SU960913A1 - Device for displaying data on color cathode-ray tube screen - Google Patents

Description

The invention relates to computing and can be used in devices for displaying information on the screen of a color electro-ray tube. A color device, a color television receiver, using a calculator, a keypad, a parallel-to-serial code converter, a control unit, a character generator and a color control unit. It is also known a device containing a color television tube, a dynamic on-line memory and static shift registers 2. The closest in technical essence to the proposed is a device containing a color television monitoring device, a buffer memory storage device, a shift register of characters,. characters, video generator, color decoder, character control generator. From a video generator to a color electron beam tube that is part of a color television monitoring device, under the control of a daifrarator, signals are received that correspond to red, green, blue and white colors. A disadvantage of the known devices is the reduced quality of displaying information, distorted moirs (parasitic patterns), caused by interference between the structures of the lines of the raster (the structure of the details of the reproduced image) and the horizontal rows of holes in the shadow mask (slotted cally, the focusing grid) color cathode-ray tube., moire also deteriorate luminance and color contrast of the image detail, sharpness reproducible border parts (raz1lavayuts boundary) razlichikyust small image parts, i.e. ability and clarity. High-frequency moire, slightly meta-sensitive, perceptions of color in JHOM broadcast television (large display viewing distance) significantly worsen the degree of | These images are in color devices; display of info infomation (small distance of observation of the display). j The aim of the invention is to increase the contrast, sharpness and clearly the information display by suppressing moire patterns. The goal is achieved by the fact that the device for displaying information on the screen of a color cathode ray tube (CRT), containing a graphic element generator, the first input of which is connected to the output of the control unit, a video signal amplifier, connected to a color CRT modulator, a block of color signal amplifiers, connected to the control grid of a color CRT, the deviation control unit whose output beam is connected to the deviation system of the CRT, the output of the control unit NIN is connected to the output information bus, The first input of the control unit is connected to the input information bus, the first and second delay elements are entered, the inputs of which are connected to the output of the control unit, the outputs, respectively, to the inputs of the control unit of the beam deviation, the shift register whose input is connected to the output of the control unit, and output - to the second input of the graphic element generator, the output of which is connected to the second input of the control unit, the inputs of the OR element and the OR elements block, the outputs of which are connected, respectively, to the video amplifier inputs About the signal and-block video amplifiers color signals. FIG. 1 is a block diagram of a device for displaying information on a color cathode ray tube screen; in fig. 2 shows an example of the occurrence of moire when crossing two rows of parallel lines; on ig.z — reproduction of monochrome details (either only red K, or only green o, or only blue B) on a colored electron beam tube; in fig. 4 shows the dependence of the coefficient vg on the ratio Al / E for two types of color electron beam tubes; in fig. 5 is a reproduction of a color image (in accordance with the block diagram of FIG. 1). The block diagram of the device for displaying information contains a block 1 of control, a generator of 2 graphic elements, a block 3 of control — beam deflection, a video amplifier 4 pKoc-fHoro signal, a block 5 of video amplifiers of red color R, green G and blue B signals, a color electron beam tube 6 , delay element 7, delay element 8, shift register 9, block 10 elements OR, element OR 11, bus 12, input information. mation (codes of reproduced elements of the image and their color, commands to write the specified codes and start functioning), output bus 13 (features) 13. A specific feature when playing television color images on three-color screens of dot or line type color electron beam tubes that do not have when playing black-and-white images on the screens of black-and-white electron beam 1 x tubes is the formation of parasitic patterns (moire) due to interference between the structures uroy dot or line screen and the structure of raster lines (or texture image details). The simplest example of moire formation is the intersection at an acute angle E of two line structures with steps a and b (Fig. 2). We find (Fig. 2) the heights of the triangles DBA and WEN and f-b- + iabcos in which the large (a) and small (a / 2.) Moirés pitch, formed at the intersection points of two systems of parallel lines, are determined. This corresponds to low (1 / a) and high (l / a) spatial frequencies, and the number of lines per unit length. For particular cases of equal steps or parallel structures, which is typical of color electron-beam tubes, we have a b or, H 2 sin b / 2 a b with b c o (or 180 °), and 0; at. d / 2. a 9 b with e O or 180), a-b 1 a-b 1. or 1 / a2. 