JP5987650B2 - Color conversion device - Google Patents

Description

  The present invention relates to a color conversion apparatus.

  As a function required for office equipment such as an image forming apparatus, there is a function related to power saving. Conventionally, an image forming apparatus that reduces power consumption by stopping reading of a memory in which image data is stored under a predetermined condition, and a display apparatus that performs similar memory control are known (for example, Patent Document 1, 2).

JP 2006-103047 A JP 2003-186445 A

Incidentally, a device that performs input / output relating to color, such as an image forming apparatus, includes a color conversion unit that converts an input color value of a predetermined color space into a color value of another color space. The color conversion unit performs color conversion with reference to a multi-dimensional lookup table indicating the correspondence between the color values of different color spaces stored in the memory. In the following description, the lookup table is referred to as LUT.
Of the information included in the LUT, only a small part of the information corresponds to a specific input value to be subjected to color conversion. However, the conventional color conversion unit enables all the storage areas of the memory in which the LUT is stored at the time of color conversion. That is, useless power is consumed for reading out information included in the LUT that is not used for color conversion.

  An object of the present invention is to provide a color conversion device that can further reduce power consumption.

The invention according to claim 1 refers to N-dimensional data including information indicating a correspondence relationship between the color value of the first color space and the color value of the second color space of N colors composed of integers of 2 or more. Then, in the color conversion device that converts the first value that is the color value of the first color space of N colors into the second value that is the color value of the second color space, in the specific color of the second color space A plurality of memories storing each of the divided data obtained by dividing the N-dimensional data into a plurality of pieces, and a correspondence relationship between the first value and the second value among the plurality of memories according to the first value A control unit that controls the memory in which the divided data related to the memory is stored in an enabled state and disables the memory in which the divided data related to the correspondence between the first value and the second value is not stored Stored in the memory enabled by the control unit. A calculation unit for obtaining the second value information by performing a calculation using the corresponding to the first value included in the divided data, characterized in that it comprises a.

According to a second aspect of the present invention, in the color conversion device according to the first aspect, ^2N memories are provided, and the arithmetic unit is smaller in number than ^2N enabled by the control unit. An interpolation operation is performed using data indicating lattice points in the first color space included in the divided data stored in the memory.

According to a third aspect of the present invention, the color conversion device according to the second aspect further includes a calculation unit that individually calculates a weighting coefficient corresponding to the first value for each of the divided data.
The calculation unit further performs the interpolation calculation using the weighting coefficient calculated by the calculation unit, and the calculation unit sets the weighting coefficient of the divided data stored in the disabled memory to 0. It is characterized by.

  According to the present invention, power consumption can be further reduced.

It is a figure which shows the color conversion apparatus which concerns on this Embodiment. It is a figure which shows an example of the circuit structure of a color conversion part. It is a schematic diagram of a three-dimensional LUT. It is a figure which shows an example of the division data memorize | stored in each of several memory. It is a figure which shows the combination pattern of four lattice points used for an interpolation calculation. FIG. 5A shows an example in which the magnitude relationship between the values represented by R [3: 0], G [3: 0], and B [3: 0] satisfies (1) or (7). FIG. FIG. 5B is a diagram illustrating an example in which the magnitude relationship between the values represented by R [3: 0], G [3: 0], and B [3: 0] satisfies (2). is there. FIG. 5C is a diagram illustrating an example in which the magnitude relationship between the values represented by R [3: 0], G [3: 0], and B [3: 0] satisfies (3). is there. FIG. 5D is a diagram illustrating an example in which the magnitude relationship between the values represented by R [3: 0], G [3: 0], and B [3: 0] satisfies (4). is there. FIG. 5E is a diagram illustrating an example in which the magnitude relationship between the values represented by R [3: 0], G [3: 0], and B [3: 0] satisfies (5). is there. FIG. 5F is a diagram illustrating an example in which the magnitude relationship between the values represented by R [3: 0], G [3: 0], and B [3: 0] satisfies (6). is there. It is a figure which shows an example of the operation | movement pattern of the switching part by a 2nd control part. It is a figure which shows an example of the calculation pattern of a tetrahedron and a weighting coefficient corresponding to the magnitude relationship of the value represented by each of R [3: 0], G [3: 0], and B [3: 0].

  Embodiments of the color conversion apparatus of the present invention will be described below with reference to the drawings.

