CN104519265B - A kind of terminal device and image capture method - Google Patents

Abstract

A kind of terminal device and image capture method that multi-direction shooting can be realized with single camera is provided, terminal device includes: camera, including camera lens and photosensitive-member, optical axis direction are orthogonal to first direction and second direction；First unthreaded hole is set to the first surface of terminal device, is configured such that the light from first direction enters terminal device；Second unthreaded hole is set to the second surface of terminal device, is configured such that the light from second direction enters terminal device；First optical path modulation component configures to change the direction of the light from the first unthreaded hole or the second unthreaded hole；And control unit, it configures the first optical path modulation component is controlled, so that the light from the first unthreaded hole projects in camera when receiving the signal of the first screening-mode of user's selection；When receiving the signal of the second screening-mode of user's selection, the first optical path modulation component is controlled, so that the light from the second unthreaded hole projects in the camera.

Description

A kind of terminal device and image capture method

Technical field

The present invention relates to photography technologies, more particularly to a kind of terminal device that multi-direction shooting can be realized with single camera And image capture method.

Background technique

Nowadays, with the multifunction of electronic product, in many laptops, tablet computer, mobile phone and other electricity Camera is equipped in sub- equipment.In order to realize the shooting to multiple directions, multiple cameras are often equipped in equipment.Example Such as, two cameras often are equipped with the back side in the front of equipment.However, the equipment phase of such design and single camera It is more larger than occupied space, affect compactedness, the frivolous property of equipment.Moreover, it is more multiple to will lead to design for multiple cameras Miscellaneous and cost increase.In this regard, being located at the positive secondary camera of equipment for realizing Self-timer in performance for save the cost Aspect is often below the main camera for being located at equipment back side, but this method sacrifices the effect of front shooting, cannot expire simultaneously The requirement of sufficient high-performance and low cost.

In order to solve the above problems, there is the technology that the shooting to multiple directions is realized using a camera.According to this Technology changes shooting direction by rotating entire camera, to realize the multi-direction shooting of single camera.But it is such to set Meter, in order to enable camera, all directions are rotated on an electronic device, are needed to configure camera in device end, be limited The layout of camera, while being difficult to minimize, influence the beauty of equipment entirety.Moreover, above-mentioned technology generally requires manually Operation rotation, influences the operational and easily damaged of user.

Summary of the invention

The present invention is completed in view of the above project, it is intended that multi-direction bat can be realized with single camera by providing one kind The terminal device and image capture method taken the photograph.According to above-mentioned terminal device and image capture method, can not only save the cost, can be with Guarantee that the camera shooting performance of multiple directions is identical, viewfinder range is wide, occupies little space, and has good operability and flexible design Property.

The embodiment provides a kind of terminal device, including: camera, including camera lens and photosensitive-member, Its optical axis direction is orthogonal to first direction and second direction；First unthreaded hole is set to the first surface of the terminal device, configuration Come so that the light from the first direction enters the terminal device；Second unthreaded hole is set to the of the terminal device Two surfaces are configured such that the light from the second direction enters the terminal device；First optical path modulation component, configuration To change the direction of the light from first unthreaded hole or second unthreaded hole；And control unit, configuration receive to work as When the signal of the first screening-mode selected to user, the first optical path modulation component is controlled, so that coming from first light The light in hole projects in the camera；When receiving the signal of the second screening-mode of user's selection, described the is controlled One optical path modulation component, so that the light from second unthreaded hole projects in the camera.

The embodiment of the present invention also provides a kind of image capture method, is applied to terminal device, and the terminal device includes camera shooting Head, including camera lens and photosensitive-member, optical axis direction are orthogonal to first direction and second direction；First unthreaded hole is set to described The first surface of terminal device is configured such that the light from the first direction enters the terminal device；Second unthreaded hole, It is set to the second surface of the terminal device, is configured such that the light from the second direction enters the terminal and sets It is standby；First optical path modulation component configures to change the direction of the light from first unthreaded hole or second unthreaded hole, In, the image capture method includes: the signal for receiving the screening-mode selected from user；When the first count for receiving user's selection When taking the photograph the signal of mode, control the first optical path modulation component so that the light from first unthreaded hole project it is described In camera；When receiving the signal of the second screening-mode of user's selection, the first optical path modulation component is controlled, so that Light from second unthreaded hole projects in the camera.

It, can not only save the cost according to above-mentioned terminal device and image capture method, it can also be ensured that multiple directions are taken the photograph Picture performance is identical, occupies little space, and has good operability and design flexibility.

Detailed description of the invention

Fig. 1 (a) and (b) are the perspective views of terminal device of the invention.

Fig. 2 (a) and (b) are the schematic diagrames of the first structure of optical path modulation component of the invention.

Fig. 3 (a) and (b) are the schematic diagrames of second of structure of optical path modulation component of the invention.

Fig. 4 (a) and (b), (c), (d) are to realize pan-shot using second of structure of optical path modulation component of the invention Schematic diagram.

