KR100902636B1 - Test apparatus for infrared rays camera module - Google Patents

Abstract

An apparatus for testing an infrared ray camera module are provided to easily test performance and reliability of the infrared ray camera module under a low illumination condition. The first display(150a) is installed at an outer sidewall of a casing(110). An opening and closing door(120) is installed at the outer sidewall of the casing. A camera module with a camera and an infrared LED is mounted in the opening and closing door. The opening and closing door inserts and ejects the camera module to/from a dark room. An image chart(140) is installed in the dark room of the casing. An infrared ray emitted from an infrared LED is applied to the image chart. A controller displays an image of the image chart photographed by the camera on the first display.

Description

Infrared camera module test device {TEST APPARATUS FOR INFRARED RAYS CAMERA MODULE}

The present invention relates to a camera module test apparatus, and to an infrared camera module test apparatus that can implement a low-light environment simply to check the performance and abnormality of the infrared camera module, and to facilitate the import and export of the camera module. will be.

In general, a camera module for a portable terminal includes a camera module having an image sensor built therein like a general camera module, but refers to a camera module that is miniaturized to be easily mounted on a portable terminal such as a mobile phone or a PDA. Such a camera module for a mobile terminal is useful for video calls by enabling video and photo taking so that a subject can be viewed on a screen through a micro lens.

In recent years, the camera module is almost essentially equipped with a lighting function to allow shooting in a dark environment, and for this purpose, includes a lighting lamp that emits light in conjunction with the camera.

More recently, an infrared camera module has been developed to enable low-light photography using infrared light without having to lightly illuminate an illumination lamp to make a video call even in a dark environment. The infrared camera module is equipped with an infrared LED (IrED) that irradiates infrared rays as an illumination device, and removes an IR cut-off filter from the camera to enable imaging by infrared to enhance the shooting function at low light. will be.

1 is a reference view schematically showing an infrared camera module.

As shown, the infrared camera module 10 is largely comprised of a camera 11, an infrared LED 13 and an FPC 15 connecting them. The camera 11 is typically made of a barrel, a lens installed on the barrel, a PCB mounted with an image sensor, and the like, and a module connector 17 connected to the main board of the portable terminal is provided at the end of the FPC. .

The infrared camera module 10 having such a configuration receives a signal applied from the main board of the mobile terminal when a video call or a camera is photographed in a dark environment, and the infrared ray LED 13 emits light to irradiate the subject with infrared rays. In low light, infrared images could be taken. Unlike visible light, infrared rays are irrelevant to people's attention and do not attract the attention of those around them. Therefore, the camera can be taken at night or in a dark room without disturbing the eyes of others or distracting them. There was a big advantage.

However, in the case of the infrared camera module 10 for such a portable terminal, there was a problem in that a suitable device for simply checking whether it was normal or bad before shipment was developed due to the recent development in earnest. Therefore, it is urgent to develop a test apparatus that can measure the overall performance of the camera and the infrared LED, including whether the infrared camera module 10 is normal or defective.

Accordingly, the present invention has been proposed to solve the above-mentioned conventional problems, and an object of the present invention is to provide an infrared camera module test apparatus for easily inspecting the performance and reliability of the infrared camera module in a low light environment. There is.

In order to achieve the above object, an infrared camera module test apparatus according to the present invention includes a casing having a dark room therein; A first display disposed on an outer wall of the casing; An inlet / outlet unit mounted on an outer wall of the casing, and equipped with a camera module having a camera and an infrared LED to carry in and out of the dark room; An image chart installed in the dark room and irradiating infrared light emitted from the infrared LED; And a controller connected to the camera module to transmit and display an image of an image chart photographed by the camera to the first display, based on the image of the image chart sent by the controller. Or it is characterized by the technical configuration that made it possible to determine whether or not defective.

delete

In addition, a plurality of photodetectors may be installed in the image chart to measure infrared radiation intensity at each position, and to transmit the measured values to the controller, respectively.

