TWI648586B - Camera module and array camera module based on integrated packaging process - Google Patents

Abstract

The invention is a camera module and an array camera module based on an integrated packaging process, wherein the array camera module comprises a plurality of camera modules, each of which comprises a circuit board, an integrated base, a photosensitive element, a lens, and a filter. a light element lens holder and a filter element; wherein the photosensitive element is operatively coupled to the circuit board, the filter element lens mount is mounted to the integral base, and the filter element is disposed on the The filter element holder is such that the filter element does not need to be directly mounted to the integral base, thereby protecting the filter element and reducing the required area of the filter element.

Description

Camera module and array camera module based on integrated packaging process

The invention relates to the field of camera modules, and further relates to a camera module and an array camera module based on an integrated packaging process.

The camera module is one of the indispensable components of the smart electronic device, such as but not limited to smart phones, cameras, computer devices, wearable devices and the like. With the continuous development and popularization of various smart devices, the requirements for camera modules are getting higher and higher.

In recent years, smart electronic devices have developed rapidly and become increasingly thin and light, and camera modules have to adapt to their development, and more and more require multi-functionality, thin and light, and miniaturization, so that the more intelligent electronic devices can be made The thinner it is, and the imaging requirements of the device for the camera module are met. Therefore, camera module manufacturers continue to design and manufacture camera modules that meet these requirements.

Molding and packaging technology is a packaging technology that has been developed on the basis of traditional COB packaging. As shown in FIG. 1A, it is a circuit board packaged using existing molding packaging technology. In this configuration, the molding portion 1 is packaged on the circuit board 2 by means of molding, and then the wafer 3 is attached to the circuit board 2, and the filter 4 is mounted to the molding portion 1. The molding part 1 covers the electronic component 5 on the circuit board, thereby reducing the space occupied by the electronic component 5 of the camera module, so that the size of the camera module can be reduced, and the dust attached to the electronic component is affected to affect the imaging. The problem of imaging quality of the module.

1B is a circuit board of a conventional COB package. COB packaging technology relative to the drive The molding and packaging technology has many advantages, such as replacing the lens holder 7 by the molding portion 1, reducing the space occupied by the electronic component 5, reducing the camera module ruler, and avoiding the adhesion of dust on the electronic component 5 to affect the camera mode. The imaging quality of the group, etc., but at the same time this structure also brings some new problems.

The filter is an important component in the modern imaging film set. The filter filters the infrared light in the light, making the light closer to the human eye. Since the filter is easily damaged and has a large proportion in the cost of the entire camera module, the larger the area, the more expensive, and the larger the area of the filter, the more difficult the manufacturing precision is to control, so the molding and packaging technology Among them, the filter becomes an implementation difficulty.

First, compared with the conventional COB packaging method, the molding and packaging method covers the electronic component 5 by the molding portion, and utilizes the spatial position of the electronic component 5, but the molding portion is enlarged relative to the COB lens holder, and the upper filter is enlarged. The installation space of 4, that is, the area of the filter 4 required for molding the package is large.

Specifically, referring to FIG. 1B, a conventional COB medium filter is mounted on the lens holder 7. Since the lens holder 7 is post-mounted on the circuit board 2, it can be manufactured in different shapes, such as inwardly extending. Therefore, the area of the filter can be reduced as much as possible while ensuring that the photosensitive area is not blocked, so that it is more convenient to install on the basis of ensuring the use requirement, and the filter of a small area is lower in price, so that The cost of the overall camera module is reduced, and in the molding package, the molding portion 1 is integrally molded on the circuit board 2 by a mold, and the molding portion is integrally extended from bottom to top, so the area of the filter 4 is determined by the opening of the molding portion 1. The area of the filter 4 required is large.

Secondly, in the molding and packaging method, referring to FIG. 1A, the filter 4 needs to be mounted in the recess 6 of the molding portion 1, and the shape of the corner opening is difficult to control based on the molding and packaging process. That is to say, the groove walls forming the grooves 6, especially the positions where the groove walls meet, may be deformed, such as burrs, so that the filter 4 cannot be provided with good mounting conditions, and the flatness cannot be ensured. It is easy to damage the filter. And for the conventional mirror base 7, there is an inner groove 8, that is to say the mirror base 7 can be inwardly extended The position where the filter 4 is mounted is provided, and the mounting area of the filter 4 is reduced. Since the molding is a molding, there is a drafting problem in the process of manufacturing through the mold, and thus the conventional mirror structure cannot be manufactured by molding, so the molding package is limited to some specific structures, such as without The molded portion 1 of the inner groove 8. There are some relative advantages and disadvantages between the traditional mirror base and the molded package lens holder and the corresponding molding process, so it is necessary to combine the advantages of the two.

Third, even if the molded portion 1 is formed in a plate shape without forming the groove 6, the flatness of the surface can be ensured, and the filter 4 can be provided with better mounting conditions. However, in this configuration, on the one hand, the filter 4 needs to be coordinated with other components such as a lens or a driver to distribute the package portion, which requires high installation precision, and other components are easily damaged during the installation process. The light sheet; on the other hand, the filter is closer to the lens, and the lens in the lens easily touches the filter and increases the back focus of the lens.

In addition, the photosensitive element, the electronic component, and the molding portion need to be mounted on the circuit board, and the layout of these components affects the area of the circuit board, and the width of the package is generally larger than that of the conventional mirror. The width of the seat, thus increasing the footprint on the board.

An object of the present invention is to provide a camera module and an array camera module based on an integrated packaging process, wherein the camera module includes a filter element lens holder, and the filter element lens holder and the camera module are integrated. The seats cooperate to provide support for different parts of the camera module.

An object of the present invention is to provide a camera module and an array camera module based on an integrated packaging process, wherein the filter element lens holder provides a suitable mounting position for the filter element, so that the filter element does not need to be directly mounted. An integral base of the camera module.

An object of the present invention is to provide a camera module and an array camera module based on an integrated packaging process, wherein the filter element lens holder has a support slot, and the filter element is adapted to be mounted on the support slot. Thereby the position of the filter element is relatively depressed.

An object of the present invention is to provide a camera module and an array camera module based on an integrated packaging process, wherein the filter element lens holder has an engagement groove, and the engagement groove is adapted to be coupled to the integrated base, thereby The relative height of the filter element lens holder and the integrated base is lowered such that the filter element is further adjacent to the photosensitive element of the camera module.

An object of the present invention is to provide a camera module and an array camera module based on an integrated packaging process, wherein the filter element lens holder includes a main body and at least one inner extension arm, and the inner extension arm is from the lower part of the main body The support groove is formed to extend inward.

An object of the present invention is to provide a camera module and an array camera module based on an integrated packaging process, wherein the filter element mirror portion includes at least a lower arm, and the sink arm extends longitudinally from the body. The inner extension arm extends laterally from the sinking arm to form the engagement groove and the support groove, respectively.

An object of the present invention is to provide a camera module and an array camera module based on an integrated packaging process, wherein the integrated base has at least one notch communicating with the outside, and the filter element lens holder includes at least one extended edge. The extended edge corresponds to the notch and accommodates different lateral widths of the integrated base.

An object of the present invention is to provide a camera module and an array camera module based on an integrated packaging process, wherein the filter element lens holder includes an upper extension wall, and the upper extension wall constrains and limits the camera module. The position of the driver or lens makes the optical axis of the camera module uniform.

An object of the present invention is to provide a camera module based on an integrated packaging process and An array camera module, wherein the filter element holder is used to relieve stress applied by the filter element when directly mounted on the integrated base, and the filter element is protected.

An object of the present invention is to provide a camera module and an array camera module based on an integrated packaging process, wherein the array camera module includes a connected filter element lens holder integrally connected by at least two filter element lens holders. In order to support a plurality of filter elements at the same time, to ensure the consistency between the plurality of camera modules.

In order to achieve the above at least one object of the present invention, an aspect of the present invention provides a camera module, the camera module including: at least one integrated base assembly; at least one photosensitive element; at least one lens; at least one filter element lens holder And at least one filter element; wherein the integrated base assembly includes an integral base and a circuit board, the integrated base is integrally packaged on the circuit board; wherein the photosensitive element is operatively coupled to the circuit board The filter element lens holder is mounted on the integrated base, and the integrated base forms a light window to provide a light path for the photosensitive element, and the filter element is disposed on the filter element a lens holder such that the filter element is located in a photosensitive path of the photosensitive element; wherein the lens is located in a photosensitive path of the photosensitive element.

In an embodiment of the present invention, the filter element lens holder includes a filter element lens holder body and at least one inner extension arm, and the inner extension arm is from the filter element mirror The seat body partially extends laterally integrally to form a support groove adapted to mount the filter element.

In an embodiment of the present invention, the filter element lens holder includes a filter element mirror body, at least a lower arm and at least one inner arm, and the sink arm The filter element housing body is steered to extend to form an engagement slot adapted to be coupled to the integral base, the inner extension arm extending from the sunburst arm to form a support slot adapted to mount the filter Optical component.

In an embodiment of the present invention, the adjacent inner arm is formed in the camera module A corner opening extending outwardly from the light window to facilitate increasing the luminous flux at the corner opening.

In an embodiment of the present invention, the sinking arm extends from the filter element mirror body toward a direction adjacent to the photosensitive element, and the filter element sinks adjacent to the Photosensitive element.

In an embodiment of the invention, the inner extension arm extends laterally inward from the sinking arm, thereby reducing the mounting area of the filter element.

In an embodiment of the present invention, the integrated base has at least one mounting slot and at least one notch, the mounting slot is connected to the optical window, and the notch is connected to the light. a window member and an outer portion, the filter element lens holder body of the filter element lens holder includes at least one engagement edge and at least one extension edge, the engagement edge being adapted to be engaged with the mounting groove, the extension edge being adapted Filling the gap forms a closed environment.

In an embodiment of the present invention, the integrated base includes three mounting slots, and the mounting slot forms a U-shaped structure, and the filter component of the filter element lens mount The mirror mount body has three engagement edges to form a U-shaped structure adapted to engage the mounting slot.

In an embodiment of the present invention, the integrated base has two mounting slots and two notches, the mounting slots are connected to the optical window, and the notches are connected to the optical window and Externally, the filter element lens holder body of the filter element lens holder comprises two engaging edges and two extending edges, the two engaging edges being adapted to be engaged with the two mounting grooves, and the two extending edges are adapted to extend The two gaps form a closed environment.

In an embodiment of the present invention, the two mounting grooves of the integrated base are opposite to each other, and the two notches are opposite, and the two engaging edges of the filter element lens holder are opposite. Two The extension is opposite.

In an embodiment of the present invention, the two mounting slots of the integrated base are adjacent to each other, and the two notches are adjacent to each other, and the two joint edges of the filter element lens holder are Adjacent, the two extended sides are adjacent.

In an embodiment of the present invention, the integrated base has a mounting slot and three notches, the mounting slot is connected to the optical window, and the notch is connected to the optical window and Externally, the filter element lens holder body of the filter element lens holder comprises a joint edge and three extension edges, the joint edge is adapted to be engaged with the mounting groove, and the extension edge is adapted to extend to three The gap forms a closed environment.

In an embodiment of the present invention, the filter element lens holder includes an upper extension wall, and the upper extension wall extends upward from the filter element lens holder body to form a limit. Bit.

In an embodiment of the present invention, the filter element lens holder includes an upper extension wall and a lower extension wall, and the upper extension wall is steered upward from the filter element mirror housing body. Extending to form a limiting port, the lower extension wall is steered downwardly from the filter element mirror body to form a lower opening.

In an embodiment of the present invention, the filter element lens holder has a receiving port for accommodating the filter element, so that the filter element is located at the photosensitive element. path.

In an embodiment of the present invention, the integrated base includes a base body, the base body is integrally packaged on the circuit board, and the base body has at least one opening. The light window and the exterior are connected, and the filter element lens holder is supplemented to the opening to form the light window.

In an embodiment of the invention, the opening of the camera module is an inverted trapezoidal structure that gradually increases from bottom to top.

In an embodiment of the invention, the filter element lens holder is at least partially connected to the circuit board in the camera module.

In an embodiment of the present invention, the filter element lens holder includes at least one extending leg, and the extending leg extends integrally from the filter element lens holder body to the circuit. a plate that replenishes the opening of the integral base such that the perimeter of the light window is closed.

In an embodiment of the present invention, the opening of the camera module is an inverted trapezoidal structure that gradually increases from bottom to top, and the extending leg has an inverted trapezoidal shape and cooperates with the shape of the opening to facilitate The filter element holder is constrained by the opening.

In an embodiment of the invention, the camera module includes at least one driver, and the driver is at least partially selectively mounted on the integrated base and the filter element lens holder, the lens is Installed on the drive.

In an embodiment of the invention, the lens of the camera module is at least partially selectively mounted to the integrated base and the filter element mirror mount.

In an embodiment of the invention, the lens in the camera module is at least partially mounted on the integrated base.

In an embodiment of the invention, the filter element in the camera module is selected from the group consisting of: an infrared cut filter, a blue glass filter, and a wafer level infrared cut filter. In an embodiment of the invention, the integrated packaging process in the camera module is integrally packaged by molding.

In an embodiment of the present invention, the circuit board in the camera module includes at least An electronic component and a substrate, the electronic component being disposed on the substrate, the integrated base covering the electronic component, and integrally packaged on the substrate.

In an embodiment of the invention, the integrated base has a lens barrel wall to form a lens chamber, and is suitable for mounting a lens. In an embodiment of the invention, the filter element lens holder in the camera module is formed by injection molding.

In an embodiment of the present invention, the integrated base has an inner side surface, the inner side surface has an inclination angle, and the engagement groove has an engagement angle, and the inclination angle is opposite to adapt.

In an embodiment of the invention, the camera module includes a plurality of the integrated base assembly, a plurality of the photosensitive elements, a plurality of lenses, a plurality of filter element lens holders, and a plurality of filters. An array camera module, wherein each of the integrated base assembly and the circuit board are integrally connected to form a connected circuit board, and each of the integrated bases is integrally connected to form a connected base, each of the filters The component mirror mounts are integrally connected to form a connected filter element mirror mount.

In an embodiment of the present invention, the filter element lens holder includes at least one limiting protrusion, and the limiting protrusion is at least partially from the top of the filter element lens holder body. The protrusions extend upwards.

In an embodiment of the invention, the limiting protrusion in the camera module has a ring structure.

In an embodiment of the invention, the camera module includes a driver, the lens is mounted on the driver, and the limiting protrusion is adapted to limit the driver to the outside.

Another aspect of the present invention provides an array of camera modules, comprising a plurality of camera modules, arranged in an array, each of the camera modules comprising: an integrated base assembly; a photosensitive element; a mirror a filter element lens holder and a filter element; wherein the integrated base assembly comprises an integral base and a circuit board, the integrated base is integrally packaged on the circuit board to form a light window, a photosensitive element providing a light path; wherein each of the photosensitive elements is operatively coupled to the circuit board, the filter element lens mount is mounted to the integrated base, and the filter element is disposed on the filter a component lens holder such that the filter element is located in a photosensitive path of the photosensitive element; wherein the lens is located in a photosensitive path of the photosensitive element; wherein the integrated base of the plurality of camera modules is integrated The ground connections form a connected base.

In an embodiment of the invention, the plurality of circuit boards are integrally connected to form a connected circuit board, and the plurality of filter element lens holders are integrally connected to form a connected filter element lens holder. It can be understood that, in some embodiments, the plurality of circuit boards may also be independent circuit boards, and the plurality of filter element lens holders may also be independent filter element lens holders.

In an embodiment of the present invention, the connected base includes a plurality of base bodies, and each of the base bodies forms the light window, and the base body is adjacent to the base body. Connecting to form a connected body, the connected filter element lens holder includes a plurality of supporting grooves communicating with respective corresponding light windows, the supporting groove being adapted to mount the filter element, adjacent to the filter The light element mirror mounts are integrally connected to form a bridging portion, and the bridging portion is bridged to the joint portion of the joint base.

In an embodiment of the present invention, each of the filter element lens holders includes a filter element lens holder body and at least one inner extension arm, and the inner extension arm filters from the filter The element housing body partially extends laterally integrally to form a support slot adapted to mount the filter element.

In an embodiment of the present invention, each of the filter element lens holders includes a filter element lens holder body, at least a lower arm and at least one inner arm, and the sink arm Steeringly extending from the filter element housing body to form an engagement slot adapted to be coupled to the integral base, the inner extension arm extending from the sinking arm to form a support slot, suitable for mounting The filter element is described.

In an embodiment of the present invention, adjacent ones of the inner camera arms of the array camera module form a corner opening extending outward from the light window to facilitate increasing at the corner opening The luminous flux of the location.

In an embodiment of the present invention, the sinking arm of the array camera module is rotated from the filter element mirror body toward a reverse direction of the photosensitive element, and the filter element is adjacent to the sinking element. The photosensitive element.

In an embodiment of the invention, the inner extension arm extends laterally inward from the inner extension arm to reduce the mounting area of the filter element.

In an embodiment of the present invention, each of the integrated bases has at least one mounting slot and at least one notch, and the mounting slot is connected to the optical window, and the notch is connected to the The light filter window frame body of the filter element lens holder includes at least one joint edge and at least one extended edge, the joint edge being adapted to be engaged with the mounting groove, the extended edge Suitable for extending the gap to form a closed environment.

In an embodiment of the present invention, each of the integrated bases in the array camera module includes three mounting slots, and the mounting slots form a U-shaped structure, and the filter of the filter element lens holder The light element mirror mount body includes three engagement edges that form a U-shaped structure adapted to engage the mounting slot.

In an embodiment of the present invention, each of the integrated bases has two mounting slots and two notches, the mounting slots are connected to the optical window, and the notches are connected to the light. The filter element lens holder body of the filter element lens holder includes two engaging edges and two extending edges, and the two engaging edges are adapted to be coupled to the two mounting grooves, and the two extending edges are suitable Extending the two gaps to form a closed environment.

In an embodiment of the present invention, each of the integrated bases in the array camera module The two mounting slots are opposite to each other, and the two notches are opposite to each other. The two engaging edges of the filter element lens holder are opposite to each other, and the two extending edges are opposite.

In an embodiment of the present invention, the two mounting slots of each of the integrated bases in the array camera module are adjacent to each other, and the two notches are adjacent to each other, and the two filter elements are The joint edges are adjacent to each other, and the two extended edges are adjacent.

In an embodiment of the present invention, each of the integrated bases has a mounting slot and three notches, the mounting slot is connected to the optical window, and the notch is connected to the light. a window member and an outer portion, the filter element lens holder body of the filter element lens holder includes a joint edge and three extension edges, the joint is adapted to be engaged with the mounting groove, and the extension edge is adapted to extend to The gaps form a closed environment.

In an embodiment of the present invention, each of the filter element lens holders includes an upper extension wall, and the upper extension wall extends upwardly from the filter element lens holder body. A limit port.

In an embodiment of the present invention, each of the filter element lens holders includes an upper extension wall and a lower extension wall, and the upper extension wall is turned from the filter element mirror base body. The ground extends upward to form a limiting port, and the lower extension wall steers downwardly from the filter element mirror body to form a lower opening.

In an embodiment of the present invention, the connected base has at least one opening extending to the circuit board, and the connected filter element mirror includes at least one extending leg. The opening supplemented to the connected base is connected to the circuit board.

In an embodiment of the invention, the extending leg of the array camera module extends from the filter element mirror body to the circuit board such that a circumference of the corresponding light window is closed.

In an embodiment of the present invention, the extending leg of the array camera module is located between two adjacent optical windows to separate the two light windows.

