RU2012161C1 - Device for alteration of color saturation - Google Patents

Abstract

FIELD: color television equipment. SUBSTANCE: device has seventeen units 1- 17 for generation of color correction signals. Each unit has subtraction circuit 18 and limiter 19. In addition device has fifteen algebraic adders 20-31, 38-40, six multipliers 32-37, reference voltage unit 41. Device provides increased possibilities for adaptation to desired characteristics of saturation of red, green, blue, yellow, cyan and purple constituents of color image in order to achieve maximum color contrast. EFFECT: increased functional capabilities by possibility of separate change of saturation of base and additional colors. 2 dwg

Description

 The invention relates to the technique of color television and can be used in the construction of color television systems for various purposes, such as television color image analyzers.

 A device for changing the color saturation, implemented in the chip K174AF4 (Digital and analog integrated circuits. / Under the editorship of S.V. Yakubovsky and other M.: Radio and communication, 1990, S. 387, Fig. 5.67, while simultaneously providing conversion color-difference signals and luminance signal into the signals of the primary colors.The color saturation in this device is changed without changing the brightness of the colors.

 A disadvantage of the known device is its unsuitability for changing the saturation of bright colors due to the limited dynamic ranges of the primary color signals and the inability to individually change the saturation of the primary (red, green, blue) and additional (yellow, magenta, blue) colors, which limits the scope of the device .

 The closest in technical essence to the device (application Germany N 3630939, class. H 04 N 9/67 from 03.24.88), containing three algebraic adders, the first inputs of which are respectively the first, second and third inputs, and the outputs are respectively the first, the second and third outputs of the device, six blocks of the formation of color correction signals (FSC), each of which contains a series-connected subtracter, the first and second inputs of which are the corresponding inputs of the FSC block, and the limiter, the output of which is the output of the block OKS FSC. The first input of the first FSC block is connected to the first input of the third, second inputs of the fifth and sixth blocks of the FSC and the first input of the third algebraic adder. The second input of the first FSC block is connected to the second input of the second, the first inputs of the fourth and fifth blocks of the FSC and the first input of the first algebraic adder. The first input of the second FSC block is connected to the second inputs of the third and fourth, the first input of the sixth FSC block and the first input of the second algebraic adder. The outputs of the first and second blocks of the FSC are connected respectively to the second and third inputs of the first algebraic adder. The outputs of the third and fourth blocks of the FSC are connected respectively to the second and third inputs of the second algebraic adder. The outputs of the fifth and sixth blocks of the FSC are connected respectively to the second and third inputs of the third algebraic adder. In the particular case, with equal and identical weighting coefficients of color correction signals generated when the reference voltage of the limiters is equal to zero, the device provides a change in the color saturation and brightness (in general, the device changes all three color parameters - brightness, saturation, color tone).

 The disadvantage of this device is the inability to individually change the saturation of the primary and secondary colors, which limits the scope of the device.

 The aim of the invention is to expand the functionality of the device by providing individual changes in saturated primary and secondary colors.

 This is achieved by the fact that in the device containing three algebraic adders, the first inputs of which are the first, second and third inputs, respectively, and the outputs are the first, second and third outputs of the device, respectively, six FSC blocks, each of which contains a subtractor connected in series, the first and the second inputs of which are the corresponding inputs of the FSC block, and the limiter, the output of which is the output of the FSC block, introduces the seventh, eighth, ninth, tenth, eleventh, twelfth, thirteenth, fourteen the fifth, fifteenth, sixteenth and seventeenth blocks of the FSC, a reference voltage block, the output of which is connected to the control input of each block of the FSC, which is the second input of the limiter. The fourth, fifth, sixth, seventh, eighth, ninth, tenth, eleventh, twelfth, thirteenth, fourteenth and fifteenth algebraic adders, first, second, third, fourth, fifth and sixth multipliers are also introduced. The first five blocks of the FSC provide five primary color correction signals, which are the corresponding differences of the input signals of the primary colors, limited by the level of the reference voltage equal to zero.

