CN110412766A - Control method, helmet and storage medium - Google Patents
Control method, helmet and storage medium Download PDFInfo
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- CN110412766A CN110412766A CN201910653636.9A CN201910653636A CN110412766A CN 110412766 A CN110412766 A CN 110412766A CN 201910653636 A CN201910653636 A CN 201910653636A CN 110412766 A CN110412766 A CN 110412766A
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- eyeglass
- helmet
- operation input
- adjustment mechanism
- mobile
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- 238000003860 storage Methods 0.000 title claims abstract description 16
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- 230000033001 locomotion Effects 0.000 claims abstract description 40
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- XECAHXYUAAWDEL-UHFFFAOYSA-N acrylonitrile butadiene styrene Chemical compound C=CC=C.C=CC#N.C=CC1=CC=CC=C1 XECAHXYUAAWDEL-UHFFFAOYSA-N 0.000 description 2
- 229920000122 acrylonitrile butadiene styrene Polymers 0.000 description 2
- 239000004676 acrylonitrile butadiene styrene Substances 0.000 description 2
- 230000003190 augmentative effect Effects 0.000 description 2
- 238000005516 engineering process Methods 0.000 description 2
- 229920000515 polycarbonate Polymers 0.000 description 2
- 230000003068 static effect Effects 0.000 description 2
- 230000000007 visual effect Effects 0.000 description 2
- 229910000838 Al alloy Inorganic materials 0.000 description 1
- 230000008901 benefit Effects 0.000 description 1
- WGWACCCAJWZIML-UHFFFAOYSA-N benzene;buta-1,3-diene;prop-2-enenitrile Chemical compound C=CC=C.C=CC#N.C1=CC=CC=C1 WGWACCCAJWZIML-UHFFFAOYSA-N 0.000 description 1
- 238000006243 chemical reaction Methods 0.000 description 1
- 238000004891 communication Methods 0.000 description 1
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Classifications
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B27/00—Optical systems or apparatus not provided for by any of the groups G02B1/00 - G02B26/00, G02B30/00
- G02B27/01—Head-up displays
- G02B27/017—Head mounted
- G02B27/0172—Head mounted characterised by optical features
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B27/00—Optical systems or apparatus not provided for by any of the groups G02B1/00 - G02B26/00, G02B30/00
- G02B27/01—Head-up displays
- G02B27/017—Head mounted
- G02B27/0176—Head mounted characterised by mechanical features
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B27/00—Optical systems or apparatus not provided for by any of the groups G02B1/00 - G02B26/00, G02B30/00
- G02B27/01—Head-up displays
- G02B27/017—Head mounted
- G02B2027/0178—Eyeglass type
Abstract
This application discloses a kind of control method, helmet and storage mediums.Control method is used for helmet, and helmet includes the first eyeglass, with the first eyeglass and to the second eyeglass of arrangement and the adjustment mechanism connecting with the first eyeglass and the second eyeglass, and control method includes: to receive the first operation input;Adjustment mechanism driving at least one of the first eyeglass and the second eyeglass movement is controlled according to the first operation input, to adjust the optical center distance between the first eyeglass and the second eyeglass;Receive the second operation input;Adjustment mechanism is controlled according to the second operation input and stops the first eyeglass of driving and the second eyeglass, so that the interpupillary distance of the wearer of optical center distance adaptation helmet.So, drive the first eyeglass and/or the second eyeglass so that the interpupillary distance of optical center distance and wearer between the first eyeglass and the second eyeglass matches according to the input control adjustment mechanism of user, to avoid user from generating spinning sensation because interpupillary distance mismatches, be conducive to the viewing experience for improving user.
Description
Technical field
This application involves electronic technology field, in particular to a kind of control method, helmet and storage medium.
Background technique
The helmet of the relevant technologies generally passes through the eyes that two lens are adapted to user respectively, comes so that user watches
The content that helmet plays.However, the interpupillary distance of two lens is generally fixed and invariable.In this way, different users wears head
When wearing equipment, the interpupillary distance of helmet cannot be adapted to the interpupillary distance of user, and user is caused to generate spinning sensation when watching video, be influenced
The viewing experience of user.
Summary of the invention
This application provides a kind of control method, helmet and storage mediums.
The application embodiment provides a kind of control method, is used for helmet, and the helmet includes first
Eyeglass, with first eyeglass and to the second eyeglass of arrangement and the tune being connect with first eyeglass and second eyeglass
Complete machine structure, the control method include:
Receive the first operation input;
The adjustment mechanism is controlled according to first operation input to drive in first eyeglass and second eyeglass
At least one movement, to adjust the optical center distance between first eyeglass and second eyeglass;
The second operation input is received during at least one of first eyeglass and second eyeglass are mobile;
The adjustment mechanism is controlled according to second operation input to stop driving first eyeglass and second mirror
Piece, so that optical center distance is adapted to the interpupillary distance of the wearer of the helmet.
The application embodiment provides a kind of helmet.The helmet includes the first eyeglass;With described first
Eyeglass and the second eyeglass to arrangement;The adjustment mechanism being connect with first eyeglass and second eyeglass;And processor, institute
State processor for receive the first operation input, and for controlling adjustment mechanism driving institute according to first operation input
It is mobile to state at least one of the first eyeglass and second eyeglass, to adjust between first eyeglass and second eyeglass
Optical center distance, and for receiving second during at least one of first eyeglass and second eyeglass are mobile
Operation input, and stop driving first eyeglass and institute for controlling the adjustment mechanism according to second operation input
The second eyeglass is stated, so that optical center distance is adapted to the interpupillary distance of the wearer of the helmet.
The helmet of the application embodiment includes:
First eyeglass;
With first eyeglass and to the second eyeglass of arrangement;
The adjustment mechanism connecting with first eyeglass and second eyeglass, the adjustment mechanism is for driving described the
One eyeglass and second eyeglass movement close to each other simultaneously move away from each other simultaneously, to adjust first eyeglass and institute
The optical center distance between the second eyeglass is stated, so that optical center distance is adapted to the interpupillary distance of the wearer of the helmet.
A kind of non-volatile computer readable storage comprising computer executable instructions that the application embodiment provides
Medium, when the computer executable instructions are executed by one or more processors, so that the processor executes the above institute
The control method stated.
In the control method of the application embodiment, helmet and storage medium, adjusted according to the input control of user
Mechanism drives the first eyeglass and/or the second eyeglass so that optical center distance and the pupil of wearer between the first eyeglass and the second eyeglass
Away from matching, so that user be avoided to generate spinning sensation because interpupillary distance mismatches, be conducive to the viewing experience for improving user.
