KR102369432B1 - Camera module - Google Patents

Abstract

According to an embodiment of the present invention, a camera module includes: an image acquisition unit including a dynamic vision sensor that outputs vision data according to light incident through a lens barrel; an image processing unit generating an input signal indicating a target position of the lens barrel according to the vision data; a position sensor that detects the current position of the lens barrel and generates a feedback signal; and an actuator for moving the lens barrel in an optical axis direction according to the input signal and the feedback signal. may include

Description

Camera Module {CAMERA MODULE}

The present invention relates to a camera module.

In general, portable communication terminals such as mobile phones, PDAs, and portable PCs have recently become common to transmit text or voice data as well as image data. In response to this trend, a camera module is basically installed in a portable communication terminal in order to transmit image data or perform video chatting.

Recent camera modules employ an AF actuator capable of autofocusing and an OIS actuator for optical image stabilization (OIS) to reduce resolution degradation due to shake.

An object of the present invention is to provide a camera module capable of performing a focus adjustment operation in real time.

According to an embodiment of the present invention, a camera module includes: an image acquisition unit including a dynamic vision sensor that outputs vision data according to light incident through a lens barrel; an image processing unit generating an input signal indicating a target position of the lens barrel according to the vision data; a position sensor that detects the current position of the lens barrel and generates a feedback signal; and an actuator for moving the lens barrel in an optical axis direction according to the input signal and the feedback signal. may include

The camera module according to an embodiment of the present invention may perform a focus adjustment operation in real time using vision data output from a dynamic vision sensor having excellent temporal resolution.

1 is a perspective view of a camera module according to an embodiment of the present invention.
2 is a schematic exploded perspective view of a camera module according to an embodiment of the present invention.
3 is a block diagram of a camera module according to an embodiment of the present invention.

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

However, the embodiment of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below. In addition, the embodiments of the present invention are provided in order to more completely explain the present invention to those of ordinary skill in the art. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention with respect to one embodiment.

In addition, 'including' a certain component means that other components may be further included, rather than excluding other components, unless otherwise stated.

1 is a perspective view of a camera module according to an embodiment of the present invention, Figure 2 is a schematic exploded perspective view of the camera module according to an embodiment of the present invention.

1 and 2 , the camera module 100 according to an embodiment of the present invention accommodates a lens barrel 210 and an actuator for moving the lens barrel 210, the lens barrel 210 and the actuator. case 110 and housing 120, an image sensor module 700 for converting light incident through the lens barrel 210 into an electrical signal, and an iris module 800 for adjusting the amount of light incident on the lens barrel 210 ) is included.

The lens barrel 210 may have a hollow cylindrical shape so that a plurality of lenses for imaging a subject can be accommodated therein, and the plurality of lenses are mounted on the lens barrel 210 along an optical axis. A plurality of lenses are arranged as many as necessary according to the design of the lens barrel 210 , and each lens has optical properties such as the same or different refractive index.

The actuator may move the lens barrel 210 . For example, the actuator may adjust the focus by moving the lens barrel 210 in the optical axis (Z axis) direction, and correct shake during shooting by moving the lens barrel 210 in a direction perpendicular to the optical axis (Z axis). can do. The actuator includes an AF actuator 400 for adjusting focus and an OIS actuator 500 for correcting shake.

The image sensor module 700 may convert light incident through the lens barrel 210 into an electrical signal. For example, the image sensor module 700 may include a sensor 710 and a printed circuit board 720 connected to the sensor 710 , and may further include an infrared filter. The infrared filter blocks light in the infrared region among the light incident through the lens barrel 210 . The sensor 710 converts light incident through the lens barrel 210 into an electrical signal. The image sensor 710 is fixed to the printed circuit board 720 , and is electrically connected to the printed circuit board 720 by wire bonding. For example, an image signal processor (ISP) may be provided on the printed circuit board 720 .

The lens barrel 210 and the actuator are accommodated in the housing 120 . For example, the housing 120 has an open top and bottom, and the lens barrel 210 and the actuator are accommodated in the inner space of the housing 120 . An image sensor module 700 is disposed under the housing 120 .

The case 110 may be coupled to the housing 120 to surround the outer surface of the housing 120 , and may protect internal components of the camera module 100 . In addition, the case 110 may shield electromagnetic waves. The case 110 may be provided of a metal material and may be grounded to a grounding pad provided on the printed circuit board 720 , thereby shielding electromagnetic waves.