In an embodiment of the present invention, each of the filter element lens holders in the array camera module has at least one receiving port for accommodating the filter element such that the filter element is located in the Photosensitive path of the photosensitive element.

In an embodiment of the invention, the array camera module includes at least one driver, and the driver is at least partially selectively mounted on the integrated base and the integrated filter element lens holder, the lens Installed on the driver to form a dynamic focus camera module.

In an embodiment of the present invention, at least one of the lenses of the array camera module is at least partially selectively mounted on the integrated base and the integrated filter element lens holder to form a certain focus imaging mode. group.

In an embodiment of the present invention, at least one camera module of the array camera module is a dynamic focus camera module, and at least one of the camera modules is a fixed focus camera module.

In an embodiment of the present invention, at least two of the camera modules in the array camera module are dynamic focus camera modules.

In an embodiment of the present invention, at least two of the camera modules in the array camera module are fixed focus camera modules.

In an embodiment of the present invention, the array camera module includes two camera modules, forming a dual camera module.

Another aspect of the present invention provides an optical component for use in an array of camera modules including a plurality of optical components, wherein each of the optical components includes an integrated base component; a photosensitive component; a filter component lens holder and a filter An optical component; wherein the integrated base assembly includes an integral base and a circuit board, The integrated base is integrally packaged on the circuit board; wherein the photosensitive element is operatively connected to the circuit board, the filter element lens mount is mounted on the integrated base, and the integrated base is formed a light window providing a light path for the photosensitive element, the filter element being disposed on the filter element lens holder such that the filter element is located in a photosensitive path of the photosensitive element; wherein the lens is located The photosensitive path of the photosensitive element.

Another aspect of the present invention provides an array camera module comprising: at least two lenses; at least two photosensitive elements; at least one connected circuit board; at least one connected base integrally packaged on the connected circuit board, and Forming at least two light windows respectively for providing corresponding light paths to the lens and the photosensitive element; at least two filter elements; and at least two filter element lens holders, each of the filter element lens holders being mounted on the Each of the filter elements is mounted on a corresponding filter element lens holder and located between the corresponding lens and the photosensitive element.

Another aspect of the present invention provides an electronic device including an electronic device body and the one or more camera modules, and each of the camera modules is disposed on the electronic device body.

In an embodiment of the present invention, the electronic device includes but is not limited to: a smart phone, a wearable device, a computer device, a television, a vehicle, a camera, and a monitoring device.

Another aspect of the present invention provides an electronic device including an electronic device body and the one or more array camera modules, and each of the array camera modules is disposed on the electronic device body.

100, 100S‧‧‧ camera module

200‧‧‧Electronic equipment main body

300‧‧‧Electronic equipment

1000, 1000S, 1000T‧‧‧ array camera module

1110T‧‧‧Connected base

10, 10S‧‧‧ integrated base assembly

11, 11A, 11B, 11D, 11E, 11Q, 11F, 11G, 11H, 11I, 11K, 11N, 11R, 11S‧‧‧ integrated base

111, 111A, 111D, 111E, 111Q, 111F, 111G, 111H, 111R, 111T‧‧‧ light windows

112, 112D, 112E, 112Q, 112F, 112H, 112R‧‧‧ pedestal body

1120S, 1120T‧‧‧ connected circuit board

1121D, 1121E, 1121Q, 1121R‧‧‧ openings

1122Q‧‧‧Open face

113‧‧‧ top surface

114A‧‧‧ inside

115F, 115G, 115H, 115J, 115K, 115N, 115R, 115T‧‧‧ mounting slots

116F, 116G, 116H, 116I, 116K, 116N, 116R‧‧‧ raised steps

117G, 117H, 117I, 117J, 117K, 117R‧‧ ‧ gap

118N‧‧‧Lens wall

1181N‧‧‧Lens room

12, 12R, 12S‧‧‧ circuit board

121‧‧‧Substrate

122R‧‧‧Electronic components

1211‧‧‧ upper surface

1212‧‧‧ lower surface

1213‧‧‧Installation area

122‧‧‧Electronic components

1311‧‧‧Photosensitive area

1312‧‧‧ Non-photosensitive area

1400H‧‧‧Continuous filter element holder

1410R‧‧‧Boundary

20‧‧‧Photosensitive elements

201‧‧‧ positive

202‧‧‧Back

203‧‧‧Electrical connection elements

30‧‧‧ lens

40, 40A, 40B, 40B1, 41B2, 40D, 40E, 40Q, 40G, 40H, 40I, 40J, 40K, 40L, 40M, 40R, 40T‧‧‧ filter element lens holder

41, 41B, 41B1, 41D, 41H, 41K, 41R‧‧‧ support slots

411‧‧‧ accommodating mouth

42, 42A, 42D, 42G, 42H, 42I, 42K, 42R‧‧‧ joint slots

43, 43A, 43B, 43B1, 43B2, 43D, 43E, 43G, 43H, 43I, 43K, 43M, 43R‧‧‧ filter element lens holder body

431G, 431H, 431I, 431J, 431K, 431R‧‧‧ joints

432G, 432I, 432J, 432K, 432R‧‧‧ extended side

433D, 433E, 433Q, 433R‧‧‧ extended legs

4331Q‧‧‧Additional noodles

44, 44A, 44B, 44B1, 44B2, 44D, 44G, 44H, 44K, 44R‧‧‧ internal arm

441C‧‧‧ corner opening

45, 45A, 45D, 45G, 45H, 45I, 45K4, 5R‧‧‧ sinking arm

46P‧‧‧ bump

46L, 46M‧‧‧Upper wall

461L, 461M‧‧‧ Limit Port

462L‧‧‧ pin port

47M‧‧‧Lower

471M‧‧‧ under the mouth

48B1, 48B2‧‧‧ Mounting slot

49B1, 49B2‧‧‧ lens section

50‧‧‧ Filter elements

60‧‧‧ drive

61‧‧‧ pin

Figure 1A is a circuit board assembly of a prior art molded package.

Figure 1B is a circuit board assembly of a prior art COB package.

2 is a cross-sectional view of a camera module in accordance with a first preferred embodiment of the present invention.

3 is an exploded view of a camera module in accordance with a first preferred embodiment of the present invention.

4 is a schematic diagram showing a partial assembly process of a camera module according to a first preferred embodiment of the present invention.

FIG. 5 is a schematic diagram of a modified embodiment of a camera module according to a first preferred embodiment of the present invention.

Figure 6 is another embodiment of a camera module in accordance with a first preferred embodiment of the present invention.

Figure 7 is a cross-sectional view showing a first modified embodiment of the integrated base assembly and the filter element lens holder in accordance with the first preferred embodiment of the present invention.

Figure 8A is a cross-sectional view showing a second modified embodiment of the integrated base assembly and the filter element lens holder in accordance with the first preferred embodiment of the present invention.

Figure 8B is a modified embodiment of a second modified embodiment of the filter element mirror mount of the first preferred embodiment of the present invention.

Figure 8C is another modified embodiment of a second modified embodiment of the filter element mirror mount in accordance with the first preferred embodiment of the present invention.

Figure 9A is a perspective view of a third modified embodiment of a filter element mirror mount in accordance with a first preferred embodiment of the present invention.

Figure 9B is a fourth modified embodiment of the integrated base assembly and the filter element mount of the camera module in accordance with the first preferred embodiment of the present invention.

10A and 10B are cross-sectional views of different orientations of a camera module in accordance with a second preferred embodiment of the present invention.

Figure 11 is an exploded perspective view of an integral base assembly and filter element mount in accordance with a second preferred embodiment of the present invention.

12A and 12B are cross-sectional views showing a modified embodiment of a unitary base assembly and a filter element lens holder in accordance with a second preferred embodiment of the present invention.

Figure 13A is an exploded perspective view of a modified embodiment of an integrated base assembly and filter element mount in accordance with a second preferred embodiment of the present invention.

FIG. 13B is a perspective view of another modified embodiment of the integrated base assembly and the filter element lens holder of the camera module according to the second preferred embodiment of the present invention. FIG.

Figure 13C is an exploded view of Figure 13B.

Figure 14 is a cross-sectional view of a camera module in accordance with a third preferred embodiment of the present invention.

15A and 15B are cross-sectional views of different orientations of a camera module in accordance with a fourth preferred embodiment of the present invention.

16A and 16B are cross-sectional views of different orientations of a camera module in accordance with a fifth preferred embodiment of the present invention.

17A and 17B are cross-sectional views showing different directions of a camera module according to a sixth preferred embodiment of the present invention.

18A and 18B are cross-sectional views showing different directions of a modified embodiment of a camera module according to a sixth preferred embodiment of the present invention.

19A and 19B are cross-sectional views showing different directions of a camera module according to a seventh preferred embodiment of the present invention.

Figure 20A is a cross-sectional view of a camera module in accordance with an eighth preferred embodiment of the present invention.

Figure 20B is a cross-sectional view of another camera module in accordance with an eighth preferred embodiment of the present invention.

Figure 21 is an exploded perspective view of a camera module in accordance with an eighth preferred embodiment of the present invention.

Figure 22 is a cross-sectional view of a camera module in accordance with a ninth preferred embodiment of the present invention.

Figure 23 is a cross-sectional view showing a camera module in accordance with a tenth preferred embodiment of the present invention.

Figure 24 is a schematic illustration of an application in accordance with the above preferred embodiment of the present invention.

25A and 25B are cross-sectional views of different directions of an array camera module according to an eleventh preferred embodiment of the present invention.

Figure 26 is an exploded view of an array camera module in accordance with an eleventh preferred embodiment of the present invention.

Figure 27 is a perspective view of a joint filter element mirror mount of an array camera module in accordance with an eleventh preferred embodiment of the present invention.

28A and 28B are cross-sectional views of another array camera module in accordance with an eleventh preferred embodiment of the present invention.

29A and 29B are cross-sectional views of still another array camera module in accordance with an eleventh preferred embodiment of the present invention.

30A and 30B are schematic views showing a modified embodiment of an array camera module according to an eleventh preferred embodiment of the present invention.

Figure 31 is a cross-sectional view showing a first modified embodiment of a joint base assembly and a continuous filter element holder according to an eleventh preferred embodiment of the present invention.

Figure 32A is a cross-sectional view showing a second modified embodiment of an array camera module in accordance with an eleventh preferred embodiment of the present invention.

Figure 32B is a modified embodiment of a second modified embodiment of a joint filter element holder according to an eleventh preferred embodiment of the present invention.

Figure 32C is another modified embodiment of a second modified embodiment of the joint filter element holder according to the eleventh preferred embodiment of the present invention.

Figure 33A is a perspective view showing a third modified embodiment of the connected base assembly and the connected filter element holder of the array camera module according to the eleventh preferred embodiment of the present invention.

Figure 33B is a fourth modified embodiment of the connected base assembly and the connected filter element holder of the array camera module in accordance with the eleventh preferred embodiment of the present invention.

34A, 34B are cross-sectional views of different orientations of an array camera module in accordance with a twelfth preferred embodiment of the present invention.

35 is a perspective exploded view of a joint base and a continuous filter element lens holder of an array camera module according to a twelfth preferred embodiment of the present invention.

36A and 36B are cross-sectional views showing different aspects of a modified embodiment of a joint base and a continuous filter element lens holder of an array camera module according to a twelfth preferred embodiment of the present invention.

36C is an exploded perspective view showing a three-dimensional deformation embodiment of a joint base and a continuous filter element mirror mount of the array camera module according to the twelfth preferred embodiment of the present invention.

37A is a perspective view showing another modified embodiment of a joint base assembly and a continuous filter element lens holder of an array camera module according to a twelfth preferred embodiment of the present invention.

Figure 37B is an exploded view of Figure 37A.

38A and 38B are cross-sectional views of different directions of an array camera module according to a thirteenth preferred embodiment of the present invention.

39 is an exploded perspective view of an integrated base assembly and a filter element lens holder of an array camera module according to a thirteenth preferred embodiment of the present invention.

40A and 40B are cross-sectional views of different directions of an array camera module according to a fourteenth preferred embodiment of the present invention.

Figure 41 is an exploded perspective view showing a joint base assembly and a continuous filter element lens holder of an array camera module according to a fourteenth preferred embodiment of the present invention.

42A and 42B are cross-sectional views showing different orientations of a modified embodiment of an array camera module according to a fourteenth preferred embodiment of the present invention.

43 is an exploded perspective view of a joint base assembly and a continuous filter element lens holder of an array camera module according to a fourteenth preferred embodiment of the present invention.

44A and 44B are cross-sectional views of different directions of an array camera module according to a fifteenth preferred embodiment of the present invention.

Figure 45 is an exploded perspective view showing a joint base assembly and a joint filter element lens holder of an array camera module according to a fifteenth preferred embodiment of the present invention.

46A and 46B are cross-sectional views showing different orientations of a variant base assembly and a continuous filter element lens holder of an array camera module according to a fifteenth preferred embodiment of the present invention.

Figure 47 is an exploded perspective view showing a modified embodiment of a joint base assembly and a continuous filter element lens holder of an array camera module according to a fifteenth preferred embodiment of the present invention.

48A and 48B are cross-sectional views of different orientations of an array camera module in accordance with a sixteenth preferred embodiment of the present invention.

49 is an exploded perspective view of a joint base assembly and a continuous filter element lens holder of an array camera module according to a sixteenth preferred embodiment of the present invention.

50A and 50B are cross-sectional views of different orientations of an array camera module in accordance with a seventeenth preferred embodiment of the present invention.

Figure 51 is an exploded view of an array camera module in accordance with a seventeenth preferred embodiment of the present invention.

Figure 52 is a cross-sectional view showing an array camera module in accordance with an eighteenth preferred embodiment of the present invention.

Figure 53 is a cross-sectional view showing an array camera module in accordance with a nineteenth preferred embodiment of the present invention.

FIG. 54A is a perspective exploded view of an array camera module according to a twentieth preferred embodiment of the present invention.

Figure 54B is a cross-sectional view of an array camera module in accordance with a twenty-first preferred embodiment of the present invention.

Figure 55 is a schematic diagram of the application of the array camera module in accordance with the above preferred embodiment of the present invention.

The following description is presented to disclose the invention to enable those skilled in the art to practice the invention. The preferred embodiments in the following description are by way of example only, and other obvious variations will occur to those skilled in the art. The basic principles of the invention as defined in the following description may be applied to other embodiments, modifications, improvements, equivalents, and other embodiments without departing from the spirit and scope of the invention.

It should be understood by those skilled in the art that in the disclosure of the present invention, the terms "longitudinal", "transverse", "upper", "lower", "front", "back", "left", "right", " The orientation or positional relationship of the indications of "upright", "horizontal", "top", "bottom", "inside", "outside", etc. is based on the orientation or positional relationship shown in the drawings, which is merely for convenience of description of the present invention and The above description of the invention is not to be construed as a limitation of the invention.

It will be understood that the term "a" is understood to mean "at least one" or "one or more", that is, in one embodiment, the number of one element may be one, and in other embodiments, the element The number can be multiple, and the term "a" cannot be construed as limiting the quantity.

Molding and packaging process is an important application in the field of camera modules. Art, although it is a well-known technology in other fields, but in the field of camera modules, especially for the recent popular multi-lens, high-pixel camera module, the molding and packaging process shows its advantages and importance, and enters the appropriate application. Stage. Compared with the conventional COB package camera module, the camera module based on the molding and packaging process forms a lens holder by molding, instead of the traditional single lens holder, the size of the camera module can be reduced, and a flat mounting surface can be provided. The advantage is that the replacement lens holder formed by the molded package needs to bear the function of the original lens holder, such as the installation of the filter element. As mentioned above, the lens holder formed by the molded package is not suitable for directly mounting the filter element. On the other hand, the layout of the photosensitive elements and electronic components on the board affects the size of the camera module. According to the present invention, a camera module and an array camera module based on an integrated packaging process and a filter element lens holder thereof are provided, wherein a filter element lens holder is introduced in the camera module and the array camera module of the integrated packaging process. The filter element lens holder and the integral base are matched to bear the function of the traditional lens holder, so that the filter unit, the driver or the lens can be used on the basis of the integrated package process, such as molding. Providing good installation conditions, making up for the installation problems caused by the integrated packaging process, and more rationally arranging the various components on the circuit board, so that the space of the circuit board is fully utilized, further reducing the size of the camera module.

As shown in FIG. 2 to FIG. 4, it is a camera module according to a first preferred embodiment of the present invention. The camera module 100 can be applied to various electronic devices, such as but not limited to smart phones, wearable devices, computer devices, televisions, vehicles, cameras, monitoring devices, and the like. The electronic device implements image acquisition and reproduction of the target object.

As shown in FIG. 2 to FIG. 4, it is a camera module according to a first preferred embodiment of the present invention. The camera module 100 includes an integrated base assembly 10, a photosensitive element 20, a lens 30, a filter element mirror mount 40, and a filter element 50.

The integrated base assembly 10 includes an integral base 11 and a circuit board 12, the integral base The socket 11 is integrally packaged on the circuit board 12, and is integrally molded, for example, but not limited to, molded on the circuit board 12, and the filter element lens holder 40 is mounted on the integrated base 11, so that The mating of the integrated base 11 and the filter element holder 40 can replace the lens holder or the bracket of the conventional camera module, and does not require the lens holder or the bracket to be attached to the circuit board by glue in a similar conventional packaging process. The photosensitive element 20 is operatively coupled to the circuit board 12. The photosensitive element 20 is electrically connected to the circuit board 12 of the integrated base assembly 10, the filter element lens holder 40 is mounted to the integrated base assembly 10, and the lens 30 is located at the photosensitive element 20 photosensitive path.

The integrated base 11 has a light window 111 and a base body 112 forming the light window 111. The light window 111 provides a light path for the photosensitive element 20, and the base body 112 is molded integrally. Packaged on the circuit board 12. In particular, in this embodiment, the light window 111 is a circumferentially closed annular structure to provide a closed interior environment for the lens 30. The circuit board 12 includes a substrate 121, and a plurality of electronic components 122 formed on the substrate 121, such as by a SMT process. The electronic components 122 include, but are not limited to, resistors, capacitors, driving devices, and the like. In this embodiment of the invention, the integrated base 11 is integrally packaged on the substrate 121 and integrally wrapped around the electronic component 122 to prevent dust and debris from adhering to a conventional camera module. The photosensitive element 20 is contaminated on the electronic component 122 to affect the imaging effect. It can be understood that, in another modified embodiment, it is also possible that the electronic component 122 is buried in the substrate 121, that is, the electronic component 122 may not be exposed. The substrate 121 of the circuit board 12 may be a PCB hard board, a PCB soft board, a soft and hard bonding board, a ceramic substrate, or the like. It should be noted that in the preferred embodiment of the present invention, since the integrated base 11 can completely cover the electronic components 122, the electronic component 122 may not be buried in the substrate 121. The substrate 121 is only used to form a conductive line, so that the resulting integrated base assembly 10 is made smaller in thickness.

It is to be noted that, in some embodiments, the electronic component 122 is disposed around the photosensitive element 20, and in different embodiments, the electronic component 122 can be disposed according to requirements. The design layout, such as focusing on one side or both sides, can be matched with the position of the photosensitive member 20 and the position of the subsequent electrical connection member 203 and the shape of the filter element holder 40, thereby making more rational use. The spatial position on the substrate 122 minimizes the size of the camera module. It should be understood by those skilled in the art that the location and type of the electronic component 122 are not limited by the present invention. It is worth mentioning that, in actual cross-section, due to the different positions of the electronic components 122, the electronic components may not be visible in the cross-sectional view or may only see one side, but in this In the drawings of the invention, the electronic component 122 is visible in cross section for ease of understanding and explanation, and the invention is not limited in this respect.

