SU1021024A1 - Device for displaying data on a large screen - Google Patents

Abstract

A DISPLAY DEVICE OF INFORMATION ON A BIG SCREEN containing kinescopes located in L ranks of K in each row, sequentially connected matching unit and clock generator, the output of which is connected to the synchronous inputs K of video signal switches, characterized in that, in order to increase the picture brightness by increasing the duration of the excitation of the element of the image, two delay blocks, a frequency multiplier, a frequency duration and two clock switches, are introduced, with the second output of the matching block is connected to the information inputs of the first and second delay blocks, the output of the sync pulse generator is connected to the clock multipliers of the frequency multiplier and two clock switches, respectively, the output of the frequency multiplier is connected to the first clock input of the first and second switches of clock pulses and to the input of the frequency divider whose output is connected to the second clock input of the first and second switches of clock pulses, the output of the first switch of clock pulses is connected to the clock input of the first the delay unit, and the output of the second clock switch are connected to the clock input of the second delay unit, the outputs of the first delay unit are connected to the first inputs of video switches, the outputs of the second delay unit are connected to the second inputs to video switches, and the output of each of the switches the video signal is connected to the cathodes of the picture tube of the column, and the modulators K of the picture tubes of each row are interconnected.

Description

11 The invention relates to electronic technology, more specifically to image reproduction devices on a large screen, and can be applied in television, computer technology and other fields of technology. An information display device using a matrix electroluminescent screen is known. In order to increase the brightness of the image, the device uses a line-by-line method of reproducing information, in which information is fed simultaneously to all columns of the matrix screen. Since the image information (video signal) is fed to the device sequentially over time, to ensure the simultaneous supply of video information to the Screen Poles, a line drive is used, which is a delay unit containing n delay elements with offsets from each element, where n is the number of elements horizontal decomposition of the image, equal to the number of columns of the matrix screen. The total time of the video signal through the delay unit is equal to the length of the line. The taps of the delay unit are connected via gating blocks and luminance control units to the columns of the matrix screen. When the device operates, after the delay block is completely filled with a video signal that carries information about the line, the strobe unit connects the delays of the delay unit to the luminance control units that generate excitation pulses proportional in amplitude to the direction of the video signal located at the time of gating on the delays of the delay unit . The duration of the excitation pulse for all elements of the excited line is the same and equal to the length of the line. Subsequent image lines are obtained in a similar way. The transition from element-by-element scanning, usually used in television, to line-by-line, allowed the device to increase the duration of the excitation of the image element by n times, and thereby increase the image brightness by about the same amount. The advantage of the information display device on the matrix screens is the possibility of creating a device with a large size and connected to the information inputs of the first and second delay blocks, the output of the clock generator i ' s with a small depth of the device. However, such a disadvantage of the known matrix screens (gas discharge, electroluminescent, etc.), as a small light output, does not allow to obtain at the present time acceptable image luminances, despite such specially taken measures as line-by-line scanning. It is also known a display device of information on a large screen, containing picture tubes located in E rows of K in each row of a series-connected matching unit and a clock generator, the output of which is connected to the synchronous inputs K of the video signal 2 switches. The disadvantage of this device is low image brightness. This is due to the fact that the excitation time of one image element t is equal to the length of the line tp divided by the number of image decomposition elements horizontally G p Therefore, despite the high luminous efficiency of cathode luminophores used in kinescopes, the image brightness of a known device does not exceed the image brightness, obtained in conventional televisions using a single kinescope, the duration of the excitation of the image of which is also equal to Tl. The purpose of the invention is to increase the image brightness by increasing the duration of the excitation of the image element. This goal is achieved by the fact that two delays are entered into a display device on a large screen containing kinescopes located in rows of K in each row, sequentially connected matching unit and driver of sync pulses, the output of which is connected to synchronous inputs K of video signal switches , a frequency multiplier, a frequency divider and two commutators | clock pulses, while the second output of the matching unit is connected to the synchronous inputs of the frequency multiplier and two clock switches respectively, the output of the frequency multiplier is connected to the first clock input of the first and second clock switches and to the frequency divider input, the output of which is connected to the second clock input of the first and second clock switches, the output of the first clock switch is connected to the clock input of the first delay unit, and the output of the second switch of clock pulses is connected to the clock input of the second delay unit, To the outputs of the first block of latching are connected to the first inputs To the switches of the video interface The outputs of each of the video signal switches are connected to the cathodes of all column tubes, and the modulators to the picture tubes of each row are interconnected. The drawing shows the structural electrical circuit of the proposed device. display information on the big screen. The device contains a matching unit 1, a synchronization driver 2, video signal switches 3, connecting lines k of video signal switches, synchronization input 5 of video signal switches, output 6 of video signal switches, kinescopes 7, kinescope cathode 9, frequency cathode 9, frequency multiplier 10, frequency divider If , two switches 12 clock pulses, clock switch input 13, clock switch synchronization input It, clock inputs of 15 delay blocks, two delay blocks 16, rejection of 17 delay blocks, od 18 delays blocks of video device operates as follows. At the beginning of the image raster line, the first line sync pulse, / 1Speaking from the output of the sync pulse generator, switches all switches 3 and 12 to the first, the position when its first input is connected to the switch output. Thus, clock pulses from frequency multiplier 10 are acquired at the clock input 15 of the first delay block 16. The frequency of these pulses is n times higher than the horizontal frequency. In the future, the clock pulses going with this frequency will be called the recording clock pulses. Their period is -. Since the delay block contains n delay elements and the filling of the delay element with information occurs per clock cycle, the total filling time of the delay block with a video signal, or the duration of recording information in the delay block is equal to the period of horizontal sync pulses or the image string length t {. Since at this moment their first inputs connected to the taps of the second delay unit 16 (in the drawing below), which are not filled with information, are connected to the output of the video signal switches 3, the first raster line currently does not carry information and images. The second horizontal sync pulse coming from the imaging unit 2, switches switches 3 and 12 to the second position when the second inputs are connected to the outputs of the latter. As a result, the write clock of the second delay block 16 begins to receive the write clock pulses and the second line of the second delay block 16 is filled with the video signal. At the clock input of the first block 16 of the delay at this time begin to receive the clock pulses from the divider frequency 11. The period of these clock pulses is K times the period of the clock pulses of the record and is equal to tc. K. Let's call them clock read pulses. Under the influence of these pulses, the previously recorded video signal of the first line of the image raster begins to move along the first delay block 1b and enter its taps 17, where through the switches 3 the video signal is fed to the cathodes 9 kinescopes 7. So as the period of the read clock pulses is K times the pulse period records, then the information from each element of the delay unit 16 in this read mode is located on its branches K times longer than when written. The sweep of the lines of all kinescopes occurs synchronously and simultaneously, with the sweep duration of each kinescope equal to the period of the horizontal sync pulses t. Thus, the length of the line in each kinescope is increased by a factor of K, the time of excitation of each element, which is equal to

