KR20220131622A - A System for Measuring a Property of a Light from Multi-Directions - Google Patents

Abstract

The present invention relates to a system for measuring spectral characteristics in a plurality of directions. The system for measuring spectral characteristics in a plurality of directions comprises: a plurality of light incidence units (13_1 to 13_N) disposed separately from each other in a circumferential direction to guide light emitted from an object (11) to be tested; a light guiding unit (15) for guiding the light, guided by the light incidence units (13_1 to 13_N), to a measuring means (17); and a spectrum fiber (16) for connecting the light guiding unit (15) and the measuring means (17). The plurality of light incidence units (13_1 to 13_N) have a guide means for guiding light. Therefore, the system can measure the characteristics of optical signals acquired at various angles, without errors.

Description

Spectral property inspection system for multiple directions {A System for Measuring a Property of a Light from Multi-Directions}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a system for inspecting spectral characteristics for multiple directions, and more particularly, to a system for inspecting spectral characteristics for multiple directions capable of measuring spectral characteristics at various angles with respect to a display.

It is advantageous that uniformity of brightness, color, or similar optical characteristics of images displayed on various types of displays is maintained in a range of a predetermined viewing angle irrespective of the angle. In order to manufacture a display having a uniform optical characteristic at various angles, optical characteristics of the display viewed from various angles are measured, and a display structure must be designed based on this. In order to measure the optical characteristics of the display at various angles, the spectral characteristics may be measured by installing a plurality of measuring instruments for each angle along a circumferential direction having a predetermined radius with respect to the display. However, the measuring device having such a structure increases the manufacturing, maintenance, or management cost of the inspection system, and has a disadvantage in that it is difficult to secure consistent and objective data because a measurement error occurs between different measuring devices. Patent Publication No. 10-2014-0036907 discloses a method for measuring the degree of non-uniformity of the luminance of a display panel. In addition, Patent Publication No. 10-2015-0137196 discloses an apparatus for measuring luminance and chromaticity distribution. This prior art does not disclose a method capable of measuring the characteristics of light emitted from the display at different angles.

The present invention is to solve the problems of the prior art and has the following objects.

Prior Art 1: Patent Publication No. 10-2014-0036907 (Samsung Display Co., Ltd., published on March 26, 2014) A method for measuring the non-uniformity of the luminance of a display panel Prior Art 2: Patent Publication No. 10-2015-0137196 (McScience Co., Ltd., published on December 9, 2015) Luminance and chromaticity distribution measuring device

An object of the present invention is to transmit an optical signal obtained through a plurality of optical fibers to a measurement module such as a single spectrometer through one optical fiber so that the characteristics of the optical signal obtained from various angles can be measured without error. It is to provide a spectral property inspection system for multiple directions.

According to a preferred embodiment of the present invention, a spectral characteristic inspection system for multiple directions includes: a plurality of light inlet units arranged to be separated from each other along a circumferential direction to guide light emitted from an inspection target; a light inducing unit for guiding the light guided by the light inleting unit to the measuring means; and a spectrum fiber connecting the light guiding unit and the measuring means, wherein the plurality of light inleting units have guiding means for guiding the light.

According to another suitable embodiment of the invention, the guiding means comprises a shutter or a mirror.

According to another suitable embodiment of the invention, the guiding means is a rotation guiding unit which rotates with respect to the light inlet unit.

According to another suitable embodiment of the present invention, while light is introduced into one light inlet unit, light inflow to the other light inlet unit is blocked.

The spectral characteristic inspection system for multiple directions according to the present invention arranges a plurality of optical fibers capable of receiving optical signals according to various angles based on the display along the circumferential direction to measure optical characteristics such as chromaticity or luminance for different angles. measure A plurality of optical properties detected at different points may be transmitted via respective optical fibers to one spectral fiber connected to one spectrometer, for example a spectrum meter. For example, one spectral fiber may be connected to the motor rotation shaft, and an opening is formed between a plurality of optical fibers and one spectral fiber to interlock with the spectral fiber, rotated according to the angle of the motor rotation shaft, and introduced through the opening. have. In addition, the introduced light may be transmitted to an analysis device such as a spectrum meter through a spectrum fiber to analyze optical characteristics. As such, detection light is transmitted from a plurality of optical fibers disposed at different positions to one spectral fiber, thereby reducing measurement error and facilitating manufacturing and management.

