KR102014171B1 - Apparatus and method for inspecting color mix defect of OLED - Google Patents

Abstract

The present invention relates to a device and a method for detecting a mixed color defect of an organic light emitting device, wherein an objective of the present invention is to provide a device and a method which can effectively detect mixed color defects at various viewing angles. Another objective of the present invention is to provide a device and a method for detecting a mixed color defect of an organic light emitting device, which enable a quick and effective detection of the entire area of a cell to be detected. The device of the present invention comprises: a lens part; a sensor part; and a control part.

Description

Apparatus and method for inspecting color mix defect of OLED}

The present invention relates to a mixed color failure detection device and a detection method of the organic light emitting device for effectively detecting color abnormalities such as mixed color phenomenon caused by a mask failure in the process of depositing the organic light emitting device.

Organic Light Emitting Diodes (OLEDs) refers to self-luminous organic materials that emit light by themselves using electroluminescent phenomena that emit light when a current flows through a fluorescent organic compound. The organic light emitting diode can be driven at low voltage, can be made thin, and has a wide viewing angle and fast response speed. Organic light emitting devices are classified into three colors (Red, Green, Blue) independent pixel method, color conversion method (CCM), color filter method, etc., depending on the color implementation method. As a result, the OLED may be classified into a low molecular OLED and a high molecular OLED, and may be classified into a passive matrix (PM) and an active matrix (AM).

In the process of manufacturing a three-color independent pixel type organic light emitting device, a mask is generally used to ensure that organic materials of R, G, and B are properly deposited at predetermined predetermined positions. However, in this process, if the position of the mask is misaligned or there is a defect in the mask itself, a color mix phenomenon occurs while other colors are buried in the original color position.

In order to solve such a mixed color defect problem, Korean Patent Publication No. 2008-0002024 ("shadow mask and manufacturing method of the organic electroluminescent device using the same", 2008.01.04, hereinafter 'priority literature') to prevent the mask sag and openings A mask structure is disclosed that improves the reduction. Although the incidence of mixed color development can be reduced by using the mask of the improved structure according to the prior art, it is difficult to completely exclude the occurrence of the mixed color phenomenon. Therefore, even if the manufacturing process is improved, it is necessary to detect the color mixing defect of the manufactured organic light emitting display.

Conventional detectors for detecting mixed color defects are obtained by acquiring an image from the front of the organic light emitting device, and by determining a number of measuring points in one cell and sampling the color defects.

By the way, when the mixed color defect is severe, the difference in color is apparent when looking at the organic light emitting device from the front, but if it is not severe, it is difficult to determine the color difference from the front. Therefore, in the case of a conventional detector that acquires only the image from the front side, there is a problem in that it does not detect the mixed color defect that is clearly present but is not severe.

In addition, the inspection was performed only on the sampled measuring points without inspecting the entire cell area due to the limitation of the working time, and at the present time, the demand for the quality of the display is gradually increasing. Necessity is also increasing. Therefore, there is a need for a technique capable of quickly detecting mixed color defects in the entire cell area.

1. Korean Patent Publication No. 2008-0002024 ("Shadow Mask and Manufacturing Method of Organic Electroluminescent Device Using the Same", 2008.01.04)

Accordingly, the present invention has been made to solve the problems of the prior art as described above, an object of the present invention is to detect a mixed color failure of the organic light emitting device and a detection method that can effectively detect the mixed color failure at various viewing angles In providing. Another object of the present invention is to provide an apparatus and a method for detecting a mixed color defect of an organic light emitting device, which enables to perform an inspection quickly and effectively on the entire region of a cell to be inspected.

In order to achieve the above object, the apparatus 100 for detecting a color failure of an organic light emitting diode according to an embodiment of the present invention includes a color mixing defect of an organic light emitting diode that inspects a planar cell in which a plurality of organic light emitting diodes are two-dimensionally arranged. A detection apparatus (100), comprising: a lens unit (120) formed to be disposed parallel to or inclined to the surface of the cell; A plurality of image sensors are formed in a planar form arranged in two dimensions to sense the image of the cell obtained through the lens, and the sensor unit is formed to be arranged parallel or inclined to the surface of the lens unit 120 130; Control unit for adjusting the angle of the lens unit 120 or the sensor unit 130; It may include.

