noted that in mechanical constraints many thirteen rotary capacitors have to be tuned in co-operation, for which full co-operation is practically unimaginable, thus occupying an individual position within the tolerance and not focusing on the 1 input channel. we want, but the decisive element of the tuning maneuver is the auxiliary oscillator 6, which has no role in the actual reception, so in fact it is not the element for which the operation serves to fine tune it. Of course, the need for the auxiliary oscillator 6 itself is one of these disadvantages, since, apart from the tuning operation, there is no need for it.

The invention is based on the discovery that the auxiliary oscillator 6 can be omitted and tuning can always be performed on the frequency determining element of the tuning circuit (s) to be tuned, if one of the input channels 1, e.g. 13 levels of the last tuned circuit and one eg. the last amplifier 14 is tuned into a loop suitable for oscillator operation during tuning, the oscillator signal thus formed is output to B and when the signal to the receiver 4 is tuned to the desired frequency and the unit 5 stops the tuning operation, the last tuned loop 13 of the input channel and returning its last 14 amplifiers to their original state, that is, to their operating state. Thus, it is certain that the frequency tuning element of the last tuned-circuit stage 13, which performs the fine tuning of the channel to be operated, is rotated to the desired position, which will certainly be tuned to the frequency sought.

Thus, the method according to the invention consists in providing one of the input channels to be tuned, e.g. operating coupling between the last tuned circuit and the preceding stage (usually the preamplifier) - e.g. by galvanic isolation or by switching the impedance modifier circuit (s) on or off, terminating the positive amplifier loop between the last amplifier and the last tuned circuit and adjusting the gain of the loop thus formed, preferably by changing the impedance of the last amplifier, and then starting the tuning control unit and when the signal level corresponding to the tuned state appears at the receiver output, stopping the tuning, disconnecting the positive feedback loop, resetting the impedance of the last amplifier and restoring the downlink operating coupling of the last tuning circuit and the preceding stage.

Of course, our method can be applied even if there is only one tone in the input channel per zone, then this single tuned circuit is switched to the oscillator mode for the duration of the tuning. However, if the radio frequency channel contains multiple tuned circuits, only one of them is switched to oscillator mode, and preferably not the first tuned circuit after the input, but the next tuned circuit in the chain, possibly the last tuned circuit. Therefore, the present case of switching the last tuned stage and the last amplifier to an oscillator will be described without limiting the invention to this embodiment.

There are many other advantages to using the process of the invention, e.g. various further simplifications may be made in the construction of a suitably designed lane transfer device which are no longer within the scope of the present invention. However, a sufficiently automated implementation of the method according to the invention alone necessitates a proper supplementation of the radio frequency equipment.

Therefore, as a further development of the present invention, the method is implemented using an automation whose actuators simultaneously perform coupling and impedance modifications in any of the designated input channels of the apparatus, and the invention also relates to a radio frequency apparatus adapted to perform the method.

FIG. 4 is a view showing a track transfer device constructed in this manner, reduced to illustrate the present invention. Thus, only one of the input channels 1 to be operated is shown.

1 and 2, it will be apparent to one skilled in the art how the measures shown in FIGS. 3 and 4 are multiplied for each of the three input channels. Figure 1 shows a general outline of a radio frequency apparatus of known design

Fig. 2 as its lane transfer device! Exports,

Figure 3 illustrates a general embodiment of the present invention, Figure 4 shows it as a track transfer device! exports.

It can be seen that the auxiliary oscillator 6 was missing, but additional organs were used in the input channels 1 and the tuning control unit 5. The last amplifier 14 of the input channel 1 is formed by an electrical signal-controlled impedance converter 142, and a positive feedback branch 141 including an electrical signal-disconnecting switch 143 is provided between the last amplifier 14 of the input channel 1 and its last tuned-circuit stage 13. For the sake of clarity, the impedance converter 142 is shown as part of the feedback branch 141, and may be so in reality, but it is not a requirement that the impedance converter 142 may be selected and installed at the discretion of one skilled in the art. the result of the electric control signal is that the resulting loop gain of the loop formed by the stage 13 and the amplifier 14 is one unit, while the other control signal causes the impedance conditions to return to the set value for the filter and amplifier mode. Finally, an additional disconnector switch 131, controlled by an electrical signal, is provided in the input channel 1, which actuates one signal to render the coupling between the preamplifier 12 and the last tuned circuit 13 ineffective, while the other signal between the last tuned circuit stage 13 and the previous stage, the operating coupling is restored.

In the tuning control unit 5, the input C is connected not only to the input of stage 51 which provides the actuator signal, but also to the actuator 52 which is supplied to three electrically controlled devices, namely the impedance converter 142 and the two disconnectors 131 and 143. - or power-on signal. Accordingly, the tuning control unit a. the output G connected to the output of a further actuator 52 is connected, directly or indirectly, to the control inputs of the impedance converter 142 and the two disconnector switches 131 and 143.

In the figure, the coupling is symbolized by the common H-point, but it may also be necessary to insert an adapter there.

From the above-described tuning method of the present invention, one skilled in the art will understand how the band transmission apparatus of the present invention operates.

