SU27113A1 - Radio transmitter - Google Patents

Description

. The proposed radio transmitter with double or counter-modulation is applicable for broadcasting, when it is desirable to extend the range of a station by simultaneously emitting two waves, one longer and one shorter. It is possible to use counter-modulation in radio telegraphy or back-telegraphy, for example, using a long wave for communicating with near and shorter waves for communicating with long-distance correspondents.

As is known, the so-called telephone power of a radio station is several times less than the telegraph power due to the fact that during radiotelephony it is necessary to choose an operating point somewhere in the middle of the modulation characteristic of high-power cascade lamps. The telephone mode, with oscillations of the x-first kind, leads to very close efficiency factors of the generator lamps. In case of oscillations of the second kind, the power of a given type of lamp during telephony is several times less than that of telegraphy. The lamp utilization rate is low, which also reduces technical efficiency. During modulation, the power delivered to the anodes of the lamps changes dramatically, which places higher demands on the power supply.

Dual modulation eliminates the above disadvantages. Counter-modulated modulation, with oscillations of the first kind, doubles the efficiency of anode power and more than doubles the technical efficiency. With oscillations of the second kind, counter-modulation leads to a double lamp utilization rate, with a corresponding increase in technical efficiency. With double modulation, approximately half of the oscillatory power of the lamp is given at one longer wavelength, and half at the shorter wavelength. The oscillations of the total power supplied to the lamps are small, which gives a quieter mode of operation of the straightening and smoothing devices.

In the proposed radio transmitter with the use of two master oscillators of different frequencies and the subsequent amplification at the same time of currents of two wavelengths, the counter-modulation is applied, with what modulation the increase in recoil

Lamps on one of the waves are accompanied by a corresponding decrease in the recoil of the lamps on the other wave in order to double the use of the lamps and increase the efficiency.

In FIG. 1, 2 depict diagrams explaining the physical meaning of the phenomena underlying the invention; FIG. 3 is a diagram of the proposed radio transmitter.

The essence of double or counter-modulation is that two alternating high-frequency voltages are simultaneously applied to the grid of generator lamps of a powerful cascade, one with frequency Wj / corresponding to a longer wavelength Xj, and the second with a frequency w corresponding to a shorter wave A- . Two resonant (oscillatory) circuits that separate from the anode current curve a component with -frequency Wi and a component with a frequency of 2 are connected to the anode circuit of a high-power cascade. Each of the resonant circuits is associated with its own antenna (or common antenna) emitting an AI wave. , and respectively Xa During quiescence (in the absence of modulation currents), each of the amplitudes supplied to the oscillation grid "1, W.2, is, for example, half of the maximum corresponding to the saturation current (Fig. 1a), and the constant The component network voltage is zero. Accordingly, the currents in the antennas are equal to each half of their maximum value, corresponding to telegraph operation. With modulation, the amplitudes of the voltages applied to the grid vary, and the currents in the antennas change accordingly. In order for the lamps to give maximum power on each of the waves, the modulation by varying the amplitudes of the grid voltages is such that the reduction of the amplitude of one of the high-frequency voltages applied to the grid is accompanied by a corresponding increase in the amplitude of the second frequency and vice versa (Fig. 16 and. is). An increase in the current in the second antenna corresponds to a decrease in the current of the first antenna and vice versa. The modulation produces a redistribution of the power delivered by the lamp on one wave and the other.

Consider 1 in more detail the principle of counter-modulation. With simultaneous supply to the grid of lamps of two frequencies

grid potential will vary by law

V - V Sin О), g: -Ь 1 / с Sin со, t is VW where 1 / s is the constant component of the grid voltage (Fig. 1). Without

one/,

the modulation of V Vg when modulated, the amplitude of the frequencies ' i b-, varies, but so that V / + I /. Vj. If for example

when modulated, the amplitude of the first component of the Wi grid voltage varies, in general, according to the law

V

Vs

GK; Sin (a., + OD

then the amplitude of the second term wj. varies by law

-i:, K, Sin (a. +9,),

K so that 1 / s -4- us Vg. The anode current varies accordingly. FIG. 2 shows in a first approximation how the anode current of the lamp varies with modulation of a sonic sine wave and modulation depth of 100%. The modulation depth for both frequencies is the same, or different, but corresponding to the maximum amplitudes of the anode current; the characteristic is assumed to be linear.