In addition, the controller may be characterized in that the power supply to the infrared LED receives a measurement of the forward voltage and resistance of the infrared LED.

In addition, a second display may be installed on an outer wall of the casing to indicate whether the controller is normal or defective based on the measured value transmitted by the controller and the measured value transmitted by the controller.

In addition, a part of the side wall of the casing is opened to form a carry-in opening, and the opening and closing means is installed to open and close in correspondence with the carry-in opening, and when the opening is open, the camera module can be mounted on an inner side thereof. It may be characterized in that the camera module mounted on the inner surface is an opening and closing door to be carried into the dark room.

In addition, it may be characterized in that it is further provided with a door pedestal that is installed on the lower side of the opening door to support the bottom of the opening door in a horizontally open state.

In addition, the upper surface of the casing can be opened and closed, the gas lifter for supporting the upper surface of the casing in an open state may be installed between the upper surface and the side wall of the casing.

In addition, the dark chamber of the casing may be characterized in that the guide bar for guiding the forward and backward movement of the image chart through the image chart in the front-rear direction.

The guide bar may have a spiral formed on an outer circumferential surface thereof to move the image chart forward and backward when rotated.

Infrared camera module test apparatus according to the present invention having the above configuration, by implementing a low light environment with a simple configuration can easily inspect the performance and abnormality of the infrared camera module.

The present invention can be easily carried in and out of the camera module to the dark room without the cumbersome work by the opening and closing door installed in the front of the casing.

The present invention, through the camera image displayed on the first display can determine the direction of the infrared LED and the skewed, whether the camera is abnormal.

The present invention can measure the radiant intensity of the infrared rays by a plurality of photodetectors installed in the image chart, and can also check the direction angle of the infrared LEDs and whether they are distorted.

According to the present invention, it is possible to measure the characteristic values of the camera and the infrared LED according to the distance while manually or automatically moving the image chart.

According to the present invention, the measured value of the forward voltage and resistance generated in the infrared LED and the radiation intensity of the infrared light transmitted from the photo detector are collectively displayed on the second display, so that it is easy to determine whether the camera module is normal or defective.

The present invention is easy to mount the camera module because the door support supports the opening and closing door in a horizontally open state.

In the present invention, since the upper surface of the casing is opened and closed, replacement and cleaning of parts installed in the casing are easy.

The present invention is provided with a gas lifter to support the upper surface of the open casing, there is no hassle to hold the operator so as not to close the upper surface of the open casing.

Hereinafter, embodiments of the present invention as described above will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view for explaining an infrared camera module test apparatus according to the present invention, Figure 3 is a block diagram schematically showing the configuration of the present invention, Figure 4 is a partial perspective view for explaining the access means according to the present invention. 5 is a partial side view of the access means according to the present invention.

As shown, the present invention is a casing 110 having a dark room (110a), the opening and closing door 120, the image chart 140, which is an entry and exit means for carrying in and out of the camera module 10 to the dark room (110a) The first display 150a, the second display 150b, and the controller 161 are configured to be included.

The casing 110 has a dark room 110a therein. As a result, the infrared camera module 10 implements roughness of 0 (lux), which is a poor environment to be actually used, so that the performance and abnormality of the camera module 10 having the infrared camera 11 can be easily inspected. An opening 113 is formed at the front of the casing 110 so as to carry the camera module 10 into and out of the dark room 110a. In addition, the upper surface 111 of the casing 110 is provided in the form of a door opening and closing. To this end, the upper surface 111 of the casing 110 is hinged by the rear wall and the hinge (111a). When the upper surface 111 of the casing 110 is configured to open and close like this, it is easy to manually adjust the position of the image chart 140 installed therein, and to easily repair, replace, and clean the parts installed in the casing 110. Do. Further, a gas lifter 112 is installed between the upper case 111 of the casing 110 and the side wall (any one of the rear wall, the left wall, and the right wall). This is supported by the gas lifter 112 so that the upper surface 111 of the casing 110 is not closed by itself unless an external force is applied in the open state. In addition, it is preferable that the cooling fan 115 is installed on the left side wall or the right side wall of the casing 110 so as to discharge heat generated in the dark room 110a. In addition, it is preferable to further support the casing 110 to a predetermined height by further provided with a casing pedestal 117. This is to make it easy for the operator to operate the infrared module test apparatus of the present invention without bending the waist almost.

