JP2006285120A - Compact imaging module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a low-cost compact imaging module capable of gradually controlling a focal distance in a zoom range between telescopic photographing and wide-angle photographing, and also, having simple, compact, and durable apparatus constitution. <P>SOLUTION: The compact imaging module has a zoom control means for changing an inter-lens distance of at least two lens groups in a prescribed range, and the zoom control means has a 1st holding part for holding the 1st lens group and a 2nd holding part for holding the 2nd lens group. The 1st and 2nd holding parts are arranged while aligning the optical axis of the 1st lens group with the optical axis of the 2nd lens group. The zoom control means includes: a shifting means capable of gradually changing the inter-lens distance while aligning the optical axis of the 1st lens group with the optical axis of the 2nd lens group, and also, capable of keeping the prescribed inter-lens distance; a zoom control member arranged in the shifting means so as to control the inter-lens distance; a guide part equipped with a guiding surface; and an adjusting member connected to the zoom control member and which is made movable on the guiding surface of the guide part. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a small imaging module mounted on a mobile phone with a photographing function, a PDA (Personal Digital Assistant), or the like, and in particular, includes a zoom unit that switches between telephoto shooting and wide-angle shooting. The present invention relates to a small imaging module that can continuously adjust a focal length within a zoom range with wide-angle imaging, has a simple device configuration, is small in size, has high durability, and is low in cost.

  Conventionally, a small imaging module mounted on a mobile phone or a small digital camera or the like usually includes a holding member that holds an imaging element such as a CCD or a CMOS sensor, and a cylindrical barrel that holds an imaging lens. It is configured in combination.

  In mobile phones with a photographing function, a small imaging module has been enhanced, and the small imaging module has a zoom mechanism capable of telephoto shooting and wide-angle shooting, and can switch between telephoto shooting and wide-angle shooting. is there. Furthermore, a small imaging module having an autofocus (hereinafter also referred to as AF) function is incorporated in a mobile phone and is commercially available.

Normally, telephoto shooting and wide-angle shooting are switched by a switching lever or the like provided on the mobile phone body. By switching this lever, the user can take a picture in either the telephoto shooting or wide-angle shooting state.
There is also an auto zoom mechanism that automatically switches to either telephoto shooting or wide-angle shooting.

However, in a conventional compact imaging module with a zoom mechanism, only telephoto shooting or wide-angle shooting can be selected. That is, there is a problem that fine adjustment is not possible in the zoom range of telephoto shooting and wide-angle shooting. For this reason, an image having a configuration desired by the photographer cannot be obtained.
In addition, when switching between telephoto shooting and wide-angle shooting of a small imaging module using a switching lever or the like provided on the mobile phone body, the zoom mechanism is small because the small imaging module is small even if handled carefully by the user. When a large force is applied to the lens, there is a possibility that the switching operation between the telephoto shooting and the wide-angle shooting cannot be stably performed, and the durability may be lowered.

  In addition, a conventional small-sized image pickup module with a zoom mechanism having an auto zoom mechanism automatically switches to either telephoto shooting or wide-angle shooting, but has a problem that fine adjustment cannot be performed. In addition, since the auto zoom mechanism is provided, there is a problem that the apparatus configuration is complicated, the number of parts is increased, the cost is increased, the power consumption is increased, and the battery such as a mobile phone is consumed greatly.

  An object of the present invention is to solve the above-mentioned problems of the prior art, the focal length can be continuously adjusted within the zoom range of telephoto shooting and wide-angle shooting, and the apparatus configuration is simple and compact. An object of the present invention is to provide a small imaging module that has high durability and low cost.

  In order to achieve the above object, the present invention provides a compact imaging module having a zoom adjustment unit that changes a distance between lenses of at least two lens groups within a predetermined range, and the zoom adjustment unit includes the two lens groups. A first holding unit that holds the first lens group, and a second holding unit that holds the remaining second lens group out of the two lens groups. A holding part and the second holding part are provided with the optical axes of the first lens group and the second lens group being coincident with each other, and the zoom adjusting means is configured to include the first lens. The distance between the lenses can be continuously changed within a predetermined range and the predetermined distance between the lenses can be maintained while maintaining the state in which the optical axes of the group and the remaining second lens group coincide with each other. A moving means, provided on the moving means, A zoom adjustment member that adjusts the distance between the lenses, and further includes a guide portion that includes a guide surface, and is connected to the zoom adjustment member and is in contact with the guide surface of the guide portion, and on the guide surface. It is possible to provide a small image pickup module having a movable adjustment member, and having a predetermined inter-lens distance by the adjustment member via the zoom adjustment member.

