CN111474702A - Lens structure, camera, terminal, control method of terminal and computer storage medium - Google Patents

Abstract

The application relates to a lens structure, a camera, a terminal, a control method of the terminal and a computer storage medium, wherein the lens structure comprises a lens barrel, a driving piece and a flexible light transmitting piece, the flexible light transmitting piece is arranged in a light path in the lens barrel, the driving piece is used for driving the flexible light transmitting piece to deform so as to change a focal length, the lens barrel comprises a light inlet and a light outlet, the light inlet is provided with a first lens, and the flexible light transmitting piece is arranged on the inner side of the first lens. The terminal comprises a camera with the lens structure. This application carries out optics through the built-in structure of camera lens and zooms, can reduce camera lens size and structure reliably.

Description

Lens structure, camera, terminal, control method of terminal and computer storage medium

Technical Field

The application relates to the technical field of terminals, in particular to a lens structure, a camera, a terminal, a control method of the terminal and a computer storage medium.

Background

With the rapid development of terminal technology, the functions of mobile terminals such as mobile phones and tablet computers are also improved, and the mobile terminals become one of the common tools in daily life and work.

Because of the user to the shooting demand of autodyne and outer shoot, mobile terminal equipment such as current smart mobile phone has been equipped with leading camera and rear camera mostly simultaneously, however, for satisfying the demand of zooming, current scheme mainly changes the focus of camera through the external module that zooms, has the unreliable and big problem of camera lens size of structure.

Disclosure of Invention

In view of the above technical problems, the present application provides a lens structure, a camera, a terminal, a control method thereof, and a computer storage medium, in which optical zooming is performed through a structure built in a lens, so that the size of the lens can be reduced and the structure is reliable.

In order to solve the technical problem, the present application provides a lens structure, including lens cone, driving piece and flexible printing opacity piece, flexible printing opacity piece sets up in the light path in the lens cone, the driving piece is used for the drive flexible printing opacity piece warp in order to change the focus.

The lens barrel comprises a light inlet and a light outlet, a first lens is arranged at the light inlet, and the flexible light-transmitting sheet is arranged on the inner side of the first lens.

The lens barrel is provided with a first support and a second support, the first support is used for fixing the driving piece, the peripheral edge of the flexible light transmission sheet is clamped between the driving piece and the second support, and the driving piece can push the flexible light transmission sheet towards the second support so that the flexible light transmission sheet is supported by the second support to generate curvature change.

The first support is arranged close to the light inlet of the lens barrel relative to the second support, the driving piece is fixed on one side of the first support, which is back to the light inlet of the lens barrel, the second support abuts against one side of the flexible light-transmitting sheet, which is back to the light inlet of the lens barrel, and the abutting point of the second support and the flexible light-transmitting sheet is opposite to the abutting point of the driving piece and the flexible light-transmitting sheet and is closer to the center of the flexible light-transmitting sheet.

The first support is arranged opposite to the second support and far away from the light inlet of the lens barrel, the driving piece is fixed on one side of the first support, facing the light inlet of the lens barrel, the second support abuts against one side, facing the light inlet of the lens barrel, of the flexible light transmission sheet, and the abutting point of the second support and the flexible light transmission sheet is opposite to the abutting point of the driving piece and the flexible light transmission sheet and is closer to the center of the flexible light transmission sheet.

The second support is an annular support with the aperture smaller than or equal to that of the light inlet.

The number of the driving pieces is greater than or equal to four, and the driving pieces are symmetrically abutted against the peripheral edge of the flexible light-transmitting sheet.

Wherein the driving member is a piezoelectric motor.

Wherein, the flexible light-transmitting sheet is flexible glass.

The application also provides a camera which comprises the lens structure.

The lens structure comprises a lens, and is characterized by further comprising a photosensitive element, wherein the photosensitive element is arranged at a light outlet of the lens structure.

The application also provides a terminal, which comprises at least one camera as described above.

Wherein, an at least camera includes first camera and second camera, first camera with the second camera is located same one side at terminal, flexible printing opacity piece in the first camera with the initial condition of the flexible printing opacity piece in the second camera is the plane, flexible printing opacity piece in the first camera with the flexible printing opacity piece in the second camera's flexible direction of transmission is opposite.

The application also provides a terminal control method, which comprises the following steps:

controlling a driving piece to drive a flexible light-transmitting plate to deform according to a target focal length, wherein the flexible light-transmitting plate is arranged in a light path in a lens barrel of the camera;

and controlling the camera to shoot.

