KR102041408B1 - Flare test system of camera module - Google Patents

Abstract

The present invention relates to a flare measuring apparatus of the camera module, and to describe in more detail, a camera fixing jig 10 for fixing the camera module (M); A light source box 20 provided with a light source for irradiating test light toward the camera module M; A jig support part 30 which fixes and supports the camera fixing jig 10; A light source support part 40 for rotatably supporting the light source box 20 in left and right directions and in a vertical direction; A base part 50 supporting the jig support part 30 and the light source support part 40; An input unit 60 for presetting a rotation path of the light source box 20 and an imaging time of the camera module M; A controller 70 for automatically controlling a rotation operation of the light source box 20 and an imaging time of the camera module M according to an input value set in the input unit 60; It relates to a flare measuring apparatus comprising a.

Description

Flare measuring system of camera module {Flare test system of camera module}

The present invention relates to a flare measuring device of the camera module, and to describe in more detail, a camera fixing jig for fixing the camera module; A light source box provided with a light source for irradiating test light toward the camera module; A jig support part which fixes and supports the camera fixing jig; A light source support part rotatably supporting the light source box in left and right directions and in a vertical direction; A base part supporting the jig support part and the light source support part; An input unit configured to preset a rotation path of the light source box and an imaging time of the camera module; A control unit for automatically controlling a rotation operation of the light source box and an imaging time of the camera module according to an input value set in the input unit; It relates to a flare measuring apparatus comprising a.

Recently, with the development of electronic technology, various types of imaging devices have been developed and marketed. In addition to conventional digital cameras, portable electronic devices such as smartphones and tablet PCs are equipped with camera modules such as CCD image sensors and CMOS image sensors. Such electronic devices may transmit image data captured by a camera module in addition to text data in real time.

In addition, according to the trend of miniaturization of electronic devices, various units constituting the camera module, particularly optical lenses, are becoming smaller. In this way, miniaturization of the optical lens increases the diffraction and scattering of light when photographing a subject, and thus increases the possibility of a so-called flare phenomenon that causes the image pickup screen to become whitish.

The flare phenomenon is a phenomenon in which incident light is reflected from the lens surface and the inner wall of the barrel, and acts as one of the important factors that degrade the performance of the camera module. Therefore, in the manufacturing process of the imaging device including the optical lens, it is necessary to test whether or not the flare phenomenon occurs. In accordance with this need, Korean Patent Registration No. 10-0995292 (November 12, 2010) provides a 'lens' which can measure flare generation while irradiating various angles of light to an optical lens in a dark room. Flare Test System 'is introduced.

FIG. 6 shows the configuration of the lens flare test system, which includes an integrated booth 10 having a dark room structure, a lens setting stage 20 and a light source stage 30 installed therein, and the light source. It is configured to include a rotary bar 40 that can rotate the stage 30. Thus, the test light is irradiated from the light source source SC of the light source stage 30 with the optical lens PLZ of the imaging device CA fixed to the lens setting stage 20. Then, the rotation bar 40 is used to test where the flare occurs while varying the incident angle of the test beam irradiated to the optical lens PLZ.

In FIG. 6, the reference numeral '60' is a 'preliminary light box' and the description of other non-described reference numerals is omitted.

Republic of Korea Patent Registration No. 10-0995292 (November 12, 2010)

The conventional 'lens flare test system' as shown in FIG. 6 includes an angle of incidence of test light irradiated from the light source stage 30 to the optical lens PLZ, a time for the image capturing device CA to capture an image, and the like. Since all must be operated manually, there was a problem that the measurement results cannot be industrially standardized or standardized.

Accordingly, an object of the present invention is to provide a flare measuring apparatus capable of automatically and accurately measuring flare generation by variously and easily setting the illumination intensity and the incident angle of the test light irradiated from a light source and the imaging time of the test camera module. To provide.

In addition, another object of the present invention is to standardize and standardize the illuminance and the incident angle of the test light irradiated from the light source and the imaging time of the camera module under test, so that the flare measurement results can be efficiently utilized to improve the flare phenomenon of the camera module. It is to provide a flare measuring device.