  In the present invention, the moving means comprises a cylindrical cam mechanism, the zoom adjusting member is a lever provided in the cylindrical cam mechanism, and the adjusting member and the lever are connected via a connection pin. It is preferable that they are connected.

  According to the small image pickup module of the present invention, the distance between the lenses is predetermined while maintaining the state in which the optical axis of the first lens group and the remaining second lens group of the two lens groups are matched. And a zoom adjusting means having a moving means capable of continuously changing the distance between the lens and a predetermined distance between the lenses and a zoom adjusting member provided on the moving means and capable of adjusting to the predetermined distance between the lenses. Thus, fine adjustment can be made in the zoom range of telephoto shooting and wide-angle shooting. In addition, since the auto zoom function is not provided, power consumption is reduced, the apparatus configuration is simplified, and the size and weight can be reduced. Furthermore, since the device configuration is simple, the number of parts can be reduced, the cost can be reduced, the reliability can be increased, and the possibility of failure can be reduced.

  In addition, according to the small image pickup module of the present invention, an adjustment member that is connected to the zoom adjustment member provided in the moving unit and is movable on the guide surface while being in contact with the guide surface of the guide portion is provided. When the user operates the adjustment member and adjusts the focal length by moving the guide member through the zoom adjustment member, the force that the adjustment member receives is adjusted. Is received by the guide surface of the guide section. For this reason, the force transmitted to the zoom adjusting member and the moving means out of the force acting on the adjusting member becomes small, and the force acting on the zoom adjusting member and the moving means becomes weak. Thereby, deformation of the zoom adjusting member and the moving means due to the force acting on the adjusting member is suppressed, the focal length can be adjusted continuously and stably, and durability can be improved. Further, the small imaging module has a lens diameter of about 6 mm and may be damaged even with a small force by a normal operation. In the present invention, since the force acting on the zoom adjusting means and the moving means during operation can be reduced, damage to the zoom adjusting member and the moving means can be suppressed, and durability can be increased.

Hereinafter, a small imaging module of the present invention will be described in detail based on a preferred embodiment shown in the accompanying drawings.
FIG. 1 is a schematic perspective view showing a mobile phone with a photographing function in which a small imaging module according to an embodiment of the present invention is incorporated. FIG. 2 is a block diagram showing the configuration of the mobile phone with a photographing function of the present embodiment. FIG. 3 is a schematic cross-sectional view showing the small imaging module of the present embodiment.

  As shown in FIG. 1, the mobile phone 10 with a photographing function includes a lower half 12 and an upper half 14, and the lower half 12 and the upper half 14 are relatively movable via a hinge. Is attached.

  A circular protective glass 18 is provided on the surface 14 a of the upper half 14. As shown in FIG. 3, the protective glass 18 is fitted into an opening 16 a formed in the frame 14 b of the lower half 14. A through hole 16b is formed in communication with the opening 16a. The small imaging module 20 is disposed in the center of the through-hole 16b so that the optical axis C coincides. The protective glass 18 protects the small imaging module 20.

  Further, as shown in FIG. 1, a guide groove 168 cut out in an arc shape is formed on the surface 14 a of the upper half 14 along the edge of the protective glass 18, and the guide groove 168 moves in the guide groove 168. An adjustment knob (adjustment member) 150 is provided as possible.

  As shown in FIG. 2, the mobile phone 10 with a photographing function basically includes a small imaging module 20, an A / D converter 22, a control unit 24, a display unit 26, an operation unit 28, an audio processing unit 30, and a reception. A speaker 32, a transmission microphone 34, a communication unit 36, an antenna 38, a memory 40, a media drive 42, and an external interface (hereinafter referred to as an external I / F) 44 are included.

In the lower half 12, a control unit 24, an operation unit 28, a communication unit 36, an antenna 38, an audio processing unit 30, a transmission microphone 34, a memory 40, a media drive 42, and an external I / F 44 are provided.
The upper half 14 is provided with a small imaging module 20, a display unit 26 for displaying characters and images, and a reception speaker 32.

