JP2006254238A - Circuit and method of flare correction for image display apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a flare correction circuit for an image display apparatus and flare correction method for the image display apparatus, with which the band and gain of flare correction can be controlled automatically according to ambient light. <P>SOLUTION: An ambient light detection unit 51 measures ambient lightness using a built-in lightness measuring sensor and outputs information on the measured lightness to a flare correction amount determination unit 52. In the flare correction amount determining unit 52, the controlled variable of the flare correction amount, corresponding to the ambient environmental lightness, is calculated and outputted to a flare correction circuit 20 by a determination circuit using operation, based on the formula stored, in advance or a look-up table, set in advance. The flare correction circuit 20 controls the band and the gain of flare correction and outputs the results to an image processing unit 30. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a flare correction circuit for an image display device and a flare correction method for an image display device, and more particularly to a flare correction circuit for an image display device that adjusts a flare correction amount according to ambient brightness and a flare method for an image display device. .

  In a projector or the like having a large image surface, in order to obtain a high quality screen, it is necessary to meet the demand for image quality improvement as the number of scanning lines increases. As for the improvement in image quality, for example, as shown in FIG. 5, the peripheral portion 61 has a predetermined color, and the central portion 62 displays an edge that is a different color from the peripheral portion 61. A phenomenon called flare in which the portion 63 is blurred occurs. FIG. 6 is a schematic diagram of an image for explaining the flare phenomenon caused by the lens of light output. The flare phenomenon is a phenomenon in which the edge portion 63 that is a boundary portion having a large luminance difference or chromaticity difference is blurred due to a finite MTF (spatial frequency characteristic) of the projection lens.

  FIG. 7 is an explanatory diagram of a video signal for correcting flare by the optical output lens of FIG. 6, (a) is a normal video signal, and (b) is a video signal corrected for flare correction. It is. The video signal corresponding to the horizontal scanning line 64 in FIG. 5 is a rectangular pulse signal as shown in FIG. 7A when the peripheral portion 61 is black and the central portion 62 is white. . When this is converted into a signal that emphasizes the frequency components in the middle and high frequencies such as the corrected video signal 72 shown in FIG. 7B and displayed on the irradiation surface, a portion having a large luminance difference or chromaticity difference is displayed. Also become clearer. Therefore, the effect of flare can be reduced by performing such correction on the video signal. Such correction is referred to as flare correction in this specification.

Devices that perform video signals are disclosed in Patent Document 1, Patent Document 2, and Patent Document 3.
Japanese Unexamined Patent Publication No. 61-270993 JP-A-61-87493 JP-A-1-246984

In the apparatus described in Patent Document 1, when performing flare correction, a method in which a viewer manually adjusts a gain to a desired setting is performed.
As in the apparatus described in Patent Document 1, flare correction in which only the gain is adjusted, although the blur of the edge portion is eliminated to some extent, there is a problem that glare may increase on the contrary.
In addition, the flare phenomenon occurs when the MTF of the projection lens is finite, and is inherently caused only by the performance of the projection lens regardless of the surrounding environment (such as ambient brightness). However, in reality, the feeling that the flare gives to the viewer changes depending on the environmental conditions such as ambient light at that time. Therefore, the apparatus described in Patent Document 1 has a problem that the viewer has to manually adjust the setting according to the ambient brightness.

  An object of the present invention is to provide a flare correction circuit of an image display device that adjusts a band of a flare correction circuit in flare correction. Alternatively, an object of the present invention is to provide a flare correction circuit for an image display device and a flare correction method for an image display device that automatically adjust the band of the flare correction circuit in response to ambient light.

The flare correction circuit of the image display apparatus of the present invention is
In the image display device in which the video signal flare corrected by the flare correction circuit is output to the image processing unit, the band of the flare correction circuit is adjusted.

  In another aspect, in the image display device in which the video signal that has been subjected to the flare correction by the flare correction circuit is output to the image processing unit, the gain and the band in the flare correction circuit are adjusted.

  In the image display device in which the video signal flare corrected by the flare correction circuit is output to the image processing unit, the band of the flare correction circuit may be automatically adjusted according to the brightness of the ambient light. The brightness of the ambient light may be detected by the ambient light detection unit, and the band may be calculated from the ambient light brightness by the flare correction amount determination unit based on a calculation based on a pre-stored calculation formula. May be measured by the ambient light detection unit, and the band may be calculated from the ambient light brightness based on a preset lookup table by the flare correction amount determination unit.