At this time, the control unit, the surface of the cell is called the object surface (1), the central surface of the lens included in the lens unit 120 is called the lens surface (2), the surface of the sensor unit 130 When referred to as the sensor surface 3, the lens unit 120 is satisfied so that the Scheimpplug condition that the extension line of the object surface 1, the extension line of the lens surface 2 and the extension line of the sensor surface 3 coincide with each other is satisfied. Or the angle of the sensor unit 130 may be adjusted.

In addition, the control unit, the center point of the lens is called a lens center point (Q), the center point of the sensor unit 130 is called a sensor center point (P), the lens center point (Q) and the sensor center point (P) is connected A point where a straight line meets the object plane 1 is referred to as a reference point T, and a point that satisfies the Scheimpplug condition is referred to as a Scheimpplug point S. The object plane 1 and the lens surface 2 The angle formed is called an optical system inclination angle α, and the sensor unit 130 is satisfied so as to satisfy the Scheimpplug condition according to the optical system inclination angle α from the parallel state of the lens surface 2 and the sensor surface 3. When the angle to be rotated is referred to as the Scheimpplug angle θ, the Scheimpplug angle θ can be calculated by the following equation.

(Here, θ: Scheimpplug angle, α: Optical tilt angle, C: Distance between reference point (T) and sensor center point, R: Distance between reference point (T) and Scheimpplug point)

In addition, the mixed color failure detection device 100 of the organic light emitting device, the tilt motor 135 for adjusting the angle of the sensor unit 130; It may include.

In addition, the mixed color detection device 100 of the organic light emitting device, the zoom motor 125 for adjusting the distance between the lens unit 120 and the sensor unit 130; may include.

In addition, when the lens unit 120 is formed by stacking a plurality of lenses, the lens surface 2 may be determined as the center plane of the lens disposed closest to the object surface 1.

In addition, the mixed color detection method of the organic light emitting device of the present invention, in the mixed color detection method of the organic light emitting device using the mixed color detection device 100 of the organic light emitting device as described above, wherein the optical system tilt angle (α) is A reference image sensing step of sensing a reference image which is 0 and an image of the entire area of the cell in a state where the lens surface 2 and the sensor surface 3 are in parallel; A viewing angle tilt adjustment step of adjusting the optical tilt angle α to a non-zero angle; A sham plug condition satisfying step in which the angle of the sensor surface 3 is adjusted to the scheimp plug angle θ so that a sham plug condition is satisfied; An inclined image sensing step of sensing an inclined image which is an image of the entire area of the cell in a state after the step of satisfying the sham plug condition; A mixed color detection step of detecting a mixed color defect by analyzing the reference image and the inclined image; It may include.

At this time, the mixed color defect detection step, the image conversion step of converting the outer shape of the inclined image to be the same as the outer shape of the reference image to generate a converted image; A partition division step of dividing the reference image and the converted image into a plurality of predetermined sections; A detection information acquisition step of obtaining detection information including an average color and light intensity for each of said sections; It may include.

In addition, the mixed color defect detection step, the reference image defect determination step of determining whether the mixed color failure occurs according to a predetermined criterion by comparing the detection information for each section of the reference image; A converted image defectiveness determining step of determining whether mixed color defects are generated according to a predetermined criterion by comparing detection information of each section of the converted image with each other; An image comparison failure determination step of comparing the detection information between the selected section of the reference image and the section of the converted image corresponding thereto to determine whether a mixed color defect has occurred according to a predetermined criterion; It may include at least one selected from.

In addition, the image conversion step may be made to generate the transform image using affine transformation (affine transformation).

According to the present invention, it is possible to detect only when viewed from the front (i.e., when the viewing angle is vertical), thereby overcoming the limitation of not being able to detect fine mixed color defects, and applying the Scheimpplug principle to tilt the detection optical system. By realizing the viewing angle, there is a great effect of performing mixed color defect detection for various viewing angles.

In addition, according to the present invention, unlike the conventional sampling and detection of only a few points of the entire cell area, by detecting the mixed color failure by acquiring the image of the entire cell, the color mixture for the entire cell area quickly and effectively There is a great effect that can perform a defect detection.

