CN110088673A - A kind of optical film layer structure, backlight module, display device and electronic equipment - Google Patents
A kind of optical film layer structure, backlight module, display device and electronic equipment Download PDFInfo
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- CN110088673A CN110088673A CN201980000378.2A CN201980000378A CN110088673A CN 110088673 A CN110088673 A CN 110088673A CN 201980000378 A CN201980000378 A CN 201980000378A CN 110088673 A CN110088673 A CN 110088673A
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- film layer
- transmittance section
- optical film
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- layer structure
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- G—PHYSICS
- G02—OPTICS
- G02F—OPTICAL DEVICES OR ARRANGEMENTS FOR THE CONTROL OF LIGHT BY MODIFICATION OF THE OPTICAL PROPERTIES OF THE MEDIA OF THE ELEMENTS INVOLVED THEREIN; NON-LINEAR OPTICS; FREQUENCY-CHANGING OF LIGHT; OPTICAL LOGIC ELEMENTS; OPTICAL ANALOGUE/DIGITAL CONVERTERS
- G02F1/00—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics
- G02F1/01—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the intensity, phase, polarisation or colour
- G02F1/13—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the intensity, phase, polarisation or colour based on liquid crystals, e.g. single liquid crystal display cells
- G02F1/133—Constructional arrangements; Operation of liquid crystal cells; Circuit arrangements
- G02F1/1333—Constructional arrangements; Manufacturing methods
- G02F1/1335—Structural association of cells with optical devices, e.g. polarisers or reflectors
- G02F1/1336—Illuminating devices
- G02F1/133602—Direct backlight
- G02F1/133605—Direct backlight including specially adapted reflectors
-
- G—PHYSICS
- G02—OPTICS
- G02F—OPTICAL DEVICES OR ARRANGEMENTS FOR THE CONTROL OF LIGHT BY MODIFICATION OF THE OPTICAL PROPERTIES OF THE MEDIA OF THE ELEMENTS INVOLVED THEREIN; NON-LINEAR OPTICS; FREQUENCY-CHANGING OF LIGHT; OPTICAL LOGIC ELEMENTS; OPTICAL ANALOGUE/DIGITAL CONVERTERS
- G02F1/00—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics
- G02F1/01—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the intensity, phase, polarisation or colour
- G02F1/13—Devices or arrangements for the control of the intensity, colour, phase, polarisation or direction of light arriving from an independent light source, e.g. switching, gating or modulating; Non-linear optics for the control of the intensity, phase, polarisation or colour based on liquid crystals, e.g. single liquid crystal display cells
- G02F1/133—Constructional arrangements; Operation of liquid crystal cells; Circuit arrangements
- G02F1/1333—Constructional arrangements; Manufacturing methods
- G02F1/1335—Structural association of cells with optical devices, e.g. polarisers or reflectors
- G02F1/1336—Illuminating devices
- G02F1/133602—Direct backlight
- G02F1/133606—Direct backlight including a specially adapted diffusing, scattering or light controlling members
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- Physics & Mathematics (AREA)
- Nonlinear Science (AREA)
- Mathematical Physics (AREA)
- Chemical & Material Sciences (AREA)
- Crystallography & Structural Chemistry (AREA)
- General Physics & Mathematics (AREA)
- Optics & Photonics (AREA)
- Devices For Indicating Variable Information By Combining Individual Elements (AREA)
- Planar Illumination Modules (AREA)
Abstract
This application provides a kind of optical film layer structures, for assembling backlight light and through detection light.The optical film layer structure includes one or more film layer units.The film layer unit includes the first optical surface and the second optical surface being oppositely arranged.First optical surface is non-planar, first optical surface includes the first plane, second optical surface includes the second plane, it first plane and second plane parallel and is oppositely arranged, defining first plane is the first transmittance section, first optical surface further includes the second transmittance section, when detection light penetrates the film layer unit by parallel and first transmittance section being oppositely arranged and the second plane, the direction of propagation that at least there is part detection light is constant, it is assembled when backlight light is incident to the film layer unit and projects from second transmittance section.In addition, the application also provides a kind of backlight module, display device and electronic equipment including above-mentioned optical film layer structure.
