KR20170007500A - Camera module comprising filter exchanger and mobile device having the same - Google Patents

Abstract

Disclosed is a filter switch unit. The filter switch unit comprises: an upper cover which includes a light through hole; a first filter blade part which is installed to be rotatable over a predetermined angle relative to a first reference axis of a base, and which includes a first filter adapted to cover the light through hole; a second filter blade part which is installed at a height identical to that of the first filter blade part so as to rotate in conjunction with the first filter blade part relative to a second reference axis of the base, and which includes a second filter adapted to cover the light through hole; a rotation part which is connected to each of the first and second filter blade parts, and which rotates in a clockwise or counterclockwise direction relative to the light through hole so as to rotate the first and second filter blade parts together; a drive part which rotates the rotation part by using magnetic force; and the base which provides guidance to the rotation of the rotation part, and which accommodates the drive part. In this case, any one of the first and second filters may cover the light through hole when the rotation part rotates in the clockwise direction, and the other one of the first and second filters may cover the light through hole when the rotation part rotates in the counterclockwise direction.

Description

TECHNICAL FIELD [0001] The present invention relates to a camera module including a filter switching device and a mobile device having the camera module.

The present invention relates to a camera module including a filter switching device and a mobile device having the camera module. More particularly, the present invention relates to a camera module including a filter switching device for simultaneously driving two filter blades by rotation of a rotating part, And a mobile device having the camera module.

Mobile devices such as smart phones and tablet PCs, which are widely used recently, include camera modules.

Such a camera module is used for shooting a moving picture, capturing a still image such as an object or a person, or biometrics.

When performing video recording or still image shooting, the image sensor of the camera reacts sensitively to an infrared ray, which is an invisible ray. Therefore, in the daytime, an infrared ray cutoff filter for blocking infrared rays is placed in front of the lens. By not being located at the front of the lens, the subject is photographed even in an environment where there is little visible light by actively transmitting infrared rays.

 In the field of biometrics such as iris recognition, a band-pass filter which partially transmits the wavelength of the visible light region as well as the wavelength of the infrared region is used as a filter for filtering incident light for identification, It is used for shooting.

However, conventionally, in order to operate the IR cut filter or the iris recognition filter on the front surface of the camera lens, a filter driving part linearly driven left and right on the front surface of the camera lens is used, or each filter is arranged on the front surface of the camera lens Each filter was driven.

Such a conventional configuration has a complicated structure for driving the filter, and as the filters are arranged vertically, the size of the filter switching device increases, so that the camera module can not be compactly implemented. In addition, due to the configuration of such a filter switching device, there is a problem that it is difficult to apply a filter switching device having two or more filters to a mobile device with a large height and size limitation.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to simplify the configuration for driving the filter and to allow the filter to operate simultaneously by the rotation unit having the filter of the same height, It is an object of the present invention to implement a camera module including an applicable filter switching device.

In order to achieve the above object, the present invention provides a filter switching device for use in a camera module of a mobile device, the filter switching device comprising: an upper cover provided with a light passage hole; A first filter blade unit including a first filter installed to rotate at a predetermined angle around a first reference axis of the base and covering the light passage hole; A second filter blade portion including a second filter that rotates at the same height as the first filter blade portion and simultaneously rotates with the first filter blade portion about the second reference axis of the base to cover the light passage hole; A rotating part connected to the first and second filter blade parts and rotated in a clockwise or counterclockwise direction about the light passing hole to simultaneously rotate the first and second filter blade parts; A driving unit for rotating the rotation unit by a magnetic force; And a base for guiding the rotation of the rotation part and receiving the driving part, wherein the rotation part covers one of the first and second filters covering the light transmission hole when rotated clockwise, The remaining one of the first and second filters may cover the light passage hole.

The filter blade portion includes: first and second blades supporting the first and second filters; And first and second guide grooves formed in the first and second blades in arc shapes at predetermined distances from the reference axes toward the first and second filters, respectively.

The rotation unit includes first and second projections that are respectively moved along the first and second guide grooves and fixed to the upper side of the rotary ring at a predetermined distance from the reference axes; And a guide ring fixed to the base and guiding the rotation ring to rotate.

The third and fourth filter blade portions include third and fourth blades supporting the first and second filters, respectively; And third and fourth guide grooves formed linearly at predetermined distances from the reference axes in the third and fourth blades toward the first and second filters, respectively.

The rotary unit includes first and second projections that are respectively moved along the first and second guide grooves and fixed to the upper side of the rotary plate at predetermined distances from the reference axes; And a guide ring fixed to the base and guiding the rotation plate to rotate.

The driving unit may include: a magnet coupling unit formed on both sides of the rotation unit; A magnet coupled to the magnet coupling part to drive the rotation part; And an electromagnet having both ends spaced apart from the first and second magnets by a predetermined distance.

The driving unit may rotate the rotating unit by an attractive force or a repulsive force with the magnet according to a change in polarity of both ends of the electromagnet.

The magnet may have different polarities in a direction parallel to a virtual axial direction passing through the light passing hole and the lens of the camera module.

The first and second reference axes may be arranged on an axis parallel to an imaginary line connecting the drive unit.

The first filter may be an infrared cut filter, and the second filter may be a band pass filter for recognizing an iris.

The first filter may be an infrared cut filter, and the second filter may be made of glass.

According to an aspect of the present invention, there is provided a mobile device including a front camera, a rear camera, and a filter switching device, and the filter switching device may be formed on the front camera or the rear camera.

According to an aspect of the present invention, there is provided a mobile device comprising: a camera module including a lens transfer unit and a lens unit moving forward and backward along the lens transfer unit; And

And a filter switching device including a driving part driven by an electromagnetic force and disposed in front of the camera module.

The lens transfer unit may have a height lower than a front surface of the lens unit with respect to an initial position of the lens unit so as to secure a space for rotating the driving unit of the filter switching device,

As described above, in the present invention, since the driving units are disposed on both sides of the base and the filter blade units are formed at the same height, a compact filter switching apparatus having a low height can be realized. Accordingly, the filter switching device according to the present invention can be applied to a mobile device having a small size and a small thickness.

Further, in the filter switching device of the present invention, the electromagnets are arranged on both sides of the base and rotated by the rotating ring, so that the structure is simple and there is little interference with other members, and the residual balance is small.

1 is a perspective view showing a front view of a mobile device according to an embodiment of the present invention.
2 is a perspective view illustrating a rear surface of a mobile device according to an embodiment of the present invention.
3 is a perspective view illustrating a camera module including a filter switching device used in a mobile device according to an exemplary embodiment of the present invention.
4 is an exploded perspective view of a camera module including a filter switching device according to an embodiment of the present invention.
5 is a perspective view showing a case where a cover is separated from a filter switching device according to an embodiment of the present invention.
Fig. 6 is a plan view showing a case where the second filter is located in the light passage hole in the filter switching device of Fig. 5;
FIG. 7 is a plan view showing a case where the first filter is located in the light passage hole in the filter switching device of FIG. 5; FIG.
8 is a perspective view showing a camera module including a filter switching device used in a mobile device according to another embodiment of the present invention.
9 is an exploded perspective view showing a camera module including a filter switching device according to another embodiment of the present invention.
10 is a perspective view showing a case where a cover is separated from a filter switching device according to another embodiment of the present invention.
11 is a plan view showing a case where the second filter is located in the light passage hole in the filter switching device of Fig.
12 is a plan view showing a case where the first filter is located in the light passage hole in the filter switching device of FIG.
13A is a side view showing a camera module according to the present invention in which the height of the lens transfer part is lower than the lens part.
13B is a side view showing the camera module of the prior art in which the height of the lens feeding portion is higher than the lens portion.

Hereinafter, embodiments of a camera module including a filter switching device according to the present invention and a mobile device having the camera module will be described in detail with reference to the accompanying drawings. It is to be understood that the embodiments described below are provided for illustrative purposes only, and that the present invention may be embodied with various modifications and alterations. In the following description, well-known functions or components are not described in detail to avoid obscuring the subject matter of the present invention. In addition, the attached drawings are not drawn to scale in order to facilitate understanding of the invention, but the dimensions of some of the components may be exaggerated.

The filter switching device of the camera module including the filter switching device according to an embodiment of the present invention can be applied to a mobile device having a camera module such as a smart phone,

Hereinafter, a smart phone will be described as an example of a mobile device to which the present invention can be applied.

FIG. 1 is a perspective view showing a front surface of a mobile device, that is, a smartphone according to an embodiment of the present invention, and FIG. 2 is a perspective view illustrating a rear surface of a smartphone according to an embodiment of the present invention. 3 is a view illustrating a camera module including a filter switching device used in a mobile device according to an embodiment of the present invention.