The actuator according to an embodiment of the present invention moves the lens barrel 210 to focus on a subject. For example, the actuator includes an AF actuator 400 that moves the lens barrel 210 in the optical axis (Z axis) direction.

AF actuator 400 includes a magnet 410 and a coil 420 for generating a driving force to move the lens barrel 210 and the carrier 300 accommodating the lens barrel 210 in the optical axis (Z axis) direction do.

The magnet 410 is mounted on the carrier 300 . For example, the magnet 410 may be mounted on the first surface of the carrier 300 . The coil 420 may be mounted on the housing 120 to face the magnet 410 . For example, the coil 420 may be disposed on the first surface of the substrate 600 , and the substrate 600 may be mounted on the housing 120 .

The magnet 410 may be mounted on the carrier 300 to move in the optical axis (Z axis) direction together with the carrier 300 , and the coil 420 may be fixed to the housing 120 . However, depending on the embodiment, the positions of the magnet 410 and the coil 420 may be changed from each other.

When a driving signal is applied to the coil 420 , the carrier 300 may move in the optical axis (Z axis) direction due to electromagnetic interaction between the magnet 410 and the coil 420 .

The lens barrel 210 is accommodated in the carrier 300 , and the lens barrel 210 is also moved in the optical axis (Z-axis) direction by the movement of the carrier 300 . In addition, the frame 310 and the lens holder 320 are also accommodated in the carrier 300, and by the movement of the carrier 300, the frame 310, the lens holder 320 and the lens barrel 210 are also included, and the optical axis ( Z axis) direction.

When the carrier 300 is moved, the rolling member B1 is disposed between the carrier 300 and the housing 120 to reduce friction between the carrier 300 and the housing 120 . The rolling member B1 may be in the form of a ball. The rolling member B1 is disposed on both sides of the magnet 410 .

A yoke 440 is disposed in the housing 120 . For example, the yoke 440 is mounted on the substrate 600 and disposed in the housing 120 . The yoke 440 is provided on the other surface of the substrate 600 . Accordingly, the yoke 440 is disposed to face the magnet 410 with the coil 420 interposed therebetween. An attractive force acts between the yoke 440 and the magnet 410 in a direction perpendicular to the optical axis (Z axis). Accordingly, the rolling member B1 by the attractive force between the yoke 440 and the magnet 410 may maintain a contact state with the carrier 300 and the housing 120 . In addition, the yoke 440 may focus the magnetic force of the magnet 410 to prevent leakage of magnetic flux from occurring. For example, the yoke 440 and the magnet 410 form a magnetic circuit.

The present invention uses a closed-loop control method for detecting and feeding back the position of the lens barrel 210 during the focus adjustment process. Accordingly, the AF actuator may include a position detection element for closed-loop control. As an example, the position detecting element may include an AF Hall element 430 . The magnetic flux value detected by the AF Hall element 430 changes according to the movement of the magnet 410 facing the AF Hall element 430 . The position detecting element may detect the position of the lens barrel 210 from a change in the magnetic flux value of the AF Hall element 430 according to the movement of the magnet 410 in the optical axis (Z axis) direction.

The OIS actuator 500 is used to correct blurring of an image or shaking of a moving picture due to factors such as a user's hand shake when shooting an image or a moving picture. For example, the OIS actuator 500 compensates for the shake by imparting a relative displacement corresponding to the shake to the lens barrel 210 when a shake occurs during image capturing due to a user's hand shake or the like. For example, the OIS actuator 500 corrects shake by moving the lens barrel 210 in a direction perpendicular to the optical axis (Z axis).

The OIS actuator 500 includes a plurality of magnets 510a and 520a and a plurality of coils 510b and 520b for generating a driving force to move the guide member in a direction perpendicular to the optical axis (Z axis). The frame 310 and the lens holder 320 are inserted into the carrier 300 to be disposed in the optical axis (Z axis) direction, and may guide the movement of the lens barrel 210 . The frame 310 and the lens holder 320 have a space into which the lens barrel 210 can be inserted. The lens barrel 210 is inserted and fixed to the lens holder 320 .

