DE2137714A1 - Device for compensating undesired reflection or scattered lights when simulating graphic processes by means of a simulator containing a display device - Google Patents

Description

213771A

PcientonvjGiie Dipl.-lng. W. Scherrmcinn. Dr.-lng. R. ROc ^ r

73 Esslingen (Neckar), Fabrikstrasse 9, Postfach 348 July 26, 1971 _{ΤοΙβΙοη}

PA 13 rÜZa Stuttgart (O711) 35i5iV

«'/ 41V

Tologrammo PutonlschuU Esslingonnockar

Uazeltine Corporation, Greenlawn, New York, 11740, USA

Device for compensating undesired reflected or scattered lights when simulating graphical methods by means of a simulator containing a display device.

The invention relates to a device for compensating for undesired reflected or scattered lights during the simulation graphic method by means of a simulator containing a display device, in which the in the graphic process to be reproduced image representing video signal is generated, the one between a lower average image brightness and an upper average image brightness variable average image brightness reproducing constant component contains.

For normal television purposes, the influence of reflection or Gianz lights in modern picture tubes is small enough to to be negligible. In certain critical applications, such as a simulator for graphic processes, However, the effects of reflected or scattered light can lead to incorrect results even with modern picture tubes to lead.

There is an older, not pre-published proposal the applicant, the influence of reflection light in a To compensate for a cathode ray tube that is used as a light point scanner

' ³ "bath 101111/1911

-for example through multiple reflections in the faceplate the cathode ray tube is created, evened out by increasing the wall thickness of the faceplate, so that it is essentially equivalent to a DC signal. Plierauf is a this uniform reflection light Proportional blanking signal, subtracted from the video signal displaying an image in order to achieve the effect of the To compensate reflection light.

, With large images, however, it is practically impossible to Make reflection light uniform in this way because of the required strength of the faceplate is not executable. In such a display device, there is therefore a reflection light corapensation by an equal shift of the reference level of the video signal only as a first order correction regard. The device that performs this correction must therefore be very inexpensive in order to be economically viable.

The invention is therefore based on the object of a Device to compensate for undesired reflected or scattered lights when simulating graphic processes to create by means of a simulator containing a display device, die.für simulators with large Display devices is suitable and a compensation for displayed images of high average image brightness supplies, the compensation being achieved in a simple, inexpensive way and the associated device can be easily integrated into existing devices.

To solve this problem, the above-mentioned device for compensating undesired reflected or scattered lights is characterized in that it is supplied with a compensation circuit with a DC / AC video signal transmission ratio of less than 1 for the

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signal, and the direct-alternating video signal transmission ratio to reduce the influence of images that are normally sharply outlined in the display on the display device Occurring reflected or scattered light switching off amount can be changed.

The new facility ensures inexpensive compensation the influence of reflection or scattered light; it is particularly advantageous in cases where a large Image is displayed on a cathode ray tube. Of course, the invention can also be used for

Compensation of the influence of reflection or scattered light Ä

be used with other display devices including a light spot scanner if necessary.

In the drawing, an embodiment of the subject matter of the invention is shown. Show it:

Fig. 1 shows a color imaging system incorporating a device according to the invention, illustrated as Block diagram,

Fig. 2 is a block diagram of an embodiment of a device according to the invention,

FL <j. 3, amplitude / timing diagrams of parts of the picture reproducing video signals to explain the embodiment of FIGS. 2 and

Fig. 4 is a diagram to illustrate the of the Device according to FIG. 2 output variable for the input signals corresponding to the Figures 3A and 3B.

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In an imaging system, reflected or scattered light can occur for a variety of reasons. An example for this purpose, multiple light reflections within the display device and -in particular within the Faceplate of a cathode ray tube. For images with high average image brightness, i. H. with sharp urar cracks Images, small dark areas are illuminated by this reflected or scattered light, so they appear brighter to the eye than would be the case if the entire image had a lower average image brightness or no reflected or scattered light would occur, with images with less sharp outlines and lower average image brightness, there is less reflected or scattered light.

Such images are displayed on the cathode ray tube in response to a video signal displaying an image shown, which can, for example, have an amplitude that varies according to the image brightness. In the case of a certain simulator for simulating graphic processes, the minimum signal amplitude gives the maximum Image brightness, while the maximum signal amplitude corresponds to the minimum image brightness (maximum darkness). According to the invention, the effect of the reflected light is compensated by the fact that the amplitude of video signals, which reproduce images that are particularly sensitive to reflected light (sharply outlined images), such It is regulated that the dark areas of these images are displayed darker than indicated by the original video signal, thus eliminating the brightening resulting from the reflected light in the system will.

