KR20050026357A - Display color adjust - Google Patents

Abstract

A system and a method for adjusting displayed colors are provided to linearly scale colors of display data, thereby adjusting colors of digital images according to color characteristic of a display form. A color screen is used as a display by using primary colors of a color space. A system processor(3) transmits downloaded display data to a display driver circuit. The display driver circuit includes a processor interface logic(7), a display adjusting circuit(6), color adjusting registers(8), a display RAM(Random Access Memory)(5), and a screen driver(4). The processor interface logic provides interface between the system processor and the display driver circuit. The display adjusting circuit adjusts display data received from the system processor and records the adjusted display data on the display RAM. The display RAM stores the adjusted display data. The screen driver controls a screen and transmits the adjusted display data to the screen.

Description

Display color adjust}

The present invention relates generally to display systems, and more particularly to a system and method for adjusting the colors displayed prior to writing to the display RAM.

The colors of the digital images should normally be adjusted to accommodate the display system used to display the digital images. Without any adjustment, the observer of digital images will not be satisfied with the colors shown. For example, color super twist nematic (CSTN), thin film transistor (TFT), organic light emitting diode (OLED), or double layer super twisted nematic All display systems, such as (double layer supertwist nematic) (DSTN) displays, have their specific defects while displaying colors. Therefore, the colors of the digital images must be adjusted to meet the expectations of the observers of the images.

Various methods of performing the color adjustment are known.

U. S. Patent No. 6,262, 817 (Sato et al.) Shows a color image system for adjusting the colors of input images including a color adjustment unit and a color display unit. The color display unit simultaneously displays the original image, the adjusted image, and color information for both the original image and the adjusted image. The color adjustment matrix is generated by the color-adjustment unit based on the color directions input to the color display unit for the color information of the original color image. The color adjustment matrix is used to directly adjust the original image without converting the image to the second color space. The color-adjustment unit generates, for the original matrix, a color adjustment matrix by adding a color adjustment command of luminance, chromaticity and color tone commanded by the image display unit used. After the color adjustment matrix is generated, the adjusted pixels can be generated by calculating the original pixels and the color adjustment matrix.

US Patent No. 6,388,648 (Clifton et al.) Discloses a luminance and color balance system using an LCD array characteristic lookup table that stores multiple sets of user selectable luminance and gamma correction values to control luminance and color balance. Disclosed is an LCD projection unit. Index table values measure the LCD array transfer function at the projection unit for each of a set of red ("R"), green ("G") and blue ("B") data input values, and the resulting S-curve. It is determined by converting the responses into corresponding sets of gamma responses, and scaling the gamma responses to produce a plurality of luminance and gamma corrected R, G, and B families. Color balance is adjusted by selecting specific R, G, and B sets of luminance and gamma corrected values that cause the LCD projection unit to match a predetermined ratio of R, G, and B luminance values. The luminance is adjusted by selecting sets of sets of R, G and B luminance values that allow the LCD to transmit the desired overall luminance while maintaining the color balance ratio. The primary colors are adjusted by a color mixing method implemented by a mathematical matrix algorithm that generates color change coefficients in the color space conversion circuit. The primary color matching algorithm performs matrix operations that measure the coordinates of the essential colors of the primary colors, determine a set of predetermined target coordinates, and calculate coefficients used in the color space conversion circuit to convert the measured to target coordinates. Performing, thereby matching the primary colors. When the primary colors are matched, the color balance and luminance matching system described above adjusts the white and gray balance to arrive at a well-matched multiscreen display system.

U.S. Patent No. 4,409,614 (Eichler et al.) Discloses three primary color signals with actual color values in a predetermined color coordinate system in which the color scanning signals generated by scanning the original image correspond substantially equal to the original theoretical color values. A method is first disclosed. Only after that conversion, the primary color signals or signals derived from them are converted to a different color rendition system, the gradation changed, or the individual colors in the entire image or separate regions. Color rendering is altered or any other nonlinear processing is done.

The main object of the present invention is to linearly scale the colors of the display data.

Another object of the invention is to achieve a cost effective solution to the scaling of colors in display data.

Another object of the present invention is to achieve a high speed processing of the adjustment of the colors of the display data.

In accordance with the objectives of the present invention, a system has been achieved for adjusting colors in any kind of electronic display. The system includes a color screen used as a display using the primary colors of the color space, a system processor for transferring downloading display data to the display driver circuit, and a display driver circuit. The display driver circuit may be configured to provide processor interface logic that provides an interface between the system processor and the display driver circuit, and to adjust display data received from the system processor through the processor interface logic and to display the adjusted display data to display RAM. A display adjustment circuit for writing, one or more color adjustment registers, a display RAM for storing adjusted display data, and a screen driver for controlling the screen and transferring the adjusted display data to the screen. .

