KR20190118316A - Apparatus for measuring performance of illumination - Google Patents

Abstract

An object of the present invention is to provide an apparatus for measuring the performance of illumination to measure the optical characteristics of a projector, such as the illuminance and contrast ratio of the projector. To this end, the present invention includes: a vertical guide part for supporting a measurement target projector to move the measurement target projector in a vertical direction and fix it at a predetermined position; a base part for moving a plurality of sensors in the x-axis direction and the y-axis direction to allow the plurality of sensors arranged in a sensor array part to be disposed in a projection region to which the light of the measurement target projector is emitted; and a sensor array part in which a plurality of sensors are arranged in an m x n matrix form and which detects the illuminance information of light emitted from the measurement target projector. Therefore, the present invention has the advantage of accurately measuring the optical characteristics of the projector such as the illuminance and the contrast ratio of the projector, and accurately measuring the optical characteristics and the uniformity of the entire screen.

Description

Lighting performance measuring device {APPARATUS FOR MEASURING PERFORMANCE OF ILLUMINATION}

The present invention relates to an illumination performance measuring apparatus, and more particularly, to an illumination performance measuring apparatus for measuring optical characteristics of a projector such as illuminance and contrast ratio of a projector.

The projector is connected to various video devices such as TV, VCR, DVD player, PC, camcorder, etc. and receives these signals to project the image enlarged through the lens onto the screen.

There are many types of such projectors, but depending on the type of device that produces the image, a CRT (Cathode Ray Tube) projector (also called 'beam projector'), LCD (liquid crystal display) projector, DLP (Digital Light) Processing) Classified into projector and LED projector (Light Emitting Diode).

In addition, since the screen projected on the screen by the projector is inferior to the brightness of the peripheral portion compared to the central portion, optical characteristics such as illuminance, contrast ratio, etc. of the projector are measured in a manner different from that of a general light source.

Specifically, the projector's illuminance unit is ANSI Lumen (ANSI Lumen), a unit specified by the American National Standards Institute (ANSI), which is a certain size of a white screen (typically 40) projected on the screen. Inch is divided into nine equal squares and the illuminance sensor is fixed at the center of each square to measure the average brightness by measuring the brightness of the projector irradiated to the corresponding point.

However, the method of measuring the optical characteristics of the conventional projector is fixed because the illumination sensor is fixed at the determined position, the screen size projected on the screen by the projector is changed, if the measurement position is changed, the illumination sensor must be reinstalled at the changed measurement position There is this.

Korean Patent Publication No. 10-1298146 (Invention: Optical Characteristic Measuring Apparatus of Projector) includes a mainframe which forms a projection area to which the projector's light is irradiated, and freely moves the projection area within the projector. A first illuminance sensor for measuring the brightness of the irradiated light, and the first illuminance sensor rotates horizontally and horizontally in the horizontal direction and the front and rear so that the light irradiated from the projector is incident on the front surface of the first illuminance sensor And a first sensor holder assembly, wherein the first sensor holder assembly includes a first fixing bracket, a first sensor holder for holding the first illuminance sensor, and between the first sensor holder and the first fixing bracket. A first vertical axis installed in the first sensor axis to serve as a rotation center axis for left and right rotation of the first sensor holder, and installed on an inner surface of the first sensor holder to provide the first roughness; An optical characteristic measuring apparatus having a first horizontal axis serving as a rotation center axis for front and rear rotation of a sensor is disclosed.

However, the optical characteristic measuring apparatus of the projector according to the prior art forms a first projection area, a second projection area, and a third projection area to which the light of the projector is irradiated, and three illuminance sensors are three projections to which the light of the projector is irradiated. It is configured to measure the brightness of the light by moving the area, respectively, there is a problem that can not measure the optical properties and uniformity of the entire screen.

In addition, the optical characteristic measuring apparatus of the projector according to the prior art, if the size of the screen is changed to change the measurement position, the light sensor is installed by moving the illuminance sensor to the measurement position is changed to measure the optical characteristics and then measure the optical characteristics There is a problem that the time increases.

Korean Registered Patent Publication No. 10-1298146 (Invention: Optical Characteristic Measuring Device of Projector)

In order to solve this problem, an object of the present invention is to provide an illumination performance measuring apparatus for measuring the optical characteristics of the projector, such as the illuminance, contrast ratio of the projector.

