RU2161872C2 - Video information reproducing device - Google Patents

Abstract

FIELD: data display on picture tube screen. SUBSTANCE: device has receiver-amplifier unit whose frame and line sync outputs are connected, respectively, to frame generator and to main-line generator; video output of receiver-amplifier unit is connected to picture tube whose line and frame deflection coils are connected through their respective output transformers to output stages of frame, main- line, and correcting-line generators; input of the latter is connected to video output of receiver-amplifier unit through series-connected reproduced-image outline detector and to threshold unit. EFFECT: improved sharpness of reproduced-image outline, facilitated implementation. 4 cl, 5 dwg

Description

 The present invention relates to techniques for reproducing images on a kinescope screen in an interlaced or interlaced decomposition mode and can be used in television receivers, monitors for applied television systems, and in raster displays.

 A device for reproducing video information according to US Pat. US N 2678964, containing a receiving-amplifying unit, frame generators, main horizontal and corrective horizontal scanning, a kinescope with a deflecting system and a detector for the contours of the reproduced image. The sharpness of the image in the known device is ensured by slowing down and accelerating the speed of line scanning of the electron beam on the screen of the kinescope due to the additional line deflecting field created by the corrective horizontal scanning generator at time points corresponding to the reproduction of the image contours.

 The disadvantage of the analogue is the low degree of sharpening of the image due to the non-rectangular shape of the signal generated by the detector of the image contours. Since the duration of this signal is equal to the duration of the fronts of the video signal from which it is generated, and this signal has a complex shape containing several half-waves of different signs, the scanning beam does not stop for the entire duration of the front of the video signal, but only a small part of it. Another disadvantage of the analogue is the great complexity of its implementation, associated with the need to change the design of the kinescope or deflecting system.

 A device for reproducing video information according to US Pat. US N 4080628, containing a receiving-amplifying unit, frame generators, main horizontal and corrective horizontal scanning, a kinescope with a deflecting system and a detector for the contours of the reproduced image. In the loop detector of the reproduced image, the output signal is generated as a result of differentiation of the video signal, its push-pull limit, summing of the limited signal with the original video signal and subsequent re-differentiation of the resulting sum. This signal through the output stage of the corrective horizontal scanning generator is supplied to the lower case deflecting plates or additional lower case deflecting coils.

 The disadvantage of the analogue is the low degree of sharpening of the reproduced image, due to the non-rectangular shape of the signal at the output of the image contour detector, as a result of which the scanning beam slows down its movement only for a small part of the duration of the edges of the video signal, as well as the great complexity of its implementation, due to the need to change the design of the picture tube or deflect system.

 The closest analogue is a device for reproducing information according to US Pat. US N 5036401, comprising a receiving-amplifying unit with a frame sync output connected to a frame scan generator, with a horizontal sync output connected to a main horizontal scan generator, a video output connected to a picture tube, and a deflecting system, to a frame deflecting coils of which a frame scan generator is connected, a horizontal horizontal oscillator is connected to the horizontal deflecting coils, and a horizontal horizontal scan generator is connected to the additional horizontal deflecting coils. To the input of the corrective horizontal scanning generator, the video output of the receiver-amplifier unit is connected through a series-connected detector of the reproduced image contours and a threshold unit. In addition, this device contains correctors of brightness and geometric distortion of the image due to the stop of the beam when playing its contours. The advantage of the prototype is the ability to significantly (approximately double) sharpen the reproduced image by completely stopping the scanning beam for the full duration of the edges of the video signal.

 The disadvantage of the prototype is the great complexity of its implementation, associated primarily with the introduction into the deflecting system of additional lower case deflecting coils. In addition, a geometrical distortion corrector is very difficult to implement in the prototype, the functioning algorithm of which requires the use of wideband delay lines for the horizontal scanning period in the device (not only in the geometrical distortion corrector), which are also difficult to implement. The implementation difficulties listed above ultimately reduce the quality of the reproduced image.

 In the present invention, the problem of simplifying the implementation of the principle of stopping the scanning beam for the full duration of the edges of the video signal proposed in the prototype is solved by minimizing the alteration of the blocks used in the video information reproducing devices, thereby ensuring a corresponding increase in image quality.

