DE719010C - Television broadcasting facility - Google Patents

Description

GERMAN EMPIRE

ISSUED ON
MARCH 26, 1942

• GERMAN PATENT OFFICE

PATENT LETTERING

JVs 719010 CLASS 21a ¹ GROUP 3520

R 9345Ϊ VIII aj21a ¹

Radio Corporation of America of New York, V. St. A. Television broadcast facility

Patented in the German Reich on May 28, 1935 Patent granted March 5, 1942

is used.

In order to take a close-up, close-up or long-range view of a To get a view, one must either change the lenses or two different ones Use arrangements, d. H. a device for the close-up and a device for the long-range. This disadvantage is intended to be eliminated by the transmitter according to the present invention will.

The invention makes use of the means known in cathode ray tubes for television reception purposes for adjusting the Image format, the size of the spot and the position of the image on the luminescent screen through

ig development of the steel deflection angle and the blasting agent position. The invention consists in the use of these electrical control devices known for image reception for image adjustment for the. Transfer of individual cutouts, also eccentrically to the screen center one on the screen of a cathode ray scanner image thrown at the transmitter by influencing the size of the deflection angle, 'the spot size and the setting of the central position of the' scanning beam Transition from long-distance to close-ups (large-scale images) at the receiving point.

The invention is' on the basis of an exemplary embodiment Illustrative figure is explained in more detail. The schematic in Fig. 1 The transmitter shown contains a cathode ray tube 10 with the Moeaikschirm 12 on an image of the view 14 is thrown using the lens system 16. the end the beam generating device 18 occurs Beam 20, which in the horizontal direction through the coils 22 and in the vertical direction is deflected by the coils 24. Circles 26 and 28 provide the necessary 4 « borrowed sawtooth-shaped current waves.

The network 28 includes a vibrator 30 with the tube 32 and the transformer 34 which couples the anode circuit to the grid circuit of the tube. A blocking capacitor 36 is located between the +5 grid of 32 and the grid winding 38. An adjustable resistor 40 allows the electrical charges stored in this capacitor to flow away.

At the beginning of the working period, the Anode strona closes, and the grid is developed as a result of the polarity of the grid) of the transformer positive. This increases the size of the anode flow until it is saturated is reached, whereupon the anode

current begins to decrease. At this point the anode current drops steeply to zero from the fact that the pretensioning of the grid at the moment in which the Anode current begins to decrease, vice versa via the transformer windings 38 and 42 will return. The lattice is suddenly given a lent far below the lower bend; lying preload.

During this process, the accumulated in the capacitor 36 arises Charge on the grid of 32 is a bias voltage below the locking voltage. The tube is therefore blocked until the stored in the capacitor Charge flows through resistor 40 to the locking point of 32, too which time a synchronization pulse of the image change synchronization pulse sequence arriving via line 44 counteracts the bias on the grid so that anode current can flow. Then the working period repeats itself.

A sawtooth wave of tension occurs across capacitor 46 and a pulse voltage wave across resistor 48. The Voltage wave across capacitor 46 and resistor 48 is amplified in tube 50 and then fed via the line 52 to the coils 24 for the vertical deflection of the beam. The angle at which the beam is deflected can be adjusted by adjusting a resistor 54, which allows the anode voltage on the oscillator tube 32 to be changed.

Network 26 is similar to network 28 and receives the synchronization signals through a conduit 56. The angle by which the beam is deflected in the horizontal direction can be adjusted by a resistor 58 '. The slide of the resistors 54 and 58 sit on a common shaft 60 which is rotated by knob 62 can be. When the shaft 60 is rotated clockwise, i.e. in the direction of the Arrow 64, the angle by which the beam is deflected horizontally or vertically is increased, so that a larger part of the entire screen surface is scanned and vice versa. If you z. B. assumes that the image the rectangular area 66 of the screen occupies the complete view, the Adjustment can be made so that the beam scans this area. Go berserk of the shaft 60 in a counterclockwise direction in a given point, the angles uim that the beam is deflected horizontally and vertically, be reduced so that the The beam scans the area 68, which is only part of the entire area 66. With further Rotation of the shaft 60 in the same direction, the even smaller area 70 is scanned. The ratio of the angle of horizontal deflection to vertical deflection remains constant during rotation; thus, if face 66 is square, faces 68 and 70 also become square be.

In order to enable the scanning of a certain area of the screen, the Core of the deflection coils 22 auxiliary coils 22 «wound with a through the resistor 72 and the slide 74 controllable direct current source are connected. When moving this slide to the right becomes the part of the surface 66 to be scanned further to the right shifted and vice versa.

On the core of the deflection coils 24 auxiliary coils 24 ° are also wound, which with a by the resistor 76 and the slide 78 controllable direct current source is connected are. When this slide is moved upwards, the part of the surface 66 to be scanned is moved further upwards and vice versa. ■

When the surface 66 is scanned, image signals are now generated and fed to an amplifier and transmitter 80. If a close-up view of a particular portion of the view is desired, the shaft 60 is rotated counterclockwise without changing a deflection frequency, so that only a portion of the surface 66, such as surface 70, is scanned. Then the slides of 72 and 76 are adjusted so that the surface 70 comes into the desired position, for example at α or b or c. The beam then only scans that part of the full view that is to be enlarged. The enlarged reproduction of the selected image section is achieved by the fact that no changes are made to the image build-up area or the deflection frequency at the receiver.

When the scanned area is reduced, it is necessary to also adjust the scanning spot to zoom out. For this purpose the usual anode 88 is connected to the slide 90 of a variable resistor 92, which is connected to a direct current source 94. This slider is also on of shaft 60, such that when the beam scans smaller portions of surface 66, the Voltage at the anode 88 becomes less positive, so that the beam is more focused will.

In the case of an enlargement of the scanned area, it may also be desirable that the To increase the strength of the scanning beam. For this purpose the beam generating device contains 18 a grid 81 connected to the slide 82 of a variable resistance connected to a direct current

source 86 is connected. Also, this slide 82 sits on the shaft 60 in such a way that with increasing area the bias of the grid 81 becomes less negative and thus the strength of the beam increases and vice versa.

Claims (1)

Claim: The use of the electrical control devices known from image receivers for image adjustment for the transmission of ^ individual ones also eccentrically to the screen center Excerpts of a lying on the screen of a cathode ray scanner on the transmitter thrown image by acting on the size of the deflection angle, the spot size and the setting of the central position of the scanning beam to the transition from Remote recordings on Naih recordings (close-ups) at the reception center. 1 sheet of drawings