DE620922C - Circuit for modulating a carrier frequency with the alternating voltages supplied by a photo cell - Google Patents

Description

The invention relates to a device for use in particular in electrical telephoto transmission arriving modulation circuit, which makes it possible to facilitate the Reinforcement introduced carrier oscillation directly with that supplied by the photocell To modulate alternating voltages.

It has already been proposed to use a double grating tube in a modulated tube transmitter to be used in such a way that the carrier oscillation is applied to the control grid and the modulation voltage to the space charge grid will; this circuit was also expanded to a push-pull arrangement in which the Control grids of two double grid tubes connected in parallel on the anode side control the carrier oscillation is fed in push-pull while the modulation voltage is applied to the space charge grid which acts on a tube. For direct control with those supplied by a photocell This circuit comes because of the smallness of the available voltages Modulation power not taken into account. There are also mixing tube circuits in heterodyne receivers known, in which a double grid tube is operated in such a way that the received vibrations match that of the cathode first lying grid and the superposition vibrations to the second, positively biased Grid are fed.

According to the invention, for the purpose of modulating a carrier frequency with that of a photocell supplied alternating voltages two screen grid tubes connected in parallel on the anode side used whose positively biased screen grid push-pull the carrier frequency while the control grid of one tube has a constant negative bias receives and the likewise negatively biased control grid of the other tube the voltages emitted by the photocell are applied.

Fig. 1 shows a push-pull arrangement with a resistor 10, which is to be modulated electrical vibrations are fed to the carrier wave through lines 11 and 12 are, furthermore, two screen grid tubes 13 and 14, the anodes of which are connected at point 15 and the screen grids 16 and 17 of which are connected to the two ends of the resistor 10.

The anodes of i3 and 14 are with the resistor 10 connected through the resistor 18, the battery 19 and the switch 20. The Bias for the control grid 21 of the tube 14 is via the sliding contact 22 of the the battery 24 bridging resistor 23

removed. This battery also provides the bias voltage for the via resistor 26 Control grid 25 of the tube 13. The photocell 27 with the battery is connected to the resistor 26 28 connected.

Before putting the modulation device into operation, the switch 20 is set so that the Tensions on the lattices 16 and 17 at every moment by 180 ° in phase offset and the voltage amplitudes in the anode circles equal and opposite are directed.

Furthermore, the position of the contact 22 is chosen so that the biases on the grids 21 and 25 are the same when no light falls on the photocell 27; in this case lift the AC components in the resistor 18, since the AC voltages in the the anode circles then have the same amplitude with a phase shift of 180 °. at When the photocell is switched on, the voltage acting on the control grid of the tube 13 is accordingly the changes in the electrical state of the modulation device changed so that the circuit is unbalanced will.

The operating voltages are chosen so that the tubes 13 and 14 on the straight Parts of their characteristic curves (area .4 in Fig. 2) work. Resistance 18 becomes proportional Made large, about 2 megohms, with a battery 30 voltage of 6 volts, so that the screen grid voltages are very small in relation to the voltage of about 90 volts, which are supplied to the anodes by batteries 30 and 19.

The carrier wave generated by the oscillator

31 is supplied has such an amplitude that the screen grid voltages do not exceed the swing out straight parts of the characteristics.

For operation it is important that the tubes 13 and 14 are at all times unexposed photocell carry such voltages that the circle remains balanced, regardless of changes in the amplitude of the carrier wave. The control grid bias of the tube 13 is equal to the voltage supplied by the battery 34, since the voltage drop at resistor 26 is very low when the photocell is not exposed.

When light falls on the photocell, a corresponding voltage change occurs at resistor 26. This changes the potential of the control grid of the tube 13, see above that the alternating current in the anode circuit of this tube is no longer due to the alternating current is canceled in the anode circuit of the tube 14. The difference appears as an alternating voltage at resistor 18 and is through the lines

32 dem. Lattice circuit of an amplifier 33 is supplied. The modulated carrier oscillation arrives then through a filter 34 and an amplifier 35 to the transmitter 36. An oscillator 37 provides the Transmit the sync tone, around 230 Hz.

The setting just described can be described as positive modulation, since the tubes 13 and 14 work in area A (Fig. 2).

For the purpose of the reverse operation - negative modulation - a second contact 38 is provided on the resistor at a point at which the circuit is then in equilibrium when the photocell is exposed to the strongest exposure. The connection to either the contact 20 or the contact 38 can be established by means of a switch 39. In the latter case, the tubes 13 and 14 operate in area B (Fig. 2) and the degree of modulation of the carrier wave increases as the exposure falling on the photocell decreases.

In the circuit of Fig. 3, the resistor 10 of Fig. 1 is through a transformer 40 replaced; the rest of the parts are the same. With this transformer coupling remains the connection between the battery 19 and the center of the secondary winding 41 of the transformer unchanged. The adjustment takes place here by setting the resistance 23; the transition from positive to negative modulation is made by a second contact 42, which corresponds to contact 38 in FIG.

In Fig. 4 the resistor 18 is shown in Fig. 1 replaced by a choke coil 43.

The circuit according to the invention is not only suitable for image transmission, but also for sound transmissions.

Claims (5)

Patent claims: 1. Circuit for modulating a carrier frequency with the one directly from one AC voltages supplied to the photocell, in particular for the purposes of telephoto transmission, characterized by the use of two screen grid tubes connected in parallel on the anode side, their positive pretensioned screen grids the carrier frequency is pushed in push-pull, while the control grid of one tube receives a constant negative bias and the control grid of the other tube the voltages supplied by the photocell are supplied. 2. Circuit according to claim 1, characterized in that the screen grid (16, 17) the two tubes (13, 14) are connected to one another by a resistor (10), at the ends of which the carrier frequency voltage is fed. 3 · Circuit according to Claim 2, characterized in that the resistor (io) with two taps (20, 38), to which the positive pole of the screen grid voltage source can optionally be connected can be connected, is equipped and the taps are chosen such that the of the two Tubes supplied anode alternating voltages in the anode circuit either for the maximum or for the minimum exposure the photocell. 4. A circuit according to claim 1, characterized in that the screen grid (16,17) of the two tubes through the secondary winding (41) one for supplying the carrier oscillation serving transformer (40) are connected, at the center of which the screen grid bias voltage source (30) is connected is, and that the optional setting of the two states of equilibrium in which the two tubes supplied anode alternating voltages either for the maximum or for the minimum Cancel exposure of the photocell by selecting the control grid bias accordingly the tube not connected to the photocell. 5. A circuit according to claim 4, characterized in that for delivery of the Control grid voltage one for both tubes, through a voltage divider (23) bridged voltage source (24) is provided, and that the transition to the two states of equilibrium through optional connection of the control grid of the tubes not connected to the photocell takes place at one of two appropriately selected taps on the voltage divider. 1 sheet of drawings