Wherein, be equipped with first support and second support on the lens cone, first support is used for fixing the driving piece, the edge clamp all around of flexible printing opacity piece is established the driving piece with between the second support, according to the flexible printing opacity board of target focus control driving piece drive deformation, include:

and controlling the push-out distance of the driving piece according to the target focal length, so that the flexible light-transmitting sheet is deformed to have the curvature corresponding to the target focal length under the support of the second support.

Wherein, the camera includes first camera and second camera, first camera with the second camera is located same one side at terminal, flexible printing opacity piece in the first camera with flexible printing opacity piece in the second camera corresponds standard focus when being in planar state, flexible printing opacity piece in the first camera focus shortens when warping, flexible printing opacity piece in the second camera focus when warping lengthens, warp according to the flexible printing opacity board of target focus control driving piece drive, include:

when the target focal length is smaller than the standard focal length, controlling a driving piece in the first camera to drive the flexible light-transmitting plate to deform according to the target focal length;

when the target focal length is larger than the standard focal length, controlling a driving piece in the second camera to drive the flexible light-transmitting plate to deform according to the target focal length;

when the target focal length is the standard focal length, a driving piece in the camera used at present is not controlled to work, and the corresponding flexible light-transmitting sheet is in a planar state.

Wherein, before controlling the driving piece to drive the flexible light-transmitting plate to deform according to the target focal length, the method further comprises the following steps:

starting the first camera or the second camera;

displaying selectable focal length types on a shooting interface, wherein the selectable focal length types comprise a long focal length, a standard focal length and a short focal length;

and switching the camera according to the selected focal length type, and displaying a focal length adjusting area for adjusting the target focal length.

The present application also provides a terminal, including a memory and a processor, where the memory is used to store at least one program instruction, and the processor is used to implement the control method of the terminal by loading and executing the at least one program instruction.

The present application further provides a computer storage medium having computer program instructions stored thereon; which when executed by a processor implement the control method of the terminal as described above.

As described above, the lens structure of the present application includes lens cone, driving piece and flexible printing opacity piece, and flexible printing opacity piece sets up in the light path in the lens cone, and the driving piece is used for driving flexible printing opacity piece to warp in order to change the focus, and the lens cone includes income light mouth and light-emitting window, and income light mouth is equipped with first lens, and flexible printing opacity piece sets up the inboard at first lens. The terminal comprises a camera with the lens structure. This application carries out optics through the built-in structure of camera lens and zooms, can reduce camera lens size and structure reliably.

On the other hand, the control method of the terminal and the computer storage medium control the driving part to drive the flexible light-transmitting plate to deform according to the target focal length, wherein the flexible light-transmitting plate is arranged in a light path in the lens barrel of the camera, and then the camera is controlled to shoot. So, this application can control built-in structure and carry out optics and zoom, obtains different focuses and shoots, satisfies different shooting demands.

Drawings

Fig. 1 is a schematic structural view of a lens structure shown according to a first embodiment;

FIG. 2 is a schematic structural view of the lens structure of FIG. 1 when the flexible light-transmissive sheet is deformed;

FIG. 3 is a schematic top view of the lens structure of FIG. 1 with the first support and portions thereof removed;

fig. 4 is a partial structural schematic view of a lens structure shown according to a second embodiment;

FIG. 5 is a schematic view of the lens structure of FIG. 4 with the flexible light transmissive sheet deformed;

fig. 6 is a schematic structural view of a camera head according to a third embodiment;

FIG. 7 is a schematic view of the camera of FIG. 6 with the flexible light transmissive sheet deformed;

fig. 8 is a schematic structural view of a terminal shown according to a fourth embodiment;

fig. 9 is a flowchart illustrating a control method of a terminal according to a fifth embodiment;

fig. 10 is one of the configuration diagrams of the terminal shown according to the sixth embodiment;

fig. 11 is a second schematic structural diagram of the terminal shown in fig. 10.

Detailed Description

The following description of the embodiments of the present application is provided for illustrative purposes, and other advantages and capabilities of the present application will become apparent to those skilled in the art from the present disclosure.

In the following description, reference is made to the accompanying drawings that describe several embodiments of the application. It is to be understood that other embodiments may be utilized and that mechanical, structural, electrical, and operational changes may be made without departing from the spirit and scope of the present application. The following detailed description is not to be taken in a limiting sense, and the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application.

First embodiment

Fig. 1 is a schematic structural diagram of a lens structure shown according to a first embodiment. Referring to fig. 1, the lens structure of the present embodiment includes a lens barrel 21, a driving member 22 and a flexible transparent sheet 23, the flexible transparent sheet 23 is disposed in an optical path in the lens barrel 21, and the driving member 22 is used for driving the flexible transparent sheet 23 to deform to change a focal length. The flexible light-transmitting sheet 23 arranged in the lens barrel 21 is driven to deform to change the focal length, so that the structure is simple, the size of the lens can be reduced, and the built-in structure is more stable and reliable.

