RU2120194C1 - Tv set - Google Patents

Abstract

FIELD: TV equipment. SUBSTANCE: device has receiving-amplification path, which first and second synchronization terminals are connected respectively to inputs of frame and line scanning generators, and at least one video terminal which is connected to kinescope which corresponding yoke assembly is connected to outputs of frame and line scanning generators. In addition device has detector of contours of displayed image which input is connected to video terminal of receiving-amplification path. Goal of invention is achieved by introduced electronic commutator which input and outputs are connected respectively to output of contour detector and input of kinescope focusing system. EFFECT: decreased noise and redundancy of image displayed on kinescope screen without loss of horizontal resolution. 3 cl, 4 dwg

Description

 The present invention relates to techniques for reproducing television images on a kinescope screen in raster mode (i.e., using interlaced, interlaced, spiral and other scans) and can be used in broadcast television receivers, applied television system monitors, and other video signal reproducing devices.

 It is known "Device for correcting the sharpness and sharpness of a television image" according to ed. St. USSR N 1188904, in which, to reduce the noise level of the image displayed on the screen of the kinescope, which does not contain sharp details (i.e., an image that is not of practical interest due to the absence of any information in it), high and the middle frequencies of the spectrum of the video signal, during playback of an image containing large parts, only the high frequencies of the spectrum of the video signal are suppressed with the low-pass filter, and during playback of an image containing small sharp details, with the help of a high-pass filter, the high-frequency spectrum of the video signal is raised.

 A disadvantage of the analogue is the impossibility of reducing the noise level of images of real practical interest that contain, in addition to the background, any details. Another disadvantage of the analogue is the impossibility of reducing the physiological redundancy of images, since the elimination of small non-essential details from the image will inevitably be accompanied by a significant deterioration in the sharpness of relatively large parts of the reproduced image, leading to an unacceptable deterioration in its quality.

 Also known as "Nonlinear Television Image Clarity Corrector" according to ed. St. USSR N 1140269, in which the noise reduction of the image displayed on the kinescope screen is provided by a low-pass filter with an adjustable upper cutoff frequency, which is controlled by a signal representing a rectified high-frequency component of the video signal spectrum.

 A disadvantage of the analogue is also the impossibility of reducing the noise level of images of real practical interest that contain, in addition to the background, any details. Another disadvantage of the analogue is the impossibility of reducing the physiological redundancy of images, since the elimination of small non-essential details from the image will inevitably be accompanied by a significant deterioration in sharpness relative to large parts of the reproduced image, leading to an unacceptable deterioration in its quality.

 The closest in technical essence and the largest number of matching distinctive features analogue is a "TV device for reproducing images" according to ed. USSR N 999170, in which the correction of sharpness and sharpness of the image is provided by controlling the aperture of the scanning electron beam in accordance with the signal generated by the detector of the contours of the reproduced image.

 The disadvantage of the prototype is the impossibility of reducing noise and physiological redundancy in the reproduced image due to the fact that when the shape of the aperture of the scanning beam changes, its area is kept constant. Therefore, when reproducing the inter-contour sections of the image, the shape of the aperture becomes round, corresponding to the nominal resolution of the picture tube, which does not make it possible to suppress high-frequency noise and unnecessary small details of the image.

 The invention solves the problem of reducing the noisiness and physiological redundancy of the image displayed on the kinescope screen without degrading its horizontal sharpness by defocusing the scanning electron beam during the reproduction of the contour sections of the image while maintaining the focus of the electron beam during the reproduction of the image contours.

 The solution to the problem is achieved by the fact that in the inventive television set containing a receiving-amplifying unit, the first and second clock outputs of which are connected respectively to the inputs of the vertical and horizontal scanning generators and at least one video output of which is connected to the picture tube, to the corresponding deflecting system of which the outputs of the human frame generators are connected and horizontal scanning, as well as a loop detector of the reproduced image, the input of which is connected to the video output of the receiver-amplifier unit, an electronic commutator is introduced torr, input and output of which are respectively connected to the output of the detector circuit and the input of the CRT focusing system.

 The solution to the problem is also achieved by the fact that the inventive TV has a luminance distortion corrector, and all the video outputs of the receiver-amplifier unit are connected to the signal inputs of the luminance distortion corrector, the output of the loop detector of the reproduced image is connected to the control input of the luminance distortion corrector, and the outputs of the luminance distortion corrector are connected to kinescope.

