RU2009620C1 - Tv signal adaptive restoring device - Google Patents

Abstract

FIELD: TV engineering. SUBSTANCE: device has switch, sync pulse selector, clock pulse generator, control unit, delay unit, videosignal sampling six formers, unnoted videosignal four calculators, videosignal values four calculators, averaging unit, lines sequence former. Videosignal selecting former has three delay members and five delay members connected in series. EFFECT: improved precision of adaptive restoration. 3 dwg

Description

 The invention relates to television technology and can be used in broadcast and applied television (TV) systems with temporary compression of the communication channel to restore the TV signal.

 A device for adaptive restoration of a television signal containing a key, blocks of delay elements per line, delay element, blocks of line samples, clock selector, blocks of video signals, adder, clock generator (GTI), blocks for selecting the direction of extrapolation, extrapolation blocks, control unit, weighted averaging block, line sequence generation block.

 The device operates as follows.

 A video signal is received from the communication channel to the input of the device, which is the sum of two video signals (AC) from different TV cameras in the form of their alternation in the AC groups of three adjacent lines. Then each aircraft is presented in summary form by a periodic sequence of aircraft groups of adjacent rows. Each group of this sequence is separated from the other by the time intervals of the aircraft transmission from another camera, and the video signals of the original camera are lost. Upon receipt of the total aircraft at the input of the recovery device, one of the aircraft is allocated from it, in which the lost (missed) aircraft are restored.

 Recovery is carried out by calculating the missed aircraft according to the approximation formulas accepted. From the periodic sequences of the adopted aircraft groups and restored, a common, restored aircraft is formed.

 The disadvantage of this device is the low accuracy of FA recovery and the inability to restore missing samples when the sampling structure coincides with the image structure.

 A device for adaptive restoration of a TV signal containing a key, a clock selector, a clock pulse generator, a control unit, a delay unit, a key unit, video signal samplers, extrapolation direction selection units, BC value calculation units, a string sequence generation unit, a delay element and an adder.

 The device operates as follows.

 From the output of the communication channel to the input of the device, the aircraft arrives, which is the sum of two TV channels (two different TV cameras) in the form of their sequential alternation in groups of three adjacent lines. The device is focused on the reception of one of the TV channels, while groups of lines of the corresponding TV channel are highlighted and lost (missed) aircraft are restored from them. Recovery is carried out by calculating the BC of the missed lines from the BC samples of the received rows or from the neighboring neighboring BC samples of the given restored string using approximation formulas. From the received and restored TV lines, a continuous TV signal is generated.

 The fuel assembly enters the inputs of the key and selector. The selector selects clock pulses (SI), which are fed to the input of the generator and the input of the control unit for the formation of control signals (US). Clock pulses from the generator are fed to the input of the delay unit, the inputs of the shapers of the aircraft sample and the input of the delay element.

 A fuel assembly, which is a gated gate along the aircraft lines, commuted by the control signal passes to the key output, and is fed to the input of the delay unit. In the block delays are combined in time synchronously and in phase necessary for the restoration of aircraft.

 At the time of combining the aircraft, the control signal from the third output of the control unit allows the passage of these aircraft through the key block. At the same time, the aircraft of adjacent rows of the first group in a natural sequence through the delay element arrive at the input of the adder. The unit for calculating the values of the video signals extrapolates (interpolates) the corresponding current samples of the reconstructed aircraft. Aircraft samplers form samples of samples along the vertical and diagonal directions of extrapolation and interpolation. From the outputs of the shapers of the samples of video signals, samples of samples are sent to the inputs of the extrapolation direction selection block, the output of which is samples of samples with a minimum derivative value. In the blocks for choosing the direction of interpolation, the final choice of the direction of interpolation (extrapolation) is made, from the outputs of which the samples with the minimum derivative are taken. In the blocks for calculating the values of the video signals, samples of samples with a minimum derivative in the selected directions are processed and the missing groups of lines are restored. From the outputs of the blocks for calculating the values of the aircraft, the reconstructed aircraft arrive at the input of the line sequence forming unit. In this block, under the influence of CSS, the aircraft is formed in the form of a sequence of aircraft of restored lines. The sun of the first restored line passes to the input of the adder.

 The disadvantage of this device is the low accuracy of the restoration and the inability to restore missing samples, the structure of which coincides with the sampling structure.

 The purpose of the invention is improving the accuracy of adaptive recovery of fuel assemblies.