Detailed description of the invention
The application is above-mentioned and/or additional aspect and advantage will become from the following description of the accompanying drawings of embodiments
Obviously and it is readily appreciated that, in which:
Fig. 1 is the stereoscopic schematic diagram of the helmet of the application embodiment;
Fig. 2 is the floor map of the helmet of the helmet of another embodiment of the application;
Fig. 3-Fig. 4 is the schematic diagram of the working principle of the helmet of the application embodiment;
Fig. 5 is the stereoscopic schematic diagram of the adjustment mechanism of the helmet of the application embodiment;
Fig. 6 is the floor map of the helmet part-structure of the application embodiment;
Fig. 7 is the schematic diagram of the adjustment process of the helmet of the application embodiment;
Fig. 8 is another schematic diagram of the adjustment process of the helmet of the application embodiment;
Fig. 9 is the floor map of the helmet part-structure of another embodiment of the application;
Figure 10 is the floor map of the helmet part-structure of the another embodiment of the application;
Figure 11 is the flow diagram of the control method of the helmet of the application embodiment;
Figure 12 is the schematic diagram of a scenario of the control method of the helmet of the application embodiment;
Figure 13 is the schematic diagram of a scenario of the control method of the helmet of the another embodiment of the application;
Figure 14 is another module diagram of the helmet of the application embodiment.
Component symbol explanation:
Helmet 100, adjustment mechanism 120, adjustment motor 121, transmission component 122, connecting rod 1221, gear 1222, the
It is one rack gear 1223, the second rack gear 1224, the first eyeglass 501, the second eyeglass 502, the first microscope base 5011, the second microscope base 5021, outer
Portion's equipment 300, processor 101, memory 102, built-in storage 103, display device 104;
Shell 20, container 22, housing top 24, outer shell bottom wall 26, notch 262, side wall of outer shell 28, support member 30,
First support 32, the first bending part 322, second support 34, the second bending part 342, elastic webbing 36, display 40, dioptric component
50, dioptric chamber 52, light-transmissive fluid 54, the first film layer 56, the second film layer 58, side wall 59, regulating mechanism 60, cavity 62, sliding slot
622, sliding part 64, driving part 66, knob 662, lead screw 664, gear 666, rack gear 668, driving motor 669, motor shaft
6691, loader 6692, adjusting cavity 68.
Specific embodiment
Embodiments herein is described below in detail, examples of the embodiments are shown in the accompanying drawings, wherein from beginning to end
Same or similar label indicates same or similar element or element with the same or similar functions.Below with reference to attached
The embodiment of figure description is exemplary, it is intended to for explaining the application, and should not be understood as the limitation to the application.
Referring to Fig. 1, the application embodiment provides a kind of helmet 100, helmet is, for example, that wear-type is aobvious
Show equipment (Head Mount Display, HMD), helmet 100 passes through the cooperation of computing system and optical system, in user
After wearing head-mounted display apparatus, optical signalling can be sent to the eyes of user, to realize virtual reality (Virtual
Reality, VR), the differences such as augmented reality (Augmented Reality, AR) and mixed reality (Mixed Reality, MR)
Effect.
Helmet 100 can be by wired or wirelessly connect with external equipment 300.External equipment 300
The for example mobile terminals such as handle, mobile phone.
Fig. 1 and Fig. 2 is please referred to, the helmet 100 of the application embodiment includes the first eyeglass 501, the second eyeglass
502 and adjustment mechanism 120, the second eyeglass 502 and the first eyeglass 501 and to arrangement.Adjustment mechanism 120 and the first eyeglass 501 and
The connection of second eyeglass 502.Adjustment mechanism 120 for drive the first eyeglass 501 and the movement close to each other simultaneously of the second eyeglass 502 or
It moves away from each other simultaneously, to adjust the optical center distance between the first eyeglass 501 and the second eyeglass 502, so that optical center distance is suitable
The interpupillary distance of wearer with helmet 100.
In the helmet 100 of the application embodiment, the first mirror is driven according to the input control adjustment mechanism 120 of user
Piece 501 and/or the second eyeglass 502 are so that optical center distance and the interpupillary distance of wearer between the first eyeglass 501 and the second eyeglass 502
Match, so that user be avoided to generate spinning sensation because interpupillary distance mismatches, is conducive to the viewing experience for improving user.
It should be pointed out that the picture that the first eyeglass 501 and the second eyeglass 502 can be used for showing helmet 100 is thrown
It is incident upon in the eyes of wearer, so that wearer can watch display picture.
Adjust the optical center between the first eyeglass 501 and the second eyeglass 502 apart from when, can be respectively in the first eyeglass 501
Optical center at and the optical center of the second eyeglass 502 at show respectively cross cursor etc. indicate, in order to which wearer judges the first eyeglass
The optical center position of 501 optical center and the second eyeglass 502.
Referring to Fig. 3, in one example, if the interpupillary distance of wearer is 65mm, and the first eyeglass 501 and the second eyeglass
Optical center distance between 502 is 60mm, then, regulating mechanism can drive the first eyeglass 501 and the second eyeglass 502 remote each other
From so that the optical center distance between the first eyeglass 501 and the second eyeglass 502 is 65mm, so that the first eyeglass 501 and second
The interpupillary distance of optical center distance adaptation wearer between eyeglass 502.
Referring to Fig. 4, in another example, if the interpupillary distance of wearer is 65mm, and the first eyeglass 501 and the second eyeglass
Optical center distance between 502 is 70mm, then, adjustment mechanism 120 can drive the first eyeglass 501 and the second eyeglass 502 each other
It is close, so that the optical center distance between the first eyeglass 501 and the second eyeglass 502 is 65mm, so that the first eyeglass 501 and the
The interpupillary distance of optical center distance adaptation wearer between two eyeglasses 502.
Specifically, referring to Fig. 5, helmet 100 includes the first microscope base 5011 and the second microscope base 5021, the first eyeglass
501 settings are in the first microscope base 5011, and for the setting of the second eyeglass 502 in the second microscope base 5021, adjustment mechanism 120 includes adjustment motor
121 adjust the transmission component 122 of motor 121 with connection.It adjusts motor 121 and first microscope base 5011 is driven by transmission component 122
It is mobile with the second microscope base 5021, so that the first eyeglass 501 of driving and the second eyeglass 502 are mobile.
In this way, the first microscope base 5011 and the second microscope base 5021 are conducive to protect the first eyeglass 501 and the second eyeglass 502, make
Obtaining the first eyeglass 501 and the second eyeglass 502 can successfully move.