1 is a state in which an object plane, a focal plane, a lens plane, and a sensor plane are formed.
2 is a defocused state according to the inclination of the focal plane when the optical system is tilted.
3 illustrates an example defocused image.
4 is an optical system adjusted to satisfy the Scheimpflug condition.
5 illustrates an example of a focused image.
6 is an explanatory diagram illustrating a principle for calculating a camera tilt angle.
7 to 10 show an embodiment of the detection apparatus of the present invention.
11 is a flowchart of a detection method of the present invention.

Hereinafter, an apparatus and a method for detecting a color failure of an organic light emitting diode according to the present invention having the above configuration will be described in detail with reference to the accompanying drawings.

Principle of the detection device and detection method of the present invention

1 shows various examples of the formation state of an object plane, a focal plane, a lens plane and a sensor plane. As shown in FIG. 1, it is assumed that an object plane 1 is photographed using a camera 10 having a lens. At this time, the lens surface 2 formed by the lens of the camera 10, the focal plane 1 'formed by the lens, and the sensor surface 3 on which the image obtained from the focal plane 1' are formed are shown in FIG. As shown, they are always formed essentially parallel. If the object plane 1 and the focal plane 1 'coincide, the image obtained at the sensor plane 3 is well focused in all areas.

2 illustrates a defocus state according to the inclination of the focal plane when the optical system is tilted. In FIG. 2, AB corresponds to the focal plane 1 'when the object plane 1 and the camera viewing angle are perpendicular, and A'-B' corresponds to the focal plane 1 'when the camera viewing angle is tilted. do. As described above, if the object plane 1 and the focal plane 1 'coincide with each other, a well-focused (ie focused) image can be obtained, but as shown in FIG. When the surface 1 'is tilted, as shown in Fig. 3, an image is obtained which is out of focus (ie defocused) in another part even if it is in focus. In the example of FIG. 3, it is well illustrated that an image in focus is obtained in the middle portion, while an image in focus is obtained in the outer portion.

As described above, in the conventional apparatus for detecting a mixed color defect of the organic light emitting device, the detection is performed with information obtained at a few points sampled in the front view. When the degree of mixing is not severe, it is difficult to determine that the mixing is bad in the front, but when viewed from a slightly inclined side it can be seen that the mixing failure occurs. However, in the conventional detection apparatus, since the optical system is designed based on the observation from the front, only the defocused image can be obtained as described in FIG. 2 when the optical system is inclined, and thus it is difficult to obtain a reliable detection result.

In order to solve this problem, the present invention applies the Schimpflug condition principle to the detection optical system. The Scheimpflug condition means that when the object plane 1 and the lens plane 2 are not parallel and form an inclination angle, the extension lines of the object plane 1, the lens plane 2, and the sensor plane 3 are always at one point. To cross. The object surface 1 is a fixed surface, and accordingly, the chime plug condition can be satisfied by tilting the lens surface 2 or the sensor surface 3 appropriately. When the Scheimpflug condition is satisfied, even if the object surface 1 and the lens surface 2 are inclined, a well-focused image can be obtained.

4 shows the optical system adjusted to satisfy the Scheimpflug condition. As shown in FIG. 4, it is assumed that the lens surface 2 is inclined at an angle with respect to the object surface 1. In general, since the lens and the sensor are arranged in parallel, in the initial state, the initial sensor surface 3 'is formed in parallel with the lens surface 2 as shown in FIG. In this state, however, the defocused image is obtained as shown in FIG. 3. At this time, as shown in FIG. 4, when the sensor is tilted so that the extension line of the sensor surface 3 satisfies the Scheimpplug condition, the focused image can be obtained as described above. 5 shows an example of the focused image even though the viewing angle is formed to be inclined as such. Compared to FIG. 3 and FIG. 5, in FIG. 3, the image is blurry because the focus is not focused on the outer portion, whereas in FIG. 5, the middle and both outer portions are well-focused. .