1 and 2, the smartphone 1 includes a housing 10, a communication unit 20, a front camera module 30, a rear camera module 40, a flash 50, and a near infrared ray LED 50 .

The housing 10 forms an outer shape of the smartphone 1, and a display unit 11 for outputting various data is provided on the front face. The display unit 11 may be an LCD or an OLED. Various types of printed circuit boards (not shown) including a controller (not shown) are installed in the housing 10 so that the smartphone 1 can exhibit various functions. A printed circuit board (not shown) or a control unit (not shown) provided inside the housing 10 is the same as or similar to that used in the conventional smartphone, and thus a detailed description thereof will be omitted.

A communication unit 20 is provided on one side of the upper portion of the front surface of the housing 10. The communication unit 20 allows various devices using an infrared remote control such as a television, audio, and set-top box to be operated by a smart phone by infrared rays. Since the communication unit 20 may not be provided depending on the type of the smart phone, detailed description thereof will be omitted.

On the other hand, a near infrared ray LED (not shown) may be provided at the communication unit 20 or at one side of the communication unit 20 so that night photography can be performed.

The front camera module 30 is located at one side of the communication unit 20. The front camera module 30 may be used for self-photographing or for iris recognition. In recent years, a smartphone holder (Selkabon) has been widely used for self-photographing. Accordingly, the front camera module 30 has increased usability as much as the camera (not shown) of the rear camera module 40.

The front camera module 30 is provided with a printed circuit board (not shown) provided with a cover glass (not shown), an autofocus lens (not shown), an image sensor (not shown), and an image sensor (not shown). A printed circuit board (not shown) provided with such a cover glass (not shown), an autofocus lens (not shown), an image sensor (not shown) and an image sensor can use the same ones as those used in a smartphone according to the related art A detailed description thereof will be omitted.

The rear camera module 40 is installed on the rear surface of the housing 10. Since the rear camera module 40 is substantially the same in configuration as the front camera module 30, a detailed description thereof will be omitted.

The flash 50 may be formed on one side of the rear camera module 40. In addition, the near-infrared LED 60 may be provided on one side of the flash 50. When shooting in the infrared mode at night, the near-infrared LED 60 emits near-infrared rays to emit a subject in a dark place, so that infrared photography is possible.

3, the filter switching device 100 is provided in a manner that the front camera module 30 or the rear camera module 40 is wrapped around the front camera module 30 or the rear camera module 40 in the direction of the subject. The filter switching device 100 will be described in detail below.

4 is an exploded perspective view of a filter switching device 100 of a camera module including a filter switching device according to an embodiment of the present invention. 5 is a perspective view showing a case where the cover 110 and 120 are separated from the filter switching device 100 of the camera module including the filter switching device according to the embodiment of the present invention.

4 and 5, a filter switching device 100 of a camera module including a filter switching device includes an outer cover 110, an inner cover 120, a first filter blade 130, A rotation unit 140, a rotation unit 150, a base 160, and a driving unit 170.

The outer cover 110 is configured to enclose the front camera module 30 or the rear camera module 40. The outer cover 110 has a rectangular parallelepiped shape and includes a front cover 111 and a first light passage hole 113. The front cover 111 forms an outer surface of the front of the filter switching device 100 closest to the subject. The first light passage hole 113 is formed in a circular shape at a central portion of the front cover 111. [ The first light passage hole 113 allows the light of the subject to pass through.

The inner cover 120 is installed in the rear of the front cover 111 and in front of the base 160. The inner cover 120 covers and protects the filter blade portions 130 and 140 and the rotation portion 150. A first cover 121 corresponding to the front cover 111 is formed in the inner cover 120 and an inner cover second light passage hole 123 is formed to allow the light of the light passage hole 113 to pass therethrough. Preferably, a cover glass (not shown) is provided in the inner cover second light passage hole 123 to protect the filter blade portions 130 and 140 and the rotation portion 150. It is of course possible that the inner cover 120 is formed integrally with the outer cover 110. Thus, the assembling process of the filter switching device 100 can be simplified.

The first filter blade 130 is installed to rotate around a reference axis 167a of the base 160 at a predetermined angle. The first filter blade 130 includes a first filter 131, a first filter blade 133, a first guide groove 135, and a cam hole 137.

The first filter 131 selectively blocks the light passage holes 113 and 123, and may be formed of an infrared cut filter, a band pass filter for recognizing the iris, or a glass filter without a filter. The first filter 131 is formed in a circular shape and is positioned at one end of the first filter blade 133.

The first filter blade 133 is rotated clockwise or counterclockwise by the first guide protrusion 151 of the rotating part 150 which rotates by the driving part 170. The first filter blade 133 is formed in a thin plate shape. A first filter 131 is disposed at one end of the first filter blade 133 and a cam hole 137 is coupled to the first reference axis 167a at the other end. The first filter blade 133 rotates about the first reference axis 167a.

The first guide groove 135 guides the first guide protrusion 151 so that the first guide protrusion 151 can be moved by the rotation of the rotation unit 150. The first guide groove 135 is formed in an arc shape having a predetermined width and a predetermined length, and is positioned between the first filter 131 and the cam hole 137. Here, the arc shape is a shape having a part of a circumference. The first and second guide grooves 135 and 145 are formed at predetermined distances from the reference axes 167a and 167b in the first and second blades 133 and 143 toward the first and second filters 131 and 141, respectively.

The cam hole 137 is located at the other end of the first filter blade 133. The cam hole 137 is formed as a circular hole to engage with the first reference shaft 167a.

The second filter blade 140 is installed to rotate around the reference axis 167b of the base 160 at a predetermined angle. The second filter blade 140 includes a second filter 141, a second filter blade 143, a second guide groove 145, and a cam hole 147.

Most of the configuration of the second filter blade portion 140 is the same as that of the first filter blade portion 130. Therefore, detailed description is omitted.

In the present embodiment, the guide grooves 135 and 145 may be formed in a linear shape, but it is preferable that the guide grooves 135 and 145 are formed in an arc shape to prevent interference or collision of the first filter 131 and the second filter 141 .

The first and second filter blade portions 130 and 140 rotate simultaneously with each other. Accordingly, when the first filter 131 of the first filter blade unit 130 is positioned in the light passage holes 113 and 123, the second filter 141 of the second filter blade 140 is inserted into the light passage hole 113 and 123, respectively. Similarly, when the second filter 141 of the second filter blade portion 140 is located in the light passage holes 113 and 123, the first filter 131 of the first filter blade portion 130 is inserted into the light passage holes 113 and 123 ). ≪ / RTI >

The first and second filter blade portions 130 and 140 are formed at the same height. Thus, compared with the conventional method in which a plurality of filter blades are vertically formed, the present invention can reduce the overall height of the filter conversion device 100, thereby realizing a compact configuration.

The cam holes 137 and 147 of the first and second filter blade portions 130 and 140 are formed on one side of the base 160 along the X-X axis. Accordingly, the first and second filter blade units 130 and 140 do not interfere with each other, so that the filter switching device 100 can be used stably and for a long time without a residue.

The rotation part 150 rotates the first and second filter blade parts 130 and 140. The rotation section 150 includes a first projection 151, a second projection 153, a first rotation ring 155, a rotation plate 157, and a corresponding hole 159. [

The first projection 151 is located on one side of the upper surface of the rotation plate 157, that is, near the first reference axis 167a. The second projection 153 is located on the other side of the upper surface of the rotation plate 157, that is, near the second reference axis 167b. The first and second protrusions 151 and 153 move along the first guide groove 135 and the second guide groove 145, respectively.

The first rotating ring 155 is formed on the lower surface of the rotating portion 150. The first rotating ring 155 has a predetermined width and a predetermined thickness and is configured to be guided and rotated within the guide ring 161 of the base 160.

The rotation plate 157 is rotated by the driving unit 170. The rotary plate 157 has a circular central portion, and rectangular engaging portions 152 and 154 at both ends in a virtual X-X axial direction. First and second projections 151 and 153 are formed on the upper surface of the rotation plate 157 and a first rotation ring 155 is formed on the lower surface. Magnets 171 and 173 are formed on the magnet coupling portions 152 and 154 of the rotary plate 157, respectively.

The corresponding hole 159 is formed in a circular shape at the central portion of the rotation plate 157 so as to pass light with a smaller diameter than the first rotary ring 155.

