DE732458C - Arrangement for the transmission of television programs - Google Patents

Description

Arrangement for the transmission of television broadcasts The invention relates to a method for the electrical transmission of television images and relates in particular on transmission systems with an electrical image splitting device on the transmitter side work.

In such methods, the image is broken down line by line electric or magnetic fields are used. To influence the electron beam, To scan the image area one after the other, it has proven to be useful instead of a sinusoidal deflection voltage, as has been suggested on various occasions to .use a stress curve that is composed of straight sections is to ensure linear scanning. One calls one such Curve course also briefly as a tilting oscillation. Contains a complete transmission facility Accordingly, a device that such a high frequency deflection voltage and a Deflection voltage supplies lower frequency, so that the interaction of the two deflection fields results in a line-by-line scan of the image.

To reassemble the image at the receiving end, it is necessary to transmit both the image signals and the deflection signals to the receiver. It transmission methods are already known in which the deflection of the electron beam used sinusoidal oscillations either by means of a separate carrier wave or on a carrier wave with the image signals modulated onto a subcarrier wave be transmitted. Such processes, however, all have the major disadvantage that either the sinusoidal oscillations directly to deflect the electron beam of the picture display tube are used and thus do not allow linear scanning or only in tilting oscillations being transformed. must, so that an additional tilt generator is necessary.

The invention now overcomes these disadvantages and provides an arrangement for the transmission of television programs with the help of image splitting tubes, in which the tilting vibrations, which are composed of two essentially rectilinear sections Voltages are formed, along with one modulated by the image signals Subcarrier wave are transmitted by means of a carrier wave.

This arrangement has the great advantage that the tilting vibrations are direct so that they can be transmitted immediately, without prior conversion, for distraction of the electron beam can be used.

A schematic exemplary embodiment of the subject matter of the invention is shown in the drawings. I # ig. 1 shows a schematic circuit example of a complete television transmitter, and Figs. Z, 3 and 4 each show a representation of the current and voltage curve in different circuits of the transmitter.

In the present case, the light-sensitive organ is a large-area one Photocathode 6 used on which an optical image is cast. The one at the photocathode released electrons «- ground with the help of the deflection plate 13, 14 and 15, 16 their way to the anode to and back via a hlenden orifice 12 of the diaphragm i i moved so that the electrons emitted from each part of the photocathode tapped one after the other behind the opening 12 from the anode to as image signals can be.

To generate the deflection voltages on the plates 13, 14 and 15, 16 two assemblies 17 are used, which produce a tension which composed of substantially rectilinear sections. Hereinafter the arrangement for generating the deflection saving of low frequency is described first, which is shown on the left side of FIG. The arrangement for generation the high-frequency deflection voltage is entirely analogous, and that of the first Arrangement of the corresponding switching elements are given the same reference numerals and the index a. Mistake. The arrangement 17 contains a three-pole tube 2o, which has an oscillation generated by for example to Hertz. In the present case, a circuit has been chosen in which a grid resistor 21 is connected to the grid 22 of the tube 2o i, * t and on the other hand via a battery 23 which supplies a negative bias voltage, with the cathode 2d. connected is. The cathode 24 is heated by a battery 25, 25. The anode 26 of the tube is connected to the via a battery 2E3 and a choke coil 25 ' Cathode 2d. connected and also has an inductance; and a; capacity 28 'in connection with your grid. The inductance 2; is shunted to one fixed capacitance 28 and a variable capacitance 29, one end of the Capacitor 28 with inductance 2; is connected and the insulation capacitor 29 with a tap of the inductance in connection. Between the hapazitäteii 28 and 29, a line 31 is all-closed, which leads to the cathode 2.-l of the tube 20 and the cathode 39 of the tube 32 is filled. The oscillating circuit can be set to any Frequency, e.g. B. to Hertz, vote and forms the voltage source for a second Resonant circuit of a similar type, but the one with a higher frequency, for example 500 oooHertz, works. The second resonant circuit contains one. PÖhre 32, the anode of which 33 is connected to your first Sch - \ - ingl; i-cis via a secondary coil 31 ', where an inductance; -! is switched on in the connection line. The inductance 34 is a high frequency throttle that prevents the high frequencies of the second Your first protective circle is pressed onto the oscillation circle. The anode 33 is via the primary coil q #> of a high-frequency transformer and via a capacitance .I1 connected to the grid. 42. Capacities .I3 and .LI are in relation to the primary development .I0 or a part of it 3111 as well. `` 'o11 your common point of the two Capacitance leads a line to the cathode of the tube 32. The grid .I2 is over a resistor 4S and a battery 46 are connected to the cathode 39. The second The oscillating circuit, which consists of the elements q (-), 43 and .1q, is finite in resonance the frequency to be generated by the tube 32.