More specifically, the substrate 121 has an upper surface 1211 opposite to the lens 30, and a lower surface 1212 opposite the direction of the lens 30. The photosensitive element 20 includes a front surface 201 and a back surface 202 opposite to the lens 30 for performing photosensitivity, and the back surface 202 is opposite to the lens 30 for bonding to The upper surface 1211 of the substrate 121. The photosensitive element 20 is electrically connected to the substrate 121 through at least one electrical connection element 203. The electrical connection element 203 is by way of example but not limited to gold wire, silver wire, copper wire, aluminum wire. The electrical connection element 203 may be disposed on one side, two sides, three sides or four sides of the photosensitive element 20. In some drawings of the present invention, the embodiment in which the four sides of the electrical connection element 203 are disposed is The example is illustrated, but in other embodiments, the electrical connection element 203 can be set to one side, two sides or three sides as needed, and those skilled in the art should understand that the number of the electrical connection elements 203 is set. The location, type, and not limitation of the invention.

The manner in which the photosensitive element 20 is mounted on the substrate 121 is exemplified by, but not limited to, SMT The process (Surface Mount Technology) is electrically connected to the substrate 121 by a COB (Chip On Board) gold wire. Of course, in other embodiments of the present invention, the photosensitive element 20 is mounted on the substrate 121 by other means, such as embedding, FC (Flip Chip), etc. It should be understood by those skilled in the art that the manner in which the photosensitive member 20 and the circuit board 12 are connected and mounted is not a limitation of the present invention.

More specifically, the front surface 201 of the photosensitive member 20 has a photosensitive region 1311 and a non-sensitive photosensitive region 1312. Specifically, the non-sensitive photosensitive region 1312 surrounds the periphery of the photosensitive region 1311. The photosensitive region 1311 is configured to perform a photo-sensing action to convert an optical signal into an electrical signal, and the non-photosensitive region 1312 is electrically connected to the circuit board 12 through the electrical connection element 203, and the electrical signal is transmitted to the Circuit board 12. The lens 30 is optically aligned with the photosensitive element 20, and the optical axes are aligned such that light passing through the lens 30 can reach the photosensitive element 20 via the light window 111, and further pass through the photosensitive element 20 After the photoelectric conversion, an electrical signal can be transmitted to the circuit board 12, thereby causing the camera module 100 to acquire image information.

As shown in FIG. 2 and FIG. 3, the camera module 100 includes a filter element 50 for filtering light passing through the lens 30. The filter element 50 is exemplified by, but not limited to, an infrared cut filter, a blue glass filter, a wafer level infrared cut filter, a full transparency, and a visible light filter. The filter element 50 is mounted to the filter element holder 40 and is located in the light path of the photosensitive element 20. The camera module may further include a driver 60 such as a voice coil motor, a piezoelectric motor, or the like. The lens 30 is mounted on the driver 60 to form a dynamic focus camera module, that is, an AF (Auto Focus) camera module. The driver 60 includes at least one pin 61 through which the driver 60 is operatively coupled to the circuit board 12. The pin 61 can be one of a single pin, a two pin, a single row pin, or a double row pin. In some of the drawings of the present invention, the two pins are exemplified, but are not limited. The pin 61 is usually The position near the edge is a cross-sectional view corresponding to the position corresponding to the AA line in the position of FIG. 3, corresponding to the cross-sectional view of FIG. 2, and the pin 61 is not actually visible in the cross-sectional view corresponding to FIG. 2, but for ease of understanding and explanation, The presence of pin 61 is indicated by a dashed line in the corresponding cross-section. It will be understood by those skilled in the art that the type, shape and location of the pins 61 are not limiting of the invention.

As shown in FIGS. 2 to 4, the filter element 50 is mounted to the filter element mirror mount 40 and sinks into the light window 111 of the integrated base 11. The integrated base 11 of the integrated base assembly 10 has a top surface 113 to which the filter element mount 40 is mounted, the driver 60 being mounted In the filter element lens holder 40. According to this embodiment of the invention, the top surface 113 of the unitary base 11 extends in a plane. In other words, the integral base 11 forms a platform structure without stepped projections, and the filter element mirror mount 40 is mounted to the platform structure. It is worth mentioning that in this manner, the top surface 113 of the unitary base 11 extends in a plane without significant bending angle, so that in the process of integral packaging, such as molding, A smoother, burr-free mounting surface is obtained that provides flat mounting conditions for the filter element mount 40.

It is worth mentioning that the filter element 50, such as a blue glass filter, is a relatively fragile and relatively expensive component that is easily broken, thus protecting the filter element 50 during the manufacturing process of the camera module. An important aspect. In the present invention, the integrated base 11 is made by molding, such as injection molding or molding, and the filter element lens holder 40 is not limited in material, as long as it has sufficient strength to mount the filter element 50. . Preferably, the filter element holder 40 and the unitary base 11 can be manufactured by different manufacturing processes, such as the injection molding process to form the filter element holder 40, and by transfer molding. The integral base 11 can thus adopt different materials, so that the filter element mirror base 40 and the integrated base 11 have different hardnesses, and the surface flexibility is different, for example, the filter element lens holder can be made 40 has better flexibility so that when the filter element 50 is mounted to the filter element holder At 40 o'clock, the stress applied to the filter element holder 40 is less affected than in the case of being mounted on the integral base 11, so that the filter element 50 is more suitably mounted, so that the filter element 50 is damaged or appears to be fragmented. That is, the filter element holder 40 relieves external stresses that the filter element 50 may be subjected to, such as stresses that are directly applied to the unitary base 11.

Further, the filter element lens holder 40 has at least one support groove 41 for mounting the filter element 50, and at least one engagement groove 42 for mounting on the integrated body. Base 11. The support groove 41 communicates with the light window 111 to form a receiving opening 411 for accommodating the filter element 50. The engagement groove 42 surrounds the periphery of the bottom of the filter element holder 40. In other words, the filter element holder 40 has the receiving opening 411 for accommodating the filter element 50 such that the filter element 50 is located in the photosensitive path of the photosensitive element 20.

It is worth mentioning that the filter element 50 is mounted on the support groove 41, and the relative height of the filter element holder 40 is lowered, so that the filter element 50 does not protrude or protrudes less. The filter element lens holder 40 does not increase the height of the camera module 100 and is less likely to touch the lens 50 or the driver 60.

In other words, the support groove 41 forms an inner loop to facilitate mounting the filter element 50 inside the filter element holder 40, the light path of the photosensitive element 20. The engagement groove 42 defines an outer loop for facilitating outward engagement to the unitary base 11 through which the filter element mount 40 is provided with a mounting position.

More specifically, the shape of the engaging groove 42 is matched with the shape of the integral base 11 in order to stably mount the filter element holder 40 to the integral base 11.

Further, referring to FIG. 2 to FIG. 4, the filter element lens holder 40 includes a filter element lens holder body 43, at least one inner extension arm 44, and at least a lower sink arm 45, and the sinker arm 45 is Filter element The mirror main body 43 extends integrally and longitudinally in a directional manner so that the mounting position of the filter element 50 sinks into the light window 111. The inner extension arm 44 is steerably and laterally extended from the sinking arm 45 to provide a horizontally mounted mounting position for the filter element 50 such that the filter element 50 and the photosensitive element 20 are The optical axes are identical. In the illustrated example, the filter element mount 40 includes four integrally connected inner extension arms 44 and four integrally connected said sink arms 45, each of said inner extension arms 44 and each of said The sinker arm 45 extends at different locations to form the filter element mount 40 that is annularly integral.

In other words, the sinking arm 45 extends longitudinally integrally to the inner side of the filter element mirror main body 43, and the engaging groove 42 is formed on the bottom side of the filter element mirror main body 43 so as to be joined to The integral base 11, the inner extension arm 44 extends laterally to the inner side of the sinker arm 45, and the support groove 41 is formed on the top side of the inner extension arm 44 to facilitate supporting the filter Element 50.

In an embodiment, the shape of the engaging groove 42 of the filter element holder 40 is the same as the shape of the light window 111 formed by the integrated base 11, and the shape of the support groove 41 is The shape of the filter element 50 is uniform. In particular, the filter element 50 has a square structure, and the top view of the support groove 41 is an annular structure, such as a square ring shape.

The filter element holder 40 has the receiving opening 411 for accommodating the filter element 50 such that the filter element 50 is located in a photosensitive path of the photosensitive element 20. Specifically, the lens holder body 43 and the inner extension arm 44 form the receiving opening 411, that is, the extension length of the inner extension arm 44 determines the minimum area required for the filter element 50. It is worth mentioning that in the molding and packaging process, since the inner extension arm 44 cannot be formed, the area of the filter element required is large, or the area of the filter element required for the conventional mirror holder is increased. In the present invention, the inner extension arm 44 extends inwardly, thereby reducing the required area of the filter element 50, so that the advantages of the filter element mirror mount 40 and the advantages of the integrated package are combined.

For example, referring to FIG. 2, the distance between the inner extension arms 44 on opposite sides is denoted by L, and the diameter of the filter element 50 only needs to be greater than L, so that it can be mounted on the inner extension arm 44. It is not necessary to be mounted on the base body 112, so that the required area of the filter element 50 is reduced.

It is to be noted that the extending distance of the sinking arm 45 affects the sinking depth of the filter element 50 in the light window 111, and the extending distance of the inner extending arm 44 affects the filter installed. The size of the area of the optical element 50. For example, when the extending distance of the sinking arm 45 is larger, the position of the filter element 50 in the light window 111 is more downward, and the distance from the photosensitive element 20 is smaller, and the corresponding position is The smaller the back focal length of the camera module 100 is, the smaller the extending distance of the inner arm 44 is, the smaller the receiving port 411 of the filter element lens holder 40 is, and the required filter element 50 is required. The smaller the area, the easier it is to obtain the suitable filter element 50, and the installation is convenient, and the cost of the camera module 100 is reduced. Of course, the extending distance of the sinking arm 45 needs to be combined with the imaging effect of the camera module, such as reducing the back focal length without causing dark spots, such as dust images; and the inner extending arm 44 The extending distance needs to consider factors such as the light path of the camera module 100 and the photosensitive area 1311 and the non-photosensitive area 1312 of the photosensitive element 20 and the remaining width of the circuit board 12, such as in the inner extension arm 44. When extending inwardly, in the case where the filter element 50 is small, the inner extension arm 44 does not block the photosensitive region 1311 of the photosensitive element 20, and does not excessively block the incoming light flux, and It may extend more in the remaining wide position of the circuit board 12 package, and extend less in the position where the remaining width of the circuit board 12 is smaller, so as to ensure the imaging quality is minimized. The area of the filter element 50.

The shape of the filter element mirror mount 40 is shown to match the shape of the unitary base 11. In some embodiments, the unitary base 11 is an approximately regular symmetrical structure, such as a square ring shape. Accordingly, the filter element lens holder 40 has a symmetrical structure, and the filter element lens holder body 43 has a regular shape. Each of the inner extension arms 44 has the same shape, and each of the sink arms 45 has the same shape. In other embodiments, due to the need for a package The positions of the covered electronic components 122 are different, and the interior of the integrated base 11 has a position protruding inward, and the width is different. Accordingly, the filter element lens holder main body 43 can be provided with corresponding grooves. The position of the projection or the length of the inner extension arm 44 is adapted to accommodate the shape of the unitary base 11, to accommodate the position of the photosensitive member 20, and to facilitate mounting of the filter element 50.

In some embodiments, the filter element lens holder 40 can be attached to the unitary base 11 by glue bonding, and the flatness of the filter element lens holder 40 can be adjusted by the glue thickness.

It is worth mentioning that in this embodiment of the invention, the integral base 11 is encapsulated on the upper surface 1211 of the circuit board 12, and in other embodiments of the invention, the integrated base 11 may extend to the side and/or bottom surface of the circuit board 12, and it will be understood by those skilled in the art that the integral forming range of the unitary base 11 is not a limitation of the present invention.

In an embodiment, in the assembly process of the integrated base assembly 10 and the filter element holder 40 of the camera module 100, referring to FIG. 4, the integrated body is first formed on the substrate 121. The susceptor 11 is then mounted on the filter element holder 40, and the filter element holder 40 with the filter element 50 is mounted on the integrated base 11 Thereby, the mounting process of the filter element 50 is relatively conveniently completed.

It is also worth mentioning that, in this embodiment of the invention, the substrate 121 is in the form of a flat plate, and the photosensitive member 20 is attached to the upper surface 1211 of the substrate 121. In another embodiment, the substrate 121 may have an inner groove, and the photosensitive member 20 is received in the inner groove to reduce the height of the photosensitive member 20 from the substrate 121. In another embodiment, the substrate 121 may have a through hole communicating with both sides of the substrate 121, and the photosensitive element 20 is received in the through hole, so that the photosensitive element 20 and the substrate The relative position of 121 is adjustable, such as the photosensitive element The upper surface of the member 20 is disposed in correspondence with the upper surface 1211 of the substrate 121 or the lower surface of the photosensitive member 20 is disposed in correspondence with the lower surface 1212 of the substrate 121. In another embodiment, the substrate 121 may have a via, the via is a stepped structure, and the photosensitive element 20 is mounted to the via by flip chip mounting. In another embodiment, the substrate 121 may have a reinforcing hole, and the integral base 11 extends into the reinforcing hole to enhance the structural strength of the integrated base 11 assembly 10. In another embodiment, the circuit board 12 includes a backing plate that is laminated on the bottom of the substrate 121 to enhance the structural strength and heat dissipation performance of the integrated base assembly 10. The backing plate is exemplified by, but not limited to, a metal plate. In another embodiment, the integrated base assembly 10 includes an electromagnetic shielding layer, and the shielding layer is wrapped around the outer base 11 or around the inner side to enhance the electromagnetic resistance of the camera module 100. Interference ability. In other embodiments of the invention, the circuit board 12 may have various other variations to increase or enhance the different performance of the integrated base assembly 10. Those skilled in the art will appreciate that the circuits described above The structural deformation of the panel 12 is not a limitation of the present invention.

In the above embodiment of the invention, the filter element holder 40 is mounted to the integral base 11, and the driver 60 is mounted to the filter element holder 40, that is, the filter The light element mirror mount 40 is disposed between the driver 60 and the integral base 11. In another variant embodiment of the invention, referring to FIG. 5, the filter element mirror mount 40 and the driver 60 are both mounted to the top surface 113 of the unitary base 11. Further, the filter element lens holder 40 is mounted at an adjacent inner position of the unitary base 11, and the driver 60 is mounted at a position adjacent to the outer side of the unitary base 11, whereby the driver 60 and the The filter element mirror mount 40 coordinates the dispensing of the top surface 113 of the unitary base 11.

It is to be noted that, in the above preferred embodiment of the present invention, the camera module 100 includes the driver 60, and the lens 30 is mounted on the driver 60 to form an automatic adjustment. In the other embodiment of the present invention, referring to FIG. 6, the camera module 100 does not include the driver 60, and forms a certain focus camera module, that is, FF (Fix). Focus) The camera module is directly mounted to the filter element mirror mount 40. It should be understood by those skilled in the art that the type of the camera module 100 is not a limitation of the present invention.

It should be understood by those skilled in the art that the filter element lens holder 40 of the present invention can be manufactured in the manner of manufacturing a conventional lens holder, and the size of the filter element lens holder 40 is designed according to the size of the integrated base 11. . For example, the filter element holder 40 can be manufactured by injection molding or by a combination, such as by bonding.

It is to be noted that the portions of the filter element holder 40, that is, the filter element holder main body 43, the inner extension arm 44, and the sinking arm 45 may be integrally formed of the same material. It can also be a different material. For the sake of clarity in the drawings, the various parts are represented by different line shading, but are not limited by material or structure.

It is also worth mentioning that the filter element lens holder 40 can be used to mount the filter element 50, and can also be used to mount the lens 30 or the driver 60, as will be understood by those skilled in the art. The mounting member on the filter element holder 40 is not a limitation of the present invention.

As shown in Figure 7, a first modified embodiment of an integral base assembly and filter element mount in accordance with a first preferred embodiment of the present invention. In this embodiment, the unitary base 11A internally extends obliquely upward to form the light window 111A whose opening is gradually increased. More specifically, the integrated base 11A has an inner side surface 114A, and the inner side surface 114A forms an inclination angle α with the central optical axis of the camera module 100, so that the opening of the light window 111A is gradually increased. In order to facilitate the manufacturing of the integral base 11A. Wherein the size of α ranges from 3° to 30°. In some embodiments, the value of α is selected from 3° to 15°, 15° to 20° or 20° to 30°. Correspondingly, the connection of the filter element lens holder 40A The engaging groove 42A has an engaging angle α 1, which corresponds to the inclined angle α, so that the shape of the engaging groove 42A is adapted to the inclined shape of the inner side surface 114A, so that the filtering The optical element mirror mount 40A is more stable to install.

In other words, the sinking arm 45A extends obliquely downward from the filter element holder main body 43A, thereby forming the engagement angle α 1 adapted to the inclination angle α. Further, in an embodiment, the inner extension arm 44A is steered and horizontally extended at the sinking arm 45A to form a support angle β, and the support angle β is greater than 90° to facilitate the filter element 50. installation. Of course, the filter element holder 40 without the engagement angle α 1 and the support angle β can also be mounted on the integral base 11 with the inclination angle α.

As shown in Fig. 8A, a second modified embodiment of the unitary base assembly and the filter element holder according to the first preferred embodiment of the present invention. The filter element lens holder 40B has a support groove 41B that communicates with the light window 111 of the integrated base 11B to provide a mounting position for the filter element 50. In other words, the filter element 50 is mounted to the support groove 41B.

Further, the filter element lens holder 40B includes a filter element lens holder main body 43B and at least one inner extension arm 44B, and the inner extension arm 44B is integrally laterally oriented from a lower portion of the filter element lens holder main body 43B. The inner extension extends to form the support groove 41B. The filter element mirror main body 43B is joined to the integral base 11.

That is, the filter element lens holder 40B does not include the sinker arm 45, and does not have the engagement groove 42, so that the mounting position of the filter element 50 does not sink with respect to the above embodiment. In the light window 111, but by the extension distance of the inner extension arm 44B, the required area of the filter element 50 can also be reduced, and the filter element 50 is accommodated in the support groove 41B. The relative height of the filter element 50 and the filter element holder main body 43B is lowered.

Figure 8B is a modified embodiment of a second modified embodiment of the filter element mirror mount of the first preferred embodiment of the present invention. The filter element lens holder 40B1 has a support groove 41B1 and a mounting groove 48B1 groove for respectively providing the lens 30 and the filter element 50 with a mounting position.

Further, the filter element holder 40B1 includes a filter element holder main body 43B1 and at least one inner extension arm 44B1 which are integrally laterally oriented from a lower portion of the filter element holder main body 43B1. The inner extension extends to form the support groove 41B1 and the mounting groove 48B1. The filter element holder 40B1 further includes a lens portion 49B1 that integrally extends upward from the filter element holder main body 43B1 to accommodate the lens 30. In this embodiment of the invention, the filter element 50 is attached to the inner extension arm 44B1 in an inverted manner.

Further, in this embodiment of the invention, the lens portion 49B1 is internally flat, non-threaded and adapted to mount a lens 30 that is unthreaded.

That is to say, when the camera module 100 is a fixed focus camera module, the lens 30 can be directly mounted inside the filter element lens holder 40B1 to limit the lens 30. In particular, there is a gap between the lens portion 49B1 and the lens 30 to facilitate mounting and adjustment of the lens 30 before being fixed in place.

