DE1015497B - Ultra high frequency oscillator - Google Patents

Description

GERMAN

The invention relates to an ultra-high frequency oscillator using an ordinary one Three-electrode tube, in which between anode and grid at least one resonant circuit is located, which is essentially from the electrode leads and an external capacitor is formed, and in which between anode and cathode · an additional Capacitor is provided. In particular, the invention provides a three-electrode miniature tube for these purposes with double feeds to the grid and to the anode.

Three-electrode tubes with double grid and anode feeds and with two in between tuned oscillating circles were known per se. It was also known for an ultra-short wave transmitter with normal triode circuit a capacitive voltage division, in which between anode and cathode also has a special circle to be provided. If you use such circuits in the Decimeter and centimeter range, so forms the decoupling of the generated high-frequency energy difficult problem. An inductive coupling is not advisable because the oscillation fields are in the are essentially located inside the tube and are therefore inaccessible. Also a capacitive coupling is inexpedient because capacitances interfere with the phase and amplitude relationships of the feedback loop. The one for the decoupling provided circuit must also the output energy to a small resistor, z. B. an ohmic Resistance of 50 ohms.

The circuit designed according to the invention solves the problem of coupling out in a more satisfactory manner Way, by placing an ultra-high frequency oscillator of the type mentioned above in series with the additional Condenser on. Parallel circuit is where the generated high-frequency power is removed.

According to an advantageous embodiment, the invention provides for the use of a three-electrode tube with double leads to the grid and to the anode and with two electrodes between these lying resonant circuits, in which the supply of the bias voltages for the grid and anode via which a resonant circuit is made and the additional capacitor including the output circuit is connected to the other resonant circuit.

Further details and advantages of the invention emerge from the following description of FIG Embodiments based on the drawings. It shows

Fig. 1 shows the high-frequency scheme of an ordinary triode,

FIG. 2 shows the use of the tubes according to FIG. 1 in a series oscillator circuit,

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Applicant:

Standard Coil Products Co., Inc.,
Los Angeles, Calif. (V. St. A.)

Representative: Dipl.-Ing. C. Wallach, patent attorney,
Munich 2, Kaufingerstr. 8th

Claimed priority:
V. St. v. America June 5 and June 17, 1953

Robert James Hannon, Huntington, NY (V. St. A.),
has been named as the inventor

3 shows a triode with double leads on two of its electrodes,

FIG. 4 shows a schematic representation of the self-inductances of a tube according to FIG. 3,

5 shows a circuit diagram with a coupled output circuit for the use of a tube according to FIG 3 and 4 in an ultra-high frequency oscillator circuit according to the invention.

Fig. 1 shows a triode 10 with a cathode, grid and anode within an evacuated bulb 11. Will If a triode is used at low frequencies, it will generally suffice to only use these parts of the tube in conjunction with the concentrated reactances, to be viewed in the outer circle. Will the If the operating frequency increases, the neglected internal apparent resistances begin an important one To play a role in determining the circle parameters. After all, they're in the frequency domain slightly below the upper limit for the operation of the System almost alone.

In Fig. 1, the internal inductances of anode, grid and cathode and their leads Lp or L _g and Lj ₁ together with the internal capacitances C _n I ₁ , C ₁ Jg and Cgk in the interior of the tube bulb are given. It is clear that a theoretical treatment of the operation of a pipe, taking into account all the sizes of the complex network of FIG. 1, is a very difficult problem. For this reason, many of these variables are often completely neglected, such as B. the cathode inductance L _k , which leads to correspondingly incorrect results.

709S9B / 222

out (which further complicates things), that these radiate a considerable part of the energy, but that they are not so easily shielded can like the tube. This radiation reduces not only the efficiency but also the amplitude of the signal in the feedback circuit below the value necessary to maintain the oscillation. FIG. 5 shows an oscillator circuit with the triode shown in FIGS. 3 and 4. With the illustrated circles

A series-tuned oscillator
is shown in FIG. 2. The triode 10 in Fig. 2 is for
the purposes of this explanation are the same as that
already dealt with in connection with FIG. Of the
outer part of the resonant circuit consists of a tuning capacitor 15 between the anode and
Grid feed. A grid resistor 16 provides
the appropriate working bias. The anode voltage is fed from the positive pole B + to a voltage source via a high-frequency choke 17, the upper oscillation frequency can be increased far and the cathode is increased via a similar choke 18 beyond the limits set by the self-earth. The tube heating circuit has been omitted. resonance in parallel oscillators or

The resonant circuit for the oscillator according to FIG. 2 is given by series resonance in circuits according to FIG. The triode 30 according to FIG. 5 with inductances L _g and L ₁ , the grid and anode to double anode pins P ₁ -P ₂ and double grid guides acts. A circle of this type oscillates with pins G ₁ -G ₂ with the internal feed inductances of acceptable power slightly above the frequencies as shown in FIG. The capacitance limit of the natural oscillation, which applies to the usual external between the electrodes, which of course as in Fig. 1 parallel resonant circuits. If, however, the working 20 are also available here, the frequency has been increased for the sake of simplicity, and this is achieved in the case of the depicted drawing.