6 is an explanatory diagram illustrating a principle for calculating a camera tilt angle. 6 illustrates the principle of the detection apparatus of the present invention in more detail. First, the parts for explaining the principle are as follows. In FIG. 6, the surface of the cell is called an object plane 1, the center surface of the lens included in the lens unit 120 is called a lens plane 2, and the surface of the sensor unit 130 is called a sensor plane. It is called (3). In FIG. 6, the initial state of the lens and the sensor in the parallel state is shown as the initial sensor surface 3 ′, and the time when the Scheimpplug condition is satisfied is shown as the sensor surface 3.

In addition, a center point of the lens is called a lens center point Q, a center point of the sensor unit 130 is called a sensor center point P, and a straight line connecting the lens center point Q and the sensor center point P is The point where the object surface 1 meets is called the reference point T, and the point that satisfies the Scheimpplug condition is called the Scheimpplug point S. In addition, the angle formed by the object surface 1 and the lens surface 2 is called an optical system inclination angle α, and the optical system inclination angle α is obtained from the parallel state of the lens surface 2 and the sensor surface 3. The angle at which the sensor unit 130 is rotated so as to satisfy the Scheimpplug condition is referred to as the Scheimpplug angle θ.

As shown in FIG. 6, when the distance between the reference point T and the lens center point Q is X, and the distance between the reference point T and the Scheimpplug point S is R, the R value is represented by Equation 1 It can be expressed as

라 하고, 기준점(T) 및 센서중심점(P) 간 거리를 C라 할 때,

값은 제2코사인법칙에 따라 수학식 2와 같이 나타낼 수 있다.The distance between the sensor center point (P) and the Scheimpplug point (S)

When the distance between the reference point (T) and the sensor center point (P) is C,

The value may be represented by Equation 2 according to the second cosine law.

의 연장선 및 C의 연장선이 이루는 각도를 β라 할 때, β 값은 수학식 3과 같이 나타낼 수 있다.Meanwhile

When an angle formed by an extension line of and an extension line of C is β, the β value may be expressed by Equation 3 below.

Substituting Equation 2 into Equation 3 and arranging for β, Equation 4 below can be obtained.

At this time, if the chime plug angle θ is represented by β, it can be expressed as Equation 5 below.

Substituting Equation 4 into Equation 5 and arranging θ, the Scheimpplug angle θ value can be obtained through Equation 6 below.

Mixed color detection device of the organic light emitting device of the present invention

7 to 10 show an embodiment of the detection device of the present invention, as shown in the mixed color failure detection device 100 of the organic light emitting device of the present invention, the lens unit 120, the sensor unit 130 And a controller (not shown), and inspects a planar cell in which a plurality of organic light emitting diodes are two-dimensionally arranged. The mixed color failure detection device 100 of the organic light emitting device of the present invention, the lens unit 120, the sensor unit 130 and the like so that the module 110 can be accommodated stably, as shown, It may further include.

The lens unit 120 is formed to be disposed parallel to or inclined to the surface of the cell. In this case, since the lens unit 120 and the like are stably supported by the case 110, the modular detection device 100 itself is attached to a separate moving device to move the lens surface of the lens unit 120 ( 2) can be arranged parallel to or inclined to the face of the cell. When the lens unit 120 is formed of a single lens, the lens surface 2 is obviously determined as a single lens center plane. Meanwhile, when the lens unit 120 is formed by stacking a plurality of lenses, the lens unit 120 may be determined to be the center plane of the lens disposed closest to the object plane 1.

The sensor unit 130 is formed in a planar shape in which a plurality of image sensors are two-dimensionally arranged to serve to sense an image of the cell acquired through the lens. In addition, the sensor unit 130 is formed to be disposed parallel or inclined to the surface of the lens unit 120, so that the sensor unit 130, even if the detection device 100 is disposed at any optical tilt angle (α) By moving separately, the Scheimpplug condition can be satisfied. For the rotation of the sensor unit 130, the detection device 100 may further include a tilt motor 135 for adjusting the angle of the sensor unit 130.

The controller controls the angle of the lens unit 120 or the sensor unit 130. When the controller wants to adjust the angle of the sensor unit 130, the controller may control the tilt motor 135. On the other hand, when the control unit wants to adjust the angle of the lens unit 120, as shown in the detection device 100 is modularized so that the detection device 100 itself to form a certain optical tilt angle (α) When it is necessary to move the mobile device, the control unit may control the mobile device.

