KR101017145B1 - Camera Module for Mobile communication terminal - Google Patents

Abstract

The present invention discloses a camera module for a mobile communication terminal. A camera module for a mobile communication terminal according to the present invention comprises: a housing; A lens unit installed to be movable in the longitudinal direction in the housing; An imaging unit which captures an image passing through the lens unit and transmits the image to the main board of the mobile communication terminal; An antenna installed in at least one of the housing and the imaging unit; And a driving unit generating power to move the lens unit in the longitudinal direction to control the resonance frequency of the antenna.

Description

Camera module for mobile communication terminal

1 is a perspective view of a camera module for a mobile communication terminal according to an embodiment of the present invention.

FIG. 2 is an exploded perspective view of the camera module for a mobile communication terminal of FIG. 1.

3 to 4 are views illustrating an operation process of a driving unit of a camera module for a mobile communication terminal according to an embodiment of the present invention.

4 is a diagram illustrating that a mobile communication terminal resonates due to radio waves transmitted from a base station.

5 is a graph illustrating a change in a resonance frequency of an antenna according to a surrounding environment.

Description of the Related Art

110. Housing 120. Lens section

130..Image 140..antenna

150..coil coil motor 151..coil

152..Permanent magnet

The present invention relates to a camera module for a mobile communication terminal, and more particularly, to a camera module for a mobile communication terminal for receiving a radio wave used in the mobile communication terminal.

In general, the antenna mounted on the mobile communication terminal is for receiving radio waves in the air. Such antennas tend to change from an external antenna to an internal antenna disposed inside the mobile communication terminal in order to enhance the appearance of the mobile communication terminal.

In recent years, most mobile communication terminals are equipped with a built-in antenna. Such a built-in antenna has been changed in shape to meet the trend of miniaturization and slimming of mobile communication terminals. That is, the size or thickness of the built-in antenna is made thinner and placed on the main board of the mobile communication terminal.

Meanwhile, in order to reduce the size of the mobile communication terminal, the size of the main board on which the antenna is arranged should be reduced, and in order to reduce the size of the main board, the size of the built-in antenna should be reduced. However, since the frequency to be received by the mobile communication terminal is defined as a standard, and the length of the built-in antenna for receiving such a standardized frequency is generally proportional to the wavelength of the frequency, the length of the antenna cannot be reduced below a predetermined length. .

Therefore, as an alternative to reducing the area of the motherboard, the integrated antenna is integrated in the camera module disposed in most mobile communication terminals. By disposing the built-in antenna as described above, the area of the main board can be reduced, and the size of the mobile communication terminal can be reduced.

On the other hand, since the antenna is an electronic component that communicates digital data in a high frequency band (approximately 1.8 GHz), when the user composed of a conductor capable of flowing electricity approaches the antenna of the mobile terminal, the antenna has no electromagnetic effect. Receive. Therefore, the resonance frequency band of the antenna is changed, and the impedance value is also changed in accordance with the change of the resonance frequency band.

In order to solve this problem, the conventional mobile communication terminal has a switch for selecting three impedance matching units and a plurality of impedance matching units between the central processing unit and the antenna of the mobile communication terminal.

Thus, when the resonance frequency band of the antenna is changed by an external member, the antenna selects one of a plurality of impedance matching units by using a switch and connects the antenna and the central processing unit so that the antenna becomes a resonance frequency band to be received. The resonance frequency band of the antenna was changed by increasing or decreasing it.

Since the above-described technique arranges about three impedance matching units, the number of resonance points is limited to three, that is, the number of impedance matching units, the structure of the impedance matching unit is complicated, and the impedance matching unit and the switch must be provided separately, so that the manufacturing cost of the mobile communication terminal is increased. There is a rising problem.

An object of the present invention is to provide a camera module for a mobile communication terminal capable of correcting a resonance frequency band using a camera module.