By the driving force generated according to the electromagnetic interaction between the plurality of magnets 510a and 520a and the plurality of coils 510b and 520b, the frame 310 and the lens holder 320 move the optical axis Z with respect to the carrier 300. axis) is moved in a direction perpendicular to the axis. Among the plurality of magnets 510a and 520a and the plurality of coils 510b and 520b, the first magnet 510a is disposed on the second surface of the lens holder 320 , and the first coil 510b is formed on the substrate 600 . The first magnet 510a and the first coil 510b generate a driving force in the first axis (Y axis) direction perpendicular to the optical axis (Z axis). In addition, the second magnet 520a is disposed on the third surface of the lens holder 320 , and the second coil 520b is disposed on the third surface of the substrate 600 , and the second magnet 520a and the second The coil 520b generates a driving force in a second axis (X axis) direction perpendicular to the first axis (Y axis). Here, the second axis (X axis) means an axis perpendicular to both the optical axis (Z axis) and the first axis (Y axis). The plurality of magnets 510a and 520a are disposed to be orthogonal to each other in a plane perpendicular to the optical axis (Z axis).

A plurality of magnets (510a, 520a) is mounted on the lens holder (320), a plurality of coils (510b, 520b) facing the plurality of magnets (510a, 520a) is disposed on the substrate (600), the housing (120) is mounted on

The plurality of magnets 510a and 520a may move in a direction perpendicular to the optical axis (Z axis) together with the lens holder 320 , and the plurality of coils 510b and 520b may be fixed to the housing 120 . However, depending on the embodiment, the positions of the plurality of magnets 510a and 520a and the plurality of coils 510b and 520b may be changed from each other.

The present invention uses a closed-loop control method in which the position of the lens barrel 210 is sensed and fed back during the shake correction process. Accordingly, the OIS actuator 500 may include a position detection element for closed-loop control. The position detection element may include OIS Hall elements 510c and 520c. The OIS Hall elements 510c and 520c are disposed on the substrate 600 and mounted on the housing 120 . The OIS Hall elements 510c and 520c may face the plurality of magnets 510a and 520a in a direction perpendicular to the optical axis (Z axis). For example, the first OIS Hall device 510c may be disposed on the second surface of the substrate 600 , and the second OIS Hall device 520c may be disposed on the third surface of the substrate 600 .

The magnetic flux values of the OIS Hall elements 510c and 520c change according to the movement of the magnets 510a and 520a facing the OIS Hall elements 510c and 520c. The position detection element is a lens barrel 210 from a change in magnetic flux values of the OIS Hall elements 510c and 520c according to movement in two directions (X-axis direction, Y-axis direction) perpendicular to the optical axis of the magnets 510a and 520a. ) can be detected.

Meanwhile, the camera module 100 includes a plurality of ball members supporting the OIS actuator 500 . The plurality of ball members functions to guide the movement of the frame 310 , the lens holder 320 , and the lens barrel 210 during the shake correction process. In addition, it also functions to maintain a gap between the carrier 300 , the frame 310 and the lens holder 320 .

The plurality of ball members includes a first ball member B2 and a second ball member B3. The first ball member B2 guides movement of the frame 310 , the lens holder 320 , and the lens barrel 210 in the first axis (Y axis) direction, and the second ball member B3 is the lens holder The movement in the second axis (X axis) direction of the 320 and the lens barrel 210 is guided.

For example, when the driving force in the first axis (Y-axis) direction is generated, the first ball member B2 rolls in the first axis (Y-axis) direction. Accordingly, the first ball member B2 guides movement of the frame 310 , the lens holder 320 , and the lens barrel 210 in the first axis (Y axis) direction. In addition, when the driving force in the second axis (X-axis) direction is generated, the second ball member B3 rolls in the second axis (X-axis) direction. Accordingly, the second ball member B3 guides the movement of the lens holder 320 and the lens barrel 210 in the second axis (X axis) direction.

The first ball member B2 includes a plurality of ball members disposed between the carrier 300 and the frame 310 , and the second ball member B3 is disposed between the frame 310 and the lens holder 320 . It includes a plurality of ball members that become.

A first guide groove portion 301 for accommodating the first ball member B2 is formed on a surface of the carrier 300 and the frame 310 facing each other in the optical axis (Z axis) direction. The first guide groove portion 301 includes a plurality of guide grooves corresponding to the plurality of ball members of the first ball member B2. The first ball member B2 is accommodated in the first guide groove portion 301 and fitted between the carrier 300 and the frame 310 . In the state accommodated in the first guide groove portion 301, the first ball member B2 is limited in movement in the optical axis (Z axis) and the second axis (X axis) direction, and in the first axis (Y axis) direction. can only be moved. As an example, the first ball member B2 is capable of rolling motion only in the first axis (Y axis) direction. To this end, the planar shape of each of the plurality of guide grooves of the first guide groove portion 301 may be a rectangle having a length in the first axis (Y axis) direction.