 The solution to the problem is also achieved by the fact that in the inventive television, the luminance distortion corrector is made in the form of identical luminance distortion correctors, the number of which is equal to the number of video outputs of the receiving-amplifier unit, each luminance distortion corrector containing the first and second electronic keys, the signal inputs of which are interconnected and are the input of the corrector of luminance distortions, the outputs of the first and second electronic keys are connected to the corresponding inputs of the analog adder, sequentially connected a comparator and an inverter, the output of which is connected to the control input of the first electronic key, the output of the comparator is connected to the control input of the second electronic key, the detector of the loops of the reproduced image is connected to it, the output of the analog adder is connected to the tube.

 The distinguishing features listed above are significant because their absence does not allow us to achieve the goal, and their presence, on the contrary, ensures its achievement. Indeed, the introduction of an electronic switch into the inventive television allows, while maintaining the focus of the electronic scanning beam during the reproduction of the image contours, to defocus it during reproduction of the image contour intervals and thereby significantly suppress high-frequency noise and remove noise-like small details from the image, i.e. to reduce the physiological redundancy of the image displayed on the picture tube screen. The introduction of the inventive TV block correction of brightness distortion can prevent their occurrence even with a very significant defocusing of the scanning electron beam and, accordingly, very effective noise suppression.

The invention is illustrated by drawings, which depict:
in FIG. 1 - an example implementation of the inventive TV;
in FIG. 2 is another example of the implementation of the inventive TV;
in FIG. 3 is an example implementation of an electronic switch;
in FIG. 4 is an example implementation of a luminance distortion corrector.

 The inventive television, the functional diagram of which is shown in FIG. 1, contains an amplifier 1 (the specific implementation of which depends on the application - for example, for a television broadcast receiver it contains a high-frequency amplifier, a frequency converter, an intermediate-frequency amplifier, a video detector, frame and horizontal sync pulses, and other nodes), a signal the input of which comes from the source of the information signal (antenna, VCR, transmitting television camera, etc.), not shown in the drawing for simplicity. The frame sync output of the receiving-amplifying unit 1 is connected to a frame-scanning generator 2 (made in any known manner). The horizontal sync output of the receive-amplifier unit 1 is connected to the horizontal generator 3 (made in any known manner). Frame 2 and line 3 scan generators are connected respectively to frame 4 and line 5 deflecting coils of the kinescope 6 deflection system. The video output (the only one in the monochrome television receiver and the widest in the color television receiver) of the receiving-amplifier unit 1 is connected to the input of the detector 7 (for example, in the form of a series-connected differentiating circuit, a push-pull rectifier and a comparator, or in the form of a series-connected integrating circuit and an exclusive OR logic circuit, to another the input of which is connected to the input of the integrating circuit) of the circuits (i.e., the boundaries of large parts) of the reproduced image and to the picture tube 6 (to the cathode, as shown in the drawing, or to a modulating electrode), to which other video outputs of the receiver are also connected to the color television receiver amplifier unit 1. The output of the detector 7 loops of the reproduced image to the focusing electrode 8 of the tube 6 is connected via an electronic switch 9 (in the form, for example, of a high-voltage pulse amplifier with an extreme equal; another example of its implementation is shown in FIG. 3).

 The inventive television, the functional diagram of which is shown in FIG. 2, it differs from its previous implementation only in the presence of an additional corrector 10 of luminance distortions (made, for example, in the form of a set of analog adders or multipliers, the number of which is equal to the number of video outputs of the receiver-amplifier unit 1; another implementation is shown in Fig. 4), included between all the video outputs of the receiving-amplifying unit 1 and the corresponding electrodes (cathodes and / or modulating electrodes) of the kinescope 6, while the output of the detectors is connected to the control input of the electronic switch 10 torus 7 contours of the reproduced image.

 The electronic switch 10, the functional diagram of which is shown in FIG. 3, contains a voltage divider from two limiting resistors 11, 12 and a potentiometer 13 connected between them, as well as an electronic switch 14 (in the form, for example, of a high-voltage pulse amplifier with an extreme level fixing circuit), shunting the limiting resistor 12. In this case, to a free terminal of the limiting resistor 11, a constant voltage source is connected, the focusing electrode 8 of the picture tube 6 is connected to the middle terminal of the potentiometer 13, and the free terminal of the limiting resistor 12 is grounded.

