JP5207832B2 - Display device - Google Patents

Description

  The present invention relates to a display device such as an image projection device or a monitor device that performs processing for reducing color unevenness of a display image.

  An image projection apparatus such as a projector decomposes light from a light source into light of three primary colors, modulates each primary color light for each pixel by a liquid crystal panel (image forming element), and synthesizes the modulated three primary color lights And a color image is displayed by projecting on a screen with a projection lens. However, unevenness in spectral irradiation intensity from the light source to the liquid crystal panel, uneven transmittance in the projection lens, uneven spectral reflectance in the color separation optical system or color combining optical system, uneven transmittance or reflectance in the liquid crystal panel surface, etc. As a result, a luminance unevenness peculiar to each primary color occurs. The luminance unevenness for each primary color becomes uneven in the projected color image.

  In order to reduce such color unevenness, color unevenness correction processing is performed when generating a signal for driving each liquid crystal panel according to the input image signal. The color unevenness correction circuit that performs color unevenness correction processing prepares color unevenness correction values for each of a plurality of specific pixels in the liquid crystal panel at a plurality of gradations, and corrects the color unevenness corresponding to the gradation of the input image signal. A signal for driving the liquid crystal panel is generated using the value.

The color unevenness correction circuit disclosed in Patent Document 1 focuses on the correlation between gradations and color unevenness correction values, and stores (holds) a reference color unevenness correction value corresponding to a certain gradation in a memory. At the same time, in other gradations, the difference from the reference color unevenness correction value is held in the memory as the color unevenness correction value. Thereby, the memory area for storing the color unevenness correction value is reduced.
JP 2001-357394 A

  However, in the conventional color unevenness correction circuit including the display device disclosed in Patent Document 1, the number of specific pixels is the same in all gradations for which the color unevenness correction value is set. That is, human visual characteristics that color unevenness is less visible as the color density is lower (lighter color or lower gradation) are not taken into consideration. For this reason, the scale of the memory that holds the color unevenness correction value is larger than necessary.

  Therefore, the present invention provides a display device capable of reducing the scale of a memory provided for color unevenness correction processing while performing good color unevenness correction.

A display device according to one aspect of the present invention uses an image forming element that forms an image, an input image signal, and a color unevenness correction value for reducing color unevenness of a display image, to the image forming element. Color unevenness correction value for a pixel different from the specific pixel, which is set for each of a plurality of specific pixels arranged at intervals among the processing means for generating a given signal and the pixels forming the display image Storage means for storing color unevenness correction values used for the calculation of each of a plurality of gradation values . The number of specific pixels varies depending on the gradation value .

  According to the present invention, since the number of color unevenness correction values to be set (the number of specific pixels) can be reduced as compared with the conventional case within a range where favorable color unevenness correction can be performed, the memory for storing the color unevenness correction values is stored. The scale of the means can be reduced.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings.

  First, the optical configuration of a liquid crystal projector (image projection apparatus) as a display apparatus according to an embodiment of the present invention will be described with reference to FIG.

  In FIG. 3, reference numeral 230 denotes a light source such as a discharge lamp, and reference numeral 231 denotes a liquid crystal panel (here, a reflection type liquid crystal) that decomposes white light from the light source 230 into three color lights of R, G, and B and is an image forming element. Panel) 210, 211, 212 is a color separation / synthesis optical system. Each liquid crystal panel is driven for each pixel by a drive signal generated by a processing circuit described later, and modulates the color light from the color separation / synthesis optical system 231 in accordance with the input video signal. The three color lights modulated by the liquid crystal panels 210, 211, and 212 are combined by the color separation / synthesis optical system 231 and guided to the projection lens 235. The projection lens 235 enlarges and projects the combined light of the three color lights onto the screen 240. As a result, a color image (display image) is displayed on the screen 240.

  Next, the electrical configuration of the projector according to the present embodiment will be described with reference to FIG. In the projector of this embodiment, a composite signal, an analog signal, or a digital signal, which is a video signal (image signal) input from the outside, is converted into a digital RGB signal or a digital YUV signal. Then, resolution conversion is performed on the first digital video signal obtained from the digital RGB signal or the digital YUV signal to generate a second digital video signal corresponding to the resolution of the liquid crystal panel. A video signal 201 shown in FIG. 2 represents a first digital video signal, and is a signal (RGB 24-bit signal) having a density represented by 8 bits for each pixel in each of R, G, and B.