FIG. 1 shows a color conversion apparatus 100 according to the present embodiment.
The color conversion apparatus 100 refers to N-dimensional data including information indicating the correspondence relationship between the color values of the first color space of the N colors and the color values of the second color space, and the first color of the N colors A color conversion device that converts a first value that is a color value of a space into a second value that is a color value of a second color space. Here, N consists of two or more integers.
In the present embodiment, the RGB color space is the first color space, and the CMYK color space is the second color space. The color conversion apparatus 100 according to the present embodiment converts RGB color values represented by 8-bit information for red (R), green (G), and blue (B) into cyan (C), magenta ( M), color conversion is performed in which each color of yellow (Y) and black (K) is converted into CMYK color values indicated by 8-bit information. For example, the color conversion apparatus 100 is provided in an image forming apparatus that forms an image using toner corresponding to the color space of CMYK, and the RGB color values of each pixel constituting the RGB image input to the image forming apparatus are obtained. The first value is converted to a CMYK color value that is the second value.

The 8-bit information is a decimal integer value and takes any value within the range of 0-255.
In the following description, an 8-digit bit pattern formed by a combination of 8 binary values constituting 8-bit information is represented by the 0th digit [0] to the 7th digit [7]. For example, when the value of the decimal number indicated by 8-bit information is 0, all the bit patterns [0] to [7] are 0. When the decimal value indicated by 8-bit information is 1, the bit pattern is [0] is 1 and [1] to [7] are 0. When the decimal value indicated by the 8-bit information is 128, [7] is 1 and [0] to [6] are 0.
The bit patterns of the color values of R, G, and B are described as R [7: 0], G [7: 0], and B [7: 0]. Of the bit patterns of the R color value, R [p] is used to indicate the pth bit pattern, and R [r: q] is used to indicate the qth to rth bit patterns. It describes. Here, 0 ≦ p ≦ 7. In addition, 0 ≦ q ≦ 6, 1 ≦ r ≦ 7, and r> q. The same applies to descriptions relating to bit patterns of other values.

The color conversion apparatus 100 according to the present embodiment includes four color conversion units 10C, 10M, 10Y, and 10K corresponding to the number of colors after color conversion. The four color conversion units 10C, 10M, 10Y, and 10K output C, M, Y, and K color values after color conversion, respectively, in response to input of RGB color values to be subjected to color conversion. The color conversion apparatus 100 combines the C, M, Y, and K color values output from the four color conversion units 10C, 10M, 10Y, and 10K, and outputs CMYK color values.
The color conversion apparatus 100 is an integrated circuit such as an FPGA or an ASIC or a system LSI provided with a plurality of these integrated circuits. Each component included in the color conversion apparatus 100 and the wiring between the components are mounted on an integrated circuit. Note that FPGA is a field programmable gate array, ASIC is an application specific integrated circuit, and LSI is an acronym for Large Scale Integration.
The four color conversion units 10C, 10M, 10Y, and 10K have the same configuration except that the output colors are different such as C, M, Y, and K, respectively. Hereinafter, the four color conversion units 10C, 10M, 10Y, and 10K will be described by taking the color conversion unit 10C as an example.

FIG. 2 shows an example of the circuit configuration of the color conversion unit 10C.
The color conversion unit 10C includes, for example, a storage unit 20, a generation unit 40, a first control unit 50, a switching unit 60, a second control unit 70, a calculation unit 80, and a calculation unit 90.

The storage unit 20 has a plurality of memories. The plurality of memories store divided data obtained by dividing N-dimensional data into a plurality of pieces.
Specifically, a plurality of memory in the present embodiment, as the eight memory 21-28 shown in FIG. 2, in response to a number of colors in the RGB color space "3", 2 ^3, i.e. , 8 are provided. Each of the eight memories 21 to 28 stores divided data 1 to 8 obtained by dividing a three-dimensional LUT corresponding to the RGB color space into eight.

Here, the three-dimensional LUT will be described with reference to FIG.
The three-dimensional LUT is data indicating the correspondence between RGB color values and C, M, Y, and K color values. Specifically, a three-dimensional LUT can be represented by a three-dimensional space with R, G, and B as axes as shown in FIG. The three-dimensional LUT includes information relating to any one of C, M, Y, and K color values corresponding to the R, G, and B color values in the three-dimensional space. That is, by referring to the three-dimensional LUT, the arithmetic unit 90 described later can obtain information on C, M, Y, and K color values corresponding to RGB color values.

The eight memories 21 to 28 of the color conversion unit 10C store three-dimensional LUT division data indicating a correspondence relationship between RGB color values and C color values. Similarly, the eight memories 21 to 28 of the color conversion unit 10M, the color conversion unit 10Y, and the color conversion unit 10K are three-dimensional LUTs that indicate the correspondence between RGB color values and the color values after color conversion. The divided data is stored. In other words, the color conversion units 10C, 10M, 10Y, and 10K are color-converted colors that are associated with RGB color values in the three-dimensional LUT that is the basis of the divided data stored in the eight memories 21 to 28. It is the same except that each value is different.
Hereinafter, a description will be given by taking a three-dimensional LUT corresponding to the color conversion unit 10C as an example.

