SU1513624A2 - Differential pulsed coder of tv signals - Google Patents

Description

<p> The invention relates to computer technology and communication technology and is an improvement to the device according to the author's certificate No. 1056455. Its use in building television systems with an effective invention relates to computer technology and communication technology, and can be used in the construction of television (TV) systems with an effective encoding the TV signal and is an improvement to the well-known coder on the auth. No. 1056455. </ P> <p> The purpose of the invention is to enhance the functionality by providing adjustment of the contrast of the encoded images. </ p> <p> In FIG. 1 shows a block diagram of an encoder; in fig. 2 - functional diagram of the contrast adjustment unit; in fig. 3 - quantizer. </ P> <p> The encoder contains an analog-to-digital converter (ADC) 1, memory block 2, block 3 multipliers, first adder 4, inverter 5, second adder 6, </ p> <p> 2 </ p> <p> Doping allows you to extend the functionality by providing adjustment of the contrast of the encoded images. The encoder contains an analog-digital converter, a memory block, a multiplier block, two adders, an inverter, a module adder, a quantizer, and a coding block. By introducing a contrast adjustment node, performed on a multiplexer, a decoder, an adder, a comparator, two blocks of NOT elements, three multipliers, and a source of a constant code, the encoder provides contrasting of the encoded signal. 3 il. </ P> <p> adder 7 modules, a quantizer 8, a node 9 for adjusting the contrast and a coding block 10. </ p> <p> Node 9 adjust the contrast (Fig. 2) contains a multiplexer 11, a decoder 12, an adder 13, a comparator 14, the first 15 and the second 16 blocks of elements NOT, the first - the third multipliers 17-19 and the source 20 constant code. In addition, the first - the third inputs 21-23 and the first third outputs 24-26 of the node are marked. </ P> <p> Quantizer 8 (Fig. 3) is made on the first 27 and second 28 delay blocks and the code converter 29. The remaining blocks of the encoder are similar to those of the known encoder. </ P> <p> The principle of the encoder is </ p> <p> next. </ p> <p> zi „„ 1513624 </ p> <p> 3 </ p> <p> 1513624 </ p> <p> 4 </ p> <p> The analog video signal input to the encoder is sampled and quantized into an ADC. In the memory block, encoded groups of η eight-bit image elements are formed. For each group, three variables are calculated: the code of the average brightness of the coded group </ p> <p> _1 _ </ p> <p> η </ p> <p> 10 </ p> <p> where x; - the brightness of the v-th encoded element, the code of the half-sum of the modules of deviations x ·. from a. </ p> <p> 15 </ p> <p> <sup> a </ sup> 1 2 </ p> <p> x. · -a. </ p> <p> character matrix code </ p> <p> a. </ p> <p> 20 </ p> <p> The listed variables are quantized in a quantizer, are grouped into a code word in a coding unit, and as part of this word are transmitted to a communication channel. </ p> <p> Brightness of the ίth element Ζ; is in accordance with the following expression that the scalar product of vectors y <sub> 4 </ sub> and gives zero, orthogonality of Y, and y ^ follows. </ p> <p> If the vector y remains constant for any coded group, then the coordinates of the vector y <sub> 2 </ sub> depend on the statistics of the coded group and are determined by it. Therefore, the reduced orthogonal decomposition is adaptive, unlike deterministic orthogonal transformations, for example, Hadamard, Walsh, Haar, Fourier, etc. In deterministic transformations, only decomposition coefficients are transferred to the channel, because