Fig. 5 (a) and (b) are the schematic diagrames of the third structure of optical path modulation component of the invention.

Fig. 6 (a) and (b) are the schematic diagrames of the preferred structure of two optical path modulation components of use of the invention.

Fig. 7 is the flow chart of first embodiment of image pickup method of the invention.

Fig. 8 is the flow chart of second embodiment of image pickup method of the invention.

Specific embodiment

To make those skilled in the art more fully understand technical solution of the present invention, this is described in detail with reference to the accompanying drawing The terminal device of invention and the embodiment of image pickup method.For convenience of explanation, in following the present embodiment with can be at least real It is illustrated for the mobile phone now taken pictures in the front-back direction, and assigns same label to same component.But art technology Personnel should be understood that the terminal device in the present invention besides a cellular phone, can also be laptop, tablet computer and Other any electronic equipments.In the following figures, using X-axis positive direction as the front-right (width direction) of terminal device, by Y-axis As the surface (length direction) of terminal device, Z axis is illustrated as the front (thickness direction) of terminal device. In addition, be illustrated using the terminal device that can shoot front-rear direction (Z axis positive direction and negative direction) as example in the present invention, But not limited to this, it is also possible to that the terminal device in other directions opposite each other can be shot.

It is noted that based on the embodiments of the present invention, those of ordinary skill in the art are not making creative work Under the premise of every other embodiment obtained, shall fall within the protection scope of the present invention.

[terminal device]

Fig. 1 (a) and (b) are the perspective views of terminal device of the invention.(a) and (b) are it is found that terminal of the invention referring to Fig.1 Equipment 100 includes: camera 110;First unthreaded hole 120；Second unthreaded hole 130；First optical path modulation component 140 and control unit 150。

In the present embodiment, camera 110 includes camera lens 111 and photosensitive-member 112, and optical axis direction is Y-axis positive direction, The plane of the photosensitive-member 112 of camera 110 is parallel to the plane of XZ axis composition, photosensitive-member 112 can be CCD either The photosensitive elements such as CMOS.The shell that first unthreaded hole 120 is set to terminal device 100 is positive (i.e. Z axis positive direction), so that from eventually The positive light of end equipment 100 enters terminal device 100.Second unthreaded hole 130 is set to the back side of shell of terminal device 100 (Z axis negative direction i.e.), so that the light at the back side from terminal device 100 enters terminal device 100.First optical path modulation portion Part 140 can change such as can be and can rotate the reflective mirror perhaps overturn from the first unthreaded hole 120 or the second unthreaded hole The optical path direction of 130 light.Control unit 150 connect with the first optical path modulation component 140, based on the received screening-mode Signal controls the first optical path modulation component 140.

The movement in the present embodiment will be illustrated next.

When user selects front camera mode etc., terminal device 100 issues front screening-mode to control unit 150 Signal, control unit 150 controls the first optical path modulation component 140 at this time, so that passing through the light of the first unthreaded hole 120 by the One optical path modulation component 140 is reflected into camera 110 (the optical path L1 in such as Fig. 1 (a)), thus photosensitive in camera 110 Component 112 can receive the light in the front (i.e. Z axis positive direction) from terminal device 100, realize 100 front side of terminal device To shooting.When user selects rear camera mode etc., terminal device 100 issues the back side to control unit 150 and shoots mould The signal of formula, control unit 150 controls the first optical path modulation component 140 at this time, so that the light for passing through the second unthreaded hole 130 passes through First optical path modulation component 140 is reflected into camera 110 (the optical path L2 in such as Fig. 1 (b)), thus the sense in camera 110 Light component 112 can receive the light at the back side (i.e. Z axis negative direction) from terminal device 100, realize 100 back side of terminal device The shooting in direction.

Next, illustrating first preferred structure of above-mentioned first optical path modulation component 140 in conjunction with Fig. 2 (a) and (b).

Fig. 2 be (a) and (b) be optical path modulation component of the invention the first structure schematic diagram.Referring to Fig. 2 it is found that the One optical path modulation component 140 includes: reflecting part 210 and the first rotation axis 220.Reflecting part 210 can be reflected from The light of one unthreaded hole 120 or the second unthreaded hole 130.First rotation axis 220 is parallel to the flat of the photosensitive-member 112 of camera 110 Face and the back side that reflecting part 210 is connected to perpendicular to Z axis (i.e. the first rotation axis 220 is parallel to X-direction), at first turn Moving axis 220 is able to drive reflecting part 210 and rotates around the first rotation axis 220 when rotating, come from the first unthreaded hole to change 120 or second unthreaded hole 130 light reflection angle.

The movement in the present embodiment will be illustrated next.