  The small imaging module 20 collects reflected light from a subject to form an image of the subject, and an imaging element that outputs an image signal of the subject image formed by the imaging lens 200 as an analog signal. 62, which will be described later in detail.

  The A / D converter 22 converts an image signal of a subject image captured by the small imaging module 20 (imaging device 62) into a digital signal.

  The control unit 24 performs setting of the telephone mode or display control of the display unit 20, other various calculations, control of each unit, and autofocus control.

  The display unit 26 includes a liquid crystal display panel or an organic EL panel for displaying characters, captured images, and various processing screens.

  The operation unit 28 has input means for inputting a number such as a telephone number, inputting characters for inputting mail characters, and various settings of the telephone. The operation unit 28 includes buttons for various operations, a menu button for switching functions, a click button to which a predetermined function is assigned, a power button for turning on / off the power, and other buttons such as a dial button. Have.

  The voice processing unit 30 is connected to the reception speaker 32 and the transmission microphone 34, converts the voice input from the transmission microphone 34 into voice information, and outputs the voice information from the reception speaker 32 as voice.

The communication unit 36 modulates audio information input from the transmission microphone 34 and converted by the audio processing unit 30 and an image signal obtained by the small imaging module 20 into a radio signal.
The antenna 38 is connected to the communication unit 36, and transmits audio information and image information modulated by the communication unit 36 into a radio signal.

The memory 40 stores various data such as image information obtained by the small imaging module 20 and telephone setting information.
The media drive 42 is loaded with a recording medium such as a memory card, and writes various information stored in the memory 40 to the memory card and reads information stored in the memory card. The read information is written into the memory 40 by the control unit 24.

  The external I / F 44 is connected to a data output cable in order to output various data such as image information obtained by the small imaging module 20 and telephone setting information to an external device. The image information obtained by the small imaging module 20 recorded in the memory 40 and the setting information of the telephone by the operation of the operation unit 28 by the user is passed through a cable connected to the external I / F 44, and the personal computer or printer Output to external devices.

Next, the small imaging module 20 of the present embodiment will be described in detail based on FIGS.
As shown in FIG. 3, the small imaging module 20 includes a substrate 50, a lens barrel 52, a moving unit 54, an imaging lens 200, and an AF mechanism 90 that controls the imaging lens 200 to be in focus. It is.

  A lens barrel 52 is placed on the substrate 50, and a moving portion 54 is provided on the lens barrel 52 so as to be movable in a direction parallel to the optical axis C (hereinafter referred to as the optical axis C direction). In the mobile phone 10 with a photographing function (small imaging module 20) of the present embodiment, the moving unit 54 moves in the direction of the optical axis C with respect to the substrate 50, so that telephoto photographing or wide-angle photographing can be performed.

  More specifically, the small imaging module 20 includes an imaging unit 60 provided on the substrate 50, an imaging lens 200 provided on the moving unit 54 and the lens barrel 52, and an AF that automatically adjusts the focus of the imaging lens 200. A mechanism 90 and zoom adjustment means are included. This zoom adjusting means has a moving part 54 and moving means for moving the moving part 54.

  In the present embodiment, the imaging lens 200 includes, for example, four lenses, a lens 202 to a lens 208. The lenses 202 to 208 are all aspherical lenses. In the present embodiment, the lenses 202 to 208 are not limited to aspherical lenses, and any of spherical lenses, aspherical lenses, partially spherical lenses, and partially spherical lenses are used as appropriate. be able to.

  In the present embodiment, the lens 202 (first lens group) is provided in the moving unit 54 (first holding unit) and moves in the direction of the optical axis C. The lens 204 (second lens group) is fixed to the lens barrel 52 (second holding unit). Further, as will be described later, the lens 206 and the lens 208 are fitted lens groups, and are provided in the lens barrel 52. The positions of the lenses 206 and 208 are changed by the AF mechanism 90. In the present embodiment, zoom adjustment is performed by changing the distance between the two lenses of the lens 202 and the lens 204. In addition, the zoom adjustment unit of the present embodiment changes the distance between the two lenses, the lens 202 and the lens 204, within a predetermined range.