Description
Technical field
The application belong to optical technical field more particularly to a kind of optical film layer structure, backlight module, display device and
Electronic equipment.
Background technique
In the prior art, in order to increase the backlight illumination of liquid crystal display, optical film layer is usually set in backlight module,
Such as: brightness enhancement film (Brightness Enhancement Film, BEF), prismatic lens etc..Currently, the optical film layer includes saturating
The micro-structure of photopolymer substrate and the strip triangular prism formed on the transparent substrates.The micro-structure of the strip triangular prism that
This is closely arranged on the transparent substrates without interval.When the backlight light from the backlight module is incident to the film layer list
When first, the micro-structure of the strip triangular prism is for concentrating backlight light at random.
Although however, the micro-structure of such strip triangular prism for the backlight light have it is stronger gather effect,
It is but to have stronger disperse function for being reflected back into the detection light of liquid crystal display from external object, makes it can not be
Focal imaging below backlight module.Therefore it is each to realize to be unable to satisfy current needs setting sensing mould group below liquid crystal display
Kind shields the optical path requirements of lower sensing function.
Summary of the invention
In order to solve the above technical problems, the application provides the new-type optical film layer structure of one kind, backlight module, display device
And electronic equipment.
The application provides a kind of optical film layer structure, for assembling backlight light and through detection light, the optics
Film layer structure includes one or more film layer units, and the film layer unit includes the first optical surface and the second light being oppositely arranged
Learn surface, wherein first optical surface be it is non-planar, first optical surface include the first plane, second light
Learning surface includes the second plane, first plane and second plane parallel and is oppositely arranged, and definition described first is flat
Face is the first transmittance section, and first optical surface further includes the second transmittance section, when detection light passes through parallel and is oppositely arranged
First transmittance section and the second plane and penetrate the film layer unit when, at least exist part detect light the direction of propagation
It is constant, it is assembled when backlight light is incident to the film layer unit and projects from second transmittance section.
The application also provides a kind of backlight module, including described in any item optical film layer structures, the optics among the above
The diffusion sheet and reflector plate that film layer structure is stacked, the diffusion sheet and the optical film layer structure are located on the reflector plate
Side, the diffusion sheet are quantum dot film, and the reflector plate is made of the material for reflecting visible light through infrared or near infrared light.
The application also provides a kind of liquid crystal display device, including display panel and backlight module, and the display panel is used for
Show picture, the backlight module is for providing backlight light to the display panel, wherein the backlight module is among the above
Backlight module described in any one.
The application also provides a kind of electronic equipment, including any liquid crystal display device among the above and at least partly sets
Set the sensing mould group below the liquid crystal display device, display area and back of the sensing mould group through the display panel
Optical mode group receives the detection light for reflecting or/and emitting from external object, to execute corresponding sensing.
Since the optical film layer structure of the application assemble to backlight light and detection light is penetrated, and at least existed
Part detection light shifts in the constant, position through the direction of propagation after the optical film layer structure, therefore, positioned at including
Sensing mould group below the backlight module of the optical film layer structure is obtained according to the constant detection light in this part direction of propagation
The associated sensed data obtained are more accurate.Correspondingly, the better user experience of the electronic equipment.
Further, micro- knot is set by the microstructure aspects or/and interval for changing the film layer unit due to the application
Structure realizes that backlight light and detection the two-way of light penetrate under the premise of backlight module not aperture, is conducive to do not influencing to show
Realize that the lower sensing of screen is promoted so as to further increase the screen accounting of electronic equipment under the premise of the display effect of showing device
The visual experience of electronic equipment.
The additional aspect and advantage of the application embodiment will be set forth in part in the description, partially will be from following
Become obvious in description, or is recognized by the practice of the application embodiment.