When user selects front camera mode etc., terminal device 100 issues front screening-mode to control unit 150 Signal, at this time control unit 150 control the first rotation axis 220, rotation the first rotation axis 220 arrive first angle α so that coming from The light of first unthreaded hole 120 is reflected into the optical path L1 in camera 110(such as Fig. 2 (a) via reflecting part 210).Thus it images Photosensitive-member 112 in first 110 can receive the light in the front (i.e. Z axis positive direction) from terminal device 100, realize terminal The shooting of 100 positive direction of equipment.When user selects rear camera mode, terminal device 100 is issued to control unit 150 The signal of back side screening-mode, control unit 150 controls the first rotation axis 220 at this time, rotates first the 220 to the second angle of rotation axis β is spent, so that the light from the second unthreaded hole 130 is reflected into the optical path in camera 110(such as Fig. 2 (b) via reflecting part 210 L2).Thus the photosensitive-member 112 in camera 110 can receive the back side (i.e. Z axis negative direction) from terminal device 100 Light realizes the shooting of 100 back side direction of terminal device.Wherein, first angle α is preferably the reflecting surface phase of reflecting part 210 Angle when plane for photosensitive-member 112 is in 45 ° counterclockwise；Second angle β is preferably the anti-of reflecting part 210 Penetrate face relative to photosensitive-member 112 the direction plane Xiang Shunzhen in 45 ° when angle.It is noted that the first rotation axis 220 can also To be set to the edge of reflecting part 210, as long as the angle of reflecting part 210 can be changed so that from the first unthreaded hole 120 with And second the light of unthreaded hole 130 be reflected into camera 110 respectively.

Next, illustrating second preferred structure of above-mentioned first optical path modulation component 140 in conjunction with Fig. 3 (a) and (b).

Fig. 3 be (a) and (b) be optical path modulation component of the invention second of structure schematic diagram.Referring to Fig. 3 (a) and (b) It is found that the first optical path modulation component 140 includes: reflecting part 310 and the second rotation axis 320.Reflecting part 310 and photographic department The plane of part 112 forms angle, reflects the light from the first unthreaded hole 120 or the second unthreaded hole 130.Wherein, reflecting part 310 Reflecting surface and photosensitive-member 112 plane formed angle be preferably 45° angle.Second rotation axis 320 and photosensitive-member 112 It is connected to plane vertical (i.e. the second rotation axis 320 is parallel to Y direction) back side of the reflecting surface of reflecting part 310, is passed through It is rotated to the direction of ω, to change the optical path direction being reflected into camera 100.Wherein, the rotation side of the second rotation axis 320 Counter clockwise direction into the two-dimensional coordinate system that ω can be Z axis and X-axis is formed is but it is also possible to be clockwise.

The movement in the present embodiment will be illustrated next.

When user selects front camera mode etc., terminal device 100 issues front screening-mode to control unit 150 Signal, control unit 150 controls the second rotation axis 320, the second rotation axis 320 of rotation to position as shown in Fig. 3 (a) at this time It sets, so that the light from the first unthreaded hole 120 is reflected into the optical path in camera 110(such as Fig. 3 (a) via reflecting part 310 L1).Thus the photosensitive-member 112 in camera 110 can receive the front (i.e. Z axis positive direction) from terminal device 100 Light realizes the shooting of 100 positive direction of terminal device.When user selects rear camera mode, terminal device 100 is to control Component 150 processed issues the signal of back side screening-mode, and control unit 150 controls the second rotation axis 320, the second rotation of rotation at this time Axis 320 arrives position as shown in Figure 3 (b), so that the light from the second unthreaded hole 130 is reflected into camera shooting via reflecting part 310 Optical path L2 in head 110(such as Fig. 3 (b)).Thus the photosensitive-member 112 in camera 110 can be received from terminal device 100 The back side (i.e. Z axis negative direction) light, realize 100 back side direction of terminal device shooting.

However, second of structure of above-mentioned optical path modulation component can also be applied in panorama photographing mode.Next, Illustrate that second of structure of above-mentioned optical path modulation component is applied to panorama photographing mode in conjunction with Fig. 4 (a) and (b), (c), (d) Preferred embodiment.

Fig. 4 (a) and (b), (c), (d) are to realize pan-shot using second of structure of optical path modulation component of the invention Schematic diagram.Referring to Fig. 4 (a) and (b), (c), (d) it is found that terminal device 100 further includes third unthreaded hole 410 and the 4th unthreaded hole 420.The right side (i.e. X-axis positive direction) that third unthreaded hole 410 is set to terminal device 100 makes the right side from terminal device 100 The light in direction enters terminal device 100.4th unthreaded hole 420 is set to the left side (i.e. X-axis negative direction) of terminal device 100, makes The light for getting the left direction of self terminal equipment 100 enters terminal device 100.Wherein, the optical axis of camera 110 is orthogonal to end The front, rear, left and right direction of end equipment 100, i.e. the optical axis direction Y-axis positive direction or negative direction of camera 110 extend.

Movement of the embodiment under panorama photographing mode will be illustrated next.

