DE3420915A1 - FREQUENCY CHANGING DEVICE - Google Patents

Description

description

The invention relates to a frequency changing device, in particular for use in a high frequency oscillator, capable of generating two or more frequencies, the frequency changing device increasing the inductance of the tuning circuit changes from one value to another using an electronic switch.

An already designed circuit arrangement with an electronic switch for switching the oscillation frequency of a high-frequency oscillator from one to one another value is shown in FIG. This circuit comprises a power supply terminal 1, which is an electrical Energy for changing the frequency is supplied to a diode 2, by means of which the passage of an electric current in the reverse direction is prevented, a resistor 3 for bias adjustment, a terminal 4, which is a fixed electrical energy for switching a diode 6 between two states is supplied to a choke coil 5, by means of which the passage of high frequency signals is prevented, the one already mentioned, as electronic Switch-acting semiconductor switching element 6, such as a diode, a bypass capacitor 7, capacitors 8 and 9, by means of which the passage of direct current is prevented, a vibrator 10 such as a Transistor, a tuning capacitor 11, a main tuning coil 12, and a tuning coil 13.

When a voltage for changing the oscillation frequency is not applied to the terminal 1, a fixed voltage E _n applied to the terminal 4 biases the diode 6 serving as an electronic switch in the forward direction so that the diode conducts. Thus, high-frequency signals can pass through the diode 6 and are therefore

the tuning coils 12 and 13 connected in parallel. The combination of the two inductors represents the inductance the tuning circuit and determines the oscillation frequency.

If the voltage applied to the terminal 1 for frequency change is higher than the voltage E _ß applied to the terminal 4, the diode 6 is reverse-biased and this electronic switch is consequently in the off state. The tuning coil 13 is therefore separated from the tuning circuit, and thus the inductance of the tuning circuit, which determines the oscillation frequency, consists only of the inductance of the main tuning coil 12.

In Fig. 2, another already designed circuit is shown, which is similar to the circuit of Fig. 1, with with the exception that a mechanical switch is added to the number of vibrational frequencies that can be generated to increase one, and that a further tuning coil 14 is inserted.

The circuit of Fig. 2 functions in exactly the same way as the circuit of Fig. 1. When the as Electronic switch acting diode 6 conducts and the added switch 15 with one end of the coil 14 is connected, the main tuning coil 12 is connected in parallel with the coil 14, so that the oscillation frequency another value is changed.

When the voltage applied to terminal 1 is higher than the fixed voltage applied to terminal 4 E_, the diode 6 is turned off as it is related

has been described with FIG. Therefore, the coils 13 and 14 are disconnected from the tuning circuit, namely regardless of whether the contact of the switch 15 with

the coil 13 or the coil 14 is connected. As a result, the frequency of oscillation is independent of position of the contact of the switch 15 made. This relationship applies when the oscillation frequency is sufficiently low. But if it is high, this relationship does not apply and the oscillation frequency varies depending on the position of the contact of the switch 15.

The circuit according to FIG. 2 was tested on the sound carrier oscillator a high frequency modulator for use in a video recorder suitable for various types of Television broadcasting standards can be used. Measurements on this circuit were made in the following manner carried out.

The diode 6 serving as an electronic switch was initially biased into the off state and the mechanical one Switch 15 was connected to tuning coil 13. Under Under these conditions, the main tuning coil 12 was set to the oscillation frequency of the sound carrier in accordance with the NTSC standard matched, d. H. to 4500.0 KHz. Then the diode was biased into the on-state and the coil 13 was on the vibration frequency of the sound carrier according to the German PAL system matched, d. H. to 5500.0 KHz. Thereafter, the contact of the mechanical switch 15 with the tuning coil 14 which was then tuned to the frequency of the sound carrier according to the British PAL system, i.e. H. to 6000.0 KHz. Thereafter, the diode 6 was turned off. A measurement showed that the oscillation frequency assumed undesirable values in the range from 4497 to 4498 KHz for the sound carrier according to the NTSC standard. When the contact of the mechanical switch 15 was connected to the coil 13, the oscillation frequency for the sound carrier was according to NTSC standard 4500.0 KHz. That is, although the diode 6 was biased off in order to activate the tuning pulse

separating len 13 and 14 became one of the position of the contact of the switch 15 depending difference of 2 to 3 KHz introduced, so that a problem for the practical application.

One of the main causes of the difference in the frequency of vibration between the positions of contact of the mechanical switch 15 occurred, is that there is a capacitance of a few pF between the electrodes, even if the electronic switch 6 does not conduct. Another reason is that the inductances of the Tuning coils 13 and 14 are not identical. Another reason can be seen in the fact that stray capacitance different values between the coil 13 and a shield case on the one hand and between the coil and the shield case on the other hand.