The lens barrel 21 is a multi-step cylindrical structure, the small aperture end is a light inlet 211, the large aperture end is a light outlet 212, the light inlet 211 is provided with a first lens 251, and a plurality of lenses 252 can be arranged between the first lens 251 and the light outlet 212 to form a light path together. The flexible light-transmitting sheet 23 is disposed inside the first lens 251, and may be located between the first lens 251 and another adjacent lens, or between two other adjacent lenses, in this embodiment, the flexible light-transmitting sheet 23 is located between the first lens 251 and another adjacent lens to be close to the light entrance 211, so that a better zooming effect may be achieved with a smaller deformation range, which is beneficial to further reducing the size of the lens. The flexible light-transmitting sheet 23 includes, but is not limited to, a transparent film with deformation-recovery capability, such as flexible glass, and in the present embodiment, the flexible light-transmitting sheet 23 corresponds to a standard focal length when in a planar state.

Referring to fig. 1 and fig. 2, the lens barrel 21 is provided with a first bracket 213 and a second bracket 215, the first bracket 213 is used for fixing the driving element 22, the peripheral edge of the flexible light-transmitting sheet 23 is sandwiched between the driving element 22 and the second bracket 215, and the driving element 22 can push the flexible light-transmitting sheet 23 toward the second bracket 215, so that the flexible light-transmitting sheet 23 generates curvature change under the support of the second bracket 215. The peripheral edge of the flexible light-transmitting sheet 23 is sandwiched between the driving member 22 and the second holder 215, so as to be positioned in the optical path in the lens barrel 21 in a manner of being perpendicular to the central axis of the lens barrel 21, and avoid wobbling in the axial direction and circumferential wobbling to a certain extent. In practical implementation, in order to further avoid circumferential shaking of the flexible light-transmitting sheet 23, a limiting structure may be disposed on the first support 213 or the second support 215, and by designing the shape and size of the flexible light-transmitting sheet 23, when the flexible light-transmitting sheet 23 is in a planar state, the edge of the flexible light-transmitting sheet 23 may abut against the limiting structure, so as to achieve circumferential limiting, where the limiting structure is, for example, an inner side surface of a central axis of the parallel lens barrel 21 of the first support 213, and depending on the structures of the first support 213 and the second support 215, the limiting structure may also abut against an inner side surface of a central axis of the parallel lens barrel 21 of the second support 215, or the limiting structure may also be a limiting protrusion on the first support 213 or the second support 215, and only needs to play a limiting role when the flexible light-transmitting sheet 23 is in a planar state and not affect the deformation-recovery process of the flexible.

In this embodiment, the first bracket 213 is disposed close to the light inlet 211 of the lens barrel 21 relative to the second bracket 215, the driving member 22 is fixed on a side of the first bracket 213 facing away from the light inlet 211 of the lens barrel 21, the second bracket 215 abuts on a side of the flexible light-transmitting sheet 23 facing away from the light inlet 211 of the lens barrel 21, and an abutting point of the second bracket 215 and the flexible light-transmitting sheet 23 is closer to a center of the flexible light-transmitting sheet 23 relative to an abutting point of the driving member 22 and the flexible light-transmitting sheet 23. In order not to affect the light incident area of the lens barrel 21, please refer to fig. 3, the second support 215 is a ring-shaped support with an aperture smaller than or equal to the light incident port 211. As shown in fig. 2, when the driving member 22 pushes the flexible light-transmitting sheet 23 toward the second holder 215, the flexible light-transmitting sheet 23 may be supported by the second holder 215 to protrude toward the light inlet 211 of the lens barrel 21 to change its curvature, so as to shorten the focal length, and when the focal length is changed from the standard focal length to the short focal length, the field angle is increased, which is equivalent to changing from the standard lens to the wide-angle lens, whereas, as shown in fig. 1, when the driving member 22 is reset, the flexible light-transmitting sheet 23 is deformed to return to the planar state, so as to change the focal length from the short focal length to the standard focal length, which is the default standard lens.

In the present embodiment, the driving member 22 is a piezoelectric motor, which is a motor driven by exciting ultrasonic waves with piezoelectric ceramic materials, and has the characteristics of large torque output at low speed, no electromagnetic interference, quiet operation, large holding torque, fast response speed, simple structure, and the like. The number of the driving members 22 is greater than or equal to four, and the driving members are symmetrically abutted against the peripheral edge of the flexible light-transmitting sheet 23 to ensure uniform driving force, as shown in fig. 3, the number of the driving members 22 in the embodiment is four, and the driving members 22 are symmetrically arranged at four corners of the flexible light-transmitting sheet 23, and the positive electrode 221 and the negative electrode 222 of the driving members 22 are led out from one side of the lens barrel 21 to be connected with the control chip.