  The ambient light detection unit may include a phototransistor, the flare correction amount determination unit may be configured by any one of an analog circuit, a digital circuit, and a CPU, and the ambient light detection unit is an image display device. It may be provided in the upper part, or may be provided in a remote controller that controls the image display device.

The flare correction method of the image display apparatus of the present invention is
The band of the flare correction circuit corresponding to the ambient brightness is calculated by one of the step of measuring the brightness of the periphery of the image display device, a calculation using a pre-stored calculation formula, and a preset lookup table. And a step of performing flare correction of the video signal output to the image processing unit according to the calculated band.

  Since the correction amount of the flare correction is adjusted according to the ambient lightness, the flare correction corresponding to the viewer's sense is performed corresponding to the ambient lightness.

  The present invention adjusts the band in the flare correction circuit, so that an image display apparatus equipped with a flare correction function can obtain an appropriate contrast feeling according to ambient light.

  In this embodiment, the intensity of ambient light is detected by a sensor, and the gain and band of the flare correction circuit are automatically adjusted to a desired amount for vision according to the intensity of ambient light. The flare correction is a video signal correction for increasing the apparent contrast. For example, in an environment where the room is bright, an appropriate contrast feeling according to the ambient light can be automatically obtained by automatically increasing the gain and band of the flare correction circuit compared to a dark environment.

  Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic block diagram for explaining a flare correction circuit according to an embodiment of the present invention.

  The flare correction circuit 10 includes a first A / D converter 11 and a second A / D converter 12 to which an R color video signal 1a, a G color video signal 2a, and a B color video signal 3a, which are video signals of three primary colors, are respectively input. The third A / D converter 13, the flare correction amount determination unit 52, and the flare correction unit 20 that outputs the three primary color video signals 1b, 2b, and 3b corrected by performing flare correction on the input video signal. Have

  The ambient light detector 51 includes an ambient lightness measurement sensor that measures the light intensity corresponding to the brightness around the display device 40. The flare correction amount determination unit 52 determines the band and gain of the flare correction circuit for obtaining a desired contrast corresponding to the ambient environment lightness based on the ambient environment lightness detected by the ambient light detection unit 51, and the signal is flare-removed. Output to the correction unit 20. The video signals of the three primary colors that have been subjected to the flare correction of the band and gain based on the signal from the flare correction amount determination unit 52 are sent from the flare correction unit 20 to the image processing unit 30. The image processing unit 30 performs necessary processing and sends the output video to the display device 40. For example, a phototransistor is used as the ambient lightness measurement sensor.

  As the flare correction circuit 10, for example, a circuit such as a television image quality improvement device described in Patent Document 1 can be applied, and a detailed description thereof is omitted here, but a basic circuit of the flare correction unit 20 is used. Is as shown in FIG. FIG. 2 is a block diagram of a schematic basic circuit for flare correction for each color video signal in the flare correction unit. The flare correction unit 20 includes a delay circuit 21, a vertical LPF (low-pass filter) unit 22, a horizontal LPF unit 23, a cutoff frequency setting unit 24, synthesis circuits 25 and 28, a gain setting unit 26, and a coefficient circuit 27. Each input flare correction is performed and output to the image processing unit 30. Here, correction is performed for each color of the three primary color video signals, but the same correction can be performed even if the video signal is input as a luminance signal, a color difference red signal, and a color difference blue signal.