 The base 160 forms the lower portion of the filter switching device 100. The base 160 includes a guide ring 161, a corresponding hole 163, an electromagnet seating portion 165, a reference axis 167 and magnet accommodating portions 169a and 169b.

The guide ring 161 is formed on the upper portion of the base 160. The guide ring 161 is formed in a donut shape and may have a predetermined thickness and a predetermined width. The guide ring 161 is formed to be larger than the radius of the first rotating ring 155 to guide the first rotating ring 155.

Although the guide ring 161 is formed to have a predetermined thickness at the upper portion of the base 160 for the sake of convenience, the guide ring 161 is preferably formed at the same height as the base 160 . The configuration of the guide ring 161 formed at the same height as the base 160 and the configuration of the thin rotation plate 157 allow the filter switching device 100 to move the guide ring 161 more It can be thinned and optimized for thinner mobile products.

The corresponding hole 163 is circular when formed by the guide ring 161. The corresponding hole 163 can guide the light of the subject to the camera module 30 or 40. [

The electromagnet seating portion 165 is capable of seating the electromagnets 175 and 177. The electromagnet seating portion 165 may have a "C" shape, but is not limited thereto and may be configured so as to seat the electromagnets 175, 177. The camera modules 30 and 40 are provided with lens feeding parts VCM 33 and 43 for performing zooming and focusing by moving the lens parts 31 and 41 in the optical axis direction.

The reference axis 167 is formed on one side of the upper portion of the base 160. The reference axis 167 includes a first reference axis 167a and a second reference axis 167b. The first and second filter blade portions 130 and 140 are coupled to the reference shaft 167 through cam holes 137 and 147, respectively. The reference axis 167 may be formed in a cylindrical shape so that the circular cam holes 137 and 147 can be engaged with each other. The reference axis 167 is formed on one side of the imaginary X-X axis of the base 160. That is, the first reference axis 167a is located in the vicinity of one end 175b of the electromagnet 175 and the second reference axis 167b is located in the vicinity of the other end 177a of the electromagnet 177.

The magnet accommodating portions 169a and 169b allow the magnets 171 and 173 to freely rotate without being interfered with the upper surface of the base 160. [ The magnet accommodating portions 169a and 169b are formed at both ends of the upper surface of the base 160 and are formed in a rectangular shape around a virtual X-X axis.

The driving unit 170 is configured to rotate the rotation unit 150. The driving unit 170 is composed of magnets 171 and 173 and electromagnets 175 and 177.

The magnets 171 and 173 may be formed as permanent magnets on the upper and lower surfaces of the magnet coupling portions 152 and 154 of the rotary portion 150, respectively. Preferably, the magnets 171 and 173 are arranged such that any one polarity is disposed between the ends 175a, 175b, 177a, and 177b, and a portion of the magnet engaging portions 152 and 154 close to the corresponding hole 159 are disposed in opposite polarities It can be disposed only on the lower surface of the magnet coupling portions 152 and 154. [ With this configuration, the blades 133 and 143 and the magnets 171 and 173 do not interfere with each other, and the height of the filter switching device 100 can be reduced.

The electromagnets 175 and 177 are formed in a substantially U-shape. The electromagnets 175 and 177 are configured such that both ends 175a, 175b, 177a and 177b are separated from the magnets 171 and 173, respectively. Concretely, both ends 177a and 177b of the electromagnet 177 are formed so as to be spaced apart from the locus drawn by the magnet 173 rotated by the vanes 154 of the rotary part 150 by a predetermined distance. 6, when the magnet 173 faces the first end 177a of the electromagnet 177 and the gap between the magnet 173 and the second end 177b of the electromagnet 177 The intervals in the case are the same. The relationship between the magnet 171 on the other side and the electromagnet 175 also operates in the same manner as the relationship between the magnet 173 and the electromagnet 177.

The U-shaped yokes 175d, 175e, 177d and 177e of the electromagnets 175 and 177 are made of a magnetic material such as iron and coils 175c and 177c are formed in the centers of the yokes 175d, 175e, 177d and 177e, The U-shaped yokes 175d, 175e, 177d, and 177e of the electromagnets 175 and 177 are magnetized to apply attraction force or repulsion force to the magnets 171 and 173, respectively, when the currents are applied to the coils 175c and 177c The end portions 175a, 175b, 177a, and 177b of the yokes 175d, 175e, 177d, and 177e may be formed to face the magnets 171 and 173 as wide as possible.