The first block of the FSC generates a signal in the region of blue and cyan colors U ₁ = U _b - U _r for U _b - U _r ≥ U _op = 0. The second block of the FSC generates a signal in the region of green and blue U ₂ = U _d - U _r when U _d - U _r ≥ 0. The third block of the FSC generates a signal in the region of blue and magenta U ₃ = U _b - U _d for U _b - U _d ≥ 0. The fourth block of the FSC generates a signal in the region of red and magenta U ₄ = U _r - U _d at U _r - U _d ≥ 0. The fifth block of the FSZ generates a signal in the region of red and yellow colors U ₅ = U _r - U _b at U _r - U _b ≥ 0.

In the next twelve blocks of the FSC, individual saturation correction signals of the primary and secondary colors of the first and second types are formed, respectively having non-overlapping zones for adjacent primary and secondary colors. In the sixth, seventh, eighth, ninth, tenth, eleventh blocks of the FSC, individual saturation correction signals of the primary and secondary colors of the first type are generated, and in the twelfth, thirteenth, fourteenth, fifteenth, sixteenth, seventeenth blocks of the FSC individual signals of the saturation correction of the primary and secondary colors are formed second type. The sixth block of the FSC generates a signal for the correction of the saturation of the region of blue colors U _c1 = U ₁ - U ₂ for U ₁ - U ₂ ≥ 0. The seventh block of the FSC generates a signal for the correction of the saturation of the region of blue colors U _g1 = U ₁ - U ₃ at U ₁ - U ₃ ≥ 0. The eighth block of the FSC generates a signal for the correction of the saturation of the region of red colors U _k1 = U ₄ - U ₃ at U ₄ - U ₃ ≥ 0. The ninth block of the FSC generates a signal for the correction of the saturation of the region of purple colors U _p1 = U ₄ - U ₅ at U ₄ - U ₅ ≥ 0. The tenth block of the FSC generates a signal for correcting the saturation of the green region U _z1 = U ₂ - U ₁ with U ₂ - U ₁ ≥ 0. The eleventh block of the FSC f generates a signal for the correction of the saturation of the region of yellow colors U _x1 = U ₅ - U ₄ at U ₅ - U ₄ ≥ 0. The twelfth block of the FSC generates a signal for the correction of the saturation of the region of blue colors U _c2 = U _c1 - 2 (U _g1 + U _p ) at U _c1 - 2 (U _g1 + U _p1 ) ≥ 0.

The thirteenth block of the FSC generates a signal for the correction of the saturation of the region of blue colors U _g2 = 2U _g1 - (U _s1 + U _c1 ) at 2U _g1 - (U _s1 + U _c1 ) ≥ 0. The fourteenth block of the FSC generates a signal of the saturation correction of the region of red colors U _k2 = U _k1 - 2 (U _z1 + + U _p1 ) with U _k1 - 2 (U _z1 + U _p1 ) ≥ 0. The fifteenth FSC block generates a correction signal for the saturation of the magenta region U _{p2 =} 2U _p1 - (U _k1 + U _s1 ) at 2U _p1 - (U _k1 + U _s1 ) ≥ 0. The sixteenth block of the FSC generates a correction signal for the saturation of the green color region U _z2 = U _z1 - 2 (U _z1 + U _g1 ) at U _z1 - 2 (U _z1 + U _g1 ) ≥ 0. The seventeenth block of the FSC forms s drove the correction of the saturation of the region of yellow colors U _W2 = 2U _W1 - (U _K1 + U _Z1 ) with 2U _W1 - (U _K1 + U _Z1 ) ≥ 0.

The tenth, eleventh, twelfth, thirteenth, fourteenth and fifteenth algebraic adders provide, respectively, the choice of types of correction signals for the saturation of blue, cyan, red, magenta, green, yellow. The first, second, third, fourth, fifth and sixth multipliers provide individual correction of the saturation of the regions of blue, cyan, red, magenta, green and yellow, respectively, in accordance with external control signals. The first, second and third algebraic adders provide the formation of the following output signals of the primary colors at the respective device outputs: U _r '= U _r - α ₁ [β ₁ U _c1 + (1 - β ₁ ) U _c2 ] -α ₂ [β ₂ U _g2 + (1 - β ₂ ) U _g2 ] - α ₅ [β ₅ U _z1 + (1-β ₅ ) U _z2 ]
U _d '= U _d - α ₁ [β ₁ U _c1 + (1 - β ₁ ) U _c2 ] - α ₃ [β ₃ U _к1 + (1 - β ₃ ) U _к2 ] -α ₄ [β ₄ U _п1 + (1- β ₄ ) U _п2 ] U _b '= U _b - α ₃ [β ₃ U _к1 + (1 - β ₃ ) U _к2 ] -α ₅ [β ₅ U _З1 + (1 - β ₅ ) U _h2 ] -α ₆ [β ₆ U _w1 + (1-β ₆ ) U _w2 ], where α ₁ , α ₂ , α ₃ , α ₄ , α ₅ , α ₆ are, respectively, the adjustment coefficients of the signals for correcting the saturation of blue, cyan, red, purple, green, yellow;
β ₁ , β ₂ , β ₃ , β ₄ , β ₅ , β ₆ are the coefficients that determine the ratios of the first and second types of saturation correction signals of the corresponding colors, varying in the range [0, 1].