510

the period of the read clock pulses it K. This allows approximately a K fold increase in the brightness of the reproduced image in comparison with the prototype.

In the future, the device works in a similar way, while in one of the blocks 1 (the S delay is the video signal of the next line, from the branches of the other delay block 16, the video signal of the previous line is fed to the cathodes and simultaneously reproduced on kinescopes of the same row.

As blocks 16 delays in the device can be used sequential shift registers (for dual-graded information) or CCD registers (for multi-graded information). As switches for video signals, analog keys on MIS structures can be used (for example), up2 - equal to the T-flip-flop, with clock sync pulses falling on the clock input. Additional switches 12 clock pulses can be performed similarly, or, inasmuch as they commute digital information, in the form of a T-trigger, control element 2-2 and-OR. The frequency multiplier 10 can be performed, for example, as a normal multiplier for harmonics of a horizontal sync signal. The frequency divider may be, for example, trigger.

Thus, due to the additionally introduced blocks, the duration of the excitation of the image element is increased K times. This makes it possible to increase the brightness of the image in the proposed device also by K times, in comparison with the known, where K is the number of kinescopes in one row of the device.

Claims (1)

LARGE SCREEN INFORMATION DEVICE containing picture tubes located in? rows in K in each row ,,, serially connected to the matching unit and the generator of clock pulses, the output of which is connected to the clock inputs K of the video switches, characterized in that, in order to increase the brightness of the image by increasing the duration of the excitation of the image element, two delay blocks are introduced, a frequency multiplier , a frequency extender and two clock switches, while the second output of the matching unit is connected to the information inputs of the first and second delay units, the output of the sync driver pulses are connected to the clock inputs of the frequency multiplier and two clock switches, respectively, the output of the frequency multiplier is connected to the first clock input of the first and second clock switches and to the input of the frequency divider, the output of which is connected to the second clock input of the first and second clock switches, the output of the first switch clock pulses connected to the clock input of the first delay unit, and the output of the second clock switch connected to the clock input of the second block delays, To the outputs of the first delay unit are connected to the first inputs of the video switch switches, To the outputs of the second delay unit are connected to the second inputs of the video switch switches, the output of each of the K video switches connected to the cathodes of all ί 2 picture tubes of the column, and the modulators K of each picture tubes of each row are connected between by myself.