Flare measuring apparatus of the camera module according to the invention, the camera fixing jig for fixing the camera module; A light source box provided with a light source for irradiating test light toward the camera module; A jig support part which fixes and supports the camera fixing jig; A light source support part rotatably supporting the light source box in left and right directions and in a vertical direction; A base part supporting the jig support part and the light source support part; An input unit configured to preset a rotation path of the light source box and an imaging time of the camera module; A control unit for automatically controlling a rotation operation of the light source box and an imaging time of the camera module according to an input value set in the input unit; Characterized in that comprises a.

The flare measuring apparatus of the camera module according to the present invention has the following effects.

First, it is possible to freely and easily adjust the illuminance, the incident angle, and the imaging time of the test camera module to accurately measure flare in various conditions.

Second, since the entire flare measuring device is compactly configured as an organic system, space utilization is high in an industrial site.

Third, the operation method is easy and automated, so it can be operated with minimum personnel and low cost.

1 is a perspective view of a flare measuring apparatus according to the present invention,
2 is a partial cutaway cross-sectional view of the flare measuring apparatus according to the present invention;
3 is an operating state diagram of the flare measuring apparatus according to the present invention,
4 is a view illustrating a screen configuration of an input unit in the flare measuring apparatus;
5 is an operation flowchart of the flare measuring apparatus according to the present invention,
6 is a diagram illustrating the structure of a conventional flare measuring apparatus.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. However, since the accompanying drawings illustrate preferred embodiments of the present invention, the protection scope of the present invention is not limited by these embodiments. In addition, even if a configuration necessary for carrying out the present invention, a detailed description is omitted for matters that are introduced in the prior art or that can be easily implemented by those skilled in the art from the known technology.

The flare measuring apparatus of the camera module according to the present invention, as shown in Figure 1, the camera fixing jig 10, the light source box 20, the jig support 30, the light source support 40, the base 50, It is configured to include an input unit 60 and a control unit 70. In FIG. 1, the controller 70 is not visible.

For reference, in the present invention, assuming that the flare measuring apparatus of FIG. 1 is installed vertically on the floor, the horizontal direction is referred to as 'left and right direction' or 'X axis direction', and the vertical direction is 'up and down direction' or 'Y'. Axial direction '.

The camera fixing jig 10 is to fix the camera module (M) to be measured flare, it is preferable to have a structure capable of fixing the camera module (M) of various types if possible. The camera fixing jig 10 may have a pair of claws 11 that are open to both sides with elastic restoring force.

Next, the light source box 20 has a structure in which a light source is installed on the reflector plate 21 by irradiating a test light toward the camera module (M). The light source is preferably composed of an LED lamp 22 provided at the center of the reflecting plate 21 and a pair of fluorescent lamps 23 provided at both sides of the LED lamp 22. In addition, a halogen lamp may be used. have.

Since the LED lamp 22 generates direct sunlight such as the sun around a point light source, it is easy to adjust illumination, and further, it is easy to measure an afterimage of light remaining in the camera module M due to light scattering and diffuse reflection. . In addition, the fluorescent lamp 23 is easy to measure the refraction of light passing through the camera lens because a lot of refraction occurs due to the diffusion of the light source.

The jig support part 30 functions to fix and support the camera fixing jig 10 at a specific position. According to a preferred embodiment of the present invention, the jig support 30 is configured to include a support cylinder 31, the lifting bar 32 and the horizontal support (33).

The support cylinder 31 is installed upright on one side of the base portion 50 in a vertical direction, and is preferably installed to move toward or away from the light source box 20. The lifting support 32 is supported so that the height can be adjusted in the support cylinder 31, the upper end is exposed over the support cylinder 31, it can be fixed in a specific position. The horizontal support 33 extends in a direction parallel to the light source box 20 at the upper end of the elevating bar 32.

The camera fixing jig 10 is provided on the horizontal support 33, preferably on the horizontal support 33 to be movable in the front and rear and left and right directions. As a result, according to a preferred embodiment of the present invention, the camera module (M) fixed to the camera fixing jig 10 is movable in the front, rear, left and right directions, respectively, from the light source box 20, fixed at a specific position You can.