Figure 8C is another modified embodiment of a second modified embodiment of the filter element mirror mount in accordance with the first preferred embodiment of the present invention. The filter element lens holder 40B2 has a support groove 41B2 and a mounting groove 48B2 for respectively providing the lens 30 and the filter element 50 with a mounting position.

Further, the filter element lens holder 40B2 includes a filter element lens holder main body 43B2 and at least one inner extension arm 44B2, and the inner extension arm 44B2 is integrally laterally oriented from a lower portion of the filter element lens holder main body 43B2. The inner extension extends to form the support groove 41B2 and the mounting groove 48B2. The filter element lens holder 40B2 further includes a lens portion 49B2 that is integrated from the filter element lens holder main body 43B2. The ground extends upward to facilitate accommodation of the lens 30. In this embodiment of the invention, the filter element 50 is attached to the inner extension arm 44B2 in an inverted manner.

Further, in this embodiment of the invention, the lens portion 49B1 has a threaded structure inside, which is adapted to mount a threaded lens 30.

That is to say, when the camera module 100 is a fixed focus camera module, the lens 30 can be directly mounted inside the filter element lens holder 40B2, thereby limiting the lens 30.

It should be noted that the above two embodiments are merely illustrative of possible deformation modes of the filter element lens holder, and the lens 30 can be directly mounted inside the filter element lens holder 40B1, 40B2. , but not limited.

As shown in Fig. 9A, a third modified embodiment of the filter element holder according to the first preferred embodiment of the present invention is shown. In this embodiment, the filter element lens holder 40 has at least one corner opening 441C, which is disposed at a corner position of the filter element lens holder 40 to facilitate the filter element 50. The installation reduces the edge shadow caused by the sharp corners in the imaging of the camera module. More specifically, the adjacent two inner extension arms 44C form a corner opening 441C that extends outwardly to increase the luminous flux of the camera module at the corner position of the filter element mirror mount 40. In other words, the adjacent inner extension arm 44C forms an outwardly extending corner opening 441C to increase the luminous flux of the filter element holder 40 at the position of the corner opening 441C, reducing edge shadow.

Specifically, in an embodiment, the corner opening 441C may be an expanded square corner, and for example, but not limited to, four corresponding extended square corners are disposed at four corner positions of the filter element mirror base 40. In other embodiments, the corner opening 441C may also be an arcuate angle that increases the luminous flux at the corner of the filter element mount 40. Of course, in some embodiments, the corner opening 441C may not be provided, and those skilled in the art should understand that the shape, the number, and the position of the corner opening 441C are It is not a limitation of the invention.

As shown in Fig. 9B, there is shown a modified embodiment of the first preferred embodiment of the present invention. The filter element lens holder 40 includes at least one limiting protrusion 46P extending at least partially and convexly upward from the top of the filter element lens holder 40. Further, the limiting protrusion 46P extends at least partially and convexly from the top surface of the filter element mirror main body 43 to limit the mounted components, block dust or light from entering the camera module. . The limit protrusion 46P is exemplified, but not limited to, limiting the driver 60 or the lens 30. In particular, in an embodiment, the limiting protrusion 46P is disposed at an intermediate portion of the lens holder main body 43 to divide the top of the lens holder main body 43 into two parts, and the outer side is for mounting the driver 60. The lens 30 is located on the inner side. In this manner, the limit projection 46P can position the driver 60 to reduce the offset of the driver 60. And during the assembly process, the glue that mounts the driver 60 can be prevented from overflowing to the inside and contaminating the lens or internal components. In particular, the limiting projection 46P may be an annular projection to position the driver 60 as a whole to block the glue from overflowing into the interior.

It should be noted that in other embodiments of the present invention, the surface of the limiting protrusion 46P may be provided with a thread to facilitate direct mounting of the lens 30. And when the outer side of the limiting protrusion 46P is provided with a thread, the lens 30 is adapted to a larger aperture.

10A to 11 are a camera module and an integrated base assembly and a filter element lens holder according to a second preferred embodiment of the present invention. The integrated base 11D includes a base body 112D forming at least one light window 111D to provide a light path for the photosensitive element 20. Further, the base body 112D has at least one opening 1121D that communicates with the light window 111D and the outside, and the filter element lens holder 40D is supplemented to the opening 1121D, thereby forming the side closed light. Window 111D.

In other words, in such an embodiment, the base body 112D is not a closed structure, but an open structure, and the base body 112D is closed by the supplement of the filter element lens holder 40D.

The filter element mirror mount 40D includes at least one extension leg 433D that extends integrally downward from the filter element mount body 43D to the substrate 121 to close the opening 1121D. By way of example and not limitation, the extension leg 433D is attached to the substrate 121 and/or the base body 112 by adhesive bonding.

Specifically, the base body 112D forms a U-shaped structure, the filter element mirror body 43 is joined to the U-shaped structure of the base body 112D, and the extension of the filter element lens holder 40D The leg 433D is supplemented to the open position of the U-shaped structure such that the unitary base 11D is closed to form a closed inner environment.

In other words, in this embodiment, the integrated base 11D and the filter element holder 40D share the function of the lens holder of the camera module, so that the advantages of the integrated package and the function of the filter element holder 40D Combine.

It is worth mentioning that, due to the increasing size requirements of the camera module, the arrangement of the electronic components 122 of the circuit board 12, the installation position of the electrical connection component 203, and the integrated base The package position and the like of the seat 11 need a reasonable arrangement, and the component layout area is minimized while the substrate 121 is fully utilized, thereby further reducing the size of the camera module. According to this embodiment of the present invention, the electronic component 122 is integrally packaged in the direction in which the electronic component 122 is disposed, and the electronic component 122 is covered, and the spatial position of the electronic component 122 is utilized to simultaneously reduce the electronic component. The electromagnetic effect between the 122 and the electrical connection element 203, and the extending leg 433D of the filter element lens holder 40D is disposed on the side where the electronic component 122 is not disposed, and the substrate 121 is fully utilized. Remaining position. On the other hand, the flatness of the integrated base 11D can be adjusted and supplemented by the bonding process of the filter element holder 40D to provide good mounting conditions for the camera module.

It is also worth mentioning that the photosensitive element 20, the electronic component 122, the electrical connection component 203, the integrated base 11D, and the filter component lens mount 40D need to be disposed on the substrate 121. The electronic component 122, the electrical connection element 203, the integrated base 11D, and the filter element mirror mount 40D are disposed at the periphery of the photosensitive element 20. In other words, the substrate 121 has a plurality of mounting regions 1213 that surround the outside of the photosensitive element 20. In order to improve the space utilization on the substrate 121, in some embodiments, the electronic component 122 is collectively disposed on the mounting area 1213 on one side of the substrate 121 or the mounting area on both sides. 1213, wherein the mounting area 1213 of the electronic component 122 is integrally packaged by the integrated base 11D, and the electronic component 122 is covered by the integrated base 11D, and Providing the electronic component 122 and/or an area adjacent to the mounting area 1213 of the electrical connection element 203, connecting the filter element mirror mount 40D, thereby utilizing the substrate through the filter element mirror mount 40D In a narrower position on 121, the filter element mirror mount 40D and the integral base 11D are mated and form the light window 111D to provide a light path for the photosensitive element 20. That is to say, the photosensitive member 20 may not be disposed at a central position of the substrate 121, but may be biased to one side to form the mounting region 1213 of different widths, thereby facilitating the centralized arrangement of the electronic component 122. Further, the extending leg 433D of the filter element mirror holder 40D is connected to a narrower position where the electronic component 122 and the electrical connection component 203 are not disposed, and the wider mounting area 1213 is mounted. The electronic component 122 and the electrical connection component 203 are described, and the integrated base 11D is integrally formed to cover the electronic component 122. For example, the width of both sides of the photosensitive element is W1 and W2, W1 is smaller than W2, and the extended leg 433D of the filter element lens holder 40D is connected on the narrower W1 side, and on the wider W2 side. Setting the electronic component 122 such that the electronic The components 122 are collectively disposed on a wider side.

By way of example and not limitation, in some embodiments, the assembly process of the unitary base assembly 10 may be prior to attaching the photosensitive element 20 to the substrate 121 and disposed in the design of the photosensitive element 20. a mounting position, such as mounting the mounting area 1213 forming a different width adjacent to one side, and then mounting the electronic component 122 in the mounting area 1213, such as the wider mounting area, the advancement is at least The mounting area 1213 of the electronic component is integrally packaged to form the integrated base 11D, and then the filter element mirror mount 40D is mounted to the integrated base 11D. In another embodiment, the electronic component 122 may be attached to the predetermined position, such as the predetermined mounting area 1213, and then the integrated base 11D is formed, and then the photosensitive element 20 is mounted. .

It is also worth mentioning that the filter element mirror mount 40D can be manufactured by injection molding, so that a smaller wall thickness can be obtained with respect to the manner of molding the integral base 11D, that is, the The thickness d1 of the extending leg of the filter element mirror holder 40D may be smaller than the thickness d2 of the integral base, so that each of the mounting regions 1213 of different widths of the substrate 121 can be utilized more rationally.

As shown in Figures 12A through 13A, there is shown a modified embodiment of an integral base assembly and filter element mount in accordance with a second preferred embodiment of the present invention. The integrated base 11E includes a base body 112E that forms at least one light window 111E to provide a light path for the photosensitive element 20. Further, the integrated base 11E has two openings 1121E, each of the openings 1121E is connected to the light window 111E and the outside, and the filter element lens holder 40E supplements the two openings 1121E, and the light window 111E is The side is closed.

The filter element mirror mount 40E includes two extending legs 433E that extend integrally downward from the filter element mount body 43E to the substrate 121 to close each of the openings 1121E. By way of example and not limitation, each of the extension legs 433E is attached to the base by bonding Plate 121 and/or the base body 112E.

More specifically, in an embodiment, the base body 112E is a parallel structure, the filter element mirror main body 43E is joined to the parallel structure of the base body 112E, and the filter element mirror mount 40E The extension leg 433E is supplemented to the open end positions of the parallel structure such that the base body 112E closes to form a closed inner environment.

As shown in Figures 13B and 13C, there is shown another alternative embodiment of an integral base assembly and filter element mount in accordance with a second preferred embodiment of the present invention. In this embodiment, the integrated base 11Q includes a base body 112Q that forms at least one light window 111Q to provide a light path for the photosensitive element 20. Further, the integrated base 11Q has two openings 1121Q, each of the openings 1121Q is connected to the optical window 111Q and the outside, and the filter element lens holder 40Q is supplemented by the two openings 1121Q, and the optical window 111Q Closed around. Different from the above embodiment, the two openings 1121Q are opposite in position and have an inverted trapezoidal structure to facilitate positioning and mounting of the filter element mirror holder 40Q. In other words, the two openings 1121Q divide the base body 112Q into opposite portions, and when the filter element mirror holder 40Q is mounted to the base body 112Q, the base body 121Q The two parts are closed by the filter element holder 40Q.

Correspondingly, the filter element lens holder 40Q includes two extending legs 433Q, each of the extending legs 433Q integrally extending downward from the filter element mirror body 43Q to the substrate 121 to facilitate the opening 1121Q closed. Specifically, the two extension legs 433Q are oppositely disposed and have an inverted trapezoidal structure, and are adapted to be supplemented to the opening 1121Q. For example, when the filter element mirror mount 40Q is mounted, the extension leg 433Q is limited to the opening 1121Q. That is, each of the openings 1121Q is gradually increased from the bottom to the upper opening, and the extending leg 433Q is gradually widened from the bottom to the top, supplementing the opening 1121Q, thereby closing the opening 1121Q.

It should be understood by those skilled in the art that the shape and size of the opening 1121Q in the embodiment of the present invention are merely illustrative of the manner in which it can be implemented, and are not limiting of the present invention.

In particular, in some embodiments, the electronic component 122 can be collectively disposed on one side and covered by at least a portion of the base body 112Q and covered by the wider base body 112Q. The side on which the electronic component 122 is not disposed corresponds to the narrower base body 112Q. The filter element mirror mount 40Q is mounted on the base body 43Q, and the extension leg 433Q is supplemented by the opening 1121Q between the two portions.

Further, the base body 112Q has at least one opening surface 1122Q, and the opening 1121Q is formed with respect to the two opening surfaces 1122Q. The opening surface 1122Q extends obliquely integrally from the substrate 121 so as to form the opening 1121Q of the inverted trapezoid. Correspondingly, the extension leg 433Q has at least one supplementary surface 4331Q corresponding to the opening surface 1122Q, so as to complement the extension leg 433Q in a complementary manner to the opening 1121Q, The light window 111Q is closed around. It can be understood that there may be a gap between the supplementary surface 4331Q of the extending leg 433Q and the opening surface 1122Q of the opening 112Q to facilitate application of a bonding medium such as glue, but the size of the gap or The presence or absence of this is not a limitation of the present invention.

In particular, the extending leg 433Q and the complementary surface 4331Q and the opening surface 1122Q of the base body 112Q may be fixed or sealed by glue bonding.

As shown in FIG. 14, the camera module and its base assembly and filter element lens holder according to a third preferred embodiment of the present invention. The integrated base 11F has a mounting groove 115F that communicates with the light window 111F. According to this embodiment of the invention, the mounting groove 115F is an annular communication groove, and the filter element lens holder 40 is mounted to the mounting groove 115F.

Specifically, the engagement groove 42 of the filter element holder 40 is engaged with the mounting groove 115F of the integral base 11F such that the filter element holder of the filter element holder 40 The main body 43 is supported and accommodated in the 115F.

The filter element holder body 43 of the filter element holder 40 has a predetermined thickness such that it does not easily touch a member located above, such as the driver 60 or the lens 30. Preferably, when the filter element holder 40 is mounted to the mounting groove 115F, the top surface of the filter element holder 40 coincides with the top surface of the base body 112F, thereby causing the The filter element holder 40 does not protrude from the base body 112F and does not easily touch the driver 60 or the lens 30 located above. Of course, in other embodiments of the present invention, the upper surface of the filter element lens holder 40 may protrude from the base body 112F, so that the driver 60 of different sizes may be matched to limit the driver 60. And the glue is prevented from overflowing to the inside when the driver is mounted, and the present invention is not limited in this respect.

More specifically, the unitary base 11F includes a plurality of raised steps 116F protruding from the base body 112F. The raised step 116F extends upwardly from the base body 112F to form the mounting groove 115F. In other embodiments of the invention, an annular integral step 116F can be used to form the mounting groove 115F.

According to this embodiment of the invention, the unitary base 11F includes four of the raised steps 116F, each of the raised steps 116F being steerably integrally closedly connected to form an annular raised structure. The driver 60 is at least partially mounted to the raised step 116F to form a dynamic focus camera module. The driver 60 is operatively coupled to the circuit board 12 by at least one pin 61. In other embodiments, the lens 30 is at least partially mounted to the raised step 116F to form a fixed focus camera module.

In this embodiment of the invention, the lateral widths of the raised steps 116F are uniform, The width of the mounting groove 115F formed is uniform, and accordingly, the width of the filter element mirror main body 43 of the filter element lens holder 40 can be designed according to the size of the support groove 41, and the filter element The width of the mirror main body 43 in each direction is uniform. In other embodiments of the present invention, the width of the convex step 116F may be changed according to requirements. Accordingly, the width of the filter element mirror main body 43 may be designed according to the width of the mounting groove 115F.

15A and 15B, a camera module according to a fourth preferred embodiment of the present invention. The integrated base 11G has at least one mounting groove 115G and at least one notch 117G. The mounting groove 115G communicates with the light window 111G, and the notch 117G communicates with the light window 111G and the outside. In other words, the mounting groove 115G is an open communication groove and is not a closed structure. The filter element mirror holder 40G is mounted to the mounting groove 115G. More specifically, in this embodiment, the mounting groove 115G is a U-shaped groove, and the U-shaped opening corresponds to the notch 117G.

Specifically, the filter element holder 40G is coupled to the mounting groove 115G of the integral base 11G such that the filter element holder main body 43G of the filter element holder 40G is supported by the It is described in the installation groove 115G.

The filter element holder main body 43G of the filter element holder 40G has a predetermined thickness so that it does not easily touch a member located above, such as the driver 60 or the lens 30. Preferably, when the filter element lens holder 40G is mounted to the mounting groove 115G, the top surface of the filter element lens holder 40G coincides with the top surface of the base body 112G, thereby causing the The filter element holder 40G does not protrude from the base body 112G, and is not easily touched to the driver 60 or the lens 30 located above.

More specifically, the unitary base 11G includes a plurality of raised steps 116G projecting from the base body 112G. Each of the protruding steps 116G extends upward from the base body 112G to form the mounting groove 115G. At least one side of the integrated base 11G does not have the raised step 116G, the gap 117G is formed.

According to this embodiment of the invention, the integral base 11G includes three raised steps 116G, each of which is steerably integrally coupled to form each of the mounting grooves 115G. That is, the side without the convex step 116G forms the notch 117G. More specifically, the three raised steps 116G are integrally connected in a steering direction to form a U-shaped projection structure.

The filter element holder main body 43G of the filter element lens holder 40G includes at least one joint edge 431G and at least one extended side 432G for engaging the mounting groove 115G, the extended side 432G is used to fill the gap 117G. In other words, the extended edge 432G extends into the gap 117G such that the gap 117G is filled to form a closed inner environment.

According to this embodiment of the invention, the filter element holder main body 43G of the filter element holder 40G includes a three-joining edge 431G and an extended side 432G, and each of the joint side 431G and the extended side 432G is turned The ground is integrally connected to accommodate the shape of the mounting groove 115G.

The sinking arms 45G are integrally extended downward from the joint side 431G and the extended side 432G, thereby forming the engagement groove 42G. The inner extension arm 44G is laterally extended integrally from the sinking arm 45G to form the support groove 41G.

It is worth mentioning that the electronic component 122 is disposed at different positions of the main body of the circuit board 12, and the integrated base 11G covers the electronic component 122. In the position where the electronic component 122 is disposed, the integrated base 11G requires a large thickness, and the mounting groove 115G is conveniently disposed, and the position of the electronic component 122 can be set to a small thickness, thereby Reducing the size of the circuit board 12 is not suitable for forming the mounting groove 115G. According to this embodiment of the present invention, the electronic component 122 is disposed on the integrated base 11G corresponding to the three joint edges 431G, and a corresponding portion of the integrated base 11G has a large lateral thickness for forming a The installation slot 115G, and the extension The integrated base 11G on the side corresponding to the side 432G has a small lateral thickness, and is not used to form the mounting groove 115G, and the notch 117G is filled by the extended side 432G, and the convex step 116G is assumed. effect.

The driver 60 is at least partially mounted to the raised step 116G to form a dynamic focus camera module. The driver 60 is operatively coupled to the circuit board 12 by at least one pin 61. In other embodiments, the lens 30 is at least partially mounted to the raised step 116G to form a fixed focus camera module.

More specifically, the three sides of the driver 60 are mounted to the raised step 116G, and the remaining one side is mounted to the extended side 432G of the filter element mirror mount 40G. In some embodiments, there is a gap between the driver 60 and the extended edge 432G, and the gap is sealed by glue to form a closed inner environment for the camera module. In other words, the surface height of the extended side 432G is lower than the surface height of the raised step 116G, and the height difference can be supplemented by glue. In particular, the driver 60 may be attached to the raised step 116G by bonding, and the optical axis of the lens 30 and the photosensitive element 20 may coincide.

16A and 16B, a camera module according to a fifth preferred embodiment of the present invention. The integrated base 11H has at least one mounting groove 115H that communicates with the light window 111H. The filter element lens holder 40H is mounted to the mounting groove 115H. More specifically, each of the mounting grooves 115H forms a U-shaped structure, and the U-shape has no opening.