In order to achieve the above object, the present invention includes a vertical guide for supporting the projector to be fixed to a predetermined position by moving the projector to be measured in the up and down direction; A base unit for moving the plurality of sensors in the x-axis direction and the y-axis direction so that the plurality of sensors arranged in the sensor array unit are disposed in a projection area to which light of the projector to be measured is irradiated; And a sensor array unit in which a plurality of sensors are arranged in an m × n matrix form and detect illuminance information of light emitted from the measurement target projector.

In addition, the lighting performance measuring apparatus according to the present invention comprises an input unit for receiving the vertical height information of the measurement target projector from the user; In response to the vertical height information inputted to the input unit, an operation control signal is output to a vertical driver so that the projector to be measured moves in an up / down direction, and corresponding to a projection area of light that varies according to the height of the projector to be measured. A controller configured to output an operation control signal to a motor driving unit such that the sensor array of the sensor array unit is moved in x and y axis directions; A vertical driver installed in the vertical guide part to change a vertical position of the measurement target projector mounted on the vertical guide part according to an operation control signal of the controller; And a motor driving part formed on the base part and configured to move a sensor of the sensor array part arranged in the base part in the x-axis and y-axis directions according to an operation control signal of the controller. .

In addition, the vertical guide unit according to the invention vertical frame; A height adjusting part installed at the vertical frame and rotating the screw to adjust the height of the holder; And a holder installed on the vertical frame to mount a projector to be measured, and moving in an up / down direction according to a rotation direction of a screw connected to the height adjusting unit.

In addition, the base portion according to the present invention is a horizontal frame disposed perpendicular to the vertical guide portion; An x-axis guide installed in the horizontal frame to guide the sensor array to move in the x-axis direction; An x-axis moving unit installed on the x-axis guide to move the sensor array unit in the x-axis direction; A y-axis guide installed in the x-axis moving unit to guide the sensor array unit to move in the y-axis direction; And an y-axis moving unit installed on the y-axis guide to move the sensor array unit in the y-axis direction.

In addition, the base portion according to the present invention is made to be separated from the vertical guide portion, the separated base portion is characterized in that it further comprises a z-axis support for supporting the horizontal frame to be mounted opposite to the vertical guide portion .

In addition, the sensor array unit 130 according to the present invention is characterized in that the sensors arranged in the m × n matrix form is moved in groups of m rows and n columns.

In addition, the sensor according to the invention the sensor body; An illuminance detector installed at the sensor body to detect illuminance information; A through hole formed in the sensor body; And a sensor guide installed in the through hole and guiding the sensor to move in a group by connecting the sensor with neighboring sensors.

In addition, the lighting performance measuring apparatus according to the invention is characterized in that for measuring the optical characteristics of the projector irradiated to the bottom surface and the optical characteristics of the projector irradiated to the vertical plane.

The present invention has the advantage of accurately measuring the optical characteristics of the projector, such as the projector's illuminance, contrast ratio.

In addition, the present invention has the advantage that can accurately measure the optical characteristics and uniformity of the entire screen.

1 is a perspective view showing a lighting performance measuring apparatus according to the present invention.
Figure 2 is a perspective view showing the operating state of the lighting performance measuring apparatus according to the present invention.
Figure 3 is a block diagram showing the configuration of the lighting performance measuring apparatus according to the present invention.
Figure 4 is a block diagram showing the configuration of the sensor unit of the lighting performance measuring apparatus according to the present invention.
Figure 5 is a block diagram showing the configuration of the motor drive unit of the lighting performance measuring apparatus according to the present invention.
6 is a cross-sectional view for explaining an operating state of the lighting performance measuring apparatus according to the present invention.
7 is a cross-sectional view showing another operating state of the lighting performance measuring apparatus according to FIG.
8 is a cross-sectional view showing another embodiment of a lighting performance measuring apparatus according to the present invention.
9 is a cross-sectional view showing another operating state of the lighting performance measuring apparatus according to FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the lighting performance measuring apparatus according to the present invention.

In this specification, the expression "comprising" a certain component means that it may further include other components rather than exclude other components.

In addition, the terms "... part", "... group", "... module" and the like refer to a unit for processing at least one function or operation, which may be divided into hardware, software, or a combination of the two.

1 is a perspective view showing a lighting performance measuring apparatus according to the present invention, Figure 2 is a perspective view showing an operating state of the lighting performance measuring apparatus according to the present invention, Figure 3 shows the configuration of the lighting performance measuring apparatus according to the present invention Figure 4 is a block diagram showing the configuration of the sensor unit of the lighting performance measuring apparatus according to the present invention, Figure 5 is a block diagram showing the configuration of the motor driving unit of the lighting performance measuring apparatus according to the present invention, Figure 6 7 is a cross-sectional view illustrating an operating state of the lighting performance measuring apparatus according to the present invention, and FIG. 7 is a cross-sectional view showing another operating state of the lighting performance measuring apparatus according to FIG. 6.

