JP2006153914A - Liquid crystal projector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To attain a high quality projecting image by correcting color unevenness of a liquid crystal panel and simultaneously removing luminance unevenness due to an integrator optical system. <P>SOLUTION: By adding a luminance unevenness correction look-up-table (LUT) data T2 which are generated using a luminance unevenness measuring camera in which shading is known, to a color unevenness correction LUT data T1 by an ordinary color unevenness measuring camera which is used in a conventional method, an illumination unevenness correction LUT data T3 for correcting two dimensional color unevenness and luminance unevenness to horizontal/vertical directions of the liquid crystal panel, according to an illumination level of an input image signal, are generated. By using the illumination unevenness correction data stored in the LUT in a liquid crystal projector, the two dimensional color unevenness and luminance unevenness are corrected to make conversion to a uniform image. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a liquid crystal projector apparatus including illuminance unevenness correcting means capable of correcting brightness unevenness.

  In the case of displaying an image using a liquid crystal panel, the occurrence of uneven color cannot be avoided.

  FIG. 7 shows an example in which color unevenness due to the non-uniformity of the gap of the liquid crystal panel has occurred. (A) is a uniform 50% gray image that is an input image to the liquid crystal projector device, and (b) is a projection image in the projector device, and the upper right part is slightly red and the lower left part is slightly blue. An example of the occurrence is shown.

  FIG. 8 is an explanatory diagram of color unevenness correction, and a table of color unevenness correction values for correcting the color unevenness occurrence example shown in FIG. FIG. 8A shows color unevenness correction values for red (R), and similarly, (b) and (c) show color unevenness correction values for green (G) and blue (B). In these examples, 9 correction points in the horizontal direction and 7 correction points in the vertical direction are possible, and each correction point has a correction value in the plus / minus direction.

  In order to correct the red color unevenness in the upper right that exists in the example of FIG. 7B, the R color unevenness correction value is corrected in the negative direction so that the upper right suppresses the intensity of red. In order to correct the color unevenness, the B color unevenness correction value is corrected in the minus direction so that the lower left part suppresses the intensity of blue. Note that for the sake of simplicity, correction is made only in the negative direction of R and B. However, in order to prevent the illuminance level from actually changing, all of RGB are also adjusted in the positive direction to correct color unevenness. There are many.

  FIG. 9 is an explanatory diagram of a color unevenness correction LUT (lookup table), and there are three correction values described in FIG. 8 according to the level of the input image. As shown in FIG. 8, there are nine correction points in the horizontal direction and seven correction points in the vertical direction, so that the total number of correction points is nine. 7 · 3 · 3 = 567. That is, there are a total of 567 color unevenness correction values in the plus / minus direction.

  This color unevenness correction LUT takes a single color image at a plurality of illuminances projected by the liquid crystal projector device with a color unevenness measuring camera, analyzes the output RGB data of the color unevenness measuring camera with a PC (personal computer), The color unevenness correction LUT built in the liquid crystal projector device is adjusted so as to reduce unevenness, the projected image after the color unevenness correction LUT is changed is picked up again by the color unevenness measuring camera, and the image data is analyzed by the PC. Such a procedure is repeated, and the color unevenness correction LUT is adjusted so that the color unevenness is corrected.

  In general, since the camera imaging data for measuring color unevenness contains the shading component of the camera lens, the reliability of the illuminance difference at each color unevenness correction point is often low, and the illuminance at the color unevenness correction point is low. In order not to change, only RGB color balance correction is often performed.

  According to the illuminance level of the input video signal, the two-dimensional color unevenness in the horizontal / vertical direction of the liquid crystal panel having the color unevenness correction LUT is stored in the color unevenness stored in the LUT included in the color unevenness correction circuit. Using the correction data, color unevenness correction processing is performed in which color unevenness is corrected two-dimensionally and converted into a uniform image. Such a technique is described in Patent Document 1.