The values of the coefficients β ₁ . . . , β ₆ , signs and the range of variation of the values of the adjustment coefficients α ₁ . . . , α ₆ determine the adaptive characteristics of the device to the desired task of color analysis, the nature of the change in the saturation of the primary and secondary colors. This allows you to expand the scope of the device.

In FIG. 1 shows a block diagram of a device for changing color saturation; in FIG. 2 - timing diagrams of the input and output signals of the primary colors, color correction signals of the device for changing the color saturation at α ₁ = α ₂ =. . . = α ₆ = 0.5, β ₁ = β ₂ =. . . = β ₆ = 0.

 A device for changing the color saturation contains seventeen blocks FSC 1.. . 17, each of which contains a series-connected subtractor 18 and a limiter 19, fifteen algebraic adders 20.. . 31, 38, 39, 40, six multipliers 32.. . 37, the reference voltage block 41.

 A device for changing the color saturation works as follows.

When applying to the first 42, second 43 and third 44 inputs of the primary color signal device U _r (see Fig. 2, a), U _d (see Fig. 2, b), U _b (see Fig. 2, c ), at the outputs of the first five FSC blocks, color correction signals U ₁ (see Fig. 2, d), U ₂ (see Fig. 2, e), U ₃ (see Fig. 2, e), U ₄ appear (see Fig. 2, g), U ₅ (see. Fig. 2, h). At the outputs of blocks FSC 6-11, signals for the correction of the saturation of the primary and secondary colors of the first type, respectively, U _c1 (see Fig. 2, i), U _g1 (see Fig. 2, k), U _k1 (see Fig. 2 , l), U _p1 (see Fig. 2, m), U _s1 (see Fig. 2, n), U _w1 (see Fig. 2, o). At the outputs of the FSC blocks 12-17, signals for the correction of the saturation of the primary and secondary colors of the second type, respectively, U _c2 (see Fig. 2, p), U _g2 (see Fig. 2, p), U _k2 (see Fig. 2 , c), U _p2 (see Fig. 2, t), U _s2 (see Fig. 2, y), U _s2 (see Fig. 2, f).

For given in algebraic adders 26.. . 31 coefficients β ₁ = β ₂ =. . . = β ₆ = 0, for given in the multipliers 32.. . 37 in accordance with external control signals supplied to the respective inputs 48.. . 53, the coefficients α ₁ = α ₂ =. . . = α ₆ = 0.5, the first 45, second 46, third 47 outputs of the device from the outputs of the corresponding algebraic adders 38,39,40 respectively receive signals of the primary colors U _r '(see Fig. 2, x), U _d ' (see Fig. 2, c), U _b '(see Fig. 2, h).

 The proposed device allows you to adapt the nature of the change in the saturation of the red, green, blue, yellow, cyan and magenta components of the colors analyzed by the operator of the class of color images to the change in their saturation required for the visual analysis task that it solves, which expands the scope of the device.