The light source support part 40 supports the light source box 20 so as to be rotatable in the horizontal direction and the vertical direction, and includes a rotating cylinder 41 and a vertical rotating arm 42. The rotary cylinder 41 is installed upright on the base portion 50 so as to be rotatable in the left and right directions, and the vertical rotating arm 42 is hinged rotatably in the vertical direction at the upper end of the rotary cylinder 41. Are combined. In FIG. 2, reference numeral '43' is a 'hinge portion' connecting the rotary cylinder 41 and the longitudinal rotating arm 42.

The light source box 20 is installed at the free end of the vertical rotation arm 42, preferably hinged to be folded over the vertical rotation arm 42. In FIG. 1, reference numeral '24' is a 'hinge portion' connecting the light source box 20 and the vertical rotation arm 42.

According to a preferred embodiment of the present invention, an upper end of the rotating cylinder 41 is provided with a protractor 44 that can determine the rotation angle of the vertical rotating arm 42, the end of the vertical rotating arm 42 The rotating needle 42a which rotates along the protractor 44 is attached to it. Thus, when the vertical rotation arm 42 rotates in the vertical direction, the angle of the X axis direction of the vertical rotation arm 42 may be visually confirmed through the rotation needle 42a and the protractor 44.

The base portion 50 serves to support the jig support portion 30 and the light source support portion 40, and has a housing having an inner space, preferably a rectangular enclosure shape. The lower end of the base 50 is provided with a moving roller 51 so as to easily move the flare measuring apparatus of the present invention. On the upper surface of the base portion 50, the division scale 52 is displayed to visually check the rotational angle of the X-axis direction of the rotary cylinder 41, and at the lower end of the rotary cylinder 41, the division scale ( A rotary needle 40a that rotates along 52 is provided.

Inside the base portion 50, as shown in Figure 2, the bearing 41a for rotatably supporting the rotating cylinder 41, the drive pulley 41b provided at the lower end of the bearing 41a and And a first drive motor 41c for rotating the drive pulley 41b. The drive pulley 41b and the first drive motor 41c are connected to each other by a drive belt (not shown). Therefore, when the rotating cylinder 41 rotates in the left and right directions, the light source box 20 installed at the end of the longitudinal rotating arm 42 rotates in the X axis direction. A sensor (not shown) is installed inside the base 50 to detect a rotational position of the rotating cylinder 41 to limit the rotation angle of the light source box 20.

On the other hand, inside the rotary cylinder 41, a screw rod 41d disposed in the vertical direction and a second drive motor 41e for rotating the screw rod 41d are provided. Then, the elevating bracket 41f is mounted on the screw rod 41d so that the elevating bracket 41f moves in the vertical direction when the screw rod 41d is rotated forward or reverse. Unexplained reference numeral '41g' is a 'decelerator' for transmitting the rotational force of the second drive motor 41e to the screw rod 41d.

One side of the elevating bracket (41f) is screwed to the screw rod (41d), the other side is exposed to the outside of the rotating cylinder 41 to support the middle portion of the longitudinal rotating arm (42). Therefore, the lifting bracket 41f is raised or lowered according to the rotational direction of the screw rod 41d, and at the same time, the vertical rotation arm 42 rotates in the vertical direction, and the light source box 20 installed at the end thereof is in the Y-axis direction. Rotate Inside the rotating cylinder 41, a sensor (not shown) is installed to sense the vertical position of the lifting bracket 41f to limit the rotation angle of the light source box 20.

FIG. 3 is a view illustrating a state (A) in which the light source box 20 is rotated to an upper limit angle in the Y-axis direction and a state (B) rotated to a lower limit angle. According to a preferred embodiment of the present invention, the light source box 20 is rotated within the range of 60 degrees to the left, 60 degrees to the right, 100 degrees to the upper side, 45 degrees to the lower side around the camera fixing jig 10. do.

The input unit 60 is a means for inputting a command for the rotation path of the light source box 20 and the imaging time of the camera module M. The input unit 60 may be selected from conventional input means, and preferably in the form of an LCD touch screen.