Accordingly, the camera module for a mobile communication terminal according to the present invention comprises: a housing; A lens unit installed to be movable in the longitudinal direction in the housing; An imaging unit which captures an image passing through the lens unit and transmits the image to the main board of the mobile communication terminal; An antenna installed in at least one of the housing and the imaging unit; And a driving unit generating power to move the lens unit in a longitudinal direction to control a resonance frequency of the antenna.

On the other hand, the longitudinal direction is defined as the path direction in which the image enters the lens unit. Therefore, the above or below described is the same direction as the longitudinal direction.

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

1 is a perspective view of a camera module for a mobile communication terminal according to an embodiment of the present invention. Referring to FIG. 1, the camera module 100 for a mobile communication terminal includes a housing 110, a lens unit 120, a driving unit, an imaging unit 130, and an antenna 140.

The housing 110 forms an appearance of the camera module 100 for a mobile communication terminal, and a predetermined space is provided.

The lens unit 120 passes an image of a subject and is installed in the housing 110 so as to be movable upward or downward. The conventional lens unit 120 includes one or more lenses to focus the subject or have an optical zoom function. The driving mechanism such as focus control or optical zoom of the lens unit 120 is already shown technology. For example, the lens unit 120 is provided with one or more lens groups composed of a plurality of lenses. When each lens group is driven by a driver to be described later, the focus can be controlled or the optical zoom can be performed.

Briefly, the driving unit generates power to move the lens unit 120 upward or downward to control the resonance frequency of the antenna 140.

As described above, in order for the driving unit to move and move the lens unit 120 upward or downward, so that the resonance frequency of the antenna 140 to be described later is changed, the material of the lens unit 120 may be formed of a dielectric material or a conductor having a higher dielectric constant than the plastic. It is preferable to form. Since the lens unit 120 used in the conventional camera module is formed of a plastic material, even if the lens unit 120 moves upwards or downwards, electrical effects on the antenna 140 are insignificant, which will be described later. The resonance frequency of the antenna 140 cannot be changed. However, the material of the lens unit 120 is not limited to a dielectric or a conductor, and any material may be used as long as the material can change the resonant frequency of the antenna 140 by position shift.

Here, the driving unit may move the lens unit 120 in the up and down directions. Alternatively, since the driving unit may move the lens unit 120 only in one of the up and down directions, the driving unit further includes an elastic member 121 for restoring the lens unit 120 to its original position. It can be provided. The lens unit 120 is coupled to the housing 110 and the lens unit 120 to elastically support.

Meanwhile, although the elastic member 121 is illustrated as a leaf spring as shown in FIG. 1, this is merely an example, and the lens unit 120 is driven upward or downward by a driving unit to be described later. As long as it is an elastic member which can be restored, you may use it.

The driving unit generates power to move the lens unit 120 upward or downward to control the resonance frequency of the antenna 140. In addition, the driving unit controls the lens unit 120 to move up and down so that an image of a subject is clearly formed on the image pickup device. The driving unit vertically moves the lens unit 120 such as a voice coil motor (VCM: 150), a stepping motor, and a general rotating motor to move the lens unit 120 in the vertical direction. As long as it can drive, you may use it. Meanwhile, in the present invention, a voice coil motor will be described.

The voice coil motor includes a coil 151 and a permanent magnet 152. The coil 151 is a form in which a highly conductive metal wire such as copper is wound several times on a predetermined member. One or more coils 151 are disposed along the outer side of the lens unit 120 to have a polarity when electricity flows through the coil 151 and generate an electromagnetic force toward the center of the lens unit 120 or the housing 110. Done.

The permanent magnet 152 is disposed in the housing 110 to correspond to the coil 151 and is disposed to have different polarities in the up and down directions. That is, the permanent magnet 152 is disposed on one surface of the housing 110 with a small clearance from the coil 151 disposed on the lens unit 120. The permanent magnet 152 has a N pole or S pole at both ends.