The voltage of the first low-frequency circuit is chosen much higher than it corresponds to the highest anode current of the -r7-wide circle. Because the second circuit only generates vibrations when the anode voltage is positive is, then the electricity generated in it runs roughly to Big. 3. The harmoniously vibrating one Stream of! created circle is shown in FIG. This stream becomes the second If an erroneous trip is pressed, a current as shown in Fig. 3 is generated every positive period of the The created current causes a series of harmonic oscillations in the second circle of substantially constant intensity while in the negative period of the first current no oscillations are generated in the second circuit.

The voltage of the second circuit is impressed on an audio circuit with a tube 48, the grid .I9 of which is connected to an inductance 51 via a grid resistor 5o and a capacitor and is thereby coupled to the inductance 4.o. - The coil 51 is connected to the cathode 52 of the Audion .I8. Shunted to the coil 51 is a capacitor 53 of such a capacity that resonance with the oscillations of the second circuit can be produced. The anode 54 of the Audion 18 is connected by a line 55 to the plate 15 of the cutting roller , while the opposite plate 16 is connected via a line 56 and a battery 5; is connected to the cathode 52. The anode resistor 58 is located in the '\ -ebenschluß to the lines 55 and 5 - so that the voltage drop occurring at this determines the voltage applied between the plates 15 and 1. 6 In the audio circuit an alternating current of the frequency generated in the first circuit is produced, but the current consists of essentially straight sections according to FIG. composed. The audio tube d.8 stores a charge as a result of the resistor 50 and the capacitor when each wave train passes through according to FIG. 3; and this charge flows off in the pause between successive wave trains, so that the output voltage of the audio terminal 48, which is applied to the plates 15 and 16, has the course of FIG. 4.

A second audio circuit provides a voltage of a similar shape for the Plates 13 and 1I of the decomposition tube, but with a high frequency, for example 50000 Hertz. The tube 2oa generates a harmoniously oscillating current of 5o00 Hertz, which is pressed onto the circle with the tube 32a. In this circle becomes a frequency of 500,000 Hertz, so that the processes proceed analogously to those just described. The output circuit of the contains the cathode 52a, a resistor 5811, a battery 57a and a modulation tube 59, which is connected with its anode 6o to the battery 57a is. A connection leads from the cathode 61 to the anode 5.4.a of the tube, I8a. Of the Voltage drop across resistor 58a is used to set the deflection voltage for the plates 13 and 14. to be delivered via lines 55a and 56a. The modulation tube 59 is with its grid 62 to a line 56 via a negative bias battery 63 while the cathode 61 is connected to line 55 via line 65. The tube 59 modulates the high frequency with the low frequency in this way of the first oscillation circuit.

The voltage for the image decomposing tube is taken from a battery 67 supplied, the negative pole of which by a line 7o. with the photocathode 6 of the Zerlegerrölire is connected, while the positive pole via a resistor 69 and a lead 68 with the anode io. the tube are in communication. The battery 67 is preferably a high voltage, about 100 volts, and resistor 69 is large sized; it is about one megohm. The diaphragm i 1 of the decomposition tube is connected by a line 71 to the positive pole of the battery 67, so that it has the same potential as the anode io, only that its current does not flow through the Resistor 69 flows.