 The goal is achieved in that in an adaptive recovery device of a fuel assembly containing a key and a delay unit connected in series, as well as a clock selector, the inputs of the clock and key selector are combined and represent the device input, the first, second and third video samplers, the information inputs of which are connected to to the corresponding outputs of the delay unit, the control inputs of the aircraft samplers are combined with each other and with the control inputs of the key and the clock selector and with the first the control input of the shaper of the string sequence and connected to the output of the clock generator, the control input of which is combined with the control input of the control unit and connected to the output of the clock selector, while the outputs of the first, second and third shapers of the aircraft samples are combined and connected to the corresponding inputs of the first and second blocks selecting the direction of extrapolation (interpolation), the outputs of which are connected to the corresponding inputs of the first and second blocks for calculating the values of the aircraft; contains the third and fourth blocks for selecting the direction of extrapolation (interpolation); and also a block for generating a sequence of lines, the second control input of which is combined with the second control input of the key and connected to the output of the control unit, while the output of the block for generating a sequence of lines is the output of the device; introduced the fifth and sixth blocks of the formation of aircraft samples, the control inputs of which are combined and connected to the output of the clock generator, other information inputs of which are connected to the corresponding inputs of the delay unit, while their outputs are combined and connected to the corresponding inputs of the third and fourth blocks of choosing the direction of extrapolation ( interpolation); as well as a weighted averaging device, the inputs of which are connected to the corresponding outputs of the BC value calculation blocks, the output of which is connected to the first input of the string sequence generator, the second and third input of which are connected to the corresponding outputs of the third and fourth video signal conditioners.

 In FIG. 1 shows a structural electrical diagram of the proposed device; in FIG. 2 - structural electrical circuits of the shapers of the aircraft; in FIG. 3 is a spatial diagram showing the possible directions of the calculation when interpolating and extrapolating elements (samples) that were missed during transmission.

 The device contains a key 1, a clock selector 2, a clock generator 3, a control unit 4, a delay unit 5, the first 6, second 7, third 8, fourth 9, fifth 10 and sixth 11 video samplers, the first 12, second 13, third 14 and fourth 15 transmitters of the missed video signal, blocks 16-19 calculation of the values of the sun, block 20 averaging, block 21 signal generation. Shaper 6 (7,10 and 11) is a series-connected delay elements 22-24, and the input of element 20 is simultaneously the input of shaper 6 (7,10 and 11) (Fig. 2a), and the outputs of elements 23 and 24 form a shaper group 6 (7, 10 and 11). Shaper 8 (9) is a series-connected delay elements 25-29 (Fig. 2b), and the input of element 25 is the input of shaper 8 (9), and the outputs of elements 25, 28, and 29 and the input of element 25 form a group of outputs of shaper 8 ( 9). All elements 22-29 delay shapers 6-11 have control inputs, which are interconnected. At the same time, the key 1 and the delay unit 5 are connected in series in the device, the inputs of the clock selector 2 and the key are combined, the first 6 is the sixth 11 shapers, the information inputs of which are connected to the corresponding outputs of the delay unit 5, the control inputs of the formers are combined with each other and with the control inputs of the key 1, block 5 delay and with the first control input of block 21 and connected to the output of the generator 3, the control input of which is combined with the control input of block 4 and connected to the output of the selector 2 SI, while the outputs of the forms The drivers 6-8 are combined and connected to the corresponding inputs of the first and second calculators 12, 13, and the combined outputs of the drivers 9-11 are connected to the corresponding inputs of the third 14 and fourth 15 computers, the outputs of the first 12 - fourth 15 subtractors are connected respectively to the inputs of the first 16 - the fourth 19 blocks, the outputs of which are connected respectively to the inputs of the weighted averaging unit 20, the output of which is connected to the first information input of the line sequence forming unit 21, the second and third information whose inputs are respectively connected to the outputs of the third 8 and fourth 9 shapers, the second control input of block 21 is combined with the second control input of key 1 and connected to the output of control unit 4.

 The device operates as follows.

 At the input of the device from the communication channel, the aircraft enters, which is the sum of two TV channels (two TV cameras) in the form of their sequential alternation in groups of two transmitted and missed samples. The phase of these groups in rows is changed every two lines to the opposite. T. about. groups of transmitted elements in the same channel from two adjacent lines with the same phases of these groups are four samples, and their location in the frame structure is a checkerboard pattern, where the transmitted groups alternate with the same missed ones (Fig. 3).

 The device is focused on the reception of one of the TV channels, while the groups of samples of the corresponding TV channel are allocated and lost (missed) video signals are restored from them.

 Recovery is carried out by calculating the BC of the missed samples according to the approximation formulas adopted. A continuous TV signal is generated from the received and restored samples.

 The sun arriving at the input of the recovery device is supplied to the inputs of the key 1 and the selector 2 of the clock pulses. The selector 2 selects from the input BC-clock pulses, which are fed to the input of the generator 3 and the input of block 4 to form control signals from them). Clock pulses from the output of the generator 3 are fed to the first control input of the key 1, to the control input of block 5, to the control inputs of the shapers 6-11 and to the first control input of the block 21.

 Under the action of the control signals coming from the output of the control unit 4 and the output of the GTI unit 3 to the second control input of key 1, the TV signal is transmitted to the output of key 1, which is an aircraft with a structure where the lines are a sequence of missed and transmitted samples (two reference), and the phase of these sequences changes every two lines to the opposite (Fig. 3). This gated by groups of elements and with a changing phase every two lines of the aircraft is fed to the input of the delay unit 5, which is designed to delay six adjacent lines.