Hereinafter, the operation of the filter switching device 100 according to one embodiment of the present invention will be described with reference to FIGS. 5 to 7. FIG. Hereinafter, for convenience of explanation, a filter switching device 100 is installed in the front camera module 30, a band-pass filter is applied to the first filter 131, a second filter 141 to which an infrared- . In addition, the magnets 171 and 173 can be coupled to one side of the magnet coupling portions 152 and 154 in the axial direction parallel to the optical axis. For convenience of explanation, the polarities of the magnets 171 and 173, that is, the polarity in the direction toward the subject in the axial direction parallel to the optical axis are S-polarized, and the polarities of the magnets 171 and 173 And the polarity in the opposite direction to the polarity is N pole. Both ends 175a, 175b, 177a, and 177b of the electromagnets 175 and 177 are illustrated as facing the N poles of the magnets 171 and 173, respectively.

In the general case, the infrared cut filter 141 is located in the light passage hole 113 as shown in FIG.

In this state, when the iris recognition is performed for identification purposes or the like, the iris recognition mode is selected. The method of selecting the iris recognition mode can be exemplified as follows. When the user executes the camera app on the display unit 11 of the smartphone 1, a screen for selecting the camera mode is output to the display unit 11. [ Accordingly, the user can touch the display unit 11 to select the iris recognition mode. At this time, if the user selects the iris recognition mode on the display unit 11, the filter switching device 100 operates in the iris recognition mode.

In addition to the method of selecting the iris recognition mode with the camera app described above, the iris recognition mode can be selected through a dedicated button or a key, and these methods are known methods, and thus a detailed description will be omitted.

6, one end 177b of the electromagnet 177 is magnetized to the N pole and the other end 177a is magnetized to the S pole. One end 175b of the electromagnet 175 on the opposite side is magnetized to the N pole and the other end 175a is magnetized to the S pole. The one end 177b of the electromagnet 177 pushes the magnet 171 facing the N pole and the other end 177a of the electromagnet 177 pulls the magnet 171 facing the N pole. The electromagnet 175 on the opposite side also applies attraction and repulsive force to the magnet 173 on the same principle as the electromagnet 175. Thus, the infrared cutoff filter 141 is located in the light passage hole 113, and the bandpass filter 131 is deviated from the light hole 159.

When the iris recognition mode is selected in this state, a control unit (not shown) flows a current in the opposite direction to the coils 175c and 177c of the electromagnets 175 and 177. [ One end 177b of the electromagnet 177 is magnetized to the S pole and the other end 177a is magnetized to the N pole. One end 175b of the opposite electromagnet 175 is magnetized to the S pole and the other end 175a is magnetized to the N pole. The one end 177b of the electromagnet 177 pulls the magnet 171 facing the N pole and the other end 177a of the electromagnet 177 pushes the magnet 171 facing the N pole. One end 175b of the opposite electromagnet 175 is magnetized to the S pole and pulls the magnet 173 facing the N pole and the other end 175a of the electromagnet 175 is magnetized to the N pole, (173).

The rotation plate 157 rotates as shown in Fig. 7 by magnetization of both ends 175a, 175b, 177a, and 177b of the electromagnets 175 and 177 described above. In this case, the first filter blade 133 rotates in the clockwise direction with the projection 151 formed on the upper portion of the rotary plate 157 about the reference axis 167a being guided by the guide groove 135. [ The second filter blade 143 rotates counterclockwise as the projection 153 formed on the upper portion of the rotary plate 157 is guided by the guide groove 145 about the reference axis 167b. In this case, the guide groove 135 is formed to have a predetermined length so that the both ends 175a, 175b, 177a, and 177b of the electromagnets 175 and 177 and the magnets 171 and 173 can be kept apart from each other by a predetermined distance .

Accordingly, the first filter 131 having the band-pass filter is located in the light passage hole 113, and the second filter 141 having the infrared ray blocking filter is located at a position deviated from the light passage hole 113. With this arrangement, the smartphone 1 can recognize the iris by the iris recognition.

When the user selects a mode in which the iris recognition mode is again set to the general photographing mode, that is, the mode in which the infrared cut filter is located in the light passage hole 113, the controller (not shown) applies a current in the opposite direction to the coil of the electromagnets 175 and 177 do. 6, the second filter 141 having the infrared cutoff filter is located in the light passage hole 113 and the first filter 131 having the bandpass filter is located at a position deviated from the light passage hole 113 . In the normal shooting mode, the infrared ray blocking filter blocks the infrared rays in the daytime and transmits only visible light, so that the image quality can be improved.