In the present embodiment, the three-dimensional LUT corresponding to the color conversion unit 10C includes information on the C color values corresponding to the R, G, and B color values sampled in units of 16 gradations. Specifically, the three-dimensional LUT is a total of 17 pattern values of 0, 16, 32, 48, 64, 80, 96, 112, 128, 144, 160, 176, 192, 208, 224, 240, 255. Information on the C color value corresponding to the grid point corresponding to the combination of the R, G, and B color values taking any one of the values. Although the description is made in units of 16 gradations, since the maximum value represented by 8 bits is 255, there are 15 gradations only between 240 and 255.
Here, since the number of color value patterns that each of R, G, and B can take is 17, the total number of combination patterns of R, G, and B color values that are lattice points is 17 × 17 × 17 [ Pieces]. Further, when a three-dimensional space is divided by line segments connecting lattice points along each of the R, G, and B axes, the three-dimensional space is divided into 16 × 16 × 16 [pieces] cubic spaces. The Rukoto.

  Here, as an example, a three-dimensional space of R, G, and B in a range where the minimum value is 0 and the maximum value is 31 will be mentioned. As described above, when the three-dimensional space is divided by line segments connecting the lattice points corresponding to the combination patterns of R, G, and B color values, eight spaces C1 to C8 are included in the three-dimensional space. Will exist. Here, the space C1 corresponds to a range in which the color values of R, G, and B are all 0-15. The space C2 corresponds to a range in which the color value of R is 16 to 31 and the color values of G and B are both 0 to 15. The space C3 corresponds to a range in which the R and B color values are both 0 to 15 and the G color value is 16 to 31. The space C4 corresponds to a range in which the R and G color values are 16 to 31 and the B color value is 0 to 15. The space C5 corresponds to a range in which the R and G color values are both 0 to 15 and the B color value is 16 to 31. The space C6 corresponds to a range in which the R and B color values are 16 to 31 and the G color value is 0 to 15. The space C7 corresponds to a range in which the R color value is 0 to 15 and the G and B color values are both 16 to 31. The space C8 corresponds to a range in which the color values of R, G, and B are all 16 to 31.

Each of the spaces C1 to C8 corresponds to either the range of 0 to 15 or the range of 16 to 31 for the color values of R, G, and B, and the color values of each of R, G, and B The combination pattern of the range does not overlap. Here, when the 8-bit value is 0 to 15, [4] becomes 0, and when the 8-bit value is 16 to 31, [4] becomes 1, so that the space C1 to the space C8 The combination patterns of R [4], G [4], and B [4] of the RGB color values included in each are different. Specifically, the combination pattern of R [4], G [4], and B [4] of RGB color values included in the space C1 is “0, 0, 0”. Hereinafter, similarly, the combination pattern of the space C2 is “1, 0, 0”. The combination pattern of the space C3 is “0, 1, 0”. The combination pattern of the space C4 is “1, 1, 0”. The combination pattern of the space C5 is “0, 0, 1”. The combination pattern of the space C6 is “1, 0, 1”. The combination pattern of the space C7 is “0, 1, 1”. The combination pattern of the space C8 is “1, 1, 1”.
In other words, there are 8 combination patterns of R [4], G [4], and B [4] of R, G, and B color values, and within the range where the minimum value is 0 and the maximum value is 31, It can be determined from the combination pattern whether the RGB color values are included in the spaces C1 to C8.

  The relation of the combination pattern of R [4], G [4], B [4] in the space C1 to the space C8 is R, G, B within the range where the minimum value is 0 and the maximum value is 31. The three-dimensional LUT data divided in units of 32 gradations for each color of R, G, and B, such as within a range where the minimum value is 32 and the maximum value is 63, is not limited to the three-dimensional space. is there. In other words, the three-dimensional LUT data divided in units of 16 gradations can be divided into eight groups according to the combination pattern of R [4], G [4], and B [4].