Arrangement a state in which in the feedback instead of short-circuit bars the double

circle does not have the right one to connect the oscillation upright, anode and grid leads maintaining phase and amplitude relationships between the outer one oscillating in series see the input and output of the arrangement divided between the necessary tuning capacitance see. In the circuit of Fig. 2, the practical and a tuning capacitor 31 is between the one

upper frequency limit int around 1200 MHz. Even if you try to use unusual means, e.g. B-. omitting the tube base and connecting the adjacent pair of anode and grid pins P ₁ -G ₁ and the other part 32 of the tuning capacitor between the second pair P ₂ -G ₂ . The grid

Wiring soldered directly to the pins, you can 30 resistor 33 connects the grid pin G ₂ with earth

Do not increase the frequency without the nominal loss "and provides the necessary grid bias. The

performance to exceed. The anode circuit lies above a high-frequency choke 34

A triode with the electrode arrangement to the .Spannungsquelle B. +. The outer cathode fig. 3 is available as an American tube with the pin K- is earthed and the filament at 35 via trade name 6AF 4. By using 35 the choke 36 in the usual way from a current electrode with a small distance is achieved, source fed.

that the running time for normal working frequencies is un- Although basically the circle described so far is important. In addition, the tube according to FIG. 3 has an oscillator with a series resonant circuit, with special characteristics, namely double anodes, it can be observed that through complete guides P ₁ , P ₂ and double grid feeds G ₁ , 40 removal of the outer shorting bars between G ₂ with a standard nine-pin miniature base. the base pins P ₁ -P ₂ and G ₁ -G ₂ and through in Reite This tube construction makes many of the
structural restrictions / avoided facing tubes
of the type generally shown in FIG. 1.

4 shows the electrical significance of this connection than would otherwise be possible. The upper limit of the order of electrodes and leads. Due to the frequency of this circuit itself, there is a considerable difference between the double feeds and two parallel halves of 1200 MHz, ie the value that was previously given as inductances L _n and L _P2 between the anode pin limit for ordinary circuits. , _{_:,} P ₁ and P ₂ th undparallele inductances L and _n. L _g2 . The upper frequency limit of this system is in the lines that the grid with the grid pins 50 conditioned by the cathode inductance L _k , for the connect. The internal inductance L _{k of} the cathode is the correct phase relationship between the input and the output to the cathode pin K at the tube path of the feedback. This cathode socket is shown. _r -; inductance can be compensated by adding a small

If a tube according to FIG. 4 is used for frequencies below a fixed capacitor 37 between one of the anodes half of the ultra-high frequency band, then 55 pins P ₁ and earth are connected by conducting, in the outer circle between the pins

J lih

instead of supply inductances working in parallel, tune one or both capacitors 31 and 32 and thereby achieve higher oscillation frequencies

P ₁ -P ₂ and the pins
Ik

lying short-circuit h d

Compensate cathode inductance L _k , at the same time

bügel, the internal inductances are connected in parallel and used to decouple the output energy, thereby reducing self-induction. If one tries as shown, the phase compensating Konim ultrahigh frequency band is to work, so it turns out 60 capacitor 37 from the anode pin P ₁ to earth via unfortunately that this reduction is connected to a parallel resonant circuit, which is not available from an effective inductance, because practically - variable capacitor 41 and a coil 42 between the short-circuit bar between each pair of pins. By selecting the tap 43, it can have approximately twice the value of L ₁ or L _s . With term resistance transformation for adapting the other words: a conventional miniature socket 65 of coaxial cable 44 will be chosen. By setting used to prevent the at least geometrical of the capacitor 41 one can achieve the necessary dimensions of lines and condition for parallel resonance. The condensation ironing that one sator 41 .fei the feed arrangement offers the further advantage that one achieves 3ie 3 and 4 intended advantages according to FIGS. Phase of the from the anode through the 'capacitor 37 If external short-circuit clips are used, then 70 sets the compensation current flowing can set: · ^; '·'

As a practical example, it should be mentioned that a tube 6 AF 4 in the circuit according to FIG. 5 with short, closely spaced, parallel brass plates as frequency-determining capacitors produced an oscillation in the band between 1700 and 2000 MHz. The frequency could be adjusted over the entire working range by changing the plate spacing and / or the plate length. Fixed ceramic capacitors can of course be used as long as a constant operating frequency is required. An ohmic load resistor of 50 ohms was connected to the correct tap on the coil 42. Then by tuning capacitor 41 one could simultaneously get the correct feedback phase relationships and match the resistance to the load circuit. If a very small capacitor is placed on the outside between the anode pins P ₁ -P ₂ , this increases the available output energy.

Claims (2)

20 patent claims: 1. Ultra-high frequency oscillator using a three-electrode tube in which between Anode and grid at least one resonant circuit is located, which is essentially from the electrode leads and an external capacitor is formed, and in which between the anode and Cathode an additional capacitor is provided, characterized in that in series with the additional capacitor is a parallel circuit from which the generated high-frequency power is removed will. 2. Ultra high frequency oscillator according to claim 1, using a three-electrode tube with double feeds to the grid and to the anode and two lying between these electrodes Resonant circuits, characterized in that the supply of the bias voltages for the grid and anode is made on a resonant circuit and that the additional capacitor including the Output circuit is connected to the other resonant circuit. Considered publications:
French Patent Nos. 757 758, 867 914; Journal for high frequency technology and electroacoustics, 1934, vol. 43, pp. 12 to 15. 1 sheet of drawings © 709 696/222 9.57