the basis functions are constant for the encoded element groups. </ P> <p> In the decomposition under consideration, the basis vector y <sub> r </ sub> is variable and its group is required to restore the group of elements on the receiving side. For this purpose, serves the code matrix characters. If 3; = 1, and the number of matrix units </ p> <p> 1 </ p> <p> then y, = * Ρ </ p> <p> live: </ p> <p> characters equals p. </ p> <p> Values Ζ </ p> <p> if </ p> <p> a - --2. ' nr ’</ p> <p> if </ p> <p> 3; = 1; 5. = 0, </ p> <p> (1) </ p> <p> p-order </ p> <p> 30 </ p> <p> p <p> 1 </ sup> </ p> <p> and Ζ = a, recoverable at the reception </ p> <p> where p is the number of units of code 5. </ p> <p> Variables a, and the coefficients of the adaptive orthogonal decomposition of the encoded fragment of η elements. Each coordinate of the first basis vector is equal to one. The coordinate of the second basis vector corresponding to 1 </ p> <p> x · element is </ p> <p> -1 </ p> <p> represent </ p> <p> - if χ · &gt; a ,, η ’&gt; ι ’</ p> <p> 35 </ p> <p> 40 </ p> <p> or </ p> <p> p </ p> <p> if x; </ p> <p> 45 </ p> <p> Let x ,, x <sub> 4 </ sub>, </ p> <p> Xp <sub> 4 </ sub>, ..... x </ p> <p> second baseline vectors <sub> g </ sub> </ p> <p> ......... &lt; and ,, then the first is u, and </ p> <p> 50 </ p> <p>, 1 I 1-1 -1h </ p> <p> <sup> y </ sup> 1 <sup> = </ sup> '' p 'p' <sup> ,,, </ sup> 'p' n-p '&quot;' 'n-p '' </ p> <p> side, equal to the average brightness of elements X), having a brightness, respectively, not less than and less than a,. </ p> <p> Let x, = 40, x <sub> 2 </ sub> = 30, x <sub>? </ sub> = 20 and x <sub> 4 </ sub> = 10. Then a ^ = 25 and <sub> 2 </ sub> = 20, p = 2 </ p> <p> and Ζ <sub> 1 </ sub> = 35, = 15, </ p> <p> since x ,, x <sub> 4 </ sub> > a </ p> <p> then </ p> <p> = 35 = Ζ ,, ^ - ^ =, 5 = 2 </ p> <p> The third, fourth coefficients of the analyzed adaptive decomposition, the second and third matrix of characters are calculated as follows: </ p> <table border = "1"> <tr> <td> <sup> a </ sup> "= </ td> <td> 5 ΣΊ "; </ td> <td> </ td> <td> ! : <sup> a </ sup> 4 </ td> <td> - 5 Σ I </ td> </ tr> <tr> <td> </ td> <td> X ', &gt; &lt; 34 </ td> <td> </ td> <td> </ td> <td> X; &lt; 0, </ td> </ tr> <tr> <td> </ td> <td> d -, ί </ td> <td> '1, </ td> <td> if </ td> <td> <sup> x </ sup> &lt; - Ζ,; </ td> </ tr> <tr> <td> </ td> <td> Μ - </ td> <td> </ td> <td> </ td> <td> </ td> </ tr> <tr> <td> </ td> <td> Ι </ td> <td> .0, </ td> <td> if </ td> <td> a, <x; &lt; </ td> </ tr> <tr> <td> </ td> <td> ί </ td> <td> Ί, </ td> <td> if </ td> <td> <sup> Ζ </ sup> 2 ~ <sup> x </ sup>; </ td> </ tr> <tr> <td> m </ td> <td> [= .3 - </ td> <td> </ td> <td> </ td> <td> </ td> </ tr> <tr> <td> </ td> <td> 1 </ td> <td> 0, </ td> <td> if </ td> <td> <sup> χ </ sup>; <sup> Ζ <sub> </ sup> ζ </ sub> </ td> </ tr> </ table> <p> 55 </ p> <p> Number of decomposition coefficients </ p> <p> is equal to n, and the number of variables (i.e. </ p> <p> those that need to be transferred) matrices </ p> <p> characters are (n-1). </ p> <p> 5 </ p> <p> 1513624 </ p> <p> 6 </ p> <p> The coder allows you to calculate two of the η decomposition coefficients and one matrix of characters. Experiments show that for η &lt; 16, to get a $ high image quality, you can limit yourself to transferring only two coefficients from η and one matrix of characters. Moreover, for n = 16, with the same high compression ratio of the flow, ana- lyzed adaptive orthogonal transformation allows one to obtain a higher image quality than with deterministic transformations. The joint coding 15 is based on the redundancy of a <sub> 2 </ sub> and 8 with a = 0 and the redundancy of code combinations a and a <sub> r </ sub> with a <sub> 4 </ sub> / 0 . </ p> <p> The second coefficient is a. decomposition can be represented as follows: </ p> <p> The expression in brackets represents the average contrast of the coded group. Therefore, the coefficient a <sub> r </ sub> with an accuracy of a constant factor of 2 can be considered as the average contrast of the coded group. By changing a ^ in one way or another in the way within the coded group, it is possible to change the contrast of the coded image. The adjustment (increase) of the contrast is made on the basis of the following expression: </ p> <p> r max </ p> <p> (n-p) a <sub> (</ sub> with 0 &lt; a, έ p-; d </ p> <p> p (A-ar with p - < a <sub> 4 </ sub> &lt; A, </ p> <p> (2) </ p> <p> 40 </ p> <p> where a. - maximum value of a, g max <sup> g </ sup> </ p> <p> for fixed values of a ^ and p. </ p> <p> For a coded group with values of a ^ and p, the second coefficient can vary from 0 to a <sub> 2max </ sub>. </ p> <p> Let η = 4, a, = 10 and p = 1. Then with eight-bit coded elements A = 255 and C = p- = 61. </ P> <p> η </ p> <p> Since a, = 10 &lt; C, then in accordance with (2) a ^ can vary from 0 to (η-p) a, = 30. </ P> <p> We check (2) for two values a <sub> 2) </ sub> equal to 30 and 40. For a <sub> g </ sub> = 30 &lt; = a, + </ p> <p> + - <sup> g </ sup> = 40, Ζ, = a.- - <sup> 2 </ sup> = 0. For a = 40 p "g. 1 <sub> n </ sub> _p g. </ p> <p> Ζ, = a, + ^ <sup> r </ sup> = 50, Ζ, = a --- <sup> x </ sup> = -3. </ p> <p> P Ζ- <sup> 1 </ sup> n-p </ p> <p> Since Ζ, and Ζ <sub> 2 </ sub> are the brightness values of the elements being decoded, 0 έ · έ 255. </ p> <p> Therefore, for the considered example, a <sub> 2 </ sub> cannot be equal to 40, since in this case Ζ <sub> 2 </ sub> < 0. By the expression for Ζ *, it is easy to verify that a <sub> r </ sub> cannot be greater than 30, which coincides with expression (2). </ P> <p> The encoder works as follows. </ p> <p> In ADC 1, the original analog signal is converted to a digital stream, for example, by the PCM method. In block 2 of the memory thanks to the 'digital delays </ p> <p> The stream creates a series of digital streams, each of which corresponds to one of the elements of the multi-element aperture-group of neighboring elements of the TV image. In block 3, the brightness value of each of the elements of the aperture is multiplied by the weighting factor 1 </ p> <p> -, where η is the number of simultaneously coded </ p> <p> elements. After multiplying, the elements of the aperture simultaneously arrive at the first adder 4, where by summing them, calculate the average value of brightness over the coded group. In a specifically configured device for four simultaneously coded elements, adder 4 includes three summation schemes: on the first one, </ p> <p> x, x <sub> 2 </ sub> „He hea </ p> <p> η η η η ’</ p> <p> in the third - the sum of the first and second summation schemes. </ p> <p> In the second adder 6, the average value fed through inverter 5 is subtracted from the multi-element aperture digital streams fed there from memory block 2. In the adder of 7 modules, η values of differences (x; -a,) are fed from the accumulator 6. At the same time adder 7 modules calculates the modulus of each difference (x; -a) </ p> <p> η </ p> <p> th addition of modules (x; -a,). On </ p> <p> ί "ι </ p> <p> the output of the adder 7 modules is transferred to the code of the reduced amount without the least significant bit, thereby forming the second coefficient </ p> <p> 1 <sup> l </ sup> </ p> <p> H <sup> = </ sup> 5 Σ (x, '- a,). </ p> <p> * 1 = 1 </ p> <p> 7 </ p> <p> 1513624 </ p> <p> 8 </ p> <p> In addition, at the output of the block, the p-raster code of the character matrix 8 = [δ; ^] 5ίβη (x; -a,) generated in this block is transmitted. <sub> 5 </ sub> </ p> <p> In quantizer 8, there is a delay of a <sub> 2 </ sub> and 5 for the time of quantization a &lt; in blocks 27 and 28. An eight-bit code a ^ is fed to the input of the code converter 29, which sub-] θ is thrown there into a coarse quantization (uniform) to reduce the number of quantization levels. </ p> <p> Code a ,, a <sub> g </ sub> and 5 synchronously from the output of the quantizer 8 are transmitted to the node, 5 9 adjust the contrast of the encoded images. Code 5 from the inputs 23 enters the decoder 12, from which the code p is read (the code of the number of units of the matrix of characters). This code is in block 19 20 </ p> <p> multiplied by code - from source 20 <sup> P </ sup> A </ p> <p> and the result of the multiplication (p -) transmits </ p> <p> to comparator 14, to the second input (which receives the code a * from the inputs </ p> <p> 25 </ p> <p> 21. The result of comparing a, with p- in </ p> <p> I </ p> <p> the quality of the control signal is fed to multiplexer 11, to one of the inputs of which the value a, (η-p), generated using block 17, is fed. To the second input of multiplexer 11, the code p arrives (aa,) from block 18. The codes a, (η-p) and p (A-a <sub> (</ sub>)) are the upper limits of the change of a <sub> r </ sub> for the ranges of change a ^ corresponding to A A </ p> <p> of course (0, p-) and (ρ-, p). To exit η η </ p> <p> multiplexer 11 is not connected to all digits a <sub> 2max </ sub>, but only some of the senior ones, i.e. part of the dynamic range of variation a <sub> 2 </ sub>. In adder 13, this part is added up with a <sub> 2 </ sub>, coming in from the quantum °. The new value of 45 a 2_ s un !! chnym1! a <sub> (</ sub> l 3 is transmitted to the K block) encoding, which is a parallel-serial register. </ p> <p> 50 </ p> <p> The units included in the differential impulse coder of the TV signal are controlled by &gt; clock signals accompanying the transmitted video signal. The ADC .1 served clock frequency elements £ ^. </ P> <p> In the specifically executed device, for n = 4 (in a row), block 2 is a series-parallel register to which the frequencies £ <sub> t </ sub> and - | - are applied. To equalize the bit-time intervals, the frequency £ <sub> t </ sub> is applied to the ϋ registers in blocks 4, 8. In block </ p> <p> 10 served frequency -7- and channel 4 </ p> <p> is the frequency £ <sub> k </ sub> with which the output code word is read in the serial code from the output of block 10. In block 10, &quot; grab &quot; codes a, a <sub> 2 </ sub> and 8 on the frequency should be carried out taking into account the fact that codes a ^ and 3 from the output of the quantizer 8 go directly to block 10, and the new value a <sub> 2 </ sub > formed with some delay. </ p> <p> With n = 4, the maximum width of a <sub> r </ sub> and, therefore, a <sub> 2Ma) (C </ sub> is 8 (in the case of eight-bit x;). Connection to the multiplexer output of three digits of these, i.e., dropping the five least significant digits, means dividing a <sub> 1mo </ sub>, <sub> kc </ sub> by 32. Thus, for each coded group with certain a, and p, the dynamic the range of variation of a <sub> r </ sub> is taken as its 32nd part and added to the true value of a <sub> r </ sub> in the adder 13. The size of the code at the output of multiplexer 11, i.e., the value of &quot; additive &quot;; a <sub> 2 </ sub>, depending on The image contrast and it is necessary to do more, the smaller the image contrast, in other