The operation of the driving unit will be described with reference to FIGS. 3 and 4 as follows. 3 shows that the lens unit 120 has no external force acting on the housing 110, and the permanent magnet 152 has N and S poles arranged side by side from the lower side of the housing 110. In this state, in order to correct the resonance frequency of the antenna 140, when electricity flows through the coil 151, the coil 151 has N pole magnetic properties. As shown in FIG. 4, the N pole of the permanent magnet 152 disposed adjacent to the coil 151 acts with the N pole of the coil 151, and the S pole of the permanent magnet 152 is a coil ( The N pole and the attraction force of the 151 acts, and the driving unit moves the lens unit 120 upward or downward with respect to the housing 110. As such, when the lens unit 120 moves upward, the antenna 140 may have an electromagnetic effect to change the resonance frequency of the antenna. In addition, the subject can be focused or optically zoomed.

As described above, the camera module corrects the resonance frequency band of the antenna 140 by using the driving unit and the lens unit 120 used to focus the subject. Therefore, it is possible to reduce the manufacturing cost of the mobile communication terminal because it is not necessary to arrange a switch for selecting one of the impedance matching units and the complex matching structure to be arranged to adjust the resonant frequency band. It works.

The imaging unit 130 captures an image passing through the lens unit 120 and converts the image data into image data. The imaging unit 130 converts the captured image data into a conversion unit (not shown) and transmits the image data to the main board of the mobile communication terminal. The imaging unit 130 is a charge-coupled device (CCD) or a complementary metal oxide semiconductor (CMOS) to form an image refracted and cropped through the lens unit 120. Imaging elements such as these can be arranged. Such an image pickup device is not limited to a charge coupling device or a complementary metal oxide semiconductor, and may be any electronic component capable of converting an image composed of light into electrical image data.

The antenna 140 is for receiving a radio wave from a communication device, and is installed in at least one of the housing 110 and the imaging unit 130. When the antenna 140 emits a radio wave having the same resonance frequency band as the antenna 140 from the base station 200, the antenna 140 recognizes the radio wave and resonates to receive the radio wave. At this time, the data contained in the received radio wave is transmitted to the main board of the mobile communication terminal (not shown).

The antenna 140 may form and arrange a conductive antenna 140 line in various forms. The shape is a helical type that wraps the outer surface of the lens unit 120 starting from one side and the other side like a screw thread formed on the outer surface of the bolt, and a patch type formed by being bent to a predetermined length such as a maze. type) and the like. The shape of the antenna 140 is not limited to the above-described form, and any form may be used as long as the antenna 140 can receive a frequency that the mobile communication terminal should receive.

As the antenna 140 is disposed in the housing 110 or the imaging unit 130 as described above, an area for installing the antenna 140 is not required on the main board of the mobile communication terminal, which is not shown. It is effective to improve the internal space efficiency of the.

In the camera module 100 for a mobile communication terminal configured as described above, the operation of the camera module 100 for a mobile communication terminal will be described in detail with reference to FIGS. 2 to 5.

First, the antenna 140 resonates. The frequency of the band that the antenna 140 can receive is emitted from the base station 200 in the air. When the antenna 140 is supplied with electricity from the main board of the mobile communication terminal (not shown) and becomes an active state capable of receiving radio waves, the antenna 140 resonates by the frequency radiated from the base station 200.