The three-dimensional LUT is stored in each of the eight memories 21 to 28 as divided data 1 to 8 divided according to the number of the eight memories 21 to 28. Here, the information included in the divided data stored in each of the eight memories 21 to 28 does not overlap.
In the present embodiment, the eight divided data 1-8 stored in each of the eight memories 21-28 are divided according to the combination pattern of R [4], G [4], B [4]. Correspond to the eight groups. Specifically, as illustrated in FIG. 4, the memory 21 stores the divided data 1 in which the combination pattern of R [4], G [4], and B [4] is “0, 0, 0”. The memory 22 stores the divided data 2 in which the combination pattern of R [4], G [4], and B [4] is “1, 0, 0”. The memory 23 stores the divided data 3 in which the combination pattern of R [4], G [4], and B [4] is “0, 1, 0”. The memory 24 stores the divided data 4 in which the combination pattern of R [4], G [4], and B [4] is “1, 1, 0”. The memory 25 stores the divided data 5 in which the combination pattern of R [4], G [4], and B [4] is “0, 0, 1”. The memory 26 stores the divided data 6 in which the combination pattern of R [4], G [4], and B [4] is “1, 0, 1”. The memory 27 stores the divided data 7 in which the combination pattern of R [4], G [4], and B [4] is “0, 1, 1”. The memory 28 stores the divided data 8 in which the combination pattern of R [4], G [4], and B [4] is “1, 1, 1”. However, exceptionally, the color values of R, G, and B, which have a value of 255, are grouped by assuming that [4] is 1 if it is 0.

  In the case of the example shown in FIG. 3, for example, (R, G, B) = (0, 0, 0), and the lattice point Ca corresponding to the space C1 or (R, G, B) = (32, The information corresponding to each of the lattice points whose combination pattern of R [4], G [4], and B [4] is “0, 0, 0”, such as the lattice point Cb that is 0,0), is divided data. 1 is stored in the memory 21 as information constituting one. Further, for example, information corresponding to the lattice point Cc where (R, G, B) = (255, 0, 0) is exceptionally stored in the memory 21 as data constituting the divided data 1. Similarly, information corresponding to other lattice points is also stored in each memory as information constituting each divided data according to the combination pattern of R [4], G [4], and B [4].

The generation unit 40 generates a memory address corresponding to the RGB color values.
Specifically, the generation unit 40 generates a memory address for referring to any of the eight memories 21 to 28 from R [7: 4], G [7: 4], and B [7: 4]. To do. Here, using [7: 4] means that information for 16 gradations represented by [3: 0] is omitted. Therefore, the memory address generated from R [7: 4], G [7: 4], and B [7: 4] is 16 gradation units.

  For example, RGB color values in which the bit patterns of R [7: 4], G [7: 4] and B [7: 4] are all 0 are R [3: 0] and G [3: 0. ] And B [3: 0] regardless of the bit pattern, the color value always exists in the range of the space C1 shown in FIG. As described above, the generation unit 40 uses the R [7: 4], G [7: 4], and B [7: 4] included in the RGB color values to divide a plurality of lines divided by line segments connecting the lattice points. Among the cubic spaces, a space corresponding to the color value is specified, and a memory address for obtaining information corresponding to the specified space is generated.

More specifically, the generation unit 40 includes RGB color values existing in a space corresponding to R [7: 4], G [7: 4], and B [7: 4] specified by the above mechanism. , R, G, and B, a memory address in which information corresponding to the grid point corresponding to the RGB color value having the smallest color value is stored is generated. In other words, the generation unit 40 includes R [3: 0], G [3: 0], and B [3: 0] among R [7: 0], G [7: 0], and B [7: 0]. ], The memory address is generated from R [7: 4], G [7: 4], and B [7: 4], so that among the RGB color values in the corresponding space, R, G, The grid point corresponding to the RGB color value with the smallest color value of each B can be specified.
For example, when each bit pattern of R [7: 4], G [7: 4], and B [7: 4] is all 0, the corresponding space is C1, and the generation unit 40 A memory address in which information corresponding to the grid point Ca corresponding to the RGB color value having the smallest R, G, B color value is stored is generated.

The first control unit 50 determines whether the divided data related to the correspondence between the RGB color values and the C color values among the eight memories 21 to 28 is changed according to the RGB color values to be subjected to color conversion. Control is performed so that the stored memory is enabled and the memory in which the divided data relating to the correspondence between the RGB color values and the C color values is not stored is disabled.
Specifically, the first control unit 50 uses the RGB color values of the eight memories 21 to 28 based on R [4: 0], G [4: 0], and B [4: 0]. And the memory in which the divided data related to the correspondence between the C color values is stored. Then, the first control unit 50 turns on the chip enable terminal of the specified memory, that is, enables reading while enabling the chip enable terminal of the other memory, turns off the chip enable terminal of other memory, that is, allows reading with the disabled state. The eight memories 21 to 28 are controlled so as not to be performed. Here, the energized memory is sufficiently energized with the data reading process. On the other hand, since data is not read from the memory in the disabled state, power consumption associated with the data reading process does not occur, and power consumption is significantly reduced compared to the enabled state. That is, the power consumption associated with reading data is reduced by the amount of memory that has been disabled.