1 shows an embodiment of a spectral characteristic inspection system for multiple directions according to the present invention.
2 shows an embodiment to which the characteristic inspection system according to the present invention is applied.
3 shows another embodiment to which the characteristic inspection system according to the present invention is applied.
4 shows another embodiment to which the characteristic inspection system according to the present invention is applied.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the embodiments are for a clear understanding of the present invention, and the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so unless necessary for the understanding of the invention, the description will not be repeated and well-known components will be briefly described or omitted, but the present invention It should not be construed as being excluded from the embodiment of

1 shows an embodiment of a spectral characteristic inspection system for multiple directions according to the present invention.

Referring to FIG. 1 , a plurality of light inlet units 13_1 to 13_N are separated from each other in a circumferential direction to guide light emitted from an inspection target 11 ; a light inducing unit 15 for guiding the light guided by the light inleting units 13_1 to 13_N to the measuring means 17; and a spectrum fiber 16 connecting the light guiding unit 15 and the measuring means 17 , wherein the plurality of light inlet units 13_1 to 13_N have guiding means for guiding the light.

The inspection target 11 may be a display, for example, a smartphone, notebook, tablet electronic device, or a display for a similar type of electronic device, but is not limited thereto. The display may have various shapes, such as, but not limited to, being rectangular. The image displayed on the inspection target 11 can be viewed from various directions, for example, at various viewing angles, such as a direction perpendicular to the display plane of the inspection target 11, a direction that is 30 degrees or 45 degrees. can see. In addition, the display needs to have uniform optical characteristics in the range of the viewing angle regardless of the viewing angle. A viewing angle for the inspection target 11 is determined, and a plurality of viewing angles may be set within the viewing angle range. For example, as shown in FIG. 1 , five different gaze angles may be determined, and the luminance or color of each detection light AR1 to ARN emitted in the direction of the gaze angle may be analyzed. The detection lights AR1 to ARN emitted at different angles from the inspection target 11 may be introduced into the respective light introduction units 13_1 to 13_N installed in the detection block 12 . The detection block 12 may be formed in a spherical shape around the target 11 to be inspected. Image light may be emitted in various directions from the inspection target 11 to the detection block 12 , and the light inlet units 13_1 to 13_N may be installed at a predetermined position of the detection block 12 . The light introduction units 13_1 to 13_N may be disposed at a predetermined position of the detection block 12 , and respective light introduction units 13_1 to 13_N may be disposed. The different light inlet units 13_1 to 13_N may be disposed at different viewing angles, and the light emitted at different angles from the inspection target 11 may be introduced into the different light inlet units 13_1 to 13_N. have. In addition, the light introduced into each of the light introduction units 13_1 to 13_N may be transmitted along the transmission paths 14_1 to 14_N and guided to the light guide unit 15 . The light introduced into each light inlet unit 13_1 to 13_N may be transmitted to the same light induction unit 15 along each transmission path 14_1 to 14_N. Each of the transmission paths 14_1 to 14_N may be various path means through which light can be transmitted, such as, for example, an optical fiber. The transmission paths 14_1 to 14_N may include reflection means or transmission holes or similar optical path forming means capable of transmitting light to a predetermined position, and the present invention is not limited thereto. According to one embodiment of the present invention, while light is introduced into one light inlet unit 13_1 , light inflow to the other light inlet units 13_2 to 13_N may be blocked. In more detail, while light is introduced into the first light introduction unit 13_1 , the light from being introduced into the second to N-th light introduction units 13_2 to 13_N may be blocked. In addition, in the process in which light is introduced into the second light inlet unit 13_2 , light from being introduced into the first light inlet unit 13_1 and the third to Nth light inlet units 13_1 and 13_3 to 13_N may be blocked. . An openable and openable shutter may be installed in each of the light introduction units 13_1 to 13_N, and light may be introduced or blocked by the operation of the shutter. The introduction or blocking of light may be made in various ways and is not limited to the presented embodiment. Interference with the light to be measured by blocking the light from being introduced into the other light inlet units (for example, 13_2 to 13_N) while the light is introduced into one light inlet unit (for example, 13_1) This can be prevented. The light inducing unit 15 may have a function of transmitting the light transmitted from each of the light inlet units 13_1 to 13_N to the spectral fiber 16 to a measuring instrument 17 such as a spectrometer. The spectral fiber 16 may be an optical fiber or various light guiding means having a similar waveguide function, and the meter 17 may be, but is not limited to, a spectrometer. The spectrum of the light introduced through each of the light inlet units 13_1 to 13_N can be analyzed by the various measuring instruments 17, whereby the light characteristics for different viewing angles of the inspected object 11 such as a display are obtained. can be measured. An embodiment to which such an inspection system is applied will be described below.