Japanese Patent Application Laid-Open No. 09-146497

  However, in the above-described conventional method, it is possible to correct the color unevenness caused by the non-uniformity of the gap of the liquid crystal panel, but the brightness unevenness caused by the integrator optical system that irradiates the liquid crystal panel with the light of the lamp. It cannot be removed.

  FIG. 10 is an example of remaining luminance unevenness after color unevenness correction. When the image of FIG. 10A is input, uneven luminance and uneven color occur as shown in FIG. ), Uneven luminance remains even after the uneven color correction, and there is a problem that the image quality of the projected image becomes low quality.

  An object of the present invention is to provide a liquid crystal projector that can solve the above-described problems and can correct illuminance unevenness including color unevenness and brightness unevenness.

  The technical feature of the liquid crystal projector device according to the present invention for achieving the above object is that it is possible to reduce both the amount of luminance unevenness and the amount of color unevenness, and the amount of unevenness correction at a plurality of illuminance levels. Illuminance unevenness correction circuit that corrects luminance unevenness distributed at a ratio independent of the illuminance level and color unevenness that changes from the illuminance level by using the lookup table correction amount, and light by the applied voltage. A liquid crystal projector device including a liquid crystal panel having a variable transmittance, wherein one luminance unevenness correction pattern generated from one pattern of luminance unevenness obtained from a projection screen and a plurality of patterns of colors at a plurality of illuminance levels From the plurality of uneven color correction patterns generated by the unevenness, the inclination angle and the illuminance rate of the applied voltage versus transmittance characteristic of the liquid crystal panel are determined. Generating an illuminance unevenness correction pattern table corresponding to a plurality of illuminance levels for reducing the amount of luminance unevenness and the amount of color unevenness generated, and the lookup table in which the illuminance unevenness correction pattern table is recorded is generated. The object of the present invention is to have means for reducing the amount of uneven illuminance generated using the uneven illuminance correction amount.

  A technical feature of the liquid crystal projector according to the present invention is an image display device that has at least one liquid crystal panel and displays an image using light from the liquid crystal panel, and the at least one liquid crystal panel. A voltage applying circuit for applying a voltage to the at least one liquid crystal panel, and correcting means for reducing the amount of luminance unevenness based on the voltage applied to the at least one liquid crystal panel.

  According to the liquid crystal projector device of the present invention, it is possible to reduce the amount of color unevenness caused by the liquid crystal panel and at the same time reduce the amount of uneven brightness generated, thereby obtaining a high-quality projected image quality.

  The present invention will be described in detail based on the embodiment shown in FIGS.

  In FIG. 1, red (R) signal / green (G) signal / blue (B) signal, which are three kinds of color signals that have passed through a PC input terminal 1, are connected to an input selector 3 via an AD converter 2. . On the other hand, a video composite signal in which the luminance (Y) signal and the modulated color (C) signal are combined through the video input terminal 4 or a video in which the luminance (Y) signal and the modulated color (C) signal are separated. The S signal is similarly connected to the input selector 3 via the AD converter 5 and the video decoder 6.

  The output of the input selector 3 is connected to the video signal processing circuit 8 through the matrix circuit 7, and the video signal processing circuit 8 is connected to the frame memory 9. The output of the video signal processing circuit 8 is connected to three liquid crystal panels 13 via a VT (applied voltage versus transmittance) correction circuit 10, an illuminance unevenness correction circuit 11, and a liquid crystal driver 12.

  On the other hand, the output of the power source 14 is connected to the lamp 16 via the lamp driving circuit 15, and the integrator optical system 17, the liquid crystal panel 13, the projection lens 18, and the screen 19 are arranged in the light projection direction of the lamp 16.

  The PC video data input to the PC input terminal 1 is converted into a digital PC (R / G / B) signal by the AD converter 2 and input to the input selector 3. On the other hand, the video signal input from the video input terminal 4 is converted into a digital video signal by the AD converter 5, and when the input video signal is a composite signal by the video decoder 6, YC separation processing and color decoding processing are performed. Is called. Further, when the input video signal is an S video signal, color decoding processing is performed, and when the input video signal is a component video signal, no processing is performed as it is, and the luminance signal is output from the video decoder 6. And two kinds of color difference signals are output.