As described above, according to the present invention, the user can selectively control the band pass filter or the infrared cut filter to perform photographing according to the purpose. In addition to the bandpass filter, the first filter may be an infrared cut filter or a normal glass, and the second filter may be a general glass or bandpass filter in addition to the infrared cutoff filter.

Hereinafter, as another embodiment of the present invention, a case where the rotating part is constituted by a rotating ring rather than a rotating plate will be described as an example.

FIG. 8 is a perspective view showing a camera module including a filter switching device used in a mobile device according to another embodiment of the present invention, and FIG. 9 is an exploded perspective view of a camera module including the filter switching device of FIG. Fig. 10 is a perspective view showing a case where the cover is separated from the filter switching device of Fig. 8, and Fig. 11 is a plan view showing a case where the second filter is located in the light passing hole in the filter switching device of Fig. 12 is a plan view showing a case where the first filter is located in the light passage hole in the filter switching device of FIG.

8 to 10, a filter switching device 200 of a camera module including a filter switching device according to another embodiment of the present invention includes an outer cover 210, an inner cover 220, a third filter blade 230, a fourth filter blade 240, a rotation unit 250, a base 260, and a driving unit 270.

In this embodiment, most of the configuration except for the configuration of the guide grooves 235, 245, the rotation part 250, and the guide ring 261 is the same as the configuration of the filter switching device 100 according to the above-described embodiment, It is omitted. Other embodiments of the present invention are corresponding to those of the above-described embodiments. Hereinafter, the configurations of the guide grooves 235 and 245, the rotation part 250, and the guide ring 261 will be described in detail.

In this embodiment, the guide grooves 235 and 245 are linearly formed to have a predetermined width and a predetermined length. The third and fourth protrusions 251 and 253 formed on the second rotating ring 255 selectively move the third and fourth filters 231 and 241 while moving the third and fourth guide grooves 235 and 245 in a straight line, It can be positioned in the through hole 213.

The rotation unit 250 rotates the third and third filter blade units 230 and 240. The rotation part 250 includes a third projection 251, a fourth projection 253, a second rotation ring 255, a magnet coupling part 258 and a light corresponding hole 259.

The third projection 251 is positioned on one side of the upper surface of the second rotating ring 255, that is, near the third reference axis 267a. The fourth projection 253 is located on the other side of the upper surface of the second rotating ring 255, that is, near the fourth reference axis 267b. The third and fourth protrusions 251 and 253 move along the third guide groove 235 and the fourth guide groove 245, respectively.

The second rotating ring 255 occupies most of the rotating part 250 and is formed in a circular shape. The second rotating ring 255 has a predetermined width and a predetermined thickness and is configured to be guided and rotated outside the guide ring 261 of the base 260.

The second rotary ring 255 is guided and rotated by the guide ring 261 having a small thickness and the third and fourth projections 251 and 253 are rotated along the third and fourth guide grooves 235 and 245 The third and fourth filter blade portions 230 and 240 can be accurately controlled. Compared with the rotation plate 157 of the filter switching device 100 described above, the present embodiment uses the second rotating ring 255 and the guide ring 261 having a small thickness, There is an advantage that it is reduced.

The second rotating ring 255 is provided with a magnet coupling portion 258 at both ends in a virtual X-X axis direction. The third and fourth magnets 271 and 273 can be coupled to the magnet coupling parts 258a and 258b, respectively.

The corresponding hole 259 is formed in a circular shape in the central part of the rotation part 250 so as to pass light with a smaller diameter than the second rotation ring 255.

The guide ring 261 is formed in a circular shape on the top of the base 260. The second rotating ring 255 can be rotated along the outer circumference of the guide ring 261. [ Preferably, the guide ring 261 is formed to have a minimum thickness that does not interfere with the base 260 when the magnets 271 and 273 rotate.

The operation of the filter switching device 200 according to another embodiment of the present invention having the above structure will be described with reference to Figs. 11 and 12. Fig.

In this embodiment, most of the operations are the same as those of the filter switching device 100 according to the above-described embodiment except for the operation of the guide grooves 235 and 245, the rotation part 250 and the guide ring 261, It is omitted.