Specifically, the engagement groove 42H of the filter element lens holder 40H is engaged with the mounting groove 115H of the integral base 11H such that the filter element lens holder of the filter element lens holder 40H The main body 43H is supported in the support groove 41H.

Further, the filter element lens holder 40H has a U-shaped structure, and the U-shaped has an opening, The U-shaped structure of the filter element mirror holder 40H matches the shape formed by each of the mounting grooves 115H.

The filter element holder main body 43H of the filter element holder 40H has a predetermined thickness so that it is less likely to touch a member located above, such as the driver 60 or the lens 30. Preferably, when the filter element lens holder 40H is mounted to the mounting groove 115H, the top surface of the filter element lens holder 40H coincides with the top surface of the base body 112H, thereby causing the The filter element holder 40H does not protrude from the base body 112H, and does not easily touch the driver 60 or the lens 30 located above.

More specifically, the unitary base 11H includes a plurality of raised steps 116H protruding from the base body 112H. Each of the protruding steps 116H extends upward from the base body 112H to form the mounting groove 115H. At least one side surface of the integrated base 11H does not have the convex step 116H, and the notch 117H is formed.

According to this embodiment of the invention, the integral base 11H includes four raised steps 116H, wherein the three raised steps 116H are integrally connected in a steering manner to form the mounting groove 115H, and the other raised step 116H The base body 112H integrally extends upward and does not form the mounting groove 115H. That is, the opening of the U-shaped structure of the mounting groove 115H is blocked by one of the convex steps 116H, thereby forming a closed structure.

The filter element holder main body 43H of the filter element mirror holder 40H includes at least one joint side 431H for engaging the mounting groove 115H.

According to this embodiment of the present invention, the filter element holder main body 43H of the filter element mirror holder 40H includes three engaging edges 431H, and each of the joint sides 431H is steerably integrally coupled to form a U-shaped opening. The structure is adapted to the shape of the mounting groove 115H.

The sinking arm 45H is steered from the engaging edge 431H and integrally extends downward to form an engaging groove 42H for facilitating engagement with the mounting groove 115H. The inner extension arm 44H is from the sinking arm 45H A support groove 41H is formed to extend laterally integrally and integrally to provide a mounting position for the filter element 50. Further, unlike the above embodiment, the engagement groove 42H and the support groove 41H are U-shaped structures having openings on one side, and are not closed structures. That is, when the filter element 50 is mounted to the filter element holder 40H, only three sides are fixed, and one of the sides directly abuts against the protrusion not used to form the mounting groove 115H. The inner surface of the step 116H.

It is worth mentioning that the electronic component 122 is disposed at different positions of the main body of the circuit board 12, and the integrated base 11H covers the electronic component 122. At a position where the electronic component 122 is disposed, the integrated base 11H requires a large thickness, and the mounting groove 115H is conveniently disposed, and the position of the electronic component 122H may be set to a small thickness, thereby Reducing the size of the circuit board 12 is not suitable for forming the mounting groove 115H. According to this embodiment of the present invention, the electronic component 122 is disposed on the integrated base 11H corresponding to the three joint edges 431H, and the lateral thickness of the integrated base 11H is large, and the mounting groove 115H is disposed. And the other integrated base 11H which is not used to form the side corresponding to the convex step 116H forming the mounting groove 115 has a small lateral thickness.

The driver 60 is at least partially mounted to the raised step 116 to form a dynamic focus camera module. The driver 60 is operatively coupled to the circuit board 12 via at least one of the pins 61. In other embodiments, the lens 30 is at least partially mounted to the raised step 116H to form a fixed focus camera module.

More specifically, the driver 60 is mounted to the raised step 116H, wherein three sides are supported by the raised step 116H forming the mounting groove 115H, and the remaining side is mounted to be used for forming The raised step 116H of the mounting groove 115H is described.

In other words, unlike the preferred embodiment described above, in this embodiment, the The filter element lens holder 40H removes the extended side 432G to form an open U-shaped structure, and the convex step 116H of the integrated base 11H extends at least partially upward to form a closed U-shaped structure without forming The gap 117G.

17A and 17B are cross-sectional views of the camera module according to a sixth preferred embodiment of the present invention in two mutually perpendicular directions. Different from the above preferred embodiment, the integrated base 11I includes two convex steps 116I, and has two notches 117I, and each of the convex steps 116I is integrally connected in a steering manner to form the mounting groove 115I. That is, the notch 117I is formed without both sides of the convex step 116I.

The filter element lens holder main body 43I of the filter element lens holder 40I includes at least one joint edge 431I and at least one extended side 432I for engaging the mounting groove 115I, the extended side 432I is used to fill the gap 117I. In other words, the extended edge 432I extends into the notch 117I such that the notch 117I is filled to form a closed inner environment.

According to this embodiment of the invention, the filter element holder body 43I of the filter element holder 40I includes two engaging edges 431I and two extended sides 432I, and the joint edges 431I and the extended sides 432I are turned The ground is integrally connected to accommodate the shape of the mounting groove 115I.

The sinking arm 45I extends downwardly integrally from the engaging edge 431I and the extended side 432I, thereby forming the engaging groove 42I. The inner extension arm 44I is laterally extended integrally from the inner extension arm 44I to form the support groove 41I.

Further, the two protruding steps 116I of the integrated base 11I are adjacent to the two engaging edges 431I, and the two notches 117I are adjacent to each other. That is, the two raised steps 116I constitute an L-shaped structure, thereby forming an L-shaped mounting groove 115I. The two notches 117I are adjacent to each other to form an L-shaped structure. Correspondingly, the two engaging edges 431I of the filter element lens holder 40I are adjacent to each other and are adapted to be coupled to the L-shaped The groove 115I is adjacent to the two extending edges 432I, and is adapted to fill the notch 117I of the L-shape to form a closed inner environment.

The driver 60 is at least partially mounted to the raised step 116I to form a dynamic focus camera module. The driver 60 is operatively coupled to the circuit board 12 via at least one of the pins 61. In other embodiments, the lens 30 is at least partially mounted on the convex step 116I or the filter element mirror main body 43I to form a fixed focus camera module.

More specifically, both sides of the driver 60 are supported by the raised step 116I forming the mounting groove 115I, and the remaining two sides are mounted to the extended side 432I of the filter element holder 40I.

18A and 18B, a modified embodiment of an integral base assembly and a filter element lens holder of a camera module according to a sixth preferred embodiment of the present invention. 18A and 18B are cross-sectional views in two mutually perpendicular directions. Different from the above embodiment, the two joint edges 431J are opposite, and the two notches 117J are opposite. Correspondingly, the two engaging edges 431J of the filter element lens holder 40J are opposite to each other, and are adapted to the opposite mounting grooves 115J, and the two extending edges 432J are opposite to each other, and are adapted to fill the opposite two notches 117J. Thereby forming a closed internal environment.

19A and 19B, a camera module according to a seventh preferred embodiment of the present invention. 19A and 19B are cross-sectional views in two mutually perpendicular directions. Unlike the preferred embodiment described above, the unitary base 11K includes a raised step 116K and three notches 117K. The protruding step 116K extends partially and integrally from the base body 112K to form the mounting groove 115K. That is, the notch 117K is formed without the three sides of the convex step 116K.

The filter element mirror main body 43K of the filter element lens holder 40K includes at least one joint edge 431K and at least one extended side 432K for engaging the mounting groove 115K, the extended side 432K is used to fill the notch 117K. In other words, the extended edge 432K extends into the gap 117K such that the gap 117K is filled to form a closed inner environment.

According to this embodiment of the invention, the filter element holder body 43K of the filter element holder 40K includes a joint edge 431K and three extended sides 432K, each of the joint side 431K and the extended side 432K turning The ground is integrally connected to accommodate the shape of the mounting groove 115K and the notch 117K.

The sinking arms 45K are integrally extended downward from the engaging edge 431K and the extended side 432K, thereby forming the engaging groove 42K. The inner extension arm 44K is laterally extended integrally from the inner extension arm 44K to form the support groove 41K.

The driver 60 is at least partially mounted to the raised step 116K to form a dynamic focus camera module. The driver 60 is operatively coupled to the circuit board 12 via at least one of the pins 61. In other embodiments, the lens 30 is at least partially mounted to the raised step 116K to form a fixed focus camera module.

More specifically, one side of the driver 60 is supported by the raised step 116K forming the mounting groove 115K, and the remaining three sides are mounted to the extended side 432K of the filter element mirror holder 40K. .

20A to 21, a camera module according to an eighth preferred embodiment of the present invention. The camera module may be a fixed focus camera module. Unlike the above preferred embodiment, the filter element lens holder 40L includes an upper extension wall 46L, and the upper extension wall 46L is from the filter element. The mirror main body 43L is steered and extended upward to form a limiting port 461L. The limit port 461L is used to limit the components to be mounted, such as but not limited to the driver 60 or the lens 30. That is, when the camera module is assembled, the driver 60 or the lens 30 is mounted in the limiting port 461L of the filter element lens holder 40L, and the limit is The driver 60 or the lens 30 is such that the driver 60 or the lens 30 coincides with the optical axis of the photosensitive element 20. The size of the limiting port 461L can be determined according to the size of the component to be mounted.

In other words, the upper extension wall 46L has a frame restraining function so that when the driver 60 or the lens 30 or the like is mounted on the filter element mirror holder 40L, excessive deviation does not occur, and the imaging is ensured. The consistency of the optical system of the module. At the same time, the upper extension wall 46L can protect the mounted components, such as the driver 60 or the lens 30, from unnecessary external contact, so that the driver 60 or the lens 30 is stably mounted. Moreover, external dust can be blocked from entering the inside of the camera module.

Further, when the camera module is a moving focus camera module, referring to FIG. 20B, the filter element lens holder 40L has at least one lead port 462L for passing through the pin 61. That is, when the driver 60 is mounted on the limiting port 461L of the filter element mirror holder 40L, the driver 60 pin passes through the pin port 462L and is electrically connected to the circuit. Board 12. Of course, when the camera module is a fixed focus camera module, the filter element lens holder 40L may not be provided with the pin port 462L. It is worth mentioning that the pin port 462L may not be visible in the cross-sectional view of the actual over-center line, but for ease of explanation and understanding, the possible projection positions of the pin port 462L are indicated by dashed lines, the pin The position of the port 462L needs to be determined according to the position of the pin 61, and the present invention is not limited in this regard.

As shown in FIG. 22, it is a camera module according to a ninth preferred embodiment of the present invention. Different from the above preferred embodiment, the filter element lens holder 40M includes an upper extension wall 46M and a lower extension wall 47M. The upper extension wall 46M is turned from the filter element lens holder main body 43M to the upward direction. Extendingly, a limiting port 461M is formed, and the lower extending wall 47M is steered from the filter element mirror main body 43M and extends downward to form a lower opening 471M. In particular, the lower extension wall 47M extends integrally from the upper extension wall 46M to form an integral outer barrier wall.

The limiting port 461M is used to limit the components to be installed, for example but not limited to the driving The actuator 60 and the lens 30. The lower cover 471M is for accommodating the integrated base 11 , that is, when the camera module 100 is assembled, the driver 60 or the lens 30 is mounted on the filter element mirror 40M. The integral base 11 is received in the lower cover opening 471M, and the upper extension wall 46M is limited to block the lens 30, so that the lens 30 and the lens 30 are The optical axis of the photosensitive element 20 is uniform, and the lower extension wall 47M blocks the integrated base 11 so that the overall structure of the camera module is relatively regular, convenient for installation, and the appearance is relatively beautiful. The size of the limiting port 461M and the lower opening 471M may be determined according to the size of the component to be mounted, such as, but not limited to, the size of the driver 60, the lens 30, and the integrated base 11.

In an embodiment, the lower extension wall 47M may extend to the circuit board 12, for example, but not limited to, fixedly connected to the circuit board 12 by glue bonding, so that the filter element lens holder The 40M is installed more stably.

As shown in FIG. 23, it is a camera module according to a tenth preferred embodiment of the present invention.

The integral base 11N includes a lens wall 118N, and the lens wall 118N extends at least partially upward from the convex step 116N to form a lens chamber 1181N suitable for mounting the lens 30 to form a certain focus camera module. .

Further, the convex step 116N and the base body 112N form the mounting groove 115N for mounting the filter element mirror mount 40. The lens wall 118N and the raised step 116N form another mounting groove 115N for providing a mounting position for the lens 30. That is, in this embodiment, the integral base 11N has two of the mounting slots 115N, one of the mounting slots 115N for mounting the filter element mirror mount 40, and the other of the mounting slots 115N is used to mount the lens 30.

Further, the engagement groove 42 of the filter element holder 40 is coupled to a mounting groove 115N, and the filter element 50 is mounted to the support groove 41 of the filter element holder 40. Said The lens 30 is mounted to the other of the mounting grooves 115N.

The lens wall 118N provides a mounting position for the lens 30, and constrains the mounting position of the lens 30 such that the optical axis of the lens 30 and the photosensitive element 20 coincide, improving the accuracy of mounting.

FIG. 24 is a schematic diagram of an application of a camera module according to the above preferred embodiment of the present invention. The camera module 100 can be applied to various electronic devices 300. The electronic device 300 includes an electronic device body 200. The camera module 100 is disposed on the electronic device body 200, and cooperates with the electronic device body 200. Complete image acquisition and reproduction. The electronic device 300 is exemplified, but not limited to, a smart phone, a wearable device, a computer device, a television, a vehicle, a camera, a monitoring device, etc., and the camera module 100 cooperates with the electronic device 300 to achieve a target object. Image acquisition and reproduction. The camera module 100 is applied to a smart phone to assist the smart phone in collecting and reproducing image information.

25A through 27 are array camera modules in accordance with an eleventh preferred embodiment of the present invention. The array camera module 1000 includes a plurality of camera module units 100, and each of the camera module units 100 cooperates with each other to realize image collection. The array camera module 1000 can be applied to various electronic devices 300 by way of example but not limited to smart phones, wearable devices, computer devices, televisions, vehicles, cameras, monitoring devices, etc., and the array camera module 1000 cooperates. The electronic device 300 enables image acquisition and reproduction of a target object.

It should be noted that, for convenience of description, in the following embodiments and drawings of the present invention, an array camera module 1000 composed of two camera module units 100, that is, a dual camera array camera module is taken as an example. For example, in the other embodiments of the present invention, the array camera module 1000 may include more monomers, such as three or more, and each of the camera module units 100 is arranged in an array to form the The array camera modules 1000 are arranged, for example, in parallel.

It is also worth mentioning that the camera module 100 of the preferred embodiment 1 to the preferred embodiment 10 and the camera module and the equivalent implementation of the camera module can be used as the camera module. The camera module unit 100 is configured to form the array camera module 1000.

Specifically, the camera module unit 100 includes an integrated base assembly 10, a photosensitive element 20, a lens 30, a filter element lens holder 40, and a filter element 50.

The integrated base assembly 10 includes an integral base 11 and a circuit board 12 that is integrally packaged on the circuit board 12, such as, but not limited to, molded integrally molded on the circuit board 12. The filter element lens holder 40 is mounted on the integrated base 11 such that the integral base 11 and the filter element lens holder 40 cooperate to replace the lens mount or bracket of the conventional camera module, and There is no need to attach the lens holder or the bracket to the circuit board by glue in a similar conventional packaging process. The photosensitive element 20 is operatively coupled to the circuit board 12.

The photosensitive element 20 is electrically connected to the integral base assembly 10, and the filter element holder 40 is mounted to the integral base assembly 10, and the lens 30 is located in a photosensitive path of the photosensitive element 20.

The integrated base 11 has a light window 111 and a base body 112 forming the light window 111. The light window 111 provides a light path for the photosensitive element 20, and the base body 112 is molded integrally. Packaged on the circuit board 12. In particular, the light window 111 is a closed loop structure to provide a closed interior environment for the lens 30.

The circuit board 12 includes a substrate 121, and a plurality of electronic components 122 formed on the substrate 121, such as by a SMT process. The electronic components 122 include, but are not limited to, resistors, capacitors, driving devices, and the like. In this embodiment of the invention, the integrated base 11 is integrally packaged on the substrate 121 and integrally wrapped around the electronic component 122, thereby preventing gray like in a conventional camera module. Dust and debris adhere to the electronic component 122 and further contaminate the photosensitive element 20, thereby affecting the imaging effect. It can be understood that, in another modified embodiment, it is also possible that the electronic component 122 is buried in the substrate 121, that is, the electronic component 122 may not be exposed. The substrate 121 of the circuit board 12 may be a PCB hard board, a PCB soft board, a soft and hard bonding board, a ceramic substrate, or the like. It should be noted that in the preferred embodiment of the present invention, since the integrated base 11 can completely cover the electronic components 122, the electronic component 122 may not be buried in the substrate 121. The substrate 121 is only used to form a conductive line, so that the resulting integrated base assembly 10 is made smaller in thickness.

More specifically, the substrate 121 has an upper surface 1211 opposite to the lens 30, and a lower surface 1212 opposite the direction of the lens 30. The photosensitive element 20 includes a front surface 201 and a back surface 202 opposite to the lens 30 for performing a photo-sensing effect. The back surface 202 is opposite to the lens 30 for mounting on the surface. The upper surface 1211 of the substrate 121 is described. The photosensitive element 20 is electrically connected to the substrate 121 through at least one electrical connection element 203. The electrical connection element 203 is by way of example but not limited to gold wire, silver wire, copper wire, aluminum wire. The manner in which the photosensitive element is mounted on the substrate 121 is exemplified by, but not limited to, an SMT process (Surface Mount Technology), and is electrically connected to the substrate 121 by a COB (Chip On Board) gold wire. . Of course, in other embodiments of the present invention, the photosensitive element 20 is mounted on the substrate 121 by other means, such as embedding, FC (Flip Chip), etc. It should be understood by those skilled in the art that the manner in which the photosensitive element 20 and the circuit board 12 are connected and mounted is not a limitation of the present invention.

More specifically, the front surface 201 of the photosensitive member 20 has a photosensitive region 1311 and a non-sensitive photosensitive region 1312. Specifically, the non-sensitive photosensitive region 1312 surrounds the periphery of the photosensitive region 1311. Said The photosensitive region 1311 is for performing a photo-sensing action to convert an optical signal into an electrical signal, and the non-photosensitive region 1312 transmits the electrical signal to the circuit board 12 through the electrical connection member 203. The lens 30 is optically aligned with the photosensitive element 20, and the optical axes are aligned such that light passing through the lens 30 can reach the photosensitive element 20 via the light window 111, and further pass through the photosensitive element 20 After the photoelectric conversion, an electrical signal can be transmitted to the circuit board 12, thereby causing the camera module to acquire image information.

As shown in FIG. 25A to FIG. 26, the camera module unit 100 includes a filter element 50 for filtering light passing through the lens 30. The filter element 50 is exemplified by, but not limited to, an infrared cut filter element 50, a blue glass filter. The filter element 50 is mounted to the filter element holder 40 and is located in the light path of the photosensitive element 20. The camera module unit 100 may further include a driver 60 such as a voice coil motor, a piezoelectric motor, or the like. The lens 30 is mounted to the driver 60 to form a dynamic focus camera module. The driver 60 includes at least one pin 61 through which the driver 60 is operatively coupled to the circuit board 12. The pin 61 can be one of a single pin, a two pin, a single row pin, or a double row pin. In the drawings of the present invention, the two pins are exemplified, but are not limited. The pin 61 is generally located near the edge, from a position corresponding to the over center line in the position of FIG. 26, corresponding to the cross-sectional views of FIGS. 25A and 25B, and the pin 61 is actually in the cross-sectional view corresponding to FIGS. 25A and 25B. Not visible, but for ease of understanding and explanation, the presence of the pin 61 is indicated by a dashed line in the corresponding cross-section, and the actual position of the pin 61 is not illustrated, and the subsequent figures are similar. It will be understood by those skilled in the art that the type, shape and arrangement position of the pins 61 are not limitations of the invention.