The electrons emanating from the photocathode.6 are released by the voltage applied to plates 15 and 16 at a frequency of about 10 Hertz steered back and forth. You are also by the lying on the plates 13 and 14 Voltage moved back and forth perpendicular to it with a frequency of about 5,000 Hertz. The result is the same as if the opening of the diaphragm i i mechanically in a Zigzag line would be moved across the photocathode so that the image is on the plate 6 is passed over once every twentieth of a second. The plates 13, 14 and 15, 16 frequencies can be increased up to i o ooo ooo Hertz, see above that you have any desired number of image changes and any desired fineness of the dismantling can achieve.

The arrangement for amplifying the image current and transmitting the signals contains a tube 72 that functions as both an image current amplifier and a modulator for a further tube 73 is used. The tube 73 generates a first carrier wave of for example about 500,000 Hertz. To this end, the anode 74 of the tube is through a line 75 connected to an inductance 76, the other end of which has a Capacitor 77 is connected to the grid 78 of the tube. The inductance is tapped in the middle at 79 and via a variable capacitor 8o, one Line 81 connected to cathode 82. The capacitor 8o and the coil 76 are matched to the carrier wave to be generated. The line 81 is also via a Capacitor 8aa connected to line 77. The grid 78 is attached to the cathode 82 connected across a grid resistor 84 and a negative bias battery. The voltage for the tube 73 is supplied by a battery 9i through a resistor or a throttle 9o. The tube 72 acts as a variable resistor in parallel with 9o and 9i and increases or decreases the voltage drop, modulates .. a @ o the voltage at the anode 7q. of tubes 73. That, grid-86 beer tube 72 is about a negative Bias 1 voltage battery 87 connected to the resistor 69, which the signals are pressed will. The anode 88 of the tube 72 is through. A line 89 to the choke or the resistor 9o and the battery 9i connected, the negative pole with the Cathode 92 of the tube 72 and with the cathode 82 of the tube 73 is in communication. .

The choke or the resistor 9o changes the voltage at the anode of the tube 7 3 in accordance with the increased image current. In the line between 90 and anode 7: 1 there is a further choke 9211, which prevents the carrier wave generated in the tube 73 from influencing the tube 72. The carrier wave generated in the tube 73 and modulated by the amplified image current is impressed on a double modulation tube 94, which modulates a further tube 95 in order to generate a second carrier wave of a higher frequency, for example 1,500,000 Hertz, ie of the wavelength to be transmitted. The tube 94 modulates the second carrier wave not only with the modulated first carrier wave of the tube 73, but also with the deflection voltages originating from the modulation tube 59. The grid 96 of the tube is connected to a coil 98 by a line 97, and the coil 98 is connected to the cathode 99 of the tube 94. The voltage coming from the tube 73 is impressed on the grid of this tube. The deflection voltages are fed to the grid 96 via a line ioo, which leads via the resistor 58d and from here via a line ioi to the cathode 99. The tube 94 belongs to a Heising modulator, the anode ioz of which is connected by a line 103 via a high-frequency choke or a resistor 104 to the positive pole of a battery io5. The negative side is at the cathode 99. The line io3 via a high frequency choke IO6 to the anode IO7 of the tube 95. The throttle IO6 prevents the second carrier wave is transmitted to the tube 94, while the throttle 104, the voltage at the anode 107 of the tube 95 in accordance with the energy output by the modulation tube 94. The anode 107 of the tube 95, which generates the carrier wave for the wireless transmission of the entire modulation, is connected to an inductance iog via a line io8. The inductance is connected to the grid i 12 of the tube 95 via a line iio and a capacitor iii. The cathode 113 of the tube is connected by line 114 and variable capacitor 115 to inductor iog. A capacitor 116 is located between the line i i4 and the line ii o. The inductance is connected to an antenna 117.

Claims (1)

PATENT CLAIMS: i. Arrangement for the transmission of television broadcasts with the aid of image splitting tubes in which tilting vibrations. which are formed from two substantially rectilinear sections are used for deflection, characterized in that a carrier wave is modulated with these tilting vibrations and at the same time with an auxiliary carrier wave modulated by the image signals. Arrangement according to claim i, characterized in that to generate these tilting vibrations an oscillation of higher friency is controlled by an oscillation of lower frequency in such a way that short wave trains of high frequency arise which charge a capacitor essentially linearly, which then discharges essentially linearly.