  As an output of the video decoder 6, a video input is selected by the input selector 3, and luminance and two kinds of color difference signals are converted into RGB signals by the matrix circuit 7. The input selector 3 selects a digital video signal output from the video decoder 6 and a digital PC (R / G / B) signal output from the AD converter 2. When the digital video signal is input, the matrix circuit 7 converts the luminance signal and the two kinds of color difference signals into RGB signals that are three kinds of color signals of red (R) / green (G) / blue (B). .

  The output of the matrix circuit 7 converted to the RGB signal is input to the video signal processing circuit 8, and when the input video signal is an interlace signal, the interlace / progressive conversion process is performed using the frame memory 9. Thus, it is converted into a progressive signal and converted into a frame rate and image resolution that can be driven by the liquid crystal panel 13.

  The video signal processing circuit 8 also performs interlace / progressive conversion processing for converting an interlaced video signal formed so as to be displayed by interlaced scanning into a progressive signal that is progressively scanned, and the frame frequency of the input video signal is liquid crystal. Digital RGB signals such as a frame rate conversion process for converting to a frame frequency that can be driven by the panel 13 and a resolution conversion process for converting the resolution of the input video signal to a resolution that can be driven by the liquid crystal panel 13 are suitable for the projector apparatus. Signal processing to convert the signal into

  The frame memory 9 can record RGB signals which are three kinds of color signals of one frame or more, and the RGB signals are used for signal processing when the video signal processing circuit 8 converts the signals into signals suitable for the projector apparatus. Is done. The VT correction circuit 10 corrects the output of the video signal processing circuit 8 with the “input voltage (V) vs. light transmittance (T)” characteristic, which is the light transmittance with respect to the input voltage of the liquid crystal panel 13, and the image input level is corrected. The illuminance is converted into illuminance corresponding to human vision and output to the illuminance unevenness correction circuit 11.

  The illuminance unevenness correction circuit 11 stores two-dimensional color unevenness and luminance unevenness in the horizontal / vertical direction of the liquid crystal panel 13 in a built-in LUT (look-up table) according to the illuminance level of the input video signal. Illuminance unevenness correction data obtained by adding brightness unevenness correction data to color unevenness correction data is used to correct color unevenness and brightness unevenness and convert it to a uniform image. In the present invention, it is not necessary to completely correct two-dimensional color unevenness and luminance unevenness, and at least the amount of occurrence of color unevenness and luminance unevenness can be reduced. Yes.

  The liquid crystal driver 12 that has received the output of the illuminance unevenness correction circuit 11 inverts the polarity at a specified timing by a built-in inverting circuit and performs serial / parallel processing for conversion to a data rate that can be driven by the liquid crystal panel 13. 13 is driven.

  The lamp driving circuit 15 generates a stable high voltage to be supplied to the lamp 16 based on the power supplied from the power source 14. The integrator optical system 17 converts the light projected from the lamp 16 into uniform light, and the liquid crystal panel 13 converts the light projected from the lamp 16 via the integrator optical system 17 into three colors R / G / B joined. Through the filter, light is transmitted and blocked corresponding to the three color RGB images. The projection lens 18 forms images of the three color images that have passed through the liquid crystal panel 13 onto the screen 19 and changes the size of the projection image, thereby forming an image on the screen 19 in accordance with the input switching signal.

  FIG. 2 is an explanatory diagram of a method of generating an illuminance unevenness correction LUT built in the illuminance unevenness correction circuit 11. The uneven illuminance referred to here is uneven color due to the liquid crystal panel 13 and uneven brightness due to the integrator optical system 17.

  The color nonuniformity correction LUT data T1 (correction pattern) obtained by a normal color nonuniformity measurement camera used in the conventional method is generated using a luminance nonuniformity measurement camera with known shading as a camera generated by this method. Luminance unevenness correction LUT data T3 (correction pattern) is generated by adding the brightness unevenness correction LUT data T2 (correction pattern).

