KR101493697B1 - Image sensor module and digital camera comprising the same - Google Patents

Abstract

In order to improve image quality by reducing deviation between image sensors by adopting image sensors of different sizes in the same one barrel structure, there is no need to employ a dedicated barrel structure for each image sensor of different sizes. (Ii) an image sensor plate on which the image sensor is mounted; (iii) an image sensor for converting an image of the subject incident on the image-forming surface into an image information; A lens base on which the image sensor plate is mounted, and (iv) first and second lens holders each for fixing the position in the first and second axial directions on a plane parallel to the image sensor surface of the image sensor with respect to the lens base, An image sensor module including a second position fixing means, and a digital camera including the same.

Digital camera, image sensor module, image sensor, center position

Description

The present invention relates to an image sensor module and a digital camera having the same,

The present invention relates to an image sensor module and a digital camera having the image sensor module. More particularly, the present invention relates to an image sensor module in which a lens barrel having a lens base on which an image sensor plate is mounted, And a digital camera having the same.

Digital cameras are image taking devices that use image sensors such as CCD and CMOS instead of film. Digital cameras are widely used because they are strong against noise, can reproduce high-quality signals at low prices, can miniaturize image storage media, and can reduce volume.

If the position of the image plane of the image sensor or the image plane in which the focal point is formed changes in the lens barrel of the digital camera, the image quality will be deteriorated. Therefore, in order to prevent deterioration of the image quality, the position of the image surface of the image sensor in the barrel or the position of the image plane must be constant. In order to achieve this, conventionally, only one type of image sensor is used for one barrel to manage the assembly reference plane.

As the size and thickness of the digital camera become smaller, the overall size and volume of the lens barrel must be reduced as well, so that the size of the image sensor is diversified and becoming smaller. Therefore, there is an increasing demand for a barrel structure capable of mounting various types of image sensors without changing the design of the barrel structure.

On the other hand, as the size and thickness of the image sensor become smaller, the size and thickness of the image sensor become various. In order to prevent deterioration of the image quality, the position of the image surface of the image sensor in the barrel or the position of the image plane must be constant. For this purpose, a dedicated image sensor plate is attached to each image sensor to compensate for the size and thickness of the different image sensors.

However, in order to employ various types of image sensors of different sizes without changing the design of a single barrel structure, the reference surfaces must be formed on the barrel structure based on the largest image sensor. Since the assembly reference surface is formed on the basis of the image sensor having the largest size, when the image sensor of this size is employed, the center position decentering or tilt of the image sensor according to the assembly does not occur. However, when an image sensor having a smaller size is used, since the assembly reference plane can not be used, the center position of the image sensor is likely to be displaced or tilted. Thereby, the image quality of the image is deteriorated.

The present invention eliminates the inconvenience of adopting a dedicated barrel structure for each of image sensors of different sizes, and adopts image sensors of different sizes in the same one barrel structure to reduce the deviation between image sensors, A sensor module, and a digital camera having the sensor module.

According to an aspect of the present invention, there is provided an image sensor including: (i) an image sensor for converting light representing an image of an object incident on an image-forming surface into image information; (ii) Plate, (iii) a lens base on which the image sensor plate is mounted such that an image forming surface of the image sensor is exposed through an opening, and (iv) a lens base on a plane parallel to the image sensor surface of the image sensor with respect to the lens base. An image sensor module including first and second position fixing means for fixing positions in the first and second axial directions, respectively.

And a portion formed by the first inner surface and the second inner surface of the lens base and the first corresponding surface and the second corresponding surface opposing the first and second inner surfaces is an escape portion, The escaping portion of the lens base is arranged such that the side of the image sensor plate among the image sensor plates on which the image sensors of different sizes are respectively mounted is the side surface of the first inner surface, the second inner surface, the first corresponding surface, As shown in Fig. Therefore, in the case of adopting the largest image sensor, the center position of the image sensor in the first axis direction and the second axis direction can be kept constant so as not to be separated without the aid of the first and second position fixing means.

Wherein the first position fixing means brings the first side of the image sensor plate facing in the first axis direction and the first inner side of the opening of the lens base into close contact with each other, The second side surface of the image sensor plate and the second side surface of the opening of the lens base are brought into close contact with each other.