After the controller adjusts the angle of the lens unit 120 to a certain optical tilt angle α, the controller is an extension line of the object surface 1, an extension line of the lens surface 2 and the sensor surface (3). The angle of the sensor unit 130 may be adjusted so that the Scheimpplug condition of which the extension line of the () is satisfied is satisfied. Of course, if the angle of the sensor unit 130 is predetermined, the control unit may be made to adjust the angle of the lens unit 120 according to the angle of the sensor unit 130. In any case, the controller can calculate the Scheimpflug angle θ by the following equation (according to the principles described above).

(Here, θ: Scheimpplug angle, α: Optical tilt angle, C: Distance between reference point and sensor center point, R: Distance between reference point and Scheimpplug point)

In addition, the detection apparatus 100 may further include a zoom motor 125 for adjusting a distance between the lens unit 120 and the sensor unit 130. The lens magnification may be adjusted by adjusting the distance between the lens unit 120 and the sensor unit 130, and by adjusting the lens magnification, an image of the cell having various sizes may be easily and effectively obtained.

Mixed color detection method of the organic light emitting device of the present invention

The detection method for detecting the color mixture defect by using the color mixture defect detecting apparatus 100 of the organic light emitting device of the present invention as described above will be described in more detail. The mixed color detection method of the organic light emitting device of the present invention, as shown in Fig. 11, includes a reference image sensing step, viewing angle tilt control step, saim plug condition satisfaction step, gradient image sensing step, mixed color defect detection step.

In the reference image sensing step, a reference image which is an image of the entire cell area in the state where the optical system tilt angle α is 0 and the lens surface 2 and the sensor surface 3 are in parallel is sensed. When the optical system tilt angle α is 0 and the lens surface 2 and the sensor surface 3 are in a parallel state, both the object surface, the lens surface, and the sensor surface are in a parallel state, and thus the relationship with the Scheimpplug condition is achieved. You can get a well-focused image without In addition, since image acquisition is performed with the lens facing the object in front, an image without shape distortion can be obtained. For example, if the cell as an object has a rectangular shape, the reference image obtained in the reference image sensing step also comes out in a rectangular shape.

In the viewing angle tilt adjusting step, the optical system tilt angle α is adjusted to a non-zero angle. As described above, when the mixed color defect inspection is performed using the image photographed from the front, there is a case that the mixed color defect that is not severe enough may not be caught. In this case, it is possible to detect such a mixed color defect by tilting the viewing angle.

In the step of satisfying the Scheimpplug condition, the angle of the sensor surface 3 is adjusted to the Scheimpplug angle θ so that the Scheimpplug condition is satisfied. As described above, when the viewing angle is inclined and viewed obliquely, in the case of the optical system in which the lens plane and the sensor plane are fixed in parallel with each other, the focal plane and the object plane are greatly displaced, thereby obtaining an unfocused image. If the detection image is not in focus, the mixed color defect detection of the organic light emitting device will not be performed correctly even if the image is analyzed. Therefore, the focused image should be obtained even when the viewing angle is tilted. At this time, as described in the principle description above, even if the optical system and the object plane is inclined, if the Scheimpplug condition is satisfied, a well-focused image can be obtained. That is, the detection apparatus 100 of the present invention is configured to be able to adjust the angle between the lens surface and the sensor surface in order to be able to obtain a focused image even in this inclined viewing angle.

In the inclined image sensing step, an inclined image, which is an image of the entire cell region, is sensed after the Scheimpplug condition satisfaction step. As described above, when the extension lines of the object plane, the lens plane, and the sensor plane meet at one point, and the Scheimpplug condition is satisfied, a well-focused image can be obtained. Therefore, by analyzing the inclined image, it is possible to detect a mixed color defect in a state in which the viewing angle is oblique. On the other hand, at this time, for example, if the cell as an object has a rectangular shape, the inclined image obtained in the inclined image sensing step comes out in a trapezoidal shape which is a distorted shape.

In the mixed color defect detecting step, the reference image and the inclined image are analyzed to detect a mixed color defect. In this case, there may be various methods of analyzing the reference image and the inclined image, which will be described below with reference to the embodiment of FIG. 11.