  In the present embodiment, the first control unit 50 converts the divided data including information corresponding to the four grid points used in the interpolation calculation process for obtaining the C color value after color conversion into the first control unit. 50 is specified as the divided data related to the correspondence between the RGB color values and the C color values.

Hereinafter, the positional relationship between the four lattice points will be described with reference to FIGS. The cube shown in each of FIGS. 5A to 5F is one space among 16 × 16 × 16 cubic spaces divided by line segments connecting lattice points.
Among the lattice points corresponding to the vertices of one cubic space, the lattice point Cy where the color values of R, G, B are all minimum and the lattice point where the color values of R, G, B are all maximum When the space is divided by a tetrahedron having a line connecting the point Cz as one side and having four lattice points as vertices, the space is as shown in FIGS. It can be divided into six tetrahedrons W1 to W6. In other words, the RGB color values existing in one cubic space exist in any of the six tetrahedrons W1 to W6.

Here, a tetrahedron in which RGB color values exist can be specified by the magnitude relationship of values represented by R [3: 0], G [3: 0], and B [3: 0].
Specifically, R [3: 0], G [3: 0], and B [3: 0] correspond to any of the following relationships (1) to (7).
R [3: 0] ≧ G [3: 0]> B [3: 0] (1)
G [3: 0]> R [3: 0] ≧ B [3: 0] (2)
G [3: 0] ≧ B [3: 0]> R [3: 0] (3)
B [3: 0]> G [3: 0] ≧ R [3: 0] (4)
B [3: 0] ≧ R [3: 0]> G [3: 0] (5)
R [3: 0]> B [3: 0] ≧ G [3: 0] (6)
R [3: 0] = G [3: 0] = B [3: 0] (7)
Here, when the relationship (1) is established, RGB color values exist in the tetrahedron W1. When the relationship (2) is established, the RGB color values exist in the tetrahedron W2. When the relationship (3) is established, the RGB color values exist in the tetrahedron W3. When the relationship (4) is established, the RGB color values exist in the tetrahedron W4. When the relationship (5) is established, the RGB color values exist in the tetrahedron W5. When the relationship (6) is established, the RGB color values exist in the tetrahedron W6.
When the relationship (7) is established, the RGB color values are included in any tetrahedron because they are located on a line segment connecting the lattice point Cy and the lattice point Cz. In the present embodiment, when the relationship of (7) is established, it is handled as existing in the tetrahedron W1, but this is an example and not limited to this, and can be arbitrarily changed.

  In the first control unit 50, the magnitude relationship between the values represented by R [3: 0], G [3: 0], and B [3: 0] is any of the above relationships (1) to (7). And the positional relationship of the four grid points corresponding to the four vertices of the tetrahedron according to the determination result is specified.

Further, the first control unit 50 selects a combination pattern of R [4], G [4], and B [4] among R [4: 0], G [4: 0], and B [4: 0]. Acquire and specify the divided data corresponding to the acquired combination pattern. The relationship between the combination pattern of R [4], G [4], and B [4] and the divided data is as described above with reference to FIG.
The first control unit 50 then includes one grid point included in the divided data corresponding to the combination pattern of R [4], G [4], and B [4], and R [3: 0], G [ 3: 0] and B [3: 0], the division including information corresponding to the four grid points according to the positional relation of the four grid points specified by the magnitude relation of the values represented Identify the data. Specifically, the first control unit 50 sets one grid point included in the divided data corresponding to the combination pattern of R [4], G [4], and B [4] to R, G, and B colors. The divided data including information corresponding to the remaining three lattice points is specified as the lattice point Cy having the minimum value.

  For example, as shown in FIGS. 5A to 5F, when the lattice point Cy is a lattice point included in the divided data 1, the lattice point Cz is a lattice point included in the divided data 8. As shown in FIG. 5A, when RGB color values exist in the tetrahedron W1, the remaining two lattice points are lattice points included in the divided data 2 and the divided data 4, respectively. Further, as shown in FIG. 5B, when the RGB color values exist in the tetrahedron W2, the remaining two lattice points are lattice points included in the divided data 3 and the divided data 4, respectively. As shown in FIG. 5C, when the RGB color values exist in the tetrahedron W3, the remaining two lattice points are lattice points included in the divided data 3 and the divided data 7, respectively. As shown in FIG. 5D, when the RGB color values exist in the tetrahedron W4, the remaining two lattice points are lattice points included in the divided data 5 and the divided data 7, respectively. As shown in FIG. 5E, when the RGB color values exist in the tetrahedron W5, the remaining two lattice points are lattice points included in the divided data 5 and the divided data 6, respectively. As shown in FIG. 5F, when the RGB color values exist in the tetrahedron W6, the remaining two lattice points are lattice points included in the divided data 2 and the divided data 6, respectively.