A second guide groove 311 for accommodating the second ball member B3 is formed on a surface of the frame 310 and the lens holder 320 facing each other in the optical axis (Z axis) direction. The second guide groove portion 311 includes a plurality of guide grooves corresponding to the plurality of ball members of the second ball member B3.

The second ball member B3 is accommodated in the second guide groove portion 311 and fitted between the frame 310 and the lens holder 320 . In the state accommodated in the second guide groove portion 311, the second ball member B3 is limited in movement in the optical axis (Z axis) and the first axis (Y axis) direction, and in the second axis (X axis) direction. can only be moved. As an example, the second ball member B3 is capable of rolling motion only in the second axis (X axis) direction. To this end, the planar shape of each of the plurality of guide grooves of the second guide groove portion 311 may be a rectangle having a length in the second axis (X-axis) direction.

Meanwhile, in the present invention, a third ball member B4 for supporting the movement of the lens holder 320 between the carrier 300 and the lens holder 320 is provided. The third ball member B4 guides both the movement in the first axis (Y-axis) direction and the movement in the second axis (X-axis) direction of the lens holder 320 .

For example, when the driving force in the first axis (Y axis) direction is generated, the third ball member B4 rolls in the first axis (Y axis) direction. Accordingly, the third ball member B4 guides the movement of the lens holder 320 in the first axis (Y axis) direction.

In addition, when the driving force in the second axis (X-axis) direction is generated, the third ball member B4 rolls in the second axis (X-axis) direction. Accordingly, the third ball member B4 guides the movement of the lens holder 320 in the second axis (X axis) direction. Meanwhile, the second ball member B3 and the third ball member B4 contact and support the lens holder 320 .

A third guide groove 302 for accommodating the third ball member B4 is formed on a surface of the carrier 300 and the lens holder 320 facing each other in the optical axis (Z axis) direction. The third ball member B4 is accommodated in the third guide groove portion 302 and fitted between the carrier 300 and the lens holder 320 . In the state accommodated in the third guide groove portion 302, the third ball member B4 is limited in movement in the optical axis (Z axis) direction, and in the first axis (Y axis) and second axis (X axis) directions. You can do cloud motion. To this end, the planar shape of the third guide groove portion 302 may be circular. Accordingly, the third guide groove portion 302 , the first guide groove portion 301 , and the second guide groove portion 311 may have different planar shapes.

The first ball member B2 is capable of rolling motion in the first axis (Y-axis) direction, the second ball member B3 is capable of rolling motion in the second axis (X-axis) direction, and the third ball member B4 is capable of rolling motion in the second axis (X-axis) direction. ) is capable of rolling motion in the first axis (Y axis) and second axis (X axis) directions.

When a driving force is generated in the first axis (Y axis) direction, the frame 310 , the lens holder 320 , and the lens barrel 210 move together in the first axis (Y axis) direction. Here, the first ball member B2 and the third ball member B4 roll along the first axis (Y axis). At this time, the movement of the second ball member B3 is limited.

Also, when a driving force is generated in the second axis (X-axis) direction, the lens holder 320 and the lens barrel 210 move in the second axis (X-axis) direction. Here, the second ball member B3 and the third ball member B4 roll along the second axis (X axis). At this time, the movement of the first ball member B2 is limited.

Meanwhile, in the present invention, a plurality of yokes 510d and 520d are provided so that the OIS actuator 500 and the first to third ball members B2, B3, and B4 maintain a contact state. The plurality of yokes 510d and 520d are fixed to the carrier 300 and are disposed to face the plurality of magnets 510a and 520a in the optical axis (Z-axis) direction. Accordingly, an attractive force is generated in the optical axis (Z axis) direction between the plurality of yokes 510d and 520d and the plurality of magnets 510a and 520a. Since the OIS actuator 500 is pressed in the direction toward the plurality of yokes 510d and 520d by the attractive force between the plurality of yokes 510d and 520d and the plurality of magnets 510a and 520a, the frame of the OIS actuator 500 310 and the lens holder 320 may maintain contact with the third to third ball members B2, B3, and B4. The plurality of yokes 510d and 520d is a material capable of generating attractive force between the plurality of magnets 510a and 520a. For example, the plurality of yokes 510d and 520d are provided with a magnetic material.