Note that the imaging lens 200 is not limited to four, but can be changed as appropriate according to the size of the apparatus and the required image quality.
In the present embodiment, zoom adjustment is performed by adjusting the distance between two lenses, one lens 202 and one lens 204, but the present invention is not limited to this. In the present embodiment, for example, at least one of the lens 202 and the lens 204 may be a lens group including a plurality of lenses. This lens group may be a combined lens in which a plurality of lenses are combined.
Further, the zoom adjusting means is not limited to the one that adjusts the distance between the two lenses of the lens 202 and the lens 204, but is one that adjusts the distance between the lenses of three or more lenses or lens groups. May be.

The board | substrate 50 is comprised by FPC (flexible printed circuit board), for example.
The imaging unit 60 includes an image sensor 62, an infrared cut filter 64, and a holding unit 68.

For example, a CCD image sensor (hereinafter referred to as a CCD sensor) is used as the imaging element 62. In the imaging element 62 (CCD sensor), a light receiving region (not shown) in which light receiving portions (not shown) constituted by, for example, photodiodes are arranged in a grid is formed on a chip (not shown). It has been done. In addition, an amplifier (not shown) and an A / D converter 22 (see FIG. 2) are formed on the chip. Further, what is necessary for configuring a CCD sensor such as a shift register is a light receiving region. It is formed around
The image sensor 62 is connected to the substrate 50 by, for example, bonding wires 62a. Note that the image sensor 62 is not limited to a CCD sensor, and may be a CMOS sensor.

  A holding portion 68 is formed on the surface of the substrate 50 so as to cover the entire surface of the image sensor 62. The holding unit 68 holds the image sensor 62 together with the infrared cut filter 64 on the substrate 50.

An opening 68 a is formed in the holding portion 68 at a portion corresponding to the upper side of the image sensor 62. An infrared cut filter 64 is provided below the opening 68a. The infrared cut filter 64 blocks the infrared component of the light incident on the image sensor 62. In this way, the image sensor 62 is sealed by the holding portion 68.
A flange portion 68 b is formed on the outer peripheral edge of the holding portion 68. The flange portion 68b and the end surface of the lens barrel 52 are matched.

  The lens barrel 52 includes a cylindrical first cylindrical portion 70 connected to the photographing unit 60 and a cylindrical second cylindrical portion 72 formed continuously with the first cylindrical portion 70. It consists of. The second cylinder part 72 has a smaller diameter than the first cylinder part 70. Further, a shoulder portion is formed at a connection portion with the first tube portion 70, and a flange portion 72b is formed at the shoulder portion. Further, a support portion 74 is formed inside the connection portion between the first tube portion 70 and the second tube portion 72.

  The support portion 74 supports the lens 204, and an opening 74 a is formed at the center position of the first tube portion 70. Moreover, the upper surface 74b of the support part 74 is formed in the horizontal surface, and the side wall 76 perpendicular | vertical with respect to this upper surface 74b is formed. The side wall 76 matches the outer shape of the lens 204. A concave portion 204a is formed on the upper surface of the lens 204, and a diaphragm 88 is provided in the concave portion 204a. The diaphragm 88 has an opening (aperture) 88a formed at the center thereof.

  Further, the inside of the distal end portion of the second cylindrical portion 72 is a smooth surface. The smooth surface of the second cylindrical portion 72 is aligned with the outer surface (smooth surface) of the annular member 108 provided on the zoom adjustment member 130 of the moving unit 54 described later, and the smooth surfaces slide with each other.

In addition, a lens 206 and a lens 208 are disposed inside the first cylindrical portion 70, and the lenses 206 and 208 are moved by the AF mechanism 90 so that the imaging lens 200 is in focus.
The AF mechanism 90 includes a main guide 92, a driving coil 94, a coil spring 96, a sub guide 98, and a sensor 102. The driving coil 94 and the sensor 102 are connected to the control unit 24 (see FIG. 2). . The AF mechanism 90 drives the driving coil 94 based on the output of the image sensor 62 and the position of the sensor 102 to focus. The main guide 92 is magnetized.

  A first fixing hole 78 a and a second fixing hole 78 b are formed on the lower surface 74 c of the support portion 74 so as to face each other in the diameter direction of the first cylindrical portion 70. The first fixing hole 78a is formed with a spring accommodating hole 80 whose diameter is increased.

  The first fixing hole 78a is where the main guide 92 is attached. The spring housing hole 80 houses a coil spring 96. In addition, the second fixing hole 78b is where the sub guide 98 is attached.