4 is a view illustrating a screen configuration of the input unit 60 according to an embodiment of the present invention, wherein the light source operating unit 61, the rotation angle setting unit 62, the capture angle setting unit 63, and the camera operating unit 64 are provided. ) And a scene storage unit 65. First, the light source operator 61 sets the illuminance levels of the light source, that is, the fluorescent lamp and the LED, by using the '+ /-' button, and controls 'ON / OFF'. In addition, the rotation angle setting unit 62 rotates the light box 20 in the X and Y axis directions using 'X start angle' and 'X stop angle' and 'Y start angle' and 'Y stop angle', respectively. Set the position to start and stop. When the 'motor origin' button is pressed, the light box 20 moves to a position where 'start angle X' and 'start angle Y' are set.

The capture angle setting unit 63 moves the left and right and up and down directions of the light source box 20 to the 'X capture angle' and 'Y capture angle' within the rotation range input to the rotation angle setting unit 62. Set the angle. That is, when '5 degrees' is input for 'X capture angle' and '120 degrees' is input for 'Y capture angle,' the light source box 20 is input to the rotation angle setting unit 62. Starting at 'start angle' and 'starting angle Y', move 5 degrees in the X-axis direction, move 120 degrees in the Y-axis direction, move 5 degrees in the X-axis direction, and then move 120 degrees in the Y-axis direction. Keep repeating. This rotation operation is terminated at the 'X stop angle' and 'Y stop angle' input to the rotation angle setting unit 62.

The camera operation unit 64 sets the imaging time of the camera module M mounted on the camera fixing jig 10. In other words, if '3 seconds' is input in 'Shutter ON', the shutter of the camera module (M) is automatically opened once every 3 seconds and takes a picture. The movement of the light source box 20 is stopped while the shutter of the camera module M is opened.

The scene storage unit 65 stores the entire input value set in the input unit 60 in one operation mode. In the input unit 60 of FIG. 4, all five different operation modes may be input. In addition, when a specific angle is input to the 'X angle' or 'Y angle' and the 'start' button is pressed, the light source box 20 moves directly to the input angle. In addition, the position of the light source box 20 may be manually moved using four arrows indicating up, down, left and right directions. Pressing the 'Stop' button on the top of the input unit 60, all the operation of the system is stopped.

Finally, the controller 70 automatically controls the rotation operation of the light source box 20 and the imaging time of the camera module M according to the input value set in the input unit 60. As shown in FIG. 2, the control unit 70 is preferably installed in the base unit 50, and the control unit 70 and the camera module M are connected to each other by wire or wirelessly.

5 is a flowchart illustrating a method of operating a flare measuring apparatus according to the present invention. The flare measuring device operates in a typical dark room. When power is applied to the flare measuring device and the system is operated using the input unit 60, the light source box 20 rotates in the X and Y axis directions at a preset input value. At this time, the camera module M mounted on the camera fixing jig 10 continuously takes a picture according to a preset time.

The pictures taken by the camera module M are stored in the camera module M together with the time taken and the coordinates of the light source at that time, that is, the X and Y axis positions. After the light source box 20 rotates from the start angle to the stop angle, the information stored together with the pictures stored in the camera module M is transferred to a computer, and then how much flare occurs when the light source is at a certain position. Observe whether or not. These test results are used as data to reduce the flare generation of the camera module (M).

The flare measuring apparatus according to the present invention may be used for focusing a camera lens or inspecting an image in addition to measuring flare generation of the camera module M. FIG.

10; Fixing jig 11; nippers
20; Light source box 21; Reflector
22; LED lamp 23; Fluorescent lamp
24,43; Hinge portion 30; Jig Support
31; Support cylinder 32; Lifting bar
33; Transverse support 40; Light source support
40a, 42a; Angle hand 41; Rotating cylinder
41a; Bearing 41b; Driving pulley
41c, 41e; Drive motor 41d; Screw rod
41f; Lifting bracket 41g; reducer
42; Longitudinal arm 44; Protractor
50; Base portion 51; Moving roller
52; Minute scale 60; Input
61; A light source manipulation unit 62; Rotation angle setting part
63; A capture angle setting unit 64; Camera control panel
65; Scene storage 70; Control
M; Camera module