Next, the operation of the flare correction circuit 10 will be described. The flare correction circuit 10 receives an R color video signal 1a, a G color video signal 2a, and a B color video signal 3a of the three primary color video signals. Each input video signal is input to the first A / D converter 11, the second A / D converter 12, and the third A / D converter 13, is digitally converted, and is output to the flare correction unit 20. The In the flare correction unit 20, an input signal for each video signal is passed through a vertical LPF (low-pass filter) unit 22 and a horizontal LPF unit 23 to which a setting signal from the cutoff frequency setting unit 24 is input. In order to match the delay due to the two-dimensional LPF of the signal (two-dimensional low-frequency signal) that has passed through the vertical LPF unit 22 and the horizontal LPF unit 23, the output signal of the horizontal LPF unit 23 is synthesized from the input signal that has passed through the delay circuit 21. By subtracting at 25, a two-dimensional mid-high range signal is extracted. Further, the gain is adjusted by the coefficient circuit 27 by the gain setting unit 26 and then added to the original input signal by the synthesis circuit 28 to obtain an output signal. The band of the flare correction circuit can be adjusted by adjusting the cutoff frequency of the two-dimensional LPF. The band of the flare correction circuit refers to a cutoff frequency of a two-dimensional LPF and can also be referred to as a cutoff frequency of a two-dimensional mid-high pass filter. By adjusting the band of the flare correction circuit, it is possible to increase or decrease the range of flare correction components (mid-high range components added for flare correction), that is, the slope of the edge portion. The range of flare correction is the region indicated by f ₁ in FIG. 3. When the cutoff frequency of the two-dimensional LPF is adjusted low, the region of f ₁ widens, and when the cutoff frequency of the two-dimensional LPF is adjusted high, f ₁ The area becomes narrower. In the case of a video signal, it is known that a favorable effect can be obtained by adjusting the cutoff frequency of the horizontal LPF to about several hundred KHz. The cut-off frequency of the vertical LPF is desirably adjusted according to the horizontal LPF. The gain can be adjusted by adjusting the setting value of the gain setting unit. From the flare correction unit 20, the input R color video signal 1a, G color video signal 2a, and B color video signal 3a are processed, and the flare corrected R color video signal 1b and the flare corrected G color video signal 2b are processed. The flare-corrected B color video signal 3b is output to the image processing unit 30.

  These processes realize an improvement in contrast, and as described in the prior art with reference to FIGS. 5 to 7, the signals are converted into signals in which the middle and high frequency components are emphasized and displayed on the irradiation surface. FIG. 3 is a schematic diagram in which the flare by the lens shown in FIG. 6 is corrected by the flare correction circuit according to the embodiment of the present application. If the flare of FIG. 6 is corrected by the flare correction circuit and the edge is raised as shown in FIG. 3, the human eye has an effect of increasing the contrast, so that the portion with a large luminance difference or chromaticity difference can be clearly seen. become. This is called the Crake-O'Brien effect. The larger the gain of the edge part and the slope of the edge part are, the more effective for increasing the contrast, but after that, the image becomes unnatural and the degree depends on the external brightness. Therefore, it is desirable to adjust the brightness according to the external brightness, and some conventional techniques have a function that allows the viewer to manually adjust the gain with their own senses. There is nothing you can do. The flare correction unit 20 of this embodiment can adjust the magnitude of the gain and the slope of the edge portion, and the signal from the flare correction amount determination unit 52 is sent to the cutoff frequency setting unit 24 and the gain setting unit 26. Once input, the gain and bandwidth are adjusted to the desired values.

  Sensitivity decreases when the surroundings are bright as human visual characteristics, so when the surroundings of the viewpoint are bright, adjusting the flare correction gain alone has little effect.For example, if the brightness exceeds a predetermined threshold It is desirable to increase the slope of the edge portion along with the flare correction gain. The flare correction amount determination unit 52 determines this adjustment amount. FIG. 4 is a schematic diagram illustrating the degree of flare correction with respect to ambient brightness according to the present embodiment, where (a) is a band adjustment graph and (b) is a gain adjustment graph. Here, a threshold is set for the ambient brightness, and the gain increases or decreases in proportion to the ambient brightness over the entire range. However, if the slope of the edge is above the threshold, the ambient brightness is increased. It is increased and decreased in proportion to and is fixed below the threshold. This is an example, and the slope of the edge portion can be reduced together with the gain as it becomes darker. Further, the proportional relationship may not be linear.

  In the image processing unit 30, a process for displaying on the display device 40 is performed based on the input video signal subjected to the flare correction, and is displayed on the display device 40 as an image. As the display device 40, for example, any device such as a cathode ray tube, a liquid crystal device, a plasma device, and a DMD device is assumed. However, the display device 40 can be applied to any kind of display device.

  The ambient light detector 51 measures the brightness around the display device 40 using a built-in ambient environment brightness measurement sensor. Information on the brightness measured by the ambient light detection unit 51 is sent to the flare correction amount determination unit 52. Although it is ideal that the brightness at the viewing position can be originally detected as the installation position of the ambient light detection unit 51, it is not possible to specify where the viewing position is in the image display device. Since it is assumed that a person often looks at the screen in the vicinity of the image display device, the ambient light detection unit 51 is provided on the top plate of the housing of the image display device. However, when the image display device is operated by a remote controller, the remote controller position is considered to be closer to the viewing position than the image display device position. Therefore, the ambient light detector 51 is provided in the remote controller to measure the ambient brightness. May be transmitted to the image display device. In this case, the brightness measurement result can also be transmitted to the projector by infrared or wireless.