  A concave portion 206 a is formed on the lower surface of the lens 206. The concave portion 206 a is fitted to the outer peripheral portion of the lens 208. The lens 206 and the lens 208 form a combined lens. Thus, by fitting and assembling the lens 206 and the lens 208, the optical axis C can be made to coincide with each other without any inter-lens eccentricity, and positioning in the direction of the optical axis C can also be performed. it can. Therefore, the lens 206 and the lens 208 can be positioned in the optical axis C direction while suppressing the eccentricity between the lenses without depending on the lens barrel 52.

Here, FIG. 4 is a schematic plan view showing the lens 206 of the present embodiment.
As shown in FIG. 4, a first attachment portion 210 and a second attachment portion 212 are formed on the outer edge portion of the lens 206 so as to face each other in the diameter direction of the lens 206.

As shown in FIG. 3, a recess 210 b is formed on the lower surface of the first mounting portion 210. A through-hole 210a that penetrates the bottom of the recess 210b is formed.
The main guide 92 is inserted through the through hole 210a and the recess 210b. In addition, a coil spring 96 is fitted in the main guide 92 protruding from the upper surface of the first mounting portion 210. The coil spring 96 biases the lens 206 and the lens 208 toward the image sensor 62.

In addition, a part of the driving coil 94 is accommodated in the concave portion 210 b, and the driving coil 94 is provided so as to surround the main guide 92.
The main guide 92 and the driving coil 94 constitute a voice coil motor. When a current is applied to the driving coil 94, an upward force is applied, and the lenses 206 and 208 can be moved upward against the urging force of the coil spring 96. By changing the current applied to the driving coil 94, the positions of the lenses 206 and 208 can be changed.

On the other hand, as shown in FIG. 4, the second mounting portion 212 has a notch 212a, and the sub guide 98 is attached to the notch 212a.
Further, as shown in FIG. 3, the light shielding member 100 is attached to the outside of the sub guide 98 in the notch portion 212 a, and the light shielding member 100 moves in the direction of the optical axis C together with the lens 206. Further, in a state where the lens 206 is attached to the main guide 92 and the sub guide 98, the position detection sensor 102 is fixed at a position where the opening of the notch portion 212a faces the inner wall of the first cylindrical portion 70. The position detection sensor 102 is configured by, for example, a transmissive photo interrupter.

  For example, when the position detection sensor 102 includes a transmissive photo interrupter, the light shielding member 100 is disposed between the light receiving element and the light emitting element. When the light blocking member 100 moves in the optical axis C direction together with the lens 204, the oblique light position in the position detection sensor 102 changes. This change is output to the control unit 24 (see FIG. 2) as an output signal of the position detection sensor 102. As described above, the positions of the lens 206 and the lens 208 are specified by the output signal of the position detection sensor 102.

  In the present embodiment, when the small imaging module 20 is activated, for example, when the mobile phone is set to the shooting mode, the AF mechanism is set so that the position detection sensor 102 always has a preset initial position. 90.

  In the present embodiment, the autofocus of the small imaging module 20 uses, for example, a contrast method that detects and focuses the state where the contrast of the image obtained by the imaging element 62 is the strongest. In this case, based on the output of the image sensor 62 and the output of the position detection sensor 102, the lens 206 and the lens 208 are moved by the driving coil 94 so that the contrast of the obtained image becomes the strongest. In this way, the focus is adjusted automatically. As a result, when the lens-to-lens distance between the lens 202 and the lens 204 is changed, only the lens 206 and the lens 208 are driven by the driving coil 94 while maintaining the adjusted lens-to-lens distance between the lens 202 and the lens 204. , And the image is automatically focused and an in-focus image can be obtained.

  The moving unit 54 changes the inter-lens distance between the lens 202 provided inside and the lens 204 provided in the lens barrel 52, and plays a role of a zoom function. The moving unit 54 includes a zoom adjustment member 130 that adjusts the contact length between the smooth surface of the lens barrel 52 and the smooth surface of the zoom adjustment member 130 that slides, that is, the inter-lens distance. The zoom adjustment member 130 performs zoom adjustment of the small imaging module 20.

The zoom adjustment member 130 has a vertical side wall 130b erected along the outer edge of the disk, and a circular opening for applying light to the image sensor 62 is provided at the approximate center of the surface 134a of the disk. A portion 106 is formed.
An annular member 108 is provided on the rear surface of the zoom adjustment member 130 so as to surround the opening 106. The outer peripheral surface of the annular member 108 is a smooth surface. A lens 202 is provided in the inside 112 of the annular member 108.