Claims (12)

A camera fixing jig 10 for fixing the camera module M;
A light source box 20 provided with a light source for irradiating test light toward the camera module M;
A jig support part 30 which fixes and supports the camera fixing jig 10;
A light source support part 40 for rotatably supporting the light source box 20 in left and right directions and in a vertical direction;
A base part 50 supporting the jig support part 30 and the light source support part 40;
An input unit 60 for presetting a rotation path of the light source box 20 and an imaging time of the camera module M;
And a controller 70 for automatically controlling the rotation operation of the light source box 20 and the imaging time of the camera module M according to the input value set in the input unit 60.
The light source support part 40 is a rotary cylinder 41 which is installed upright on the base part 50 so as to be rotatable in a left and right direction, and hinged to be rotatable in a vertical direction at an upper end of the rotary cylinder 41. It includes a vertical rotating arm 42,
The light source box 20 is a flare measuring device of the camera module, characterized in that installed on the free end of the vertical rotation arm 42 to rotate up and down, left and right around the camera fixing jig (10).
The light source box 20 of claim 1, wherein the light source box 20 includes an LED lamp 22 provided at the center of the reflector plate 21 and a pair of fluorescent lamps 23 provided at both sides of the LED lamp 22. Flare measuring device of the camera module, characterized in that.
According to claim 1, The jig support 30, the support cylinder 31 is installed upright on one side of the base portion 50, the height can be adjusted in a state that the upper end is exposed to the support cylinder (31). And a horizontal support 33 extended in a direction parallel to the light source box 20 at an upper end of the elevating bar 32, and the camera fixing jig 10. Flare measuring device of the camera module, characterized in that installed on the horizontal support (33).
According to claim 3, The support cylinder 31 is installed on the base portion 50 so as to move toward or away from the light source box 20, the camera jig 10 is installed Flare measuring apparatus of the camera module, characterized in that installed on the horizontal support 33 to move in the front and rear and left and right directions.
delete A bearing (41a) for supporting the rotary cylinder (41) rotatably, a drive pulley (41b) provided at a lower end of the bearing (41a), Flare measuring apparatus of the camera module, characterized in that the first drive motor (41c) for rotating the drive pulley (41b) is provided.
The screw rod (41d) arranged in the up-down direction, the 2nd drive motor (41e) which rotates the said screw rod (41d), and the said screw rod in the inside of the said rotating cylinder (41). A device for measuring flare of a camera module, characterized in that a lifting bracket (41f) is provided to support an intermediate portion of the longitudinal rotating arm (42) while lifting in accordance with the rotational direction of (41d).
According to claim 1, The upper end of the rotating cylinder 41 is provided with a protractor 44 that can measure the rotation angle of the longitudinal rotating arm 42, the end of the longitudinal rotating arm 42 Device for measuring flare of a camera module, characterized in that the rotating needle (42a) is rotated along the protractor (44).
The flare measuring apparatus of claim 1, wherein the light source box (20) is coupled to each other by a hinge part (24) so that the light source box (20) can be folded and folded on the longitudinal rotating arm (42).
According to claim 1, wherein the light source box 20 is configured to rotate within the range of 60 degrees to the left, 60 degrees to the right, 100 degrees to the upper side, 45 degrees to the lower side around the camera fixing jig 10 as a center. Flare measuring device of the camera module, characterized in that.
According to claim 1, wherein the input unit 60, the light source control unit 61 for controlling the light source installed in the light source box 20, and the light source box 20 starts to rotate in the X-axis and Y-axis direction, respectively Rotation angle setting unit 62 to set the position to stop and the position to stop, and set the angle to move the light source box 20 in the left and right and up and down direction within the rotation range set in the rotation angle setting unit 62 A scene for storing a capture angle setting unit 63, a camera operating unit 64 for setting an imaging time of the camera module M, and an entire input value set in the input unit 60 in one operation mode. ) Flare measuring device of the camera module, characterized in that comprises a storage (65).
The flare measuring apparatus of claim 1, wherein the control unit (70) is provided inside the base unit (50) and is connected to the camera module (M) by wire or wirelessly.

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