Control unit 150 successively rotates the second rotation axis when receiving the signal of panorama photographing mode of user's selection 320 arrive position as shown in Figure 4 (a), position as shown in Figure 4 (b), position as shown in Figure 4 (c), as shown in Fig. 4 (d) At least two positions in position, so that coming from the first unthreaded hole 120, third unthreaded hole 410, the second unthreaded hole 130, the 4th unthreaded hole The light of at least two unthreaded holes in 420 is successively reflected into camera 110 via reflecting part 310.

Specifically, by taking 360 ° of shootings as an example, signal of the control unit 150 when the panorama photographing mode for receiving user's selection When, the second rotation axis 320 of control turns to position as shown in Figure 4 (a), and the record of camera 110 is via reflecting part 310 at this time The light (its optical path is L1) of the positive direction from terminal device 100 of reflection generates direct picture.Then, second turn is controlled Moving axis 320 turns to position as shown in Figure 4 (b), and the record of camera 110 comes from eventually via what reflecting part 310 reflected at this time The light (its optical path is L3) of the right direction of end equipment 100 generates image right.Then, the second rotation axis 320 of control rotation To position as shown in Figure 4 (c), at this time camera 110 record via reflecting part 310 reflect from terminal device 100 The light (its optical path is L2) of back side direction generates back side image.Then, the second rotation axis 320 of control is turned to such as Fig. 4 (d) institute The position shown, the light (its optical path is L4) that camera 110 records the left direction from terminal device 100 at this time generate left side Image.Then split is carried out to aforementioned four image by the application software being installed in terminal device 100, to complete complete Scape shooting.

By above-mentioned structure, user can complete pan-shot without own rotation, have shooting speed fast, be not easy to tremble Dynamic advantage can obtain the panoramic picture of high quality.

Wherein, the position of third unthreaded hole 410 and the 4th unthreaded hole 420 is not limited to above-mentioned position, as long as the first unthreaded hole 120, Two unthreaded holes 130, third unthreaded hole 410, that the 4th unthreaded hole 420 is formed by plane is vertical with the second rotation axis 320.On in addition, Face illustrates the case where 360 ° of shootings of four direction, but is readily applicable to the bat in two of them direction or three directions It takes the photograph.

Preferably, positive direction, the right direction, back side direction, left side side of terminal device 100 can also be selected by user At least two directions in, by direction packet contained in the signal of panorama photographing mode.Control unit 150, which is worked as, to be received When the signal of the panorama photographing mode of user's selection, successively rotate corresponding to the second rotation axis 320 to the direction of direction information Position so that the light of the unthreaded hole in the direction from direction information is successively reflected into camera 110 via reflecting part 310 In.

It is further preferred that terminal device 100 can also be designed are as follows: in reflection component 310 along perpendicular to the second rotation Translucent material is used on shell around the plane of axis 320, so that the light from the arbitrary angle in plane degree can be into Enter the inside of terminal device 100, to replace the first above-mentioned unthreaded hole 120, the second unthreaded hole 130, third unthreaded hole 410, the 4th unthreaded hole 420.Such structure can be realized 360 ° and shoot at any angle.

Next, illustrating the third preferred structure of above-mentioned first optical path modulation component 140 in conjunction with Fig. 5 (a) and (b).

Fig. 5 be (a) and (b) be optical path modulation component of the invention the third structure schematic diagram.Referring to Fig. 5 (a) and (b) It is found that the first optical path modulation component 140 includes: reflecting part 510 and rotation wall 520.

The plane of reflecting part 510 and photosensitive-member 112 forms angle, and reflection comes from the first unthreaded hole 120 or the second light The light in hole 130.Wherein, the angle that the plane of the reflecting surface of reflecting part 310 and photosensitive-member 112 is formed is preferably 45° angle.

It rotates 520 one end of wall and connects camera 110, the other end connects reflecting part 510, and including cinclides 530.Cinclides 530 are used to rotate within wall 520 so that entering across the light of the first unthreaded hole 120 or the second unthreaded hole 130, then lead to light Reflecting part 510 is crossed to be reflected into camera 110.It is rotated by rotation wall 520 to the direction of ω, drives 510 turns of reflecting part It is dynamic, to change the optical path direction being reflected into camera 110.Wherein, the rotation direction ω for rotating wall 520 can be Z axis and X The counter clockwise direction in two-dimensional coordinate system that axis is formed is but it is also possible to be clockwise.

The movement in the present embodiment will be illustrated next.

When user selects front camera mode etc., terminal device 100 issues front screening-mode to control unit 150 Signal, the rotation wall 520 of the control of control unit 150 at this time, rotation rotation wall 520 makes to get to position as shown in Fig. 5 (a) The optical path being reflected by reflecting part 510 from the light of the first unthreaded hole 120 via cinclides 530 in camera 110(such as Fig. 5 (a) L1 in).Thus the photosensitive-member 112 in camera 110 can receive the front (i.e. Z axis positive direction) from terminal device 100 Light, realize 100 positive direction of terminal device shooting.When user select rear camera mode when, terminal device 100 to Control unit 150 issues the signal of back side screening-mode, the rotation wall 520 of the control of control unit 150 at this time, rotation rotation wall 520 To position as shown in Fig. 5 (b), so that the light from the second unthreaded hole 130 is reflected into via cinclides 530 by reflecting part 510 Optical path L2 in camera 110(such as Fig. 5 (b)) in.Thus the photosensitive-member 112 in camera 110, which can receive, carrys out self terminal The light at the back side (i.e. Z axis negative direction) of equipment 100 realizes the shooting of 100 back side direction of terminal device.