Note that “density” (density value) in this embodiment can be rephrased as “gradation” (gradation value), and “high density” (dark) corresponds to “high gradation”. .

  The first digital video signal 201 is an RGB 24-bit signal, but the resolution (the number of pixels) is indefinite, and is input to the resolution conversion circuit 202. The resolution conversion circuit 202 converts the first digital video signal 201 into a second digital video signal having a resolution corresponding to the resolution of the liquid crystal panels 210, 211, and 212 through enlargement / reduction processing.

  In this way, the second digital video signal in which the resolution and the density for each pixel are normalized is a reflectance that represents the density value (gradation) on the liquid crystal panel (transmittance in the case of a transmissive liquid crystal panel). Is associated with the gamma correction circuit 203. In this embodiment, XGA (1024 × 768) resolution is assumed as the resolution of the liquid crystal panel.

  For example, an analog video signal output from a personal computer shows density values in the sRGB space. However, the VT characteristic of the liquid crystal panel does not correspond to the density value in the sRGB space at all. Therefore, the gamma correction circuit 203 performs gamma correction so that the reflectance (or transmittance) characteristic of the liquid crystal panel is linear with respect to 256 density values represented by 8 bits for each color in the second digital video signal. Done.

  The gamma correction circuit 203 extends the RGB 24-bit second digital video signal to an RGB 30-bit video signal of 10 bits (1024 density values) for each color. This is because, in each of RGB, if a lookup table for gamma correction is configured with an output 256 density for an input 256 density, the same output value is often output for different input values. In this way, the gamma correction circuit 203 generates a third digital video signal whose bits are expanded and has a density value (gradation value) for each pixel corresponding to the VT characteristics of the liquid crystal panel.

  The third digital video signal output from the gamma correction circuit 203 is separated into R, G, and B video signals and input to color unevenness correction circuits (processing means) 204, 205, and 206.

  Each color unevenness correction circuit uses a third digital video signal and a color unevenness correction value for reducing the color unevenness of the display image (projected image) to provide a signal (correction for each pixel). A fourth digital video signal having a post-density value is generated. Specific processing in the color unevenness correction circuit will be described later.

  Reference numeral 220 denotes a CPU as a control means (controller) for controlling the operations of the resolution conversion circuit 202, the gamma correction circuit 203, and the color unevenness correction circuits 204 to 206.

  Reference numeral 221 denotes a non-volatile memory (for example, EEPROM) as storage means, which stores (holds) color unevenness correction values. The color unevenness correction value is given to the color unevenness correction circuits 204 to 206 via the CPU 220.

  The fourth digital video signal on which the color unevenness correction circuits 204, 205, and 206 have been subjected to the color unevenness correction process is supplied to the liquid crystal panels 210, 211, and 212 as panel drivers for R, G, and B. 207, 208, and 209. Each panel driver drives the liquid crystal panel by outputting a panel drive signal obtained by A / D converting the signal to the liquid crystal panel. Thus, R, G, and B liquid crystal images corresponding to the input video signal are formed in the image forming areas of the three liquid crystal panels 210, 211, and 212.

  Next, details of color unevenness correction processing will be described. Color unevenness correction processing is actually performed for each of R, G, and B colors. In the following, processing common to R, G, and B will be described.

  In this embodiment and the conventional color unevenness correction circuit, information on the density value for each pixel included in the third digital video signal, information on the pixel position on the liquid crystal panel obtained by the video synchronization signal and the pixel count, Capture. Then, a color unevenness correction amount as a color unevenness correction value is calculated from the pixel position and the density value, and is added to the density value for each pixel included in the third digital video signal, whereby the color unevenness correction is performed. A fourth digital video signal (having a corrected density value) is generated.

  Here, it is also possible to store the color unevenness correction amount in a lookup table format for all the RGB pixels. However, for example, if the density value is expanded from 8 bits to 10 bits by the gamma conversion, the number of color unevenness correction amounts required for the XGA standard projector is 1024 × 768 × 1024 × 3 = 24159919104. In this case, even if only 1 byte is assigned to the color unevenness correction amount, a table of about 2.4 GB is required, which is not realistic.