In practice, the lens barrel 21 may be divided into an upper portion and a lower portion, the first bracket 213 may be integrally provided with the upper portion of the lens barrel 21, and the second bracket 215 may be integrally provided with the lower portion of the lens barrel 21, and the upper portion of the lens barrel 21 may be fixed to the lower portion of the lens barrel 21 by engaging, screwing, or adhering the first bracket 213 and the second bracket 215, thereby forming the complete lens barrel 21.

The lens structure of this embodiment includes lens cone, driving piece and flexible printing opacity piece, and flexible printing opacity piece sets up in the light path in the lens cone, and the driving piece is used for driving flexible printing opacity piece to warp in order to change the focus. The structure built in the lens is used for carrying out optical zooming, the size of the lens can be reduced, and the structure is reliable.

In addition, the relative second support of first support is close to the income light mouth setting of lens cone, the driving piece is fixed in the one side of the income light mouth of the lens cone of the back of the first support, the second support supports and leans on the one side at the income light mouth of the lens cone of flexible printing opacity piece, the support of the support point of second support and flexible printing opacity piece is more close to the center of flexible printing opacity piece with the support point of flexible printing opacity piece relative driving piece and flexible printing opacity piece, when the driving piece promoted flexible printing opacity piece towards the direction of second support, flexible printing opacity piece can be protruding and take place curvature change to the income light mouth direction of lens cone under the support of second support, make the focus shorten, realize the standard focus to the regulation between the short focus.

Second embodiment

Fig. 4 is a partial structural schematic diagram of a lens structure shown according to a second embodiment. Referring to fig. 4, fig. 4 only shows the matching structure among the first bracket 313, the second bracket 315, the driving member 32 and the flexible light-transmitting sheet 33, and the main difference between the lens structure of the present embodiment and the first embodiment is:

the first bracket 313 is disposed away from the light inlet (refer to the light inlet 211 in fig. 1) of the lens barrel relative to the second bracket 315, the driving member 32 is fixed on a side of the first bracket 313 facing the light inlet of the lens barrel, the second bracket 315 abuts against a side of the flexible light-transmitting sheet 33 facing the light inlet of the lens barrel, and an abutting point of the second bracket 315 and the flexible light-transmitting sheet 33 is closer to a center of the flexible light-transmitting sheet 33 relative to an abutting point of the driving member 32 and the flexible light-transmitting sheet 33.

Thus, as shown in fig. 5, when the driving member 32 pushes the flexible light-transmitting sheet 33 toward the second holder 315, the flexible light-transmitting sheet 33 may be supported by the second holder 315 to protrude toward the light outlet (refer to the light outlet 212 in fig. 1) of the lens barrel, so as to change the curvature of the light-transmitting sheet, so as to increase the focal length, and when the focal length changes from the standard focal length to the long focal length, the field angle becomes smaller, which is equivalent to changing from the standard lens to the narrow-angle lens, whereas, as shown in fig. 4, when the driving member 32 is reset, the flexible light-transmitting sheet 33 deforms and returns to the flat state, so as to change the focal length from the long focal length to the standard focal length, which is the.

Other parts of the lens structure of this embodiment are described in the first embodiment, and are not described herein again.

The lens structure of the embodiment performs optical zooming through the built-in structure of the lens, can reduce the size of the lens and has a reliable structure. In addition, the income light mouth setting that the lens cone was kept away from to the relative second support of first support, the driving piece is fixed in one side of the income light mouth of first support orientation lens cone, the second support supports and leans on the flexible printing opacity piece towards the income light mouth of lens cone one side, the support point of second support and flexible printing opacity piece is more close to the center of flexible printing opacity piece with the support point of flexible printing opacity piece relative driving piece and flexible printing opacity piece, when the driving piece promoted flexible printing opacity piece towards the direction of second support, flexible printing opacity piece can be protruding and take place the camber change to the light-emitting opening direction of lens cone under the support of second support, make the focus lengthen, realize the regulation between standard focus to the long focus.

Third embodiment

Fig. 6 is a schematic structural diagram of a camera head shown according to the third embodiment. Referring to fig. 6, the camera of the present embodiment includes the lens structure according to the first embodiment, and when the lens structure according to the first embodiment is applied, the camera of the present embodiment can achieve adjustment from a standard focal length to a short focal length.