In the case of oscillations of the first kind, the axis of the zero anode current serves as a continuous horizontal straight line, and in the oscillations of the second kind, this axis is, for example, one of the dotted horizontal straight lines. Of course, in this case, the parts of the curve entering the region of the negative anode current should be discarded.

The mathematical anadiz of the generator-lamp mode during oscillations of the first kind showed that the use of double modulation directly doubles the efficiency of the lamps in terms of anode power. With oscillations of the second kind, double modulation increases approximately twice the total oscillating power delivered by the lamps, bringing it closer to the telegraph power.

With oscillations of the second kind, the shorter wave is modulated by the frequency of the longer wavelength, which, however, does not harm the transmission. The resulting side frequencies are far from the main wave and are emitted weakly.

The implementation of the proposed modulation is very simple and can be done in many ways. It is necessary to have in the modulated cascade two modulating devices, one for long, the second for short wave. The high-frequency oscillations come from the master oscillator to the modulated cascade, where their amplitudes change (modulate), as indicated above. Modulated oscillations arrive at the grid of a powerful amplifier (terminal or intermediate). By simply switching the low-frequency conductors to the modulator, one of the frequencies can already be achieved counter-action.

A schematic diagram of the proposed radio transmitter is shown in FIG. 3. The master oscillators gi, g-2 (separate oscillators with self-excitation for each wave are taken in the diagram) are connected capacitively (GI, Cy capacitors) with a modulated cascade. The modulation is selected onto the grid, for which modulating voltages from the transformer T are fed through the reactive coils DI, D-2. The windings / Ci, KZ of the transformer are connected so that the directions of the turns coincide. This gives the counter. The modulated high-frequency oscillations through the coupling coil L for co and the capacitor C3 for oai are fed to the grid of the power amplifier y. The constant component of the grid voltage is provided by the battery B. In the anode circuit of a powerful amplifier, there are two resonant circuits PI, P-2 connected to the antennas AI, A. The diagram presented represents one of many possible variants. The number of stages before and after the modulation is unlimited and not necessarily equal for both frequencies. Connections between cascades can be taken by any capacitive, transformer, and so on. It is possible to modulate frequencies in a single cascade. The modulation method can be applied by any, for example, a lamp in a grid, on a grid, on an anode, and optionally the same for both frequencies. Schemes of generators and effort. Telemogugs can be taken any way, both serial and parallel power. Can one of the resonant circuits be connected in parallel with another — in series with the lamp.

It is advisable to apply a modulation method in which one of the lamps operating at one frequency is modulated in any way onto the grid, and at the same time serves as a modulation lamp for the modulated lamp operating at a different frequency. For this purpose, a low-frequency modulation reactive coil is connected to the anode circuit that feeds both lamps in parallel. In this case, a counter action is obtained.

Counter-modulation can be easily implemented on existing radio transmitters, adding the required short-wavelength (or vice versa) part to the long-wavelength.

In case of telegraphy, when manipulating with a key, it is possible to mark intensively.

A dual modulation transmitter can be exploited, if desired, as an ordinary oscillator on one of the waves, switching off, for example, the master oscillator and the modulator for one of the frequencies.

Subject of art.

Claims (3)

1. Radio transmitter with the use of two master oscillators of different frequencies and subsequent amplification of currents of two wavelengths at the same time, in contrast to the use of counter-modulation, with which modulation the increase in the recoil of lamps on one of the waves is accompanied by a corresponding decrease in the recoil of lamps on the other wave in order to double the use of lamps and increase efficiency. 2. The form of the radio transmitter according to claim 1, characterized in that the chains of grids of two modulator lamps are connected via reactive coils D. ,, D to the ends of the windings of the transformer T of the microphone amplifier, the midpoint of which is connected to the heating circuit of the modulator lamps. 3. The form of the radio transmitter according to claim 1 using the modulation of one of the lamps on the grid, characterized by the use of a low-frequency reactive coil included in the anode circuit of the modulators of both frequencies. fggp JiiM / ku l, iy g ML yyl RCM / I and U U iJ and  ... l-e TlACHH- .-. YsE; .i.i . .... / -) C- 2, o i NSj: 3 L3 -.Shfig. 2 , +. 4., fel / -0: 1g..1 bt, ri T; -: