KR20130119778A - Apparatus for recognizing face - Google Patents

Abstract

The present invention relates to a face recognizing device which recognizes a person using the unique facial information of each person. The face recognizing device includes a housing, a display unit, a visible ray camera, an infrared camera, and an infrared lamp. The display unit is integrated inside the housing while the screen is exposed to the front side of the housing. The visible ray camera is integrated inside the housing while the visible ray lens is exposed to the front side of the housing. The infrared camera is integrated, next to the visible ray camera, inside the housing while the infrared lens is exposed to the front side of the housing. The infrared lamp is integrated inside the housing and includes infrared light emitters which are arranged along at least part of the circumference of the visible ray lens and the infrared lens while being exposed to the front side of the housing.

Description

Apparatus for recognizing face

The present invention relates to a biometric device, and more particularly to a face recognition device.

In biometrics, access control, time and attendance management, building integrated systems, financial automation equipment, computer security, electronic commerce authentication, airport information systems, and other biometric technologies have been proposed. Among them, face recognition technology is a technology for recognizing a person using face information having unique characteristics for each person. The face recognition technology is divided into a face detection technology for finding a face in a captured image and an authentication technology for checking whether a detected face is a registered user's face.

On the other hand, the face recognition device may be configured to photograph the subject under illumination, it is necessary to illuminate the subject uniform illumination in order to increase the face recognition rate. In particular, in the case of a photographed person wearing glasses, a phenomenon in which the photographed image is distorted may occur because the illumination light is reflected by the glasses. Therefore, there may be a problem that the face recognition rate is lowered, a solution for this is required.

An object of the present invention is to provide a face recognition device that can increase the face recognition rate.

According to an aspect of the present invention, there is provided a face recognition device comprising: a face recognition device for recognizing a person using face information having unique characteristics for each person, the housing; A display unit which is exposed to the front surface of the housing and is built in the housing; A visible light camera embedded in the housing by exposing a visible light lens unit to the front surface of the housing; An infrared camera exposed to the front of the housing and embedded in the housing, the infrared camera being disposed beside the visible light camera; And an infrared illuminator in which infrared light irradiation units are arranged at least partially along each circumference of the visible light lens unit and the infrared lens unit and are exposed to the front surface of the housing and embedded in the housing.

According to the present invention, an ambient light effect is generated around the visible light lens unit and the infrared lens unit, so that light of uniform brightness can be illuminated on the face of the subject. In addition, it is easy to detect the light source pattern reflected from the subject wearing glasses, and the distorted information may be corrected. Therefore, there may be an effect of increasing the face recognition rate.

1 is a perspective view of a face recognition device according to an embodiment of the present invention.
2 is a front view of FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. The configuration of the face recognition device described below schematically shows only the components necessary to describe the embodiment of the present invention. Therefore, components for performing other functions essential for the operation of the face recognition device may be additionally included in the face recognition device. Additional components may vary depending on the type or function of the face recognition device.

1 is a perspective view of a face recognition device according to an embodiment of the present invention. 2 is a front view of FIG. 1.

1 and 2, the face recognition device 100 is a device for recognizing a person using face information having unique characteristics for each person, access control, time and attendance management, building integration system, financial automation equipment, computer security Applicable to the field, e-commerce certification, airport information system, etc.

The face recognition device 100 includes a housing 110, a display unit 120, a visible light camera 130, an infrared camera 140, and an infrared illuminator 150.

The housing 110 forms the appearance of the face recognition device 100 and serves to protect the built-in components. The housing 110 has a space therein. The display unit 120, the visible light camera 130, the infrared camera 140, and the infrared illuminator 150 are mounted in the inner space of the housing 110.

The housing 110 may have a bottom surface that is wider than the top surface. In this case, when the rear surface of the housing 110 is fixed to a wall or the like, the screen 121 of the display unit 120 provided on the front surface of the housing 110 may be inclined upward. When the photographer goes through the authentication process while checking his / her face through the screen 121 of the display unit 120, even if the physical characteristics such as the height of the subject are different, the screen 121 of the display unit 120 is more conveniently used. You can hit the face.

Various operation buttons 101 such as a function operation button or a call operation button may be installed on the front surface of the housing 110. The operation button 101 receives an operation signal of the subject and transfers it to a controller (not shown) of the face recognition device 100 so as to process an event corresponding to the operation signal. Here, the controller performs overall management and control functions necessary for the operation of the face recognition device 100.

The display unit 120 is exposed to the front surface of the housing 110 and is embedded in the housing 110. An opening having a size corresponding to the screen 111 of the display unit 120 is formed on the front surface of the housing 110, and the display unit 120 is housed with the screen 111 of the display unit 120 exposed through the opening. It may be mounted inside the 110. The display unit 120 may include various display devices such as a liquid crystal display. The display unit 120 may be disposed in an upper region of the housing 110.

The display unit 120 may be controlled by the controller to output an image obtained from the visible light camera 130 through the screen 121. Therefore, the photographed person may adjust the position or facial expression of the face while checking his or her face through the screen 121.

The visible light camera 130 is embedded in the housing 110 by exposing the visible light lens unit 131 to the front of the housing 110. An opening having a size corresponding to that of the visible light lens unit 131 is formed in a front surface of the housing 110, and the visible light camera 130 is connected to the housing 110 with the visible light lens unit 131 exposed through the opening. ) Can be mounted inside.

The visible light camera 130 captures an image of the visible light band with respect to the face of the subject. An image of the visible light band photographed by the visible light camera 130 is input to the controller, and the controller analyzes an image of the visible light band to detect a face region and determine whether the detected face is a registered user's face. Can be.

The visible light camera 130 may include an infrared cut filter (not shown). The infrared cut filter 130 is one so that the infrared component is not input to the sensor of the visible light camera 130. Here, the infrared cut filter 130 may have a structure in which a portion passes the infrared component.

For example, an edge or center portion of the infrared cut filter may be formed to pass infrared components. Accordingly, the visible light band image can be output to the screen 121 of the display unit 120 even in a completely dark place, so that the subject checks his / her face through the screen 121 and the face position or expression, etc. To adjust it.

The infrared camera 140 is embedded in the housing 110 by exposing the infrared lens unit 141 to the front of the housing 110. An opening having a size corresponding to the infrared lens unit 141 is formed on the front surface of the housing 110, and the infrared camera 140 is disposed inside the housing 110 while the infrared lens unit 141 is exposed through the opening. It can be mounted on. The infrared camera 140 is disposed on the side of the visible light camera 130.

For example, the infrared camera 140 may be disposed on the right side of the visible light camera 130. Here, the center of the infrared lens unit 141 may be positioned on the same horizontal line as the center of the visible light lens unit 131. In addition, the infrared camera 140 and the visible light camera 130 may be disposed under the display unit 120.

The infrared camera 140 captures an image of an infrared band with respect to the face of the subject under the illumination of the infrared illuminator 150. The image of the infrared band photographed by the infrared camera 140 is input to the controller, and the controller may analyze the image of the infrared band together with the image of the visible light band and use it to detect the face region.

For example, when the controller cannot detect the face region from the image of the visible light band, the controller estimates the face area from the image of the visible light band using the infrared band image, and analyzes the detected or estimated face feature to determine suitability. Can be determined. Therefore, even in an environment where night and day are continuously changed, or even when the external lighting is largely affected, such as indoors, face recognition for a photographic subject may be stable.

The infrared illuminator 150 enables the infrared camera 140 to acquire an image of the subject under infrared illumination. The infrared illuminator 150 may be controlled to operate by the controller when the infrared camera 140 is photographed.

The infrared illuminator 150 includes at least a portion of the infrared light irradiation units 151 and 152 arranged along each circumference of the visible light lens unit 131 and the infrared lens unit 141 and is exposed to the front surface of the housing 110. Built in). In front of the housing 110, portions corresponding to the infrared light emitting units 151 and 152 are made of transparent windows capable of transmitting light, and the infrared illuminator (151, 152) is exposed through the transparent windows. 150 may be mounted inside the housing 110. Accordingly, the infrared light irradiation units 151 and 152 may irradiate infrared light in a direction coinciding with the optical axis direction of the infrared camera 140, respectively.

For example, the infrared illuminator 150 may include first and second infrared light emitters 151 and 152. The first infrared light irradiation units 151 may be arranged at least partially along the circumference of the visible light lens unit 131, and may be spaced apart from the center of the visible light lens unit 131 by the same distance. The second infrared light irradiation units 152 may be arranged at least partially along the circumference of the infrared lens unit 141, and may be spaced apart from each other by the same distance from the center of the infrared lens unit 141.

That is, the first and second infrared light irradiation units 151 and 152 may be arranged in a partial circular shape around each of the visible light lens unit 131 and the infrared lens unit 141. Therefore, an ambient lighting effect is generated around the visible light lens unit 131 and the infrared lens unit 141, so that light of uniform brightness may be illuminated on the face of the subject. In addition, it is easy to detect the light source pattern reflected from the subject wearing glasses, and the distorted information may be corrected. That is, when the first and second infrared light irradiation units 151 and 152 are arranged in a partial circular shape around each of the visible light lens unit 131 and the infrared lens unit 141, the visible light lens unit 131 and the infrared light are arranged. Compared to the lens unit 141, the lens unit 141 may secure a minimum uniform illumination required for face recognition, and may easily detect distortion reflected by the glasses. As a result, there may be an effect of increasing the face recognition rate.

In addition, the first and second infrared light irradiation units 151 and 152 may not be disposed in the common region 111 between the visible light lens unit 131 and the infrared lens unit 132. Here, the common area 111 is defined as a region defined between the virtual tangents L1 and L2 passing through the positions positioned closest to each other at each edge of the visible light lens unit 131 and the infrared lens unit 141.

The first infrared light emitters 151 may be arranged at predetermined intervals along a portion of the visible light lens unit 131 circumferential region beyond the common region 111. The second infrared light emitters 152 may be arranged at regular intervals along the circumferential region outside the common region 111 of the circumferential region of the infrared lens unit 141. Accordingly, since the infrared light irradiated from the first and second infrared light irradiation units 151 and 152 does not overlap each other in the common region 111, more uniform illumination may be generated.

The infrared illuminator 150 may be controlled to adjust the wavelength of the infrared light. For example, the infrared illuminator 150 may be selectively controlled, such as near infrared illumination of about 700 to 1400 nm wavelength or long wavelength infrared illumination of about 1400 nm wavelength.

On the other hand, the front of the housing 110 may be provided with a proximity sensor 160 for detecting the approach of the photographed person toward the front of the housing 110. The controller may determine whether the subject approaches the front of the housing 110 by detecting the movement of the subject based on the signal output from the proximity sensor 160. If it is determined that the subject approaches the front of the housing 110, the controller may control the face recognition apparatus 100 to auto-on.

The proximity sensor 160 may be disposed between the visible light camera 130 and the infrared camera 140, that is, between the visible light lens unit 131 and the infrared lens unit 141. This is because, in order to perform face authentication, the subject needs to measure the authentication position as the distance to the face, and the closer the distance is between the lenses 131 and 141 and the face, the better. In addition, the proximity sensor 160 may be located in the same direction as the visible light camera 130 and the infrared camera 140 and located close to the visible light camera 130 and the infrared camera 140. Therefore, when the subject enters the photographing region of the visible light camera 130 and the infrared camera 140, the proximity sensor 160 may detect whether the subject approaches the subject more accurately.

For example, the proximity sensor 160 may be configured as an optical proximity sensor. The proximity sensor 160 includes a light emitting unit 161 and a light receiving unit 162. The light emitted from the light emitting unit 161 is reflected by the subject to measure the change in the amount of light entering the light receiving unit 162, thereby detecting the position of the subject. In this case, portions of the light emitting portion 161 and the light receiving portion 162 are formed on the front surface of the housing 110 to be transparent to light, and the light emitting portion 161 and the light receiving portion 162 are exposed through the transparent windows. In this state, the proximity sensor 160 may be mounted inside the housing 110.

The proximity sensor 160 may be configured of various types of proximity sensors such as magnetic, ultrasonic, inductive, and capacitive, in addition to the optical. In addition, the visible light camera 130 may be used to detect whether or not the subject is approaching. The controller may determine whether the subject approaches the front of the housing 110 by detecting the movement of the subject through the image captured by the visible light camera 130.

When the illumination is dark, the visible light illumination unit 170 may be further provided so that the visible light camera 130 can capture an image of the visible light band under visible light illumination. Visible light illumination unit 170 is a visible light irradiation unit 171 is disposed between the visible light camera 130 and the infrared camera 140 and exposed to the front of the housing 110 is embedded in the housing 110.

The front surface of the housing 110 is made of a transparent window capable of transmitting light to a portion corresponding to the visible light irradiation unit 171, the visible light illumination unit 170 is a housing in a state in which the visible light irradiation unit 171 is exposed through the transparent window It may be mounted inside the 110.

The visible light radiator 171 may be positioned on a virtual line connecting the centers of the visible light lens unit 131 and the infrared lens unit 141. Accordingly, when the photographer stares at the visible light camera 130 and the infrared camera 140 for face recognition, the visible light may be illuminated so that no shadow is generated or distorted on the face of the subject.

The visible light illuminator 170 may include a white light emitting device (LED). As another example, the visible light illuminator 170 may include a green light emitting device and a light emitting device in all other visible light wavelength bands.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

110. Housing 120. Display
130. Visible light camera 131 Visible light lens part
140. Infrared camera 141 Infrared lens
150. Infrared illuminator 151, 152 Infrared light irradiation unit
160. Proximity sensor 170. Visible light unit

Claims (6)

In the face recognition device that recognizes a person using face information that has unique characteristics for each person,
housing;
A display unit which is exposed to the front surface of the housing and is built in the housing;
A visible light camera embedded in the housing by exposing a visible light lens unit to the front surface of the housing;
An infrared camera exposed to the front of the housing and embedded in the housing, the infrared camera being disposed beside the visible light camera; And
An infrared illuminator in which infrared light irradiation units are arranged at least partially along each circumference of the visible light lens unit and the infrared lens unit and exposed to the front surface of the housing and embedded in the housing;
Face recognition device comprising a. The method of claim 1,
The infrared light irradiation unit,
First infrared light irradiation units arranged at least partially along the circumference of the visible light lens unit and spaced apart from the center of the visible light lens unit at the same distance, and
And second infrared light irradiation units arranged at least partially along the circumference of the infrared lens unit and spaced apart from the center of the infrared lens unit by the same distance, respectively. 3. The method of claim 2,
A common area is provided between the virtual tangents passing through the points located closest to each other at each edge of the visible light lens unit and the infrared lens unit;
The first infrared light irradiation units are arranged at regular intervals along a portion of the peripheral region of the visible light lens unit outside the common region,
And the second infrared light irradiation units are arranged at predetermined intervals along a circumferential region outside the common region of the circumferential region of the infrared lens unit. The method of claim 1,
And a proximity sensor disposed between the visible light camera and the infrared camera, the proximity sensor detecting whether a photographed person approaches the front of the housing. The method of claim 1,
Visible light irradiation unit further comprises a visible light illumination unit disposed between the visible light camera and the infrared camera and exposed to the front surface of the housing embedded in the housing. The method of claim 1,
The visible light camera includes an infrared cut filter;
The infrared cut filter is a face recognition device, characterized in that made of a portion to pass the infrared component.

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