The first side of the image sensor plate on which the image sensor of the small size is mounted is fixed by the first position fixing means to the image sensor plate on which the small size image sensor is mounted when the image sensor of the size smaller than that of the largest image sensor is used, The second side of the image sensor plate on which the small size image sensor is mounted is brought into close contact with the second inner side surface by the second position fixing means. Accordingly, even when an image sensor having a size smaller than the size of the escape portion formed in the opening of the lens base is employed, the center position of the image sensor in the first axis direction and the second axis direction can be kept constant.

The first position fixing means includes: (i) a first image sensor plate boss formed on the image sensor plate, (ii) a first lens base boss formed on the lens base to correspond to the first image sensor plate boss, and Iii) one end fixed to the first image sensor plate boss, the other end fixed to the first lens base boss, and the first side of the first image sensor plate and the first inner side of the lens base (Ii) a second image sensor plate boss formed on the image sensor plate, (ii) a second image sensor plate boss formed on the image sensor plate so as to correspond to the second image sensor plate boss, and A second lens base boss formed on the lens base, and (iii) one end fixed to the second image sensor plate boss, And elastic means fixed to the second lens base boss and providing an elastic force such that the second side of the second image sensor plate and the second inner side of the lens base are in contact with each other.

Wherein the image sensor plate is mounted on the lens base by a screw fastened in a third axial direction orthogonal to the first and second axial directions, and the image sensor plate is mounted on the lens base in the third axial direction The alignment position is determined by fastening the screw.

According to another aspect of the present invention, there is provided an image sensor comprising: (i) an image sensor for converting light representing an image of an object incident on an image-forming surface into image information; (ii) (Ii) a lens base on which the image sensor plate is mounted so that the image plane of the image sensor is exposed through the opening, (iv) a lens base on the plane parallel to the image sensor surface of the image sensor with respect to the lens base in the first and second axial directions (Vi) an optical system for causing light representing an image of a subject to be formed on the image-forming surface of the image sensor, (vi) an optical system for controlling the optical system and the image sensor, And a central operation control unit for acquiring and outputting image information corresponding to the image information.

Since the image sensor module and the digital camera having the same according to the embodiment of the present invention can employ image sensors having different sizes in the same one barrel structure, the deviation between the image sensors can be reduced to improve the image quality. Also, there is no need to use a dedicated barrel structure for each image sensor.

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

The internal structure of a digital camera according to an embodiment of the present invention will be described with reference to FIG.

An image pickup apparatus according to an embodiment of the present invention includes an optical system 102, drivers 104, 106 and 108, a timing control unit 110, an image sensor 112, a correlated double sampling (CDS) An A / D converter 116, an image input control unit 118, a central operation control unit 120, an operation unit 122, an image signal processing unit 124, a video random access (VRAM) A memory 126, a compression processing unit 128, a memory 130, a display unit 132, an LCD (Liquid Crystal Display) driver 134, a recording media control unit 136, and a recording medium 138 .

The optical system 102 causes the image sensor 112 to image the light representing the image of the object through the lens. The driver 104 drives the zoom mechanism of the optical system 102. The driver 106 drives the diaphragm mechanism of the optical system 102. The driver 108 drives the focus mechanism of the optical system 102. The timing control unit 110 controls the exposure period and the charge reading by each pixel constituting the image sensor 112. [ The image sensor 112 is constituted by elements capable of photoelectric conversion, and each element generates an electric signal in accordance with the light received. The CDS / AMP 114 removes the low frequency noise included in the electric signal obtained from the CCD 112 and amplifies the electric signal to a certain level. The A / D converter 116 converts the analog electric signal into a digital signal. The image input control unit 118 receives the operation command from the central operation control unit 120 and performs the operations of the image sensor 112, the CDS / AMP 114 and the A / D conversion unit 116 related to the input of the image . The operation unit 122 is composed of a power switch, a mode switching unit, a shutter button, and the like, and is used by a user to set a shutter speed, an ISO sensitivity, and the like. The image signal processing unit 124 calculates an evaluation value of the exposure amount set by automatic exposure control (AE) and calculates an evaluation value of the focal distance set by auto-focus (AF).