In accordance with the objectives of the present invention, a method of adjusting colors in any kind of electronic display has been invented. The method includes first providing a display driver circuit comprising a display screen, a system processor, processor interface logic, display adjustment circuitry, one or more adjustment registers, display RAM, and screen driver circuitry. The steps of the method may include defining adjustment data for each primary color used by the display screen to adjust the colors according to the characteristics of the screen, and one or more bits for each primary color. Storing the adjustment data for each primary color in providing one or more registers, computing unadjusted data, and defining a word structure for storing the adjusted display data in display RAM. The word structure definition step, wherein a defined number of bits is assigned for each primary color, and in the display circuitry using a hardware description language, an algorithm for adjustment of each of the primary colors used by the screen. Implementing Following these steps, downloading the display data from the system processor to the display adjustment circuit, adjusting the display data in the display adjustment circuit according to the previously implemented algorithm and previously defined and stored adjustment data, and displaying the adjusted display data. Writing to RAM followed by transferring the adjusted display data from the display RAM to the display screen by the screen driver circuit.

Preferred embodiments disclose a system and method for linearly scaling display data prior to writing to the display RAM. Embodiments of the present invention are in the form of any electronic display, such as, for example, color super twist nematic (CSTN), thin film transistor (TFT), organic light emitting diode (OLED) or double layer super twisted nematic (DSTN) displays. It can be applied to. Compared with the prior art solutions, the system and method of the present invention provide a fast and cost effective way to adjust the colors of digital images according to the color characteristics of the display type used.

1 is a block diagram showing a preferred embodiment of the present invention. The display system shows a display driver IC 1 which is the key to the solution of the present invention. Moreover, the system includes a display 2 and a system processor 3. As mentioned above, the display 2 can be any type of display. The display driver IC 1 has a display adjustment circuit for receiving unadjusted display data from the processor interface logic 7 in comparison with the prior art, and the color adjustment registers 8 for red, green and blue. To adjust the unadjusted display data, write the adjusted display data to the display RAM 5, and include the display data displayed on the screen display 2; Moreover, the system includes a screen driver circuit 4 for driving the screen display.

Those skilled in the art will appreciate that the display driver circuit described above is suitable for the implementation of the ASIC circuit.

The displayed colors can be adjusted by simple integer multiplication of the color data values before they are written to the display RAM 5. In the preferred embodiment, the 65K color display has 16-bit words divided into red, green and blue components. In other embodiments, in addition to RGB, color displays using other color spaces, such as, for example, CMY, may also be used.

The table below shows the word structure used in the embodiment of the present invention. In the 16-bit structure selected in the preferred embodiment, five bits are provided for red, six bits are provided for green, and five bits are provided for blue. Using the word structure shown in the table below, 32 different values of red, 64 different values of green and 32 different values of blue are shown in the case of unadjusted display data. This results in a palette of 32 x 64 x 32, which means 65536 different colors.

5-bit RED 6-bit GREEN 5-bit BLUE R4 R3 R2 R1 R0 G5 G4 G3 G2 G1 G0 B4 B3 B2 B1 B0

Each color value is individually adjusted by its own setting which allows for maximum flexibility in display adjustment. The system processor 3 sets the red, green and blue adjustment register settings for a particular display (eg LCD, TFT, OLED). The display data is downloaded from the system processor 3, and the display color adjustment circuit 6 adjusts the display data before the display data is written to the display RAM 5.

In the preferred embodiment the display data is scaled linearly by the programmable amount. The multiplication factor is chosen to provide simple logic execution.

The table below is represented by 5 bits and depends on the multiplication factor n, the related scaling factor, the equation used, the relevant percentage of change in red (RED), and the related number of colors that can be displayed (RED). To show. It is clear that blue, also represented by 5 bits, has exactly the same characteristics with respect to the adjustment of red (RED) shown in the table below. Therefore, BLUE is not shown as a separate table.

The table below shows whether red (RED) can be increased or decreased depending on the multiplication factor n and the plus or minus algebraic representation of the mathematical formula used. It is understood that the mathematical operations used are performed very quickly by simple operations of internal registers. The right-hand column shows how the number of different colors that can be displayed in total decreases with the amount of increase / decrease in RED. This reduction in the number of colors is due to mathematical operations (shift of registers) during adjustment. In addition, blue has the same value as red shown in the table below.

