DE673220C - Mixed arrangement for transposition receiver - Google Patents

Description

Mixing arrangement for transposition receivers There are oscillator circuits bjekamit for transposition receivers, in which the mixing and the production the auxiliary oscillation takes place in a discharge vessel. With such combined mixing tubes, z. B. in the case of hexodes or octodes, it is not always possible for everyone to consider receiving frequencies to achieve the necessary oscillator alternating voltage. When receiving high frequencies, the oscillator circuit attenuation is usually so great that the steepness of a vibrating tube part is not sufficient to cope with the vibration conditions. in full height over the whole range variation of usual size. The steepness of the transposition falls with such frequencies as the frequency rises very strong. Since the vibrating tube part of such multi-pole tubes also comes from depends in some way on the mixing part, there is no particular leeway in the operating conditions of the vibrating tube part to. z. B. by increasing the anode voltages to improve the oscillation use and the oscillation amplitude. Some improvement - it means when, one does not get the vibrations from the Create mixing tube, lets; but from a separate tube whose oscillation amplitude by any coupling member on the grid of the mixing tube provided for the mixing is transmitted. Apart from that. of the. Difficulties that this coupling into the Circuit carries is; here, too, at higher frequencies the equality and magnitude of the Auxiliary oscillation cannot be produced with simple means across the range variation, especially since the transmission element introduces additional attenuation. Increase in the anode voltage The oscillator tube creates an undesirable increase - the harmonics. The number of turns of the feedback coil is practically limited to the point , at which the natural oscillation of the coupling coil becomes higher than the smallest wavelength, which are still to be delivered. must.

Let the difficulties of oscillator vibration generation. themselves bypassing first by using a clocked oscillating circuit, for example such, d; ate two same oscillator tubes in a known manner with one. Tuning circuit connected without using a special feedback coil and the vibration generated thereby in a suitable manner on the mixing grid is transmitted to a separate mixing tube: The control of the vibration and amplitude ratios are hereby considerably: facilitated. Against it Such a circuit still contains disadvantages resulting from the type of coupling on the mixing stage and finally to the extent that in addition to the mixing tube two Oscillating tubes are required.

According to the invention, these disadvantages can be remedied by a mixing arrangement will; in which the - oscillation generation of my push-pull circuit takes place, like this; that, the one system of the push-pull arrangement the oscillatable part of a multi-pole mixer tube represents, while the second oscillation system by an additional one, not for mixing serving tube is shown. The advantage of easy vibration amplitude control By means of push-pull arrangement is in this way with the advantage of electron coupling connected without a special coupling element in the mixing tube, while the tube expenditure is not larger than in the otherwise known mixer circuits, which each consist of one self-employed. Mixer and oscillator tubes exist. Figs. R, 2 and 3 show. analogous circuit examples.

In Fig. Z, 2 means the tuning circuit leading through the amplifying reception frequency to the mixing tube 2. The illustrated mixing tube 2 -stone octode. T he immediately following the cathode grid is therefore the control grid of the oscillator and the next: Grid the oscillator Anode: The cathode and said two grid of the tube 2 therefore constitute a according to the invention nor intended particular oscillation tube 3 similar triode: These two tube systems 2 and 3 are with the help of the tuning circle q. coupled in such a way that the oscillation conditions are met and an oscillation corresponding to the resonance frequency of the circuit q. begins. With regard to the mixing process, the octode i does not differ in any way from the usual application; only the arrangement is because of the support by even. this special triode 3 flawlessly and powerfully oscillating up to much higher frequencies than would be possible with the octode 2 alone in.: the usual circuit. Since the A.nodenspa; input supply to both oscillator anodes in the middle of the coil of the. Tuning circuit q. occurs together, the optimal prerequisite for the onset of the oscillation is not yet readily achieved; because the anode voltage at the second grid of octode 2, which is at the same time the anode voltage for: the particular triode 3, is determined by the requirements of the mixture.

The object on which the invention is based is therefore achieved in the exemplary embodiment solved even better according to fig. Here the anode voltage is separated for each vibrating tube supplied: The anode voltage can therefore be optimally adjusted in any case. The center tap of the coil: does not apply, which is the case with several switchable wave ranges is still of great advantage. The anode voltage of the octode 5 according to Ab: b. 2 -will fed through the resistor 6 and the coil to the grid forming the anode Octode connected through the capacitor 7, while the anode voltage of the triode fed through the resistor 8 and the coil through the capacitor 9 to the anode connected to the triode.

In a normal push-pull oscillation system it is important that both tubes are used equally to generate the oscillation. This is of course not the case in the two examples according to Fig. I and z, there. the oscillating part of the octode or hexode is generally never exactly the same as the separate triode. A solution has also been found for this circumstance in the present invention, for example according to Figure 3. been by the anode voltages of the two tubes. io and 2 2 and their grid biases have been made adjustable. The voltage ratios are changed until the high-frequency grid load of the two tubes is the same, -what z. B. can be controlled by measuring the grid current. In FIG. 3, the determining resonant circuit located between the mixing tube io and the separate oscillator tube ii is denoted by 12. The anode voltages are controlled by the adjustable resistors 13 and 1q. fed. The grid discharge resistors are labeled 2 5 and 1 6 ; their base points are routed to the cathode resistors 27 and 18, which are designed as potentiometers, for automatic grid bias generation. The attitude of the two. Directional direct currents to the same value tracked by means of the direct current meters rg and 20.

With the exemplary arrangement according to Figure 3, according to the invention but also exactly the opposite of the idea just described, the grid load of the tubes, if necessary, can be made different, as can the anode power dissipation. r This can be useful if the vibration amplitude required for mixing is a bigger Anode power dissipation .requires, as the. Oscillating system of the mixing tube they take over can. In such a case, the main part of the vibration power can be separated from the Oscillator tube i i in, Fig. 3. The distribution of the grid currents and the anode power dissipation in this sense can then be achieved by the device can be adjusted as required according to Fig. 3.

Claims (1)

PATENT CLAIMS: i. Mixing arrangement for transposition receivers, at which generates the oscillation in a push-pull circuit, characterized in that, that the one system of the push-pull arrangement is the oscillatable part. a multi-pole mixer tube represents, while the second oscillation system by an additional, not to the mixture serving tube is shown. a. Mixed arrangement for transposition receivers according to claim i, characterized in that the anode voltage supplied for both oscillating tubes is the same. 3. Mixing arrangement for transposition receivers according to Claim i, characterized in that for each vibrating tube the anode and Grid biases are supplied separately and can be regulated separately.