  Further, the outer peripheral surface of the annular member 108 is aligned with the smooth surface at the tip of the second cylindrical portion 72, and the moving portion 54 and the lens barrel 52 slide with the smooth surfaces in contact with each other. In the present embodiment, the distance between the lenses 202 and 204 can be continuously and continuously changed by adjusting the contact length between the smooth surfaces. Thereby, zoom can be continuously adjusted steplessly within the range of wide-angle shooting to telephoto shooting.

  A space 136 is formed between the side wall 130 b and the second cylindrical portion 72. A coil spring 138 is accommodated in the space 136. By this coil spring 138, the lens barrel 52 and the moving part 54 are urged in directions away from each other.

Further, on the outer periphery of the zoom adjustment member 130, a moving unit 140 constituting a cam mechanism is provided. The moving unit 140 includes a cylindrical member 142, a contact member 144, and a cylindrical cam 148 to which a lever 146 is integrally attached.
The cylindrical member 142 is provided on the outer peripheral surfaces of the lens barrel 52 and the zoom adjusting member 130. The lens barrel 52 is movable in the optical axis C direction with respect to the cylindrical member 142.
A contact member 144 is provided at the lower end of the cylindrical member 142. The contact member 144 has a slope with a predetermined slope, and the slopes 144a and 144b of the contact member 144 have different heights.

  A cylindrical cam 148 is provided between the flange portion 72 b of the lens barrel and the contact member 144. The cylindrical cam 148 can be rotated by a lever 146.

Further, the lever 146 is connected to the adjustment knob 150 via the connection pin 152.
Further, in the mobile phone 10 with a photographing function of the present embodiment, a guide portion 160 is formed on the back surface 14c of the lower half 14 on which the small imaging module 20 is provided. The guide unit 160 guides an adjustment knob 150 for adjusting the distance between the lenses of the small imaging module 20.

  The guide portion 160 is formed by projecting a part of the frame 14b of the lower half 14 from the front surface 14a side to the back surface 14c in a concave shape. The guide portion 160 is constituted by a guide frame 162. As shown in FIG. 1, the guide frame 162 is formed to extend in an arc shape along the peripheral edge of the protective glass 18.

  The guide frame 162 has a notch 164 a facing the surface 14 a of the lower half 14. A cover 154 is attached to the notch 164a so as to close the opening of the guide frame 162. The cover 154 has a first guide hole 154a. The first guide hole 154 a is formed to extend in an arc shape along the peripheral edge of the protective glass 18, similarly to the guide frame 162.

Further, a second guide hole 166 is formed on the bottom surface 164b of the guide frame 162 at a position aligned with the first guide hole 154a. A bottom surface 164b of the guide frame 162 serves as a guide surface (guide surface).
In the present embodiment, the adjustment knob 150 is disposed in a guide groove 168 formed by being surrounded by the cover 154 and the guide frame 162.

The adjustment knob 150 includes a base portion 150a and a flange portion 150b formed around the lower portion of the base portion 150a. The base 150a protrudes from the first guide hole 154a. The flange portion 150 b is disposed in the guide groove 168, and the circumferential surface thereof is regulated by the side surface 164 c of the guide frame 162.
The base 150a is formed with a connecting portion 150c to which the connecting pin 152 is inserted and connected.
The lower surface 150d of the adjustment knob 150 contacts the guide surface (bottom surface 164b), and the lower surface 150d and the bottom surface 164b slide to guide the adjustment knob 150 on the bottom surface 164b.

  In the small image pickup module 20 of the mobile phone 10 with a photographing function according to the present embodiment, the user moves the adjustment knob 150 along the guide groove 168, whereby the lever 146 is rotated via the connection pin 152, and comes into contact. The height of the cam surface of the cylindrical cam 148 with which the member 144 abuts can be changed, and the distance between the lens 202 and the lens 204 can be changed. That is, zoom adjustment can be performed.