It, can not only save the cost according to above-mentioned terminal device and image capture method, it can also be ensured that multiple directions are taken the photograph Picture performance is identical, occupies little space, and has good operability and design flexibility.

But in above explained multiple embodiments, since the size of reflecting part 210,310,510 is limited, because This first unthreaded hole 120 is overlapped on the front-rear direction (i.e. Z-direction) of terminal device 100 with the second unthreaded hole 130 needs or phase Closely, the design to terminal device 100 is constrained.In order to solve the above problems, of the invention is additionally provided using two optical paths The embodiment of modulating part.

In the present embodiment, terminal device 100 further includes the second light other than the component that the first above-mentioned structure has Road modulating part.Wherein, direction of the first optical path modulation component 140 for changing the light from the first unthreaded hole 120, the second light Road modulating part for changing the light from the second unthreaded hole 130 direction.

In the present embodiment, 120 to the second unthreaded hole 130 of the first unthreaded hole is closer to camera 110, the second optical path modulation portion Part is set on the extended line of the optical axis of camera 110, and corresponding with the position of the second unthreaded hole 130.

The movement in the present embodiment will be illustrated next.

When user preposition camera mode etc., terminal device 100 issues the letter of front screening-mode to control unit 150 Number, control unit 150 controls the first optical path modulation component 140 and/or the second optical path modulation component at this time, covers from second Unthreaded hole 120 is to the light in camera 110 and the light across the first unthreaded hole 120 is made to pass through the first optical path modulation component 140 It is reflected into camera 110, thus the photosensitive-member 112 in camera 110 can be received from the positive of terminal device 100 Light realizes the shooting of 100 positive direction of terminal device.When user select rear camera mode scape when, terminal device 100 to Control unit 150 issue back side screening-mode signal, at this time control unit 150 control the first optical path modulation component 140 and/ Or the second optical path modulation component, masking is from the first unthreaded hole 120 to the light in camera 110 and makes across the second unthreaded hole 130 light is reflected into camera 110 by the second optical path modulation component, thus 112 energy of photosensitive-member in camera 110 The enough light for receiving the back side from terminal device 100, realizes the shooting of 100 back side direction of terminal device.

Next, preferred structure when illustrating in conjunction with Fig. 6 (a) and (b) using two optical path modulation components.

Fig. 6 (a) and (b) are the schematic diagrames of the preferred structure of two optical path modulation components of use of the invention.Referring to Fig. 6 (a) and (b) are it is found that the first optical path modulation component 140 includes: reflecting part 610 and third rotation axis 620.Wherein, light-reflecting portion Part 610 is set on the extended line of the optical axis of camera 110, and corresponding with the position of the first unthreaded hole 120, for covering via the Two optical path modulation components and to the light that camera 110 projects, and the light from the first unthreaded hole 120 is reflected into camera In 110.Third rotation axis 620 be parallel to the plane of the photosensitive-member 112 of camera 110 and perpendicular to terminal device 100 just Face direction and back side direction (i.e. third rotation axis is parallel to X-direction) and the edge for being connected to the reflecting surface of reflecting part 210, So that driving reflecting part 610 to be turned to position as shown in Figure 6 (a) or such as Fig. 6 (b) by the rotation of third rotation axis 620 Shown in position.It is noted that third rotation axis 620 also can be set in the back side of reflecting part 610, as long as enabling to anti- Light component 610 is turned to position as shown in Figure 6 (a) and position as shown in Figure 6 (b).

In the following, the movement of preferred structure when explanation is using two optical path modulation components.

When user preposition camera mode etc., terminal device 100 issues the letter of front screening-mode to control unit 150 Number, control unit 150 controls third rotation axis 620 at this time, so that reflecting part 610 is turned to position as shown in Figure 6 (a). At this point, the light come from the second unthreaded hole 130 via the reflection of the second optical path modulation component is by the back side of the reflecting surface of reflecting part 610 It covers (the chain-dotted line optical path L2 in such as Fig. 6 (a)), while reflecting part 610 passes through the light of the first unthreaded hole 120 and is reflected into and takes the photograph As in head 110 (the solid line optical path L1 in such as Fig. 6 (a)), thus the photosensitive-member 112 in camera 110 can be received from eventually The light in the front (i.e. Z axis positive direction) of end equipment 100 realizes the shooting of 100 positive direction of terminal device.After user's selection When setting camera mode, terminal device 100 issues the signal of back side screening-mode to control unit 150, at this time control unit 150 Third rotation axis 620 is controlled, so that reflecting part 610 is turned to position as shown in Figure 6 (b).At this point, coming from the first unthreaded hole 120 light is reflected to the direction other than camera 110 (the solid line optical path L1 in such as Fig. 6 (b)), while allowing across second Unthreaded hole 130 and via the second optical path modulation component reflection come light project in camera 110 (the chain-dotted line in such as Fig. 6 (b) Optical path L2), thus the photosensitive-member 112 in camera 110 can receive the back side (the i.e. Z axis losing side from terminal device 100 To) light, realize 100 back side direction of terminal device shooting.