1 / b - 1 / a; 1 / ar 1 / b + 1 / a. Consider the reproduction of monochrome images of either only red R, or only green G, or only blue B in color CRT tubes, where the pitch is one color, is equal to Asg. Let the current of the electron beam kines; copa L (x) when you scan some considered row O x varies according to the cosine law with a period E, so that the maximum value corresponds to X O (Fig.Za), i.e. 3U), cos, where. Is the modulus Qyi of the beam current, i.e. the ratio of the amplitude value of J to the constant component of JQ. The spatial distribution of the B (x) length along a given line for a black-and-white cathode ray tube (PBT, Fig. 3 with a continuous screen and no mask or grid) will be 6U) .0, cos where BO is the constant component of luminance; 0 is the characteristic of the beam aperture. This distribution is shown in FIG. Zb is solid. In the color electron beam tubes (the CG in Fig. 3), the discrete structure of the screen node creates an additional aperture effect, which can be expressed by the characteristic of the rectangular aperture g. and PS And where the width of the rectangular aperture C characterizes the transparency of the screen node, i.e. indicates how much of the beam current falls on the monochrome elements in question. The dependence of the magnitude 67 on the ratio ASH / E for a color electron beam tube with a mass CM and for a color electron beam tube with a GX focusing grid is shown in FIG. 4. In colored electron-beam tubes, the luminance intensity of the nth element of a dotted or dashed screen is determined by samples from a periodic luminous signal, having coordinates along the line xn-Aw (where n is 0, 1, 2, etc.). The modulation coefficient is weakened by the joint action of the aperture of the beam b and the aperture of the screen node QU, the constant component of B d is reduced in C ra. As a result, for a color cathode ray tube we obtain the following dependence of the change in luminance on the number of a dotted element or a screen stroke 6 .-. 4m, 0, (l3I, 4). In Fig. 3b-d circles are shown extracts corresponding to discrete values of luminosity on the color screen elements of a color EFL tube, and the envelope of the samples is shown by a dotted line. which is natural and with maximum contrast reproduced large parts of the image corresponding to (range O i Ats, / E 0.25 1 s 6 I in Fig. 4), for which (for zone I) the attenuation of the amplitude of the amplitude signal dn; - r1 1. small. At 0.25 Aw / E 0.5 (zone II in Fig. 4), the reproduction depends on the phase shift between the dashed image details and the color elements of the screen. For example (Fig. Sv), at 0.5 the phase shift is on Ausch / 2 leads to a current that the amplitudes of all samples are compared. In the region of 0.5 Aw / E 1 (zone III in Fig. 4), the reproduction will be highly distorted — instead of the useful signal with transition B, low-frequency moirs with a peri ode will be reproduced. At the same time -J- -t- - -p l t. FIG. 3 shows an example of such a reproduction Aw / E 0.8; at the same time, the moire period is A 5-Aiu 4E. Here, the amplitude of the sample envelope is greatly attenuated. Thus, the moire intensity, characterizing the attenuation of the amplitude of the useful luminous signal, is equal to,. B i- & m 6m-Qi-B 6 (- (- 0). So for e2. 1, the intensity of moire is equal to O (the case typical of black-white electron-beam tubes). At 1 0 O, the amplitude decreases to some extent of the useful signal (a case typical of colored electron-beam tubes). So, when the moire intensity is W = Bml Bt, i.e., it is almost completely masked, the noise is with the useful signal. As follows from Fig. 4, when A / E 0 Indeed, at step Ash Oh, when Oh, all the point elements of the screen of the cathode ray tube merge, the mask node becomes Align, (all the holes or slits of the mask merge), thus eliminating the interference between the structures of the lines of the raster and the raster structure of the mask, i.e. the color electron beam tube turns into a black and white in which moire does not occur. The ratio A / E is zero and accordingly also in the case when the period of the signal E tends to infinity. In this case, the moire does not occur in the color electron beam tube. Since the pitch is one-color: screen elements A, and the pitch of the openings (slits) of the mask of the mask node are TRAM color elements: ktronnoluchevoy tube, which change for the selected color cathode-ray tube it is not possible to reduce moire intensivnos .t possible only by the use of signals which can be regarded as signals whose period tends to infinity.