  Therefore, in the conventional color unevenness correction circuit, as shown in the upper side of FIG. 4, the vertical axis indicates density (gradation), and the horizontal two axes indicate the H direction coordinate position and the V direction coordinate position. Set the color unevenness correction space. Then, a color unevenness correction plane is set for each density (gradation) set at a predetermined density interval. In other words, the color unevenness correction plane is set in a plurality of gradations corresponding to the color density of the image formed on the liquid crystal panel or the display image as the projection image.

  In each color unevenness correction plane, the amount of color unevenness correction is set only for a plurality of specific pixels arranged at predetermined pixel intervals in the H direction coordinate and the V direction coordinate. Only the color unevenness correction amount for these specific pixels is held as table data. The color unevenness correction circuit includes two or more color unevenness correction planes on two or more color unevenness correction planes, unless the color unevenness correction described later is not performed on each pixel in the color unevenness correction plane and in the color unevenness correction space. A corrected density value is generated by an interpolation calculation using a color unevenness correction amount set for a specific pixel.

  4 is a diagram showing the arrangement of specific pixels on each conventional color unevenness correction plane when the resolution is XGA. Here, the pixel position takes a value from 0 to 1023 in the H direction and 0 to 767 in the V direction, and the density value takes a value from 0 to 1023. Four color unevenness correction planes 301, 302, 303, and 304 are set for the correction space. In each color unevenness correction plane, a color unevenness correction amount for the density value of the plane in a specific pixel is set. The intersection of meshes shown in each color unevenness correction plane corresponds to a specific pixel. In this example, specific pixels are arranged for every 128 pixels in the H direction and the V direction, respectively.

  On the other hand, in the color unevenness correction circuits 204, 205, and 206 of this embodiment, the following arrangement of specific pixels on each color unevenness correction plane is adopted when the resolution is XGA.

  On the upper side of FIG. 5, in this embodiment, four color unevenness correction planes 501 to 504 (ccLayer3) set for a plurality of (four) densities, that is, for each density (gradation) having a predetermined density interval. ~ CcLayer0). The uneven color correction planes ccLayer3, ccLayer2, ccLayer1, and ccLayer0 are assigned plane names in order from the higher (darker) side to the lower (lighter) side. The density corresponding to each color unevenness correction plane is ccLayer3 = 900, ccLayer2 = 600, ccLayer1 = 300, and ccLayer0 = 100. In addition, these density | concentrations are examples and can be changed arbitrarily. However, the relationship is 1023 ≧ ccLayer3 ≧ ccLayer2 ≧ ccLayer1 ≧ ccLayer0 ≧ 0. The color unevenness correction plane ccLayer3 corresponds to the highest density among the above four densities, and the color unevenness correction plane ccLayer0 corresponds to the lowest density.

  As shown in the lower side of FIG. 5, in the color unevenness correction plane 501 (ccLayer3 = 900), 2 × 2 (the number in the H direction × the number in the V direction: the same applies to the four corners of the color unevenness correction plane 501). ) Color unevenness correction amount C is set for each specific pixel. These four color unevenness correction amounts C are no correction value = 0 (same value) indicating that color unevenness correction is not performed. Due to the setting of the color unevenness correction plane 501, color unevenness correction is not performed regardless of the coordinate position for pixels having a density value of 900 or more in the input video signal (third digital video signal). However, setting the color unevenness correction amount C to an uncorrected value (= 0) is merely an example, and is set to a value for performing color unevenness correction, or at least one of the four color unevenness correction amounts C is set. It may be a value different from others. The same applies to the color unevenness correction plane 504 (ccLayer0 = 100) described later.

  In the color unevenness correction plane 502 (ccLayer2 = 600), color unevenness correction is performed for specific pixels (corresponding to the intersections of meshes in the color unevenness correction plane 502) arranged every 128 pixels in the H direction and the V direction. A quantity C is set. That is, the color unevenness correction amount C is set for 9 × 7 specific pixels.

  In the color unevenness correction plane 503 (ccLayer1 = 300), the color unevenness correction amount C is set for specific pixels arranged every 256 pixels in the H direction and the V direction. That is, the color unevenness correction amount C is set for 5 × 4 specific pixels.