As shown in FIG. 11, the mixed color defect detection step may include an image conversion step, a partition classification step, and a detection information acquisition step.

In the image conversion step, the outline shape of the inclined image is converted to be the same as the outline shape of the reference image to generate a converted image. As described above, for example, if the cell is rectangular in shape, the reference image is in a rectangular shape (without distortion), and the inclined image is in trapezoidal shape (as it is distorted). In this case, the tilted image may be easily generated as the transformed image by using a method of coordinate transformation corresponding to each point of the reference image and the tilted image, that is, an affine transformation. Since the affine transformation is only a spatial transformation, it does not affect the brightness of the image. Thus, there is no problem in checking mixed color defects using the converted image made using the affine transformation.

In the partition classification step, the reference image and the converted image are divided into a plurality of predetermined sections. As described above, when the cell has a rectangular shape, the cell may be divided into M rows and N columns and divided into M ㅧ N partitions, where M and N values may be appropriately determined as desired by a user.

In the detection information acquisition step, detection information including an average color and light intensity is obtained for each of the partitions. The mixed color defect may be inspected using the acquired detection information, and at least one of the reference image defect determination step, the conversion image defect determination step, and the image comparison failure determination step may be performed according to the inspection method.

In the reference image defective determination step, the detection information for each section of the reference image is compared with each other, and it is determined whether a mixed color defect has occurred according to a predetermined criterion. For example, when the reference image is acquired with the R color turned on for the entire cell, the detection information obtained in all M ㅧ N sections will be identical if the mixed image defect is an ideal case. On the other hand, when mixed color defects occur in one compartment, that is, as an example, when G or B organic light-emitting material is mixed at a position where the R organic light-emitting material should be printed, the R value is lower than that of the other compartments and G Or B value will be high. If such a compartment is found, it can be determined that a mixed color defect has occurred in the compartment. However, in the ideal case as described above, the detection information in all the sections will be the same, but in reality, the detection information in all the sections cannot be completely the same due to some noise. Therefore, when the mixed color defect is determined, it is preferable that the mixed color defect is determined in such a manner that the detected information in each section is within a range of a predetermined appropriate level, and is determined as being out of the range.

In the converted image defective determination step, similarly to the reference image defective determination step, mixed color defect occurrence is determined using the converted image. That is, the detection information of each section of the converted image is compared with each other, and it is determined whether a mixed color defect occurs according to a predetermined criterion. As described above, when the mixed color defect is severe, the mixed color defect is easily detected even in the image viewed from the front (that is, the reference image), but when the mixed color defect is not severe, the mixed color defect may not be well detected at the front side. In this case, by performing the mixed color defect detection using the image viewed at an angle (that is, the converted image), it is possible to detect the mixed color defect that is not so severe and not detected from the front.

In the image comparison failure determination step, the detection information between the selected section of the reference image and the section of the converted image corresponding thereto is compared with each other, and it is determined whether a mixed color defect has occurred according to a predetermined criterion. In each of the reference image defective determination step or the converted image defective determination step, mixed color failure is determined solely by the reference image or the converted image. As described above, in the ideal case, when there is no defect, the detection information in all sections should appear the same, but in reality, a slight brightness difference may appear depending on the position due to noise such as lighting. However, if the failure criteria are taken in consideration of such variables, there is a risk that the standard range becomes too wide. On the other hand, in the image comparison failure determination step, since mixed color defects are determined by comparing the converted images with reference to the reference image, it is not necessary to hold the range of defect determination criteria unnecessarily. In this way, a mixed color defect, which is not detected when viewed from the front but can be detected when tilted, can be detected more effectively.

In the mixed color detection step, it is not necessary to perform all of the reference image defect determination step, the conversion image defect determination step, and the image comparison failure determination step as described above. For example, if a mixed color defect is detected in the reference image by first performing the reference image defective determination step, the mixed color defect has already been detected, and the remaining two steps do not need to be performed. On the other hand, if the mixed color defect is not detected in the reference image, it is necessary to check whether the mixed color defect is detected in the converted image. At this time, the mixed image defect determination step and the image comparison defect determination step are performed by any one of the two steps. Detection may be performed or both steps may be performed.