Scaling factor Equation Where n = %change Number of colors RED × 3/4 RED-RED / 2 ⁿ 2 -25% 25 RED × 7/8 RED-RED / 2 ⁿ 3 -12.5% 29 RED × 15/16 RED-RED / 2 ⁿ 4 -6.3% 31 RED × 1 No change 0 32 RED × 17/16 RED + RED / 2 ⁿ 4 + 6.3% 31 RED × 9/8 RED + RED / 2 ⁿ 3 + 12.5% 29 RED × 5/4 RED + RED / 2 ⁿ 2 + 25% 26

If the result of equation RED + RED / 2 ⁿ is greater than 31, the result is limited to 31 due to the 5-bit limitation.

The table below shows the values of the colors represented by 6 bits. As described above, green is represented by 6 bits in the preferred embodiment of the present invention. The table below shows the same columns as the table above. This is accomplished by using 6 bits, whereby adjustment is performed in two additional steps (one or more steps each for increasing or decreasing the color values) and compared to the 5 bits in the table, of the other colors that can be displayed. It is clear that the numbers are significantly higher.

Scaling factor Equation Where n = %change Number of colors GREEN × 3/4 GREEN-GREEN / 2 ⁿ 2 -25% 49 GREEN × 7/8 GREEN-GREEN / 2 ⁿ 3 -12.5% 57 GREEN × 15/16 GREEN-GREEN / 2 ⁿ 4 -6.3% 61 GREEN × 31/32 GREEN-GREEN / 2 ⁿ 5 -3.1% 63 GREEN × 1 No change 0 64 GREEN × 33/32 GREEN + GREEN / 2 ⁿ 5 + 3.1% 63 GREEN × 17/16 GREEN + GEEEN / 2 ⁿ 4 + 6.3% 61 GREEN × 9/8 GREEN + GREEN / 2 ⁿ 3 + 12.5% 57 GREEN × 5/4 GREEN + GREEN / 2 ⁿ 2 + 25% 52

If the result of the equation GREEN + GREEN / 2 ⁿ is greater than 63, the result is limited to 63 due to the 6-bit limit.

As mentioned earlier, in a preferred embodiment of the present invention, the palette of red (RED) and blue (BLUE) and 5 (6) bits, respectively, representing 5 bits, respectively, is a palette of 536 different colors. Can be displayed using unused color values. Typical adjustments include a 0% change in RED, a + 6% change in GREEN, and a 0% change in BLUE. Using the above typical adjustment, 32 different values of RED, 61 different values of GREEN, and 32 different values of BLUE can be displayed. This will have a palette of 32 x 61 x 32, which means that 62464 different colors can be displayed. More precise adjustments result in a -12% change in red and blue and a + 6% change in green. This will have a palette of 29 x 61 x 29, which means that 51301 different colors can be displayed.

The table below shows how color adjustment registers are used in the preferred embodiment of the present invention to store color adjustment information. In the preferred embodiment, two registers each having 8 bits B0 to B7 are used. In register 1, three bits B0 to B2 are used to store red adjustment data RCA 2: 0. The data for blue adjustment (BCA 2: 0) is stored in three bits of B4 to B6 of register (1). The data for the green adjustment (GCA 3: 0) is stored in four bits of B0 through B3 of the register 2.

B7 B6 B5 B4 B3 B2 B1 B0 Register 1 BCA (2: 0) RCA (2: 0) Register 2 GCA (3: 0)

The following table shows how the three bits for the red adjustment RCA (2: 0) are used in the preferred embodiment. The percentage values in the table below show the amount of increase / decrease in the color value of RED.

011 = + 25% (2-bit shift and add)

010 = + 12.5% (3-bit shift and add)

001 = + 6.3% (4-bit shift and addition)

000 = no change (default)

101 = -6.3% (4-bit shift and subtraction)

110 = -12.5% (3-bit shift and subtraction)

111 = -25% (2-bit shift and subtraction)

The same arrangement of bits is also used for blue adjustment BCA (2: 0) with three bits of adjustment data. As shown in the register table above, green adjustment GCA (3: 0) is performed using four bits of adjustment data. For example, in the preferred embodiment of the present invention the bit arrangement for green adjustment is as follows.