  In the color unevenness correction plane 504 (ccLayer0 = 100), similarly to the color unevenness correction plane 501 (ccLayer3 = 900), the color unevenness correction amount C is set for 2 × 2 specific pixels. These color unevenness correction amounts C are uncorrected values = 0 (same values). Due to the setting of the color unevenness correction plane 504, color unevenness correction is not performed regardless of the coordinate position for pixels having a density value of 100 or less in the input video signal (third digital video signal).

  As described above, in this embodiment, the number of specific pixels for which the color unevenness correction value is set differs depending on the density (gradation) corresponding to the color unevenness correction planes 501 to 504. Also, the density (second gradation) in which the specific pixel number for which the color unevenness correction value is set in the color unevenness correction plane 503 is higher than the density (first gradation) corresponding to the color unevenness correction plane 503. Is smaller than the number of specific pixels for which the color unevenness correction value is set in the color unevenness correction plane 502 corresponding to. Further, the density (second gradation) in which the specific pixel number for which the color unevenness correction value is set in the color unevenness correction plane 504 is higher than the density (first gradation) corresponding to the color unevenness correction plane 504. Is less than the specific number of pixels for which the color unevenness correction value is set in the color unevenness correction plane 503. In the color unevenness correction planes 502 to 504, the number of specific pixels decreases as the density corresponding to the color unevenness correction plane decreases.

  Thereby, compared with the case where the same number of specific pixels and uneven color correction amounts are set in all the uneven color correction planes, the uneven color correction amount held in the memory 221 can be reduced, and the scale of the memory 221 ( Necessary storage capacity) can be reduced.

  FIG. 1 illustrates a data flow in the color unevenness correction process according to this embodiment.

  Reference numeral 101 denotes pixel density information indicating the density value for each pixel output from the gamma correction circuit 203 shown in FIG. 2, and takes a value of 0 to 1023 by 10 bits as the range of the density value.

  Reference numeral 102 denotes pixel position information indicating the pixel position on the liquid crystal panel (in the image forming area) corresponding to the pixel density information 101. This pixel position information is calculated from the H / V synchronization signal output from the gamma correction circuit 203 and the dot clock.

  Reference numeral 103 denotes a color unevenness correction amount (2 × 2) (no correction value) set in the color unevenness correction plane ccLayer3 held in the memory 221.

  However, the color unevenness correction amount 103 may be held as a hard-coded fixed value in the memory units 204a to 206a provided in the color unevenness correction circuits 204 to 206, as shown in FIG. Thereby, the color unevenness correction amount held in the memory 221 can be further reduced, and the scale of the memory 221 can be further reduced.

  Reference numeral 104 denotes a process for calculating a color unevenness correction amount for each pixel in the color unevenness correction plane ccLayer3. In this embodiment, since the color unevenness correction amount 103 is fixed to an uncorrected value, the uncorrected value is output regardless of the pixel position information.

  Reference numeral 105 denotes a color unevenness correction amount (9 × 7) set in the color unevenness correction plane ccLayer2 held in the memory 221.

  Reference numeral 106 denotes a process for calculating a color unevenness correction amount for each pixel in the color unevenness correction plane ccLayer2. In the process 106, the color unevenness correction amount for each pixel at the density corresponding to the color unevenness correction plane ccLayer2 is calculated from the color unevenness correction amount 105 and the pixel position information 102.

  Reference numeral 107 denotes a color unevenness correction amount (5 × 4) set in the color unevenness correction plane ccLayer1 held in the memory 221.

  Reference numeral 108 denotes a process for calculating a color unevenness correction amount for each pixel in the color unevenness correction plane ccLayer1. In the process 108, the color unevenness correction amount for each pixel at the density corresponding to the color unevenness correction plane ccLayer1 is calculated from the color unevenness correction amount 107 and the pixel position information 102.

  Reference numeral 109 denotes a color unevenness correction amount (2 × 2) (no correction value) set in the color unevenness correction plane ccLayer3 held in the memory 221.

  However, the color unevenness correction amount 109 may also be held as a hard-coded fixed value in the memory units 204a to 206a provided in the color unevenness correction circuits 204 to 206, similarly to the color unevenness correction amount 103. Thereby, the color unevenness correction amount held in the memory 221 can be further reduced, and the scale of the memory 221 can be further reduced.

  Reference numeral 110 denotes a process for calculating a color unevenness correction amount for each pixel in the color unevenness correction plane ccLayer0. In this embodiment, since the color unevenness correction amount 109 is fixed to an uncorrected value, an uncorrected value is output regardless of the pixel position information.