 The problem is solved in that in a video information reproducing device containing a receiving-amplifying unit, the frame and horizontal sync outputs of which are connected respectively to a frame scanning generator and to a horizontal scanning generator, the video output of the receiving and amplifying block is connected to a picture tube, to the deflecting coils of which through its output transformers connected output stages of vertical and horizontal scanning generators, as well as a horizontal scanning generator connected to the video the move receiving-amplifier unit via the series-connected detection circuits reproduced image and a block threshold, the output stage of the generator horizontal correcting connected to the primary winding of the line output transformer of the generator main line scanning.

 The problem is also solved by the fact that in the device for reproducing video information, the horizontal output transformer is made in the form of an autotransformer.

 The problem is also solved by the fact that a paired pulse shaper is inserted into the video information reproducing device, which is connected between the output of the threshold block and the input of the corrective horizontal scanning generator.

 The problem is also solved by the fact that at least one luminance distortion corrector is inserted into the video information reproducing device, which is connected between the video output of the receiver-amplifier unit and the picture tube, and the output of the dual pulse shaper is connected to the second input of the luminance distortion corrector.

 The distinguishing features listed above are significant because their absence does not allow us to solve the problem, and their presence, on the contrary, provides its solution. Indeed, the connection of the output stage corrective horizontal scanning ultimately to the same deflecting coils, which are loaded with the main generator horizontal scanning, allows you to use existing picture tubes and deflecting systems, which greatly simplifies the implementation of the inventive device for playing video information. The introduction of the paired pulse shaper into the inventive device eliminates the use of a difficult to implement geometric distortion corrector, as well as broadband delay lines for the horizontal scanning period, which almost completely removes the remaining difficulties of implementing the principle of stopping the scanning beam proposed in the prototype for the full duration of the video signal fronts. And the inclusion of a corrector of luminance distortions in the proposed manner allows for a simplified circuit of the device to provide high image quality.

The invention is illustrated by drawings, which depict:
in FIG. 1 - an example implementation of the inventive device based on a monochrome picture tube;
in FIG. 2 is a simplified schematic diagram of the connection to the line output autotransformer of the output stages of the main line and corrective line scan;
in FIG. 3 is a diagram explaining the implementation of the inventive device shown in FIG. 1;
in FIG. 4 is an example of implementation of a pair of pulse shapers;
in FIG. 5 is another example of implementation of a pair of pulse shapers.

 The inventive video information reproducing apparatus, the functional diagram of which is shown in FIG. 1, contains a receiving-amplifying unit 1 (for example, in relation to a monochrome television broadcasting receiver, it includes a high-frequency amplifier, a frequency converter, an intermediate-frequency amplifier, a video detector, a video amplifier, a clock selector, and other nodes), the frame sync output of which is connected to the generator 2 vertical scan (performed in a known manner), horizontal sync output is connected to the generator 3 of the main horizontal scan (also performed in a known manner), and the video output through the corrector 4 brightness distortions (made, for example, on the basis of an analog adder) is connected to the picture tube 5. In addition, the video output of the receiver-amplifier unit 1 through a detector 6 of the reproduced image circuits (made, for example, in the form of a series-connected differentiator and a push-pull rectifier) and a threshold block 7 (for example, in the form of a comparator) is connected to a pair former (meaning a pair - the first pulse to stop the horizontal scan and the next pulse to return to the standard scan) pulses (note The implementation implementation of which is shown in FIG. 4 and 5). The output of the shaper 8 of the paired pulses is connected to the generator 9 corrective horizontal scanning (for example, in the form of series-connected integrator and output lamp, the same as in the generator main horizontal scanning) and the second input of the corrector 4 brightness distortion. The frame scan generator 2 is loaded on the frame deflection coils 10, and the main line 3 generators and the corrective line 9 scans through the output line transformer 11 (in most cases this is, as shown in Fig. 2, an autotransformer) are loaded on the line deflection coils 12.

 In FIG. 2 shows a simplified schematic diagram of the connection of the output lamp 13 of the generator 9 corrective horizontal scan to the standard output stage of the generator 3 of the main horizontal scan. The diagram also shows the output lamp 14 of the output stage of the main flyback generator 3, a damping diode 15 and a high-voltage rectifier diode 16, as well as a voltage boost capacitor 17 and horizontal deflection coils 12 connected to the autotransformer 18 in the usual way. Moreover, with respect to the output lamp 13 of the generator 9 corrective horizontal scan lowercase deflecting coils 12 are included with a transformation ratio greater than unity.