The VRAM 126 is constituted by a memory having a plurality of channels so as to simultaneously record the display image in the image display memory and display on the display section 132 at the same time. The compression processing unit 128 compresses the input image data in a format such as a JPEG compression format or an LZW compression format. The memory 130 may be constituted by a semiconductor storage element such as an SDRAM (Synchronous DRAM) and stores a high-speed shutter image photographed in a time-division manner. The synthesized image synthesized by the image signal processing unit 124 may be recorded, and the operation program of the central operation control unit 120 may be stored.

The display section 132 is constituted by display means such as an LCD and displays an image read from the VRAM 126. [ The LCD driver 134 drives the display unit 132 and controls the output of the display unit 132. [

The recording media control unit 136 controls recording of image data on the recording medium 138 or reading of image data and setting information recorded on the recording medium 138. [ The recording medium 138 is composed of an optical storage medium, a magneto-optical disk, a magnetic disk, or a semiconductor storage medium, and can record photographed image data. The recording medium 138 may be detachable from the image pickup apparatus.

Hereinafter, an image sensor module according to an embodiment of the present invention will be described. 2 and 3, it is assumed that the image sensor 1, 11 has a size enough to touch the assembly reference plane of the lens base 6, 16, The problem of position alignment of the image sensors 1 and 11 which may occur in the case of FIG.

2, both sides of the image sensor 1 in the Y-axis direction are located on the lens base 6 when the image sensor 1 has a size enough to touch the assembling reference surface of the lens base 6, Is mounted on the lens base (6) so as to be in contact with the assembly reference surface of the lens base (6). In this case, the buffer material 5 may be disposed on the upper surface of the image sensor 1 and the lens base 6. Both side surfaces of the image sensor 1 in the X-axis direction are also in contact with the assembly reference surface of the lens base 6, although they are not shown in the drawing. Thus, the image sensor 1 is prevented from being displaced relative to the lens base 6 in the Y-axis direction and the X-axis direction by the side surface of the image sensor 1 being in contact with the assembly reference surface of the lens base 6.

On the other hand, when the image sensor 11 having a size smaller than the size of the image sensor 1 shown in Fig. 2 is used, both side surfaces of the image sensor 11 in the Y- . On the other hand, the image sensor plate 14 on which the image sensor 11 is mounted can be engaged with the lens base 16 by screws 17. By screwing the screw 17 through the screw through hole 14a of the image sensor plate 14 and the corresponding screw hole of the lens base 16, the X-axis and Y-axis directions with respect to the lens base 16 The position of the image sensor plate 14 with respect to the image sensor is somewhat aligned but not accurately aligned. This is because the inner diameter of the through hole 14a of the image sensor plate is made larger than the outer diameter of the screw 17 for manufacturing tolerance so that the screw 17 can play in the through hole 14a. That is, the screwing of the image sensor plate 14 and the lens base 16 can align the position of the image sensor 11 in the Z-axis direction with respect to the lens base 16, The position of the robot does not play a role.

In order to overcome such a problem, the image sensor module according to the embodiment of the present invention shown in FIG. 4 is constructed such that even when different types of image sensors 11 having a small size are used, The image sensor 11, the image sensor plate 14, the lens base 16, and the first and second image sensor plates 14, 16, and 16 are disposed in the X- And position fixing means. Hereinafter, a case of using an image sensor 11 having a small size in the image sensor module according to an embodiment of the present invention will be described.

The image sensor 11 converts light representing an image of an object incident on the image-forming surface 11a into image information. Examples of the image sensor 11 include a charge coupled device (CCD) and a complementary metal oxidized semiconductor (CMOS). The image sensor 11 on which the cover glass 2 is formed is attached to a flexible circuit board (FPCB) 13. The image sensor 11 may be attached to the flexible circuit board 13 by means of a component seal or the like. The electrode pads of the image sensor 11 are electrically connected to the conductive pads of the flexible circuit board 13 so that the image sensor 11 is electrically connected to the other electric parts by the conductive lines of the flexible circuit board 13. [ Signals are exchanged.