A more detailed examination is carried out with reference to FIG. 2. The cathode of diode 6 is across the bypass capacitor 7 is grounded and is therefore at zero potential for high frequencies. The one on one The higher potential anode of the diode 6 is connected to the switch 15 and the tuning coils 13, 14. As a result, there are stray capacitances between earth or ground and each switch 15 and coils 13, 14 are present, as well as the stray capacitance in the diode 6 parallel to that of the tuning capacitor 11 and the Main tuning coil 12 existing tuning circuit. For high frequencies, capacitors 8 and 9 are by means of which a passage of direct current is prevented is negligible, and thus the circuit of Fig. 2 when the electronic switch 6 is biased into the off state, by an equivalent circuit diagram shown in FIG as long as high frequencies are considered.

-7 - 3420D J5

In FIG. 3, considered next, the circuit components denoted by reference numerals 10 to 15 correspond the components denoted by the same reference numerals in FIG. 2. If the diode 6 does not conduct, there is a stray capacitance between anode and cathode

16. A stray capacitance 17 is present between the tuning coil 13 and ground. Another stray capacitance 18 exists between tuning coil 14 and ground. A stray capacitance 19 is present between switch 15 and ground.

The same measurements as those explained above were carried out on the circuit shown in FIG. 3. The diode 6 was connected in parallel to the main tuning capacitor 11 and this was tuned to the frequency of the sound carrier, d. H. to 4500.0 KHz. The combination of the stray capacitances 17, 18, 19 and the stray capacitance 16 in the Diode 6 was labeled Cx. Then the electronic switch 6 was biased to the on-state and the Tuning coils 13 and 14 were tuned to 5500.0 KHz and 6000.0 KHz, respectively. Subsequently, the contact of the switch 15 connected to the coil 13. Under these conditions there was a combination of the stray capacitances

17, 18, 19 and 16 of Cx + Acx. ACx was the sum of the changes in the stray capacitances 17 and 18 when the coils 13 and 14 connected in parallel were adjusted. As already mentioned, when the contact of the switch 15 was switched from the coil 14 to the coil 13, there was a change in the oscillation frequency of 2 to 3 KHz. This phenomenon can be attributed to Δΰχ, the sum of the changes in stray capacitances 17 and 18. This combined capacitance is usually on the order of a few pF and the changes in stray capacitances produced when coils 13 and 14 are adjusted are combined . The-

This combined capacity affects the vibrational capacity. Hence, Acx cannot be neglected.

The object of the present invention is in particular to make a frequency changing device available, at which · the difficulties described do not occur.

The solution to this problem is specified in claim 1 and can advantageously be further developed in accordance with the subclaims will.

With the invention, a frequency changing device has been made available, one being an electronic one Has switch serving diode, which is arranged in the circuit at a point from that point is different, at which it is located in the solutions that have already been designed, so that they are less affected by changes the stray capacitances, which are caused by adjusting the parallel to the Main tuning coil inserted tuning coils during a change in frequency.

The invention creates one for a high-frequency oscillator with a tuning circuit and at least one auxiliary coil Usable frequency changing device with a semiconductor switching element serving as an electronic switch, the high potential side between the high potential side of that contained in the tuning circuit Main tuning coil and one end of the auxiliary coil is connected, the other end of which with the lower potential having the low potential side of the main tuning coil is connected.

The invention, developments and advantages of the invention

and further aspects of the object on which it is based will now be explained in more detail with the aid of embodiments. In the drawing show:

Fig. 1 is a circuit diagram of an already designed circuit arrangement, in which an electronic switch for changing the oscillation frequency of one is used to another value;

Fig. 2 is a circuit diagram of another already conceived

Circuit arrangement which, in addition to the components of FIG. 1, includes a mechanical switch to increase the number of possible oscillation frequencies by one?

3 shows an equivalent circuit diagram of the circuit according to FIG. 2 for high frequencies;

Fig. 4 is a circuit diagram of an embodiment of an inventive Frequency changing device, which corresponds to the circuit of Fig.l;

FIG. 5 is a circuit diagram of a further embodiment of FIG frequency changing device according to the invention, which corresponds to the circuit of FIG. 2; and

Fig. 6 is an equivalent circuit diagram of the circuit of FIG. 5 for high frequencies for the case that the as electronic switch serving diode is biased in the off state.

Frequency changing devices according to the invention are shown in 4 and 5 and correspond to the circuit arrangements according to FIGS. 1 and 2. An equivalent circuit the arrangement according to Fig. 5 for high frequencies in the supply

stand, in which the diode serving as an electronic switch is biased off, is shown in FIG. 6. The arrangements according to FIGS. 4 and 5 have the same structure as the arrangements according to FIGS. 1 and 2, respectively Except that the diode 6 is inserted in different places. The former circuit arrangements differ however, differ greatly from the latter circuit arrangements. That is, the equivalent circuits of the the former circuit arrangements differ from the latter circuit arrangements for high frequencies.

This will now be elaborated on. With each of these new V ¹ . Frequency changing device * the diode 6 is connected to the high potential side. Therefore, when the electronic switch 6 is biased in the off state, the equivalent circuit shown in FIG. 6 can be used

obtain. The bypass capacitor 7 allows high frequencies to pass through. This leads to, that the stray capacitance 16 in the diode 6 is connected in series to form a parallel circuit, which is through the stray capacitances 17, 18 and 19 is formed. This series connection formed from the capacitance 16 and the parallel connection is connected in parallel to the main tuning capacitor 11.

