CN105717644A - Image adjusting method and device and applicable intelligent glasses - Google Patents

Abstract

The invention discloses an image adjusting method and device and applicable intelligent glasses. The image adjusting device comprises a lens adjusting unit provided with two groups of lenses, and a displacement acquiring unit connected with the lens adjusting unit, wherein the lens adjusting unit is used for adjusting a position relation between the central point of each lens and a pupil based on a received adjusting instruction; the displacement acquiring unit is used for acquiring position change information of the central point of each lens according to a displacement track obtained when the lens adjusting unit is used for adjusting each lens, and transmitting the acquired position change information to an image display unit; and the image display unit is used for adjusting the central position of an image of each lens based on the acquired position change information. With the adoption of the image adjusting method and device, the problem that the intelligent glasses cannot be adaptive to pupil distances of all users so that people easily have a dizzy feeling when people use the intelligent glasses is solved.

Description

Image adjusting method, device and the intelligent glasses being suitable for

Technical field

The present embodiments relate to electronic technology, particularly relate to a kind of image adjusting method, device and the intelligent glasses being suitable for.

Background technology

Virtual reality technology is a kind of can establishment and the computer simulation system in the experiencing virtual world.It utilizes computer to generate a kind of simulated environment, utilizes the interactive mode of Multi-source Information Fusion, provides the user Three-Dimensional Dynamic what comes into a driver's, and in conjunction with the entity behavior of user, allows user be immersed in corresponding environment.

Owing to people rely on visual experience most, therefore people wear intelligent glasses and can experience the virtual scene of three-dimensional.Wherein, described intelligent glasses can be shape of glasses or be embedded on the helmet.

Intelligent glasses comprises the lens of corresponding eyes, and is positioned at the screen of lens opposite side.People see, through lens, the picture that screen presents, so that oneself being immersed in the picture that screen provides.At present, lens in intelligent glasses are integrally fixed on picture frame, people are in use, owing to everyone interpupillary distance is different, therefore, in use, owing to the central point of the center of image, lens does not all mate with pupil, cause people when long-time use intelligent glasses, it may appear that the situation of dizziness.Accordingly, it would be desirable to prior art is improved.

Summary of the invention

The present invention provides a kind of image adjusting method, device and the intelligent glasses being suitable for, to realize the purpose that the lens centre point of intelligent glasses is adjusted.

First aspect, embodiments provide a kind of image adjusting device, for comprising the intelligent glasses of the lens of screen and each eyes of correspondence, including: the lens regulon of lens described in two groups is installed, for adjusting the position relationship of each lens centre point and pupil based on the instruction that adjusts received；The displacement acquiring unit being connected with described lens regulon, for adjusting deformation trace during each lens according to described lens regulon, obtain the change in location information of each lens centre point adjusted, and acquired change in location information is passed to image-display units；Described image-display units for adjusting the center of the image of corresponding each lens based on acquired each position change information.

Second aspect, the embodiment of the present invention additionally provides a kind of intelligent glasses, including: image adjusting device as above.

The third aspect, the embodiment of the present invention additionally provides a kind of image adjusting method, for image adjusting device as above, including: obtain the lens regulon deformation trace when adjusting each lens in described image adjusting device；Adjust deformation trace during each lens according to described lens regulon, obtain the change in location information of each lens centre point adjusted；The center of the image of corresponding each lens on described screen is adjusted based on each described change in location information.

Present invention pupil position regulates lens centre point and image center location, solve intelligent glasses cannot the interpupillary distance of adaptive all users, cause people when using intelligent glasses, it is easy to the problem producing spinning sensation.

Accompanying drawing explanation

Fig. 1 is the structural representation of the image adjusting device in the embodiment of the present invention one；

Fig. 2 is the structural representation of a kind of image adjusting device in the embodiment of the present invention two；

Fig. 3 is the structural representation of another image adjusting device in the embodiment of the present invention two；

Fig. 4 is the structural representation of the image adjusting device in the embodiment of the present invention three；.

Fig. 5 is the flow chart of the image adjusting method in the embodiment of the present invention five.

Detailed description of the invention

Below in conjunction with drawings and Examples, the present invention is described in further detail.It is understood that specific embodiment described herein is used only for explaining the present invention, but not limitation of the invention.It also should be noted that, for the ease of describing, accompanying drawing illustrate only part related to the present invention but not entire infrastructure.

Embodiment one

The structural representation of the image adjusting device that Fig. 1 provides for the embodiment of the present invention one, the present embodiment is applicable in intelligent glasses and adjusts lens and Image display position, making lens centre point be positioned at the situation in pupil front, wherein, described intelligent glasses comprises screen and the lens of each eyes of correspondence.User can utilize described intelligent glasses viewing 3-D view, so, corresponding display two width images on described screen, to present 3-D effect.User is before using described intelligent glasses to experience three-dimensional virtual environment, first use the described adjusting apparatus position relationship to adjust between lens and pupil, lens centre point is made to be positioned at pupil front, simultaneously, also corresponding adjustment image center location and lens centre point, in order to pupil, lens centre point and image center location are on the same line.

Described image adjusting device 1 includes: lens regulon 11, displacement acquiring unit 12, image-display units 13.

Described lens regulon 11 is provided with lens described in two groups, for adjusting the position relationship of each lens centre point and pupil based on the instruction that adjusts received.Wherein, described adjustment instruction can be signal instruction, it is also possible to be mechanical order.

Specifically, described lens regulon 11 can provide the user the corresponding adjustment button often organizing lens, and user regulates, by pressing, the position adjusting lens that button is independent, until the scene that sensation is seen is without bending, spinning sensation.Described lens regulon 11 can the lateral attitude individually adjusting each lens merely transversely, it is also possible to and vertical direction is overall/individually adjust the lengthwise position of each lens.When adjusting each lens position, described lens regulon 11 also provides deformation trace to displacement acquiring unit 12.

Described displacement acquiring unit 12, for adjusting deformation trace during each lens according to described lens regulon 11, obtains the change in location information of each lens centre point adjusted, and acquired change in location information is passed to image-display units 13.

Specifically, described displacement acquiring unit 12 presets two-dimensional coordinate system, and the range that regulates according to described lens regulon 11 presets coordinate range and the zero of this two-dimensional coordinate system.When described lens regulon 11 provides deformation trace to described displacement acquiring unit 12, described displacement acquiring unit 12 correspondence in described two-dimensional coordinate system, obtain on described track each tracing point relative to the change in location information of zero.Wherein, what described displacement acquiring unit 12 can be real-time is supplied to, by obtained change in location information, the image-display units 13 connected.Or described displacement acquiring unit 12 adds up the duration that each tracing point is lasting, if the duration lasting at same tracing point exceedes preset time threshold, then preserve this change in location information, and when receiving enabled instruction, this change in location information is supplied to described image-display units 13.

At this, described displacement acquiring unit 12 correspondence can often be organized lens and arrange two-dimensional coordinate system, it is also possible to is plotted in same two-dimensional coordinate system by the deformation trace of two groups of lens.When being plotted in same two-dimensional coordinate system, corresponding left eye and right eye can presetting each initial coordinate point respectively in described displacement acquiring unit 12, the coordinate difference of corresponding each deformation trace organizing lens and corresponding initial coordinate point, as the change in location information of correspondence tracing point.

Described image-display units 13 for adjusting the center of the image of corresponding each lens based on acquired each position change information.

At this, described screen can be integrally fixed at the part on intelligent glasses, and the left images correspondence of screen is shown in left one side of something of screen and right one side of something by described image-display units 13.When described image-display units 13 gets the change in location information of corresponding each group lens, the corresponding relation according to the zero of default two-dimensional coordinate system Yu image center location, adjust image center location according to acquired each position change information.

