JP2006153698A - Device and method for measuring contrast ratio - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device and a method for measuring a contrast ratio capable of precisely measuring the reproducible contrast ratio in the measuring device for measuring the contrast ratio of a color filter by reducing the dispersion of the measurement value by keeping the parallelism and perpendicularity of polarization axes of 2 sheets of polarization plate. <P>SOLUTION: This device is constituted of: (A) a surface plate 1 with back light with a stage 2 for mounting a 1st polarization plate P1, a stage 3 for mounting a color filter CF, and a freely rotatable rotation stage 4 mounting a 2nd polarization plate P20 are parallelly provided; (B) a luminance meter 6 for detecting light from the back light; (C) a driving part 7 for rotating the rotary stage; and (D) a control part 8 for controlling the back light, the rotary stage, the luminance meter and calculating the contrast ratio. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to measurement of the contrast ratio of a color filter, and more particularly to a contrast ratio measuring apparatus and measurement method capable of accurately measuring the contrast ratio of a color filter used in a liquid crystal display device.

FIG. 4 is a plan view schematically showing an example of a color filter used in the liquid crystal display device. FIG. 5 is a cross-sectional view taken along the line XX ′ of the color filter shown in FIG.
As shown in FIGS. 4 and 5, the color filter used in the liquid crystal display device has a black matrix (41), a colored pixel (42), and a transparent conductive film (43) sequentially on a glass substrate (40). It is formed.
4 and 5 schematically show a color filter, and 12 colored pixels (42) are represented. In an actual color filter, for example, several hundred pixels are arranged in a 17-inch diagonal area. A large number of colored pixels of about μm are arranged.

As a method for manufacturing a color filter having the above structure used in many liquid crystal display devices, a black matrix is first formed on a glass substrate to form a black matrix substrate, and then the black matrix on the black matrix substrate is used. A method is widely used in which a colored pixel is formed by aligning with the pattern, and a transparent conductive film is aligned and formed.
The black matrix (41) is a matrix having light shielding properties, the colored pixels (42) have, for example, red, green, and blue filter functions, and the transparent conductive film (43) is transparent. Provided as a simple electrode.

The black matrix (41) is composed of a matrix portion (41A) between the colored pixels (42) and a frame portion (41B) surrounding the peripheral portion of the region (display portion) where the colored pixels (42) are formed. Yes.
The black matrix determines the position of the colored pixels of the color filter, makes the size uniform, and shields unwanted light when used in a display device, making the image of the display device uniform and uniform. In addition, it has a function of making an image with improved contrast.

For the production of this black matrix substrate, a metal or a metal compound such as chromium (Cr) or chromium oxide (CrO _x ) as a black matrix material is formed into a thin film on a glass substrate (40). An etching resist pattern is formed on the formed thin film using, for example, a positive photoresist, and then an exposed portion of the formed metal thin film is etched and an etching resist pattern is stripped, and Cr, CrO _A method has been adopted in which a black matrix (41) made of a metal thin film such as _X is formed.
Alternatively, the black matrix (41) is formed on the glass substrate (40) by photolithography using a black photosensitive resin for forming a black matrix.

In addition, the colored pixels (42) are formed by providing a coating film on the black matrix substrate using, for example, a negative photoresist in which a pigment or other pigment is dispersed, and exposing and developing the coating film. A method of forming colored pixels is used.
The transparent conductive film (43) is formed on the black matrix substrate on which the colored pixels are formed by, for example, forming a transparent conductive film by sputtering using ITO (Indium Tin Oxide). .

  The color filter shown in FIGS. 4 and 5 has a basic function as a color filter used in a liquid crystal display device. The liquid crystal display device incorporates such a color filter to realize full color display, and its application range is dramatically expanded, and many products using liquid crystal display devices such as liquid crystal color TVs and notebook PCs are created. It was done.

Color filters used in liquid crystal display devices require physical properties such as heat resistance, light resistance, and chemical resistance, as well as spectral characteristics (brightness, color purity, white balance), contrast ratio, dimensional accuracy, Various characteristics such as smoothness are required.
The contrast ratio of the color filter refers to depolarization and is a characteristic that affects the contrast of the liquid crystal display device.