  The calculated color unevenness correction amount for each pixel in the color unevenness correction planes ccLayer3 to ccLayer0, the density value 112 corresponding to the color unevenness correction planes ccLayer3 to ccLayer0, and the pixel density information 101 are supplied to the color unevenness correction amount calculation process 111. Entered. Based on these input data (through the process 113 for adding the color unevenness correction amount and the pixel density information 101), the color unevenness correction amount calculation process 111 performs final pixel density information (the above-described corrected density value) 114. 'Is calculated. The pixel density information 114 ′ is included in the fourth digital video signal together with the pixel position information 115, and the fourth digital video signal is output to the panel driver together with the H / V synchronization signal and the dot clock. As a result, each liquid crystal panel is driven, and a color image with reduced color unevenness is projected onto the screen 240 shown in FIG.

  Although not described in detail here, a process for correcting a delay with respect to the synchronization signal caused by the calculation time of the uneven color correction amount is also performed.

  FIG. 6 shows a method of interpolation calculation of the color unevenness correction amount in the color unevenness correction space performed by each color unevenness correction circuit. Here, a case will be described in which the density value of the input image signal is 500, and the coordinates of the pixel that is subject to color unevenness correction are A (100, 200).

  In this case, the point A in the color unevenness correction space is sandwiched between the color unevenness correction plane ccLayer2 (= 600) and the color unevenness correction plane ccLayer1 (= 300). Therefore, the positions of the points Pz, Px0, Px1, Py0, and Py1 in the figure corresponding to the point A are calculated as follows. Note that z corresponds to the density direction, x corresponds to the H direction, and y corresponds to the V direction.

Pz = (500-300) / (600-300) = 0.667
Px0 = (100% 256) /256=0.391
Px1 = (100% 128) /128=0.781
Py0 = (200% 256) /256=0.781
Py1 = (200% 128) /128=0.563
However, “%” is a modulo operator.

  Then, by applying the values of Pz, Px0, Px1, Py0, and Py1 to the equations in the figure, linear interpolation calculation of the color unevenness correction amount C at the point A is performed. For the pixels other than the pixel at the point A, the color unevenness correction amount can be similarly calculated by linear interpolation.

  FIG. 7 is a flowchart showing processing in the process 104 shown in FIG. 1 performed using the color unevenness correction plane ccLayer3. The color unevenness correction plane ccLayer3 is the color unevenness correction plane corresponding to the highest density among the four color unevenness correction planes ccLayer3 to ccLayer0, and the color unevenness correction amount as an uncorrected value is set for the four specific pixels. ing.

  When this flow starts in S801, in S802, the process 104 (that is, the color unevenness correction circuit) acquires pixel position information. In step S <b> 803, the process 104 acquires a color unevenness correction amount (both uncorrected values) corresponding to the pixel position information. In step S804, the process 104 outputs the acquired color unevenness correction amount to the process 111 illustrated in FIG. 1, and the flow ends in step S805. Note that the processing shown in this flowchart may be executed by a computer program or hardware. The same applies to other processes described later.

  FIG. 8 is a flowchart showing processing in the process 106 shown in FIG. 1 performed using the color unevenness correction plane ccLayer2. In the color unevenness correction plane ccLayer2, color unevenness correction amounts are set for 63 specific pixels.

  When this flow starts in S901, in S902, the process 106 (that is, the color unevenness correction circuit) acquires pixel position information (x, y). Next, in S903, the process 106 reads the color unevenness correction amount (shown as c in FIG. 8) set for the 63 specific pixels on the color unevenness correction plane ccLayer2 as color unevenness correction table data.

  Next, in step S904, the process 106 uses the color unevenness correction table data and the arithmetic expression shown in the drawing to correct the color unevenness correction amount on the color unevenness correction plane ccLayer2 corresponding to the pixel position information (x, y). Is obtained (interpolation calculation). In step S905, the process 106 outputs the acquired color unevenness correction amount to the process 111 illustrated in FIG. 1, and ends this flow in step S906.

  FIG. 9 is a flowchart showing processing in the process 108 shown in FIG. 1 performed using the color unevenness correction plane ccLayer1. In the color unevenness correction plane ccLayer1, color unevenness correction amounts are set for 20 specific pixels.