  The flare correction amount determination unit 52 calculates the flare correction gain and band corresponding to the ambient environment lightness by calculation based on a pre-stored calculation formula or a preset lookup table. As the determination circuit of the flare correction amount determination unit 52, devices such as an analog circuit, a digital circuit, and a CPU can be applied. The calculated flare correction gain and band are output to the flare correction unit 20. The flare correction unit 20 performs flare correction as described above using the input gain and band. As a result, an image subjected to flare correction corresponding to the brightness around the display device 40 is displayed on the display device 40.

  In the above-described embodiment, the form in which both the gain and the band of the flare correction circuit are adjusted has been described. However, the effect of the present invention is sufficiently achieved even in the embodiment in which only the band is adjusted. In the above-described embodiment, the flare correction amount is automatically adjusted. However, the flare correction amount may be manually adjusted. In the above-described embodiment, the ambient light detection unit is provided on the top plate of the housing of the image display device. However, the position of the ambient light detection unit may be any place as long as the position is above the image display device. Absent.

It is a typical block diagram for demonstrating the flare correction circuit of embodiment of this invention. It is a block diagram of a schematic basic circuit of flare correction for video signals of each color in a flare correction unit. It is the schematic diagram which correct | amended the flare of the image of FIG. 6 with the flare correction circuit of embodiment of this application. It is a schematic diagram which shows the degree of the flare correction | amendment with respect to the surrounding brightness of this Embodiment, (a) is a graph of the band adjustment of flare correction, (b) is a graph of the gain adjustment of flare correction. It is a schematic diagram of an image for explaining a flare phenomenon. It is a schematic diagram of the image for demonstrating the flare phenomenon by the lens of an optical output. It is a comparison figure of the normal video signal for explaining flare phenomenon, and the video signal corrected for flare correction, (a) is a normal video signal, (b) is corrected for flare correction Video signal.

Explanation of symbols

1a R color video signal 2a G color video signal 3a B color video signal 1b Corrected R color video signal 2b Corrected G color video signal 3b Corrected B color video signal 10 Flare correction circuit 11 First A / D Converter 12 Second A / D converter 13 Third A / D converter 20 Flare correction unit 21 Delay circuit 22 Vertical LPF unit 23 Horizontal LPF unit 24 Cutoff frequency setting unit 25, 28 Synthesis circuit 26 Gain setting unit 27 Coefficient circuit DESCRIPTION OF SYMBOLS 30 Image processing part 40 Display device 51 Ambient light detection part 52 Flare correction amount determination part 61 Peripheral part 62 Center part 63 Edge part 64 Scan line 71 Video signal 72 Corrected video signal

Claims (10)

In the image display device in which the video signal flare corrected by the flare correction circuit is output to the image processing unit,
A flare correction circuit of an image display device that adjusts a band of the flare correction circuit. In the image display device in which the video signal flare corrected by the flare correction circuit is output to the image processing unit,
A flare correction circuit of an image display device that adjusts a gain and a band in the flare correction circuit. In the image display device in which the video signal flare corrected by the flare correction circuit is output to the image processing unit,
The flare correction circuit of the image display device according to claim 1, wherein the band of the flare correction circuit is automatically adjusted according to the brightness of ambient light. The brightness of the ambient light is detected by the ambient light detector,
The flare correction circuit of the image display device according to claim 3, wherein the band is calculated from the ambient light brightness by a flare correction amount determination unit based on a calculation based on a calculation formula stored in advance. The brightness of the ambient light is measured by the ambient light detector,
The flare correction circuit of the image display device according to claim 3, wherein the band is calculated from ambient lightness based on a preset look-up table by a flare correction amount determination unit.   The flare correction circuit for an image display device according to claim 4, wherein the ambient light detection unit includes a phototransistor.   The flare correction circuit device according to claim 4 or 5, wherein the flare correction amount determination unit includes any one of an analog circuit, a digital circuit, and a CPU.   The flare correction circuit for an image display device according to claim 3, wherein the ambient light detection unit is provided on an upper portion of the image display device.   The flare correction circuit for an image display device according to claim 3, wherein the ambient light detection unit is provided in a remote controller that controls the image display device. Measuring the brightness around the image display device;
A step of calculating a band of the flare correction circuit corresponding to the brightness of the surroundings by any of an operation based on a pre-stored calculation formula and a preset lookup table;
Performing flare correction of the video signal output to the image processing unit according to the calculated bandwidth;
A flare correction method comprising:

Images