The new device for compensating undesired reflection or flare is illustrated at 10 in Fig. 1 in the context of an image sensing system, such as

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it is explained in detail in the applicant's earlier patent application P 20 54 099.2. The boxes 11, 12R, 12G, 12B, 13R, 13G, 13B and 14 have essentially the same meaning as the corresponding boxes in Fig. 5 of the earlier application, where the function of these parts is described in detail. Box 11 illustrates a unit which has four parallel optical channels and accommodates a group of four color separation transparencies, while boxes 12R, 12G, 12B each represent a non-linear amplifier and boxes 13R, 13G, 13B each correspond to a driver amplifier. The cathode ray tube is indicated at L5. For everyone *

of the three color channels (red, blue, green) a separate reflection or scattered light compensator 10 is provided because each color displayed on the screen of the cathode ray tube 15 has its own reflected or scattered light can occur. If the display system used is monocromatic, the entire compensation can can be made by a single compensator 10. Since all three capacitors 10 also with regard to their function are essentially identical, the description of the invention is limited to only one channel, for example the red (R) channel. The arrangement of the capacitors between the non-linear amplifiers 12 and the X, Y, Z; R, G, B Matrix 11 happens at a point where the *

Vidao signal amplitude linearly reproduces the image brightness. The Koi.ipansatoren 10 could also be arranged at other points in the individual video signal paths of the display device, at which the video signal amplitude linearly reproduces the brightness of the image. If a compensator 10 is provided in a non-linear part of the signal path, such as between the UCM non-linear amplifier 12 and the driver amplifier 13, the resulting compensation is not as effective, although this arrangement may be useful in some applications. It is also noted that if the

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Compensation takes place, the video signal must be coupled to the picture tube in terms of DC voltage, because an alternating current coupling circuit the difference in the reference level of the video signals for sharp and would destroy less sharply defined images.

In FIg. 2 is an embodiment of one according to the invention ! Compensators IO shown between an output amplifier 15 of the matrix 11 and an input amplifier 16 of the non-linear amplifier R is switched on. The compensator 10 is a line 17 a Image video signal of the type described (in which the maximum amplitude represents maximum darkness) is supplied, A portion of such a signal is illustrated in Fig. 3A, the dashed line indicating the maximum level Represents darkness. This signal has a small dark area, which is caused by the narrow pulse 18 given is; it also has a large bright area that is drawn through the rest of the signal, which between blanking intervals 19 and 20 is illustrated. Part of a second signal is in 3B. This signal has a relatively large dark area, which is due to the large Amplitude of the entire signal between the blanking intervals 19, 20 is shown.

Box 10 represents a facility with an equal / AC video signal transmission ratio of less than I for input video signals, which allows the ratio the direct to the alternating component of a supplied video signal to change an amount which is the undesirable Effect of the sharp urarlssener images displayed in the display device that normally occurs reflected or scattered light turns off. The facility

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tion has the effect of adjusting the supplied video signals to a reference level which depends on its constant component is slightly variable, with sharply outlined images representing signals on a higher and therefore darker reference levels can be set than signals which have less sharply outlined images represent.

In Fig. 4, the output size of the block 10 is illustrated for the superimposed signals shown in FIGS. 3Λ and 3B. As can be seen from the drawing, the signal part according to FIG. 3A is shown at a higher - reference level than the signal part according to FIG. 3B, the difference between the reference levels being illustrated by the dashed area in FIG. If these signals are coupled with DC voltage into a picture tube, for example through the non-linear amplifier 12R and the driver amplifier 13R in the cathode ray tubes 15 of the arrangement according to FIG. 1, the following effect results:

The signal part according to FIG. 3B controls the associated electrode of the cathode ray tube (red in this case) accordingly the amplitude changes, whereby signals with maximum amplitude switch off the electrode completely, which is a maximum dark, d. H. black, representation on the "

Cathode ray tube 15 results. Since the average brightness of the image according to Fig. 3B is low (the mean amplitude is large) there is no particular scattering problem in the image display. A little darker Area therefore appears just as dark to the eye as a large dark area. The signal of Figure 3A turns on on the other hand, an image with a high average image brightness in which, as stated above, the Reflected or scattered light can illuminate small dark areas, such as the area caused by the pulse

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is produced. This scattered illumination is caused by the enlargement resulting from the higher reference level of the signal the amplitude of the pulse 18 is switched off, so that the small dark area appears to have the same darkness has what it would have if the average image brightness had been low. Since the reference level is continuously is dependent on the mean amplitude (i.e. the DC component) of the video signal and therefore on the is shifted to average image brightness, all video signals input are set to a reference level, which results in a first-order compensation for every image, because the scattered light decreases with decreasing image brightness and therefore the amount of compensation required going back. However, this type of compensation is only effective in the range in which the amplitude of the is not compensated video signal is not sufficient to switch off the associated electrode of the cathode ray tube itself, because with certain arrangements after reaching the maximum darkness there is no possibility of what is shown To make the picture even darker.