  When this flow starts in S1001, in S1002, the process 108 (that is, the color unevenness correction circuit) acquires pixel position information (x, y). Next, in S1003, the process 108 reads the color unevenness correction amount (shown as c in FIG. 9) set for 20 specific pixels on the color unevenness correction plane ccLayer1 as color unevenness correction table data.

  Next, in S1004, the process 108 uses the color unevenness correction table data and the arithmetic expression shown in the drawing to correct the color unevenness correction amount on the color unevenness correction plane ccLayer1 corresponding to the pixel position information (x, y). Is obtained (interpolation calculation). In step S1005, the process 108 outputs the acquired color unevenness correction amount to the process 111 illustrated in FIG. 1, and ends this flow in step S1006.

  FIG. 10 is a flowchart showing the process in the process 110 shown in FIG. 1 performed using the color unevenness correction plane ccLayer0. The color unevenness correction plane ccLayer0 is a color unevenness correction plane corresponding to the lowest density among the four color unevenness correction planes ccLayer3 to ccLayer0, and the color unevenness correction amount as an uncorrected value is set for four specific pixels. ing.

  When this flow starts in S1101, in S1102, the process 110 (that is, the color unevenness correction circuit) acquires pixel position information. Next, in S1103, the process 110 acquires a color unevenness correction amount (both are uncorrected values) corresponding to the pixel position information. In step S1104, the process 108 outputs the acquired color unevenness correction amount to the process 111 illustrated in FIG. 1, and ends this flow in step S1105.

  FIG. 11 is a flowchart showing processing in the color unevenness correction amount calculation process 111 shown in FIG.

  When this flow is started in S1201, in S1202, the process 111 (that is, the color unevenness correction circuit) acquires pixel density information d. In step S1203, the process 111 acquires the color unevenness correction amounts cc3 to cc0 for the color unevenness correction planes calculated in the processes 104, 106, 108, and 110 by the processes illustrated in FIGS. Furthermore, in S1204, the process 111 acquires density values L3 to L0 corresponding to the color unevenness correction planes ccLayer3 to ccLayer0.

  In step S1205, the process 111 determines whether the acquired pixel density information d is a value equal to or higher than the density value L3 corresponding to the color density correction plane ccLayer3 having the highest density. If the pixel density information d is greater than or equal to the density value L3, the process proceeds to S1206, and the color unevenness correction amount cc3 (no correction value) set in the color unevenness correction plane ccLayer3 is used as the final color unevenness correction amount. To do.

  When the pixel density information d is a value smaller than the density value L3, the process proceeds to S1207. In step S1207, the process 111 determines whether or not the pixel density information d is a value equal to or higher than the density value L2 corresponding to the color unevenness correction plane ccLayer2. If the pixel density information d is greater than or equal to the density value L2, the process proceeds to S1208, and a final color unevenness correction amount is calculated by linear interpolation calculation in the color unevenness correction space described above.

  When the pixel density information d is a value smaller than the density value L2, the process proceeds to S1209. In step S1209, the process 111 determines whether the pixel density information d is a value equal to or higher than the density value L1 corresponding to the color unevenness correction plane ccLayer1. If the pixel density information d is greater than or equal to the density value L1, the process proceeds to S1210, and a final color unevenness correction amount is calculated by linear interpolation calculation in the color unevenness correction space described above.

  If the pixel density information d is smaller than the density value L1, the process proceeds to S1211. In S1211, the process 111 determines whether or not the pixel density information d is larger than the density value L0 corresponding to the color unevenness correction plane ccLayer0. If the pixel density information d is larger than the density value L0, the process proceeds to S1212, and the final color unevenness correction amount is calculated by the linear interpolation calculation in the color unevenness correction space described above.

  When the pixel density information d is a value equal to or lower than the density value L0, the process proceeds to S1213. In S1213, the process 111 adopts the calculated color unevenness correction amount cc0 (no correction value) set in the color unevenness correction plane ccLayer0 as the final color unevenness correction amount.

  When the final color unevenness correction amount is calculated in this way, the process 111 outputs the color unevenness correction amount in S1214, and ends this flow in S1215.

  The embodiments described above are merely representative examples, and various modifications and changes can be made to the embodiments when the present invention is implemented.