In the present embodiment, for example, the connection pin 152 is inserted into the second guide hole 166, and the protruding portion of the connection pin 152 is inserted into the connection portion 150c of the adjustment knob 150, so that the adjustment knob 150 and the connection pin 152 are inserted. And the lever 146 and the adjustment knob 150 are connected.
As described above, after the adjustment knob 150 is disposed inside the guide frame 162, the cover 154 is attached to the notch 164a. Thereby, the base 150a of the adjustment knob 150 protrudes from the first guide hole 154a. In the present embodiment, the adjustment knob 150 can be slid along the guide groove 168 with the base portion 150a of the adjustment knob 150 protruding from the first guide hole 154a. The cover 154 and the lower half 14 are flush with each other.

Next, the operation of the small imaging module 20 attached to the mobile phone 10 with a photographing function of the present embodiment will be described.
In the present embodiment, first, the user operates the operation unit 28 of the mobile phone 10 with the photographing function to enter the photographing mode. When the user sets the photographing mode, the control unit 24 applies a current to the driving coil 94, and the lenses 206 and 208 are moved to the initial positions.

  Next, the imaging lens 200 of the small imaging module 20 of the cellular phone 10 with the imaging function is directed toward the subject. Next, the focus (focus) is automatically adjusted by the AF mechanism 90.

  In the present embodiment, image information of an image obtained by the image sensor 62 is stored in the memory 40, and the control unit 24 calculates contrast from the image information. At this time, the positions of the lens 206 and the lens 208 are also specified by the control unit 24.

Next, it is determined whether or not the contrast of the obtained image is the strongest. If the contrast is not the strongest, the control unit 24 applies a current to the driving coil 94 to move the lenses 202 and 208. .
Next, the contrast of the image obtained by the image sensor 62 is calculated again, and it is determined whether or not the contrast is strongest, that is, whether or not the focus is in focus.
Thus, until the state in which the contrast of the image is the strongest is detected, the calculation of the contrast, the position detection of the lenses 206 and 208 by the position detection sensor 102, and the movement of the lenses 206 and 208 by the driving coil 94 are repeated. Focus.

  Further, in the small imaging module 20 of the mobile phone 10 with the imaging function of the present embodiment, the state shown in FIG. 3 is shown in FIG. 5 from the state most suitable for telephoto shooting when the user moves the adjustment knob 150. The distance between lenses can be continuously and continuously adjusted within a range suitable for wide-angle shooting. That is, zoom adjustment can be performed continuously and continuously.

  In the present embodiment, the state shown in FIG. 3 is the maximum telephoto state of the small image pickup module 20. From this state, the adjustment knob 150 is moved along the guide groove 168, and the lever 146 is rotated clockwise. As a result, the height of the cam surface of the cylindrical cam 148 with which the contact member 144 contacts gradually decreases, and the lens barrel 52 is urged downward by the coil spring 138, so that the lens barrel 52 moves downward. As a result, the distance between the lens 202 and the lens 204 increases, and the compact imaging module 20 shown in FIG.

  On the other hand, when the adjustment knob 150 is moved along the guide groove 168 from the state shown in FIG. 5 and the lever 146 is rotated in the counterclockwise direction, the height of the cam surface of the cylindrical cam 148 with which the contact member 144 abuts. However, the lens barrel 52 is lifted by the cylindrical cam 148 and the contact member 144, and the distance between the lens 202 and the lens 204 becomes the shortest, and the maximum telephoto state shown in FIG. 3 is obtained. .

Further, in this embodiment, by moving the adjustment knob 150 along the guide groove 168, the position of the lever 146 is changed, the height of the cam surface is changed, and the distance between the lens 202 and the lens 204 is continuously reduced. The distance between the lenses can be adjusted to a predetermined distance. As described above, the user can adjust the distance between the lenses by moving the adjustment knob 150 along the guide groove 168. That is, zoom adjustment can be performed. Even when the zooming is performed and the shooting state is changed, the lens 206 and the lens as described above are used by the AF mechanism 90 in a state where the zoom is adjusted, that is, in a state where the distance between the lens 202 and the lens 204 is maintained. The position 208 is adjusted and the focus is automatically adjusted.
Thus, in the present embodiment, by adjusting the adjustment knob 150 along the guide groove 168, it is possible to obtain an in-focus image intended by the user.