Further, transmission component 122 includes connecting rod 1221, gear 1222, the first rack gear 1223 and the second rack gear 1224,
First rack gear 1223 and 1224 sandwiched gear 1222 of the second rack gear are simultaneously engaged with gear 1222.The connection of first microscope base 5011 connects
Bar 1221 is simultaneously fixedly connected with the first rack gear 1223, and the second microscope base 5021 is fixedly connected with the second rack gear 1224, and connecting rod 1221 connects
Adjustment motor 121 is connect, adjustment motor 121 is rotated for drive link 1221, to drive the first microscope base 5011 relative to gear
1222 is mobile, to make the first rack gear 1223 driving gear 1222 rotate, to drive the second rack gear 1224 to drive the second microscope base
5021 is mobile relative to gear 1222.
In this way, transmission component 122 is cooperated by structures such as the gear teeth, so that the first eyeglass 501 and the second eyeglass 502 are mobile more
Add stabilization, the precision of the first eyeglass 501 and the movement of the second eyeglass 502 can be improved.
In one example, the original state of adjustment mechanism 120 is as shown in figure 5, adjustment 121 drive link 1221 of motor
It rotates clockwise.Connecting rod 1221, which rotates clockwise, drives the first microscope base 5011 along the second rack gear 1224 to close to gear 1222
Direction is mobile.And the first microscope base 5011 is fixedly connected with the first rack gear 1223, and therefore, while the first microscope base 5011 is mobile,
Drive the first rack gear 1223 mobile, and the direction of the first rack gear 1223 movement is identical as the mobile direction of the first microscope base 5011.
And the first rack gear 1223 is engaged with gear 1222, therefore, the mobile driving gear of the first rack gear 1223 turns counterclockwise
It is dynamic, so that the second rack gear 1224 that driving is engaged with gear 1222 is mobile, and the direction and the first mirror that the second rack gear 1224 is mobile
Seat 5011 moves contrary.
Since the second microscope base 5021 is fixedly connected with the second rack gear 1224, the mobile drive of the second rack gear 1224
Two microscope bases 5021 are mobile, and the direction of the second microscope base 5021 movement is identical as the mobile direction of the second rack gear 1224, that is, the second mirror
The mobile direction of seat 5021 is contrary with the movement of the first microscope base 5011.In other words, the first microscope base 5011 and the second microscope base
5021 is close to each other.So, the first eyeglass 501 and the second eyeglass 502 are close to each other, the first eyeglass 501 and the second eyeglass 502 it
Between optical center distance reduce.
Similarly, in the case where the original state of adjustment mechanism 120 is as shown in Figure 5, in adjustment 121 drive link of motor
1221 when rotating counterclockwise, and the first eyeglass 501 and the second eyeglass 502 are located remotely from each other, the first eyeglass 501 and the second eyeglass 502 it
Between optical center distance increase.The specific transmission process of transmission component 122 can refer to connecting rod 1221 when connecting rod 1221 rotates counterclockwise
The specific transmission process of transmission component 122 when rotating clockwise.To avoid redundancy, details are not described herein.
It please refers to referring again to Fig. 1 and Fig. 2, the helmet 100 of the application embodiment includes shell 20, support member
30, display 40, dioptric component 50, regulating mechanism 60 and processor 101.
Specifically, in the example of this Fig. 2, the portion 100 that wears of helmet 100 includes display 40 and dioptric component
50, the quantity of display 40 is two, and the quantity of dioptric component 50 is two, corresponding 40 He of display of the first eyeglass 501
One dioptric component 50, another corresponding display 40 of the second eyeglass 502 and another dioptric component 50.
Shell 20 is the exterior components of helmet 100, plays the inside zero of protection and fixed helmet 100
The effect of part.Inner components are surrounded by shell 20, these inner components can be caused to avoid extraneous factor
Direct damage.
Specifically, in the present embodiment, shell 20 can be used for accommodating and fixing display 40, dioptric component 50 and adjust
At least one of mechanism 60.In the example of fig. 1, shell 20 is formed with container 22, and display 40 and dioptric component 50 are received
Hold in container 22.Regulating mechanism 60 partly exposes from shell 20.
Shell 20 further includes housing top 24, outer shell bottom wall 26 and side wall of outer shell 28.The middle part of outer shell bottom wall 26 is outside
Shell roof 24 forms notch 262.In other words, shell 20 is substantially in " B " font.When user wears helmet 100, wear
Equipment 100 can be erected on the bridge of the nose of user by notch 262, can not only guarantee the stability of helmet 100 in this way, but also
It can guarantee the comfort that user wears.Regulating mechanism 60 can partly expose from side wall of outer shell 28, so that user is to dioptric portion
Part 50 is adjusted.
In addition, shell 20 can pass through computer numerical control (Computerized Numerical Control, CNC) lathe
Processing aluminium alloy is formed, can also be using polycarbonate (Polycarbonate, PC) or PC and acrylonitrile-butadiene-benzene
Vinyl plastics (Acrylonitrile Butadiene Styrene plastic, ABS) injection molding.Herein not to shell 20
Specific manufacture and specific material be defined.
Support member 30 is used to support helmet 100.When user wears helmet 100, helmet 100 can
The head of user is fixed on by support member 30.In the figure 2 example, support member 30 includes first support 32, second
Frame 34 and elastic webbing 36.
First support 32 and second support 34 are symmetrical arranged about notch 262.Specifically, first support 32 and second support
34 are rotatably arranged in the edge of shell 20, can be by first support 32 and when user does not need using helmet 100
Two brackets 34 are stacked close to shell 20, in order to store.It, can be by first support 32 when user needs using helmet 100
It is unfolded with second support 34, to realize the function of first support 32 and the support of second support 34.
First support 32 is formed with the first bending part 322 far from one end of shell 20, and the first bending part 322 is towards shell bottom
Wall 26 is bent.In this way, user, when wearing helmet 100, the first bending part 322 can be erected on the ear of user, thus
Helmet 100 is set to be not easy to slide.
Similarly, second support 34 is formed with the second bending part 342 far from one end of shell 20.Second bending part 342
Explanation and illustration can refer to the first bending part 322, and to avoid redundancy, details are not described herein.
The detachably connected first support 32 of elastic webbing 36 and second support 34.In this way, wearing helmet in user
When 100 progress aggravating activities, helmet 100 can be further fixed by elastic webbing 36, prevent helmet 100 in play
It loosens in strong activity and even falls.It is appreciated that elastic webbing 36 also can be omitted in other examples.
In the present embodiment, display 40 includes OLED display screen.OLED display screen is not necessarily to backlight, is conducive to wear
Equipment 100 it is lightening.Moreover, OLED screen curtain visible angle is big, power consumption is lower, is conducive to the amount of saving energy.
Certainly, display 40 can also use light-emitting diode display or Micro light-emitting diode display.These displays, which are only used as, to be shown
Example and embodiments herein is not limited to this.