Such as, described image-display units 13 determines that the change in location information of acquired left eye lens central point is (x1, y1), the Pixel Dimensions of image to display is (500,600), the initial position co-ordinates of corresponding left eye lens is (0,0).Then, described image-display units 13 is according to the proportionate relationship of default left half of screen pixels length and width with two-dimensional coordinate system length and width range, coordinates computed (x1, y1) image center location (250 is corresponded to respectively at long and cross direction, 300) side-play amount, adjusts the left half of center showing described image of screen according still further to the side-play amount in computed length and width direction.

The technical scheme of the present embodiment, regulates lens centre point and image center location according to pupil position, solve intelligent glasses cannot the interpupillary distance of adaptive all users, cause people when using intelligent glasses, it is easy to the problem producing spinning sensation.

Embodiment two

A kind of structural representation of the image adjusting device that Fig. 2 provides for the embodiment of the present invention two.The present embodiment is on the basis of the various embodiments described above, and described lens regulon includes: the catch 22 of corresponding each described lens, fixing parts 21 and adjustment parts.

Described catch 22 is provided with through hole.Described through hole sets based on pinhole imaging system principle, and namely described catch 22 other parts except described through hole are all in the light.The shape of described catch 22 can be identical with the shape of lens.When described catch 22 is completely overlapped with lens, through hole is positioned at lens centre Dian Chu.The quantity of described catch 22 is 2, the corresponding one group of lens of each catch 22.

Described fixing parts 21 are for individually fixing described lens and/or catch 22；Wherein, after described lens and catch 22 are fixed on described fixing parts 21, the lead to the hole site of described catch 22 is overlapping with the central point of described lens.

At this, described fixing parts 21 can fix described lens and corresponding catch 22 simultaneously.Such as, described fixing parts 21 comprise the lens bracket of fixing lens, and described lens bracket edge has the draw-in groove for fixing catch 22, and catch 22 can be fixed in draw-in groove by user.Or, described catch 22 and lens can be circular, and catch 22 and rims of the lens are provided with threaded disassembly and assembly structure, in order to be screwed on lens bracket.

Described lens bracket can be the groove surrounding each edge of lens.Or described lens bracket comprises horizontal and vertical separately positioned groove, each groove is by the fixing lens of disassembly and assembly structure and/or catch 22.Described fixing parts 21 can also include disassembly and assembly structure (being unillustrated), is used for dismounting lens and catch 22.Described disassembly and assembly structure includes but not limited to: be positioned at the screw on lens bracket or holding firmware.Such as, catch 22 is fixed on groove by screw, and user utilizes this screw dismounting lens and catch 22.When needs adjust some position, lens centre, catch 22 is arranged on described lens bracket, after the adjustment lens is replaced catch 22, and then uses intelligent glasses.

Described adjustment parts include: comprise transverse displacement arrangement 232 and the transverse adjustment 231 of laterally movable end.Wherein, described laterally movable end is fixed on described fixing parts 21.Described transverse displacement arrangement 232 includes: the telescopic sleeving rod of helical structure.The movable end (i.e. laterally movable end) of described telescopic sleeving rod is fixed on described fixing parts 21.Such as, the movable end of described telescopic sleeving rod is fixed on lens bracket.

Or, described transverse displacement arrangement 232 includes: laterally driven portion and lateral connection portion, and the one end in described lateral connection portion is fixed on laterally driven portion, the other end is laterally movable end.Wherein, described laterally driven portion is exemplified as gear (group), or with the guide rail of tooth row/damping and on guide rail the limited block of movement.Wherein, the facewidth in tooth row, the facewidth in gear (group) are step units.Described lateral connection portion is fixed on gear (group) or limited block.

Described transverse adjustment 231 regulates for user, and it is connected with described transverse displacement arrangement 232.Under the operation of user, described transverse displacement arrangement 232 is driven to adjust the through hole of described catch 22 and the lateral attitude relation of pupil, in order to before the central point of described lens is positioned at pupil.

Wherein, described transverse adjustment 231 is exemplified as the plectrum/knob being arranged on intelligent glasses shell, and described plectrum/knob is fixed on transverse displacement arrangement 232.Or, described transverse adjustment 231 is exemplified as push button panel, described push button panel is connected with laterally driven portion, when user presses the corresponding button, described push button panel sends the driving instruction of correspondence, then laterally driven portion moves according to the duration that step units and driving instruction are lasting, so regulates the position relationship between through hole and pupil on catch 22.

