CN107703595A - Optical filter, camera lens module and imaging modules - Google Patents
Optical filter, camera lens module and imaging modules Download PDFInfo
- Publication number
- CN107703595A CN107703595A CN201710915380.5A CN201710915380A CN107703595A CN 107703595 A CN107703595 A CN 107703595A CN 201710915380 A CN201710915380 A CN 201710915380A CN 107703595 A CN107703595 A CN 107703595A
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- China
- Prior art keywords
- eyeglass
- optical filter
- light
- actuator
- reflection film
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Classifications
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B26/00—Optical devices or arrangements for the control of light using movable or deformable optical elements
- G02B26/001—Optical devices or arrangements for the control of light using movable or deformable optical elements based on interference in an adjustable optical cavity
-
- G—PHYSICS
- G02—OPTICS
- G02B—OPTICAL ELEMENTS, SYSTEMS OR APPARATUS
- G02B7/00—Mountings, adjusting means, or light-tight connections, for optical elements
- G02B7/006—Filter holders
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- G—PHYSICS
- G03—PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
- G03B—APPARATUS OR ARRANGEMENTS FOR TAKING PHOTOGRAPHS OR FOR PROJECTING OR VIEWING THEM; APPARATUS OR ARRANGEMENTS EMPLOYING ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ACCESSORIES THEREFOR
- G03B17/00—Details of cameras or camera bodies; Accessories therefor
- G03B17/02—Bodies
- G03B17/12—Bodies with means for supporting objectives, supplementary lenses, filters, masks, or turrets
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04N—PICTORIAL COMMUNICATION, e.g. TELEVISION
- H04N23/00—Cameras or camera modules comprising electronic image sensors; Control thereof
- H04N23/50—Constructional details
- H04N23/55—Optical parts specially adapted for electronic image sensors; Mounting thereof
Abstract
The invention discloses a kind of optical filter.Optical filter includes the first eyeglass, the second eyeglass, Parallel testing component and drive component.First eyeglass and the second eyeglass interval are oppositely arranged, and high reflection film layer is provided with the first eyeglass and relative two surfaces of the second eyeglass.Whether Parallel testing component is used for two high reflection film layers of detection parallel.Drive component is used to drive the first eyeglass or the second lens movement when high reflection film layer is not parallel so that two high reflection film layers are parallel.Invention additionally discloses a kind of camera lens module and imaging modules.In optical filter disclosed by the invention, camera lens module and imaging modules, when Parallel testing component detection is not parallel to two high reflection film layers, drive component can drive the first eyeglass or the second lens movement, so that two high reflection film layers are parallel, it is ensured that optical filter has preferable filter effect.
Description
Technical field
The present invention relates to technical field of imaging, more specifically, is related to a kind of optical filter, camera lens module and imaging modules.
Background technology
Changeable filter device may include two eyeglasses parallel to each other, typically by multiple actuators drive eyeglass movement with
Change the distance between eyeglass, and the wavelength of the emergent light for adjusting changeable filter device, however, due to different driving part
Precision is had differences, and eyeglass may be caused not parallel, so as to cause the filter effect of changeable filter device bad.
The content of the invention
Embodiment of the present invention provides a kind of optical filter, camera lens module and imaging modules.
The optical filter of embodiment of the present invention includes:
It is spaced the first eyeglass and the second eyeglass that are oppositely arranged, first eyeglass and relative two of second eyeglass
High reflection film layer is provided with surface;
Parallel testing component, whether the Parallel testing component is used for two high reflection film layers of detection parallel;With
Drive component, the drive component are used to drive first eyeglass or institute when the high reflection film layer is not parallel
The second lens movement is stated so that two high reflection film layers are parallel.
The camera lens module of embodiment of the present invention includes:
Microscope base;
Lens barrel on the microscope base;With
Optical filter described in above-mentioned embodiment, the optical filter are arranged in the lens barrel or the microscope base.
The imaging modules of embodiment of the present invention include:
Substrate;
Imaging sensor on the substrate is set;With
Camera lens module described in above-mentioned embodiment, the camera lens module are fixed on the substrate, described image sensing
Device is housed in the camera lens module.
In optical filter, camera lens module and imaging modules that embodiment of the present invention provides, when Parallel testing component detection arrives
When two high reflection film layers are not parallel, drive component can drive the first eyeglass or the second lens movement, so that two highly reflecting films
Layer is parallel, it is ensured that optical filter has preferable filter effect.
The additional aspect and advantage of embodiments of the present invention will be set forth in part in the description, partly will be from following
Description in become obvious, or recognized by the practice of embodiments of the present invention.
Brief description of the drawings
The above-mentioned and/or additional aspect and advantage of the present invention is from combining in description of the accompanying drawings below to embodiment by change
Obtain substantially and be readily appreciated that, wherein:
Fig. 1 is the structural representation of the optical filter of embodiment of the present invention;
Fig. 2 is the schematic top plan view of the optical filter of embodiment of the present invention;
Fig. 3 is the structural representation of the optical filter of embodiment of the present invention;
Fig. 4 is the structural representation of the optical filter of embodiment of the present invention;
Fig. 5 is the structural representation of the optical filter of embodiment of the present invention;
Fig. 6 is the structural representation of the camera lens module of embodiment of the present invention;
Fig. 7 is the structural representation of the imaging modules of embodiment of the present invention;
Fig. 8 is the optical filtering part of embodiment of the present invention and the structural representation of actuator.