In the present invention, a plurality of yokes 510d and 520d are provided so that the frame 310 and the lens holder 320 can maintain contact with the first to third ball members B2, B3, and B4, while external impact The stopper 330 is provided to prevent the first to third ball members B2 , B3 , and B4 , the frame 310 , and the lens holder 320 from being separated from the carrier 300 by the other. The stopper 330 is coupled to the carrier 300 to cover at least a portion of the upper surface of the lens holder 320 .

The aperture module 800 may include an aperture 810 , a magnet 820 , a coil 830 , a Hall element 840 , and a substrate 850 . The magnet 820 , the coil 830 , and the Hall element 840 may constitute the IRIS actuator of the aperture module 800 .

The aperture 810 of the aperture module 800 may be coupled to the lens barrel 210 through the upper portion of the case 110 . For example, the aperture 810 may be mounted on the lens holder 320 into which the lens barrel 210 is fixedly inserted, and may be coupled to the lens barrel 210 . Accordingly, the stop 810 may move together with the lens barrel 210 and the lens holder 320 .

The magnet 820 may be provided on one side of the stop 810 . For example, the magnet 820 may be mounted on the substrate 850 provided on one side of the stop 810 and disposed on one side of the stop 810 . The magnet 820 may be provided on one side of the stop 810 and disposed on the fourth surface of the lens holder 320 . For example, the magnet 820 may include two magnetic materials that are polarized to each other.

The substrate 850 may be coupled to the diaphragm 810 to be movable in the first axis (Y axis) direction. The substrate 850 is connected to the diaphragm 810 so as to be movable in the first axis (Y-axis) direction, and the substrate 850 is inserted in the first axis (Y-axis) direction of the diaphragm 810 to be movable. member may be provided. The diameter of the entrance hole at the top of the stopper 810 varies according to the degree to which the connection member of the substrate 850 is inserted, that is, the distance between the substrate 850 and the stopper 810 in the first axis (Y-axis) direction. Thus, the amount of light transmitted through the diaphragm 810 may be determined.

The coil 830 is disposed on the fourth surface of the substrate 600 to face the magnet 820 . The coil 830 is disposed on the fourth surface of the substrate 600 , and the magnet 820 and the coil 830 generate a driving force in the first axis (Y axis) direction. When the driving force is generated in the first axis (Y axis) direction by the magnet 820 and the coil 830 , the distance in the first axis (Y axis) direction between the magnet 820 and the stopper 810 may be varied. .

The Hall element 840 is fixedly disposed to face the magnet 820 on the fourth surface of the substrate 600 . The Hall element 840 may include a first Hall element 841 and a second Hall element 842 disposed with the coil 830 interposed therebetween. The magnetic flux value of the Hall element 840 changes according to the movement of the magnet 820 . The position of the magnet 820 may be detected from the magnetic flux value of the Hall element 840 .

Meanwhile, in the above-described embodiment, it has been described that the AF actuator 400 and the OIS actuator 500 are driven by electromagnetic interaction between the magnet and the coil, but according to the embodiment, the AF actuator 400 and the OIS actuator 500 ) may be driven by a well-known shape memory alloy (SMA) method. In addition, in the above-described embodiment, the AF actuator 400 and the OIS actuator 500 are described as guiding the movement of the lens barrel 210 using a rolling member and a plurality of ball members, but according to the embodiment , the AF actuator 400 and the OIS actuator 500 may include a spring member guiding the movement of the lens barrel 210 and the like.

3 is a block diagram of a camera module according to an embodiment of the present invention. Hereinafter, a driving method of the camera module 1000 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3 .

The camera module 1000 according to the embodiment of FIG. 3 includes an image acquisition unit 1100, an image processing unit 1200, an AF driver IC 1300, an AF coil 1400, an AF magnet 1500, and an AF position sensor ( 1600) may be included. The AF driver IC 1300 , the AF coil 1400 , the AF magnet 1500 , and the AF position sensor 1600 may constitute an AF actuator.

The image acquisition unit 1100 may include a dynamic vision sensor (DVS) and may additionally include an image sensor.

A dynamic vision sensor (DVS) and an image sensor may operate in different time periods.