Described intelligent glasses can only adjust the lateral attitude relation of each lens, when user needs longitudinally adjusted lens centre point, can adopt the mode adjusting glasses height.

In a kind of alternative, described adjustment parts also include vertically moving structure 233 and longitudinal adjuster 234.As shown in Figure 3.

Wherein, structure 233 is vertically moved described in similar to transverse displacement arrangement 232 and transverse adjustment 231 respectively with the structure of longitudinal adjuster 234.It is different in that, described in vertically move structure 233 and longitudinal adjuster 234 vertically moves fixing parts 21, wherein, described in vertically move structure 233 and can regulate two baffle plates simultaneously, to adjust the position between two through hole and pupil simultaneously.

Corresponding, described lens bracket comprises horizontal and vertical separately positioned groove, and each groove fixes lens and/or catch 22.The described structure 233 that vertically moves connects horizontal groove, and described transverse displacement arrangement 232 connects longitudinal groove.Thus, when adjustment vertically moves structure 233, catch 22 longitudinally groove moves；When adjusting transverse displacement arrangement 232, catch 22 transversely groove moves.

The structure example of the lens regulon 11 with the intelligent glasses of two groups of lens is as follows:

The often all corresponding following structure of group lens: with the catch 22 of through hole, fixing parts 21 and adjustment parts.Wherein, the shape of catch 22 is identical with lens shape.

Described fixing parts 21 include the lens bracket of fixing lens and catch 22, and described lens bracket is provided with holding firmware.

Described adjustment parts include: transverse displacement arrangement 232, the transverse adjustment 231 being connected with described transverse displacement arrangement 232, vertically move structure 233, vertically move, with described, the longitudinal adjuster 234 that structure 233 is connected.Wherein, described transverse displacement arrangement 232 and the movable end vertically moving structure 233 are fixed on described lens bracket.

Described transverse displacement arrangement 232 all includes with vertically moving structure 233: drive division and the connecting portion being connected with drive division.Wherein, one end of connecting portion is fixed on described lens bracket.Described drive division can be the gear train with step-by-step toothed or limit guide rail.

The work process of described lens regulon 11 is exemplified below:

User, before using intelligent glasses, operates the holding firmware in each fixing parts 21 and unloads lens, and replace upper corresponding catch 22, and wear described intelligent glasses.Then, user by adjust each adjustment parts up and down adjust the position of through hole on each catch 22, until utilizing through hole it can be seen that external sights.Again each catch 22 is unloaded, gain the lens of correspondence.

The technical scheme of the present embodiment, utilize pinhole imaging system principle, the catch 22 with through hole is utilized to measure two pupil positions of human eye, the mode that recycling through hole is overlapping with lens centre point, guarantee that lens centre point is positioned at through hole front, thus solve lens centre point inconsistent with pupil position, spinning sensation during produced long-time use intelligent glasses.

It addition, adopt horizontal and vertical moving structure 233 to adjust the position of through hole, it is possible to wear the custom of intelligent glasses for different user, provide the user the mode that adjusts easily.

Embodiment three

Fig. 4 show the structural representation of the image adjusting device that the embodiment of the present invention three provides.On the basis of foregoing embodiments, described displacement acquiring unit includes: adapter, pressure sensitive array 25.

Described adapter moves with described lens regulon.Such as, the quantity of described adapter is two, and each adapter is individually connected on each adjustment parts, or is individually connected with the lens bracket in each fixing parts 21.Specifically, described adapter can comprise conducting connecting bar and the circuit powered for described conducting connecting bar, and wherein, one end of described conducting connecting bar is provided with contact pilotage 26.Described contact pilotage 26 is also conductive material.