The ratio of the transmittance when the polarization axes of the two linearly polarized polarizing plates are made parallel to the transmittance when the polarization axes are orthogonal is about 5000: 1. However, when a color filter is inserted between two polarizing plates, the transmittance ratio decreases due to the depolarization of the color filter.
As shown in FIG. 1A, the contrast ratio of the color filter is such that the polarization axes of the first polarizing plate (P1) and the second polarizing plate (P2) are kept parallel, and the color filter (CF) is kept in the first polarizing plate. The transmittance (brightness A) when sandwiched between (P1) and the second polarizing plate (P2), and the first polarizing plate (P1) and the second polarizing plate (P2) as shown in FIG. ) With the polarization axes kept orthogonal and expressed as a ratio of the transmittance (luminance B) when the color filter (CF) is sandwiched between the first polarizing plate (P1) and the second polarizing plate (P2). .

  The contrast ratio of the color filter when a dye is used as a pigment is about 3000, but the contrast ratio of the color filter when a pigment is used is reduced to about 1500. This is because the pigment has a property of disturbing the polarization, and depends on the type of the pigment itself, the particle size of the pigment, and the like.

  FIG. 2 is a perspective view for explaining an example of a method for measuring the contrast ratio of the color filter. As shown in FIG. 2, a linearly polarized first polarizing plate (P1), a color filter (CF), and a linearly polarized second polarizing plate (P2) are stacked and placed on a transparent substrate (10). ing. The transparent substrate (10) is provided on an illumination backlight (not shown), and a luminance meter (12) for detecting transmitted light is provided above the transparent substrate (10). It has been.

The light from the backlight reaches the luminance meter (12) through the transparent substrate (10), the first polarizing plate (P1), the color filter (CF), and the second polarizing plate (P2).
In order to accurately superimpose the first polarizing plate (P1), the color filter (CF), and the second polarizing plate (P2) at a substantially central portion on the transparent substrate (10), on the transparent substrate (10). Is provided with a three-way pin (11). The three-way pin (11) is provided with a first pin (11A) and a second pin (11B) parallel to the longitudinal direction of the transparent substrate (10), and is perpendicular to the linear direction connecting the two pins. A third pin (11C) is provided at the position.

The shapes of the first polarizing plate (P1), the color filter (CF), and the second polarizing plate (P2) are all rectangular, and of the two orthogonal sides, the long side is the first pin (11A) and the second side. The short side is brought into contact with the pin (11B) and the third pin (11C) to match the overlapping position.
Moreover, the polarizing plate used for the measurement is the first polarizing plate (P1), the first polarizing plate (P1), the second polarizing plate A (P2-A) whose polarization axis is parallel, and the first polarizing plate (P1). And the second polarizing plate B (P2-B) whose polarization axes are orthogonal to each other.

The first polarizing plate (P1) has a polarization axis parallel to the linear direction connecting the two pins, the first pin (11A) and the second pin (11B), as indicated by an arrow in FIG. First, the angle of the long side that strikes the two pins is adjusted in advance. Further, the angle is adjusted so that the short side that strikes the third pin (11C) is perpendicular to the long side.

  Further, the second polarizing plate A (P2-A) is exactly the same as the first polarizing plate (P1), and the first pin (11A) and the second pin have their polarization axes indicated by arrows in FIG. (11B) The angle of the long side which abuts against the two pins is adjusted in advance so as to be parallel to the linear direction connecting the two pins of (11B). Further, the angle is adjusted so that the short side that strikes the third pin (11C) is perpendicular to the long side.

  In addition, the second polarizing plate B (P2-B) has a polarization axis of 2 in advance so that its polarization axis is perpendicular to the linear direction connecting the two pins of the first pin (11A) and the second pin (11B). Adjust the angle of the long side that strikes each pin and finish it. Further, the angle is adjusted so that the short side that strikes the third pin (11C) is perpendicular to the long side.

The contrast ratio of the color filter is measured on a transparent substrate (10) on a first polarizing plate (P1), a color filter (CF), and two types of second polarizing plates (second polarizing plate A (P2-A). ) And the second polarizing plate B (P2-B)) are superposed and placed, and the light transmitted through these is detected with a photometer.
As shown in FIG. 3 (a), first, on a transparent substrate (10), a first polarizing plate (P1), a color filter (CF), and a second polarizing plate A (P2) whose polarization axis is parallel to the long side. -A) is overlapped to detect the brightness A when parallel. Next, as shown in FIG. 3 (b), the second polarizing plate A (P2-A) is removed, and a second polarizing plate B (P2-B) whose polarization axis is perpendicular to the long side is superposed instead. The luminance B at the time of orthogonality is detected.

From the detected parallel brightness A and orthogonal brightness B, the contrast ratio of the color filter is easily calculated by the following formula.