Note that the information for specifying the divided data corresponding to the remaining three lattice points from the lattice point Cy is information corresponding to the data structure of the three-dimensional LUT shown in FIG. 3, and the first control unit 50 , R [4: 0], G [4: 0] and B [4: 0] and the division data corresponding to each grid point according to the information.
As described above, the first control unit 50 uses a combination of R [4], G [4], and B [4] from R [4: 0], G [4: 0], and B [4: 0]. The four divided data corresponding to the four lattice points by acquiring the pattern and the magnitude relationship of the values represented by R [3: 0], G [3: 0], and B [3: 0] Is identified. Then, the first control unit 50 allows the memory in which the specified divided data is stored to be enabled and allows reading, and sets the other memories to the disabled state so as not to permit reading. Control. Thus, the first control unit 50, eight four memory less than the number of memory 21-28 corresponding to 2 ³ to the enabled state, the remaining four memory disabled state.

The switching unit 60 is a switch that is provided so as to be interposed between the eight memories 21 to 28 and the calculation unit 90 and switches the connection between the eight memories 21 to 28 and the calculation unit 90. The switching unit 60 connects any one of the eight memories 21 to 28 to each of the eight input units LA to LH of the calculation unit 90 shown in FIG.
The switching unit 60 operates under the control of the second control unit 70.

The second control unit 70 controls the operation of the switching unit 60.
Specifically, the second control unit 70 uses a combination pattern of R [4], G [4], and B [4] as a memory connected to each of the eight input units LA to LH of the calculation unit 90. The operation of the switching unit 60 is controlled so as to switch according to the above.
More specifically, the second control unit 70 determines that the divided data stored in the memory connected to the input units LA, LB, LC, LD, LE, LF, LG, and LH have the relationship shown in FIG. In addition, the connection between the eight memories 21 to 28 and the calculation unit 90 is switched.

  For example, when the combination pattern of R [4], G [4], and B [4] is “0, 0, 0”, the second control unit 70 connects the input unit LA and the memory 21 to input the input unit LB and memory 22 are connected, input LC and memory 23 are connected, input LD and memory 24 are connected, input LE and memory 25 are connected, input LF and memory 26 are connected, input unit LG and the memory 27 are connected, and the input unit LH and the memory 28 are connected. For the other combination patterns of R [4], G [4], and B [4], the second control unit 70 performs connection according to the relationship shown in FIG.

The calculation unit 80 individually calculates a weighting coefficient corresponding to the RGB color values to be subjected to color conversion for each of the divided data 1 to 8.
Specifically, the calculation unit 80 sets each of the divided data 1 to 8 in accordance with the magnitude relationship of values represented by R [3: 0], G [3: 0], and B [3: 0]. The weighting coefficient for applying to is calculated separately.

More specifically, as shown in FIG. 7, the calculation unit 80 responds to the magnitude relationship between values represented by R [3: 0], G [3: 0], and B [3: 0]. Thus, the division coefficient corresponding to each of the input units LA to LH, that is, the weighting coefficient for each of the divided data 1 to 8 stored in the eight memories 21 to 28 connected to the input units LA to LH is calculated. And output to the input units PA to PH of the calculation unit 90. Here, the input units PA, PB, PC, PD, PE, PF, PG, and PH are sequentially stored in a memory connected to the input units LA, LB, LC, LD, LE, LF, LG, and LH. It is an input unit for inputting a weighting coefficient for divided data.
For example, when the magnitude relationship between the values represented by R [3: 0], G [3: 0], and B [3: 0] corresponds to the above relationship (1) or (7), The calculating unit 80 calculates 1−ΔR as a weighting coefficient for the divided data corresponding to the input unit LA and outputs the calculated 1R to the input unit PA, and calculates ΔR−ΔG as the weighting coefficient for the divided data corresponding to the input unit LB. Output to the input unit PB, calculate ΔG−ΔB as a weighting coefficient for the divided data corresponding to the input unit LD, output to the input unit PD, and calculate ΔB as a weighting coefficient for the divided data corresponding to the input unit LH Output to the input section PH. Here, the memory in which the divided data corresponding to the input units LA, LB, LD, and LH is stored is a memory that is allowed to be read by the first control unit 50. In the case of the magnitude relationship of other R [3: 0], G [3: 0], and B [3: 0], the calculation unit 80 similarly calculates the weighting coefficient as shown in FIG. Output.
ΔR, ΔG, and ΔB are calculated by the following equations (8) to (10).
ΔR = R [3: 0] / 16 (8)
ΔG = G [3: 0] / 16 (9)
ΔB = B [3: 0] / 16 (10)
That is, ΔR, ΔG, and ΔB are respectively divided by 16 in decimal numbers in the range of 0 to 15 corresponding to the bit patterns of R [3: 0], G [3: 0], and B [3: 0]. Value.