The camera further includes a photosensitive element 46 and a circuit board 47, the photosensitive element 46 is disposed at the light exit of the lens barrel 41, and light entering from the light entrance 411 of the lens barrel 41 enters the photosensitive element 46 to generate a photosensitive signal through adjustment of each lens and the flexible light-transmitting sheet 43, and is processed by a chip on the circuit board 47 to generate an image.

When a short focal length is required, as shown in fig. 7, the driving member 42 is controlled to push the flexible light-transmitting sheet 43 toward the second holder 415, the flexible light-transmitting sheet 43 protrudes toward the light inlet 411 of the lens barrel 41 under the support of the second holder 415 to change the curvature, so that the focal length is shortened, when the focal length is changed from the standard focal length to the short focal length, the field angle is increased, which is equivalent to changing from the standard lens to the wide-angle lens, and conversely, as shown in fig. 6, when the driving member 42 is reset, the flexible light-transmitting sheet 43 is deformed to return to the planar state, so that the focal length is changed from the short focal length to the standard focal length, which is the default standard lens.

Other parts of the lens barrel structure of the camera in this embodiment are described in the first embodiment, and are not described herein again.

The camera of this embodiment includes the lens structure described in the first embodiment, and optical zooming is performed by the structure built in the lens, so that the size of the lens can be reduced, the structure is reliable, and in addition, adjustment from a standard focal length to a telephoto focal length can be realized.

In another embodiment, the camera may further include the lens structure described in the second embodiment, and when the lens structure described in the second embodiment is applied, the camera may implement adjustment between a standard focal length and a telephoto focal length, and the specific structure and the working engineering refer to the description of the second embodiment, which is not described herein again. In practical implementation, the lens structure according to the first embodiment or the second embodiment may be selected and applied according to a zoom function to be implemented by the camera.

Fourth embodiment

Fig. 8 is a schematic structural diagram of a terminal shown according to a fourth embodiment. Referring to fig. 8, the terminal 50 of the present embodiment includes at least one camera, and each camera has the lens structure described in the first embodiment or the second embodiment.

The terminal 50 includes a front camera and a rear camera, and both the front camera and the rear camera can use the lens structure described in the first embodiment or the second embodiment.

In this embodiment, at least one camera includes a first camera 51 and a second camera 52, the first camera 51 and the second camera 52 are located on the same side of the terminal 50, and may be located on the screen side or on the rear housing side, the initial states of the flexible light-transmitting sheet in the first camera 51 and the flexible light-transmitting sheet in the second camera 52 are both planar, and correspond to a standard focal length, and the flexible light-transmitting sheet in the first camera 51 and the flexible light-transmitting sheet in the second camera 52 have opposite deformable directions, that is, the zoom functions of the first camera 51 and the second camera 52 are different, for example, the focal length of the flexible light-transmitting sheet in the first camera 51 is shortened when deformed, and the focal length of the flexible light-transmitting sheet in the second camera 52 is lengthened when deformed. So, through configuring two cameras that zoom the function difference with one side at terminal 50 for terminal 50's camera module can change between short focal length, standard focal length, long focal length, and the focus control range is big, is fit for various shooting scenes.

The terminal of the embodiment includes the camera having the lens structure of the first embodiment and/or the second embodiment, and the size of the lens can be reduced and the structure is reliable by optically zooming through the structure built in the lens, so that the overall thickness of the terminal can be reduced, the structure is reliable, and the adjustment of the focal length can be realized.

Fifth embodiment

Fig. 9 is a flowchart illustrating a control method of a terminal according to a fifth embodiment. Referring to fig. 9, the method for controlling a terminal of the present embodiment includes:

step 610, controlling a driving piece to drive a flexible light-transmitting plate to deform according to a target focal length, wherein the flexible light-transmitting plate is arranged in a light path in a lens barrel of the camera;

and step 620, controlling the camera to shoot.

In this embodiment, be equipped with first support and second support on the lens cone of camera, first support is used for fixed driving piece, and the edge clamp all around of flexible printing opacity piece is established between driving piece and second support, and according to the flexible light-passing board of target focus control driving piece drive deformation, include:

and controlling the pushing-out distance of the driving piece according to the target focal length to enable the flexible light-transmitting sheet to deform to have curvature corresponding to the target focal length under the support of the second support.

Wherein, the degree of deformation that the camber refers to flexible printing opacity piece is protruding, and the camber is big more, and the degree that shows protruding deformation is big more, the distance of release of driving piece influences the degree of deformation of flexible printing opacity piece, also influences the camber after flexible printing opacity piece warp promptly, and the size of focus is then decided to the camber after flexible printing opacity piece warp, consequently, the distance of release is big more, and flexible printing opacity piece deformation degree is big more, and the focus is then shorter. When the driving piece is a piezoelectric motor, the pushing-out distance of the motor is controlled by controlling the voltage, so that the corresponding focal length is obtained.