The dynamic vision sensor DVS may operate in a focus adjustment time period for a focus adjustment operation, and the image sensor may operate in an image capture time period for image capture. The focus adjustment time period precedes the image capture time period, and after focus adjustment is completed in the focus adjustment time period, image data may be acquired in the image capture time period.

The dynamic vision sensor (DVS) and the image sensor may be configured separately, and according to an embodiment, the dynamic vision sensor (DVS) and the image sensor may be integrally formed to constitute an integrated module. there is.

Meanwhile, in the above-described embodiment, it is described that the image acquisition unit 1100 includes both a dynamic vision sensor (DVS) and an image sensor, but image reconstruction is performed from edge information of vision data. If possible, the image acquisition unit 1100 may include only a dynamic vision sensor (DVS).

The image sensor may output image data according to the light incident through the lens barrel 210 . For example, the image sensor may include a charge coupled device (CCD) or a complementary metal-oxide semiconductor (CMOS).

Since the image sensor corresponds to a general image sensor that acquires image data through light incident through the lens barrel 210 , a detailed description thereof will be omitted.

The dynamic vision sensor DVS may convert light incident through the lens barrel 210 into vision data. The vision data may include edge information of the subject.

A dynamic vision sensor (DVS) is an image sensor that adopts a method in which a person's iris receives information, and may acquire vision data for a moving subject. For example, the dynamic vision sensor (DVS) transmits vision data to the image processing unit 1200 only when there is a local change due to movement in a pixel unit.

That is, the dynamic vision sensor DVS may transmit vision data to the image processing unit 1200 only when a moving event occurs. Therefore, the dynamic vision sensor (DVS) does not process data when the subject is still, but measures the moving subject only when the subject is moving and transmits the vision data to the image processing unit 1200 . By transmitting the image data, it is possible to prevent wastage of the generated data.

A dynamic vision sensor (DVS) can solve the problem that a general visual recognition system is vulnerable to fast movement. The dynamic vision sensor (DVS) can overcome the blur phenomenon because it receives data on a per-pixel basis rather than on a frame-by-frame basis.

Also, the dynamic vision sensor (DVS) may have a resolution of microseconds. Specifically, since vision data output from the dynamic vision sensor (DVS) includes only edge information of the subject, the dynamic vision sensor (DVS) may have superior temporal resolution than a high-speed camera that takes thousands of frames per second. Furthermore, since the dynamic vision sensor (DVS) also greatly reduces power consumption and data storage requirements, the dynamic range corresponding to the range of brightness that the sensor can distinguish can also be dramatically increased.

The image processing unit 1200 may image data output from the image acquisition unit 1100 . The image processing unit 1200 may include an image signal processor (ISP).

The image processing unit 1200 may generate an input signal Sin by processing vision data provided from the dynamic vision sensor DVS during the focus adjustment time period.

As an example, the image processing unit 1200 may generate an input signal Sin indicating a target position in the optical axis direction of the lens barrel by applying an automatic focus adjustment algorithm to vision data provided from a dynamic vision sensor (DVS). . As an example, the auto-focusing algorithm may include a well-known phase-difference-based auto-focusing algorithm.

On the other hand, the image processing unit 1200, in the image capture time period, automatic exposure (AE: Auto Exposure) adjustment, automatic white balance (AWB: Auto White Balance), and the lens to image data output from the image sensor (Image Sensor), An algorithm such as Lens Shading Correction (LSC) may be applied.

On the other hand, the image processing unit 1200, in the image capture time period, image reconstruction (Image Reconstruction) from the edge information of the vision data, to generate image data, automatic exposure (AE: Auto Exposure) control to the generated image data, Algorithms such as Auto White Balance (AWB) and Lens Shading Correction (LSC) may be applied.

The AF driver IC 1300 generates a driving signal Sdr according to the input signal Sin and the feedback signal Sf in the focus adjustment time period, and provides the generated driving signal Sdr to the AF coil 1400 . can do. The input signal Sin provided from the image processing unit 1200 may include information about a target position of the lens barrel in the optical axis direction.

The feedback signal Sf may be provided from the AF position sensor 1600 that detects the current position of the lens barrel in the optical axis direction. For example, the AF position sensor 1600 may include a Hall element. The AF position sensor 1600 may detect the current position of the lens barrel through the current position of the AF magnet 1500 .