Also, the calculation unit 80 sets the weighting coefficient of the divided data stored in the disabled memory to 0.
For example, when the magnitude relationship between the values represented by R [3: 0], G [3: 0], and B [3: 0] corresponds to the above relationship (1) or (7), As illustrated in FIG. 7, the calculation unit 80 sets the weighting coefficient of the divided data corresponding to the input units LC, LE, LF, and LG to 0 and outputs the result to the input units PC, PE, PF, and PG. Here, the memory in which the divided data corresponding to the input units LC, LE, LF, and LG is stored is a memory that has been disabled by the first control unit 50.

  In principle, data is not output from the memory disabled by the first control unit 50, but each part of the color conversion unit 10C including the eight memories 21 to 28 is extremely dense on the integrated circuit. Since it is mounted, an output that can be interpreted as data may be obtained from a memory that has been disabled for some reason, such as the influence of leakage current. Therefore, by setting the weighting coefficient corresponding to the divided data in the disabled memory to 0, the influence of the divided data that does not need to be referenced can be eliminated more reliably.

The calculation unit 90 performs a calculation using information included in the divided data stored in the memory enabled by the first control unit 50 and performs CMYK color values corresponding to RGB color values to be subjected to color conversion. Get.
Specifically, the calculation unit 90 obtains the color value C_Color_C after color conversion by the following equation (11).
Color_C = LA × PA + LB × PB + LC × PC + LD × PD
+ LE × PE + LF × PF + LG × PG + LH × PH (11)
Here, LA, LB, LC, LD, LE, LF, LG, and LH in equation (11) are read from the memories connected to the input units LA, LB, LC, LD, LE, LF, LG, and LH, respectively. It is information included in the output divided data. In addition, PA, PB, PC, PD, PE, PF, PG, and PH in Expression (11) are output from the calculation unit 80 to the input units PA, PB, PC, PD, PE, PF, PG, and PH, respectively. It is a weighting factor. As shown in Expression (11), the calculation unit 90 corresponds to data indicating lattice points included in the divided data stored in the memory, that is, corresponding to each lattice point corresponding to the positional relationship as shown in the example of FIG. The interpolation calculation is performed using the information to be calculated and the weighting coefficient calculated by the calculation unit 80.

More specifically, the arithmetic unit 90 reads from four memories that are permitted to be read by the first control unit 50 according to the memory address generated by the generation unit 40 among the eight memories 21 to 28. Information corresponding to the four grid points that have been output is obtained. Here, information corresponding to the four lattice points is included in four of LA, LB, LC, LD, LE, LF, LG, and LH in Expression (11). In addition, the calculation unit 90 obtains the weighting coefficient output from the calculation unit 80 corresponding to PA, PB, PC, PD, PE, PF, PG, and PH in Expression (11). And the calculating part 90 obtains Color_C by Formula (11). Then, the calculation unit 90 outputs the obtained Color_C.
Here, since the information corresponding to the four lattice points is included in four of LA, LB, LC, LD, LE, LF, LG, and LH in the equation (11), the four lattice points are included in the four lattice points. The other four that do not include the corresponding information are in a state in which no value is included. Therefore, it is assumed that the other four that do not include information corresponding to the four grid points in Expression (11) do not affect the calculation result of Color_C regardless of the weighting coefficient. Then, the calculation unit 80 sets the weighting coefficient corresponding to each of the other four to zero. In other words, the color conversion unit 10C according to the present embodiment reliably prevents the influence of the divided data that is not related to the calculation of the color value after the color conversion by using the weighting coefficient of 0.

  Although the color conversion unit 10C has been described above, the color conversion units 10M, 10Y, and 10K also operate in the same manner, and calculate and output M, Y, and K color values after color conversion, respectively.

  As described above, according to the color conversion apparatus 100 of the present embodiment, among the eight memories 21 to 28, the divided data relating to the correspondence between the RGB color values and the C, M, Y, and K color values is stored. Control is performed so that the memory in which the divided data relating to the correspondence between the RGB color values and the C, M, Y, and K color values is not stored is disabled. The power consumption is reduced according to the number of memories that are disabled. That is, according to the color conversion apparatus 100 of the present embodiment, power consumption can be further reduced.

Also, four fewer than the number of eight memory 21-28 corresponding to 2 ³ because the memory in the enabled state, the memory power consumption for reading relates data in the reference three-dimensional LUT is performed The number can be halved and the power consumption can be further reduced.
Further, by performing the interpolation calculation, it is possible to achieve both reduction of the information amount of each divided data and high-precision color reproduction.