2 shows an embodiment to which the characteristic inspection system according to the present invention is applied.

Referring to FIG. 2 , the spectral fiber 16 may be an optical fiber, and the transmission paths 14_1 to 14_N may also be an optical fiber. A connector 25 connected to a measuring device may be coupled to one end of the spectral fiber 16, and the other end of the spectral fiber 16 may be connected to each radially extending transmission path 14_1 to 14_N. have. In this way, one optical fiber is connected to a plurality of optical fibers branching from each other, so that light can be transmitted to the induction optical fiber through each branch optical fiber without optical loss or external interference. Incoming cameras 22_1 to 22_N for introducing light may be coupled to the end of each of the transmission paths 14_1 to 14_N by the transmission connectors 24_1 to 24_N. Shutters 21_1 to 21_N that can be opened and closed may be installed in front of each of the inlet cameras 22_1 to 22_N, and by opening and closing each of the shutters 21_1 to 21_N, light enters the inlet 23_1 to 23_N through the inlet camera. (22_1 to 22_N) may be introduced to the meter via the spectral fiber (16). An opening/closing time of each of the shutters 21_1 to 21_N may be set, and each of the shutters 21_1 to 21_N may be sequentially opened at a predetermined time interval. The opening and closing of the shutters 21_1 to 21_N may be automatically adjusted, and the transmission paths 14_1 to 14_N may be set in various numbers or in various directions according to the viewing angle to be measured, and the present invention is not limited thereto.

3 shows another embodiment to which the characteristic inspection system according to the present invention is applied.

Referring to FIG. 3 , light entering from different viewing angles may be guided to a spectral fiber by mirrors 34_1 to 34_N. The optical system barrels 31_1 to 31_N of the plurality of camera units may be disposed at predetermined positions, and light having different viewing angles may be introduced into each of the optical system barrels 31_1 to 31_N. The spectral fiber including the optical fiber may consist of a light receiving unit 35 and a transmitting unit 36, and may be installed to extend in a predetermined direction. The spectral fiber may be fixed to face a predetermined direction, and the plurality of optical system barrels 31_1 to 13_N may be separated from each other and aligned at 90 degrees or another predetermined angle with respect to the extension direction of the spectral fiber. The light detection unit 32 may be coupled to one side of each of the optical system barrels 31_1 to 31_N, and the focusing lens 33 may be coupled to the other side. The light emitted to the inspection target and introduced through the optical fiber may be guided to each focus lens 33 via the light detection unit 32 installed in each camera unit, and the focus of each focus lens 33 . Light may be introduced into the light receiving unit 35 by the mirrors 34_1 to 34_N at positions. The light introduced into the light receiving unit 35 may be guided to a measuring device through the transmitting unit 36 and analyzed. Induction of light by the mirrors 34_1 to 34_N may be performed in various ways. For example, the mirrors 34_1 to 34_N may be installed at the focal positions of each of the focusing lenses 34_1 to 34_N, and the directions of the respective mirrors 34_1 to 34_N may be adjusted. Alternatively, shutters may be installed in the optical system barrels 31_1 to 31_N. Alternatively, one mirror (eg, 34_1 ) may be moved to each focal position to guide the light transmitted through each camera unit to the light receiving unit 35 . Specifically, as one mirror (eg, 34_1) is moved linearly, the light transmitted through each camera unit at each focal position may be sequentially guided to the light receiving unit 35 . Optionally, the movement of one mirror (eg, 34_1) may be linked with the light detection unit 32 coupled to each of the optical system barrels 31_1 to 31_N. Induction of light by the mirrors 34_1 to 34_N may be performed in various ways and is not limited to the presented embodiment.