 The pair pulse generator 8 shown in FIG. 4, contains an analog subtractor 19, to the two inputs of which are connected two monovibrators 20, 21, the inputs of which are combined.

 The pair pulse generator 8 shown in FIG. 5, contains an analog subtractor 22, the mono-vibrators 23, 24 are connected to its two inputs. The first inputs of both mono-vibrators are combined and connected to the output of the threshold unit 7. The outputs of both mono-vibrators 23, 24 are also connected to the two inputs of the AND circuit 25, whose output connected to the low-pass filter 26 and the counter 27. The output of the low-pass filter 26 through the limiter 28 is connected to the numerator input of the analog divider 29. The output of the counter 27 through the digital-to-analog converter 30 and the sampling and storage unit 31 is connected to the Znamenate input "analog divider 29. To the control input of the node 31 of the selection and storage is connected to the clock output of the receiving-amplifier unit 1, which is connected to the input" Reset "of the counter 27 through a monovibrator 32.

 Other implementations of the claimed device are possible, differing in the different implementation of the nodes included in it (for example, using a color picture tube, implementation of the output stage on transistors or thyristors). In particular, a pair of pulse shapers can be implemented on the basis of micro-computers, which will allow it to use more advanced information conversion algorithms.

 The inventive video information reproducing apparatus, 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 a device on a monochrome picture tube - one; in devices on a color picture tube - at least two). Frame and line sync pulses supplied respectively to the generators of frame 2 and main line 3 sweeps ultimately ensure the formation of frame-like currents of frame line frequency in the frame 10 and line 12 deflecting coils. Under the influence of these currents, an interlaced or progressive raster is formed on the screen of the tube 5 by its electron beam. And the video signal coming from the receiving-amplifying unit 1 to the kinescope 5 provides modulation of the electron beam in density and, accordingly, 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 5. In this way, on the screen of the tube 5, the transmitted image is played. But since the fronts arriving at the kinescope 5 video pulses, due to the limited bandwidth of the communication channel, as well as the limited resolution of the transmitting television tube have a finite duration, this duration, multiplied by a constant line scan speed, gives the corresponding area on the screen of the kinescope 5 blur, even if the resolution of the tube 5 would be infinitely large. In the claimed device, this blur zone is proposed to be reduced to a value determined only by the resolution of the tube 5, i.e. about twice, by completely stopping the beam for the entire duration of the reproduction of portions of the image with rapid changes in brightness, for short called contours. This result is achieved by using an additional, so-called corrective horizontal scan, which, at the moments of image contours playback, generates a sawtooth current in the lowering deflecting coils 12, which is equal in magnitude but opposite in polarity (see Fig. 3d) to the sawtooth current generated in the same deflecting coils 12 by the generator 3 of the main horizontal scanning (in Fig. 3d dashed line). Therefore, during the reproduction of the image contours, the resulting deflecting current (in Fig. 3D by a solid line) in the lower-case deflecting coils 12 remains constant, and the electron beam on the screen of the tube 5 stops. But so that there are no geometric distortions, i.e. all the lines of the raster had the same length, and all the contours of the image displayed on the screen of the kinescope 5 remained in place, the inventive device proposes to immediately move the beam along the screen of the kinescope 5 to the next same length of time at twice the speed of the kinescope 5 (see Fig. 3d). Therefore, after a time interval equal to twice the duration of the edges (see Fig. 3a) of the reproduced image, the scanned electron beam reaches the position (see Fig. 3d) that it would occupy if only the main horizontal scan was used. The signal (Fig. 3c), necessary for generating such symmetrical sawtooth pulses in the generator 9 of the corrective horizontal scan (Fig. 3d), is generated in the shaper 8 of the paired pulses, the form of which, generally speaking, may be different depending on the corrective pulse generator used in the generator 9 line scan of sawtooth generator circuit. For example, the durations of both paired pulses can be the same and equal to the duration of the input pulse (Fig. 3b) generated in the threshold block 7, and the moments of their appearance should correspond to the leading and trailing edges of the input pulse. The difficulty here lies in the fact that the pulses of the absolute value of the derivative of the video signal generated in the detector 6 of the contours of the reproduced image have an unstable range (for example, depending on the contrast of the reproduced image) and duration (depending, for example, on the source of the information signal used, i.e. on the degree of its perfection). Therefore, the duration of the pulses generated in the threshold block 7 (Fig. 36) of a constant value may turn out to be unstable. But to ensure maximum efficiency of the generator 9 corrective horizontal scanning, it is necessary that the trailing edge of the leading edge and the leading edge of the rear of the pair of pulses (Fig. 3B) coincide. These circumstances should be taken into account when choosing a specific implementation of the shaper of 8 pair pulses.

