SU803122A1 - Correcting signal shaping method - Google Patents

Description

(54) METHOD OF FORMING CORRECTIVE

SIGNAL

The invention relates to radio engineering and can be used in broadcast and applied television. A known method of generating a correction signal for aligning the unevenness of the television (TV) image, based on dividing the TV image into sections and sampling the correction signal for each of the image sections, followed by simultaneous reading of the sequences of samples in the frame scan direction synchronously with the scan of the corrected image, smoothing each from sequences of samples, sequential reading of smoothed sequences In the direction of line scanning with subsequent secondary smoothing 1. However, in a known method, during the execution of a forg smoothing operation: a correcting correction signal inevitably receives a delay in time comparable to the duration of scanning one image section in each of the scanning directions, which leads to deterioration corrected image. The aim of the invention is to eliminate the time error of the formation of the correction signal. To do this, in a known method of forming a correction signal to align the unevenness of the TV image, a reading of a sequence of samples in each of the scanning directions is advanced ahead of the scanning of the corrected image by a time equal to the scan duration of one section of the corrected image in the corresponding direction, and the initial sample of each sequence is read t in the blanking interval, and the last sample is read until eduyuschego blanking interval, the smoothing for each of the scan directions is performed so that each extremum smoothed sample with 5padal with its respective middle portion of the image, and in the blanking intervals of the amplitude sequence of samples equate initial amplitude corresponding sample sequence.

Removing from the memory the sequences of samples of the correction signal ahead of the frame scanning process of the image to be corrected provides a time reserve for the smoothing operation in the frame scanning direction. The delay of the samples of the correction signal compensates for the advance introduced, with the result that the smoothed sequences of the samples of the correction signal are aligned with the video signal to be corrected in the direction of vertical scanning.

Determining the amount of advance when extracting a correction signal from the memory equal to the scan duration of one image area in the frame scanning direction allows the same auxiliary pulse to be used to mark a specific image area and to remove a correction signal from the sample memory. , except for the first and last samples in each of the sequences (for image areas adjacent to the upper and lower edges of ra).

The first sample is taken out of the memory earlier than the scanning of the corresponding part of the image, i.e. in the frame interval.

The peculiarity of the last sample is that after the start of scanning the image area adjacent to the bottom edge of the raster, the regular cycle of extracting samples from the memory is complete, because there is no correction signal sample for the image area outside the bottom edge of the image . This is near the bottom edge of the raster. In order to minimize the errors, the last sample was re-extracted during the scan time interval of the corresponding image area.

For the possibility of obtaining equal smoothing products for all areas, each smoothing process leads to its original state, which is characterized by the absence of transients, in the frame grading intervals, which excludes the effect of the last sample from the previous field on the formation of a correction signal in the subsequent field, as well as allows to obtain a smoothing product from the first sample, which is equivalent to the products of the smoothing of other samples.

By gating the smoothed sequences of samples of the correction signal in the order of dividing the image in the direction of horizontal scanning, a sequence of pulses is obtained with a period equal to the horizontal scanning period. Continuing gating of smoothed sequences of samples for image areas adjacent to the right and left edges of the raster, as well as entering an advance in gating relative to the horizontal scanning process under the underlying image correction for the scanning time of one image section in the horizontal scanning direction, a sequence of pulses is obtained that is statistically similar to the output from

memory sequences of corrective signal samples. As a result, a geometrical alignment of the generated correction signal with the image to be corrected in the direction of the horizontal scanning is achieved.

The drawing shows a structural electrical circuit of the device that implements the proposed method.

The correction signal generating device comprises memory locations 1-12,

0 combined in groups of three, generator 13 pulses, readings, blocks 14, 15, 16 and 17 leading to the initial state in the vertical blanking intervals, smoothing filters 18, 19, 20, 21 in the direction of vertical scanning, gating unit

 22, a gating pulse generator 23, a resetting unit 24 in the horizontal thickening intervals, a smoothing filter 25 in the horizontal scanning direction.

0 The device operates as follows.

The spatial arrangement of memory cells 1-12 corresponds to the division of the image into sections. Thus, cell 1 stores the value of the correction signal for the upper left portion of the image, cell 4 stores a sample of the correction signal for the upper right portion of the image, etc., respectively, combined into one group

the memory cells 1, 5, 9 recorded samples of the correction signal for the image areas near the left edge of the raster, etc.