According to above structure, in the first unthreaded hole 120 and the second unthreaded hole 130 larger at a distance from Z-direction, also can guarantee The camera shooting performance of multiple directions is identical, occupies little space, and has good operability and design flexibility.

In above-mentioned multiple embodiments, illustrate that the optical axis direction of camera 110 is the example of Y-axis positive direction.But as long as Its optical axis direction is orthogonal to Z-direction and above-mentioned function may be implemented.That is, the optical axis direction of camera can also be the Y in Fig. 1 The positive direction or negative direction etc. of axis negative direction and X-axis.At this point, those skilled in the art easily acknowledge that, by corresponding The identical function can be realized in the positional relationship that ground adjusts other all parts.

Multiple embodiments of terminal device of the invention are explained above.It, can be with when using terminal device of the invention Any combination one or more embodiment recited above.Obviously, those skilled in the art are not departing from spirit of the invention With in range can to above-described embodiment various modification can be adapted or deformation.Those of ordinary skill in the art are not making creation Property labour under the premise of every other embodiment obtained, shall fall within the protection scope of the present invention.

[image capture method]

In the following, first embodiment of the image capture method in conjunction with Fig. 7 during the present invention will be described in detail.

Image capture method of the invention is applied to terminal device, and this terminal device includes camera;First unthreaded hole；Second light Hole；Optical path modulation component and control unit.

Wherein, camera includes camera lens and photosensitive-member, and optical axis direction is orthogonal to the front and the back side of terminal device. Photosensitive-member can be the photosensitive elements such as CCD either CMOS.First unthreaded hole is set to the shell front of the terminal device, so that Positive light from terminal device enters terminal device.Second unthreaded hole is set to the back side of shell of the terminal device, so that The light at the back side from terminal device enters terminal device.First optical path modulation component for example can be and can rotate or turn over The reflective mirror etc. turned, can change the optical path direction of the light from the first unthreaded hole or the second unthreaded hole.

Fig. 7 is the flow chart of first embodiment of image pickup method of the invention.

Referring to Fig. 7 it is found that firstly, when user selects front camera mode or rear camera mode to shoot, terminal Equipment receives the signal (step S101) of front selected by user or back side screening-mode.

After terminal device receives the signal of the screening-mode of user's selection, judge whether the signal of the screening-mode is positive The signal (step S102) of face screening-mode.

When judging the signal for the signal of front screening-mode (step S102, "Yes"), the first optical path modulation portion is controlled Thus part is taken the photograph so that the light for passing through the first unthreaded hole is reflected into camera (step S103) by the first optical path modulation component As the photosensitive-member 112 in first 110 can receive the positive light from terminal device, terminal device positive direction is realized Shooting, subsequent tenth skill.

When judging the signal not to be the signal of front screening-mode (step S102, "No"), the bat is further judged Take the photograph mode signal whether be back side screening-mode signal (step S104).

When judging the signal for the signal of back side screening-mode (step S104, "Yes"), the first optical path modulation portion is controlled Thus part is taken the photograph so that the light for passing through the second unthreaded hole is reflected into camera (step S105) by the first optical path modulation component The light at the back side (i.e. Z axis negative direction) from terminal device can be received as the photosensitive-member in head, realize terminal device 100 The shooting of back side direction, subsequent tenth skill.

When judging the signal not to be the signal of back side screening-mode (step S104, "No"), illustrate the screening-mode Signal be not front screening-mode signal, nor the signal of back side screening-mode, therefore tenth skill.

It, can not only save the cost according to above-mentioned image capture method, it can also be ensured that the camera shooting performance of multiple directions is identical, accounts for It is small with space, there is good operability and design flexibility.

In the following, second embodiment of the image capture method in conjunction with Fig. 8 during the present invention will be described in detail.

Terminal device in the second embodiment further comprises: the second optical path modulation component.The second optical path tune Component processed for changing the light from the second unthreaded hole direction.At this point, the first optical path modulation component is for changing from first The direction of the light of unthreaded hole.

Fig. 8 is the flow chart of second embodiment of image pickup method of the invention.

Referring to Fig. 8 it is found that firstly, when user selects front camera mode or rear camera mode to shoot, terminal Equipment receives the signal (step S201) of front selected by user or back side screening-mode.

After terminal device receives the signal of the screening-mode of user's selection, judge whether the signal of the screening-mode is positive The signal (step S202) of face screening-mode.