Embodiment
Embodiments of the present invention are described further below in conjunction with accompanying drawing.Same or similar label is from beginning in accompanying drawing
To the whole element for representing same or similar element or there is same or like function.
In addition, the embodiments of the present invention described below in conjunction with the accompanying drawings are exemplary, it is only used for explaining the present invention's
Embodiment, and be not considered as limiting the invention.
In the present invention, unless otherwise clearly defined and limited, fisrt feature can be with "above" or "below" second feature
It is that the first and second features directly contact, or the first and second features pass through intermediary mediate contact.Moreover, fisrt feature exists
Second feature " on ", " top " and " above " but fisrt feature are directly over second feature or oblique upper, or be merely representative of
Fisrt feature level height is higher than second feature.Fisrt feature second feature " under ", " lower section " and " below " can be
One feature is immediately below second feature or obliquely downward, or is merely representative of fisrt feature level height and is less than second feature.
Refer to Fig. 1 and Fig. 2, the optical filter 10 of embodiment of the present invention includes the first eyeglass 11, the second eyeglass 12, parallel
Detection components 14 and drive component 15.First eyeglass 11 and the second eyeglass 12 interval are oppositely arranged, the first eyeglass 11 and the second mirror
Piece 12 is provided with high reflection film layer 13 on two relative surfaces.Parallel testing component 14 is used to detect two high reflection film layers
Whether 13 is parallel.Drive component 15 is used to drive the first eyeglass 11 or the second eyeglass 12 to transport when high reflection film layer 13 is not parallel
Move so that two high reflection film layers 13 are parallel.
In the optical filter 10 of embodiment of the present invention, when Parallel testing component 14 detects that two high reflection film layers 13 are uneven
During row, drive component 15 can drive the first eyeglass 11 or the second eyeglass 12 to move, so that two high reflection film layers 13 are parallel, really
Protecting optical filter 10 has preferable filter effect.
Referring to Fig. 1, specifically, the first eyeglass 11 and the second eyeglass 12 can be plate glass or quartz plate.High reflection
Film layer 13 can be metal film or multilayer dielectric film, wherein, metal film can be silverskin, aluminium film etc..First eyeglass 11 and second
Eyeglass 12 forms Fabry-Perot interferometer, and Fabry-Perot-type cavity is formed between two high reflection film layers 13.Including a variety of ripples
Long light is injected into optical filter 10, and into after Fabry-Perot-type cavity, wavelength meets that the light of resonance condition can go out in transmission spectrum
Now very high peak value, high-transmission rate is correspond to, therefore, this kind of light can form dry in Fabry-Perot intracavitary progress multiple reflections
Light beam is related to, eventually passes through that optical filter 10 is wholly transmissive to go out, and the light for being unsatisfactory for resonance condition can not be by optical filter 10.Light exists
Gap between the transmissivity of Fabry-Perot-type cavity and two high reflection film layers 13 is relevant, it is generally the case that what resonance condition referred to
The width (d) for being gap is the half of the wavelength (λ) of light, i.e. d=λ/2, this time has higher transmissivity.
The light (such as white light) including multi-wavelength of optical filter 10 is incided, it is exportable in the presence of optical filter 10
The light of specific wavelength, such as infrared light, feux rouges, blue and green light etc., and by adjust two high reflection film layers 13 between
Gap size, the emergent light of different wave length can be obtained.In actual use, optical filter 10 can be applied to imaging modules 1000
In (shown in Fig. 7), optical filter 10 can be operated in visible mode, now adjust the gap between two high reflection film layers 13,
So that the light transmitted from optical filter 10 is visible ray, imaging modules 1000 can realize visual light imaging to obtain cromogram
Picture;Optical filter 10 can also be operated in infrared optical mode, now adjust the gap between two high reflection film layers 13 so that from filter
Light in being transmitted in mating plate 10 is infrared light, and imaging modules 1000 can realize infrared imaging to obtain infrared image.Further
Ground, if imaging modules 1000 are applied to be configured with the mobile device of iris identifying function, now mobile device only needs to set
Put an imaging modules 1000 i.e. can be achieved coloured image shooting and iris image shooting, so as to realize visual light imaging with
The multiplexing of infrared imaging, reduces the hardware cost of mobile device, while increases the free space of the screen of mobile device.