As shown in FIGS. 25A to 27, the filter element 50 is mounted to the filter element mirror mount 40 and sinks into the light window 111 of the integrated base 11. The integral base 11 of the integrated base assembly 10 has a top surface 113 to which the filter element mirror mount 40 is mounted. The top surface 113, the driver 60 is mounted to the filter element mirror mount 40. According to this embodiment of the invention, the top surface 113 of the unitary base 11 extends in a plane, in other words, the unitary base 11 forms a platform structure, no stepped projections, and the filter element mirror A seat 40 is mounted to the platform structure. It is worth mentioning that in this manner, the top surface 113 of the unitary base 11 extends in a plane without significant bending angle, so that in the process of integral packaging, such as molding, A smoother, burr-free mounting surface is obtained that provides flat mounting conditions for the filter element mount 40.

Further, the filter element lens holder 40 has a support groove 41 for mounting the filter element 50, and an engagement groove 42 for mounting on the integrated base. 11. The support groove 41 communicates with the light window 111 to form a receiving opening 411 for accommodating the filter element 50. The engagement groove 42 surrounds the periphery of the filter element lens holder 40.

In other words, the support groove 41 forms an inner loop to facilitate mounting the filter element 50 inside the filter element holder 40, the light path of the photosensitive element 20. The engagement groove 42 defines an outer loop for facilitating outward engagement to the unitary base 11 through which the filter element mount 40 is provided with a mounting position.

More specifically, the shape of the engaging groove 42 is matched with the shape of the integral base 11 in order to stably mount the filter element holder 40 to the integral base 11.

Further, the filter element lens holder 40 includes a filter element lens holder body 43, at least one inner extension arm 44 and at least a lower sink arm 45, and the sinker arm 45 turns from the filter element lens holder main body 43. The ground and the longitudinal direction are integrally extended so that the mounting position of the filter sinks into the light window 111. The inner extension arm 44 extends integrally and laterally from the sinking arm 45 so as to provide a horizontally mounted mounting position for the filter element 50 such that the filter element 50 and the photosensitive element 20 The optical axes are identical. In particular, the filter element mount 40 includes four integrally connected inner extension arms 44 and four integrally connected sinks The arm 45, each of the inner extension arms 44 and each of the sinking arms 45 extend at different positions to form the filter element holder 40 which is integrally formed in a ring shape.

In an embodiment, the shape of the engaging groove 42 of the filter element holder 40 is the same as the shape of the light window 111 formed by the integrated base 11, and the shape of the support groove 41 is The shape of the filter element 50 is uniform. In particular, the filter element 50 has a square structure, and the top view of the support groove 41 is an annular shape, such as a square ring shape.

It is worth mentioning that the extending distance of the sinking arm 45 affects the sinking depth of the filter in the light window 111, and the extending distance of the inner extending arm 44 affects the filtering of the installation. The size of the piece. For example, when the extending distance of the sinking arm 45 is larger, the position of the filter in the light window 111 is more downward, and the distance from the photosensitive element 20 is smaller, and the corresponding The smaller the back focal length of the camera module unit is, the smaller the extending distance of the inner arm 44 is, the smaller the receiving port 411 of the filter element lens holder 40 is, and the required filter element 50 is required. The smaller the area, the easier it is to obtain the suitable filter element 50, and the installation is convenient, and the cost of the camera module unit is reduced. Of course, the extending distance of the sinking arm 45 needs to be combined with the imaging effect of the camera module, such as reducing the back focal length without causing dark spots, such as dust images; and the inner extending arm 44 The extending distance needs to consider factors such as the single light path of the camera module and the photosensitive area 1311 of the photosensitive element 20 and the non-photosensitive area 1312 and the remaining width of the circuit board 12, such as in the inner extension arm. When the filter element 50 is inwardly extended, the inner extension arm 44 does not block the photosensitive area 1311 of the photosensitive element 20, and does not excessively block the incoming light flux. And it can extend more in the position where the circuit board 12 has a wider width, and the position of the remaining width of the circuit board 12 is smaller, so that the image quality can be reduced as much as possible. The area of the filter element 50 is described.

For example, referring to FIG. 25B, the distance mark between the inner extension arms 44 on opposite sides In the case of L, the diameter of the filter element 50 needs to be greater than L, so that it can be mounted on the inner extension arm 44 without being mounted on the base body 112, so that the filter element 50 is The demand area is reduced.

The shape of the filter element holder 40 is shown to match the shape of the unitary base 111A. In some embodiments, the unitary base 11 is an approximately regular symmetrical structure, such as a square ring shape. Accordingly, the filter element lens holder 40 has a symmetrical structure, and the filter element lens holder body 43 has a regular shape. Each of the inner extension arms 44 has the same shape, and each of the sink arms 45 has the same shape. In other embodiments, due to the different positions of the electronic components 122 to be covered, the interior of the integrated base 11 has an inwardly protruding position, and the width is different. Accordingly, the filtering is performed. The component mirror main body 43 may be provided with a corresponding groove or protruding position, or the length of the inner extending arm 44 may be different to adapt to the shape of the integral base 11 to accommodate the position of the photosensitive element 20, It is also convenient to install the filter element 50.

In some embodiments, the filter element lens holder 40 can be attached to the unitary base 11A by glue bonding, and the flatness of the filter element lens holder 40 can be adjusted by the glue thickness.

Further, the two camera modules are connected in series to form an array structure. Specifically, the two integrated base assemblies 10 of the two camera module units 100 are connected to form a connected base assembly 1100. The two circuit boards 12 are integrally connected to form a connected circuit board 1120. The two integrated bases 11 are connected in series to form a connected base 1110. The two filter element mirror holders 40 are connected in series to form a connected filter element mirror holder 1400. That is, the connected base 1110 formed in the integrated packaging process forms two light windows 111 to provide light paths for the two photosensitive elements 20, respectively. Alternatively, the two filter element mirror mounts 40 may be separate mirror mounts that are not integrally connected and are respectively mounted to the joint base 1110. The two integral bases 11 can also be two separate bases.

Specifically, the connected base 1110 is integrally packaged on the connected circuit board 1120, and the connected base 1110 has two light windows 111, which are two photosensitive elements 20 and the lens 30 respectively. Provide light access. The connected filter element holder 1400 has two support grooves 41 for mounting the filter element 50, respectively.

It is worth mentioning that the manner in which the two camera modules 100 are connected in series helps to improve the mutual consistency between the two camera modules 100 and save space. For example, the connected filter element holder 1400 can simultaneously provide mounting positions for the two filter elements 50, and during the manufacturing process, the consistency of the two support grooves 41 can be controlled by the area, thereby Filter element 50 provides a consistent installation environment.

The connected base 1110 includes a joint portion 1111 that integrally connects adjacent ones of the integrated bases 11. The joint filter element mount 1400 includes a bridging portion 1410 that integrally connects the two filter element mirror mounts 40, and is adapted to be bridged to the joint base 1110. The joint portion 1111. More specifically, the two adjacent sides of the base body 112 of the two integrated bases 11 are integrally connected to form the connected body portion 1111. The two adjacent sides of the filter element holder main body 43 of the filter element holder 40 are integrally connected to form the bridging portion 1410.

It is to be noted that, in this embodiment of the present invention, referring to FIGS. 25A and 25B, the two camera module units 100 each include the driver 60, that is, the two camera modules are single. Each of the 100 is a moving focus camera module, and the two moving focus camera modules cooperate with each other to realize image collection. In other embodiments of the present invention, the array camera module 1000 can also be a combination of other types of camera modules. In an embodiment, referring to FIG. 28A, 28B, the two camera module units 100 do not include the driver 60, that is, the two camera modules 100 are fixed focus camera modules. The two fixed focus camera modules cooperate with each other to realize image acquisition. In an embodiment, referring to Figures 29A, 29B, One of the camera module units 100 of the array camera module 1000 includes a driver 60 to form a focus camera module, and the other camera module 100 does not include the driver 60. The focus camera module, the dynamic focus camera module and the fixed focus camera module cooperate to realize image acquisition.

In this embodiment, the connected filter element holder 1400 is mounted to the connected base 1110, and each of the drivers 60 is mounted to the connected filter element holder 1400, that is, The continuous filter element mirror mount 1400 is disposed between the driver 60 and the connected base 1110. In another modified embodiment, the connected base 1110 and the driver 60 are both mounted to the top surface 113 of the connected base 1110 with reference to FIGS. 30A, 30B. Further, the connected filter element holder 1400 is mounted at an adjacent inner position of the integrated base 11, and the driver 60 is mounted at a position adjacent to the outer side of the connected base 1110, so that the driver 60 The top surface 113 of the connected base 1110 is coordinated with the joint filter element mount 1400.

As shown in Fig. 31, a first modified embodiment of a joint base and a continuous filter element holder according to an eleventh preferred embodiment of the present invention is shown. In this embodiment, the interior of each of the unitary bases 11A extends obliquely upward to form the light window 111A whose opening is gradually increased. More specifically, each of the integrated bases 11A has an inner side surface 114A, and the inner side surface 114A forms an inclination angle α with the central optical axis of the camera module, so that the opening of the light window 111A is gradually increased. In order to facilitate the manufacturing of the integral base 11A. Wherein the size of α ranges from 3° to 30°, and in some embodiments, the value of α is selected from 3° to 15°, 15° to 20°, or 20° to 30°. Correspondingly, the engaging groove 42A of each of the filter element mirror holders 40A has an engagement angle α 1, and the engagement angle α 1 corresponds to the inclination angle α to facilitate the shape of the engagement groove 42A. The inclined shape of the inner side surface 114A is adapted such that the filter element holder 40A is more stably mounted.

In other words, the sinking arm 45A is turned from the filter element mirror main body 43A to the ground, The inclination extends downward to form the engagement angle α 1 which is adapted to the inclination angle α. Further, in an embodiment, the inner extension arm 44A is steered and horizontally extended at the sinking arm 45A to form a support angle β, and the support angle β is greater than 90° to facilitate the filter element 50. installation. Of course, the filter element holder 40A without the engagement angle α 1 and the support angle β may be mounted on the integral base 11A with the inclination angle α.

As shown in Fig. 32A, there is shown a second modified embodiment of the joint base assembly and the joint filter element holder according to the eleventh preferred embodiment of the present invention. Each of the filter element lens holders 40B has a support groove 41B that communicates with the light window 111B of the corresponding integrated base 11B to provide a mounting position for the filter element 50. In other words, the filter element 50 is mounted to the support groove 41B.

Further, the filter element lens holder 40B includes a filter element lens holder main body 43B and at least one inner extension arm 44B, and the inner extension arm 44B is integrally laterally oriented from a lower portion of the filter element lens holder main body 43B. The inner extension extends to form the support groove 41B. The filter element holder main body 43B is joined to the integral base 11B.

That is, the filter element lens holder 40B does not include the sinker arm 45, and does not have the engagement groove 42, so that the mounting position of the filter element 50 does not sink with respect to the above embodiment. Inside the light window 111B. However, by the extension distance of the inner extension arm 44B, the required area of the filter element 50 can also be reduced.

Figure 32B is a modified embodiment of a second modified embodiment of a joint filter element holder according to an eleventh preferred embodiment of the present invention. Each of the filter element lens holders 40B1 has a support groove 41B1 and a mounting groove 48B1 for respectively providing mounting positions of the lens 30 and the filter element 50.

Further, each of the filter element lens holders 40B1 includes a filter element lens holder main body 43B1. And at least one inner extending arm 44B1 extending inwardly from the lower portion of the filter element mirror main body 43B1 to form the support groove 41B1 and the mounting groove 48B1. The filter element holder 40B1 further includes a lens portion 49B1 that integrally extends upward from the filter element holder main body 43B1 to accommodate the lens 30. In this embodiment of the invention, the filter element 50 is attached to the inner extension arm 44B1 in an inverted manner.

Further, in this embodiment of the invention, the lens portion 49B1 is internally flat, non-threaded and adapted to mount a lens 30 that is unthreaded.

That is to say, when the camera module unit 100B1 is a fixed focus camera module, the lens 30 can be directly mounted inside the filter element lens holder 40B1 to limit the lens 30. In particular, there is a gap between the lens portion 49B1 and the lens 30 to facilitate mounting and adjustment of the lens 30.

Figure 32C is another modified embodiment of a second modified embodiment of the joint filter element holder according to the eleventh preferred embodiment of the present invention. Each of the filter element lens holders 40B2 has a support groove 41B2 and a mounting groove 48B2 groove for respectively providing the lens 30 and the filter element 50 with a mounting position.

Further, each of the filter element lens holders 40B2 includes a filter element lens holder main body 43B2 and at least one inner extension arm 44B2 that is laterally integrated from a lower portion of the filter element lens holder main body 43B2. Extending inwardly, the support groove 41B2 and the mounting groove 48B2 are formed. The filter element holder 40B2 further includes a lens portion 49B2 that integrally extends upward from the filter element holder main body 43B2 to accommodate the lens 30. In this embodiment of the invention, the filter element 50 is attached to the inner extension arm 44B2 in an inverted manner.

Further, in this embodiment of the invention, the lens portion 49B1 has an inside A threaded structure adapted to mount a threaded lens 30.

That is to say, when the camera module unit 100B2 is a fixed focus camera module, the lens 30 can be directly mounted inside the filter element lens holder 40B2, thereby limiting the lens 30.

It should be noted that the above two embodiments are merely illustrative of possible deformation modes of the filter element lens holder 40, and the lens 30 can be directly mounted on the filter element lens holder 40B1, 40B2. Internal, but not limited.

As shown in FIG. 33A, a third modified embodiment of the array camera module according to the eleventh preferred embodiment of the present invention is shown. In this embodiment, each of the filter element lens holders 40C has at least one corner opening 441C, which is disposed at a corner position of the filter element lens holder 40 to facilitate the filter element. The installation of 50 reduces the edge shadow caused by the sharp corners in the imaging of the camera module. More specifically, the adjacent two inner extension arms 44C form a corner opening 441C that extends outwardly to increase the luminous flux of the camera module at the corner position of the filter element mirror mount 40C.

Specifically, in an embodiment, the corner opening 441C may be an expanded square corner, such as, but not limited to, four corresponding extended square corners disposed at four corner positions of the filter element mirror mount 40C. In other embodiments, the corner opening 441C may also have a circular arc angle to increase the luminous flux at the corner of the filter element holder 40C. Of course, in some embodiments, the corner opening 441C may not be provided, and it should be understood by those skilled in the art that the shape, position and number of the corner opening 441C are not limited by the present invention.

As shown in Fig. 33B, a modified embodiment of the eleventh preferred embodiment of the present invention is shown. In this embodiment of the invention, each of the filter element lens holders 40P includes a limiting protrusion 46P, and the limiting protrusion 46P is at least partially from the top surface of the filter element lens holder main body 43P. The protrusions extend upward to facilitate limiting the mounted components, blocking dust or light from entering the interior of the camera module. Said The limit projection 46P is exemplarily, but not limited to, limiting the driver 60 or the lens 30. In particular, in this embodiment of the invention, the joint filter element holder 1400P includes two of the limiting protrusions 46P, each forming an annular protrusion, and the corresponding driver 60 is limited. In another embodiment, the intermediate portion of the joint filter element holder 1400P formed by the two filter element holders 40P, that is, the bridging portion 1410P may not be provided with the limiting protrusion 46P. The limit protrusion 46P is provided only around the joint filter element holder 1400P.

In this embodiment of the invention, the limiting projection 46P can position the driver 60, reduce the offset of the driver 60, and prevent the glue of the driver 60 from being installed during assembly. Overflow to the interior contaminated lens 50 or internal components.

It should be noted that in other embodiments of the present invention, the surface of the limiting protrusion 46P may be provided with a thread to facilitate direct mounting of the lens 30. And when the outer side of the limiting protrusion 46P is provided with a thread, the lens 30 is adapted to a larger aperture.

As shown in FIGS. 34A to 35, an array camera module according to a twelfth preferred embodiment of the present invention is shown. Each of the integrated bases 11D includes a base body 112D forming at least one light window 111D to provide a light path for the photosensitive element 20. Further, the base body 112D has at least one opening 1121D that communicates with the light window 111D and the outside, and the filter element lens holder 40D is supplemented to the opening, thereby forming the light window closed sideways. 111D.

Each of the filter element mirror mounts 40D includes at least one extended leg 433D that extends integrally downward from the filter element mount body 43D to the substrate 121D to close the opening 1121D. By way of example and not limitation, the extension leg 433D is bonded to the substrate 121D and/or the base body 112D by bonding.

The base body 112D forms a U-shaped structure, and the filter element mirror main body 43D a U-shaped structure joined to the base body 121D, and the extended leg 433D of the filter element mirror holder 40D is supplemented to an opening position of the U-shaped structure, thereby closing the integral base 11D to form A closed internal environment.

In other words, in this embodiment, the integrated base 11D and the filter element holder 40D share the function of the lens holder of the camera module, so that the advantages of the integrated package and the function of the filter element holder 40D Combine.

It is worth mentioning that, due to the increasing size requirements of the camera module, the arrangement of the electronic components 122D on the circuit board 12D, the installation position of the electrical connection component 203, the integration The package position and the like of the susceptor 11D require a reasonable arrangement, and the component layout area is minimized while the substrate 121D is fully utilized, thereby further reducing the size of the camera module. According to this embodiment of the invention, the electronic component 122D is integrally packaged in the direction in which the electronic component 122D is disposed, and the electronic component 122D is covered, and the spatial position of the electronic component is utilized, and the electrical component and the electricity are simultaneously reduced. The electromagnetic effect between the elements 203 is connected, and the filter element holder 40D is provided in such a manner that the electric component is not provided, and the remaining position on the substrate 121D is fully utilized. On the other hand, the flatness of the integrated base 11D can be adjusted and supplemented by the bonding process of the filter element holder 40D to provide good mounting conditions for the camera module.

36A to 36C show a variant embodiment of a joint base and a continuous filter element lens holder of an array camera module according to a twelfth preferred embodiment of the present invention. The integrated base 11E includes a base body 112E that forms at least one light window 111E to provide a light path for the photosensitive element 20. Further, the integrated base 11E has two openings 1121E, each of the openings 1121E is connected to the light window 111E and the outside, and the filter element lens holder 40E supplements the two openings 1121E, and the light window 111E is The side is closed.

The filter element holder 40E includes two extending legs 433E that extend integrally downward from the filter element holder body 43E to the substrate 121E to close each of the openings. By way of example and not limitation, each of the extension legs 433E is bonded to the substrate 121E and/or the base body 112E by adhesive bonding. More specifically, in an embodiment, the base body 112E is a parallel structure, the filter element lens mount 40E body is coupled to the parallel structure of the base body 112E, and the filter element lens mount 40E The extension leg 433E is supplemented to the open end positions of the parallel structure such that the base body 112E closes to form a closed inner environment. In some embodiments, two adjacent extending legs 433E are integrally connected to form a common extending leg, and the common leg is spaced apart from the two light windows 111E to isolate the light paths of the two camera module units. . That is, in this embodiment, the connected filter element holder 1400E includes three of the extending legs 433E, arranged in parallel, wherein the extending leg 433E in the middle separates the two light windows 111E And the other two extending legs 433E are respectively supplemented to the opening 1121E of the connected base 1110E, thereby forming two closed and independent light windows 111E. In other words, in the array camera module 1000E, the two light windows 111E of the two camera module units 100E are in communication with each other, and the connected body is supplemented by the connected filter element mirror holder 1400E. The pedestal 1110E forms two spaced, closed light windows 111E. The adjacent extension legs 433E of the filter element holder 40E form a common portion instead of the conjoined portion 1111E of the conjoined base 1110E. In an embodiment, two adjacent extension legs 433E are integrally connected.