Described pressure sensitive array 25 is for sensing the change of the pressure position of described contact pilotage 26, and obtains corresponding contact pilotage 26 motion track.The quantity of described pressure sensitive array 25 can be one, and two contact pilotages 26 press against on described pressure sensitive array 25.The quantity of described pressure sensitive array 25 can be two, and each contact pilotage 26 is individually pressed in a pressure sensitive array 25.The motion track sensed is transferred to corresponding change in location information laterally and/or longitudinally by described pressure sensitive array 25, and exports to image-display units 13.Wherein, described pressure sensitive array 25 is exemplified as the pressure inductor in pressure touch screen.

It should be noted that image-display units in the present embodiment not necessarily annexation as shown in Figure 4, it is also possible to it is directly connected to all pressure sensitive arrays.

The present embodiment utilizes pressure sensing array to provide change in location information, it is possible to provide the change in location of lens centre point easily.

Embodiment four

With foregoing embodiments the difference is that, the screen that described image adjusting device 1 adjusts is provided by intelligent terminal.Then described image-display units 13 may be located in described intelligent terminal.Corresponding, described intelligent glasses also includes: interface communication unit 14.Shown in Fig. 4.

Described interface communication unit 14 connects the image-display units 13 in described displacement acquiring unit 12 and described intelligent terminal.When described displacement acquiring unit 12 obtains the change in location information of corresponding each lens centre point, each described change in location information is sent to described image-display units 13 by described interface communication unit 14.

At this, described interface communication unit 14 includes but not limited to: USB interface or bluetooth communication etc..

Under a kind of default mode, acquired each position change information is only supplied to described image-display units 13 by described interface communication unit 14, the described image-display units 13 viewing area according to the left and right view of acquiescence, the mode provided according to the various embodiments described above adjusts image center location.

Under increasingly complex scene, as various sizes of intelligent terminal, when being installed on intelligent glasses, the viewing area of corresponding display left and right view is not completely the same.Now, the placement location of screen, while sending described change in location information or when detecting that intelligent terminal is connected on intelligent glasses, is supplied to the image-display units 13 in intelligent terminal by described interface communication unit 14.Wherein, described placement location includes but not limited to: the middle part of screen is positioned at each lens coverage or the lower-left/upper left/bottom right/upper right corner based on screen and shows two images.Such as, when interface communication unit 14 detects the electrical connection with intelligent terminal, the change in location information of default screen placement location and acquired each lens is sent to the image-display units 13 in described intelligent terminal.

Described image-display units 13 is used for the placement location based on described screen and each described change in location information, it is determined that shown each image center location, and shows respective image based on each described center.

Specifically, described image-display units 13, according to the corresponding relation of initial position co-ordinates point in the change in location information of the acquired each lens of correspondence and the image center location preset and default two-dimensional coordinate system, redefines the image center location after adjustment；Further according to acquired placement location, it is determined that image center location is in the display position of screen, and then shows two width images in corresponding viewing area.Achieve the center of image and lens and the purpose of pupil conllinear.

Embodiment five

The flow chart of the image adjusting method that Fig. 5 provides for the embodiment of the present invention five.The present embodiment can based on the various embodiments described above, and described method includes: step S110, S120 and S130.

Step S110, obtain the deformation trace when adjusting each lens of lens regulon in described image adjusting device.

Wherein, described deformation trace includes the transverse path of often organizing lens, it is preferable that also include longitudinal track.Wherein, longitudinal track of two groups of lens can be identical, it is possible to different.

At this, described lens regulon may utilize default step units to measure horizontal and vertical mobile time the direction of track and number of steps.Then, described deformation trace is made up of moving direction and corresponding number of steps.

Preferably, the displacement acquiring unit in described image adjusting device adopts pressure sensitive array that the contact pilotage moved with lens regulon and contact pilotage press to obtain the motion track produced when lens regulon adjusts lens.

Step S120, deformation trace when adjusting each lens according to described lens regulon, obtain the change in location information of each lens centre point adjusted.