The AF driver IC 1300 may be driven in a closed loop type that compares the input signal Sin and the feedback signal Sf. The closed-loop type AF driver IC 1300 may be driven in a direction to reduce an error between a target position included in the input signal Sin and a current position detected in the feedback signal Sf. The closed-loop driving has an advantage in that linearity, accuracy, and repeatability are improved as compared to the open-loop system.

The AF driver IC 1300 may have an H-bridge circuit capable of bidirectional driving therein, and may provide a driving signal Sdr to the AF coil 1400 in a voice driving coil motor method. . The driving signal Sdr may be provided to the AF coil 1400 in the form of current or voltage.

When the driving signal Sdr is applied to the AF coil 1400 , the AF coil 1400 may provide a driving force to the AF magnet 1500 . For example, the lens barrel may move in the optical axis direction due to electromagnetic influence between the AF magnet 1500 and the AF coil 1400 .

The AF magnet 1500 may be mounted on one side of the lens barrel, and the AF coil 1400 may be mounted on the housing to face the AF magnet 1500 . However, depending on the embodiment, the positions of the AF magnet 1500 and the AF coil 1400 may be changed from each other.

The camera module 1000 according to an embodiment of the present invention may perform a focus adjustment operation in real time using vision data output from a dynamic vision sensor (DVS) having excellent temporal resolution.

In the above, the present invention has been described with specific matters such as specific components and limited embodiments and drawings, but these are provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , various modifications and variations can be devised from these descriptions by those of ordinary skill in the art to which the present invention pertains.

Therefore, the spirit of the present invention should not be limited to the above-described embodiments, and not only the claims described below but also all modifications equivalently or equivalently to the claims described below belong to the scope of the spirit of the present invention. will do it

110: case
120: housing
210: lens barrel
300: carrier
310: frame
320: lens holder
400: AF actuator
500: OIS actuator
600: substrate
700: image sensor module
800: aperture module
810: aperture
820: magnet
830: coil
840: Hall element
850: substrate
1000: actuator
1100: image acquisition unit
1200: image processing unit
1300: AF driver IC
1400: AF coil
1500: AF magnet
1600: AF position sensor

Claims (16)

an image acquisition unit including a dynamic vision sensor outputting vision data according to light incident through the lens barrel and an image sensor outputting image data according to light incident through the lens barrel;
an image processing unit generating an input signal indicating a target position of the lens barrel according to the vision data;
a position sensor that detects the current position of the lens barrel and generates a feedback signal; and
an actuator for moving the lens barrel in an optical axis direction according to the input signal and the feedback signal; including,
The dynamic vision sensor and the image sensor operate in different time periods, wherein the dynamic vision sensor operates in a focus adjustment time period, and the image sensor operates in an image capture time period.
camera module.
According to claim 1,
The vision data is a camera module including edge information of the subject.
delete delete delete According to claim 1,
The dynamic vision sensor and the image sensor are integrally formed with a camera module.
According to claim 1, wherein the image processing unit,
A camera module for generating the input signal by applying an automatic focus adjustment algorithm to the vision data.
According to claim 1, wherein the actuator,
and a driver IC configured to compare the input signal and the feedback signal to generate a driving signal.
The method of claim 8, wherein the actuator,
The camera module further comprising a magnet provided on one side of the lens barrel and a coil to which the driving signal is applied to provide a driving force to the magnet.
an image acquisition unit including a dynamic vision sensor outputting vision data and an image sensor outputting image data according to light incident through the lens barrel; and
an image processing unit that image-processes data output from the image acquisition unit and generates an input signal indicating a target position of the lens barrel; and
an actuator for moving the lens barrel in an optical axis direction according to the input signal and a feedback signal corresponding to the current position of the lens barrel; including,
The dynamic vision sensor and the image sensor operate in different time periods, wherein the dynamic vision sensor operates in a focus adjustment time period for a focus adjustment operation, and the image sensor operates in an image capture time period for image capture.
camera module.
delete The method of claim 11, wherein the image processing unit,
In the focus adjustment time period, the camera module for generating the input signal.
The method of claim 12, wherein the image processing unit,
A camera module for generating the input signal by applying an automatic focus adjustment algorithm to the vision data.
delete 11. The method of claim 10,
The vision data is a camera module including edge information of the subject.
11. The method of claim 10,
The dynamic vision sensor and the image sensor are integrally formed with a camera module.

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