37A and 37B, another modified embodiment of the integrated base assembly and the filter element mount according to the twelfth preferred embodiment of the present invention. In this embodiment, each of the integrated bases includes a base body 112Q that forms at least one light window 111E to provide a light path for the photosensitive element 20. Further, the integrated base 11Q has at least one opening 1121Q, each of the openings is connected to the light window 111Q and the outside, and the filter element lens holder 40Q is added to the opening. The port 1121Q closes the periphery of the light window 111Q. Different from the above embodiment, in the connected base assembly 1100Q, the two openings 1121Q of the two integrated base bodies 112Q are oppositely positioned, thereby conveniently limiting the joint filter from the two sides respectively. Component mirror mount 1400Q.

Further, each of the openings 1121Q has an inverted trapezoidal structure to facilitate positioning and mounting of the filter element mirror holder 40Q. Correspondingly, the filter element lens holder includes at least one extending leg 433Q, and each of the extending legs 433Q integrally extends downward from the filter element mirror body 43Q to the substrate 121 to facilitate the opening 1121Q closed. Specifically, the two extension legs 433Q are oppositely disposed and have an inverted trapezoidal structure, and are adapted to be supplemented to the corresponding openings 1121Q. For example, when the filter element lens holder 40Q is mounted, the extension legs are limited to the opening 1121Q, and the two light windows 111Q are respectively closed around.

It should be understood by those skilled in the art that the shape and size of the opening 1121Q in the embodiment of the present invention are merely illustrative of the manner in which it can be implemented, and are not limiting of the present invention.

In particular, in some embodiments, the electronic component 122Q may be collectively disposed on one side and covered by at least a portion of the base body 112Q and covered by the wider base body 112Q. The side on which the electronic component 122Q is not provided corresponds to the narrow base body 112Q. The filter element lens holder is mounted on the base body 43Q by 40Q, and the extension leg 433Q is supplemented by the opening 1121Q between the two parts.

Further, the base body 112Q has at least one opening surface 1122Q, and the opening 1121Q is formed with respect to the two opening surfaces. The opening surface 1121Q extends obliquely integrally from the substrate 121 so as to form the trapezoidal opening 1121Q. Correspondingly, the extension leg 433Q has at least one supplementary surface 4331Q corresponding to the opening surface 1122Q, so as to complement the extension leg 433Q in a complementary manner to the opening 1121Q, The light window 111Q is closed around.

In particular, the extending leg 433Q and the complementary surface 4331Q and the opening surface 1122Q of the base body 112Q may be fixed by glue bonding.

As shown in FIGS. 38A to 39, an array camera module according to a thirteenth preferred embodiment of the present invention is shown. Each of the integrated bases 11F has a mounting groove 115F and at least one notch 117F, and the mounting groove 115F communicates with the light window 111F. In this embodiment of the invention, the notch 117F is disposed adjacent to the two integrated bases, that is, above the connecting portion 1111F of the connected base 1110F, and communicates with both sides. That is, the two mounting grooves 115 are communicated through the notch 117F to accommodate the bridging portion 1410F of the connected filter element holder 1400F.

Each of the filter element mirror holders 40F is attached to the mounting groove 115F. More specifically, the mounting groove 115F is a U-shaped groove, and the U-shaped opening corresponds to the notch 117F. In particular, the U-shaped grooves of the two filter element holders 40F are opposite to each other to form an internal communication closed structure. When the connected filter element holder 1400 is mounted to the connected base 1110, the bridging portion 1410 of the continuous filter element holder 1400 is bridged to the notch 117F located in the middle.

Specifically, the engagement groove 42F of the filter element lens holder 40F is engaged with the mounting groove 115F of the integral base 111F such that the filter element lens holder of the filter element lens holder 40F The main body 43F is supported in the support groove 41F.

The filter element holder main body 43F of the filter element holder 40F has a predetermined thickness so that it does not easily touch a member located above, such as the driver 60 or the lens 30. Preferably, when the filter element mirror mount 40F is mounted to the mounting groove 115F, the top surface of the filter element mirror mount 40F coincides with the top surface of the base body 112F, thereby causing the The filter element mirror holder 40F does not protrude less or less from the base body 112F and does not easily touch the driver 60 or the lens 30 located above.

More specifically, each of the unitary bases 11F includes a plurality of raised steps 116F protruding from the center The base body 112F is described. Each of the protruding steps 116F extends upward from the base body 112F to form the mounting groove 115F. At least one side surface of the integrated base 11F does not have the convex step 116F, and the notch 117F is formed.

According to this embodiment of the invention, each of the unitary bases 11F includes three raised steps 116F, and each of the raised steps 116F is steerably integrally coupled to form the U-shaped mounting groove 115F. That is, the side without the raised step 116F forms the notch 117F.

The filter element lens holder main body 43F of the filter element lens holder 40F includes at least one joint edge 431F and at least one extended side 432F for engaging the mounting groove 115F, the extended side 432F is used to fill the gap 117F. In other words, the extended edge 432F extends into the gap 117F such that the gap 117F is filled to form a closed inner environment. In this embodiment, the extended edge 432F forms the bridging portion 1410F.

According to this embodiment of the invention, the filter element holder body 43F of the filter element holder 40F includes a three-engaged side 431F and an extended side 432F, and each of the joined side 431F and the extended side 432F is turned The ground is integrally connected to accommodate the shape of the mounting groove 115F.

The sinking arms 45F are integrally extended downward from the engaging edge 431F and the extended side 432F, thereby forming the engaging groove 42F. The inner extension arm 44F is laterally extended integrally from the inner extension arm 44F to form the support groove 41F.

It is worth mentioning that the electronic component 122F is disposed at different positions of the main body of the circuit board 12F, and the integrated base 11F covers the electronic component 122F. In the position where the electronic component is disposed, the integrated base 11F requires a large thickness, and the mounting groove 115F is conveniently disposed, and the position of the electronic component 122F can be set to a smaller thickness, thereby reducing The mounting groove 115F is not suitable for the size of the circuit board 12F. According to this embodiment of the invention, in three The electronic component 122F is disposed on the integrated base 11F corresponding to the joint edge 431F. The integrated base 11F has a large lateral thickness, and the mounting groove 115F is disposed, and the side of the extended side 432F is corresponding. The integral base 11F has a small lateral thickness, and the mounting groove 115F is not provided, and the notch 117F is filled by the extended side 432F to assume the function of the convex step 116F.

The driver 60 is at least partially mounted to the raised step 116F to form a dynamic focus camera module. The driver 60 is operatively coupled to the circuit board 12 by at least one pin 61. In other embodiments, the lens 30 is mounted on the raised step 116F or the filter element mirror mount 40F to form a fixed focus camera module.

More specifically, the three sides of the driver 60 are mounted to the raised step 116F, and the remaining side is mounted to the extended side 432F of the filter element mirror mount 40F. In some embodiments, there is a gap between the driver 60 and the extended edge 432F, and the gap is sealed by glue to form a closed inner environment for the camera module. In other words, the surface height of the extended side 432F is lower than the surface height of the raised step 116F, and the height difference can be supplemented by glue. In particular, the driver 60 may be attached to the raised step 116F by bonding, and the optical axis of the lens 30 and the photosensitive element 20 may coincide.

As shown in FIG. 40A to FIG. 41, it is an array camera module according to a fourteenth preferred embodiment of the present invention.

Each of the integrated bases 11R includes a base body 112R forming at least one light window 111R to provide a light path for the photosensitive element 20. Further, the base body 112R has at least one opening 1121R that communicates with the light window 111R and the outside, and the filter element lens holder 40R is supplemented to the opening, thereby forming the light window closed sideways. 111R. In this embodiment, the two openings 1121R of the two integrated bases 11R of the joint base 1110R communicate with each other.

Each of the filter element holders 40R includes at least one extending leg 433R that integrally extends downwardly from the filter element holder body 43R to the substrate 121R to close the opening 1121R. By way of example and not limitation, the extension leg 433R is bonded to the substrate 121R and/or the base body 112R by adhesive bonding.

In some embodiments, two adjacent extending legs 433R are integrally connected to form a common extending leg, that is, a shared leg. In particular, the common leg is spaced apart from the two light windows 111R, and the two are described. The light path of the camera module is isolated. That is, in this embodiment, the connected filter element holder 1400R includes two integrally connected extension legs 433R, located in the middle of the two optical windows 111R in the middle, separating the two light windows. 111R, thereby forming two closed, mutually independent light windows 111R.

The integrated base 11R has at least one mounting groove 115R and an opening 117R. The mounting groove 115R communicates with the light window 111R, and the notch 117R communicates with the light windows 111R on both sides. The filter element mirror holder 40R is mounted to the mounting groove 115R.

According to this embodiment of the invention, the integral base 11R includes three raised steps 116R, wherein each of the raised steps 116R extends partially upward from the base body 112R to form the mounting groove 115R.

The filter element holder main body 43R of the filter element mirror holder 40R includes at least one joint side 431R for engaging the mounting groove 115R.

According to this embodiment of the present invention, the filter element holder main body 43R of each of the filter element holders 40R includes a three-joining edge 431R and an extended side 432R adjacent to the joint of the unitary base 11R. The sides 431R are integrally extended and parallel to each other, and the extended sides 432R are disposed between the joint sides 431R. That is to say, in this embodiment, the notch 117R of the connected base is disposed adjacent to the two bases 11R and communicates with each other. The extension of the joint filter element holder The sides 432R are disposed at respective adjacent positions, integrally connected to form the bridging portion 1410R.

The sinking arm 45R is steered from the engaging edge 431R and integrally extends downward to form an engaging groove 42R for facilitating engagement with the mounting groove 115R. The inner extension arm 44R is steered from the sinking arm 45R and integrally extends laterally to form a support groove 41R to provide a mounting position for the filter element 50. It is worth mentioning that the electronic component 122R is disposed at different positions of the circuit board main body 121R, and the integrated base 11R covers the electronic component 122R. At a position where the electronic component is disposed, the integrated base 11R requires a large thickness and is convenient for forming the mounting groove 115R, and the position of the electronic component 122R may be set to a small thickness, thereby Reducing the size of the circuit board 12R is not suitable for forming the mounting groove 115R. According to this embodiment of the present invention, the electronic component 122R is disposed on the integrated base 11R corresponding to the two joint edges 431R, and the lateral thickness of the integrated base 11R is large, and the mounting groove 115R is disposed. The integral base 11R of the other side of the convex step 116R on which the mounting groove 115R is not formed is smaller in the lateral direction.

The driver 60 is at least partially mounted to the raised step 116R to form a dynamic focus camera module. The driver 60 is operatively coupled to the circuit board 12R via at least one of the pins 61. In other embodiments, the lens 30 is mounted on the raised step 116R or the filter element mirror mount 40R to form a fixed focus camera module.

More specifically, the driver 60 is mounted to the raised step 116R, wherein both sides are supported by the raised step 116R forming the mounting groove 115R, and the remaining side is mounted to the mounting groove not formed 115R of the raised step 116R, the remaining side is supported by the extended side 432R.

42A to 43 are modified embodiments of an array camera module according to a fourteenth preferred embodiment of the present invention. Each of the integrated bases 11H includes three raised steps 116H, three The raised steps 116H are integrally connected in a steering manner, wherein the two raised steps 116H and the base body 112H form a mounting groove 115H, and the other raised step 116H extends integrally upward from the base body 112H. And the mounting groove 115H is not formed. The two adjacent bases 11H do not include the raised step 116H adjacent to each other to form a notch 117H. That is, the connected base 1110H forms two juxtaposed mounting grooves 115H, and the notches 117H are located between the two mounting grooves 115H. Accordingly, each of the filter element mirror holders 40H forms a U-shaped structure, and the opening of the U-shaped structure is opposed to the convex step 116H where the mounting groove 115H is not formed. That is to say, the integrated filter element lens holder 1400H has an E-shaped structure as a whole, and the intermediate portion of the E-shaped intermediate structure is connected to the connected portion 1111H of the connected base 1110H, and the openings at both ends are The raised step 116H is blocked.

44A, 44B and 45 are array camera modules in accordance with a fifteenth preferred embodiment of the present invention.

Different from the above preferred embodiment, the integrated base 11I includes a convex step 116I, and has three notches 117I extending partially integrally from the integrated base 112I. The mounting groove 115I is described. That is, each of the notches 117I is formed on the three sides without the raised step 116I.

The filter element lens holder main body 43I of the filter element lens holder 40I includes at least one joint edge 431I and at least one extended side 432I for engaging the mounting groove 115I, the extended side 432U1 is used to fill the gap 117I. In other words, the extended edge 432I extends into the notch 117I such that the notch 117I is filled to form a closed inner environment.

According to this embodiment of the invention, the filter element holder body 43I of the filter element holder 40I includes a joint edge 431I and three said extension sides 432I, the joint side 431I and each of the above The extended side 432I is integrally connected to the steering direction to accommodate the shape of the mounting groove 115I. It is worth mentioning that, In this embodiment, in the array camera module, two of the adjacent filter elements 1400I formed by the two filter element lens holders 40I are integrally connected to each other. The body is formed to form a common portion of two adjacent camera module units 100I, that is, the bridging portion 1410I is formed.

The sinking arm 45I extends downwardly integrally from the engaging edge 431I and the extended side 432I, thereby forming the engaging groove 42I. The inner extension arm 44I is laterally extended integrally from the inner extension arm 44I to form the support groove 41I.

Further, in this embodiment, the two protruding steps 116I of the two integrated bases 11I of the connected base 1100I are integrally extended and connected to form a flat structure, thereby forming an in-line mounting groove. . The notches 117I are adjacent to each other to form an E-shaped structure. Correspondingly, the extended sides 432I of the filter element holder 40I are adjacent to each other to form a U-shaped structure, and the joint sides 431I are disposed on the connection ports of the U-shaped structure. In the joint filter element holder 1400I, two adjacent extending edges 432I are integrally connected to form the bridging portion 1410I to accommodate the conjoined portion 1111I of the conjoined base 1110I.

According to another modified embodiment, the two protruding steps 116I of the integrated base 11I are adjacent to each other, and the two notches 117I are adjacent to each other. That is, the two raised steps 116I constitute an L-shaped structure, thereby forming an L-shaped mounting groove 115I. The notches 117I are adjacent to each other to form an L-shaped extension. Correspondingly, the two engaging edges 431I of the filter element lens holder 40I are adjacent to each other, and are adapted to be joined to the L-shaped mounting groove 115I, and the two extending edges 432I are adjacent to each other, and are suitable for filling the L-shaped portion. The gap 117I is described to form a closed internal environment. The driver 60 is at least partially mounted to the raised step 116I to form a dynamic focus camera module. The driver 60 is operatively coupled to the circuit board 12I via at least one of the pins 61. In other embodiments, the lens 30 is mounted on the convex step 116I or the filter element lens holder 40I to form a fixed focus camera module. More specifically, both sides of the driver 60 are supported by the raised step 116I forming the mounting groove 115I, and the remaining two sides are mounted on The extended side 432I of the filter element mirror mount 40I.

As shown in FIG. 46A and FIG. 47, it is a modified embodiment of the array camera module according to the fifteenth preferred embodiment of the present invention. In this embodiment of the invention, the arrangement of the raised steps 116J is different from the preferred embodiment described above. In the connected base 1110J of the array camera module, the raised steps 116J of the two integrated bases 11J are opposite to each other to form a parallel structure, and each of the raised steps 116J and corresponding The base body 111 forms the mounting groove 115J. That is, the two mounting grooves 115J located at the joint base 1110J are disposed at positions opposing each other. With respect to the above-described embodiment fifteen, in this modified embodiment, the two convex steps 116J of the joint base 1110J are arranged in a word arrangement to be relatively parallel.

48A, 48B and 49 are embodiments of an array camera module in accordance with a sixteenth preferred embodiment of the present invention. Different from the above preferred embodiment, each of the unitary bases 11K includes a raised step 116K and three notches 117K. The protruding step 116K extends partially and integrally from the base body 112K to form the mounting groove 115K. That is, the notch 117K is formed without the three sides of the convex step 116K.

The filter element mirror main body 43K of the filter element lens holder 40K includes at least one joint edge 431K and at least one extended edge 432K for engaging the mounting groove 115K, the extended side 432K is used to fill the gap 117K. In other words, the extended edge 432K extends into the gap 117K such that the gap 117K is filled to form a closed inner environment.

According to this embodiment of the invention, the filter element holder body 43K of the filter element holder 40K includes a joint edge 431K and three extended sides 432K, each of the joint side 431K and the extended side 432K turning The ground is integrally connected to accommodate the shape of the mounting groove 115K and the notch 117K. Two adjacent extending edges 432K are integrally connected to form the joint filter element holder 1400 The bridging portion 1410K is bridged to the conjoined portion 1111K of the connected base 1110K.

The sinking arms 45K are integrally extended downward from the engaging edge 431K and the extended side 432K, thereby forming the engaging groove 42K. The inner extension arm 44K is laterally extended integrally from the inner extension arm 44K to form the support groove 41K.

The driver 60 is at least partially mounted to the raised step 116K to form a dynamic focus camera module. The driver 60 is operatively coupled to the circuit board 12K via at least one of the pins 61. In other embodiments, the lens 30 is mounted on the raised step 116K or the filter element mirror mount 40K to form a fixed focus camera module.

More specifically, one side of the driver 60 is supported by the raised step 116K forming the mounting groove 115K, and the remaining three sides are mounted to the extended side 432K of the filter element mirror holder 40K. .

It is to be noted that, in this embodiment of the invention, the two protruding steps 116K of the two integrated bases 11K are staggered in parallel, thereby limiting the mounting position of the connected filter element holder 1400. In other embodiments of the invention, the relative positions of the raised steps 116K may be other layouts, such as parallel or vertical directions. It should be understood by those skilled in the art that the layout structure of the two raised steps 116K is not limited by the present invention.

As shown in Figs. 50A to 51, an array camera module according to a seventeenth preferred embodiment of the present invention is shown. Different from the above preferred embodiment, each of the filter element lens holders 40L includes an upper extension wall 46 that is steered from the filter element lens holder main body 43L and extends upward to form a Limit port 461L. The limiting port 461L is used to limit the components to be mounted, such as but not limited to the driver 60 and the lens 30. In other words, when the array of the array camera module 1000L is assembled, each of the drivers 60 or the lens 30 is mounted in the limiting port 461L of each of the filter element mirror holders 40L, and the limiting position is Drive The actuator 60 or the lens 30 is such that each of the drivers 60 or each of the lenses 30 coincides with the optical axis of each of the photosensitive elements 20. The size of the limiting port 461L can be determined according to the size of the component to be mounted.

In other words, the upper extension wall 46L has a frame restraining function so that when the driver 60 or the lens 30 or the like is mounted on the filter element mirror holder 40L, excessive deviation does not occur, and the imaging is ensured. The consistency of the optical system of the module. At the same time, the upper extension wall 46L can protect the mounted components, such as the driver 60 or the lens 30, from unnecessary external contact, so that the driver 60 or the lens 30 is stably mounted. Moreover, external dust can be blocked from entering the inside of each of the camera module units 100L.