And it is in use, if the gap length d between two high reflection film layers 13 of Fabry-Perot intracavitary is not place
Locate equal, i.e. if two high reflection film layers 13 are not parallel to each other, the interference of the light of Fabry-Perot intracavitary can be by
Influence, and can not preferably transmit wavelength X=2d light, cause the filter effect of optical filter 10 bad.Parallel testing group
Whether part 14 can be used for two high reflection film layers 13 of detection parallel.Specifically, Parallel testing component 14 can be arranged on Fabry-
In Perot cavity, it can also be arranged on outside Fabry-Perot-type cavity.Parallel testing component 14 can be used for the preceding inspection that filters in optical filter 10
Whether parallel survey two high reflection film layers 13, and testing result is sent to drive component 15, testing result can include two
Whether high reflection film layer 13 is parallel, the gap of which position is less than it more than gap, the gap of which position of its peripheral location
The gap of peripheral location, the maximum difference in gap etc. of multiple positions.
Drive component 15 receives the testing result of Parallel testing component 14, if two high reflection film layers 13 are parallel, drives
Component 15 does not act, if two high reflection film layers 13 are not parallel, drive component 15 is according to above-mentioned testing result driving the
One eyeglass 11 or the second eyeglass 12 move, so that two high reflection film layers 13 are parallel, such as drive the first eyeglass 11 or the second mirror
The position maximum in gap of piece 12 be adjacent to each other, in the minimum position in gap away from each other etc..Drive component 15 can individually drive
Dynamic first eyeglass 11 moves, and the second eyeglass 12 can be operated alone and move, can also drive the first eyeglass 11 and the second mirror simultaneously
Piece 12 moves.
Fig. 1 and Fig. 2 are referred to, in some embodiments, Parallel testing component 14 includes at least three not with always
On line apart from detection unit 141, be used to detect the distance between two high reflection film layers 13 apart from detection unit 141.
First eyeglass 11 and the second eyeglass 12 can be with the shapes such as rounded, rectangle, ellipse, two high reflection film layers 13
It is parallel refer to two high reflection film layers 13 where plane it is parallel.At least three apart from detection unit 141 not in same straight line
On, the distance between at least three groups of points not on the same line for being used to detect high reflection film layer 13 apart from detection unit 141,
It is if equal two-by-two in the distance that at least three groups of points measure, then it represents that two high reflection film layers 13 are parallel;If surveyed at least three groups of points
The distance obtained is not equal two-by-two, then it represents that two high reflection film layers 13 are not parallel.
Fig. 1 and Fig. 2 are referred to, in some embodiments, each includes being separately positioned on two apart from detection unit 141
Pole plate 1411 in high reflection film layer 13, two pole plates 1411 are oppositely arranged to form electric capacity, are used for apart from detection unit 141
The size of electric capacity is detected to detect the distance between two high reflection film layers 13.
Pole plate 1411 can be made up of transparent conductive materials such as ITO (tin indium oxide), IZO (indium zinc oxide) not influence
In the light path of Fabry-Perot intracavitary, it is anti-with height that pole plate 1411 can be arranged on eyeglass (the first eyeglass 11 or the second eyeglass 12)
Penetrate between film layer 13.It is appreciated that forming electric capacity between two relative pole plates 1411, the distance of two pole plates 1411 changes
Afterwards, the capacitance of electric capacity also correspondingly changes, the size by detecting capacitance can further obtain two pole plates 1411 it
Between distance, that is, obtain the distance between two high reflection film layers 13.
Fig. 2 and Fig. 4 are referred to, in some embodiments, each includes the He of transmitter 1412 apart from detection unit 141
Receiver 1413.Transmitter 1412 and receiver 1413 are separately positioned on the first eyeglass 11 and the second eyeglass 12, transmitter
1412 are correspondingly arranged with receiver 1413, and transmitter 1412 is used to launch light or ultrasonic wave, and receiver 1413 is used for reception pair
The light or ultrasonic wave that the transmitter 1412 answered is launched.
Incorporated by reference to Fig. 2 and Fig. 4, in embodiments of the present invention, transmitter 1412 and receiver 1413 can may be contained within method
Outside Fabry-Perot-type cavity, to avoid having an impact the light path of Fabry-Perot intracavitary.Transmitter 1412 and receiver 1413 can
Can be specifically that transmitter 1412 is arranged on first to be separately positioned on the marginal position of the first eyeglass 11 and the second eyeglass 12
Eyeglass 11, and receiver 1413 is arranged on the second eyeglass 12;It can also be that transmitter 1412 is arranged on the second eyeglass 12, and receive
Device 1413 is arranged on the first eyeglass 11.Transmitter 1412 is used to launch light or ultrasonic wave, receiver 1413 to receiver 1413
For receiving the light or ultrasonic wave launched by corresponding transmitter 1412, light that receiver 1413 receives or ultrasonic wave
Intensity can be converted into electric signal, and the power of electric signal can be used for the power for characterizing light or ultrasonic wave, and further characterize two
The size in the gap between individual high reflection film layer 13, specifically, electric signal is more strong then to represent light or ultrasonic wave in communication process
In loss it is smaller, that is, the distance of two high reflection film layers 13 is smaller.