  FIG. 3 is an explanatory diagram of means for obtaining luminance unevenness data. A white image with 90% illuminance projected on the screen 22 by the liquid crystal projector device 21 is captured by the luminance unevenness measuring camera 23, and the obtained output RGB data is analyzed by the PC 24. The PC 24 measures the shading characteristics of the luminance unevenness measuring camera 23 in advance, adds the shading correction data created from the measurement results to the output RGB data, and deletes the shading component of the luminance unevenness measuring camera 23.

  FIG. 4 is a graph showing applied voltage versus transmittance characteristics of the liquid crystal panel 13 for generating the luminance unevenness correction LUT data T2. The luminance unevenness due to the integrator optical system 17 obtained by the method of FIG. 3 becomes a fixed ratio regardless of the illuminance level. For example, assuming that the luminance unevenness at 90% illuminance is 1, the luminance unevenness at 45% illuminance is 0.5, and the luminance unevenness at 22.5% illuminance is 0.25. In addition, the inclination angle of the light transmittance T with respect to the input level V of the liquid crystal panel 13 is 2 when the inclination at 90% illuminance is 1, and 1.6 at the 22.5% illuminance ratio.

  In this way, using the output RGB data from which the shading component of the measurement camera 23 is removed, luminance unevenness correction data at 90% illuminance rate is generated for the three RGB data. Then, as shown in FIG. 2, the color unevenness correction LUT data T3 at the three types of input image levels shown in FIG. 9 is generated, and the illuminance rate at the input image level is 90%, 45%, 22.5%. It is said.

  FIG. 5 is another explanatory diagram of a method for generating uneven illuminance correction LUT data T3. The R luminance unevenness correction value at the 90% illuminance rate is obtained by removing a shading component from the output R data of the luminance unevenness correcting camera 23 and generating a correction value. This R luminance unevenness correction value is multiplied by the illuminance unevenness ratio and the reciprocal of the inclination angle of the light transmittance with respect to the input level of the liquid crystal panel 13 to generate each R luminance unevenness correction value at 90%, 45% and 22.5%. To do.

  FIG. 6 is still another explanatory view of the method for generating the uneven illuminance correction LUT data T3. The 90%, 45%, and 22.5% R luminance unevenness correction values are added to the 90%, 45%, and 22.5% R color unevenness correction values generated by the conventional method. %, And 22.5%, each R illuminance unevenness correction value is generated. The same processing is performed for G and B, and a G illuminance unevenness correction value and a B illuminance unevenness correction value are generated.

  This example can be described as follows. The image display apparatus of this embodiment (which may be referred to as a liquid crystal projector apparatus or simply a projector) has at least one liquid crystal panel, and uses only one liquid crystal panel, and superimposes a plurality of colors in a time-division manner. Alternatively, the three liquid crystal panels may be used to display the image by combining the color lights from the three liquid crystal panels, and there may be no problem even if four or more liquid crystal panels are used. An image display device that displays an image using light from at least one liquid crystal panel, based on an image signal input to the image display device from a computer, a TV, a video deck, an antenna, a TV tuner, or the like. A voltage application circuit that applies a voltage to at least one liquid crystal panel and a correction unit that reduces the amount of luminance unevenness based on the voltage applied to the at least one liquid crystal panel may be provided.

  Here, it is more preferable that the correction means reduce the amount of color unevenness in accordance with the voltage applied to at least one liquid crystal panel and / or the brightness of an image displayed by the device. Further, the correcting means determines the amount of color unevenness based on a plurality of different types of color unevenness correction patterns according to the voltage applied to at least one liquid crystal panel and / or the brightness of an image displayed by the liquid crystal panel. You may comprise so that it may reduce.

  In the embodiment described here, a liquid crystal panel is used, and the transmittance is changed according to the voltage applied to the liquid crystal panel. However, such an image display device is not a liquid crystal panel. However, if a panel composed of an element that modulates the light that occurs in the same manner is used, the same problem occurs, and it goes without saying that the same solution as in this embodiment can be achieved.