Let C "be the capacity of the series circuit or the combined capacitance of the stray capacitance in the diode 6 and the parallel connection formed by the stray capacitances 17, 18, 19 when the oscillation frequency falls to the previously mentioned 4500.0 KHz of the sound carrier is tuned. The diode 6 is biased in the on-state, and then the tuning coils 13 and 14 are tuned to 5500.0 KHz and 6000.0 KHz, respectively, according to the procedure described above. The contact of the switch 15 is then connected again to the tuning coil 13, as shown in FIG.

shows is. Under these conditions, the series combination of the stray capacitance 16 in the diode 6 and the parallel connection of the stray capacitances 17, 18, 19 is equal to C "+ Ac", where Ac _{y represents} the sum of the changes in the stray capacitances that are caused when the coils 13 and 14 can be adjusted.

The stray capacitance 16 in the diode 6 is in the size range of 1 pF, while the combined capacitance of the Stray capacitances 17, 18 and 19 is a few pF. Consequently, the capacity of the series circuit, which is determined by the Stray capacitance 16 in the diode 6 and the parallel connection of the capacitances 17 to 19 is always smaller than the capacitance of the diode 6 of about 1 pF. Therefore the low capacitance 16 dominates in the capacitance of the series circuit, through the stray capacitance 16 in the diode and the parallel connection of the stray capacitances 17 to is formed. Thus, even if the stray capacitances in the tuning coils 13 and 14 change, the Change in capacitance of the series circuit is much smaller. Therefore, the capacity of the series circuit has that in parallel to the tuning circuit from the capacitor 11 and the coil 12 is inserted, inherently quite a small value less than 1 pF. In addition, the effect of the sum Ac of the changes in the stray capacitances in the Coils 13 and 14 caused by the tuning process is minimal.

The change in the frequency of oscillation caused by the pre-tensioning the diode 6 was brought into the on or the off state in the circuit arrangement according to FIG. 5, was actually measured in the same manner as the aforementioned measurements. The values obtained were in Range from 0.15 to 0.2 KHz. These values are a factor of 10 to 20 below those of the circuit arrangement

Fig. 2. One thus has the fact that the diode 6, which is used as an electronic switch, is at the higher voltage having side, a quite considerable frequency changing device achieved.

Although a high-frequency modulator in the previous description has been considered as an example, the invention is not limited to frequency conversion in such a Modulator, but rather it can be used with all high-frequency oscillators that have both a electronic switch as well as a mechanical switch for changing the frequency of oscillation from one to use a different value.

As described, the invention makes one in a high frequency oscillator usable frequency changing device is available in which the semiconductor switching element connected to the high potential side of the main tuning coil and causes the auxiliary tuning coils to be parallel to the Main tuning coil can be inserted to change the inductance value. As a result, the circuit arrangement becomes less by the stray capacitances in the auxiliary tuning coils influenced than in the circuit arrangement already designed, and consequently it can its frequency conversion or perform frequency change in a stable manner.

Claims (4)

IiALKM KLUNKER SCHMnT-NILSON KIRSCH -J'- "" ^ BREEDING OFFICERS EUROPEAN ALPS ELECTRIC CO., LTD. 1-7 Yukigaya Otsuka-cho _{K 2} i 252S / 6s Ota-ku, Tokyo Japan Priority: July 21, 1983, Japan, No. 113447/83 Frequency changing device Claims Frequency changing device that can be used in a high frequency oscillator,
marked by a tuning circuit (11 to 14) with a main tuning coil (12) and at least one auxiliary coil (13, 14), the can be connected in parallel to the main tuning coil (12) or can be separated from it, such that the oscillator can generate two or more frequencies
- a device (8) for connecting one end of the auxiliary coil (13, 14) to the lower potential having the low potential side of the main tuning coil (12), - A semiconductor switching element serving as an electronic switch (6), via which the auxiliary coil (13, 14) can be connected in parallel to or from the main tuning coil (12) this is separable and one end with the other Ren end of the auxiliary coil (13, 14) is connected, and - A device (9) for connecting the other end of the semiconductor switching element (6) to the higher potential having high potential side of the main tuning coil (12), - The semiconductor switching element (6) being controllable in such a way that it has the auxiliary coil (13, 14) parallel to the main tuning coil (12) switches or disconnects from this, whereby the inductance of the tuning circuit (11 to 14) and thus the oscillation frequency of the oscillator is changed from one value to another. 2. Frequency changing device according to claim 1, characterized in that between the high potential side of the main tuning coil (12) and a power source terminal (1), which is an electrical Energy for changing the frequency can be supplied, a diode (2) is arranged. 3. Frequency changing device according to claim 1 or 2, characterized in that - That several auxiliary coils (13, 14) in parallel are provided to each other, - That this parallel connection between the low potential side of the main tuning coil (12) and the semiconductor switching element (6) is switched, - and that between the low potential side of the main tuning coil (12) and the semiconductor switching element (6) a switch (15) is arranged. 4. frequency changing device according to claim 3, characterized in that between A capacitor (7) is arranged on the ground and the connection point of the auxiliary coils (13, 14) connected in parallel is.