Referring to Figure 2 together and Fig. 6, dioptric component 50 are arranged in 40 side of display.Dioptric component 50 includes dioptric chamber
52, light-transmissive fluid 54, the first film layer 56, the second film layer 58 and side wall 59.
Light-transmissive fluid 54 is arranged in dioptric chamber 52.Regulating mechanism 60 is used to adjust the amount of light-transmissive fluid 54 to adjust dioptric
The form of component 50.Specifically, the second film layer 58 is arranged relative to the first film layer 56, and side wall 59 connects the first film layer 56 and second
Film layer 58, the first film layer 56, the second film layer 58 and side wall 59 surround dioptric chamber 52, and regulating mechanism 60 is for adjusting light-transmissive fluid
54 amount is to change the shape of the first film layer 56 and/or the second film layer 58.
In this way, realizing the realization of 50 dioptric function of dioptric component.Specifically, " change the first film layer 56 and/or the second film layer
58 shape " includes three kinds of situations: the first situation: changing the shape of the first film layer 56 and does not change the shape of the second film layer 58
Shape;Second situation: not changing the shape of the first film layer 56 and changes the shape of the second film layer 58;The third situation: change the
The shape of one film layer 56 and the shape for changing the second film layer 58.It note that for convenience of explanation, in the present embodiment, with first
It is illustrated for kind situation.
First film layer 56 can have elasticity.It is appreciated that the case where amount of the light-transmissive fluid 54 in dioptric chamber 52 changes
Under, the pressure in dioptric chamber 52 also changes therewith, so that the form of dioptric component 50 changes.
In one example, regulating mechanism 60 reduces the amount of light-transmissive fluid 54 in dioptric chamber 52, the pressure in dioptric chamber 52
Strong to reduce, the pressure difference of the pressure in pressure and dioptric chamber 52 outside dioptric chamber 52 increases, and dioptric chamber 52 is more recessed.
In another example, regulating mechanism 60 increases the amount of light-transmissive fluid 54 in dioptric chamber 52, in dioptric chamber 52
Pressure increases, and the pressure difference of the pressure in pressure and dioptric chamber 52 outside dioptric chamber 52 reduces, and dioptric chamber 52 more protrudes.
In this way, being achieved that the amount by adjusting light-transmissive fluid 54 to adjust the form of dioptric component 50.
Regulating mechanism 60 connects dioptric component 50.Regulating mechanism 60 is used to adjust the form of dioptric component 50 to adjust dioptric
The diopter of component 50.Specifically, regulating mechanism 60 includes cavity 62, sliding part 64, driving part 66, adjusting cavity 68 and switch
61。
Sliding part 64 is slidably arranged in cavity 62, and driving part 66 is connect with sliding part 64, cavity 62 and sliding part
64 limit adjusting cavity 68 jointly, and adjusting cavity 68 is connected to dioptric chamber 52 by side wall 59, and driving part 66 is for driving sliding part
64 adjust the amount of the light-transmissive fluid 54 in dioptric chamber 52 relative to the sliding of cavity 62 to adjust the volume of adjusting cavity 68.
In this way, the volume for adjusting adjusting cavity 68 by sliding part 64 is realized, to adjust the light-transmissive fluid in dioptric chamber 52
54 amount.In one example, referring to Fig. 7, sliding part 64 is slided toward the direction away from side wall 59, the volume of adjusting cavity 68
Increase, the pressure in adjusting cavity 68 reduces, and the light-transmissive fluid 54 in dioptric chamber 52 enters adjusting cavity 68, the first film layer 56 more to
Sunken inside.
In another example, referring to Fig. 8, sliding part 64 is slided toward the direction towards side wall 59, the appearance of adjusting cavity 68
Product reduces, and the pressure in adjusting cavity 68 increases, and the light-transmissive fluid 54 in adjusting cavity 68 enters dioptric chamber 52, and the first film layer 56 is more
It outwardly protrudes.
Side wall 59 is formed with flow channel 591, and flow channel 591 is connected to adjusting cavity 68 and dioptric chamber 52.Regulating mechanism 60
Switch 61 including flow channel 591 is arranged in, switch 61 are used to control the open and-shut mode of flow channel 591.
In the present embodiment, the quantity of switch 61 is two, and two switches 61 are single-way switch, one of switch
61 flow to dioptric chamber 52 from adjusting cavity 68 for controlling light-transmissive fluid 54, another switch 61 is for controlling light-transmissive fluid 54 from the wrong
Optical cavity 52 flow to adjusting cavity 68.
In this way, flowing of the light-transmissive fluid 54 between adjusting cavity 68 and dioptric chamber 52 is realized by switch 61, to keep side
The pressure equilibrium of 59 two sides of wall.As previously mentioned, the change of 68 volume of adjusting cavity, can cause the variation of pressure in adjusting cavity 68, from
And cause existing flowing of the light-transmissive fluid 54 between adjusting cavity 68 and dioptric chamber 52.And switch 61 passes through control flow channel 591
Open and-shut mode, can be realized to control flowing of the light-transmissive fluid 54 between adjusting cavity 68 and dioptric chamber 52, thus control bend
The adjusting of the form of light component 50.
In one example, referring to Fig. 7, control light-transmissive fluid 54 flow to the switch 61 of adjusting cavity 68 from dioptric chamber 52
It opens, sliding part 64 is slided toward the direction away from side wall 59, and the volume of adjusting cavity 68 increases, and the pressure in adjusting cavity 68 reduces,
Light-transmissive fluid 54 in dioptric chamber 52 enters adjusting cavity 68 by switch 61, and the first film layer 56 is more recessed inwardly.
In another example, control light-transmissive fluid 54 is closed from the switch 61 that dioptric chamber 52 flow to adjusting cavity 68, even if
Sliding part 64 is slided toward the direction away from side wall 59, and the volume of adjusting cavity 68 increases, and the pressure in adjusting cavity 68 reduces, dioptric chamber
Light-transmissive fluid 54 in 52 also cannot be introduced into adjusting cavity 68, and the form of the first film layer 56 does not change.
In another example, referring to Fig. 8, control light-transmissive fluid 54 flow to the switch of dioptric chamber 52 from adjusting cavity 68
61 open, and sliding part 64 is slided toward the direction towards side wall 59, and the volume of adjusting cavity 68 reduces, and the pressure in adjusting cavity 68 increases
Greatly, the light-transmissive fluid 54 in adjusting cavity 68 enters dioptric chamber 52 by switch 61, and the first film layer 56 more outwardly protrudes.