4 shows another embodiment to which the characteristic inspection system according to the present invention is applied.

Referring to FIG. 4 , the induction of light to the spectral fiber may be performed by the rotation induction unit 47 rotating with respect to the light inlet units 13_1 to 13_N. Light emitted from an inspection target such as a display may be introduced into the detection units 43_1 to 43_N. A detection frame 41 having a flat arrangement surface may be disposed, and a plurality of fixing brackets 42_1 to 42_N may be disposed at positions corresponding to the viewing angle of the detection frame 41 . A plurality of linearly extending protection conduits 44_1 to 44_N may be fixed to the fixing brackets 42_1 to 42_N, and a transmission unit such as an optical fiber capable of transmitting light may be disposed inside the protection conduits 44_1 to 44_N. have. One end of the transmitting unit may be connected to the detection units 43_1 to 43_N, and the other end of the transmitting unit may be formed to guide light in a predetermined direction. The transmission frame 45 may be installed on the rotation stage 46 , and a drum-shaped rotation induction unit 47 may be disposed on the rotation stage 46 . A guide wall 471 may be formed in a vertical direction along a part of the circumference of the rotation guide unit 47 . In addition, a detection hole DH through which light transmitted to a transmission unit such as an optical fiber may be guided may be formed in the guide wall 471 . Opposite the guiding wall 471 may be formed a guiding block 48 which is connected to a measuring guiding unit 49 which guides the light to the measuring instrument. In addition, a guide hole GH may be formed in the guide block 48 . The rotation induction unit 47 may be rotated by a driving means such as a motor, and accordingly, the detection hole DH is connected to each of the protection conduits 44_1 to 44_N so that the light is guided through the detection hole DH. (GH). Optionally, a light detection unit or a focusing lens may be installed in the protection conduits 44_1 to 44_N, and the focal point of the focusing lens may be formed in the detection hole DH or the induction hole GH. Induction of light by the rotation induction unit 47 may be accomplished in various ways and is not limited to the presented embodiment.

Although the present invention has been described in detail with reference to the presented embodiments, those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. . The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

11: target to be tested 12: detection block
13_1 to 13_N: light inlet unit 14_1 to 14_N: transmission path
15: light guide unit 16: spectral fiber
17: measuring means 23_1 to 23_N: shutter
34_1 to 34_N: mirror 47: rotation induction unit

Claims (4)

A plurality of light inlet units (13_1 to 13_N) arranged to be separated from each other along the circumferential direction to guide the light emitted from the inspection target (11);
a light inducing unit 15 for guiding the light guided by the light inleting units 13_1 to 13_N to the measuring means 17; and
a spectral fiber (16) connecting the light guiding unit (15) and the measuring means (17);
A plurality of light inlet units (13_1 to 13_N) having a guiding means for guiding the light in multiple directions of the spectral characteristic inspection system. The system according to claim 1, wherein the guiding means comprises shutters (23_1 to 23_N) or mirrors (34_1 to 34_N). The spectral characteristic inspection system according to claim 1, wherein the guiding means is a rotation guiding unit (47) that rotates with respect to the light inlet units (13_1 to 13_N). The system according to claim 1, wherein, while light is introduced into one light inlet unit (13_1), light inflow to other light inlet units (13_2 to 13_N) is blocked.

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