Specifically, preset two-dimensional coordinate system, preset coordinate range and the zero of this two-dimensional coordinate system according to the range that regulates of described lens regulon.When described lens regulon provides deformation trace to described displacement acquiring unit, what described displacement acquiring unit was corresponding obtain in described two-dimensional coordinate system on described track each tracing point is relative to the change in location information of zero.Wherein, what described displacement acquiring unit can be real-time is supplied to, by obtained change in location information, the image-display units connected.Or described displacement acquiring unit adds up the duration that each tracing point is lasting, if exceeding preset time threshold at the duration that same tracing point is lasting, then preserves this change in location information, and when receiving enabled instruction, based on this change in location information and executing step S130.

At this, the present embodiment correspondence can often be organized lens and be separately provided two-dimensional coordinate system, it is also possible to is plotted in same two-dimensional coordinate system by the deformation trace of two groups of lens.When being plotted in same two-dimensional coordinate system, this enforcement corresponding left eye and right eye can preset each initial coordinate point respectively, and the coordinate difference of corresponding each deformation trace organizing lens and corresponding initial coordinate point, as the change in location information of correspondence tracing point.

Step S130, adjust the center of the image of corresponding each lens on described screen based on each described change in location information.

At this, described screen can be integrally fixed at the part on intelligent glasses, and the left images correspondence of screen is shown in left one side of something of screen and right one side of something by the present embodiment.When getting the change in location information of corresponding each group lens, the corresponding relation according to the zero of default two-dimensional coordinate system Yu image center location, adjust image center location according to acquired each position change information.

Such as, step S120 determine that the change in location information of acquired left eye lens central point is for (x1, y1), simultaneously, it is determined that the Pixel Dimensions of left-eye image to display is (500,600), the initial position co-ordinates of corresponding left eye lens is (0,0).Then, proportionate relationship according to default left half of screen pixels length and width with two-dimensional coordinate system length and width range, coordinates computed (x1, y1) image center location (250 is corresponded to respectively at long and cross direction, 300) side-play amount, adjusts the left half of center showing described image of screen according still further to the side-play amount in computed length and width direction.

Embodiment six

With foregoing embodiments the difference is that, the screen that described image adjusting device adjusts is provided by intelligent terminal.Then described image-display units may be located in described intelligent terminal.Corresponding, described method, before performing step S130, also includes step S140 (being unillustrated).

The change in location information of each lens centre point is passed to intelligent terminal by interface communication unit in described image adjusting device by step S140, described image adjusting device.

At this, described interface communication unit includes but not limited to: USB interface or bluetooth communication etc..

Under a kind of default mode, acquired each position change information is only supplied to described image-display units by described interface communication unit, the described image-display units viewing area according to the left and right view of acquiescence, performs step S130.

Under increasingly complex scene, as various sizes of intelligent terminal, when being installed on intelligent glasses, the viewing area of corresponding display left and right view is not completely the same.Now, the placement location of screen, while sending described change in location information or when detecting that intelligent terminal is connected on intelligent glasses, is supplied to the image-display units in intelligent terminal by described interface communication unit.Wherein, described placement location includes but not limited to: the middle part of screen is positioned at each lens coverage or the lower-left/upper left/bottom right/upper right corner based on screen and shows two images.Such as, when interface communication unit detects the electrical connection with intelligent terminal, the change in location information of default screen placement location and acquired each lens is sent to the image-display units in described intelligent terminal.

Described step S130 farther includes: based on placement location and each described change in location information of described screen, it is determined that shown each image center location, and shows respective image based on each described center.

Specifically, described image-display units, according to the corresponding relation of initial position co-ordinates point in the change in location information of the acquired each lens of correspondence and the image center location preset and default two-dimensional coordinate system, redefines the image center location after adjustment；Further according to acquired placement location, it is determined that image center location is in the display position of screen, and then shows two width images in corresponding viewing area.Achieve the center of image and lens and the purpose of pupil conllinear.

It should be noted that the product in the various embodiments described above can perform the method that any embodiment of the present invention provides, described method possesses the beneficial effect identical with the functional module in corresponding product.