Detailed description of the invention
Fig. 1 is the front schematic view for the electronic equipment that the application first embodiment provides.
Fig. 2 is the partial structure diagram of electronic equipment shown in Fig. 1.
Fig. 3 is the front schematic view for the electronic equipment that the application second embodiment provides.
Fig. 4 is the partial structure diagram of electronic equipment shown in Fig. 3.
Fig. 5 is the structural schematic diagram for the backlight module that the application third embodiment provides.
Fig. 6 is the structural schematic diagram for the backlight module that the 4th embodiment of the application provides.
Fig. 7 is the structural schematic diagram for the optical film layer structure that the 5th embodiment of the application provides.
Fig. 8 is index path when backlight light passes through the first film layer unit shown in fig. 7 with detection light.
Fig. 9 is the correspondence diagram of display pixel point and optical film layer structure 5.
Figure 10 is the first film layer unit shown in Fig. 7 along the cross-sectional view of IX-IX '.
Figure 11 is the structural schematic diagram for the optical film layer structure that the application sixth embodiment provides.
Figure 12 is the structural schematic diagram for the optical film layer structure that the 7th embodiment of the application provides.
Figure 13 is the structural schematic diagram for the optical film layer structure that the 8th embodiment of the application provides.
Figure 14 is the structural schematic diagram for the optical film layer structure that the 9th embodiment of the application provides.
Figure 15 is index path when backlight light passes through the first film layer unit shown in Figure 14 with detection light.
Figure 16 is the first film layer unit shown in Figure 14 along the cross-sectional view of XV-XV '.
Figure 17 is the structural schematic diagram for the optical film layer structure that the tenth embodiment of the application provides.
Figure 18 is the structural schematic diagram for the optical film layer structure that the 11st embodiment of the application provides.
Figure 19 is the structural schematic diagram for the optical film layer structure that the 12nd embodiment of the application provides.
Figure 20 is the structural schematic diagram for the optical film layer structure that the 13rd embodiment of the application provides.
Figure 21 is the structural schematic diagram for the optical film layer structure that the 14th embodiment of the application provides.
Figure 22 is the structural schematic diagram for the optical film layer structure that the 15th embodiment of the application provides.
Specific embodiment
Presently filed embodiment is described below in detail, the example of the embodiment is shown in the accompanying drawings, wherein from beginning
Same or similar element or element with the same or similar functions are indicated to same or similar label eventually.Below by ginseng
The embodiment for examining attached drawing description is exemplary, and is only used for explaining the application, and should not be understood as the limitation to the application.?
In the description of the present application, it is to be understood that term " first ", " second " are only used for describing, and should not be understood as instruction or dark
Show relative importance or implicitly indicates the quantity of indicated technical characteristic or put in order.Define as a result, " first ",
The technical characteristic of " second " can explicitly or implicitly include one or more technical characteristic.In retouching for the application
In stating, the meaning of " plurality " is two or more, unless otherwise specifically defined.
In the description of the present application, it should be noted that unless otherwise specific regulation or limit, term " installation ", " phase
Even ", " connection " shall be understood in a broad sense, for example, it may be being fixedly connected, may be a detachable connection, or integration connection;It can
To be mechanical connection, it is also possible to be electrically connected or is in communication with each other;It can be directly connected, the indirect phase of intermediary can also be passed through
Even, the connection inside two elements or the interaction relationship between two elements be can be.For the ordinary skill of this field
For personnel, the concrete meaning of above-mentioned term in this application can be understood as the case may be.
Following disclosure provides many different embodiments or example is used to realize the different structure of the application.In order to
Simplify disclosure herein, hereafter only to the component of specific examples and being set for describing.Certainly, they are merely examples, and
And purpose does not lie in limitation the application.