Contrast ratio of color filter = luminance A when parallel / luminance B when orthogonal

However, when the contrast ratio of the color filter is measured by the apparatus and method as described above, for example, when producing three types of polarizing plates, it is difficult to finish the long side and the polarization axis accurately in parallel or at right angles. There will be some errors.
Also, for example, when the first polarizing plate (P1), the second polarizing plate A (P2-A), and the second polarizing plate B (P2-B) are abutted against the three-way pins, it is difficult to accurately abut them. There will be some errors.
In addition, during use, the end of the first polarizing plate (P1), the second polarizing plate A (P2-A), and the second polarizing plate B (P2-B) wears the polarizing plate. Edge accuracy will deteriorate.

  Therefore, when the contrast ratio of the color filter is measured by the apparatus and method as described above, the parallelism between the polarization axis of the first polarizing plate (P1) and the polarization axis of the second polarizing plate A (P2-A), and An error occurs in the orthogonality between the polarization axis of the first polarizing plate (P1) and the polarization axis of the second polarizing plate B (P2-B), the measurement accuracy of the contrast ratio of the color filter is lowered, and the measured value for each measurement Therefore, it becomes difficult to accurately measure a reproducible contrast ratio.

  When adjusting the angles of the long side and the short side of the three types of polarizing plates, the first polarizing plate (P1), the second polarizing plate A (P2-A), and the second polarizing plate B (P2-B), In the case of the work of adjusting the angles of the first polarizing plate (P1) and the second polarizing plate A (P2-A), since it is adjustment of the parallelism of the polarization axis, the amount of transmitted light is large and easy to see. . Further, even if an angle change (error) with a certain degree of parallelism occurs, the change in transmitted light is small. That is, it is easy to adjust the angle at which the transmitted light is maximized.

  On the other hand, in the case of the work of adjusting the angle of the second polarizing plate B (P2-B), since it is adjustment of the orthogonality of the polarization axis, the amount of transmitted light is small and difficult to view. Moreover, even if the orthogonality changes with a certain angle (error), it is difficult to view the change in transmitted light, and an error in work is likely to occur. That is, it is not easy to adjust the angle so that the transmitted light is minimized. It is difficult to accurately cause the second polarizing plate B (P2-B) to have a polarizing axis perpendicular to the polarizing axis of the first polarizing plate (P1).

In other words, in the operation of adjusting the angle of the second polarizing plate B (P2-B), the accurate polarizing axis perpendicular to the polarizing axis of the first polarizing plate (P1) is set to the second polarizing plate B (P2-B). ), The measurement accuracy of the contrast ratio can be improved.
However, it is not easy to accurately adjust the angle so that the transmitted light is minimized. When the contrast ratio of the color filter is measured by the apparatus and method as described above, the variation in the measured value increases, and it is difficult to accurately measure the reproducible contrast ratio.

  The present invention has been made in order to solve the above-described problem. A color filter is sandwiched between two polarizing plates, and the luminance when the polarization axes of the two polarizing plates are parallel to each other and the luminance when orthogonal to each other. In the contrast ratio measurement device that measures the contrast ratio of the color filter, the parallelism and orthogonality of the polarization axes of the two polarizing plates are accurately maintained, the variation in the measured values is small, and the reproducibility is high. It is an object of the present invention to provide a contrast ratio measuring apparatus capable of measuring a certain contrast ratio.

  In the present invention, a color filter is sandwiched between two polarizing plates, and the contrast ratio of the color filter is measured from the ratio of the luminance when the polarizing axes of the two polarizing plates are parallel to the luminance when the polarizing axes are orthogonal to each other. Contrast that can accurately measure reproducible contrast ratios with high accuracy, keeping the parallelism and orthogonality of the polarization axes of the two polarizing plates accurate, minimizing variation in measured values It is an object to provide a method for measuring a ratio.

The present invention is a contrast ratio measuring apparatus for measuring a contrast ratio of a color filter by sandwiching a color filter between two polarizing plates.
A) A surface plate with a backlight provided with a stage on which the first polarizing plate is placed,
2. A stage for placing a color filter above the surface plate,
3. Above the stage on which the color filter is placed, a rotary stage on which the second polarizing plate is placed and rotatable is provided in parallel,
B) A luminance meter for detecting light from the backlight above the rotary stage;
C) a drive unit for rotating the rotary stage;
D) a control unit that controls the backlight, the rotary stage, and the luminance meter, and calculates the contrast ratio of the color filter;
A contrast ratio measuring device characterized by comprising:

Further, the present invention provides a contrast ratio measurement method for measuring a contrast ratio of a color filter by sandwiching a color filter between two polarizing plates.
A) A surface plate with a backlight provided with a stage on which the first polarizing plate is placed on the upper surface, a stage on which the color filter above it is placed, and a second polarizing plate above it are placed. Then, the first polarizing plate is placed on the stage on which the first polarizing plate is placed on the rotatable rotation stage,
B) The second polarizing plate is placed on a rotary stage that can be rotated by placing the second polarizing plate. C) The rotatable rotary stage on which the second polarizing plate is placed is rotated, and the back is rotated. The rotation angle A of the rotary stage at which the light from the light is detected to the maximum is set, and the rotation angle B of the rotary stage at which the light from the backlight is detected to the minimum is set. Is stored in the control unit,
D) A color filter is placed on the stage on which the color filter is placed, the brightness A is measured at the set rotation angle A of the rotary stage, and the brightness B is measured at the set rotation angle B of the rotary stage,
The contrast ratio is calculated from the luminance A and the luminance B in the control unit, and the contrast ratio is measured.

The present invention includes: A) a surface plate with a backlight provided with a stage on which the first polarizing plate is placed, a stage on which the color filter is placed, and a rotatable stage on which the second polarizing plate is placed, B) a luminance meter that detects light from the backlight;
C) a drive unit for rotating the rotary stage, D) a contrast ratio measuring device including at least a control unit for controlling the backlight, the rotary stage, and the luminance meter and calculating the contrast ratio of the color filter. It becomes a contrast ratio measuring apparatus capable of accurately measuring the parallelism and orthogonality of the polarization axis of the polarizing plate, minimizing variations in measurement values, and accurately measuring a reproducible contrast ratio.

In addition, the present invention provides A) a platen with a backlight provided with a stage on which a first polarizing plate is placed, a stage on which a color filter is placed, and a second polarizing plate, which are placed in parallel. Place the first polarizing plate on the stage where the first polarizing plate of the free rotation stage is placed,
B) Place the second polarizing plate on a rotatable rotation stage, and C) Rotate the rotatable rotation stage to set the rotation angle A of the rotation stage where the light from the backlight is detected to the maximum. Further, the rotation angle B of the rotary stage at which light from the backlight is detected to the minimum is set, and the rotation angle A and the rotation angle B are stored in the control unit,
D) A color filter is placed on the stage on which the color filter is placed, the brightness A is measured at the set rotation angle A of the rotary stage, and the brightness B is measured at the set rotation angle B of the rotary stage and controlled. This is a contrast ratio measurement method that calculates the contrast ratio at the center, so that the parallelism and orthogonality of the polarization axes of the two polarizing plates are accurately maintained, the variation in measured values is small, and the reproducible contrast is accurate. The contrast ratio can be measured by a contrast ratio measurement method.

Hereinafter, embodiments of the present invention will be described in detail.
FIG. 6 is a cross-sectional view of an embodiment of a contrast ratio measuring apparatus according to the present invention. As shown in FIG. 6, the contrast ratio measuring apparatus has a backlight (not shown) provided with a stage (2) for placing a polarizing plate on the upper surface thereof as a stage for placing a polarizing plate and a color filter. A surface plate (1), a stage (3) on which the color filter (CF) is placed above the surface plate, and a second polarizing plate (in the present invention above the stage (3) on which the color filter is placed) A rotary stage (4) on which P20) is mounted and rotatable is provided in parallel.

  Above the rotary stage (4), a luminance meter (6) for detecting light from the backlight is provided, and a drive unit (7) for rotating the rotary stage is provided adjacent to the rotary stage (4). Yes. Moreover, the control part (8) which controls the said backlight, a rotation stage (4), and a luminance meter (6) and calculates the contrast ratio of a color filter is provided.

FIG. 6 shows a state where the first polarizing plate (P1), the color filter (CF), and the second polarizing plate (P20) according to the present invention are placed on each stage. The first polarizing plate (P1) is a linearly polarizing plate, and is placed and fixed on a stage (2) on which the polarizing plate is placed. The color filter (CF) is, for example, a color filter used in a liquid crystal display device, and is placed and fixed on a stage (3) on which the color filter is placed.

The rotatable rotary stage (4) has, for example, a circular shape in plan view, and is rotated by an arbitrary angle by the adjacent drive unit (7) and stopped. The second polarizing plate (P20) is a linearly polarizing plate, and is placed and fixed on a rotatable rotating stage (4).
The second polarizing plate (P20) has an angle of the polarization axis of the second polarizing plate (P20) with respect to the polarization axis of the fixed first polarizing plate (P1) as the rotatable rotating stage (4) rotates. It is going to change.