Note, above are only presently preferred embodiments of the present invention and institute's application technology principle.It will be appreciated by those skilled in the art that and the invention is not restricted to specific embodiment described here, various obvious change can be carried out for a person skilled in the art, readjust and substitute without departing from protection scope of the present invention.Therefore, although the present invention being described in further detail by above example, but the present invention is not limited only to above example, when without departing from present inventive concept, other Equivalent embodiments more can also be included, and the scope of the present invention is determined by appended right.

Claims (10)

1. an image adjusting device, for comprising the intelligent glasses of the lens of screen and each eyes of correspondence, it is characterised in that including:

The lens regulon of lens described in two groups is installed, for adjusting the position relationship of each lens centre point and pupil based on the instruction that adjusts received；

The displacement acquiring unit being connected with described lens regulon, for adjusting deformation trace during each lens according to described lens regulon, obtain the change in location information of each lens centre point adjusted, and acquired change in location information is passed to image-display units；

Described image-display units for adjusting the center of the image of corresponding each lens based on acquired each position change information.

2. image adjusting device according to claim 1, it is characterised in that described lens regulon includes:

The catch of corresponding each described lens, is provided with through hole on each described catch；

Fixing parts, for individually fixing described lens and/or catch；Wherein, after described lens and/or catch are fixed on described fixing parts, the lead to the hole site of described catch is overlapping with the central point of described lens；

Regulate parts, including: comprise transverse displacement arrangement and the transverse adjustment of laterally movable end, wherein, described laterally movable end is individually fixed on described fixing parts, described transverse adjustment drives described transverse displacement arrangement to adjust the through hole of catch and the lateral attitude relation of pupil, in order to before the central point of described lens is positioned at corresponding pupil.

3. image adjusting device according to claim 2, it is characterised in that described adjustment parts also include:

What comprise longitudinally-moving end vertically moves structure and longitudinal adjuster, wherein, described longitudinally-moving end is fixed at least one described fixing parts, vertically moves the through hole of each described catch of structural adjustment and the lengthwise position relation of pupil described in the drive of described longitudinal adjuster.

4. image adjusting device according to claim 1, it is characterised in that described displacement acquiring unit includes:

With the adapter that described lens regulon moves, including contact pilotage；

By the pressure sensitive array that described contact pilotage presses, export corresponding change in location information for the deformation trace according to described contact pilotage.

5. image adjusting device according to claim 1, it is characterised in that described image-display units is arranged in intelligent terminal, before the screen of described intelligent terminal is arranged on lens；

Corresponding, described image adjusting device also includes: connect the interface communication unit of described displacement acquiring unit and image-display units, and each described change in location information is sent to described image-display units by described interface communication unit by described displacement acquiring unit.

6. image adjusting device according to claim 5, it is characterised in that described interface communication unit be additionally operable to detect be connected with described intelligent terminal time, in described intelligent terminal image-display units provide screen placement location；

Described image-display units is used for the placement location based on described screen and each described change in location information, it is determined that shown each image center location, and shows respective image based on each described center.

7. an intelligent glasses, it is characterised in that including:

In claim 1-6 arbitrary as described in image adjusting device.

8. an image adjusting method, in claim 1-6 arbitrary as described in image adjusting device, it is characterised in that including:

Obtain the lens regulon deformation trace when adjusting each lens in described image adjusting device；

Adjust deformation trace during each lens according to described lens regulon, obtain the change in location information of each lens centre point adjusted；

The center of the image of corresponding each lens on described screen is adjusted based on each described change in location information.

9. image adjusting method according to claim 8, it is characterised in that before based on the center of the image of corresponding each lens on each described change in location information described screen of adjustment, also include:

The change in location information of each lens centre point is passed to intelligent terminal by interface communication unit in described image adjusting device by described image adjusting device；

Described intelligent terminal adjusts the center of the image of corresponding each lens on described screen based on each described change in location information.

10. image adjusting method according to claim 9, it is characterized in that, state image adjusting device by the change in location information of each lens centre point by, while interface communication unit passes to intelligent terminal in described image adjusting device, also including: the placement location of screen is passed to described intelligent terminal；

Corresponding, described intelligent terminal is based on the placement location of described screen and each described change in location information, it is determined that shown each image center location, and shows respective image based on each described center.