0100 = + 25% (2-bit shift and add)

0011 = + 12.5% (3-bit shift and add)

0010 = + 6.3% (4-bit shift and add)

0001 = + 3.1% (5-bit shift and add)

0000 = no change (default)

1001 = -3.1% (5-bit shift and subtraction)

1010 = -6.3% (4-bit shift and subtraction)

1011 = -12.5% (3-bit shift and subtraction)

1100 = -25% (2-bit shift and subtraction)

The register transfer level code (RTL) language in the display adjustment circuit 6 has been used in the preferred embodiment to implement the algorithms described above. RTL is very effective, but other hardware description languages (HDL) can also be used. An example of the RTL code used for red adjustment is shown here.

To the person skilled in the art, the above example shows how simple and fast color adjustment is performed in the preferred embodiment.

Figure 2 shows a method related to scaling display data in display driver circuitry before display data is written to the display RAM. The first step 21 of the method is to define the adjustment data for each primary color used by the display screen to adjust the colors according to the characteristics of the screen. The next step 22 is to store the adjustment data for each primary in one or more registers that provide one or more bits for each primary. Step 23 defines the word structure for computing unadjusted data and storing the adjusted display data in the display RAM, wherein the defined word structure definition is assigned a defined number of bits for each primary color. Explain. The next step 24 shows the implementation of an algorithm for adjusting each of the primary colors used by the screen in the display adjustment circuit using a hardware description language. In step 25, the display data is downloaded from the system processor to the display adjustment circuit, and then in step 26, the display data adjusted in the display adjustment circuit in accordance with the previously implemented algorithm and previously defined and stored adjustment data is Is written to the display RAM. In the final step 27, the adjusted display data is transferred from the display RAM to the display screen by the screen driver circuit.

While the invention has been particularly shown and described with reference to the preferred embodiments, it will be understood by those skilled in the art that various modifications may be made in form and detail without departing from the spirit and scope of the invention.

According to the system and method of the present invention, it is possible to adjust the colors of the digital images according to the color characteristics of the display form used in a fast and cost effective manner.

1 is a block diagram illustrating the basic elements of a system of the present invention.

2 shows a flowchart of the method of the present invention.

* Brief description of symbols for the main parts of the drawings

1 ... Display Driver IC 2 ... Display Screen

3 ... system processor 4 ... screen driver circuit

Claims (36)