The light from the backlight includes a stage (2) on which a polarizing plate is placed, a first polarizing plate (P1), a stage (3) on which a color filter is placed, a color filter (CF), and a rotatable rotating stage (4). ) And the second polarizing plate (P20) in the present invention, the luminance meter (6) is reached.
The light detected by the luminance meter (6) is calculated by the control unit (8), and the contrast ratio of the color filter is calculated. The control unit (8) controls the backlight, the luminance meter (6), and the drive unit (7).

In the measurement of the contrast ratio of the color filter using this contrast ratio measuring device, the angles of the polarization axes of the first polarizing plate (P1) and the second polarizing plate (P20) are set in advance. The contrast ratio is measured after setting the angle.
The angle setting of the polarization axis of the polarizing plate is performed in advance by setting the parallelism of the polarization axes of the first polarizing plate (P1) and the second polarizing plate (P20), and the first polarizing plate (P1) and the second polarizing plate ( P20) is the setting of the orthogonality of the polarization axis. The angle is set as follows.

  First, a 1st polarizing plate (P1) is mounted in the stage (2) which mounts a polarizing plate. Although the polarization axis of the first polarizing plate (P1) is arbitrary, for example, the first polarizing plate (P1) is made to be substantially parallel to one side of the stage (2) on which the polarizing plate is placed. It fixes to the stage (2) to mount. No color filter (CF) is placed on the stage (3) on which the color filter is placed. The second polarizing plate (P20) is placed on the rotatable rotation stage (4). The polarization axis of the second polarizing plate (P20) is arbitrary. For example, the rotation axis of the rotatable rotating stage (4) is set to the direction of approximately 0 degrees, and the second polarizing plate (P20) is rotatable. Fix to (4).

Next, the parallelism is set by rotating the rotatable rotary stage (4) while detecting the light from the backlight with the luminance meter (6), and reading the rotation angle at which the luminance is maximized. (Rotation angle A) is set to a rotation angle A at which the polarization axis of the first polarizing plate (P1) and the polarization axis of the second polarizing plate (P20) are parallel.
The orthogonality is set by rotating the rotatable rotary stage (4) while detecting the light from the backlight with the luminance meter (6), reading the rotation angle at which the luminance is minimized, and rotating the rotation angle ( The rotation angle B) is set to a rotation angle B at which the polarization axis of the first polarizing plate (P1) and the polarization axis of the second polarizing plate (P20) are orthogonal to each other.
The rotation angle A and the rotation angle B are stored in the control unit (8).

After the angle is set, the contrast ratio of the color filter is measured as follows using this contrast ratio measuring device.
First, the color filter (CF) is placed and fixed on the stage (3) on which the color filter is placed in the contrast ratio measuring apparatus in a state where the rotation angle A and the rotation angle B are set. Next, the luminance A is measured at the rotation angle A of the rotary stage set as described above, and the luminance B is measured at the rotation angle B of the rotary stage set as described above.

Subsequently, the control unit performs measurement such as calculating the contrast ratio of the color filter from the obtained luminance A and luminance B using the following mathematical formula.

Contrast ratio of color filter = luminance A when parallel / luminance B when orthogonal

As described above, in the contrast ratio measuring apparatus according to the present invention, the conventional first polarizing plate (P1), the second polarizing plate A (P2-A), and the second polarizing plate B (P2-B). The work of adjusting the angles of the long side and the short side as in the case of the three types of polarizing plates is not necessary. In the contrast ratio measuring apparatus according to the present invention, the first polarizing plate (P1) is fixed, the second polarizing plate (P20) on the rotatable rotating stage (4) is rotated, and the transmitted light is detected by a luminance meter. Therefore, the parallelism and orthogonality of the polarization axis can be set accurately and easily.

  In particular, the work of accurately adjusting and finishing the orthogonality of the second polarizing plate B (P2-B) was difficult, but by using the contrast ratio measuring apparatus according to the present invention, It can also be done easily.

Conventionally, when the first polarizing plate (P1), the second polarizing plate A (P2-A), and the second polarizing plate B (P2-B) are struck against the three-way pin, there is a slight angle change (error). However, by using the contrast ratio measuring apparatus according to the present invention, the abutment is unnecessary, and an angle change (error) associated with the abutment work does not occur.
Conventionally, while using the first polarizing plate (P1), the second polarizing plate A (P2-A), and the second polarizing plate B (P2-B), they are abutted by wear of the end of the polarizing plate. In some cases, a slight change in angle (error) occurred, but wear at the end of the polarizing plate was not involved.