In another example, control light-transmissive fluid 54 is closed from the switch 61 that adjusting cavity 68 flow to dioptric chamber 52, even if
Sliding part 64 is slided toward the direction towards side wall 59, and the volume of adjusting cavity 68 reduces, and the pressure in adjusting cavity 68 increases, adjusting cavity
Light-transmissive fluid 54 in 68 also cannot be introduced into dioptric chamber 52, and the form of the first film layer 56 does not change.
Driving part 66 can realize its function of driving sliding part 64 to slide based on various structures and principle.
In the example of Fig. 1, Fig. 6-Fig. 8, driving part 66 includes knob 662 and lead screw 664, and lead screw 664 connects knob
662 and sliding part 64, knob 662 is for driving the rotation of lead screw 664 to drive sliding part 64 to slide relative to cavity 62.
Sliding part 64 is driven by knob 662 and lead screw 664 in this way, realizing.Due to matching for lead screw 664 and knob 662
Conjunction can convert lead screw 664 for the rotary motion of knob 662 and move along a straight line, when user rotates knob 662, lead screw 664
It drives sliding part 64 to slide relative to cavity 62, so as to cause the variation of 68 volume of adjusting cavity, and then adjusts in dioptric chamber 52
The amount of light-transmissive fluid 54.Knob 662 can expose from shell 20, to facilitate user to rotate.
Specifically, it is formed with threaded portion on knob 662, the threaded portion cooperated with knob 662, rotation are formed on lead screw 664
Button 662 and lead screw 664 are threadedly coupled.
While knob 662 rotates, switch 61 can be opened accordingly.In this way, flowing light-transmissive fluid 54, protect
Demonstrate,prove the pressure equilibrium of 59 two sides of side wall.
In one example, knob 662 rotates clockwise, and sliding part 64 is slided toward the direction away from side wall 59, then will control
Light-transmissive fluid 54 processed is opened from the switch 61 that dioptric chamber 52 flow to adjusting cavity 68.In another example, knob 662 is counterclockwise
Rotation, sliding part 64 are slided toward the direction towards side wall 59, then control light-transmissive fluid 54 are flow to dioptric chamber 52 from adjusting cavity 68
Switch 61 open.
It note that in present embodiment, be not associated with the rotation angle of knob 662 and the refractive diopter of dioptric component 50,
Knob 662 is rotated to the optimal position of visual experience by user.Certainly, in other implementations, can also be associated with
The rotation angle of knob 662 and the refractive diopter of dioptric component 50.Here, not to the rotation angle of knob 662 and dioptric component
Whether 50 refractive diopter, which is associated with, is defined.
Referring to Fig. 9, driving part 66 includes gear 666 and the rack gear 668 engaged with gear 666,668 tooth connection of rack gear
Wheel 666 and sliding part 64, gear 666 are mobile to drive sliding part 64 to slide relative to cavity 62 for drive rack 668.
Sliding part 64 is driven by gear 666 and rack gear 668 in this way, realizing.Due to matching for gear 666 and rack gear 668
Conjunction can convert rack gear 668 for the rotary motion of gear 666 and move along a straight line, when user rotates gear 666, rack gear 668
It drives sliding part 64 to slide relative to cavity 62, so as to cause the variation of 68 volume of adjusting cavity, and then adjusts in dioptric chamber 52
The amount of light-transmissive fluid 54.Gear 666 can expose from shell 20, to facilitate user to rotate.
Similarly, while gear 666 rotates, switch 61 can be opened accordingly.In this way, making light-transmissive fluid 54 can
With flowing, guarantee the pressure equilibrium of 59 two sides of side wall.
In one example, gear 666 rotates clockwise so that rack gear 668 is engaged on gear 666, the length of rack gear 668
Degree shortens, and pulls sliding part 64 mobile toward the direction for deviating from side wall 59, then control light-transmissive fluid 54 is flow to tune from dioptric chamber 52
The switch 61 for saving chamber 68 is opened.
In another example, gear 666 rotates counterclockwise so that the rack gear 668 being engaged on gear 666 is from gear 666
It is detached from, the length of rack gear 668 increases, and pushes sliding part 64 toward towards the movement of the direction of side wall 59, then will control light-transmissive fluid 54
The switch 61 for flowing to dioptric chamber 52 from adjusting cavity 68 is opened.
Similarly, in present embodiment, it is not associated with the rotation angle of gear 666 and the refractive diopter of dioptric component 50,
Gear 666 is rotated to the optimal position of visual experience by user.Certainly, in other implementations, can also be associated with
The rotation angle of gear 666 and the refractive diopter of dioptric component 50.Here, not to the rotation angle of gear 666 and dioptric component
Whether 50 refractive diopter, which is associated with, is defined
Referring to Fig. 10, driving part 66 includes driving motor 669, the motor shaft 6691 of driving motor 669 connects sliding
Part 64, driving motor 669 is for driving sliding part 64 to slide relative to cavity 62.
Sliding part 64 is driven by driving motor 668 in this way, realizing.Specifically, driving motor 669 can be linear electric machine.
Linear motor structure is simple, needs not move through intermediate conversion mechanism and directly generates linear motion, can reduce movement inertia simultaneously
Improve dynamic response performance and positioning accuracy.Sliding part 64 is driven by driving motor 668, so that the driving to sliding part 64
With editability.For example, driving motor 668 can be associated with the degree of dioptric by prior calibration.User can
To directly input the degree of dioptric, 668 automatic operating of driving motor driving sliding part 64 slides into corresponding position.
Further, driving part 66 can also include loader 6692, and loader 6692 includes but is not limited to key, rotation
The devices such as button or touch screen.In the example in figure 7, loader 6692 is key, and two keys are separately positioned on the phase of cavity 62
To two sides.Key can expose from shell 20, to facilitate user to press.Key can be controlled according to the number or duration of pressed by external force and be driven
The operating time of dynamic motor 669, to control the sliding distance of sliding part 64.
Similarly, while driving motor 669 works, switch 61 can be opened accordingly.In this way, making light-transmissive fluid 54
It can flow, guarantee the pressure equilibrium of 59 two sides of side wall.
In one example, user presses a key in two keys, and drive motor shaft 6691 extends, motor shaft
6691 push the past direction towards side wall 59 of sliding part 64 mobile, then will control light-transmissive fluid 54 from adjusting cavity 68 and flow to dioptric chamber
52 switch 61 is opened.
In another example, user presses another key in two keys, and drive motor shaft 6691 shortens, motor
Axis 6691 pulls sliding part 64 mobile toward the direction for deviating from side wall 59, then will control light-transmissive fluid 54 from dioptric chamber 52 and flow to tune
The switch 61 for saving chamber 68 is opened.