words, the code length at the output of multiplexer 11 is fixed and is chosen experimentally for a known class of encoded images. </ p> <p> The elimination of the lower-order bits from a <sub> 2 </ sub> is equivalent to coarse uniform quantization of a <sub> r </ sub> without rounding. </ p> <p> Since the coefficient a <sub> 2 </ sub> characterizes the contrast of the coded group, by increasing a <sub> 2 </ sub>, an increase in the contrast of the coded images is achieved. </ p> <p> Let n = 4, a, = 100, p = 2 and 3 <sub> 2 </ sub> · = 40. </ p> <p> Then C = p ^ = 128, a, < 128 and a <sub> 2 </ sub> = </ p> <p> = (n-p) .a, = 200 <sub> 1o </ sub> = 1 1001000 <sub> 2 </ sub>. When five low-order bits are dropped, the code-110 is fed to the input of the adder 13, i.e. 6 is added to 40 and, instead of 40, the value a <sub> 2 </ sub> = 46 is transmitted to the channel. </ p> <p> With a <sub> 4 </ sub> = 40, the levels Ζ and Ζ <sub> 4 </ sub> are equal to </ p> <p> 120 and 80 respectively, and 4 Ζ = 40. </ p> <p> 9 </ p> <p> 1513624 </ p> <p> 10 </ p> <p> For a <sub> g </ sub> = 46, the difference between уровня between levels and Ζ <sub> 4 </ sub> is increased by 6, i.e. </ p> <p> has become more contrast. </ p> <p> It is easy to verify that when a ^ = 0, there is no change in a <sub> 4 </ sub>. Indeed, for a = 0, all x = a, and p = n. Then C = A and to the output of multiplexer 11 in accordance with (2) must be connected (p-p). And <sub> 1 </ sub> = 0, since p-p = 0. </ P> <p> When adding a <sub> g </ sub> with part of the dynamic range of variation of a <sub> 2 </ sub>, a <sub> 2 </ sub> may occur outside the limits. On the receiving side, in this case, an excess occurs. Ζ, > 255 or Ζ <sub> 4 </ sub> < 0. Since 0 έ έ 255, then Ζ is equal to 255, and Ζ <sub> 2 </ sub> is zero. Thus, exceeding a <sub> 2tk </ sub> in the encoder does not lead to erroneous decoding of the group. </ P> <p> Thus, in addition to coding monochrome images, the encoder contrasts TV images, which allows to improve the subjective quality of images. </ p>

Claims (1)

Claim Differential pulse coder of a television signal on azt.sv. 10 '1056455, characterized in that, in order to extend the functionality by providing contrast adjustment of the encoded images, a contrast adjustment node is introduced between the outputs of the quantizer and the inputs of the coding unit, performed on the decoder, alternators, blocks of elements HE, multiplexer, adder, source constant code and the comparator, the first inputs of which are combined with the first inputs of the first multiplier, the inputs 10 of the first block of elements are NOT and are the first inputs and outputs of the node, the outputs of the first The block of elements is NOT connected to the first inputs of the second multiplier, the outputs of the first and> second multipliers are connected to the first and second information inputs of the multiplexer, the outputs of which are connected to the first inputs of the adder, the second inputs and outputs of which are 20 second respectively the inputs and outputs of the node, the inputs of the decoder are the third inputs and outputs of the node, the outputs of the decoder are connected to the first inputs of the third and second inputs of the second multiplier and the inputs of the second block of elements NOT whose outputs are connected to the second inputs of the first multiplier, the outputs of the constant code source are connected with ι 30 second inputs of the third multiplier, the outputs of which are connected to the second inputs of the comparator, the output of which is connected to the control input of the multiplexer. FIG. 2 1513624