In addition, the application can reuse reference number and/or reference letter, this reuse in different examples
It is itself not indicated between the various embodiments discussed and/or setting to simplify and clearly state the application
Particular kind of relationship.In addition, provided various specific techniques and material are only to realize the application skill to the application in the following description
The example of art scheme, but those of ordinary skill in the art should be aware that the technical solution of the application can also be by hereafter not
Other techniques and/or other materials of description are realized.
Further, described feature, structure can be incorporated in one or more embodiment party in any suitable manner
In formula.In the following description, many details are provided so as to fully understand presently filed embodiment.However, this
Field technical staff will be appreciated that even if without one or more in the specific detail, or using other structures, group
Member etc. can also practice the technical solution of the application.In other cases, it is not shown in detail or describes known features or operation
To avoid the emphasis of fuzzy the application.
Also referring to Fig. 1 and Fig. 2, the application first embodiment provides a kind of electronic equipment 1.The electronic equipment 1
Such as, but not limited to mobile phone, laptop, tablet computer, e-book, personal digital assistant, touch-control interactive terminal
Deng.The electronic equipment 1 includes memory 12, processor 14, display device 3 and is at least partially disposed in the display dress
Set the sensing mould group 10 at 3 back sides.
The display device 3 includes display panel 30 and the backlight module 4 positioned at 30 lower section of display panel.It is described aobvious
Show panel 30 for showing picture.The backlight module 4 is used to provide backlight light for the display panel 30.From the backlight
The backlight light that mould group 4 is emitted to the display panel 30 is visible light.The region for defining the display of display device 3 picture is
Display area, and the region except display area is non-display area.In the present embodiment, the display panel 30 is, for example,
Liquid crystal display panel.So, ground is changed, the display panel 30 can also be the display panel of other suitable types, such as electronics
Paper display panel.
The sensing mould group 10 is at least partially disposed at the lower section of the backlight module 4, and display area described in face is arranged.
The sensing mould group 10 is used to receive the detection light for being emitted or/and being reflected by external object itself, and is received according to described
Detection light realize corresponding sensing.For example, the sensing mould group 10 is received through the display panel 30 and backlight module 4
The detection light.The external object be such as, but not limited to user's finger, user's face or other suitable positions, again or
The other suitable objects of person and be not limited to human body etc..
Optionally, the sensing mould group 10 is further used for transmitting detection light to the external object.For example, the biography
Sense mould group 10 emits the detection light to external object through the display panel 30 and backlight module 4.
The sensing mould group 10 is such as, but not limited to for executing biological information according to the detection light received
Sensing, two-dimentional and/or 3-D image sensing, 3 D stereo modeling, distance sensing etc..Wherein, the biological information sensing
For example including but be not limited to finger print information sensing, three dimensional face information sensing, biological information sensing etc..
In the present embodiment, the sensing mould group 10 emits detection light through the display panel 30 and backlight module 4
Line is received through the display panel 30 and backlight module 4 and emits from external object itself or/and reflect to external object
Detection light.So, ground is changed, the sensing mould group 10 can also be not through display device 3 or through the display device 3
Subelement transmitting detection light is to external object, and the sensing mould group 10 the transmission display panel 30 and backlight module 4
Receive the detection light for emitting from external object itself or/and reflecting.Alternatively, the sensing mould group 10 penetrates the display surface
Plate 30 and the transmitting detection light of backlight module 4 are to external object, and the sensing mould group 10 is not through the display device 3 or saturating
The subelement for crossing the display device 3 receives the detection light for emitting from external object itself or/and reflecting.
It should be noted that the structure setting of the sensing mould group 10 is not limited to shown in illustrations, can also be
Various other suitable constructions.
The memory 12 is such as, but not limited to the biological information template for prestoring one or more samples.Again
For example, the memory 12 is used to store data, the journey relevant to sensing that the sensing mould group 10 generates during the sensing process
Sequence implements data required for sensing correlation function.The processor 14 is used to believe the sensing that the sensing mould group 10 obtains
Breath performs corresponding processing, and is stored in the biological information and memory 12 that the sensing mould group 10 obtains for example, comparing
Biological information template, according to comparison result realize to the external object carry out identification.For another example the processing
Device 14 can be used for executing program relevant to sensing.The electronic equipment 1 can according to it is described sensing mould group 10 sensing result or/
It is corresponding with the processing result of the processor 14 to execute relevant function, such as: extinguish screen, removing screen locking, pays, steps on
Land account, into next stage menu, open permission etc..