An image sensor 11 attached to the flexible circuit board 13 is mounted on and supported by the image sensor plate 14. [ The image sensor plate 14 is attached to the rear side of the image sensor 11 when the direction in which the image forming surface 11a of the image sensor 11 is formed (the positive direction of the Z axis) The image sensor plate 14 is mounted on the lens base 16. The image sensor plate 14 is used exclusively for the image sensor 11. The image sensor plate 14 is provided with an assembly reference guide 14c protruding from at least one side S1a in the Y-axis direction so that the image sensor 11 can be seated. Although not shown in the drawing, an assembly reference guide (not shown) is formed so as to project at least on one side (not shown) in the X-axis direction. Alternatively, as shown in FIG. 5, the assembly reference guide portions 14c and 14d may be formed so as to protrude from both sides in the Y-axis direction. Similarly, an assembly reference guide (not shown) may be formed so as to protrude from both sides in the X-axis direction.

The lens base 16 is coupled to and supported by the lens barrel of the camera, and a rectangular opening is formed at the center of the lens base 16. The image sensor plate 14 is mounted so that the image forming surface 11a of the image sensor 11 is exposed forward through the opening. An escape portion is formed in the rear of the aperture (negative direction in the Z axis) of the image sensor plate. The inner surface in the Y axis direction of the escape portion is defined as a first inner surface S1a and a first corresponding surface S1b, The first inner side surface S1a of the escaping portion is an assembling reference surface for assembling and aligning the image sensor 11 in the Y-axis direction, and the second inner side surface and the second corresponding surface And the second inner side surface of the escape portion forms an assembling reference surface A2 for assembling alignment of the image sensor 11 in the X axis direction. The side of the largest image sensor 1 among the image sensor plates 14 on which the image sensors 11 are respectively mounted is a first inner side surface S1a of the escapement portion, a second inner side surface (not shown) (S1b) and the second corresponding surface (not shown).

On the other hand, the assembly reference guide portions 14c and 14d in the Y-axis direction are arranged such that the distance between the outer side surfaces of the assembly reference guide portions 14c and 14d is smaller than the distance between the first inner side surface S1a of the escaping portion of the lens base 16 Is equal to or smaller than the distance between the first corresponding surfaces (S1b). This is because the image sensor 11 and the image sensor plate 14 are not fitted to the opening side of the lens base 16 otherwise. For the same reason, the assembly reference guide portions (not shown) in the X-axis direction are arranged such that the distance between the outer surfaces of the assembly reference guide portions is larger than the distance between the second inner surface (not shown) (Not shown).

On the other hand, the lens base 16 and the image sensor plate 14 are provided with alignment pins 16a and alignment grooves (not shown) for easily indicating alignment positions when the image sensor plate 14 is assembled to the lens base 16. [ 14b may be respectively formed. Conversely, an alignment groove is formed in the lens base 16, and an alignment pin may be formed on the image sensor plate 14 at a position corresponding thereto. The alignment pins 16a formed at the positions to be aligned with each other are fitted into the alignment grooves 14b, thereby facilitating the alignment for assembly of the two parts. However, since the alignment pin 16a and the alignment groove 14b are not easily manufactured so as to fit accurately without gaps due to manufacturing tolerances, the outer diameter of the alignment pin 16a is smaller than the inner diameter of the alignment groove 14b It is generally designed to be slightly more compact.

To engage the image sensor plate 14 to the lens base 16, a threaded engagement can be used. However, since the position of the image sensor plate 14 with respect to the lens base 16 in the X-axis direction and the Y-axis direction is not accurately aligned, the position of the image sensor 11 It can be different. However, as mentioned above, the screwing between the image sensor plate 14 and the lens base 16 serves to align the position of the image sensor 11 in the Z-axis direction with respect to the lens base 16.

The first position fixing means includes a first image plate boss 14f, a first lens base boss 16b, and an elastic means 21.

The first image sensor plate boss 14f is formed to project perpendicularly to the surface of the image sensor plate 14. The first lens base boss 16b is formed to protrude perpendicularly to the surface of the lens base 16. The first lens base boss 16b and the first image sensor plate boss 14f are disposed substantially parallel to the X axis direction. Both ends of the first elastic means 21, for example, the coil spring are fitted to the first lens base boss 16b and the first image sensor plate boss 14f, respectively.