When the camera includes first camera and second camera, first camera and second camera are located same one side at the terminal, correspond standard focus when flexible printing opacity piece in the first camera and the flexible printing opacity piece in the second camera are in planar state, the focus shortens when warping flexible printing opacity piece in the first camera, the focus is elongated when warping flexible printing opacity piece in the second camera, at this moment, according to the flexible printing opacity board of target focus control driving piece drive deformation, include:

when the target focal length is smaller than the standard focal length, controlling a driving piece in the first camera to drive the flexible light-transmitting plate to deform according to the target focal length;

when the target focal length is larger than the standard focal length, controlling a driving piece in the second camera to drive the flexible light-transmitting plate to deform according to the target focal length;

when the target focal length is the standard focal length, a driving piece in the camera used at present is not controlled to work, and the corresponding flexible light-transmitting sheet is in a planar state.

Wherein, through configuring two cameras that zoom the function difference with one side at the terminal for the camera module at terminal can change between short focal length, standard focus, long focal length, and focus control range is big, is fit for various shooting scenes, and during the use, only need can satisfy the camera that the focus required according to required focus control and carry out work, and another camera is out of work, can shoot satisfied photo.

In order to obtain the target focal length, before controlling the driving element to drive the flexible light-transmitting plate to deform according to the target focal length, the method further comprises:

starting the first camera or the second camera;

displaying selectable focal length types on a shooting interface, wherein the selectable focal length types comprise a long focal length, a standard focal length and a short focal length;

and switching the camera according to the selected focal length type, and displaying a focal length adjusting area for adjusting the target focal length.

After the photographing application is opened, the first camera or the second camera is started firstly, a preview picture is provided for a user to refer to, selectable focal length types are displayed on a photographing interface, the selectable focal length types comprise a long focal length, a standard focal length and a short focal length, then the user can select one of the focal length types according to needs, the terminal opens the corresponding camera according to the focal length type selected by the user, namely, the camera is switched, and the currently working camera can meet the current focal length requirement. Meanwhile, the shooting interface also displays a focus adjusting area for adjusting the target focus, for example, an operating area such as a slide bar, and a user can adjust the focus within the corresponding focus range by pulling the slide bar to obtain the target focus.

In a scene, after a photographing application is opened, a first camera is started, selectable focal length types are displayed on a photographing interface, the selectable focal length types comprise a long focal length, a standard focal length and a short focal length, then, if a user selects the short focal length or the standard focal length, the camera does not need to be switched, and if the user selects the long focal length, the second camera is switched to work. Meanwhile, the shooting interface also displays a slide bar for adjusting the target focal length, if the current focal length type is the short focal length, the slide bar can slide between the standard focal length and a shorter focal length to select the target focal length, and if the current focal length type is the long focal length, the slide bar can slide between the standard focal length and a longer focal length to select the target focal length. In addition, if the current focal length type is the standard focal length, the adjusting range of the focal length adjusting area covers the short focal length and the long focal length, and the adjustable operating key is displayed at the standard focal length, if the user adjusts the short focal length, the currently working camera is switched to the first camera, otherwise, if the user adjusts the long focal length, the currently working camera is switched to the second camera, that is, the camera can also be switched by operating in the focal length adjusting area, so that the convenience of interaction is improved.

According to the control method of the terminal, the driving piece is controlled to drive the flexible light-transmitting plate to deform according to the target focal length, the flexible light-transmitting plate is arranged in a light path in the lens barrel of the camera, and then the camera is controlled to shoot. So, this application can control built-in structure and carry out optics and zoom, obtains different focuses and shoots, satisfies different shooting demands.

Sixth embodiment

Fig. 10 is one of the structural diagrams of the terminal shown according to the sixth embodiment. Referring to fig. 10, the terminal 10 of the present embodiment includes a memory 102 and a processor 106, where the memory 102 is configured to store at least one program instruction, and the processor 106 is configured to implement the control method of the terminal according to the fifth embodiment by loading and executing the at least one program instruction.

Referring to fig. 11, in actual implementation, the terminal 10 includes a memory 102, a memory controller 104, one or more processors 106 (only one of which is shown), a peripheral interface 108, a radio frequency module 150, a positioning module 112, a camera module 114, an audio module 116, a screen 118, and a key module 160. These components communicate with each other via one or more communication buses/signal lines 122.

It will be appreciated that the configuration shown in FIG. 11 is merely illustrative and that terminal 10 may include more or fewer components than shown in FIG. 11 or may have a different configuration than shown in FIG. 11. The components shown in fig. 11 may be implemented in hardware, software, or a combination thereof.