The opening and closing door 120 serves to simply carry in and take out the camera module 10 into the dark room 110a in the casing 110 as described above. To this end, the opening and closing door 120 is hinged by a lower jaw and a hinge 121 (see FIG. 6) in which an opening 113 is formed among the front surfaces of the casing 110, and the opening 113. It is formed in a corresponding shape and size. The camera module 10 is mounted on an inner side surface of the opening / closing door 120 (ie, an inner side surface means a surface located in the dark room 110a when the opening door 120 is closed). A test jig (130 Test Jig) is installed to be connected to the circuit. The test jig 130 includes a capture board 131, a header board 133 header board, and a fixing board 135 fixing stably fixing the camera module 10 to the header board 133. In this case, the capture board 131 serves to perform an interface with the controller 161. In the drawings of the present embodiment, the capture board 131 performs the interface by using the USB cable 137. However, the capture board 131 performs the interface by the USB (Pipheral Component Interconnect) as well as the Universal Serial Bus (USB). Of course, various alternative interfaces are possible. The header board 133 supplies power to the mounted camera module 10, outputs synchronization and control signals, and receives image data and transmits the image data to the capture board 131. In addition, the header board 133 outputs a synchronization and control signal for the operation of the infrared LED 13 through the LED operation cable 139. Reference numerals 15 and 17 which are not referred to by reference are respectively a flexible printed circuit (FPC) for connecting the camera 11 and the infrared LED 13, and a connector for a module electrically connected to the test jig.

The relationship between the entire components including the connection of the camera module 10, the test jig 130, and the LED tester 160 as shown above is shown in FIG. The LED tester 160 is formed by tying together a controller 161 and a database 163 storing various data and programs necessary for inspecting the camera module 10.

When the opening and closing door 120 is provided in the case of the opening door in the front of the casing 110, the operator can bring the camera module 10 directly into the dark room (110a) by opening and closing the opening and closing door 120. .

In addition, a door pedestal 125 supporting the open / close door 120 in a horizontally open state is provided at a lower side of the open / close door 120. The door pedestal 125 allows the camera module 10 to be easily mounted by stably supporting the door 120 in a horizontally open state.

The image chart 140 is installed at a position facing the camera module 10 carried in the dark room 110a of the casing 110. As a result, the infrared ray irradiation on the image chart 140 and the camera 11 can be photographed. In addition, the image chart 140 is provided with a plurality of photo detectors (140a) for measuring the radiation intensity (Po) of the infrared radiation irradiated around the central portion. In the drawing, nine photo detectors 140a Photo Detecters are provided and arranged in the form of three rows and three columns, but may be arranged in more various forms. For example, in order to measure the infrared radiation intensity (Po) more precisely, the number of photo detectors 140a may be increased to 16 and arranged in four rows and four columns.On the contrary, after the photo detectors 140a are reduced to five, one is installed in the center. The rest may be placed radially around it. As such, when a plurality of photo detectors 140a are installed, it can be seen that the infrared angle of the LED 13 is distorted. That is, since the infrared LED 13 is in the form of a lens, the infrared light of the strongest intensity is emitted toward the center and the infrared light of weak intensity is emitted toward the outside, so that if the state of the infrared LED 13 is normal, the photodetector located in the center ( 140a) receives the strongest infrared ray, and the photodetector 140a located in the vicinity receives weak intensity infrared rays according to the distance from the center, so that it is easy to determine the directivity and distortion of the infrared LED 13. It can be.