It should be noted that the structure of dioptric component 50 not only include more than dioptric chamber 52, light-transmissive fluid 54, the first film
The 56, second film layer 58 of layer and side wall 59, as long as guaranteeing that the effect of the change of diopter may be implemented in dioptric component 50.Example
Such as, in other modes, dioptric component 50 includes multiple eyeglasses and actuator, and actuator is for driving each eyeglass from receiving position
It sets and is moved to dioptric position.In this way, can be by the combination of multiple eyeglasses, to change the diopter of dioptric component 50.Certainly,
Actuator can also drive each eyeglass being moved on dioptric position to move on dioptric optical axis, to change dioptric component 50
Diopter.
Therefore, the form of above-described dioptric component includes the shape and state of dioptric component, the above dioptric chamber 52, thoroughly
Light liquid 54, the first film layer 56, the second film layer 58 and side wall 59 frame mode by changing the first film layer 56 and/or second
The shape of film layer 58 is to realize the change of diopter;The frame mode of above multiple eyeglasses and actuator, by changing eyeglass
State is to realize the change of diopter.
In summary, a kind of helmet 100 that the application embodiment provides includes display 40, dioptric component 50
With regulating mechanism 60.Dioptric component 50 is arranged in 40 side of display.Regulating mechanism 60 connects dioptric component 50, regulating mechanism 60
For adjusting the form of dioptric component 50 to adjust the diopter of dioptric component 50.
The helmet 100 of the application embodiment adjusts the form of dioptric component 50 by regulating mechanism 60, to adjust
The diopter of dioptric component 50 enables ametropic user to see the image of the display of display 40 clearly, is conducive to improve and use
Family experience.
Moreover, in the helmet 100 of the application embodiment, dioptric component 50 and regulating mechanism 60 can linearly be corrected in the wrong
Luminosity number wear the people of each different refractive diopters can flexibly.Meanwhile the body of dioptric component 50 and regulating mechanism 60
Product is smaller, does not influence the wearing experience of helmet 100.User does not need to buy many eyeglasses, can reduce price.
Figure 11 is please referred to, the application embodiment provides a kind of control method, and control method is used for helmet 100,
Helmet 100 include the first eyeglass 501, with the first eyeglass 501 and to the second eyeglass 502 of arrangement and with the first eyeglass
501 and second adjustment mechanism 120 that connects of eyeglass 502, control method includes:
010, receive the first operation input;
020, adjustment mechanism 120 is controlled according to the first operation input and is driven in the first eyeglass 501 and the second eyeglass 502 extremely
A few movement, to adjust the optical center distance between the first eyeglass 501 and the second eyeglass 502;
030, it is defeated that the second operation is received during at least one of the first eyeglass 501 and the second eyeglass 502 are mobile
Enter;
040, adjustment mechanism 120 is controlled according to the second operation input and stops the first eyeglass 501 of driving and the second eyeglass 502,
So that the interpupillary distance of the wearer of optical center distance adaptation helmet 100.
In some embodiments, as shown in figure 5, helmet 100 includes processor 101, processor 101 is for receiving
First operation input, and the first eyeglass 501 and the second eyeglass are driven for controlling adjustment mechanism 120 according to the first operation input
At least one of 502 is mobile, to adjust the optical center distance between the first eyeglass 501 and the second eyeglass 502, and for first
The second operation input is received during at least one of eyeglass 501 and the second eyeglass 502 are mobile, and for according to second
Operation input controls adjustment mechanism 120 and stops the first eyeglass 501 of driving and the second eyeglass 502, so that optical center distance adaptation is worn
The interpupillary distance of the wearer of equipment 100.
In the control method and helmet 100 of the application embodiment, according to the input control adjustment mechanism 120 of user
The first eyeglass 501 and/or the second eyeglass 502 are driven so that optical center distance and pendant between the first eyeglass 501 and the second eyeglass 502
The interpupillary distance of wearer matches, so that user be avoided to generate spinning sensation because interpupillary distance mismatches, is conducive to the viewing body for improving user
It tests.
Specifically, the first operation input is acquired by the input unit of helmet 100 and is obtained, and/or is set by outside
Standby 300 acquisition obtains.Second operation input is acquired by the input unit of helmet 100 and is obtained, and/or is set by outside
Standby 300 acquisition obtains.
For example, the input unit of helmet 100 is, for example, key, when user presses the button for the first time, can make
First eyeglass 501 and/or the second eyeglass 502 are mobile, and the optical center distance between the first eyeglass 501 and the second eyeglass 502 is in
When suitable position, user can press the button for the second time, at this point, the first eyeglass 501 and/or the second eyeglass 502 stop moving
It is dynamic, the optical center distance between the first eyeglass 501 adjustable in this way and the second eyeglass 502.
For another example, as shown in figure 12, external equipment 300 is, for example, mobile phone, and mobile phone can pass through the wireless modes such as bluetooth and head
Wear 100 connection communication of equipment.Mobile phone is provided with corresponding application program.Application program is provided with relevant touch key-press,
When one click touch key-press, the first eyeglass 501 and/or the second eyeglass 502 can be made mobile, click touching for the second time in user
When touching key, the first eyeglass 501 and/or the second eyeglass 502 stop movement, the first eyeglass 501 adjustable in this way and the second mirror
Optical center distance between piece 502.
It may be noted that be, the first operation input and/or the second operation input include click, in sliding and pressing at least
It is a kind of.For example, the first eyeglass 501 and/or the second eyeglass 502 are mobile when user clicks the touch key-press in application program;User
When sliding on the touchscreen, the first eyeglass 501 and/or the second eyeglass 502 stop movement.
It is appreciated that the movement of at least one of the first eyeglass 501 and the second eyeglass 502 also refers to, the first eyeglass
501 is static, and the second eyeglass 502 is mobile;First eyeglass 501 is mobile, and the second eyeglass 502 is static;Or first eyeglass 501 and
Two eyeglasses 502 are mobile simultaneously.
In one example, the movement speed range of the first eyeglass 501 and/or the second eyeglass 502 is 0.5-1mm/s.Such as
This, the movement speed of the first eyeglass 501 and/or the second eyeglass 502 is preferable, user can be allowed to operate in time in this way so that
First eyeglass 501 and/or the second eyeglass 502 stop movement, so that the light between the first eyeglass 501 and the second eyeglass 502
Interpupillary distance of the heart away from adaptation user.
In some embodiments, step 020 includes:
Controlling adjustment mechanism 120 according to the first operation input drives the first eyeglass 501 and the second eyeglass 502 to lean on each other simultaneously
It is close mobile;Or
Controlling adjustment mechanism 120 according to the first operation input drives the first eyeglass 501 and the second eyeglass 502 remote each other simultaneously
From movement.