The first coil spring 21 is inserted into the first lens base boss 16b and the first image sensor plate boss 14f respectively in a state slightly elongated from the original shape so that the coil spring 21 is fixed to the image sensor plate 14 (The outer side surface of the first assembly reference guide portion 14c) of the lens base 16 is brought into close contact with the first inner side surface S1a of the lens base 16. In this embodiment, the coil spring is taken as an example of the first elastic means, but the protective scope of the present invention is not limited to this, and the first assembly reference guide portion 14c of the image sensor plate 14 may be provided on the lens base 16, Any one that applies a force to the first image sensor plate boss 14f and the first lens base boss 16b can be used as an elastic means in such a manner that the first image sensor plate boss 14f and the first lens base boss 16b are brought into close contact with the first inner side surface S1a.

Similarly, the second image sensor plate boss 14g is formed to protrude perpendicularly to the surface of the image sensor plate 14. The second lens base boss 16c is formed to protrude perpendicularly to the surface of the lens base 16. The second lens base boss 16c and the second image sensor plate boss 14g are disposed substantially parallel to the Y axis direction. Both ends of the second elastic means 22, for example, the coil spring are fitted to the second lens base boss 16b and the second image sensor plate boss 14g, respectively.

The second coil spring 22 is inserted into the second lens base boss 16c and the second image sensor plate boss 14g respectively in a state in which the second coil spring 22 is slightly elongated from the original shape, (Not shown) of the lens base 16 to the first inner surface S1a of the lens base 16. [

The first position fixing means fixes the position of the image sensor 11 with respect to the lens base 16 in the X-axis direction and the second position fixing means fixes the position of the image sensor 11 with respect to the lens base 16 in the Y- 11) is fixed. For example, the second position fixing means includes a first inner side surface of the image sensor plate 14 facing in the Y-axis direction, more specifically, an outer side surface of the assembly reference guide portion 14c, Tightly contact each other. Similarly, the first position fixing means includes a second inner side surface of the image sensor plate 14 facing in the X-axis direction, more specifically, an outer side surface of the assembly reference guide (not shown) .

That is, when the image sensor 11 having a smaller size than the largest image sensor 1 among the image sensors of different sizes is used, the first inner side surface of the image sensor plate 14 on which the small image sensor 11 is mounted The second inner surface of the image sensor plate 14 on which the small image sensor 11 is mounted is brought into close contact with the first fixing reference surface A1 of the lens base 16 by the first position fixing means, Is brought into close contact with the second assembly reference surface (A2) of the lens base (16).

The center of the image sensor 11 on the Y-axis and the Y-axis is moved from the optical axis to the reference plane of the lens base 16 by closely contacting the assembly reference guide portion of the image sensor plate 14 along the X- It is possible to prevent deviation and keep this state.

The description of the small-sized image sensor 11 described above applies equally to other small-sized image sensors. In this case, the assembly reference guides 14c (not shown) of the image sensor plate 14 manufactured and attached according to the size of the applied image sensor are fixed to the X axis and the Y So that the center of the image sensor 11 does not deviate from the optical axis by tightly contacting the first and second assembly reference surfaces A1 and A2 of the lens base 16 in the axial direction.

As described above, when the image sensor 1 having the largest size is employed, the X-axis and Y-axis side surfaces of the image sensor 1 are arranged in the X-axis and Y-axis directions The center of the image sensor 1 in the X-axis and Y-axis directions is maintained not to deviate from the optical axis, and when a small-sized image sensor 11 is employed The assembly reference guides 14c (not shown) of the image sensor plate 14 are fixed to the first and second assembly reference planes (not shown) of the lens base 16 in the X- and Y-axis directions by the first and second position fixing means A1 and A2, respectively, so that the center of the image sensor 11 does not deviate from the optical axis. Thereby, any one of the image sensors 11 and their dedicated image sensor plates 14 and their dedicated image sensor plates 14 can be employed in one and the same column.

The present invention can be used in industries that manufacture and use image sensor modules.

FIG. 1 is a block diagram schematically illustrating an internal configuration of a digital camera according to an embodiment of the present invention. Referring to FIG.