1 to 7, the lighting performance measuring apparatus 100 according to the present invention includes a vertical guide part 1100, a base part 120, and a sensor array part 130.

The vertical guide part 110 is a structure for supporting the projector 200 to be fixed to a predetermined position by moving the measurement target projector 200 in the up / down direction. The vertical frame 111, the height adjusting part 112, and the holder 113 are provided. It is configured to include).

The vertical frame 111 allows the height adjusting part 112 and the holder 113 to be installed, and guides the path so that the holder 113 is moved in the up / down direction according to the operation of the height adjusting part 112. do.

The height adjusting part 112 is installed on the upper portion of the vertical frame 111 so as to be free to rotate, and comprises a screw (112a) that rotates in accordance with the rotation operation of the height adjusting part (112).

One side of the screw 112a is connected to the height adjusting part 112, and the other side of the screw 112a is a rod-shaped member installed on the bottom of the vertical frame 111. The cradle 113 formed in engagement with the screw 112a according to the rotational direction of the height adjusting part 112 moves upward / downward, so that the height of the cradle 113 can be adjusted.

The holder 113 is a plate-shaped member installed on one side of the vertical frame 111 installed in the vertical direction, the measurement target projector 200 is mounted on the holder 113.

In addition, the holder 113 is configured by engaging with the screw 112a connected to the height adjusting part 112, the upper direction of the vertical frame 111 according to the forward or reverse rotation direction of the height adjusting part 112. Alternatively, the measurement position of the projector 200 to be measured may be changed by moving downward.

The base unit 120 is installed on one side of the vertical guide unit 110, the plurality of sensors (130a, 130b, 130c) arranged in the m × n matrix form on the sensor array unit 130 is the measurement target projector 200 The plurality of sensors (130a, 130b, 130c) is moved in the x-axis direction and the y-axis direction so as to be disposed in the projection area irradiated with light, the horizontal frame 121, the x-axis guide 122, The x-axis moving part 123, the y-axis guide 124, the y-axis moving part 133, and the z-axis support stand 125 are comprised.

In addition, the base portion 120 is configured to be separated from the vertical guide portion 110, when the measurement target projector 200 irradiates light to the bottom surface, the base portion 120 is parallel to the bottom surface It is installed to be configured to measure the optical characteristics of the projector 200 is irradiated to the floor surface in the sensor array unit 130.

In addition, when the projector 120 to measure the light is irradiated to the front vertical surface, as shown in FIGS. 8 and 9, the base part 120 is connected to the vertical guide part 110. According to the size of the screen to be separated and projected apart a certain distance and mounted in the vertical direction, the optical characteristics of the projector 200 irradiated to the vertical plane is configured to measure in the sensor array unit 130.

The horizontal frame 121 is a configuration arranged on the bottom surface perpendicular to the vertical guide portion 110, the housing so that the sensor array unit 130 can move to the projection area to which the light of the projector 200 to be measured is irradiated. to provide.

The x-axis guide 122 is installed on the x-axis horizontal frame on the horizontal frame 121 to guide the sensor array unit 130 to move in the x-axis direction. It is installed opposite.

The x-axis moving unit 123 is installed on the x-axis guide 122 to move the sensor array unit 130 including the plurality of sensors 130a, 130b, and 130c in the x-axis direction. Is configured to allow a y-axis guide 124 to move along the x-axis guide 122.

The y-axis guide 124 is installed on the x-axis moving unit 123 to guide the sensor array unit 130 to move in the y-axis direction of the horizontal frame 121.

In addition, the y-axis moving unit 133 is installed on the y-axis guide 122 so that the sensors 130a, 130b, and 130c included in the sensor array unit 130 may move in the y-axis direction.

The z-axis support 125 is a configuration in which a predetermined length protrudes toward one side of the horizontal frame 121. When the horizontal frame 121 is disposed in the vertical direction, the horizontal frame 121 does not fall down and the vertical guide part does not fall. Support 110 to be mounted opposite to each other.

The sensor array unit 130 is configured to detect the illumination information of the light emitted from the projector 200 to be measured, and includes a plurality of sensors including a sensor 1 (130a), a sensor (2) 130b, and a sensor n (130c). (130a, 130b, 130c) are arranged in an m × n matrix form.