Fig. 2 and Fig. 5 are referred to, in some embodiments, each includes the He of transmitter 1412 apart from detection unit 141
Receiver 1413, transmitter 1412 and receiver 1413 are arranged on the first eyeglass 11 or the second eyeglass 12, transmitter 1412
Corresponding with receiver 1413, transmitter 1412 is used to launch light or ultrasonic wave, and receiver 1413 is used to receive reflected light
Line or the ultrasonic wave reflected.
Specifically, transmitter 1412 and receiver 1413 can may be contained within outside Fabry-Perot-type cavity, to avoid to method cloth
In-Perot cavity in light path have an impact.Transmitter 1412 and receiver 1413 can be arranged on the first eyeglass 11, also may be used
To be arranged on the second eyeglass 12.In the embodiment as shown in fig.5, transmitter 1412 and receiver 1413 are arranged at
On first eyeglass 11, transmitter 1412 launches light or ultrasonic wave, light or ultrasonic wave in the second eyeglass 12 to the second eyeglass 12
Upper to reflect, receiver 1413 receives reflected light line or the ultrasonic wave reflected, by the hair for detecting transmitter 1412
The time difference at moment and the time of reception of receiver 1413 is penetrated, light or ultrasonic wave can be obtained in the first eyeglass 11 and the second mirror
The stroke propagated between piece 12, and further obtain the size in the gap between two high reflection film layers 13 of the position.
Referring to Fig. 1, in some embodiments, optical filter 10 also includes pedestal 16, the second eyeglass 12 is fixedly installed on
On pedestal 16, optical filter 10 also includes eyeglass actuator 17, and eyeglass actuator 17 is used to drive the first eyeglass 11 relative to second
Eyeglass 12 moves, to change the size in the gap between the first eyeglass 11 and the second eyeglass 12.
Pedestal 16 can be as a part for the shell of optical filter 10, and pedestal 16 offers light-emitting window 161, light-emitting window 161
Corresponding with Fabry-Perot-type cavity, light can enter Fabry-Perot-type cavity from the first eyeglass 11, through Fabry-Perot-type cavity after from
Second eyeglass 12 appears, and further passs through light-emitting window 161 to pass optical filter 10.Eyeglass actuator 17 can be that MEMS is caused
One or more in dynamic device, magnetic deformation actuator, piezo-activator, eyeglass actuator 17 can be arranged on the first eyeglass 11
Between the second eyeglass 12, to drive the first eyeglass 11 to be moved relative to the second eyeglass 12 and change the first eyeglass 11 and second
The size in the gap between eyeglass 12, so as to realize that the tuning of light is filtered.
In one example, optical filter 10 can be operated under visible mode for visual light imaging, eyeglass actuating
Device 17 can drive the first eyeglass 11 to obtain the light of multiple color several times.Such as between eyeglass actuator 17 changes in three times
Gap, to be obtained across the light of the three of optical filter 10 kinds of different wave lengths, such as wavelength be 700 nanometers (i.e. feux rouges), 540 nanometers (i.e.
Green glow), the light of 460 nanometers (i.e. blue light), the light of these three colors can be used for follow-up imaging.Eyeglass actuator 17 also may be used
Change the gap of optical filter 10 in six times to be received respectively by wavelength as 700 nanometers, 740 nanometers, 510 nanometers, 550 nanometers, 460
Rice, 480 nanometers of light, wherein, the light that wavelength is 700 nanometers and 740 nanometers is feux rouges, and wavelength is 510 nanometers and 550 nanometers
Light be green glow, wavelength is that 460 nanometers and 480 nanometers of light is blue light.In this way, optical filter 10 not only can by feux rouges,
Green glow and blue light, feux rouges, green glow and blue light can be also layered respectively, to obtain more color informations, are advantageous to follow-up
Imaging so that the color of the image finally given is more true and abundant.
Referring to Fig. 1, in some embodiments, optical filter 10 also includes connector 18, connector 18 is connected to first
Between the eyeglass 12 of eyeglass 11 and second, the first eyeglass 11 is rotatablely connected with connector 18, and the second eyeglass 12 rotates with connector 18
Connection.Drive component 15 includes the electrostatic layer 151 and electrostatic actuator 152 being arranged on the first eyeglass 11.Electrostatic actuator 152
Electrostatic layer 151 can be driven to move, to drive the first eyeglass 11 to be moved relative to the second eyeglass 12.
Specifically, when high reflection film layer 13 is made of an electrically conducting material, high reflection film layer 13 can be used as electrostatic layer simultaneously
151;When high reflection film layer 13 is made up of insulating materials, electrostatic layer 151 can be arranged on the eyeglass of high reflection film layer 13 and first
Between 11.Electrostatic layer 151 can be connected with external power source, so that electrostatic layer 151 is selectively negatively charged or positive electricity.Electrostatic causes
Dynamic device 152 can also be arranged on pedestal 16, and electrostatic actuator 152 is connected with external power source, and external power source is used to cause electrostatic
Move device 152 selectively positively charged or negative electricity.According to the electric charge principle that identical charges repel each other, there is a natural attraction between the sexes, when needing driving first
When eyeglass 11 is away from the second eyeglass 12, control external power source makes electrostatic layer 151 electrical identical with electrostatic actuator 152,
When needing to drive the first eyeglass 11 close to the second eyeglass 12, control external power source makes electrostatic layer 151 and electrostatic actuator 152
It is electrical opposite.Electrostatic actuator 152 can be used for driving electrostatic layer 151 to move, and specifically, electrostatic actuator 152 is used for
Driving electrostatic layer 151 rotates around connector 18, and electrostatic layer 151 drives the first eyeglass 11 to be rotated around connector 18.