The memory 102 may be used to store software programs and modules, such as program instructions/modules corresponding to the control method of the terminal in the embodiment of the present application, and the processor 106 executes various functional applications and data processing by running the software programs and modules stored in the storage controller 104, so as to implement the control method of the terminal.

The memory 102 may include high speed random access memory, and may also include non-volatile memory, such as one or more magnetic storage devices, flash memory, or other non-volatile solid-state memory. In some examples, the memory 102 may further include memory located remotely from the processor 106, which may be connected to the terminal 10 via a network. Examples of such networks include, but are not limited to, the internet, intranets, local area networks, mobile communication networks, and combinations thereof. Access to the memory 102 by the processor 106, and possibly other components, may be under the control of the memory controller 104.

Peripheral interface 108 couples various input/output devices to the CPU and memory 102. The processor 106 executes various software, instructions within the memory 102 to perform various functions of the terminal 10 and to perform data processing.

In some embodiments, the peripheral interface 108, the processor 106, and the memory controller 104 may be implemented in a single chip. In other examples, they may be implemented separately from the individual chips.

The rf module 150 is used for receiving and transmitting electromagnetic waves, and implementing interconversion between the electromagnetic waves and electrical signals, so as to communicate with a communication network or other devices. Rf module 150 may include various existing circuit elements for performing these functions, such as an antenna, a radio frequency transceiver, a digital signal processor, an encryption/decryption chip, a Subscriber Identity Module (SIM) card, memory, and so forth. The rf module 150 may communicate with various networks such as the internet, an intranet, a wireless network, or with other devices via a wireless network. The wireless network may comprise a cellular telephone network, a wireless local area network, or a metropolitan area network. The Wireless network may use various Communication standards, protocols, and technologies, including, but not limited to, Global System for Mobile Communication (GSM), Enhanced Data GSM Environment (EDGE), wideband Code division multiple Access (W-CDMA), Code Division Multiple Access (CDMA), Time Division Multiple Access (TDMA), bluetooth, Wireless Fidelity (WiFi) (e.g., Institute of Electrical and Electronics Engineers (IEEE) standard IEEE802.11 a, IEEE802.11 b, IEEE 802.2.1 g, and/or IEEE802.11 n), Voice over Internet Protocol (VoIP), world wide Internet Microwave Access (Microwave for Wireless Communication), other suitable protocols for short message service (Max), and any other suitable Communication protocols, and may even include those protocols that have not yet been developed.

The positioning module 112 is used for acquiring the current position of the terminal 10. Examples of the positioning module 112 include, but are not limited to, a global positioning satellite system (GPS), a wireless local area network-based positioning technology, or a mobile communication network-based positioning technology.

The camera module 114 is used to take a picture or video. The pictures or videos taken may be stored in the memory 102 and transmitted through the radio frequency module 150.

Audio module 116 provides an audio interface to a user that may include one or more microphones, one or more speakers, and audio circuitry. The audio circuitry receives audio data from the peripheral interface 108, converts the audio data to electrical information, and transmits the electrical information to the speaker. The speaker converts the electrical information into sound waves that the human ear can hear. The audio circuitry also receives electrical information from the microphone, converts the electrical information to voice data, and transmits the voice data to the peripheral interface 108 for further processing. The audio data may be retrieved from the memory 102 or through the radio frequency module 150. In addition, the audio data may also be stored in the memory 102 or transmitted through the radio frequency module 150. In some examples, the audio module 116 may also include an earphone jack for providing an audio interface to a headset or other device.

The screen 118 provides an output interface between the terminal 10 and the user. In particular, screen 118 displays video output to the user, the content of which may include text, graphics, video, and any combination thereof. Some of the output results are for some of the user interface objects. It is understood that the screen 118 may also include a touch screen. The touch screen provides both an output and an input interface between the terminal 10 and a user. In addition to displaying video output to users, touch screens also receive user input, such as user clicks, swipes, and other gesture operations, so that user interface objects respond to these user input. The technique of detecting user input may be based on resistive, capacitive, or any other possible touch detection technique. Specific examples of touch screen display units include, but are not limited to, liquid crystal displays or light emitting polymer displays.

The key module 160 also provides an interface for user input to the terminal 10, and the user can press different keys to cause the terminal 10 to perform different functions.

The present application further provides a computer storage medium having computer program instructions stored thereon; the computer program instructions, when executed by a processor, implement a control method of a terminal as described in the fifth embodiment.

In practical implementation, the computer storage medium is applied to the terminal shown in fig. 10 or fig. 11, so that the built-in structure can be controlled to perform optical zooming, different focal lengths can be obtained for shooting, and different shooting requirements can be met.