Further, when the camera module unit 100L is a moving focus camera module, the filter element lens holder 40L has at least one lead port 462L for passing through the pin 61. That is, when the driver 60 is mounted on the limiting port 461L of the filter element mirror holder 40L, the driver 60 pin passes through the pin port 462L and is electrically connected to the circuit. Board 12L. Of course, when the camera module unit 100L is a fixed focus camera module, the filter element lens holder 40L may not be provided with the pin port 462L.

It should be noted that, in the actual cross-sectional view, the pin port 462L may not be visible, but for convenience of explanation and understanding, the pin port 462L is indicated by a broken line in the figure, and the position is not limited to the actual setting. position.

It is worth mentioning that the driver 60 or the lens 30 of the array camera module 1000L is limited to the upper extension wall 46L, which helps to constrain the optical axis consistency of the camera module unit 100L. At the same time, it is convenient to control the consistency of the two camera modules 100L.

As shown in FIG. 52, it is an array camera module according to an eighteenth preferred embodiment of the present invention. Different from the above preferred embodiment, each of the filter element mirror holders 40M includes an upper extension wall 46M and a lower extension wall 47M. The upper extension wall 46M is turned from the filter element mirror main body 43M to the ground. Extending upwardly, a limiting port 461M is formed, and the lower extension wall 47M is turned from the filter element mirror main body 43M to the ground The lower extension forms a lower mouth 471M. In particular, the lower extension wall 47M extends integrally from the upper extension wall 46M to form an integral outer barrier wall.

The limiting port 461M is used to limit the components to be mounted, such as but not limited to the lens 30. The lower cover opening 471M is for accommodating the integrated base 11M, that is, when the array camera module 1000M is assembled, the driver 60 or the lens 30 is mounted on the filter element lens holder. In the limiting port 461M of the 40M, the integral base 11M is received in the lower opening 471M, and the upper extension wall 46M limits the occlusion of the lens 30, so that the lens 30 and the camera 30 The optical axis of the photosensitive element 20 is uniform, and the lower extension wall 47M blocks the integrated base 11M, so that the overall structure of the array camera module 1000M is relatively regular, convenient to install, and the appearance is relatively beautiful. The size of the limiting port 461M and the lower opening 471M may be determined according to the size of the component to be mounted, such as but not limited to the size of the driver 60, the lens 30, and the integrated base 11M.

In an embodiment, the lower extension wall 47M may extend to the circuit board 12M, for example, but not limited to, fixedly connected to the circuit board 12M by glue bonding, so that the filter element lens holder The 40M is installed more stably.

Figure 53 is a cross-sectional view showing an array camera module in accordance with a nineteenth preferred embodiment of the present invention.

Each of the integrated bases 11N includes a lens wall 118N, and the lens wall 118N extends at least partially upward from the convex step 116N to form a lens chamber 1181N suitable for mounting the lens 30 to form a certain focal length imaging mode. group.

Further, the convex step 116N and the base body 112N form the mounting groove 115N for mounting the filter element mirror base 40N. The lens wall 118N and the raised step 116N form another mounting groove 115N for providing a mounting position for the lens 30.

Further, the engagement groove 42N of the filter element holder 40N is joined to the mounting groove 115N, and the filter element 50 is attached to the support groove 41N of the filter element holder 40N. The lens 30 is mounted to another of the mounting grooves 115N.

The lens wall 118N provides a mounting position for the lens 30, and constrains the mounting position of the lens 30 such that the optical axis of the lens 30 and the photosensitive element 20 coincide, improving the accuracy of mounting.

As shown in Fig. 54A, there is shown an exploded view of an array camera module in accordance with a twentieth preferred embodiment of the present invention. The array camera module 1000S includes two camera module units 100S, each of the camera module units 100S includes an integrated base unit 10S, wherein the integrated base unit 10S includes a circuit board 12S, different In the above preferred embodiment, the two circuit boards 12S of the two camera module units 100S are spliced to each other to form the connected circuit board 1120S, and the integrated base 11S is integrally packaged in the two circuits. Board 12S. That is to say, the two circuit boards 12S are not integrally connected. In another embodiment of the present invention, the two circuit boards 12S may be independent of each other and have a gap, which is not a splicing manner. It is to be understood that the present invention is not limited in this respect.

Figure 54B is a cross-sectional view of an array camera module in accordance with a twentieth preferred embodiment of the present invention. The array camera module 1000T includes two integrally connected camera module units 100T, and includes a connected circuit board 1120T integrally formed on the connected base 1110T of the connected circuit board 1120T. The pedestal 1110T has two light windows 111T for providing light paths for the two photosensitive elements 20 and the two lenses 30, respectively, and the connected base 1110T forms two mounting grooves 115T on the top side, and two independent filter element mirror holders. 40T is provided in each of the two mounting grooves 115T for respectively mounting the two filter elements 50. It can be understood that, in another modified embodiment, the connected base 1110T may be formed on the top side without forming the mounting groove 115T, but has a flat surface for mounting the two independent filters. Component lens holder 40T. It is to be noted that each of the individual filter element lens holders 40T can also be constructed in any of the above-described first to tenth embodiments.

It is to be noted that, in the above embodiment, a two-lens array camera module composed of two camera module units 100 is taken as an example. In other embodiments, the array camera module 1000 is illustrated. More of the camera module unit 100 may also be included. In the above embodiment, the features of each of the camera module units 100 are arranged in a symmetrical form to form the array camera module 1000, and in other implementations, each of the camera module units 100 The various features of the array can be combined arbitrarily to form an asymmetric array camera module 1000. The invention is not limited in this respect.

FIG. 55 is a schematic diagram of an application of the array camera module according to the above embodiment of the present invention. The array camera module 1000 is disposed in an electronic device body 200 to form an electronic device 300 with the array camera module 1000.

As shown in FIG. 55, the array camera module 1000 is applied to a smart phone, and cooperates with the smart phone to realize image collection and reproduction. In other embodiments, the array camera module 1000 can be disposed on other electronic device bodies 200 to form different electronic devices 300. The electronic device 300 is specifically, but not limited to, a wearable device and a tablet computer. , laptops, cameras, surveillance equipment, etc.

It is worth mentioning that, in the present invention, the camera module of the integrated packaging process is supplemented by the filter element lens holder, and the integrated base of the camera module cooperates with the function of the traditional lens holder. Based on the advantages of the integrated packaging process, it can make up for and improve the application deficiencies in the integrated package. On the other hand, the filter element lens holder can be integrally formed, for example, integrally formed by injection molding, so that it has better flatness, and more preferably, the reflectance of incident light can be reduced by utilizing the characteristics of the material itself. Furthermore, it can be seen from the above embodiments that, in combination with the shape of the integral base, The filter element lens holder can have various variants, the molding structure is simple, easy to process, and more preferably, when a suitable plastic material is selected, no etching or the like is required, and no blackening or roughening is required. Processing can reduce the reflectivity of incident light and avoid stray light.

Those skilled in the art should understand that the embodiments of the present invention described in the above description and the accompanying drawings are only by way of illustration and not limitation. The object of the invention has been achieved completely and efficiently. The present invention has been shown and described with respect to the embodiments of the present invention, and the embodiments of the present invention may be modified or modified without departing from the principles.

Claims (58)

An array camera module, comprising: a plurality of camera modules, arranged in an array, each of the camera modules comprises: an integrated base assembly; a photosensitive element; a lens; a filter element mirror And a filter element; wherein the integrated base assembly comprises an integral base and a circuit board, the integrated base is integrally packaged on the circuit board to form a light window, and provides light passage for the photosensitive element; Wherein each of the photosensitive elements is operatively coupled to the circuit board, the filter element lens mount is mounted to the integral base, and the filter element is disposed on the filter element lens mount such that The filter element is located in a photosensitive path of the photosensitive element, wherein the lens is located in a photosensitive path of the photosensitive element. The array camera module of claim 1, wherein each of the filter element lens holders comprises a filter element lens holder body and at least one inner extension arm, wherein the inner extension arm is from the filter element The main body of the mirror body partially extends laterally integrally to form a support groove adapted to mount the filter element. The array camera module of claim 1, wherein the filter element lens holder comprises a filter element mirror body, at least a lower arm and at least one inner arm, and the sink arm is The filter element housing body is steered to extend to form an engagement slot adapted to be coupled to the integral base, the inner extension arm extending from the sunburst arm to form a support slot adapted to mount the filter Optical component. The array camera module of claim 3, wherein each of the integrated bases has at least one mounting slot and at least one notch, the mounting slot is connected to the optical window, and the notch is connected The filter element lens holder body of the filter element lens holder includes at least one joint edge and at least one extension edge, the joint edge being adapted to be engaged with the mounting groove, The extended edge is adapted to extend the gap to form a closed environment. The array camera module of claim 4, wherein the integrated base comprises three mounting slots, the mounting slot forms a U-shaped structure, and the filter component of the filter element lens mount The mirror body includes three engaging edges that form a U-shaped structure adapted to engage the mounting slot. The array camera module of claim 4, wherein the integrated base has two mounting slots and two notches, the mounting slots are connected to the optical window, and the notches are connected to the optical window and Externally, the filter element lens holder body of the filter element lens holder comprises two engaging edges and two extending edges, the two engaging edges being adapted to be engaged with the two mounting grooves, and the two extending edges are adapted to extend The two gaps form a closed environment. The array camera module of claim 6, wherein the two mounting grooves of the integrated base are opposite, and the two notches are two pairs, and the two joint edges of the filter element lens holder are opposite. The two extended sides are opposite. The array camera module of claim 6, wherein the two mounting slots of the integrated base are adjacent to each other, and the two notches are adjacent to each other, and the two joint edges of the filter element lens holder are Adjacent, the two extended sides are adjacent. The array camera module of claim 4, wherein the integrated base has a mounting slot and three notches, the mounting slot is connected to the optical window, and the notch is connected to the optical window and Externally, the filter element lens holder body of the filter element lens holder comprises a joint edge and three extension edges, the joint edge is adapted to be engaged with the mounting groove, and the extension edge is adapted to extend to three The gap forms a closed environment. The array camera module of claim 3, wherein the integrated base has an inner side surface, the inner side surface has an inclination angle, and the engagement groove has an engagement angle, and the inclination angle is adapt. The array camera module of claim 1, wherein each of the filter element mirror holders includes an upper extension wall, and the upper extension wall extends upward from the filter element mirror body to form a Limit port. The array camera module of claim 1, wherein each of the filter element mirror holders includes an upper extension wall and a lower extension wall, the upper extension wall being steered from the filter element mirror housing body Extending upwardly to form a limiting port, the lower extension wall is steered downwardly from the filter element mirror body to form a lower opening. The array camera module of claim 1, wherein each of the filter element lens holders includes at least one limiting protrusion, and the limiting protrusion is at least partially from the top of the filter element lens holder body. The protrusions extend upwards. The array camera module of claim 1, wherein the integrated base has at least one opening extending to the circuit board, and the filter element lens holder includes at least one extending leg, supplemented by the integrated body The opening of the base. The array camera module of claim 14, wherein the extending leg extends from the filter element mirror body to the circuit board such that the corresponding light window is closed. The array camera module of claim 14, wherein the extending leg is located between two adjacent light windows to separate the two light windows. The array camera module of claim 13, wherein the array camera module comprises at least one driver, each of the lenses is mounted on the driver, and the limiting protrusion is adapted to limit the The drive is on the outside. The array camera module according to any one of the preceding claims, wherein the array camera module comprises at least one driver, the lens is mounted on the driver, and the driver is mounted on the driver The integral base or the integral filter element mirror mount, or a portion of the driver is mounted to the integral base and another portion of the integral filter element mount. The array camera module according to any one of claims 1 to 16, wherein the lens is mounted on the integrated base or the integrated filter element mirror mount, or a part of the lens is mounted And an integral part of the integrated filter element lens holder on the integral base. The array camera module according to any one of the preceding claims, wherein at least one camera module is a moving focus camera module and at least one of the camera modules is fixed focus. The camera module; or the camera module is a moving focus camera module; or the camera module is a fixed focus camera module. The array camera module according to any one of claims 1 to 17, wherein the integrated base is integrally packaged on the circuit board and the photosensitive element. The array camera module according to any one of claims 1 to 17, wherein a plurality of the circuit boards of the plurality of camera modules are integrally connected to form a connected circuit board. The array camera module according to any one of the preceding claims, wherein the plurality of the circuit boards of the plurality of array camera modules are each a separate circuit board. The array camera module of any one of the preceding claims, wherein the plurality of the integrated bases of the array camera module form a connected base. The array camera module of any one of the preceding claims, wherein the plurality of the integrated bases of the array camera module are each a separate base. The array camera module according to any one of the preceding claims, wherein the plurality of filter element lens holders of the array camera module form a continuous filter element lens holder. The array camera module of claim 25, wherein the plurality of filter element lens holders of the array camera module form a connected filter element lens holder. The array camera module according to any one of the preceding claims, wherein the plurality of filter element lens holders of the array camera module are each an independent filter element lens holder. The array camera module according to any one of claims 1 to 3, wherein the plurality of the integrated bases form a connected base, and the connected base comprises a plurality of base bodies Each of the base bodies forms the light window, and the plurality of filter element lens holders are integrally connected to form a connected filter element lens holder, and the adjacent base bodies are integrally connected to form a connected body. The joint filter element lens holder has a plurality of support grooves communicating with the corresponding light windows, the support grooves being adapted to mount the filter elements, and the adjacent filter element lens holders are integrally connected to form a bridging portion that is bridged to the conjoined portion of the conjoined base. An optical component for use in an array camera module, comprising: a plurality of optical components, each of the optical components comprising an integrated base component; a photosensitive component; a filter component lens holder and a filter component; The integrated base assembly includes an integral base and a circuit board, the integrated base is integrally packaged on the circuit board; wherein the photosensitive element is operatively coupled to the circuit board, the filter element lens mount Being mounted on the integrated base, forming a light window with the integrated base to provide a light path for the photosensitive element, the filter element being disposed on the filter element lens holder to enable the filter The light element is located in the photosensitive path of the photosensitive element. The optical component of claim 30, wherein each of the filter element lens holders comprises a filter element lens holder body and at least one inner extension arm, the inner extension arm from the filter element lens holder The body partially extends laterally integrally to form a support groove adapted to mount the filter element. The optical component according to claim 30, wherein the filter element mirror base comprises a filter element mirror body, at least a lower arm and at least one inner arm, and the sink arm is self-filtering The light element lens holder body is steered to extend to form an engagement groove adapted to be coupled to the integral base, and the inner extension arm is steered from the sinking arm to form a support groove adapted to mount the filter element . The optical component of claim 32, wherein each of the integrated bases has at least one mounting groove and at least one notch, the mounting groove is connected to the light window, and the notch is connected to the light window And externally, the filter element mirror body of the filter element lens holder includes at least one engagement edge and at least one extension edge, the engagement edge being adapted to be engaged with the mounting groove, the extension edge being adapted to extend The gap forms a closed environment. The optical assembly of claim 33, wherein the integral base comprises three mounting slots, the mounting slots form a U-shaped structure, and the filter element lens holder of the filter element lens mount The body includes three engaging edges that form a U-shaped structure adapted to engage the mounting slot. The optical component according to claim 33, wherein the integrated base has two mounting slots and two notches, the mounting slots are connected to the light window, and the notches are connected to the light window and the outside. The filter element lens holder body of the filter element lens holder comprises two engaging edges and two extending edges, the two engaging edges being adapted to be engaged with the two mounting grooves, and the two extending edges are adapted to extend to two The gap forms a closed environment. The optical component of claim 35, wherein the two mounting grooves of the integrated base are opposite, two of the two notches are opposite, and the two engaging edges of the filter element lens holder are opposite, two The extended sides are opposite. The optical component according to claim 35, wherein the two mounting grooves of the integrated base are adjacent to each other, and the two notches are adjacent to each other, and the two adjacent sides of the filter element lens holder are adjacent to each other. The two extended sides are adjacent. The optical component according to claim 33, wherein the integrated base has a mounting groove and three notches, the mounting groove is connected to the light window, and the notch is connected to the light window and the outside. The filter element lens holder body of the filter element lens holder includes a joint edge and three extension edges, the joint edge is adapted to be engaged with the mounting groove, and the extension edge is adapted to extend to three The gap forms a closed environment. The optical assembly of claim 32, wherein the integral base has an inner side surface, the inner side surface has an inclination angle, and the engagement groove has an engagement angle adapted to the inclination angle. The optical component of claim 30, wherein each of the filter element mirror holders comprises an upper extension wall that extends upwardly from the filter element mirror housing body to form a limit mouth. The optical component according to claim 30, wherein each of the filter element mirror holders comprises an upper extension wall and a lower extension wall, the upper extension wall extending upward from the filter element mirror main body A limiting port is formed, and the lower extension wall is steered downwardly from the filter element mirror body to form a lower opening. The optical component according to claim 30, wherein each of the filter element lens holders comprises at least one limiting protrusion, the limiting protrusion being at least partially convex from the top of the filter element lens holder body. The ground rises upwards. The optical component according to claim 30, wherein the integral base has at least one opening extending to the circuit board, and the filter element lens holder includes at least one extending leg, supplemented by the integrated base Said opening. The optical assembly of claim 43, wherein the extension leg extends from the filter element mount body to the circuit board such that the corresponding light window is closed. The optical component of claim 43, wherein the extending leg is located between two adjacent light windows to separate the two light windows. The optical component of claim 42, wherein the array camera module comprises at least one driver, each of the lenses is mounted on the driver, and the limiting protrusion is adapted to limit the driver to Outside. The optical component according to any one of claims 30 to 46, wherein the array camera module includes at least one driver, the lens is mounted to the driver, and the driver is mounted on the An integral base or the integral filter element mirror mount, or a portion of the driver is mounted to the integral base and another portion of the integral filter element mount. The optical component according to any one of claims 30 to 45, wherein the lens is mounted on the integral base or the integral filter element lens mount, or a part of the lens is mounted on the same The integrated base and the other part of the integrated filter element lens holder. The optical component according to any one of claims 30 to 45, wherein at least one camera module is a moving focus camera module and at least one of the camera modules is a fixed focus camera module. The camera module is a moving focus camera module; or the camera module is a fixed focus camera module. The optical component according to any one of claims 30 to 46, wherein the integral base is integrally packaged on the circuit board and the photosensitive element. The optical component according to any one of claims 30 to 46, wherein the plurality of the circuit boards of the plurality of optical elements are integrally connected to form a connected circuit board. The optical component of any one of clauses 30 to 46, wherein the plurality of the circuit boards of the plurality of optical elements are each a separate circuit board. The optical component of any one of clauses 30 to 46, wherein the plurality of the integral bases of the plurality of optical elements form a connected base. The optical assembly of any one of clauses 30 to 46, wherein the plurality of the integral pedestals of the plurality of optical elements are each a separate pedestal. The optical component of any one of clauses 30 to 46, wherein the plurality of filter element holders of the plurality of optical elements form a continuous filter element holder. The optical component of claim 54, wherein the plurality of filter element holders of the plurality of optical elements form a continuous filter element holder. The optical component of any one of clauses 30 to 46, wherein each of the plurality of filter element mirrors of the plurality of optical elements are each a separate filter element holder. The optical component according to any one of claims 30 to 32, wherein the plurality of the integrated bases form a connected base, and the connected base comprises a plurality of base bodies, each The base body forms the light window, and the plurality of filter element lens holders are integrally connected to form a connected filter element lens holder, and the adjacent base bodies are integrally connected to form a connected body, The joint filter element lens holder has a plurality of support grooves communicating with the corresponding light windows, the support grooves being adapted to mount the filter elements, and the adjacent filter element lens holders are integrally connected to form a cross a connecting portion, the bridging portion is bridged to the connected portion of the connected base.