Fig. 1 and Fig. 2 are referred to, in some embodiments, the quantity of electrostatic actuator 152 is multiple, and multiple electrostatic cause
Dynamic device 152 is apart from one another by multiple electrostatic actuators 152 are set around the first eyeglass 11 and the second eyeglass 12, each electrostatically actuated
Device 152 can independently drive electrostatic layer 151 to move.
Specifically, multiple electrostatic actuators 152 can be equiangularly spaced along the circumference of the first eyeglass 11 and the second eyeglass 12
Set, can also be correspondingly arranged with multiple apart from detection unit 141, such as apart from detection unit 141 quantity be four, electrostatic
The quantity of actuator 152 also for four and respectively with four position correspondences apart from detection unit 141.Each electrostatic actuator
152 can according to corresponding one apart from detection unit 141 detect gap size driving electrostatic layer 151 move, without by
The influence of other electrostatic actuators 152, such as a gap that the position is obtained apart from the detection of detection unit 141 are less than other positions
During the gap put, it can control with this and be in apart from the corresponding electrostatic actuator 152 of detection unit 141 and the identical of electrostatic layer 151
Electrically, so that electrostatic layer 151 moves in the presence of Coulomb force, and the gap increase of the position is caused.
Referring to Fig. 1, in some embodiments, connector 18 is eyeglass actuator 17, eyeglass actuator 17 is used to drive
Dynamic first eyeglass 11 moves relative to the second eyeglass 12, to change the big of the gap between the first eyeglass 11 and the second eyeglass 12
It is small.
That is, eyeglass actuator 17 can be used as connector 18, and before optical filter 10 is used to filter, electrostatic actuator
152 are used to drive electrostatic layer 151 to rotate around eyeglass actuator 17 so that two high reflection film layers 13 are parallel to each other;In optical filter
10 for when filtering, eyeglass actuator 17 to can be used for the first eyeglass 11 of driving to be moved relative to the second eyeglass 12, to change first
The size in the gap between the eyeglass 12 of eyeglass 11 and second.
Referring to Fig. 3, in some embodiments, connector 18 includes eyeglass actuator 17 and elastic component 19.Eyeglass causes
Dynamic device 17 is used to drive the first eyeglass 11 to move relative to the second eyeglass 12, to change between the first eyeglass 11 and the second eyeglass 12
Gap size.Elastic component 19 is used for when drive component 15 drives the first eyeglass 11 to be moved relative to the second eyeglass 12
Deformation.
Before optical filter 10 is used to filter, sends a telegraph actuator 152 and be used to drive electrostatic layer 151 to rotate around elastic component 19,
Elastic component 19 deforms upon simultaneously so that two high reflection film layers 13 are parallel to each other;When optical filter 10 is used to filter, eyeglass causes
Dynamic device 17 can be used for the first eyeglass 11 of driving to be moved relative to the second eyeglass 12, to change the first eyeglass 11 and the second eyeglass 12
Between gap size.
Referring to Fig. 6, the camera lens module 100 of embodiment of the present invention includes microscope base 20, the lens barrel on microscope base 20
30 and above-mentioned any one embodiment in optical filter 10.Optical filter 10 is arranged in lens barrel 30 or microscope base 20.
Referring again to Fig. 6, in some embodiments, camera lens module 100 is also included to focus lens 40, to focus lens 40 with
Optical filter 10 is located in same light path.Specifically, focus lens 40 are arranged in lens barrel 30, optical filter 10 can be arranged on lens barrel
30 or microscope base 20 in.When optical filter 10 is located in microscope base 20, focus lens 40 are arranged on the top of optical filter 10, i.e. lens barrel
In 30.When in the lens barrel 30 of optical filter 10, focus lens 40 may be provided above or below optical filter 10, in other words,
When optical filter 10 is located in lens barrel 30, extraneous light can successively by optical filter 10 and to focus lens 40, or successively by pair
Focus lens 40 and optical filter 10.
Quantity to focus lens 40 can be multiple, and camera lens module 100 can be zoom lens.Specifically, camera lens module
100 also include focus drive 50, multiple that focus lens 40 are connected with focus drive 50, the driving focusing of focus drive 50
Eyeglass 40 is moved to change the focusing focal length of camera lens module 100.Certainly, camera lens module 100 can also be tight shot, i.e. right
Focus lens 40 are irremovable in lens barrel 30 to be fixed on.
Referring to Fig. 7, the imaging modules 1000 of embodiment of the present invention include substrate 300, the figure of setting on the substrate 300
As sensor 200 and the camera lens module 100 of any of the above-described embodiment.Camera lens module 100 is fixed on the substrate 300.Image passes
Sensor 200 is housed in camera lens module 100.