The sensor 1 (130a), the sensor 2 (130b) to the sensor n (130c) arranged in the m × n matrix form is divided into nine equal squares formed in a 3 × 3 matrix form, the sensor 1 (130a), the sensor 2 By measuring the illumination information (or brightness information) of the projector 200 irradiated by the sensor (130b) to the sensor n (130c) to provide to a management module (not shown) connected by a wired network or a wireless network, the projector ( It is possible to measure the illuminance, visual acuity, the average value of the illuminance, the sum value, and the amount of light for each sensor.

The m × n matrix is defined for convenience of description and illustration, and is not limited thereto. It will be apparent to those skilled in the art that the m × n matrix may be variously modified.

The sensor 1 130a includes a rectangular sensor body 131a and an illumination detector 132a installed in the sensor body 131a to detect illumination information.

In addition, the sensor array unit 130 is a sensor body so that the sensor 1 (130a), the sensor 2 (130b) to the sensor n (130c) arranged in an m × n matrix form can be moved in groups of m rows and n columns. A through hole 133a is formed in the 131a, and the through hole 133a is installed in the through hole 133a to connect the sensor 1 130a with the neighboring sensor 2 130b and the sensor n 130c to move the group. It is configured to include a sensor guide 134.

That is, when the size of the screen is changed and the position of the sensor is changed, the sensor guide 134 may move neighboring sensors in the 'm' row or the 'n' column where the sensor is installed to move in the x-axis or y-axis direction together. By configuring the position of the sensor 1 (130a), the sensor 2 (130b) to the sensor n (130c) due to the change in the size of the screen can be automatically changed in conjunction with the movement of the sensor.

In addition, the measuring device 100 according to the present invention can be operated manually by further comprising an input unit 140, a control unit 150, a vertical drive unit 160, and a motor drive unit 170. It can be configured to run automatically.

The input unit 140 is configured to receive vertical height information of the measurement target projector 200 from a user, and may be configured as an input means such as a switch, a button, a keypad, and the like.

The controller 150 outputs an operation control signal to the vertical driver 160 to move the projector 200 to be measured in the up / down direction according to the vertical height information input to the input unit 140, and the projector to be measured. The sensor 130a, 130b, and 130c of the sensor array 130 to move in the x-axis and y-axis direction corresponding to the projection area of the light variable according to the height of the 200 is operated as the motor drive unit 170 Output a control signal.

That is, the controller 150 previously stores the area where the sensor array unit 130 is disposed and the position of the sensor array unit 130 according to the size of the projection area that varies according to the height at which the projector 200 emits light. The sensor 200 controls the sensor array unit 130 to move to the stored position information corresponding to the height at which the projector 200 emits light.

In addition, the control unit 150 is connected to the illumination information of the projector 200 measured by the sensor array unit 130 through a network (eg, smart phone, tablet PC, desktop with an optical characteristic measurement program is installed) Display device such as a monitor or the like by transmitting the measured illuminance information to a PC, a server, etc. You can also output

The vertical driving unit 160 has a rotating shaft connected to the screw 112a installed in the vertical guide unit 110, and the measurement target projector 200 mounted on the vertical guide unit 110 according to an operation control signal of the controller 150. ), The vertical position is variable, and is composed of a motor such as a stepping motor and a DC motor.

The motor driving unit 170 is installed in the x-axis moving unit 123 and the y-axis moving unit 133 installed in the base unit 120 to the base unit 120 according to an operation control signal of the controller 150. The arranged sensor 1 (130a), the sensor 2 (130b) to the sensor n (130c) is composed of a motor 1 (171), a motor 2 (172) to a motor n (173) to move in the x-axis and y-axis direction. .

Therefore, by using a measuring device having a sensor array arranged in the form of m × n matrix, it is possible to easily measure the optical characteristics and uniformity of the projector, such as the illuminance, contrast ratio of the projector.

As described above, it has been described with reference to a preferred embodiment of the present invention, but those skilled in the art various modifications and changes of the present invention without departing from the spirit and scope of the invention described in the claims below I can understand that you can.

In addition, the reference numerals described in the claims of the present invention are not limited to the above described for clarity and convenience of the description, but are not limited thereto, the thickness of the lines shown in the drawings, the size of the components, etc. May be exaggerated for clarity and convenience of the description, and the above terms are terms defined in consideration of functions in the present invention, and may vary according to the intention or custom of the user or operator, and thus the interpretation of these terms Will be made based on the contents throughout the specification.

