SU680195A1 - Device for shaping electron-beam tube focusing beam correction signal - Google Patents

Description

I

The invention relates to the field of radio electronics and can be used in electron beam indicators for various applications, including television ones.

A device for generating a focus beam correction signal of a cathode ray tube is known, comprising two amplifiers of scanning signals, the outputs of each of which are connected to deflection coils of the cathode ray tube (CRT), and the input of each amplifier of the scanning signals is connected to the first and second outputs of the deviation signal correction unit, respectively whose input is connected to the tcrv output of the image signal generator, the second output of which through a video amplifier is connected to a CRT modulator, to the subfocusing coil which is connected to the output of the amplifier sig} 1a of the dynamic focusing of the beam, and the output of the first and the output of the second amplification are connected to the astigmatism correction coils of the CRT

Astigmatism correction signals, the input of the first amplifier of the astigmatism correction signal is connected to the output of the first multiplier, two inputs of which are connected respectively to two outputs of the deviation correction unit, the input of the second amplifier of correction signals astigmatism is connected to the output of the first adder, two inputs of which are connected respectively to the output of the second and the output of the third multiplier, while the input of the second multiplier is connected to the first output of the deflection signal correction unit, and the third input a multiplier connected to the second output of the correction unit deflection signals l.

A significant disadvantage of the known device is that it does not provide high accuracy of focusing on the entire CRT screen.

Claims (1)

The diameter of the spot on the edge of the screen is 1.5-2 times the diameter of the spot, which is in the center, the resolution on the screen changes as many times. The purpose of the invention is to improve the beam focusing accuracy and resolution across the entire CRT screen. To do this, in device form the commands for the beam focusing correction signal of the electron beam circuit containing two amplifiers of the sweep signals, the outputs of each of which are connected to the deflection coils of the electron beam tube (CRT), and the input of each amplifier of the scan signals are connected respectively to the first and second outputs of the correction unit of the deflection signals, the input of which is connected to the first output of the image signal generator; the second output of which is connected via a video amplifier to a CRT modulator to the subfocusing coil The output of the amplifier of the dynamic beam focusing signal is connected, and the output of the first amplifier of the astigmatism correction signal is connected to the astigmatism correction coils of the CRT and the output of the first multiplier is connected to the output of the first multiplier, two inputs of which are respectively connected to two outputs of the deflection signal correction unit, the input of the second force of the bodies of the astigmatism correction signals is connected to the output of the first adder, two inputs of which are connected} The output of the second multiplier is connected to the first output of the deviation signal correction unit, and the input of the third multiplier is connected to the second output of the deviation correction block, the second adder is entered, the two inputs of which are connected respectively with the output of the second and the output of the third multiplier, and the output of the sum is connected to the input of the amplifier of the dynamic beam focusing signal. The drawing shows a structural electrical circuit of the device for forming a focus correction signal for a cathode ray tube. The device contains an electron beam tube 1, deflecting coils 2, subfocusing coil 3, astigmatism correction coils 4, two amplifiers of scanning signals 5 and 6, a beam dynamic focusing signal amplifier 7, two amplifiers of stigmatism correction signals 8 and 9, video amplifier 10, in adder 11 and 12, the first, second, third multipliers 13, 14 and 15, the correction signal locker 16, the image signal generator 17, the CRT motor 18. The device works as follows. The image signal generator 17 generates deflecting signals U x Ij and a video signal transmitted to the ide amplifier 1O. In its composition, during periodic scanning, generators of line and frame sweeps are contained, and for a rasterless (coordinate) ravert, they are digital-to-analog converters. The deflection signal correction unit 16 is designed to eliminate geometric image distortions arising in a CRT with a relatively flat screen, in which the radii of curvature of the screen and the deflection of the beam are significantly different. This block 16 forms the deflection signals U and 0 at its outputs, taking into account corrective amendments. The multipliers 13-15 multiply the two input analog signals, and the multipliers 14 and 15 multiply the input signal by itself, i.e., perform the functions of quadrators. Thus, at the output of the multiplier 13, a signal is formed that is directly proportional to X Uy, at the output of the multiplier 14, the signal Uv, at the output of the multiplier 15, the signal and Totalizers 11, 12 of the signals are usually based on operational amplifiers, and the adder 11 is the output produces a signal (U - U), and the adder 12 - a signal (and + and). Video amplifier 10 is a broadband multiplication cascade that converts a low-voltage video signal to high-voltage. The sub-focusing coil 3 has a relatively small number of turns in comparison with the main focusing coils (not shown in the drawing), which is necessary to ensure a given focusing speed. Coil 3 is placed either in the focusing slit or in a special bore of the magnetic screen of the main focusing coil. Astigmatism correction coil 4 is a paired four-pole magnetic lens on a common magnetic core. A proportional current (U - Uy) should flow through one of the four-pole lenses, and a current proportional to Uj U should flow through the second one. The first of the two four-pole linges should be positioned so that its collecting and dissipating planes coincide with the horizontal and vertical axis of the raster, and the collecting and scattering planes of the second four-pole lens must coincide with the raster diagonal, i.e. the planes of the lenses are rotated relative to each other by 45. The coils 4 are located between the deflecting coils 2 and the focusing coil 3 on the mountains CRT 1. Thus, the introduction of new elements makes it possible to almost completely eliminate astigmatism across the entire image field and to obtain the same and high resolution in the center and at the edge of the screen. The invention of the device for shaping the signal for correcting the focusing of a beam of a cathode ray tube, contains two amplifiers of the scanning signals, the outputs of each of which are connected to the bias of the cables of the optical gain tube (CRT) and the input of each amplifier of the scanning signals is connected respectively to the first and second outputs of the offset signal unit signals, whose input is connected to the first output of the image signal generator, the second output of which is connected through a video amplifier to a CRT module, to the coil subfocus -j of which is connected to the output of the dynamic beam focusing signal amplifier, and the output of the first and the second amplifiers of the astigmatism correction signals are connected to the astigmatism correction coils of the CRT, the input of the first amplifier of the astigmatism correction signals is connected to the output of the first multiplier, two inputs of which are connected two outputs of the deviation signal correction block, the input of the second astigmatism correction signal amplifier is connected to the output of the first adder, two inputs of which are connected corresponding to the output of the second and the output of the third multiplier, while the input of the second multiplier is connected to the first output of the correction signal correction unit, and the input of the third multiplier & l is connected to the second output of the correction signal correction module, which is In order to improve the beam focusing accuracy and resolution across the entire CRT screen, a second adder is introduced, two inputs of which are connected respectively to the output of the second and the output of the third multiplier, and the output of the adder is connected to the input of the signal amplifier dynamic beam focusing. Sources of information taken into account in the examination 1. US Pat. No. 3961223, cl. 3.15-371, 1976.