2 is a sectional view of the image sensor module in a case where the image sensor has a size enough to touch the assembly reference plane of the lens base.

3 is a cross-sectional view of the image sensor module when the image sensor has a size smaller than an assembling reference plane of the lens base.

4 is a cross-sectional view of an image sensor module according to an embodiment of the present invention in a case where the image sensor has a size smaller than an assembly reference plane of the lens base.

5 is a cross-sectional view taken along the line IV-IV of FIG.

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

1, 11: Image sensor 1a, 11a: Image plane

2, 12: Cover glass 3, 13: Flexible circuit board

4, 14: image sensor plate 4b, 14b: alignment hole

14c: first assembly reference guide section 6, 16: lens base

16a: alignment pin 17: screw

Claims (9)

An image sensor for converting light representing an image of a subject incident on the image-forming surface into image information; An image sensor plate on which the image sensor is mounted; A lens base on which the image sensor plate is mounted such that an image forming surface of the image sensor is exposed through an opening; And First and second position fixing means for respectively fixing positions in the first and second axial directions on a plane parallel to the image sensor surface of the image sensor with respect to the lens base, Wherein the first position fixing means closely contacts the first side face of the image sensor plate facing the first axis direction and the first inner side face of the opening of the lens base, And the second position fixing means brings the second side face of the image sensor plate facing in the second axial direction and the second inside face of the opening side of the lens base into close contact with each other. delete The method according to claim 1, When a portion formed by the first inner surface and the second inner surface of the lens base and the first corresponding surface and the second corresponding surface opposed to the first and second inner surfaces is referred to as an escape portion, Wherein the escape portion of the lens base has a side surface of the largest image sensor among the image sensor plates on which image sensors having different sizes are respectively mounted on the first inner surface, the second inner surface, the first corresponding surface, The image sensor module The method of claim 3, When an image sensor having a size smaller than that of the largest image sensor among the image sensors having different sizes is used, The first side of the image sensor plate on which the image sensor with the small size is mounted is brought into close contact with the first inner side surface by the first position fixing means, The second side of the image sensor plate on which the small size image sensor is mounted is brought into close contact with the second inner side surface by the second position fixing means. The method according to claim 1, Wherein the first position fixing means comprises: A first image sensor plate boss formed on the image sensor plate; A first lens base boss formed on the lens base to correspond to the first image sensor plate boss; And One end of which is fixed to the first image sensor plate boss and the other end is fixed to the first lens base boss, and the first side surface of the first image sensor plate and the first inner side surface of the lens base are in contact with each other And elastic means for providing a resilient force, Wherein the second position fixing means comprises: A second image sensor plate boss formed on the image sensor plate; A second lens base boss formed on the lens base to correspond to the second image sensor plate boss; And One end being fixed to the second image sensor plate boss, the other end being fixed to the second lens base boss, and the second side surface of the second image sensor plate and the second inner side surface of the lens base And an elastic means for providing elastic force to the image sensor module. The method according to claim 1, And a flexible circuit board electrically connected to the image sensor and disposed between the image sensor and the image sensor plate. The method according to claim 1, Wherein the image sensor plate is mounted on the lens base by screws which are fastened in a third axial direction perpendicular to the first and second axial directions. 8. The method of claim 7, Wherein an alignment position of the image sensor plate in the third axial direction with respect to the lens base is determined by fastening the screw. An image sensor for converting light representing an image of a subject incident on the image-forming surface into image information; An image sensor plate on which the image sensor is mounted; A lens base on which the image sensor plate is mounted such that an image forming surface of the image sensor is exposed through an opening; First and second position fixing means for respectively fixing positions in the first and second axial directions on a plane parallel to the image sensor surface of the image sensor with respect to the lens base; An optical system for converging light representing an image of a subject onto an image-forming surface of the image sensor; And And a central operation control unit for controlling the optical system and the image sensor to acquire and output image information corresponding to an image of a subject, Wherein the first position fixing means closely contacts the first side face of the image sensor plate facing the first axis direction and the first inner side face of the opening of the lens base, Wherein the second position fixing means closely contacts the second side face of the image sensor plate facing in the second axial direction and the second inside face of the opening side of the lens base.

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