 The luminance distortion corrector 10 can be made in the form of a set of identical luminance distortion correctors, the number of which is equal to the number of video outputs of the receiver-amplifier unit 1 and each of which is made according to the functional diagram shown in FIG. 4. As can be seen, each luminance distortion corrector contains an analog adder 15 (made in any known manner), to the two inputs of which the corresponding video output of the receiver-amplifier unit 1 is connected through two electronic keys 16 and 17 (made in any known manner). In this case, the output of the detector 7 of the circuits of the reproduced image is connected to the control input of one electronic key 17 through a comparator 18, the output of which is connected to the control input of another electronic key 16 through the inverter 19.

 There are other options for the implementation of the claimed TV, differing in the implementation of the nodes: electrostatic deflecting system, non-standard (spiral, sinusoidal or other) scan generators, design of the electrostatic focusing unit, electromagnetic focusing system, etc. For example, when using a focusing system that provides rotation of an elliptical aperture scanning beam, when reproducing the contour sections of the image under the influence of the control voltage from the output electronic switch, the semi-major axis of the elliptical aperture should be installed horizontally. It should also be borne in mind that all schemes are presented in a simplified form, i.e. in practical implementation, they may contain additional nodes (for example, elements of the inputs and outputs of adjacent nodes by polarity in level, time, etc.).

 The inventive television, the functional diagram of which is shown in FIG. 1, works as follows. In the receiving-amplifying unit 1 from the source of the information signal (television antenna, video recorder, transmitting television camera, computer, etc.), for simplicity not shown, the initial information is received and then it is processed accordingly so that a frame sync pulse is output , horizontal sync pulse and at least one video signal (in televisions on a monochrome picture tube - one, in televisions on a color picture tube - at least three). Frame and line sync pulses supplied respectively to frame 2 and line 3 sweep generators ultimately provide sawtooth currents of frame and line frequency in frame 4 and line 5 deflecting coils. Under the influence of these currents, an interlaced or interlaced raster is formed on the screen of the kinescope 6 with its electron beam. And the video signal coming from the receiving-amplifying unit 1 to the kinescope 6 provides the modulation of the electron beam in density and, accordingly, the modulation in brightness (and in the case of several rays and in color) of each element of the raster reproduced on the screen of the tube 6. In this way, on the screen of the tube 6, a transmitted image is reproduced comprising portions corresponding to the edges of relatively large image elements and portions corresponding to the contour intervals of the image. Moreover, the latter are always filled with noise due to the imperfection of television systems, and small details of the original transmitted image, which are little distinguishable from noise. Both of them weary our eyesight, because they distract the human eye from its main work - transferring information about the large details of the observed image to the brain (only a small part of the information objectively reproduced on the kinescope screen is transmitted to the brain) - so they say that the television image has a large physiological redundancy). It is difficult to use low-pass filters in TVs to suppress noise and small details of the image that are unnecessary for the viewer, since the introduction of low-pass filters into the video path unacceptably impairs the sharpness of the reproduced image. In this regard, it should be emphasized that in order to ensure high image quality, it is necessary to have high sharpness rather than sharpness of a television image, since even images with low definition have a high physiological redundancy. Therefore, the high definition of the image in television basically makes sense to the extent that it is accompanied by its high sharpness. High sharpness of the image significantly increases the comfort of visual perception, as it leads to a decrease in the amplitude of the scanning eye movements and, accordingly, less tired eyesight. Therefore, in the inventive TV, a dynamic focusing circuit is provided, comprising a detector 7 of the reproduced image circuits and an electronic switch 9 connected between the widest video output (in monochrome television receivers the only output) of the receiving-amplifier unit 1 and the focusing electrode 9 of the picture tube 6. This circuit provides defocusing of the scanning beam during the reproduction of the contour sections of the image and, therefore, a significant suppression in these areas of the image s and fine details of the original image, i.e., reduces the physiological redundancy of the image. During the reproduction of the contours of large objects on the transmitted image, which are detected by the detector of the contours of the reproduced image, this circuit ensures good focusing of the scanning electron beam and, accordingly, high sharpness of the image contours.