The output circuit of the memory cells of one group is common, and a signal recorded in one of the cells appears when a read pulse is sent to this cell from the generator 13, which is synchronized by the external clock pulses arriving at its input. The removal of samples of the correction signal corresponding to the image areas equally located in the frame scanning direction is carried out simultaneously in all groups of memory cells.

5 The combined output circuits of the memory cells of each group are connected to the inputs of the smoothing filters 18-21 in the direction of the vertical scanning, as well as to the signal inputs of the blocks 14 - 17 leading to

the initial state in the intervals of the personnel damping.

Each smoothing filter 18-21 is implemented on the basis of an operational amplifier and is designed so that its pulse response is symmetrical in time; the latter eliminates the influence of the framing direction on the type of the correction signal being formed to the outputs of the smoothing filters 18-21 connected to the output circuit of electronic keys included in blocks 14-17. Beyond the lock intervals, all keys are locked. In the frame grating intervals, a positive pulse, for example, arriving at the control input of block 14, puts the electronic keys of the latter into a saturation state, while the output circuits of block 14 become equipotential to the signal input and output of the smoothing filter 18. After the control pulse ends, the electronic keys of the block 14 are closed, and the potential of the output circuit of the smoothing filter 18 begins to smoothly change in the direction of the value that is fed to its signal input, and characterizes the next section from swallows. Thus, a smoothed sequence of samples is formed. Other smoothed sequences of samples of the correction signal are formed by blocks 15-17 and smoothing filters 19-21, which operate similarly.

The outputs of the smoothing filters 18-21 are connected to the inputs of the gating unit 22, which is a switch with several inputs and one output controlled by pulses from the generator 23 of gating pulses, which in turn is controlled by synchronizing pulses received at its input from an external clock generator. The gating pulses at the output of the generator 23 are distributed in time, so that each of the n input signals of the gating unit 22 passes to the output during the n part of the image scanning length in the horizontal scanning direction, except for the smoothed sequences of corrective samples coming from the outputs of the smoothing filters 18 and 21. The first of them corresponds to a group of image areas adjacent to the left edge of the raster, and passes to the entrance of the gating unit 22 during horizontal thickening intervals. The second of them corresponds to the group of image areas adjacent to the right edge of the raster, and its arrival at the output is not interrupted until the next horizontal blanking interval. At the same time, the output of the gating unit 22 forms a sequence of pulses, similar to a sequence of samples of the correction signal at the common outputs of groups of memory cells 1-12, and acting on the horizontal time base.

The smoothing filter 25 and block 24 are similar to smoothing filters 18-21 and blocks 14-17. The smoothing filter 25 differs from the smoothing filter 18 only in that the time constants of the filter chains of the smoothing filter 25. choose so many times less than the time constant of the filter chains of the filter 18, how many times the scanning time of one image section in the horizontal scanning direction is smaller than in the direction of the frame scan. The generated correction signal is removed from the output of the smoothing filter 25.

Thus, performing all operations using the device described allows generating a correction signal in full time correspondence with the video signal to be corrected.

Claims (1)

Invention Formula 0 A method of generating a correction signal for aligning the unevenness of a television image, based on dividing the television image into portions and sampling the correction signal for each of the image regions and then simultaneously reading the sample sequences in the direction of the frame scan synchronously with the scan of the corrected image, smoothing them separately each time. from sequences of samples, sequential reading of smoothed sequences samples in the direction of the line scan with subsequent secondary smoothing, characterized in that, in order to eliminate the time error of the formation of the correction signal in the time correspondence with the video signal to be corrected, read the sequence of samples in each of the scanning directions produced ahead of the sweep of the corrected image for a time equal to the duration of scanning one section of the corrected image in the corresponding direction, the initial sample of each sequence is read in the blanking interval, and the last sample is read to the subsequent blanking interval, with smoothing for each from the directions of the sweep perform so that the extremum of each smoothed sample coincides with the middle of the corresponding part of the image, and in the blanking intervals the amplitude of the sequence of samples equals the amplitude of the initial sample of the corresponding sequence. Sources of information taken into account in the examination 1. UK patent number 1334044 ,, class. H 4 F, pub. 1973 (prototype).