Next, the user is adjacent to the mobile communication terminal, the process of changing the resonant frequency of the antenna 140. Data received from the base station 200 is transmitted to the motherboard not shown in the mobile communication terminal. The main board, not shown, analyzes the data received from the antenna 140 and informs the user that the call has been received by using a ring tone or vibration and light. The user grasps the mobile terminal to answer the call. At this time, the user's head or hand is a conductor through which current flows and thus has an electrical effect on the antenna 140, thereby changing the resonance frequency band of the antenna 140. Referring to FIG. 5, a change in the resonant frequency band of the antenna 140 by a user is described as follows. In the graph of FIG. 5, the vertical axis represents impedance (unit dB), and the horizontal axis represents frequency (unit GHz). In the two graphs, N is a curve showing the case where the resonance frequency of the antenna 140 is optimal, and H is a curve showing the case where the user's hand contacts the mobile communication terminal. Looking at the resonance frequency in the curve N showing the case where the resonance frequency of the antenna 140 is optimal, it can be seen that the antenna 140 resonates at the N1 point. The resonant frequency in the graph is the frequency of the point where the impedance value is the lowest. Therefore, taking into account the lowest impedance value, the value of the N1 point is approximately 1.8 GHz. As shown in FIG. 4, when the user's hand is adjacent to the mobile communication terminal, the user's hand changes as shown by the curve H showing the state of contact with the mobile communication terminal. The resonance frequency of the curve H showing the case where the user's hand contacts the mobile communication terminal is H1, and H1 is approximately 1.7 GHz.

The above description will be described as an example. The resonant frequency band of a typical personal communication services (PCS) mobile communication terminal should be 1.8 GHz. When the user is adjacent to the antenna 140, the resonant frequency of the antenna 140 changes to 1.8 GHz or less. The resonance frequency should be changed so that the 140 can resonate at 1.8 GHz. Here, the change of the resonance frequency is not limited to the PCS method, but also various communication methods.

Lastly, the resonant frequency of the antenna 140 is corrected. The main board not shown transmits a signal indicating that the resonance frequency band of the antenna 140 has changed to the driver. The driving unit moves the lens unit 120 upward or downward so as to be a resonance frequency band that the mobile communication terminal should receive. Then, the resonance frequency band of the antenna 140 is changed by the lens unit 120 made of a dielectric or a conductor. When the resonance frequency band of the antenna 140 changes, when the resonance frequency band to be received reaches, the main board not shown stops driving the driving unit.

Meanwhile, the manufacturer stores the resonance frequency of the antenna 140 according to the position of the lens unit 120 in a predetermined memory, and reads it from the predetermined memory to correct the resonance frequency. It may be used to control the position of 120.

As described above, the linear movement of the lens unit 120 by the driving unit causes the antenna 140 to have one or more resonance points, thereby receiving various frequency bands.

As described above, the camera module for a mobile communication terminal according to the present invention changes the resonance frequency band of the antenna by using the driving unit of the camera module mounted in most mobile communication terminals, thereby to separate the resonance frequency band of the antenna. Since there is no need to install electronic components, manufacturing costs can be reduced.

In addition, by linearly moving the lens unit by the driving unit, the antenna has a plurality of resonance points, and thus there is an effect of receiving various frequency bands.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and any person skilled in the art to which the present invention pertains may have various modifications and equivalent other embodiments. Will understand. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Claims (5)

housing; A lens unit installed to be movable in the longitudinal direction in the housing; An imaging unit for capturing an image passing through the lens unit and transmitting the image to the main board of the mobile communication terminal; An antenna installed in at least one of the housing and the imaging unit; And And a driving unit generating power to move the lens unit in a longitudinal direction to control a resonance frequency of the antenna. The drive unit: A coil disposed along an outer side of the lens unit and exhibiting polarity when electricity flows; And And a permanent magnet installed in the longitudinal direction of the housing so as to correspond to the coil, and at least both ends thereof have permanent magnets having different polarities. delete The method of claim 1, The lens unit includes: And a resilient member disposed to be coupled to the housing to restore the lens to its original position when no external force acts on the lens. The method of claim 3, wherein The driving unit camera module for a mobile communication terminal, characterized in that for controlling the focus of the subject by moving the lens unit in the longitudinal direction. The method according to any one of claims 1, 3, and 4, The lens unit is a camera module for a mobile communication terminal, characterized in that formed of a dielectric or conductor having a higher dielectric constant than plastic.

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