It is a block diagram of the liquid crystal projector apparatus of an Example. It is explanatory drawing of illumination intensity nonuniformity correction | amendment LUT. It is explanatory drawing of a means to obtain brightness nonuniformity data. It is an applied voltage vs. transmittance characteristic diagram of a liquid crystal panel. It is explanatory drawing of the production | generation method of other illumination intensity nonuniformity correction | amendment LUT data. It is explanatory drawing of the production | generation method of other illumination intensity nonuniformity correction | amendment LUT data. It is explanatory drawing of the example of color nonuniformity generation | occurrence | production. It is explanatory drawing of color nonuniformity correction. It is explanatory drawing of color unevenness correction | amendment LUT. It is explanatory drawing of the residual example of the brightness nonuniformity after color nonuniformity correction | amendment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 PC input terminal 2, 5 A / D converter 3 Input selector 4 Video input terminal 6 Video decoder 7 Matrix circuit 8 Video signal processing circuit 9 Frame memory 10 Illuminance unevenness correction circuit 12 Liquid crystal driver 13 Liquid crystal panel 14 Power supply 15 Lamp drive circuit 16 Lamp 17 Integrator optical system 18 Projection lens 19, 22 Screen 21 Liquid crystal projector 23 Camera for measuring uneven brightness

Claims (6)

  It is possible to reduce both the amount of luminance unevenness and the amount of color unevenness, record the amount of illuminance unevenness correction at multiple illuminance levels in a lookup table, and use the lookup table correction amount to illuminance level A projection screen comprising: a luminance unevenness correcting circuit that corrects luminance unevenness distributed at a ratio independent of light intensity and color unevenness that changes from an illumination level; and a liquid crystal panel that changes light transmittance according to an applied voltage. From one luminance unevenness correction pattern generated from one pattern of luminance unevenness obtained from the above and a plurality of color unevenness correction patterns generated by a plurality of color unevenness correction patterns at a plurality of illuminance levels. A plurality of illuminance levels that reduce the amount of luminance unevenness and the amount of color unevenness by using the tilt angle and the illuminance rate of the transmittance characteristic. And a means for reducing the amount of illuminance unevenness generated using the illuminance unevenness correction amount of the lookup table in which the illuminance unevenness correction pattern table is recorded. A liquid crystal projector device.   The illuminance unevenness correction pattern table generates a first coefficient generated from the reciprocal of the inclination angle of the applied voltage versus transmittance characteristic of the liquid crystal panel, and the one luminance unevenness correction pattern obtained from the projection screen. A second coefficient generated from a ratio between the illuminance level projected at the time and the illuminance level on which a look-up table in which luminance unevenness and color unevenness correction patterns are recorded is calculated, and the first coefficient 2. The liquid crystal projector device according to claim 1, wherein the brightness unevenness correction pattern is multiplied by the second coefficient and the uneven brightness correction pattern is added to the result of the multiplication. .   2. The liquid crystal projector according to claim 1, wherein the brightness unevenness of the white image projected on the screen is measured by a brightness unevenness correcting camera, and the brightness unevenness correction pattern is generated based on the measured value.   An image display device having at least one liquid crystal panel and displaying an image using light from the liquid crystal panel, the voltage applying circuit for applying a voltage to the at least one liquid crystal panel, and the at least one liquid crystal An image display apparatus comprising: correction means for reducing the amount of luminance unevenness based on a voltage applied to the panel.   The correction means reduces the amount of color unevenness according to a voltage applied to the at least one liquid crystal panel and / or brightness of an image displayed on the liquid crystal panel. The image display device described in 1.   The correction means generates the color unevenness based on a plurality of different color unevenness correction patterns according to a voltage applied to the at least one liquid crystal panel and / or brightness of an image displayed on the liquid crystal panel. The image display device according to claim 4, wherein the amount is reduced.