Claims (1)

 A device for changing the saturation of colors, containing the first, second and third algebraic adders, the first inputs of which are respectively the first, second and third inputs of the device, and the outputs are respectively the first, second and third outputs of the device, the first, second, third, fourth, fifth and the sixth color correction signal generation block, each of which contains a series-connected subtracter, the first and second inputs of which are the corresponding inputs of each signal generation block color correction, and the limiter, the output of which is the output of the color correction signal generation block, while the first input of the device is connected to the first inputs of the first, second and fifth blocks of color correction signals, the second input of the device is connected to the first inputs of the third and fourth blocks of color correction signals, and the third the input of the device is connected to the second input of the fifth block of the formation of color correction signals, characterized in that, in order to expand functionality by providing cross-sections of individual changes in the saturation of the primary and secondary colors, the seventh, eighth, ninth, tenth, eleventh, twelfth, thirteenth, fourteenth, fifteenth, sixteenth and seventeenth color correction signal generation block are introduced, the reference voltage block, the output of which is connected to the control inputs of each signal generation block color grades, which are the second input of the limiter, the fourth, fifth, sixth, seventh, eighth, ninth, tenth, eleventh, twelfth, thirteenth, four the eleventh and fifteenth algebraic adders, the first, second, third, fourth, fifth and sixth multipliers, while the second input of the first color correction signal generation unit is connected to the second input of the third color correction signal generation unit and the third input of the device, the second input of the second color correction signal generation unit is connected with the second input of the device, the second input of the fourth block for generating color correction signals is connected to the first input of the device, the first input of the sixth block for generating signals The color correction channel (FSC) is connected to the output of the first FSC block and to the first inputs of the seventh and tenth blocks of the FSC, the output of the second FSC block is connected to the second inputs of the sixth and tenth blocks of the FSC, the output of the third FSC block is connected to the second input of the seventh FSC block and the first input of the FSC , the eighth block of the FSC, the second input of which is connected to the first input of the ninth block of the FSC, the first input of the eleventh block of the FSC and the output of the fourth block of the FSC, the output of the fifth block of the FSC is connected to the second inputs of the ninth and eleventh block of the FSC, the output of the sixth block FSC is connected to the first inputs of the fifth, seventh and tenth algebraic adders and the first input of the twelfth block of the FSC, the second input of which is connected to the output of the fourth algebraic adder, the first input of which is connected to the first inputs of the eleventh and eighth algebraic adders, the first input of the thirteenth block of the FSC and the seventh output FSC, the output of the eighth block of the FSC is connected to the second input of the seventh algebraic adder and the first inputs of the ninth and twelfth algebraic adders and fourteenth b Oka FSC, the output of the ninth block of the FSC is connected to the second input of the fourth algebraic adder and the first inputs of the sixth and thirteenth algebraic adders and the first input of the fifteenth block of the FSC, the output of the tenth block of the FSC is connected to the second inputs of the fifth and ninth algebraic adders and the first inputs of the fourteenth and eleventh algebraic block FSC, the output of the eleventh block FSC is connected to the second inputs of the sixth and eighth algebraic adders and the first inputs of the fifteenth algebraic umator and the seventeenth block of the FSC, the output of the twelfth block of the FSC is connected through the second input of the tenth algebraic adder to the first input of the first multiplier, the output of the fifth algebraic adder is connected to the second input of the thirteenth block of the FSC, the output of which through the second input of the eleventh algebraic adder is connected to the first input of the second multiplier, the output of the sixth algebraic adder is connected to the second input of the fourteenth block of the FSC, the output of which is connected through the second input of the twelfth algebraic sum torus with the first input of the third multiplier, the output of the seventh algebraic adder is connected to the second input of the fifteenth block of the FSC, the output of which is connected through the second input of the thirteenth algebraic adder with the first input of the fourth multiplier, the output of the eighth algebraic adder is connected to the second input of the sixteenth block of the FSC, the output of which is through the second the input of the fourteenth algebraic adder is connected to the first input of the fifth multiplier, the output of the ninth algebraic adder is connected to the second input of the sem the fifth block of the FSC, whose output is through the second input of the fifteenth algebraic adder with the first input of the sixth multiplier, the second input of which is the sixth input of the external control signal, the first, second, third, fourth and fifth inputs of the external control signal are connected to the second inputs of the corresponding multipliers, the output of the first the multiplier is connected to the second inputs of the first and second algebraic adders, the output of the second multiplier is connected to the third input of the first algebraic adder, the fourth input of which a second input coupled to the third algebraic adder and the output of the fifth multiplier, a third multiplier output being coupled to the third inputs of the second and third algebraic adders fourth multiplier output connected to a fourth input of the second algebraic adder, the output of the sixth multiplier connected to a fourth input of the third adder.

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