Imaging sensor 200 receives by the light of optical filter 10 and generates corresponding electric signal output, by with imaging modules
The processor of 1000 connections carries out signal transacting to obtain shooting image.When optical filter 10 is operated under visible mode, figure
As sensor 200 receives the visible ray (such as feux rouges, green glow and blue light) through a variety of different wave lengths of optical filter 10 and divides more
The secondary corresponding electric signal of output, processor carry out signal transacting and can obtain coloured image.When optical filter 10 is operated in infrared light
When under pattern, imaging sensor 200 receives the infrared light through a variety of different wave lengths of optical filter 10 and exports corresponding telecommunications
Number, processor carries out signal transacting and can obtain infrared image.
Referring to Fig. 7, in some embodiments, imaging modules 1000 also include optical filtering part 400, optical filtering part 400 is set
In light path between imaging sensor 200 and optical filter 10, optical filtering part 400 is used for optionally by visible ray or infrared
Light.
It is appreciated that the Fabry-Perot interference chamber formed in optical filter 10 between first eyeglass 11 and the second eyeglass 12
The light of predefined type, by taking infrared light as an example, now transmission of the optical filter 10 for infrared light can only be passed through under ideal conditions
The ratio that rate accounts for actual incident light may be up to 99%, and the accounting of the transmissivity of the light of other wavelength is almost nil, now red
The boundary position of the wavelength of outer light, the perpendicular downward trend of accounting of the transmissivity of optical filter 10.But in practical operation,
The boundary position of the wavelength of infrared light, the accounting of the transmissivity of optical filter 10 are that have certain decline process.In other words, this
When optical filter 10 can not only pass through infrared light, moreover it is possible to marginally pass through the light of other wavelength in addition to infrared light.Similarly, exist
In practical operation, optical filter 10 is when largely passing through visible ray, moreover it is possible to marginally passes through other wavelength in addition to visible ray
Light.Therefore,, can be in imaging mould to obtain more preferable image quality to make the light that imaging sensor 200 receives more accurate
An optical filtering part 400 is set selectively to filter out except visible or infrared light in group 1000.
Referring again to Fig. 7, in some embodiments, mounting hole 22 is offered on lens barrel 30 or microscope base 20, light passes through
Mounting hole 22 is passed through after optical filter 10, with further to imaging sensor 200.Optical filtering part 400 is movably mounted to mounting hole
In 22.Imaging modules 1000 also include actuator 500.Actuator 500 is used to drive optical filtering part 400 to move to open or block peace
Fill hole 22.
Actuator 500 includes stator 502 and rotor 504.Stator 502 is arranged on the inwall of lens barrel 30 or microscope base 20.Filter
One end of light part 400 is set on rotor 504.Rotor 504, which rotates, drives optical filtering part 400 to rotate to open or block mounting hole
22。
Specifically, when mounting hole 22 is opened on lens barrel 30, actuator 500 is correspondingly disposed on lens barrel 30, stator 502
Also it is correspondingly disposed on lens barrel 30;When mounting hole 22 is opened on microscope base 20, actuator 500 is correspondingly disposed in microscope base 20
On, stator 502 is also correspondingly disposed on microscope base 20.
In one example, it is necessary to when imaging sensor 200 is used for into visual light imaging, if optical filtering part 400 is infrared section
Only optical filter (being only used for by the light outside infrared light), when optical filter 10 is in visible mode (only passing through visible ray), drive
Moving part 500 can be used for driving optical filtering part 400 to block or open mounting hole 22;If optical filtering part 400 (is only used to be infrared by optical filter
In passing through infrared light), when optical filter 10 is in visible mode, actuator 500 can be used for driving optical filtering part 400 to open mounting hole
22。
In another example, it is necessary to when imaging sensor 200 is used for into infrared imaging, if optical filtering part 400 is infrared
Edge filter, when optical filter 10 is in infrared optical mode (only passing through infrared light), actuator 500 can be used for driving optical filtering part
400 open mounting hole 22;If optical filtering part 400 passes through optical filter, when optical filter 10 is in infrared optical mode, actuator to be infrared
500 can be used for driving optical filtering part 400 to block or open mounting hole 22.
Incorporated by reference to Fig. 7 and Fig. 8, in some embodiments, optical filtering part 400 includes visible ray optical filtering portion 402 and infrared light
Optical filtering portion 404.Imaging modules 1000 also include actuator 500, and actuator 500 is used to switching visible ray optical filtering portion 402 and infrared
In a light path between imaging sensor 200 and optical filter 10 among light optical filtering portion 404.
Specifically, in some embodiments, actuator 500 includes stator 502 and rotor 504, and stator 502 is arranged on mirror
On the inwall of cylinder 30 or microscope base 20, it is seen that light optical filtering portion 402 and infrared light optical filtering portion 404 are fixedly connected with rotor 504.Rotor
504 can rotate, to drive one among visible ray optical filtering portion 402 and infrared light optical filtering portion 404 to turn to imaging sensor
In light path between 200 and optical filter 10.