The above embodiments are merely illustrative of the principles and utilities of the present application and are not intended to limit the application. Any person skilled in the art can modify or change the above-described embodiments without departing from the spirit and scope of the present application. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical concepts disclosed in the present application shall be covered by the claims of the present application.

Claims (11)

1. The utility model provides a lens structure, its characterized in that includes lens cone, driving piece and flexible printing opacity piece, flexible printing opacity piece sets up in the light path in the lens cone, the driving piece is used for the drive flexible printing opacity piece warp in order to change the focus, the lens cone is including going into light mouth and light-emitting window, it is equipped with first lens to go into the light mouth, flexible printing opacity piece sets up the inboard of first lens.

2. The lens structure according to claim 1, wherein the lens barrel is provided with a first bracket and a second bracket, the first bracket is used for fixing the driving element, a peripheral edge of the flexible light-transmitting sheet is clamped between the driving element and the second bracket, and the driving element can push the flexible light-transmitting sheet toward the second bracket, so that the flexible light-transmitting sheet is supported by the second bracket to change its curvature.

3. The lens structure according to claim 2, wherein the first bracket is disposed close to the light entrance of the lens barrel relative to the second bracket, the driving member is fixed to a side of the first bracket facing away from the light entrance of the lens barrel, the second bracket abuts against a side of the flexible light transmitting sheet facing away from the light entrance of the lens barrel, and an abutting point of the second bracket and the flexible light transmitting sheet is closer to a center of the flexible light transmitting sheet relative to an abutting point of the driving member and the flexible light transmitting sheet.

4. The lens structure according to claim 2, wherein the first bracket is disposed away from the light entrance of the lens barrel relative to the second bracket, the driving member is fixed on a side of the first bracket facing the light entrance of the lens barrel, the second bracket abuts against a side of the flexible light-transmitting sheet facing the light entrance of the lens barrel, and an abutting point of the second bracket and the flexible light-transmitting sheet is closer to a center of the flexible light-transmitting sheet relative to an abutting point of the driving member and the flexible light-transmitting sheet.

5. The lens structure according to claim 3 or 4, wherein the second support is an annular support having an aperture smaller than or equal to the light inlet.

6. A control method of a terminal, comprising:

controlling a driving piece to drive a flexible light-transmitting plate to deform according to a target focal length, wherein the flexible light-transmitting plate is arranged in a light path in a lens barrel of the camera;

and controlling the camera to shoot.

7. The method according to claim 6, wherein a first bracket and a second bracket are provided on the lens barrel, the first bracket is used for fixing the driving member, a peripheral edge of the flexible transparent sheet is clamped between the driving member and the second bracket, and the driving member is controlled to drive the flexible transparent sheet to deform according to the target focal length, the method including:

and controlling the push-out distance of the driving piece according to the target focal length, so that the flexible light-transmitting sheet is deformed to have the curvature corresponding to the target focal length under the support of the second support.

8. The method for controlling the terminal according to claim 6, wherein the camera includes a first camera and a second camera, the first camera and the second camera are located on the same side of the terminal, the flexible transparent sheet in the first camera and the flexible transparent sheet in the second camera correspond to a standard focal length when in a planar state, the focal length of the flexible transparent sheet in the first camera is shortened when the flexible transparent sheet in the first camera is deformed, the focal length of the flexible transparent sheet in the second camera is lengthened when the flexible transparent sheet in the second camera is deformed, and the driving member is controlled to drive the flexible transparent sheet to be deformed according to the target focal length, including:

when the target focal length is smaller than the standard focal length, controlling a driving piece in the first camera to drive the flexible light-transmitting plate to deform according to the target focal length;

when the target focal length is larger than the standard focal length, controlling a driving piece in the second camera to drive the flexible light-transmitting plate to deform according to the target focal length;

when the target focal length is the standard focal length, a driving piece in the camera used at present is not controlled to work, and the corresponding flexible light-transmitting sheet is in a planar state.

9. The method of claim 8, wherein before the controlling the driving member to drive the flexible transparent plate to deform according to the target focal length, the method further comprises:

starting the first camera or the second camera;

displaying selectable focal length types on a shooting interface, wherein the selectable focal length types comprise a long focal length, a standard focal length and a short focal length;

and switching the camera according to the selected focal length type, and displaying a focal length adjusting area for adjusting the target focal length.

10. A terminal, characterized in that it comprises a memory for storing at least one program instruction and a processor for implementing the control method of the terminal according to any one of claims 6 to 9 by loading and executing the at least one program instruction.

11. A computer storage medium having computer program instructions stored thereon; the computer program instructions, when executed by a processor, implement a control method for a terminal as claimed in any one of claims 6 to 9.

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