When the tuning control unit 5 receives input signal from the receiver 4 to start tuning, the control signal to the output G first ensures that an input oscillator of the last tuned loop stage 13 and the last amplifier 14 is formed in the input channel 1 and has the same function as 1. and

2 with the auxiliary oscillator. After de-coupling, loop-in and impedance switching - all at the same time - the tuner system is operational. Thus, after a slight delay (e.g., 1 ms), the control signal is output to the G output, and the tuning instruction is sent to the E output, and the actuator performs the tuning in cooperation. When the stop command is received, the signal to output E immediately stops tuning, and the signal to output G repeats the coupling, uncoupling, and impedance reversal operations in the opposite sense before starting tuning, so that the input frequency tuned to the desired frequency is ready. the two tuned circuits of the first tuned circuit 11 are tuned to the desired frequency within the co-tolerance, and the last tuned circuit 13 performing further filtering is tuned directly to the desired channel.

For ease of traceability, as mentioned above, the use of a track transfer device is described in greater detail, whereby the known and the inventive designs are compared with reference to Figures 2 and 4, respectively. If now the 1st and the

Comparison of the embodiment of FIG. 3 (the same reference numerals and essentially the same mechanism do not require detailed explanation), it can be seen that in the end, the converter according to the invention is equally applicable to the inlet channels 1 without the 2 channels. , if tuning is performed on radio equipment having only one input channel 1 and one tuned circuit therein. Basically, for devices with a simpler design, the tuning process preparation and reset do not need to be automated; after all, a self-tuning tuning mechanism is required, and the linking can be changed manually. Ultimately, the method of the present invention is accomplished by manually switching these two stages to oscillator operation for a single tuning circuit and amplifier input channel, and then restoring the state required for reception. Even then, we save the auxiliary oscillator that is needed for tuning, and it is true that not the auxiliary oscillator but the filter circuit to be operated is tuned to the desired frequency, so both quality improvement and cost reduction, lower number of elements for greater reliability, and volume reduction already occurs with this basic solution. However, in the case described in the introduction, when used with the apparatus of Fig. 4, all the additional benefits are obtained by co-tuning the input channels and the converter channels in such an advantageous manner.

Claims (6)

Patent claims: 1. A method for tuning a tuning circuit (s) of a radio frequency equipment configured with a tuning control unit to tuned to a desired frequency, the receiver to be directly or indirectly connected to an input channel, and to the input channel directly to a desired frequency. or indirectly, by switching to the antenna input of the receiver and then starting the tuning control unit to tune the tuner loop (s) until the signal level corresponding to the tuned state appears on the output of the tuner, which is tuned to the desired frequency, one) between the tuned circuit and the stage prior to the tuned circuit - e.g. by galvanic isolation or by turning the impedance modifier circuit (s) on or off, disconnecting the positive feedback circuit between the amplifier and the tuner circuit and adjusting the amplification of the loop thus formed, preferably by varying the impedance of the amplifier, and then starting the unit. the tuning control unit and when the signal level corresponding to the tuned state appears at the receiver output, the tuning is stopped, the positive feedback branch is disconnected, the amplifier impedance is reset to operating value, and the operating coupling between the tuned circuit and the prior stage is restored. The method of claim 1 for use in a band-transmitting device adapted to convert the frequency domain of one of the input channels at any one time, characterized in that it is implemented by means of an automation whose actuator controls the respective selected input channel and input channel. and tuning all the tuner circuits of the converter channel inserted between the receiver and switching (one) the tuner circuit and (one) amplifier of the input channel to be tuned into the oscillator mode, as described above, and then tuning the tuner to the desired channel. back. 3. Radio frequency equipment with at least one input channel formed by a tuning circuit and an amplifier and a receiver directly or indirectly connected to the input channel, and a so-called "radio receiver". a self-tuning tuning control circuit, the control input of which is connected to an output of the receiver, and one of its outputs - or an actuator connected to the output - is connected to the control input of the frequency determining element of the tuning circuit (s); 14) - electrically controlled - provided with an impedance transducer (142) between the (one) input channel amplifier (14) and (one) tuned-circuit stage (13) - comprising a positive electrical feedback-disconnecting switch (143) 141), an additional disconnect switch (131), which is electrically controlled, is provided between the (one) tuned-circuit stage (13) and the preceding preamplifier (12) and the other output (G) of the tuning control unit (5) or directly - the impedance converter (142) and the two isolators connected switches (131, 143) vezérlőbemeneteire. An embodiment of a radio frequency device according to claim 3, characterized in that: a 5 additional isolation switches (131) for galvanic isolation. An embodiment of a radio frequency device according to claim 3, characterized in that the further disconnecting switch (131) is a de-coupling switch by impedance modification. 6. In steps 3-5. The radio frequency device according to any one of claims 1 to 6, adapted for frequency conversion (band-transmitting device), with N input channels (N, eg 3) for different frequency ranges, otherwise uniformly connected, and one or more channels connected between the input channels and the antenna input of the receiver. characterized in that the tuning control unit (5) is one The 0 output is also connected to the frequency determining element of the tuner circuit (s) of the converter channel (s) (2).