Visible ray optical filtering portion 402 is used to pass through visible ray, and filters out the light of its all band.Infrared light optical filtering portion 404
For by infrared light, and filter out the light of its all band.
When optical filter 10 is in visible mode, actuator 500 drives visible ray optical filtering portion 402 to turn to image sensing
In light path between device 200 and optical filter 10, specifically, mounting hole 22 is blocked in now visible ray optical filtering portion 402.Work as optical filter
10 when being in infrared optical mode, and actuator 500 drives infrared light optical filtering portion 404 to turn to imaging sensor 200 and optical filter 10
Between light path on, specifically, mounting hole 22 is blocked in now infrared light optical filtering portion 404.Referring to Fig. 8, in the embodiment of the present invention
In, it is seen that the angle α between light optical filtering portion 402 and infrared light optical filtering portion 404 is more than or equal to 90 degree.So that proper visible ray filter
When mounting hole 22 is blocked in light portion 402 completely, the completely open mounting hole 22 in infrared light optical filtering portion 404, similarly, when infrared light optical filtering portion
404 when blocking mounting hole 22 completely, it is seen that the completely open mounting hole 22 in light optical filtering portion 402.
In the description of this specification, reference term " some embodiments ", " embodiment ", " some embodiment party
The description of formula ", " exemplary embodiment ", " example ", " specific example " or " some examples " means with reference to the embodiment
Or specific features, structure, material or the feature of example description are contained at least one embodiment or example of the present invention.
In this manual, identical embodiment or example are not necessarily referring to the schematic representation of above-mentioned term.Moreover, description
Specific features, structure, material or feature can be in any one or more embodiments or example with suitable side
Formula combines.
In addition, term " first ", " second " are only used for describing purpose, and it is not intended that instruction or hint relative importance
Or the implicit quantity for indicating indicated technical characteristic.Thus, define " first ", the feature of " second " can be expressed or
Implicitly include at least one feature.In the description of the invention, " multiple " are meant that at least two, such as two,
Three, unless otherwise specifically defined.
Although embodiments of the invention have been shown and described above, it is to be understood that above-described embodiment is example
Property, it is impossible to limitation of the present invention is interpreted as, one of ordinary skill in the art within the scope of the invention can be to above-mentioned
Embodiment is changed, changed, replacing and modification, the scope of the present invention are limited by claim and its equivalent.
Claims (15)
- A kind of 1. optical filter, it is characterised in that including:It is spaced the first eyeglass and the second eyeglass that are oppositely arranged, first eyeglass and relative two surfaces of second eyeglass On be provided with high reflection film layer;Parallel testing component, whether the Parallel testing component is used for two high reflection film layers of detection parallel;WithDrive component, the drive component are used to drive first eyeglass or described the when the high reflection film layer is not parallel Two lens movements are so that two high reflection film layers are parallel.
- 2. optical filter according to claim 1, it is characterised in that the Parallel testing component includes at least three not same On one straight line apart from detection unit, it is described to be used to detect the distance between two described high reflection film layers apart from detection unit.
- 3. optical filter according to claim 2, it is characterised in that each described to include being separately positioned on apart from detection unit Pole plate in two high reflection film layers, two pole plates are oppositely arranged to form electric capacity, described to be used apart from detection unit In the size for detecting the electric capacity to detect the distance between two described high reflection film layers.
- 4. optical filter according to claim 2, it is characterised in that each described to include transmitter apart from detection unit and connect Device is received, the transmitter and the receiver are separately positioned on first eyeglass and second eyeglass, the transmitter It is correspondingly arranged with the receiver, the transmitter is used to launch light or ultrasonic wave, and the receiver is corresponding for receiving The light or ultrasonic wave of the transmitter transmitting;OrEach described to include transmitter and receiver apart from detection unit, the transmitter and the receiver are arranged at described On first eyeglass or second eyeglass, the transmitter is corresponding with the receiver, the transmitter be used for launch light or Ultrasonic wave, the receiver are used to receive the light reflected or the ultrasonic wave reflected.
- 5. optical filter according to claim 1, it is characterised in that the optical filter also includes pedestal, second eyeglass It is fixedly installed on the pedestal, the optical filter also includes eyeglass actuator, and the eyeglass actuator is used to driving described the One eyeglass is relative to second lens movement, to change the big of the gap between first eyeglass and second eyeglass It is small.
- 6. optical filter according to claim 1, it is characterised in that the optical filter also includes connector, the connector It is connected between first eyeglass and second eyeglass, first eyeglass and the connector are rotatablely connected, and described the Two eyeglasses are rotatablely connected with the connector, and the drive component includes:The electrostatic layer being arranged on first eyeglass;WithElectrostatic actuator, the electrostatic actuator can drive the electrostatic layer to move, with drive first eyeglass relative to Second lens movement.
- 7. optical filter according to claim 6, it is characterised in that the connector is eyeglass actuator, and the eyeglass causes Dynamic device is used to drive first eyeglass relative to second lens movement, to change first eyeglass and second mirror The size in the gap between piece.