The periphery of the image chart 140 is supported by the guide bar 141 installed in the front and rear direction in the dark room 110a to be guided by the guide bar 141 when moved in the front and rear directions. Here, the guide bar 141 is provided in the form of a screw (Screw) formed on the outer circumferential surface it is possible to move the image chart 140 in the front and rear direction during rotation. As a result, the radiation intensity of the irradiated infrared ray may be measured while changing the distance between the infrared LED 13 and the image chart 140. Here, the rotational force of the guide bar 141 is provided from a motor not shown. If the spiral is not formed on the outer circumferential surface of the guide bar 141, the upper surface 111 of the casing 110 may be opened and the image chart 140 may be manually moved.

The first display 150a is installed at the front of the casing 110 to display an image of the image chart 140 captured by the camera 11. As a result, whether the camera 11 and the infrared LED 13 are normal or defective may be checked through the image of the image chart 140 displayed on the first display 150a. If both the camera 11 and the infrared LED 13 are in a normal state, the irradiation area 13a by infrared rays on the first display 150a will be correctly displayed centering on the center of the image chart 140. For example, some types of images displayed on the first display 150a may be seen in FIG. 6. If both the camera 11 and the infrared LED 13 are normal, it will be displayed as shown in FIG. However, if it is displayed as (b) or (c), the direction angle of the infrared LED 13 is wrong or wrong.

The second display 150b is installed in the casing 110 in parallel with the first display 150a and is determined by the controller 161 based on various measured values and the measured values received by the controller 161 or Indicates whether or not it is defective. The measured value includes a forward voltage (VF) and a resistance (IR) generated when power is applied to the infrared LED 13, as well as the infrared radiation intensity measured by the photodetector 140a installed in the image chart 140 ( Po) and the like. However, in order to determine whether the controller 161 is normal or defective based on the measured value, a program for determining whether the controller 161 is normal or defective based on the accumulated data and the data through repeated experiments. This is necessary but detailed description thereof will be omitted.

The method for inspecting the infrared camera module 10 using the infrared camera module test apparatus according to the present invention configured as described above will be described in detail with reference to FIGS. 7 and 8 and other attached drawings. 7 and 8 are reference perspective views for explaining the operation of the present invention.

First, the operation of bringing the camera module 10 into the dark room 110a formed in the casing 110 is performed. To this end, as shown in FIG. 7, the opening and closing door 120 is opened by pulling the opening and closing door 120 having a handle 123 in the closed initial state. Then, the opening and closing door 120 is opened, and the opening and closing door 120 opened as shown in FIG. 8 is in a horizontally laid state so as to be conveniently mounted by the camera module 10 while being supported by the pedestal.

Thereafter, the camera module 10 is positioned on the header board 133 of the test jig 130 installed on the inner side of the open / close door 120 and then fixed using the fixing board 135. As a result, the camera module 10 mounted on the test jig 130 is connected to the controller 161 through the USB cable 137 and the LED manipulation cable 139.

When the operation of mounting the camera module 10 on the inner side of the opening and closing door 120 is completed as above, the opening and closing door 120 is pushed up and closed. Then, the camera 11 and the infrared LED 13 included in the camera module 10 are brought into the dark room 110a to face the image chart 140 located in the dark room 110a.

Thereafter, the controller 161 applies power to the camera module 10 carried in the dark room 110a to operate the camera 11 and the infrared LED 13. Then, the infrared LED 13 emits infrared rays in the dark room 110a, and infrared rays are irradiated onto the image chart 140, and the camera 11 photographs the image chart 140 irradiated with infrared rays. In this case, the camera 11 transmits a signal by capturing only a portion irradiated with infrared rays by the image sensor.