In some embodiments, processor 101 is used to control the driving of adjustment mechanism 120 first according to the first operation input
502 movement close to each other simultaneously of eyeglass 501 and the second eyeglass;Or it is driven for controlling adjustment mechanism 120 according to the first operation input
Dynamic first eyeglass 501 and the second eyeglass 502 move away from each other simultaneously.
It is appreciated that the eyes of user are generally concerned with the positional symmetry of the bridge of the nose, corresponding to the eyes of user, the first eyeglass
501 and second eyeglass 502 the generally mirror image arrangement of arrangement, to meet the demand of ergonomic.Therefore, adjustment mechanism is controlled
120 the first eyeglasses 501 of driving and the movement close to each other simultaneously of the second eyeglass 502 move away from each other, so rapidly by the
Optical center distance is adjusted to suitable position between one eyeglass 501 and the second eyeglass 502, easy to operate, improves user experience.
Certainly, in other embodiments, the first eyeglass 501 and the second eyeglass 502 can also be moved, one by one to adjust
Optical center distance between first eyeglass 501 and the second eyeglass 502.
In some embodiments, the first eyeglass 501 for moving back and forth between the first position and the second position, and second
Eyeglass 502 is used in the third place and the movement of the 4th position, and the second position is arranged close to the third place;
Controlling adjustment mechanism 120 according to the first operation input drives the first eyeglass 501 and the second eyeglass 502 remote each other simultaneously
Include: from mobile step
Controlling adjustment mechanism 120 according to the first operation input drives the first eyeglass 501 mobile to first position;
Drive the second eyeglass 502 mobile to the 4th position;
Controlling adjustment mechanism 120 according to the first operation input drives the first eyeglass 501 and the second eyeglass 502 to lean on each other simultaneously
The step closely moved includes:
Adjustment mechanism 120 is controlled according to the first operation input to drive the first eyeglass 501 mobile to the second position and drive the
Two eyeglasses 502 are mobile to the third place.
In some embodiments, processor 101 is used to control the driving of adjustment mechanism 120 first according to the first operation input
Eyeglass 501 is mobile to first position and drives the second eyeglass 502 mobile to the 4th position;Or for according to the first operation input control
Adjustment mechanism 120 processed drives the first eyeglass 501 mobile to the second position and drives the second eyeglass 502 mobile to the third place.
In other words, the first eyeglass 501 be moved to behind first position can automatically counter motion to the second position, the first mirror
Piece 501 be moved to behind the second position can automatically counter motion to first position.Similarly, the second eyeglass 502 is moved to third
Behind position can automatically counter motion to the 4th position, the second eyeglass 502 is moved to behind the 4th position can be automatically reversed
It moves to the third place.
It is appreciated that helmet 100 can not know the eyes interpupillary distance of wearer after wearer's distribution helmet 100.
Therefore, after the first eyeglass 501 and the second eyeglass 502 move back and forth the position of position suitable, user triggers 501 He of the first eyeglass
Second eyeglass 502 stops mobile so that the optical center distance between the first eyeglass 501 and the second eyeglass 502 matches eyes interpupillary distance.
In one example, as shown in figure 13, after user wears helmet 100, the first eyeglass 501 and the second eyeglass
Optical center distance between 502 is less than the interpupillary distance of user, at this point, user triggers the first eyeglass 501 and the movement of the second eyeglass 502 refers to
After order, the first eyeglass 501 and the movement close to each other of the second eyeglass 502;The second position, the second mirror are moved in the first eyeglass 501
When piece 502 is moved to the third place, the first eyeglass 501 and the second eyeglass 502 start to move away from each other, the first eyeglass 501 to
First position is mobile, and the second eyeglass 502 is mobile to the 4th position, is moved to the first mirror in the first eyeglass 501 and the second eyeglass 502
When the interpupillary distance of the optical center distance adaptation user between piece 501 and the second eyeglass 502, user can be with triggering command so that the first eyeglass
501 and second eyeglass 502 stop movement.
Embodiment further provides a kind of computer readable storage mediums by the application.One or more can be held comprising computer
The non-volatile computer readable storage medium storing program for executing of row instruction, when computer executable instructions are held by one or more processors 101
When row, so that processor 101 executes the control method of any of the above-described embodiment.
The helmet 100 and computer readable storage medium of the application embodiment pass through the target position slidably inputed
The target interpupillary distance of determining helmet 100 is set, and controls the adjustment mechanism 120 of helmet 100 for the interpupillary distance of helmet 100
Adjusting can make the interpupillary distance of helmet 100 and the interpupillary distance of user match to target interpupillary distance, to avoid user because of interpupillary distance
It mismatches and generates spinning sensation, be conducive to the viewing experience for improving user.
Figure 14 is the internal module schematic diagram of the helmet 100 in one embodiment.Helmet 100 includes passing through to be
The processor 101 of bus 109 of uniting connection, memory 102 (for example, non-volatile memory medium), built-in storage 103, display
Device 104 and adjustment mechanism 120.
Processor 101 can be used for providing calculating and control ability, support the operation of entire helmet 100.Helmet
100 built-in storage 103 provides environment for the computer-readable instruction operation in memory 102.The display of helmet 100 fills
Setting 104 can be the display 40 being arranged on helmet 100.
Those of ordinary skill in the art will appreciate that realizing all or part of the process in above-described embodiment method, being can be with
Instruct relevant hardware to complete by computer program, program can be stored in a non-volatile computer readable storage medium
In matter, the program is when being executed, it may include such as the process of the embodiment of above-mentioned each method.Wherein, storage medium can for magnetic disk,
CD, read-only memory (Read-Only Memory, ROM) etc..
Above embodiments only express the several embodiments of the application, and the description thereof is more specific and detailed, but can not
Therefore it is interpreted as the limitation to the application the scope of the patents.It should be pointed out that for those of ordinary skill in the art,
Without departing from the concept of this application, various modifications and improvements can be made, these belong to the protection model of the application
It encloses.Therefore, the scope of protection shall be subject to the appended claims for the application patent.
Claims (17)
1. a kind of control method, it to be used for helmet, which is characterized in that the helmet includes the first eyeglass, with described the
One eyeglass and to the second eyeglass of arrangement and the adjustment mechanism being connect with first eyeglass and second eyeglass, the control
Method processed includes:
Receive the first operation input;
The adjustment mechanism is controlled according to first operation input to drive in first eyeglass and second eyeglass extremely
A few movement, to adjust the optical center distance between first eyeglass and second eyeglass;
The second operation input is received during at least one of first eyeglass and second eyeglass are mobile;
The adjustment mechanism is controlled according to second operation input to stop driving first eyeglass and second eyeglass, with
The optical center distance is set to be adapted to the interpupillary distance of the wearer of the helmet.