Signals whose period tends to infinity are not physically realizable. However, the implementation of signals that can be considered as signals whose period tends to infinity can be artificially approximated. The degree of approximation determines the degree of moire depression.

For the above approximation, it is used that in devices for displaying modulation information (control) of the beam current value is performed by square pulsed signals: signals. The switching of the modulating impulse signals can be carried out only at those times when the beam (rays) of the color CR tube hits the surface of the mask, and not in the hole (slit) of the mask (Fig. 5), since the screen of the color CRC is in the shade the masked node, for the operator watching the reproduced image, the reproduced image line seems to have neither a beginning nor an end, since the switching moments of the modulating signal remain invisible for the operator. Thus, the real physical signal for the operator becomes a signal whose period tends to infinity, which explains the significant suppression along the line of the reproduced image observed by the operator of the moire.

An analogue of the proposed technical solution, according to its essence, is to obtain a movie image. A motion picture tape consists of separate frames, but viewers do not notice this, because at the time of the transition from one frame to another, the image is overlapped with a special disk (obturator). Movie image for the viewer seems continuous, endless.

The proposed device for displaying information on the screen of a color electron-beam tube operates as follows. . .

The input information from the bus 12 through the control unit 1 is recorded in the generator 2 of graphic elements. The control unit 1 is a pulse generator connected in series, a counter (pulse distributor) and a diffuser. From the output of the control unit 1, the horizontal sync pulses through the first delay element 7, and the frame sync pulses through the second

The delay element 8 is fed to the inputs of the beam deflection control unit 3. The latter includes a lowercase and personnel mastering the TOFM and lowercase and frame breaking coils. (The convergence nodes of the color of the electron-beam tube 6, the high-voltage rectifier is not shown).

The movement of the rays (beam) of the color electron beam tube 6 along its screen is carried out by the beam deflection control unit 3 in accordance with the television principle from left to right and from top to bottom (see Fig. 5), the Graphic Generator 2 in accordance with the content and color of the displayed information ( , graphics) modulates the beam of a cathode-ray tube 6 in brightness and color through the element OR 11, the video amplifier 4 of the power signal, the block of elements OR 10 and the block 5 of video amplifiers of color signals at strictly defined moments of time tim when it is necessary to highlight the corresponding scanning element formed graphic elements in a dot matrix, for example 8x8 pixels.

Reproducible information is generated line by line, i.e. as the electron beam moves along the line, elements of the upper, middle, and then lower rows of matrices are successively highlighted.

Thus, from graphic elements, like a picture from a mosaic, symbols or a graphic image are added. The generator 9 of graphic elements regenerates the reproduced image with a frequency of 50 frames in 1 s. Signs of the end of the reproduction of the line or frame of the reproduced image from the output of the graphic element generator 2 through the control unit 1 are fed to the output information bus 13, since it is convenient to record new information in the graphic element generator 2 during the return stroke on the line or frame - the flickering of the reproduced images. The image modulation pulses are rigidly connected with the horizontal sync pulses, which, through the shift register 9, initiate the reading of information from the generator 2 of graphic elements.

Claims (3)