When judging the signal for the signal of front screening-mode (step S202, "Yes"), the first optical path modulation portion is controlled Part and/or the second optical path modulation component cover the light from the second unthreaded hole into camera and make across the first unthreaded hole Light be reflected into camera (step S203) by the first optical path modulation component, thus the photosensitive-member in camera can The positive light from terminal device is received, realizes the shooting of terminal device positive direction, subsequent tenth skill.

When judging the signal not to be the signal of front screening-mode (step S202, "No"), the bat is further judged Take the photograph mode signal whether be back side screening-mode signal (step S204).

When judging the signal for the signal of back side screening-mode (step S204, "Yes"), the first optical path modulation portion is controlled Part and/or the second optical path modulation component cover the light from the first unthreaded hole into camera and make across the second unthreaded hole Light be reflected into camera (step S205) by the second optical path modulation component, thus the photosensitive-member in camera can The light at the back side from terminal device is received, realizes the shooting of terminal device back side direction, subsequent tenth skill.

When judging the signal not to be the signal of back side screening-mode (step S204, "No"), illustrate the screening-mode Signal be not front screening-mode signal, nor the signal of back side screening-mode, therefore tenth skill.

It, can be larger at a distance from front and back side direction with the second unthreaded hole in the first unthreaded hole according to above-mentioned image pickup method When, also guarantee that the camera shooting performance of multiple directions is identical, occupies little space, there is good operability and design flexibility.

Be described above first judge screening-mode signal whether be front screening-mode signal, then judge whether it is The example of the signal of back side screening-mode.But its sequencing is also possible to opposite, it can first judges the letter of screening-mode Number whether be back side screening-mode signal, then judge whether it is the signal of front screening-mode again.

In addition, being illustrated by taking front screening-mode and back side screening-mode as an example among the above.But the present invention is not It is limited to this, the above method can also be applied to other multidirectional shootings.

Multiple embodiments of image capture method of the invention are explained above.It, can be with when using image capture method of the invention Any combination one or more embodiment recited above.Obviously, those skilled in the art are not departing from spirit of the invention With in range can to above-described embodiment various modification can be adapted or deformation.Those of ordinary skill in the art are not making creation Property labour under the premise of every other embodiment obtained, shall fall within the protection scope of the present invention.

Claims (11)

1. a kind of terminal device, including:

Camera, including camera lens and photosensitive-member, optical axis direction are orthogonal to first direction and second direction；

First unthreaded hole is set to the first surface of the terminal device, be configured such that the light from the first direction into Enter the terminal device；

Second unthreaded hole is set to the second surface of the terminal device, be configured such that the light from the second direction into Enter the terminal device；

First optical path modulation component configures to change the direction of the light from first unthreaded hole or second unthreaded hole； And

Control unit configures to control the first optical path tune when receiving the signal of the first screening-mode of user's selection Component processed, so that the light from first unthreaded hole projects in the camera；When the second count for receiving user's selection When taking the photograph the signal of mode, control the first optical path modulation component so that the light from second unthreaded hole project it is described In camera；

Wherein,

The first optical path modulation component includes:

Reflecting part forms angle with the plane of the photosensitive-member, and configuration is reflected from first unthreaded hole or described The light of second unthreaded hole；And

Wall is rotated,

The rotation wall, one end connect the camera, and the other end connects the reflecting part, and including cinclides, configures to lead to It crosses its rotation and drives the reflecting part rotation.

2. terminal device according to claim 1, wherein the angle includes first angle and second angle,

The first angle be the reflecting part reflecting surface relative to the photosensitive-member plane to counterclockwise be in 45 ° when Angle,

The second angle be the reflecting part reflecting surface relative to the photosensitive-member plane to clockwise be in 45 ° when Angle.

3. terminal device according to claim 1, wherein the first optical path modulation component further includes the second rotation axis,

The control unit rotates second rotation axis to the when receiving the signal of the first screening-mode of user's selection One position, so that the light from first unthreaded hole is reflected into the camera via the reflecting part；When receiving When the signal of the second screening-mode of user's selection, second rotation axis is rotated to the second position, so that coming from described second The light of unthreaded hole is reflected into the camera via the reflecting part.

4. terminal device according to claim 3, wherein

The terminal device further include:

Third unthreaded hole is set to the third surface of the terminal device, is configured such that the light from third direction enters institute State terminal device；

4th unthreaded hole is set to the 4th surface of the terminal device, is configured such that the light from fourth direction enters institute Terminal device is stated,

The optical axis of the camera is orthogonal to the first direction, the second direction, the third direction and the described 4th Direction,

The control unit successively rotates second rotation axis when receiving the signal of third screening-mode of user's selection To the first position, the third place, the second position, at least two positions in the 4th position, so that from described the One unthreaded hole, the third unthreaded hole, second unthreaded hole, at least two unthreaded holes in the 4th unthreaded hole light successively via institute Reflecting part is stated to be reflected into the camera.