  In addition, since the weighting coefficient of the divided data stored in the disabled memory is set to 0, an output that can be interpreted as data for some reason is generated from the disabled memory. However, it is possible to more reliably eliminate the influence of the value related to the divided data that does not require reference on the color value after color conversion.

  The embodiment of the present invention should be considered that the embodiment disclosed this time is illustrative and not restrictive in all respects. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims.

For example, in the above embodiment, since the first color space is an RGB color space, a three-dimensional LUT is used. However, the first color space is merely an example, and the first color space is not limited to this. The color space and the number of dimensions of the N-dimensional data can be changed as appropriate. Similarly, the second color space can be changed as appropriate. Further, the first color space and the second color space may be the same color space. For example, the present invention is applicable even when color conversion is performed between the same color spaces in order to adjust a difference in color reproducibility between apparatuses.
The data format is not limited to the LUT, and any data format that can indicate the correspondence between the color values of the first color space and the color values of the second color space may be used.

Further, the memory may be set to 2 ⁿ according to the number n of colors in the first color space having two colors or four or more colors.
Further, in the above embodiment, depending on a number of colors in the RGB color space "3", 2 ^3, ie, eight memory 21-28 is provided, is merely an example It is not limited to this. That is, the number of memories is not limited to the number of colors in the color space and can be changed as appropriate.

  In the above-described embodiment, four of the eight memories are enabled. However, this is an example, and the present invention is not limited to this, and can be changed as appropriate. For example, when the color after color conversion is obtained by 6-point interpolation calculation, the divided data corresponding to 6 grid points is referred to, so that 6 memories corresponding to 6 divided data are enabled. It becomes. As described above, the number of memories to be enabled may be controlled according to the number of divided data referred to for color conversion.

  In the above-described embodiment, the second color value after color conversion is calculated using an equation in which all of the input units LA to LH corresponding to the number of the plurality of memories are considered, as in equation (11). Although the value is calculated, it is an example and the present invention is not limited to this. For example, the calculation unit 90 may perform a calculation in which the portion related to the input unit corresponding to the memory to be disabled is omitted from the equation (11).

  In the above embodiment, the color conversion device 100 is mounted such that a plurality of color conversion units 10C, 10M, 10Y, and 10K are provided, but this is an example and the present invention is not limited to this. . For example, N-dimensional data stored in one color conversion unit is obtained by using N color values of a first color space of N colors and a plurality of color values of a second color space having a plurality of colors. The data may be directly associated with each other, and one color conversion unit may perform color conversion of N colors to a plurality of colors. In addition, the color conversion apparatus 100 may include one color conversion unit as in the above-described embodiment, and may perform color conversion from N colors to single colors.

In the above embodiment, the interpolation calculation using the grid points is performed for the calculation of the color value after the color conversion. However, this is an example and the present invention is not limited to this. For example, color conversion may be performed only by referring to the divided data.
Further, the formulas for calculating the weighting coefficients shown in the formulas (8) to (10) in the above embodiment are merely examples, and the formulas are not limited to this, and the weights for the data read from the divided data are given. It can be appropriately changed according to the intention of

100 color conversion devices 10C, 10K, 10M, 10Y color conversion units 1 to 8 divided data 21 to 28 memory 40 generation unit 50 first control unit 60 switching unit 70 second control unit 80 calculation unit 90 calculation unit

Claims (3)

A first color of N colors with reference to N-dimensional data including information indicating the correspondence relationship between the color values of the first color space of the N color consisting of an integer of 2 or more and the color values of the second color space In a color conversion device that converts a first value that is a color value of a space into a second value that is a color value of a second color space,
A plurality of memories storing each of divided data obtained by dividing the N-dimensional data in the specific color of the second color space into a plurality of pieces;
In accordance with the first value, among the plurality of memories, the memory in which the divided data relating to the correspondence between the first value and the second value is stored is enabled, and the first value and the first value A control unit that controls to disable a memory in which the divided data related to the binary relationship is not stored;
A calculation unit that performs calculation using information included in the divided data stored in the memory enabled by the control unit to obtain the second value corresponding to the first value;
A color conversion device comprising: 2N memories are provided,
The calculation unit performs an interpolation calculation using data indicating lattice points in the first color space included in the divided data stored in a smaller number of memories than 2N enabled by the control unit. The color conversion apparatus according to claim 1. A calculation unit that individually calculates a weighting coefficient corresponding to the first value for each of the divided data;
The calculation unit further performs the interpolation calculation using the weighting coefficient calculated by the calculation unit,
The color conversion apparatus according to claim 2, wherein the calculation unit sets a weighting coefficient of the divided data stored in the disabled memory to 0.

Images