In addition, after acquiring one reference image, multiple oblique images may be acquired by changing the inclination angle of the optical system to detect mixed color defects. For example, after acquiring one reference image, if the angle of inclination of the optical system is inclined 45 degrees to the right, and is inclined to 45 degrees to the left, two inclined images are acquired in this way. Detection can be performed. In this case, the steps related to the tilted image described above may of course be repeated as many times as the number of the tilted image when acquiring and detecting each tilted image.

The present invention is not limited to the above-described embodiments, and the scope of application of the present invention is not limited to those of ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Of course, various modifications can be made.

10: camera
1: Object plane 1 ': Focal plane
2: lens surface 3: sensor surface
3 ': initial sensor surface
100: detection device
110: case
120: lens unit 125: zoom motor
130: sensor unit 135: tilt motor
Q: Lens center point P: Sensor center point
T: Reference point S: Scheimpplug point

Claims (16)

delete delete delete delete delete delete A lens unit including a lens, a sensor unit for sensing an image of the cell acquired through the lens, to inspect a planar cell in which a plurality of organic light emitting elements are arranged two-dimensionally, the lens unit or the sensor In the mixed color detection method of the organic light emitting device using the mixed color detection device of the organic light emitting device comprising a control unit for adjusting the negative angle,
The surface of the cell is called an object plane, the center plane of the lens included in the lens unit is called a lens plane, the surface of the sensor unit is called a sensor plane, the center point of the lens is called a lens center point, and the center point of the sensor unit is Is a sensor center point, and a point where a straight line connecting the lens center point and the sensor center point meets the object plane is referred to as a reference point, and a sine that the extension line of the object plane, the extension line of the lens plane and the extension line of the sensor plane coincide The point that satisfies the plug condition is called a Scheimpplug point, and the angle formed by the object plane and the lens plane is called an optical system inclination angle. When the angle to rotate the sensor unit to satisfy the Scheimpplug angle,
A reference image sensing step of sensing a reference image which is an image of the entire cell area when the optical system tilt angle is 0 and the lens plane and the sensor plane are parallel to each other;
A viewing angle tilt adjustment step of adjusting the optical tilt angle to a non-zero angle;
A schimeplug condition satisfaction step of adjusting an angle of the sensor surface to the schimeplug angle so that a schimeplug condition is satisfied;
An inclined image sensing step of sensing an inclined image which is an image of the entire area of the cell in a state after the step of satisfying the sham plug condition;
A mixed color detection step of detecting a mixed color defect by analyzing the reference image and the inclined image;
Mixed color failure detection method of an organic light emitting device comprising a.
The method of claim 7, wherein the mixed color detection step,
An image conversion step of converting the outline shape of the tilted image to be the same as the outline shape of the reference image to generate a converted image;
A partition division step of dividing the reference image and the converted image into a plurality of predetermined sections;
A detection information acquisition step of obtaining detection information including an average color and light intensity for each of said sections;
Mixed color failure detection method of an organic light emitting device comprising a.
The method of claim 8, wherein the mixed color detection step,
A reference image defect determination step of comparing detection information of each section of the reference image with each other to determine whether a mixed color defect has occurred according to a predetermined criterion;
A converted image defectiveness determining step of determining whether mixed color defects are generated according to a predetermined criterion by comparing detection information of each section of the converted image with each other;
An image comparison failure determination step of comparing the detection information between the selected section of the reference image and the section of the converted image corresponding thereto to determine whether a mixed color defect has occurred according to a predetermined criterion;
Mixed color failure detection method of an organic light emitting device, characterized in that it comprises at least one selected.
The method of claim 8, wherein the image conversion step,
The mixed image detection method of the organic light emitting device, characterized in that the conversion image is generated using affine transformation (affine transformation). delete delete The method of claim 7, wherein the SheimerPlus condition satisfaction step,
The method of detecting a color failure of an organic light emitting device, characterized in that to calculate the Scheimpflug angle by the following equation.

(Here, θ: Scheimpplug angle, α: Optical tilt angle, C: Distance between reference point and sensor center point, R: Distance between reference point and Scheimpplug point)
delete delete delete

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