5. terminal device according to claim 4, wherein

It include the first direction, the second direction, the third in the signal of the third screening-mode of user's selection The directional information at least two directions in direction, the fourth direction, the control unit is when receiving the of user's selection When the signal of three screening-modes, position corresponding to second rotation axis to the direction of the directional information is successively rotated, is made The light for obtaining the unthreaded hole in the direction from the directional information is successively reflected into the camera via the reflecting part.

6. terminal device according to claim 1, wherein

The control unit rotates the rotation wall to first when receiving the signal of the first screening-mode of user's selection It sets, so that the light from first unthreaded hole is reflected into the camera via the cinclides by the reflecting part；When When receiving the signal of the second screening-mode of user's selection, the rotation wall is rotated to the second position, so that across described the The light of two unthreaded holes is reflected into the camera via the cinclides by the reflecting part.

7. according to terminal device described in any one in claim 3 to 6, wherein

The angle that the plane of the reflecting surface of the reflecting part and the photosensitive-member is formed is 45 °.

8. terminal device according to claim 1, wherein

Further include the second optical path modulation component, configure to change the direction of the light from second unthreaded hole,

The first optical path modulation component configures to change the direction of the light from first unthreaded hole,

The control unit controls first optical path modulation portion when receiving the signal of the first screening-mode of user's selection Part and/or the second optical path modulation component, masking is from second unthreaded hole to the light in the camera and makes Light from first unthreaded hole projects in the camera；When the signal for the second screening-mode for receiving user's selection When, control the first optical path modulation component and/or the second optical path modulation component, masking from first unthreaded hole to Light in the camera simultaneously projects the light from second unthreaded hole in the camera.

9. terminal device according to claim 8, wherein

First unthreaded hole than second unthreaded hole closer to the camera,

On the extended line for the optical axis that the second optical path modulation component is set to the camera, and the position with second unthreaded hole Correspondence is set, the light from second unthreaded hole is reflected into the direction of camera by configuration,

The first optical path modulation component includes:

Reflecting part is set on the extended line of the optical axis of the camera, and corresponding with the position of first unthreaded hole, configuration It covers via the second optical path modulation component to the light that the camera projects, and first unthreaded hole will be come from Light be reflected into the camera；

Third rotation axis is parallel to the plane of the photosensitive-member of the camera and perpendicular to the first direction and described Second direction and the edge or the back side for being connected to the reflecting surface of the reflecting part, are configured such that the reflecting part surrounds The third rotation axis and turn to first position or the second position,

The control unit controls the reflecting part and turns to when receiving the signal of the first screening-mode of user's selection The first position covers the light come from the second optical path modulation component reflection and makes the light from first unthreaded hole Line reflection is into the camera；When receiving the signal of the second screening-mode of user's selection, the reflecting part is controlled The second position is turned to, the light from first unthreaded hole is covered and to reflect from the second optical path modulation component The light come projects in the camera.

10. a kind of image capture method, it is applied to terminal device, the terminal device includes camera, including camera lens and photosensitive-member, Its optical axis direction is orthogonal to first direction and second direction；First unthreaded hole is set to the first surface of the terminal device, configuration Come so that the light from the first direction enters the terminal device；Second unthreaded hole is set to the of the terminal device Two surfaces are configured such that the light from the second direction enters the terminal device；First optical path modulation component, configuration Change the direction of the light from first unthreaded hole or second unthreaded hole, the first optical path adjustment component includes anti- The plane of light component and rotation wall, the reflecting part and the photosensitive-member forms angle, configures to reflect from described The light of first unthreaded hole or second unthreaded hole, described rotation wall one end connect the camera, and other end connection is described anti- Light component, and including cinclides, configuration to drive the reflecting part to rotate by its rotation, wherein

The image capture method includes:

Receive the signal of the screening-mode selected from user；

When receiving the signal of the first screening-mode of user's selection, the first optical path modulation component is controlled, so that coming from The light of first unthreaded hole projects in the camera；

When receiving the signal of the second screening-mode of user's selection, the first optical path modulation component is controlled, so that coming from The light of second unthreaded hole projects in the camera.

11. image capture method according to claim 10, the terminal device further include: the second optical path modulation component, configuration Change the direction of the light from second unthreaded hole, the first optical path modulation component configuration to be to change from described first The direction of the light of unthreaded hole, wherein

It is described to control the first optical path modulation component when receiving the signal of the first screening-mode of user's selection, so that It includes: to work as the first screening-mode for receiving user's selection in the camera that light from first unthreaded hole, which projects, When signal, the first optical path modulation component and/or the second optical path modulation component are controlled, is covered from second light Hole is to the light in the camera and the light from first unthreaded hole is projected in the camera；

It is described to control the first optical path modulation component when receiving the signal of the second screening-mode of user's selection, so that It includes: to work as the second screening-mode for receiving user's selection in the camera that light from second unthreaded hole, which projects, When signal, the first optical path modulation component and/or the second optical path modulation component are controlled, is covered from first light Hole is to the light in the camera and the light from second unthreaded hole is projected in the camera.