A system for adjusting colors in any kind of electronic display, A color screen used as a display using primary colors of a color space, A system processor for transmitting the downloading display data to the display driver circuit, As a display driver circuit, Processor interface logic to provide an interface between the system processor and the display driver circuit; Display adjustment circuitry for adjusting display data received from the system processor through the processor interface logic and writing the adjusted display data to display RAM; One or more color adjustment registers, A display RAM for storing the adjusted display data; And a display driver circuit for controlling the screen and transmitting the adjusted display data to the screen. The color adjustment system of claim 1, wherein the color space is RGB. The color adjustment system of claim 1, wherein the color space is CMY. The color adjustment system of claim 1, wherein the screen is an LCD display. The color adjustment system of claim 4, wherein the LCD display is a CSTN display. 5. The color adjustment system of claim 4, wherein the LCD display is a DSTN display. The color adjustment system of claim 1, wherein the screen is a TFT display. The color adjustment system of claim 1, wherein the screen is an OLED display. 2. The color adjustment system of claim 1, wherein the display adjustment circuit uses two color adjustment registers for storing adjustment data defining adjustment amounts. 10. The color adjustment system of claim 9, wherein the color adjustment registers store adjustment data for each of all primary colors of the selected color space. 11. The color adjustment system of claim 10, wherein the color adjustment registers comprise three bits for storing adjustment information for each of the two primary colors and four bits for the third primary color. 12. The color adjustment system of claim 11, wherein the color adjustment registers comprise three bits for storing adjustment information for each of red and blue and four bits for green. The color adjustment system of claim 1, wherein the display data is stored in the display RAM using a 16-bit word. 14. The color adjustment system of claim 13, wherein the 16-bit word comprises 5 bits for each of the two primary colors and 6 bits for the third primary color. 15. The color adjustment system of claim 14 wherein the 16-bit word comprises 5 bits for red and blue and 6 bits for green, respectively. The color adjustment system of claim 1, wherein the color display data is scaled linearly by a programmable amount. 17. The color adjustment system of claim 16 wherein the display data is adjusted for each color according to equations implemented in the display adjustment circuit using a hardware description language. 18. The color adjustment system of claim 17 wherein the display data is adjusted for each color according to equations implemented in the display adjustment circuit using a register transfer level (RTL) language. 17. The method according to claim 16, wherein each primary color of said color display data is scaled linearly by a programmable amount, said programmable amount being a required reduction of the primary color according to the following formula: color _adjust = color _unadjust -color _unadjust / ²ⁿ . Where color _adjust is the value of the adjusted color, color _unadjust is the value of the _unadjusted color, and n is a set of parameters for each primary color according to the desired adjustment. 17. The method according to claim 16, wherein each primary color of said color display data is scaled linearly by a programmable amount, said programmable amount being the required increase in primary color according to the following formula: color _adjust = color _unadjust + color _unadjust / ²ⁿ . Where color _adjust is the value of the adjusted color, color _unadjust is the value of the _unadjusted color, and n is a set of parameters for each primary color according to the desired adjustment. The color adjustment system of claim 1, wherein the display driver circuit is implemented as an IC. The color adjustment system of claim 1, wherein the display driver circuit is implemented as an ASIC. A method of adjusting colors in any kind of electronic display, Providing a display driver circuit including a display screen, a system processor, processor interface logic, display adjustment circuitry, one or more color adjustment registers, display RAM, and screen driver circuitry; Defining adjustment data for each primary color used by the display screen to adjust the colors in accordance with the characteristics of the screen; Storing said adjustment data for each primary in one or more registers providing one or more bits for each primary; Defining a word structure for computing unadjusted data and storing the adjusted display data in display RAM, wherein the defined word structure is assigned a defined number of bits for each primary color; In the display adjustment circuit using a hardware description language, implementing an algorithm for adjusting each of the primary colors used by the screen; Downloading display data from the system processor to the display adjustment circuit; Adjusting the display data in the display adjustment circuit according to the previously implemented algorithm and previously defined and stored adjustment data, and writing the adjusted display data to the display RAM; Transferring display data adjusted from the display RAM to the display screen by the screen driver circuit. 24. The method of claim 23, wherein the primary colors belong to an RGB color space. 24. The method of claim 23, wherein the primary colors belong to a CMY color space. 24. The method of claim 23 wherein the word structure comprises a 16-bit word. 27. The method of claim 26, wherein the 16-bit word comprises 5 bits for each of the two primary colors and 6 bits for the third primary color. 28. The method of claim 27, wherein the 16-bit word comprises 5 bits for red and blue and 6 bits for green, respectively. 24. The method of claim 23, wherein the hardware description language is a register transfer level (RTL) language. 24. The method of claim 23, wherein said algorithm for reducing primary color values is color _adjust = color _unadjust -color _unadjust / 2 ⁿ , Is, Wherein color _adjust is the value of the adjusted color, color _unadjust is the value of the _unadjusted color, and n is a set of parameters for each primary color according to the desired adjustment. 24. The method of claim 23, wherein said algorithm for increasing a primary color value is color _adjust = color _unadjust -color _unadjust / 2 ⁿ , Where color _adjust is an adjustment color value, color _unadjust is an _unadjusted color value, and n is a parameter set for each primary color according to the desired adjustment. 24. The method of claim 23, wherein the color adjustment registers comprise three bits for storing adjustment data for each of the two primary colors and four bits for the third primary color.  33. The method of claim 32, wherein the color adjustment registers comprise three bits for storing the adjustment data for each of blue and red and four bits for green. 34. The method of claim 33, wherein the adjustment data for red is the following bit combinations. 011 = + 25% (2-bit shift and add) 010 = + 12.5% (3-bit shift and add) 001 = + 6.3% (4-bit shift and addition) 000 = no change (default) 101 = -6.3% (4-bit shift and subtraction) 110 = -12.5% (3-bit shift and subtraction) 111 = -25% (2-bit shift and subtraction) 34. The method of claim 33, wherein the adjustment parameters for blue are the following bit combinations. 011 = + 25% (2-bit shift and add) 010 = + 12.5% (3-bit shift and add) 001 = + 6.3% (4-bit shift and addition) 000 = no change (default) 101 = -6.3% (4-bit shift and subtraction) 110 = -12.5% (3-bit shift and subtraction) 111 = -25% (2-bit shift and subtraction) 33. The method of claim 32, wherein the adjustment parameters for green are the following bit combinations. 0100 = + 25% (2-bit shift and add) 0011 = + 12.5% (3-bit shift and add) 0010 = + 6.3% (4-bit shift and addition) 0001 = + 3.1% (5-bit shift and add) 0000 = no change (default) 1001 = -3.1% (5-bit shift and subtraction) 1010 = -6.3% (4-bit shift and subtraction) 1011 = -12.5% (3-bit shift and subtraction) 1100 = -25% (2-bit shift and subtraction)