In the present invention, it is preferable to use a pulse motor for rotationally driving the rotatable stage (4) on which the second polarizing plate is mounted. The rotation angle is controlled, for example, in increments of 0.1 to 0.2 degrees, and the rotation angle A and the rotation angle B are set with the accuracy of this increment.
The work of finishing by adjusting the parallelism of the polarization axis is easy and the influence when an angle change (error) occurs is small. For the control of the rotation angle, a step of 0.2 degree of rotation angle may be adopted in the case of parallelism. In the case of the orthogonality, the increment of the rotation angle is preferably 0.1 degree.

In addition, as the luminance meter (6) in the present invention, for example, a luminance meter capable of measuring with a luminance accuracy of about ± 4% at a luminance angle of 0.02 cd / m ² or more in a measurement angle range of 2 degrees can be used.
By using the contrast ratio measuring apparatus according to the present invention, the measurement accuracy of the contrast ratio of the color filter can be obtained with a measurement accuracy of about ± 1% compared to the conventional measurement accuracy of about ± 10%.

(A) is explanatory drawing of the contrast ratio of a color filter. (B) is an explanatory diagram of the contrast ratio of the color filter. It is a perspective view explaining an example of the method of measuring the contrast ratio of a color filter. (A) is explanatory drawing of the measurement procedure of the contrast ratio of a color filter. (B) is explanatory drawing of the measurement procedure of the contrast ratio of a color filter. It is the top view which showed typically an example of the color filter used for a liquid crystal display device. FIG. 5 is a cross-sectional view taken along line X-X ′ of the color filter illustrated in FIG. 4. It is sectional drawing of one Example of the measuring apparatus of contrast ratio by this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... The surface plate with a backlight which provided the stage which mounts a polarizing plate on the upper surface 2 ... The stage 3 which mounts a polarizing plate 3 ... The stage 4 which mounts a color filter ... 2nd polarized light Rotating stages 6, 12, which can be rotated by placing a plate, luminance meter 7, driving unit 8, control unit 10, transparent substrate 11, three-way pin 40, glass substrate 41 ... Black matrix 41A ... Black matrix 41B ... Black matrix frame 42 ... Colored pixel 43 ... Transparent conductive film CF ... Color filter P1 ... First polarization Plate P2 ... Second polarizing plate P2-A ... First polarizing plate and second polarizing plate A whose polarization axis is parallel
P2-B ... The second polarizing plate B whose polarizing axis is orthogonal to the first polarizing plate
P20: Second polarizing plate in the present invention

Claims (2)

In a contrast ratio measuring apparatus for measuring a contrast ratio of a color filter by sandwiching a color filter between two polarizing plates,
A) A surface plate with a backlight provided with a stage on which the first polarizing plate is placed,
2. A stage for placing a color filter above the surface plate,
3. Above the stage on which the color filter is placed, a rotary stage on which the second polarizing plate is placed and rotatable is provided in parallel,
B) A luminance meter for detecting light from the backlight above the rotary stage;
C) a drive unit for rotating the rotary stage;
D) a control unit that controls the backlight, the rotary stage, and the luminance meter, and calculates the contrast ratio of the color filter;
An apparatus for measuring a contrast ratio, comprising: In a contrast ratio measurement method for measuring a contrast ratio of a color filter by sandwiching a color filter between two polarizing plates,
A) A surface plate with a backlight provided with a stage on which the first polarizing plate is placed on the upper surface, a stage on which the color filter above it is placed, and a second polarizing plate above it are placed. Then, the first polarizing plate is placed on the stage on which the first polarizing plate is placed on the rotatable rotation stage,
B) The second polarizing plate is placed on a rotary stage that can be rotated by placing the second polarizing plate. C) The rotatable rotary stage on which the second polarizing plate is placed is rotated, and the back is rotated. The rotation angle A of the rotary stage at which the light from the light is detected to the maximum is set, and the rotation angle B of the rotary stage at which the light from the backlight is detected to the minimum is set. Is stored in the control unit,
D) A color filter is placed on the stage on which the color filter is placed, the brightness A is measured at the set rotation angle A of the rotary stage, and the brightness B is measured at the set rotation angle B of the rotary stage,
A contrast ratio measuring method, wherein a contrast ratio is calculated from luminance A and luminance B in a control unit.

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