In the small imaging module 20 of the present embodiment, the zoom knob 150 is configured to simply move the adjustment knob 150 along the guide groove 168, and an auto zoom mechanism is not provided, so that power consumption is reduced. In addition, the apparatus configuration is not complicated, the apparatus configuration can be simplified, and the apparatus can be reduced in size and weight. As a result, the apparatus cost can be reduced. Furthermore, since the structure can be simplified, the reliability can be increased and the possibility of failure can be reduced.
In addition, since the small imaging module of the present invention can be reduced in size and weight, when incorporated in a mobile phone, the mobile phone can also be reduced in size and weight.

  Further, in the small imaging module 20 of the present embodiment, the adjustment knob 150 is disposed on the bottom surface 164b (guide surface). Therefore, when the adjustment knob 150 is moved along the guide groove 168, the force acting on the adjustment knob 150 is received by the bottom surface 164b, so that the force acting on the lever 146 via the connection pin 152 can be reduced. For example, when a vertical force acts on the adjustment knob 150, the bottom surface 164b of the guide frame 162 and the lower surface 150d of the adjustment knob 150 come into contact with each other. The guide frame 162 receives a vertical force on the adjustment knob 150. For this reason, the force which acts on the connection pin 152 is reduced. Thereby, the bending moment acting on the lever 146 is reduced, and the contact pressure between the cylindrical cam 148 and the contact member 144 does not become higher than necessary. Therefore, the adjustment knob 150 can be stably slid and zoomed, and the durability of the small imaging module 20 can be increased.

  In the present embodiment, the case where the small imaging module 20 is provided in the mobile phone has been described as an example. However, the present invention is not limited to this, and can be applied to a PDA. Needless to say, the same effect as that of the embodiment can be obtained.

  The small imaging module of the present invention has been described above. However, the present invention is not limited to the above-described embodiment, and various improvements or modifications may be made without departing from the gist of the present invention. It is.

1 is a schematic perspective view showing a mobile phone with a photographing function in which a small imaging module according to an embodiment of the present invention is incorporated. It is a block diagram which shows the structure of the mobile telephone with an imaging | photography function of this embodiment. It is a typical sectional view showing the small image pick-up module of this embodiment. It is a typical top view which shows the lens of this embodiment. It is typical sectional drawing which shows the state which moved the moving part of the small imaging module of this embodiment shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Cellular phone with photographing function 12 Lower half 14 Upper half 20 Small imaging module 22 A / D converter 24 Control unit 26 Display unit 28 Operation unit 30 Audio processing unit 32 Reception speaker 34 Transmission microphone 36 Communication unit 38 Antenna 40 Memory 42 Media Drive 44 External interface (external I / F)
DESCRIPTION OF SYMBOLS 50 Board | substrate 52 Lens tube 54 Moving part 60 Image pick-up part 62 Image pick-up element 64 Infrared cut filter 68 Holding part 90 Autofocus mechanism (AF mechanism)
92 Main guide 94 Driving coil 96 Coil spring 98 Sub guide 102 Position detection sensor 106 Zoom adjustment member 140 Moving part 142 Cylindrical member 144 Abutting member 146 Lever 148 Cylindrical cam 150 Adjustment knob 152 Connection pin 154 Cover 160 Guide part 162 Guide frame 162b Bottom (guide surface)
168 Guide groove 200 Imaging lens 202, 204, 206, 208 Lens C Optical axis

Claims (2)

A small imaging module having a zoom adjustment means for changing a distance between lenses of at least two lens groups within a predetermined range,
The zoom adjusting unit includes a first holding unit that holds a first lens group of the two lens groups, and a second holding unit that holds the remaining second lens group of the two lens groups. A holding portion, and the first holding portion and the second holding portion are provided such that the optical axes of the first lens group and the second lens group coincide with each other,
Further, the zoom adjusting means continuously changes the inter-lens distance within a predetermined range while maintaining the state in which the optical axes of the first lens group and the remaining second lens group are matched. And a moving means capable of maintaining a predetermined distance between the lenses,
A zoom adjusting member that is provided in the moving means and adjusts to a predetermined distance between the lenses;
Furthermore, a guide part provided with a guide surface;
An adjustment member connected to the zoom adjustment member and movable on the guide surface while abutting on the guide surface of the guide portion;
A small imaging module characterized in that a predetermined inter-lens distance is provided by the adjustment member via the zoom adjustment member.   The moving means includes a cylindrical cam mechanism, and the zoom adjustment member is a lever provided in the cylindrical cam mechanism, and the adjustment member and the lever are connected via a connection pin. Item 2. The small imaging module according to Item 1.

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