- 8. optical filter according to claim 6, it is characterised in that the connector includes eyeglass actuator and elastic component, The eyeglass actuator is used to drive first eyeglass relative to second lens movement, with change first eyeglass with The size in the gap between second eyeglass, the elastic component are used to drive first eyeglass relative in the drive component Deformed upon when second lens movement.
- 9. optical filter according to claim 6, it is characterised in that the quantity of the electrostatic actuator is multiple, Duo Gesuo Electrostatic actuator is stated apart from one another by and being set around first eyeglass and second eyeglass, each electrostatic actuator The electrostatic layer can be independently driven to move.
- A kind of 10. camera lens module, it is characterised in that including:Microscope base;Lens barrel on the microscope base;WithOptical filter described in claim 1-9 any one, the optical filter are arranged in the lens barrel or the microscope base.
- 11. camera lens module according to claim 10, it is characterised in that the camera lens module also includes being arranged on the mirror In cylinder to focus lens, it is described that focus lens and the optical filter are located in same light path.
- A kind of 12. imaging modules, it is characterised in that including:Substrate;Imaging sensor on the substrate is set;WithCamera lens module described in claim 10 or 11, the camera lens module are fixed on the substrate, described image sensor It is housed in the camera lens module.
- 13. imaging modules according to claim 12, it is characterised in that the imaging modules also include optical filtering part, described Optical filtering part is arranged in the light path between described image sensor and the optical filter, the optical filtering part be used for optionally by Visible or infrared light.
- 14. imaging modules according to claim 13, it is characterised in that the optical filtering part includes visible ray optical filtering portion and red Outer light optical filtering portion, the imaging modules also include actuator, and the actuator is used to switching the visible ray optical filtering portion and described In a light path between described image sensor and the optical filter among infrared light optical filtering portion.
- 15. imaging modules according to claim 14, it is characterised in that the actuator includes stator and rotor, described Stator is arranged on the inwall of the lens barrel or the microscope base, and the visible ray optical filtering portion and the infrared light optical filtering portion are and institute State rotor to be fixedly connected, the rotor can rotate, to drive among the visible ray optical filtering portion and the infrared light optical filtering portion One turn in the light path between described image sensor and the optical filter.
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CN201710915380.5A CN107703595A (en) | 2017-09-30 | 2017-09-30 | Optical filter, camera lens module and imaging modules |
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CN201710915380.5A CN107703595A (en) | 2017-09-30 | 2017-09-30 | Optical filter, camera lens module and imaging modules |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111919097A (en) * | 2019-09-04 | 2020-11-10 | 深圳市海谱纳米光学科技有限公司 | Optical lens and optical equipment |
CN111936907A (en) * | 2019-09-04 | 2020-11-13 | 深圳市海谱纳米光学科技有限公司 | Optical lens and optical equipment |
CN112492169A (en) * | 2020-12-02 | 2021-03-12 | 维沃移动通信有限公司 | Camera module and electronic equipment |
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CN105045292A (en) * | 2014-05-01 | 2015-11-11 | 精工爱普生株式会社 | Actuator apparatus, electronic device, and control method |
CN106707499A (en) * | 2016-11-21 | 2017-05-24 | 苏州大学 | Capacitive-feedback-type tunable Fabry-Perot filter |
CN107153314A (en) * | 2017-06-30 | 2017-09-12 | 广东欧珀移动通信有限公司 | Camera lens module, camera module and electronic installation |
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CN105045292A (en) * | 2014-05-01 | 2015-11-11 | 精工爱普生株式会社 | Actuator apparatus, electronic device, and control method |
CN106707499A (en) * | 2016-11-21 | 2017-05-24 | 苏州大学 | Capacitive-feedback-type tunable Fabry-Perot filter |
CN107153314A (en) * | 2017-06-30 | 2017-09-12 | 广东欧珀移动通信有限公司 | Camera lens module, camera module and electronic installation |
Cited By (6)
Publication number | Priority date | Publication date | Assignee | Title |
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CN111919097A (en) * | 2019-09-04 | 2020-11-10 | 深圳市海谱纳米光学科技有限公司 | Optical lens and optical equipment |
CN111936907A (en) * | 2019-09-04 | 2020-11-13 | 深圳市海谱纳米光学科技有限公司 | Optical lens and optical equipment |
CN111936907B (en) * | 2019-09-04 | 2021-11-23 | 深圳市海谱纳米光学科技有限公司 | Optical lens and optical equipment |
CN111919097B (en) * | 2019-09-04 | 2022-08-05 | 深圳市海谱纳米光学科技有限公司 | Optical lens and optical equipment |
CN112492169A (en) * | 2020-12-02 | 2021-03-12 | 维沃移动通信有限公司 | Camera module and electronic equipment |
CN112492169B (en) * | 2020-12-02 | 2022-04-29 | 维沃移动通信有限公司 | Camera module and electronic equipment |
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Application publication date: 20180216 |