The second rotating ring 255 rotates as shown in Figs. 11 to 12 by the magnetizations of both ends 275a, 275b, 277a and 277b of the electromagnets 275 and 277. [ In this case, the projection 251 formed on the upper portion of the second rotary ring 255 about the reference axis 267a is guided by the guide groove 235 to rotate clockwise in the third filter blade 233. The fourth filter blade 243 is rotated in the counterclockwise direction by the projection 253 formed on the upper portion of the second rotary ring 255 about the reference axis 267b being guided by the guide groove 245. [ In this case, the guide groove 235 is formed to have a predetermined length so that the both ends 275a, 275b, 277a, and 277b of the electromagnets 275 and 177 and the magnets 271 and 273 can be kept apart from each other by a predetermined distance .

Also in this embodiment, the third filter 231 and the fourth filter 241 may be formed of a band-pass filter, an infrared cut filter, and a general glass according to a desired mode.

FIG. 13A is a view showing a camera module according to the present invention in which the height of the lens transfer portion is lower than that of the lens portion, and FIG. 13B is a view showing a camera module of the conventional invention in which the height of the lens transfer portion is higher than the lens portion.

13B, the height of the lens transfer part 433 is H3 from the lowermost end of the camera module, and the distance between the upper end of the lens part 431 and the lens transfer part 433 is H4. Further, the stroke area of the lens portion 431 is equal to or smaller than H4. Accordingly, in the conventional invention, the lens transfer section 433 is higher than the lens section 431, so that the camera module can not be realized in a small size. Further, when the same configuration as the filter switching device is applied to the front surface of the lens portion 431, there is no space between the lens portion 431 and the lens transfer portion 433, and an additional volume corresponding to H4 is required.

13A, the camera module applied to the mobile device according to the present invention has a height H1 from the lowermost end of the camera module to the initial position of the lens portion 331, and the height H1 of the lens transfer portion 333 and the lens portion 331 The interval between the initial positions is H2. With this configuration, the lens portion 331 is formed so as to form a step with the front surface of the lens transfer portion 333. Here, the initial position means a position where the distance from the top of the lens feeding part 333 becomes minimum when the lens part 331 moves for focus adjustment.

The lens transfer portion 333 of the present invention is lower in height than the lens portion 331. [ That is, when a further configuration, such as a filter switching device, is applied to the front surface of the camera module, the lens feeding part 333 moves the front surface of the lens part 331 relative to the initial position of the lens part 331 Is formed at a lower height. Accordingly, the camera module according to the present invention can realize a low and compact overall structure, and is easily applicable to a mobile device having a large height and size limitation.

Although the stroke area of the lens section 331 of the present invention is formed in the same manner as that of the conventional camera module according to Fig. 13B, both the initial position of the lens transfer section 333 and the initial position of the lens section 331, An empty space is formed. This space can be utilized as a space for driving the camera such as the position of the electromagnet of the filter switching device or the rotation of the magnet. Accordingly, the efficiency of space utilization is increased in the camera module according to the present invention, and the magnet or the like of the driving unit of the filter switching device can be prevented from interfering with other members when rotating.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention.

1: smartphone 10: housing
20: front camera module 40: rear camera module
50: flash 60: near-infrared LED
100 (200): filter switching device 110 (210): outer cover
120 (220): inner cover 130 (230): first and third filter blade portions
140 (240): the second and fourth filter blade portions
150 (250): rotating part 160 (260): base
170 (270): Driving unit 331:
333:

Claims (6)

A lens portion; And
And a lens feeding part for driving the lens part forward and backward,
Wherein a front surface of an initial position of the lens unit is formed higher than a front surface of the lens transfer unit. The method according to claim 1,
Wherein the initial position is a position where the distance between the lens unit and the uppermost portion of the lens transfer unit is minimized by driving the lens unit forward and backward. The method according to claim 1,
And at least a part of the lens portion is inserted into the lens transfer portion. The method of claim 3,
Wherein an empty space is formed on an outer side surface of a stroke area where the lens unit is driven forward and backward and on an upper side of the lens transfer unit. 5. The method of claim 4,
Further comprising a filter switching device disposed in front of the lens portion,
Wherein at least part of the driving unit of the filter switching device is formed in the empty space. A mobile device comprising a camera module as claimed in any one of claims 1 to 5.

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