Thereafter, the controller 161 displays the image photographed by the camera 11 through the first display 150a. In the first display 150a, a portion irradiated with infrared rays of the image chart 140 is clearly displayed. In addition, the controller 161 measures the infrared rays measured from the respective photodetectors 140a installed in the image chart 140 together with the forward voltage (VF) and resistance (IR) measurement values generated from the infrared LED 13 when the power is applied. While receiving the measured value of the radiation (Po) of the display on the second display (150b), it is displayed on the basis of these measurements and whether the normal or bad of the camera module 10 determined. At this time, while moving the image chart 140 by rotating the guide bar 141, the characteristic value when the distance between the infrared LED 13 and the image chart 140 is also examined.

Thereafter, the operator starts the classification operation by classifying the camera module 10 according to whether the camera module 10 is finally determined in consideration of the contents displayed on the first display 150a and the second display 150b. To do this, simply open and close the door 120 to release the inspected camera module 10 and process it in the designated place depending on whether it is normal or defective. As a result, the inspection for confirming whether the camera module 10 is normal or defective is completed.

And while mounting a new camera module in the open and closed door 120, the inspection operation for the camera module 10 in accordance with the above-mentioned method may be repeated.

 Although the preferred embodiment of the present invention has been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

1 is a reference view schematically showing an infrared camera module.

Figure 2 is a perspective view for explaining an infrared camera module test apparatus according to the present invention.

Figure 3 is a block diagram schematically showing the configuration of the present invention.

Figure 4 is a partial perspective view for explaining the access means according to the present invention.

5 is a partial side view of the access means according to the present invention.

FIG. 6 is a reference diagram illustrating some of types of images displayed on a first display. FIG.

7 and 8 are reference perspective views for explaining the operation of the present invention.

* Description of the symbols for the main parts of the drawings *

110: casing 110a: darkroom

113: entrance 120: opening and closing door

121: door pedestal 130: test jig

140: image chart 140a: photo detector

141: guide bar 150a: first display

150b: second display 161: controller

Claims (10)

A casing having a dark room therein; A first display disposed on an outer wall of the casing; An inlet / outlet unit mounted on an outer wall of the casing, and equipped with a camera module having a camera and an infrared LED to carry in and out of the dark room; An image chart installed in the dark room and irradiating infrared light emitted from the infrared LED; And a controller connected to the camera module to transmit and display an image of an image chart captured by the camera on the first display. A plurality of photo detectors are installed in the image chart to measure the radiation intensity of the infrared light irradiated at each position, and transmit the measured value to the controller, respectively. delete delete A casing having a dark room therein; A first display disposed on an outer wall of the casing; An inlet / outlet unit mounted on an outer wall of the casing, and equipped with a camera module having a camera and an infrared LED to carry in and out of the dark room; An image chart installed in the dark room and irradiating infrared light emitted from the infrared LED; And a controller connected to the camera module to transmit and display an image of an image chart captured by the camera on the first display. The controller supplies power to the infrared LED to receive a measurement of the forward voltage and resistance of the infrared LED module. The method according to claim 1 or 4, And a second display on the outer wall of the casing, the second display indicating whether the controller is normal or defective based on the measured value received from the controller and the measured value received from the controller. The method according to claim 1 or 4, A portion of the sidewall of the casing is opened to form an inlet, The opening and closing means is installed so as to open and close in response to the opening and closing, it is possible to mount the camera module on the inner side when opened, the opening and closing door so that the camera module mounted on the inner side is brought into the dark room when closed. Infrared camera module test device, characterized in that. The method of claim 6, Infrared camera module test apparatus, characterized in that it further comprises a door support installed on the lower side of the opening and closing the door in a state in which the opening and closing door is opened horizontally. The method of claim 6, The upper surface of the casing is opened and closed, Infrared camera module test apparatus, characterized in that the gas lifter for supporting the upper surface of the casing in an open state between the upper surface and the side wall of the casing. The method according to claim 1 or 4, Infrared camera module test apparatus, characterized in that the guide bar for guiding the forward and backward movement of the image chart through the image chart in the dark room of the casing is installed. The method of claim 9, The guide bar has a spiral formed on the outer peripheral surface of the infrared camera module test apparatus, characterized in that for moving the image chart forward and backward when rotated.

Images