 At the moment of the appearance of the aircraft of the first line at the last output of block 5, the corresponding aircraft of the remaining five lines (in-phase and synchronously delayed) participating in the restoration appear on the remaining outputs of the block.

 Delayed synchronously and in-phase signals of six adjacent lines in the appropriate order are fed to the inputs of the shapers 6-11.

 Shapers 11, 10, 7, and 6, delaying incoming aircraft samples from lines 1, 2, 5, and 6, respectively, form samples of samples in the vertical direction of interpolation and extrapolation.

Shapers 8 and 9 form samples of samples from the 3rd and 4th rows in the horizontal direction of interpolation and extrapolation. Each of the shapers 6-11 is a set of delay elements per image element (count) (Fig. 2). The implementation of their internal connections, outputs is determined by the selected sets of samples forming the corresponding samples, which are shown in FIG. 3, where 1,2,3 and 4 are the missing elements to be restored, X ₁ , X ₂ , X ₃ , X ₄ and X ₁ ^I , X ₂ ^I , X ₃ ^I , X ₄ ^I, respectively, horizontal and vertical directions of recovery and sampling.

Samples of samples from the outputs of the shapers 6-11, corresponding to the restoration directions X ₁ -X ₄ and X ₁ ^I -X ₄ ^I , go to the inputs of the calculators 12-15, which for each restored element of each of the restored groups passes samples of samples from minimum value of the derivative.

 In blocks 16-19, extrapolation (interpolation) of the values of the missed samples by the transmitted reference is carried out.

 Block 20, processing the samples of samples received at the input, carries out a weighted averaging of the values of the restored samples, finally calculates the values of the restored samples of the missed group of elements.

 During one line (in accordance with the control signals from the second output of block 4 and from the output of generator 3), the missing group of elements is restored in two lines — lines 3 and 4 (Fig. 3). The restored values of the elements simultaneously from two lines from the output of block 20 are fed to the first input of block 21, the reference samples of the 3rd and 4th lines come simultaneously to the outputs of the shapers 8 and 9 to the second and third inputs of the block 21. In block 21, under the action of control signals from the outputs, block 4 and generator 3 at the output, the aircraft is formed in the form of a sequence of samples of the 3rd and 4th rows with the restored samples. On this, the recovery cycle ends and a new one begins.

 As for the implementation of the device blocks, they can be implemented on the following elemental base: key 1 - K555KP11, K555TM8; selector 2 - K155ID4, K555IM 6 generator 3 - K155LA3, K555LA8, K155IE7; control unit 4 - K155IE5, K155IE7, K155KP5, K555LA8, K555LA1; delay unit 5 - R565RU5, K132RU4, K555IR23; shapers 6-11 - K555IR23, K555IR24; calculators 12-15 - interpolation K555IR23, K555IM6; blocks 16-19 - K555IR23, K555IM6, K555LP5; block 20 - K555IR23, K555IM6; block 21 - R555IP23, K555KP11, K565RU5; delay elements 22-29 - IC K555IR23. (56) Copyright certificate of the USSR N 1525943, cl. H 04 M 7/18, 1989.

Claims (1)

 DEVICE FOR ADAPTIVE RECOVERY OF A TV SIGNAL, containing a key and a delay unit in series, as well as a clock selector, the inputs of the clock and key selectors being combined and being the device input, the first, second and third video samplers, the information inputs of which are connected to the corresponding outputs of the delay unit the control inputs of the shapers of the video signal samples are combined with each other and with the control inputs of the key and with the first control input of the shapers the signal source of the string sequence and are connected to the output of the clock generator, the control input of which is combined with the control input of the control unit and connected to the output of the clock selector, while the outputs of the first, second, and third video samplers are combined and connected to the corresponding inputs of the first and second computers the video signal, the outputs of which are connected to the inputs of the first and second blocks for computing the values of the video signal, respectively, contains the third and fourth one of the missing video signal calculators, as well as a line sequence signal generating unit, the second control input of which is combined with the second key control input and connected to the output of the control unit, while the output of the line sequence forming unit is the output of the device, characterized in that, in order to increase accuracy adaptive restoration of the formation of the video signal into it introduced the fourth, fifth and sixth shapers of the samples of the video signal, the control inputs of which are combined and connected to the output of the clock generator, the other information inputs of which are connected to the corresponding outputs of the delay unit, while the outputs of the fourth, fifth, and sixth shapers of video samples are combined and connected to the corresponding inputs of the third and fourth computer of the skipped video signal, and an averaging block is introduced, the inputs of which are connected with the corresponding outputs of the video signal value calculator, the output of the averaging unit is connected to the first information input of the signal conditioner atelnosti rows, second and third informational inputs of which are connected to respective third and fourth formers outputs video samples.

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