 The inventive television, the functional diagram of which is shown in FIG. 1, works basically the same as its previous implementation. The difference lies in the fact that a much larger relative defocusing of the scanning electron beam is permissible in it when reproducing the contour sections of the image, at which the brightness distortions of the image become noticeable. To compensate for them, a corrector 10 of luminance distortions was introduced, which in the simplest case adds correction pulses to the video signal taken from the output of the detector 7 of the contours of the reproduced image. But since the latter have a constant range, and the magnitude of the video signals during operation can change, this option for correcting brightness distortions does not provide its high quality. More perfect are the corrector implementations of 10 brightness distortions based on analog multipliers, in which the above-mentioned drawback is already completely eliminated. One such implementation is shown in FIG. 4.

 The electronic switch 9, the functional diagram of which is shown in FIG. 3, works as follows. The voltage is supplied to the focusing electrode of the kinescope 6, as is customary in serial models, from the midpoint of the potentiometer 13, the value of which, taking into account the size of the limiting resistors 11, 12, is selected so as to provide the necessary range of manual adjustment. Therefore, with the locked electronic key 14, a voltage is applied to the picture tube 6, which ensures good focusing of the scanning electron beam. With the unlocked electronic key 14, the resistor 12 is shunted, as a result of which the voltage at the midpoint of the potentiometer 13 connected to the focusing electrode 8 is reduced, which ensures the defocusing of the scanning electron beam.

 The luminance distortion corrector 10, the functional diagram of which is shown in FIG. 4, works as follows. In the analog adder 15, the input video signals passing through the alternately open electronic keys 16, 17 are summed in a proportion that provides a complete correction of luminance distortion. The alternate operation of the electronic keys 16, 17 is provided by the antiphase of the signals supplied to their control inputs from the output of the comparator 18 (to emphasize this fact, an inverter 19 is introduced into the circuit of the luminance distortion corrector 10, which can be combined with the comparator 18). The introduction into the corrector 10 of brightness distortions of the comparator 18 ensures the independence of the signal at its output from the contrast of the reproduced image, i.e. increases the reliability and stability of the claimed TV (more precisely, the process of noise suppression and eliminating the physiological redundancy of reproduced images in it).

 The introduction into the inventive device of the distinguishing features listed in the claims makes it possible, due to the dynamic defocusing of the scanning beam during the reproduction of the contour sections of the image while maintaining its focus during the reproduction of the image contours, to significantly reduce the noise level of the image and eliminate unnecessary small details from it, i.e. reduce the physiological redundancy of the image while maintaining its high horizontal sharpness, and thereby significantly increase the comfort of viewing television images.

Claims (3)

 1. A television set containing a receiving-amplifying unit, the first and second clock outputs of which are connected respectively to the inputs of the vertical and horizontal scanning generators and at least one video output of which is connected to the picture tube, the outputs of the vertical and horizontal scanning generators are connected to the corresponding deflecting system, and detector of the contours of the reproduced image, the input of which is connected to the video output of the receiver-amplifier unit, characterized in that an electronic switch is inserted into it, the input and output to torogo respectively connected to the output of the detector circuit and the input of the focusing system of the kinescope.  2. The TV according to claim 1, characterized in that a luminance distortion corrector is introduced into it, wherein all the video outputs of the receiver-amplifier unit are connected to the signal inputs of the luminance distortion corrector, the output of the reproduced image contour detector is connected to the control input of the luminance distortion corrector, and the corrector outputs luminance distortion connected to the tube.  3. The TV according to claim 2, characterized in that the luminance distortion corrector is made in the form of identical luminance distortion correctors, the number of which is equal to the number of video outputs of the receiving-amplifier unit, each luminance distortion corrector containing the first and second electronic keys, the signal inputs of which are connected between themselves and are the input of the corrector of luminance distortions, the outputs of the first and second electronic keys are connected to the corresponding inputs of the analog adder, the comparator and inverter are connected in series OR, whose output is connected to the control input of the first electronic key to the control input of the second electronic key connected to the output of the comparator, which is connected to the input of the detector circuits of the reproduced image, the analog adder output is connected to the kinescope.

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