  In the above-described embodiment, in all of R, G, and B, the number of specific pixels (that is, the color unevenness correction amount) set in the color unevenness correction plane corresponding to the same density (gradation) is the same. explained. However, the number of specific pixels on the color unevenness correction plane corresponding to the same density in R, G, and B may be different. For example, considering human visual characteristics, R and B have inferior human frequency sensitivity characteristics compared to G. Therefore, the specific number of pixels on the color unevenness correction plane in R and B is determined in G. It may be less than the specific number of pixels on the color unevenness correction plane corresponding to the same density.

  Although the projector has been described in the above embodiments, the present invention can also be applied to a display device that directly observes an image formed on an image forming element such as an LCD.

The data flow figure of the color nonuniformity correction circuit in the Example of this invention. FIG. 2 is a diagram illustrating an electrical configuration of a projector that is an embodiment. FIG. 2 is a diagram illustrating an optical configuration of a projector that is an embodiment. The figure which shows the concept of the color nonuniformity correction process in the past. The figure which shows the concept of the color nonuniformity correction process in an Example. The figure which shows the linear interpolation method of the color nonuniformity correction amount in an Example. 7 is a flowchart illustrating a process for calculating a color unevenness correction amount in a color unevenness correction plane ccLayer3 in the embodiment. 7 is a flowchart illustrating a process for calculating a color unevenness correction amount in a color unevenness correction plane ccLayer2 in the embodiment. 7 is a flowchart illustrating a process for calculating a color unevenness correction amount in a color unevenness correction plane ccLayer1 in the embodiment. 9 is a flowchart illustrating a process for calculating a color unevenness correction amount in a color unevenness correction plane ccLayer0 in the embodiment. 6 is a flowchart illustrating a final color unevenness correction amount calculation process in the embodiment.

Explanation of symbols

201 Video signal 202 Resolution conversion circuit 203 Gamma correction circuit 204 Color unevenness correction circuit (R)
205 Color unevenness correction circuit (G)
206 Color unevenness correction circuit (B)
207 Panel driver (R)
208 Panel driver (G)
209 Panel driver (B)
210 LCD panel (R)
211 LCD panel (G)
212 LCD panel (B)
221 Nonvolatile memory

Claims (11)

An image forming element for forming an image;
Processing means for generating a signal given to the image forming element using an input image signal and a color unevenness correction value for reducing color unevenness of a display image;
The color unevenness which is set for each of a plurality of specific pixels arranged at intervals among the pixels forming the display image and is used for calculating the color unevenness correction value for a pixel different from the specific pixel. Storage means for storing the correction value for each of the plurality of gradation values ,
The number of the specific pixels is different depending on the gradation value . The number of the specific pixels in the first grayscale value among the plurality of gradation values is less than the number of the specific pixels in the second gradation value higher than the first gradation value The display device according to claim 1.   The said processing means calculates the color unevenness correction value of each pixel of the image forming element by an interpolation operation using the color unevenness correction value stored in the storage means. The display device described. 4. The color unevenness correction value set for the plurality of specific pixels at the lowest gradation value among the plurality of gradation values is the same as each other. 5. The display apparatus as described in any one. 5. The display device according to claim 4, wherein the color unevenness correction value set for the plurality of specific pixels at the lowest gradation value is an uncorrected value. 6. The display device according to claim 4, wherein the color unevenness correction value set for the plurality of specific pixels at the lowest gradation value is a hard-coded fixed value. At the highest gradation value among the plurality of tone values, the color non-uniformity correction value set for the plurality of specific pixel is one of claims 1 to 6, characterized in that the same value to each other The display apparatus as described in any one. The display device according to claim 7, wherein the color unevenness correction value set for the plurality of specific pixels at the highest gradation value is an uncorrected value. 9. The display device according to claim 7, wherein the color unevenness correction value set for the plurality of specific pixels at the highest gradation value is a hard-coded fixed value.   The display device according to claim 1, wherein the image signal is a signal that has been gamma-corrected according to a reflectance or transmittance of the image forming element.   As the image forming element,
  An image forming element for green that forms a green image;
  An image forming element for red that forms a red image;
  It has a blue image forming element that forms a blue image,
  In a specific gradation value among the plurality of gradation values, the number of the specific pixels in the image forming element for red or blue is smaller than the number of the specific pixels in the image forming element for green. The display device according to claim 1, wherein the display device is a display device.