100: measuring device 110: vertical guide portion
111: vertical frame 112: height adjustment unit
112a: screw 113: holder
120: base portion 121: horizontal frame
122: x-axis guide 123: x-axis moving part
124: y-axis guide 125: z-axis support
130: sensor array unit 130a: sensor 1
130b: sensor 2 130c: sensor n
131a, 131b, 131c: sensor body
132a, 132b, and 132c: illuminance detector
133: y-axis moving part 133a: through hole
134: sensor guide 140: input unit
150 control unit 160 vertical drive unit
170: motor driving unit 171: motor 1
172: motor 2 173: motor n
200: projector

Claims (8)

A vertical guide part 110 moving the object to be measured 200 in an up / down direction to be fixed at a predetermined position;
The plurality of sensors 130a, 130b, 130c arranged in the sensor array unit 130 may be disposed in the projection area where the light of the projector 200 is irradiated. A base portion 120 moving in the axial direction and the y-axis direction; And
A plurality of sensors (130a, 130b, 130c) is arranged in an m × n matrix form, the illumination performance measuring device including a sensor array unit 130 for detecting the illumination information of the light irradiated from the measurement target projector 200 . The method of claim 1,
The lighting performance measuring apparatus includes an input unit 140 for receiving vertical height information of the measurement target projector 200 from a user;
In accordance with the vertical height information input to the input unit 140 outputs an operation control signal to the vertical drive unit 160 to move the measurement target projector 200 in the up / down direction, the measurement target of the projector 200 Outputs an operation control signal to the motor driver 170 so that the array of the sensors 130a, 130b, and 130c of the sensor array unit 130 moves in the x-axis and y-axis directions in response to a projection area of light that varies according to the height. A controller 150;
A vertical driver 160 installed in the vertical guide part 110 to vary a vertical position of the measurement target projector 200 mounted on the vertical guide part 110 according to an operation control signal of the controller 150; And
The x and y axes of the sensors 130a, 130b, and 130c of the sensor array unit 130 installed in the base unit 120 and arranged in the base unit 120 according to an operation control signal of the control unit 150. Lighting performance measuring apparatus further comprises a motor drive unit 170 consisting of a plurality of motors (171, 172, 173) moving in the direction. The method according to claim 1 or 2,
The vertical guide portion 110 is a vertical frame 111;
A height adjuster 112 installed at the vertical frame 111 to rotate the screw 112a to adjust the height of the holder 113; And
Is installed on the vertical frame 111 is mounted to the measurement target projector 200, and includes a cradle 113 for moving in the vertical direction in accordance with the rotation direction of the screw 112a connected to the height adjusting part 112. Lighting performance measuring device, characterized in that. The method according to claim 1 or 2,
The base portion 120 includes a horizontal frame 121 orthogonal to the vertical guide portion 110;
An x-axis guide (122) installed in the horizontal frame (121) to guide the sensor array unit (130) to move in the x-axis direction;
An x-axis moving unit 123 installed in the x-axis guide 122 to move the sensor array unit 130 in the x-axis direction;
A y-axis guide 124 installed on the x-axis moving unit 123 and guiding the sensor array unit 130 to move in the y-axis direction; And
Illumination performance measuring apparatus is installed on the y-axis guide (122) comprises a y-axis moving unit (133) for moving the sensor array unit (130) in the y-axis direction. The method of claim 4, wherein
The base portion 120 is detachably formed from the vertical guide portion 110, and the separated base portion 120 supports the horizontal frame 121 to be mounted to face each other with the vertical guide portion 110. Lighting performance measuring device further comprises a z-axis support (125). The method according to claim 1 or 2,
The sensor array unit 130 is an illumination performance measuring device, characterized in that the sensor (130a, 130b, 130c) arranged in an m × n matrix form is moved in groups of m rows and n columns. The method of claim 6,
The sensor 130a includes a sensor body 131a;
An illuminance detector 132a installed in the sensor body 131a to detect illuminance information;
A through hole 133a formed in the sensor body 131a; And
And a sensor guide (134) installed in the through hole (133a) and guiding the sensor (130a) with a neighboring sensor (130b, 130c) to guide the group movement. The method according to claim 1 or 2,
The lighting performance measuring apparatus is characterized in that for measuring the optical characteristics of the projector 200 is irradiated to the bottom surface and the optical characteristics of the projector 200 is irradiated to the vertical plane.

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