The delay of the horizontal sync pulse entering the horizontal scan generator of the control unit 3 by deflection of the ray allows to control the position of the modulating pulses along the image line, and therefore arrange them, as indicated, so that the switching of the modulating pulses takes place in the shadow of the mask site of the electron beam tube 6 (see Fig. 5). Obviously, the duration of the modulating pulses must be a multiple of the time T. where V is the speed of the beam moving across the screen of the colored electron beam tube b (see, Fig. 5). The horizontal sync pulse delay is performed by the first delay element 7. It is known that in order to suppress moire along the image frame, arising due to interference between the structures of the raster lines and the horizontal rows of mask holes, the exact steps of the monochrome screen elements and the beacon slots of the vertical beacon are avoided. in the color cathode ray tube 6, and in a small range the vertical size of the raster is changed. In addition to these measures, given the mask format and image format, it is advisable to be able to offset the entire frame of the reproducible image relative to the iviaco4Horo of the color CR tube b. Such an offset is effected by the delay of the frame sync pulse imposing on the frame scan generator of the beam deflection control unit 3, the second delay element 8. Practically, the delays of the first 7 and second 8 delay elements are set experimentally by the minimal visibility of the moire, as compared with that of the moire, when delay 7 is delayed by elements 7 and 8. The video amplifiers R, G, B of the block 5 video amplifiers of color signals are usually much narrower in transmission bandwidth (1.5 MHz) than the video amplifiers of the 4 amplitude signal. Thus, the switching time of the modulating signals at the outputs of the video amplifiers R, G, B of the block 5 video amplifiers of color signals is longer than the switching time of the video amplifier 4 loudspeaker signal. Therefore, when simultaneously reading the codes of graphic elements and the color of graphic elements from the output of the generator 2 of graphic elements, video amplifiers R, G, B of block 5 of the video amplifiers of color signals begin to switch immediately after the appearance of signals on their tracks. The modulation pulses from the output of the graphic element generator 2 through the element OR 11 to the input of the video amplifier 4 luminous signal arrive only at the moment when the video amplifiers R, G, B have finished switching to the block of video amplifiers of color signals, which makes it possible to block the beam of the color electron beam tube for switching off video amplifiers R, G, B, since the beam is only unlocked for times when there is a modulation pulse at the output of video amplifier 4 and block 5 of video amplifiers. A delay in the beginning of the coupling of modulation pulses from the generator 2 output of graphic elements for the capacitive channel as compared to the modulation pulses for the color channels is carried out by the shift register 9; In the latter, the first few and the last few bits are not connected to the generator 2 of graphic elements. Since all bits of the shift register 9 are excited at a given clock frequency sequentially, when these first few and last several bits are excited, the information from the graphic element generator 2 does not occur, but only the start of reading is delayed by the activation time of the K, G, B video amplifiers 5 video amplifiers of color signals and the end of reading before the R, G, B video amplifiers start turning off. as the beginning of their inclusion coincides with the moment of the excitation of the first of the last unconnected bits of the shift register 9. When the generator 2 simultaneously generates graphic elements of modulation pulses for reproducing symbols and graphics, when they are superimposed on each other, to avoid the occurrence of moire at the intersection of the vertex of one of the pulses and the front of the other of the pulses, the OR 11 element transmits to its output from two modulation pulses arriving at its input, a modulation pulse for which the leading edge starts earlier and the falling edge ends later. The anshotic task is solved by a block of 10 elements OR, containing in its composition three independent output elements OR, for each of the video amplifiers R, NW, B of the block 5 video amplifiers of color signals. Thus, with the discrete structure of the screen and the mask assembly of the color electron beam tube 6, sampling the image, which, it seemed, could only increase the intensity of the moire, carried out by the proposed method, can significantly reduce the intensity of the moire. The color slides taken from the screen of the color cathode ray tube of the active sample of the proposed device are examples of reproducible images. When viewing slides through a magnifying glass or overhead projector it is not possible to see moire patterns, which indicates a high degree of suppression of moire patterns. The contrast and color contrast, edge sharpness, clarity and resolution are very high at the same time. The image is reproducible. The use of the first and second elements of the shift register delay, the block of the OR elements, and the OR element favorably distinguishes the proposed device for displaying information on the screen of a colored electro-ray tube, since the quality of the information display is enhanced by suppressing moire patterns while improving contrast, sharpness and clarity . The invention device for displaying information on the screen of a color cathode ray tube (CRT), containing a graphic element generator, whose input is connected to the output of the control unit, a video signal amplifier, connected to a color CRT modulator, a block of color signal amplifiers, connected to a control grid a color CRT, a beam deflection control unit whose output is connected to a deflection system of a CRT, an output of a control unit is connected to an output information bus, the first input is a block control is connected to the input information bus, characterized in that, in order to increase the contrast, sharpness, and clarity of the image due to the suppression of moire, the first and second delay elements are entered into it, the inputs of which are connected to the output of the control unit, and the outputs, respectively, the inputs of the beam deflection control unit, the shift register, whose input is connected to the output of the control unit, and the output to the second input of the graphic element generator, the output of which is connected to the second input of the control unit, to the element inputs and OR and OR block elements, the outputs of which are connected respectively to the inputs of the luminance signal video amplifier and the video amplifiers block color signals, I, information sources, the received note in the examination. 1. For Great Britain No. 1405141, cl. G 06 K 13/20, published. 09/03/75. 2. For Japan Japan 5023572f G 06 P 3/14, published. 08.08.75 3. For the UK of UK number 1293506, cl. G 06 K 15/20, published. 10/18/72 (prototype). h ×