 In FIG. Figure 2 shows one of the possible options for coordinating the operation of the main line 3 generators and the corrective line 9 scans loaded on the same deflecting coils 12. As can be seen, the output lamp 14 of the main line scan generator, damping diode 15, high-voltage rectifier 16 and voltage boost capacitor 17 connected to the autotransformer 18 in the usual way. And the output lamp 13 (for simplicity, it can be the same as lamp 14, but it is better to use it less powerful to improve the temperature regime of the claimed device) with respect to the deflecting coils 12 is connected with a transformation coefficient greater than unity. This is beneficial for several reasons: firstly, the parasitic output capacity of the lamp 13, connected in parallel with the deflecting coils 12, with this inclusion is insignificant; secondly, the voltage pulses during the flyback on the anode of the lamp 13 are small; thirdly, with this inclusion it is easier to coordinate the current modes of the lamps 13 and 14.

 The simplest implementation of the pairwise pulse generator 8 shown in FIG. 4, works as follows. In monovibrators 20 and 21, leading and trailing edges of the input pulse (Fig. 3b) form pulses of the same magnitude and of the same (constant) duration. In the subtractor 19 of them, a pair of bipolar pulses is formed (Fig. 3c). Despite its simplicity, this scheme with respect to television receivers allows you to get quite satisfactory results.

 A more complex implementation of the pair pulse generator 8 shown in FIG. 5 provides automatic adjustment of the duration of paired pulses, maintaining its equality of the duration of the input pulses (i.e., this circuit is more suitable when used in applied television, for example, for reproducing images transmitted by small-sized television cameras). The output pair pulse (Fig. 3c) here is formed in the same way as in the previous case. And for automatic adjustment of their duration by the logic circuit “I” 25, a pulse is formed corresponding to the conjunction of pulses generated by monovibrators 23, 24, and by all other nodes the duration of this pulse is stabilized at a certain minimum level. To do this, a negative feedback circuit is connected to the second inputs of the monovibrators, containing a low-pass filter 26 and a limiter 28 connected in series. To ensure that this feedback does not depend on the number of circuits along the line, an analog divider is added to the circuit, to the input of which the "Numerator" is connected the output of the limiter 28, and to the input of the "Denominator" is a series-connected counter 27, a digital-to-analog converter 30, and a sampling and storage unit 31. The monovibrator 32 is introduced in the circuit so that the analog value proportional to the number of contours along the line at the very end of the forward horizontal scan is stored in the sampling and storage unit 31.

 The introduction into the inventive device for reproducing video information of the distinguishing features listed in the claims makes it possible to significantly simplify the implementation of the principle of the complete stop of the electron beam on the kinescope screen proposed in the prototype for the entire time the image contours are reproduced and thereby approximately double (the specific gain depends on the ratio of the resolving power of the used kinescope and quality incoming to the receiving-amplifying unit of initial information) increase the horizontal sharpness images, i.e. to obtain results that are practically consistent with the ultimate visual acuity of a person.

Claims (4)

 1. A video information reproducing device comprising a receiving-amplifying unit, the frame and horizontal sync outputs of which are connected respectively to a frame scanning generator and to a horizontal scanning generator, the video output of the receiving-amplifying unit is connected to a picture tube, and output stages are connected to its horizontal and frame rejecting coils through its output transformers vertical and horizontal line-scan generators, as well as a horizontal line-scan generator, connected by input to video dy receiving-amplifying unit via a series connected circuit of the reproduced image detector and threshold unit, characterized in that the output stage of the generator horizontal correcting connected to the primary winding of the line output transformer of the generator main line scanning.  2. The video playback device according to claim 1, characterized in that the lowercase output transformer is made in the form of an autotransformer.  3. The video information reproducing device according to claim 1 or 2, characterized in that a pair of pulse shapers is inserted into it, included between the output of the threshold block and the input of the corrective horizontal scanning generator.  4. The video information reproducing apparatus according to claim 3, characterized in that at least one luminance distortion corrector is inserted into it and is connected between the video output of the receiver-amplifier unit and the picture tube, and the output of the dual pulse shaper is connected to the second input of the luminance distortion corrector.

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