A particularly effective and cheap method of setting the video signals to the correct reference level results from the use of a partial DC coupling in the form of a parallel connection of a variable resistor 22 and a capacitor 23. An alternating voltage coupling is briefly understood to mean a coupling, by which the equal comporiente of the signal is blocked (usually by a capacitance), while under a DC coupling, which normally occurs through a resistor, the DC component of the Signal is allowed through * The partial DC coupling has the effect that part of the DC component of a Signal is allowed through and a part is blocked,

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in other words, this means that the equal-to-ax transfer ratio is less than 1. In the illustrated embodiment, this is the transmission ratio by the interdependence of the capacitance of the capacitor 23, the resistance of the variable Resistance 22 and the output and input impedance of the amplifier 15, 16 given.

From FIG. 4 it can be seen how the reference levels for the signals of FIG. 3 are established. The signal after 3A has a small constant component (mean value) which corresponds to its small mean amplitude. I.

It is therefore transmitted through the coupling element (resistor 22 and capacitor 23) essentially unaffected. The signal of Fig. 3B has a large DC component, that of its relatively large mean Corresponds to amplitude. If the coupling were completely in terms of DC voltage, the DC component of the signal would be completely blocked, while the resulting video signal is averaged out with respect to its mean value which means that it would drop well below the signal of Fig. 3A. When using the partial DC coupling results in a decrease by an amount that is only part of |

of the lowering, which in the case of a complete alternating voltage Coupling would arise. The signal according to FIG. 3B is therefore only below this amount that lowered according to Fig.3A.

Are z. B. the resistor 22 and the capacitor 23 are chosen so that a 5% partial DC voltage Coupling results, or in other words, a 25% DC / AC transmission ratio is present, the signal according to FIG Signal according to Fig. 3Λ) decrease by an amount that approximates

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-wciso 5% soinGG corresponds to its own mean. The bigger clic mean amplitude of the signal and therefore the lower the mean image brightness, the greater the reduction and the lower the reference level at which these signals are set. Signals that are on set the highest (darkest) reference level, signals are with little or no constant component (mean value) ; they reproduce images which, as already stated, are particularly sensitive to stray light and therefore in particular make compensation necessary.

In order now to properly adjust the resistor 22 to a value that provides adequate compensation results in the entire range of the possibly supplied signals, the following procedure is suggested:

First a large area of predetermined darkness and then a small area of equal darkness considered the cathode ray tube. The resistor 22 is then adjusted until the larger dark area appears to have the same darkness as the smaller area. For this purpose there was once a full screen filling dark area and then a dark,

Area measuring 25.4 mm in the center of the cathode ray tube viewed with both areas set to the same darkness.

The exemplary embodiment described does not, of course, represent a limitation of the invention. It is only used to illustrate the idea of the invention.

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Claims (5)

$ ■ "21377H - li - Claims 1 Λ Device to compensate for unwanted reflections or scattered light when simulating graphic processes by means of a device containing a representation Simulator, in which one is used in the graphic process Image to be reproduced representing video signal is generated, the one between a lower mean image brightness and an upper average image brightness contains constant components reproducing average image brightness, characterized in that it includes a compensation circuit (10, 22, 23) with a DC-to-AC video signal transmission ratio of less than 1 for the supplied video signal up / down, and that the equal-to-alternating video signal transmission ratio one, the influence of normally in the display of sharply outlined images the amount of reflected or scattered light that occurs on the display device can be changed. 2. Device according to claim 1, characterized in that da3 the supplied video signal has an amplitude which corresponds linearly to the picture brightness. 3. Device according to claim 2, characterized-characterized, that the compensation circuit (10) is a partial DC voltage Coupling circuit (22> 23). has, and the compensated video signal of the display device DC voltage: Tnäßig is coupled. 4. Device according to claim. 3, characterized by, that the partial DC voltage. Coupling circuit (10) the parallel connection of a resistor (22) and a capacitor (23). - 12 - 109887/1715 "· ^{;:? A} * ^3. BAD ORIGINAL 5. Device according to claim 4, characterized in that the resistor (22) and the capacitor (2 3) a DC / AC video signal transmission ratio of about 95%. 109887/1715 ORIGINAL BATHROOM IS Blank page