2. control method according to claim 1, which is characterized in that control the adjustment according to first operation input
Mechanism drives at least one of first eyeglass and second eyeglass mobile, comprising:
According to first operation input control the adjustment mechanism drive first eyeglass and second eyeglass simultaneously that
This is close to mobile;Or
According to first operation input control the adjustment mechanism drive first eyeglass and second eyeglass simultaneously that
This is far from mobile.
3. control method according to claim 2, which is characterized in that first eyeglass is used in first position and second
Move back and forth between position, second eyeglass is used in the third place and the movement of the 4th position, and the second position is close to institute
State the third place setting;
According to first operation input control the adjustment mechanism drive first eyeglass and second eyeglass simultaneously that
This is far from mobile, comprising:
Controlling the adjustment mechanism according to first operation input drives the first eyeglass mobile to the first position;
Drive second eyeglass mobile to the 4th position;
According to first operation input control the adjustment mechanism drive first eyeglass and second eyeglass simultaneously that
This is close to mobile, comprising:
Controlling the adjustment mechanism according to first operation input drives the first eyeglass mobile to the second position;
Drive second eyeglass mobile to the third place.
4. control method according to claim 1, which is characterized in that first operation input passes through the helmet
Input unit acquire obtain, and/or by external equipment acquisition acquisition;Second operation input passes through the helmet
Input unit acquire obtain, and/or by external equipment acquisition acquisition.
5. control method according to claim 1, which is characterized in that first operation input and/or the second operation are defeated
Enter including at least one of click, sliding and pressing.
6. a kind of helmet characterized by comprising
First eyeglass;
With first eyeglass and to the second eyeglass of arrangement;
The adjustment mechanism being connect with first eyeglass and second eyeglass;With
Processor, the processor is for the first operation input of reception, and is used for according to first operation input control
Adjustment mechanism drives at least one of first eyeglass and second eyeglass mobile, to adjust first eyeglass and institute
The optical center distance between the second eyeglass is stated, and in the movement of at least one of first eyeglass and second eyeglass
The second operation input is received in the process, and stops driving institute for controlling the adjustment mechanism according to second operation input
The first eyeglass and second eyeglass are stated, so that optical center distance is adapted to the interpupillary distance of the wearer of the helmet.
7. helmet according to claim 6, which is characterized in that the processor is used for defeated according to first operation
Enter to control the adjustment mechanism and drives first eyeglass and second eyeglass movement close to each other simultaneously;Or for according to institute
The first operation input is stated to control adjustment mechanism driving first eyeglass and second eyeglass while moving away from each other.
8. helmet according to claim 7, which is characterized in that first eyeglass is used in first position and second
Move back and forth between position, second eyeglass is used in the third place and the movement of the 4th position, and the second position is close to institute
State the third place setting;The processor, which is used to control the adjustment mechanism according to first operation input, drives the first eyeglass
To the first position movement and drive second eyeglass mobile to the 4th position;Or for according to first operation
Adjustment mechanism described in input control drives the first eyeglass mobile to the second position and drives second eyeglass to described the
Three positions are mobile.
9. helmet according to claim 7, which is characterized in that first operation input passes through the helmet
Input unit acquire obtain, and/or by external equipment acquisition acquisition;Second operation input passes through the helmet
Input unit acquire obtain, and/or by external equipment acquisition acquisition.
10. helmet according to claim 7, which is characterized in that first eyeglass and/or second eyeglass
Movement speed range is 0.5-1mm/s.
11. helmet according to claim 7, which is characterized in that the adjustment mechanism includes adjustment motor and connection
The transmission component of the adjustment motor, the transmission component connect first eyeglass and second eyeglass, the processor
For controlling the movement of transmission component described in the adjustment motor driven, to drive in first eyeglass and second eyeglass
At least one movement, to adjust the optical center distance between first eyeglass and second eyeglass.
12. helmet according to claim 11, which is characterized in that the helmet includes the first microscope base and second
Microscope base, in first microscope base, second eyeglass is arranged in second microscope base, the transmission group for the first eyeglass setting
Part connects first microscope base and second microscope base.
13. helmet according to claim 12, which is characterized in that the transmission component includes connecting rod, gear, first
Gear described in rack gear and the second rack gear, first rack gear and the second rack gear sandwiched is simultaneously engaged with the gear, described
First microscope base connects the connecting rod and is fixedly connected with first rack gear, second microscope base and the fixed company of second rack gear
It connects, the connecting rod connects the adjustment motor, and the adjustment motor is for driving the link rotatable, to drive first mirror
Seat is mobile relative to the gear, to make gear described in first rack drives rotate, to drive the second rack gear band
It is mobile relative to the gear to move second microscope base.
14. helmet according to claim 7, which is characterized in that the helmet includes:
Dioptric component, the dioptric component and first eyeglass and second eyeglass, which stack, to be arranged;With
The regulating mechanism of the dioptric component is connected, the regulating mechanism is used to adjust the form of the dioptric component to adjust
State the diopter of dioptric component.
15. a kind of helmet characterized by comprising
First eyeglass;
With first eyeglass and to the second eyeglass of arrangement;
The adjustment mechanism connecting with first eyeglass and second eyeglass, the adjustment mechanism is for driving first mirror
The movement close to each other simultaneously of piece and second eyeglass moves away from each other simultaneously, to adjust first eyeglass and described the
Optical center distance between two eyeglasses, so that optical center distance is adapted to the interpupillary distance of the wearer of the helmet.
16. helmet according to claim 15, which is characterized in that the helmet includes the first microscope base and second
Microscope base, in first microscope base, second eyeglass is arranged in second microscope base, the adjustment machine for the first eyeglass setting
Structure includes the transmission component for adjusting motor and connecting the adjustment motor, and the transmission component includes connecting rod, gear, the first rack gear
With the second rack gear, gear described in first rack gear and the second rack gear sandwiched is simultaneously engaged with the gear, described first
Microscope base connects the connecting rod and is fixedly connected with first rack gear, and second microscope base is fixedly connected with second rack gear,
The connecting rod connects the adjustment motor, and the adjustment motor is for driving the link rotatable, to drive first microscope base
It is mobile relative to the gear, to make gear described in first rack drives rotate, to drive second rack drives
Second microscope base is mobile relative to the gear.
17. a kind of non-volatile computer readable storage medium storing program for executing comprising computer executable instructions, which is characterized in that when described
When computer executable instructions are executed by one or more processors, so that any in processor perform claim requirement 1-5
Control method described in.
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CN115327783A (en) * | 2022-10-13 | 2022-11-11 | 杭州灵伴科技有限公司 | Diopter adjusting member capable of adjusting diopter, optical module and display equipment |
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