In the present embodiment, the memory 12 and processor 14 are in the electronic equipment 1 independently of sensing mould group
The component of 10 settings.So, ground is changed, may alternatively be integrated within institute some or all of in the memory 12 or/and processor 14
It states in sensing mould group 10.
The sensing mould group 10 includes receiving unit 103.The receiving unit 103 is located at the lower section of the backlight module 4,
And display area described in face, it is used to receive through the display panel 30 and backlight module 4 by described external object itself
Transmitting or/and reflected detection light, and realized according to the detection light received to the corresponding of the external object
Sensing.
Optionally, the receiving unit 103 includes camera lens 104 and the imaging sensor positioned at 104 lower section of camera lens
106.The display panel 30 and backlight module are penetrated by described external object transmitting itself or/and reflected detection light
It is received by the camera lens 104 by described image sensor 106 after 4.Described image sensor 106 is for example according to the detection light
Line obtains the image or associated sensed data of the external object, to realize corresponding sensing.So, in certain embodiments
In, the camera lens 104 also can be omitted or be replaced by other elements, such as be replaced by beam collimation element.
In the present embodiment, the sensing mould group 10 further comprises transmitting unit 102.The transmitting unit 102 is set
It sets below the backlight module 4.The transmitting unit 102 is through the backlight module 4 and the transmitting inspection of the display panel 30
Light is surveyed to the external object.
Optionally, the transmitting unit 102 includes sensing light source.The detection light that the sensing light source 102 issues penetrates
It turns back, is again passed through after display device 3 described in the receiving unit 103 after being reflected by external object after display device 3
It receives, carries out identification such as, but not limited to therefrom to extract the correlated characteristic data of the external object.
According to sensing principle and application scenarios, the detection light has specific wavelength.In the present embodiment, described
Detection light can be used for, but be not limited to, and sense the 3-D image of fingerprint or face, can be infrared or near infrared light,
Wave-length coverage is 800nm to 1650nm.Ground is changed, in other embodiments, the detection light can also be other suitable
Detection signal, such as ultraviolet light, ultrasonic wave, electromagnetic wave etc..
Also referring to Fig. 3 and Fig. 4, the application second embodiment provides a kind of electronic equipment 2, implements with first
The structure for the electronic equipment 1 that mode provides is roughly the same, and the two main distinction is: the transmitting unit of the sensing mould group 20
202 the back side of the display device 3 is not arranged in, but the outside of the display area of the display device 3, example is arranged in
As but be not limited to be arranged in the other of the side of the display panel 30 or the side of backlight module 4 or electronic equipment 1
Suitable position etc..The detection light that the transmitting unit 202 is issued is not needed through the display device 3 or through display dress
It is incident upon in external object after setting 3 subelement, the transmission power for being applicable to require the transmitting unit 202 is arranged such
Higher scene, such as, but not limited to: the transmitting unit 202, which needs to project, has the hot spot of predetermined pattern in external object
On, to realize the sensing of three-dimensional surface.
In the present embodiment, the top front center position of electronic equipment 2 is arranged in the transmitting unit 202, penetrates
Cover sheet (the not indicating) transmitting of electronic equipment 2 detects light beam to external object.The receiving unit 203 of the sensing mould group 20
The lower section of the backlight module 4 is set, for being emitted through the display device 3 reception by external object itself or/and instead
The detection light penetrated.
It should be noted that mainly penetrating the display surface in each embodiment of the application with the sensing mould group 10 or 20
Plate 30 and backlight module 4 are received to be illustrated by external object transmitting itself or/and reflected detection light, but the application
Not as limitation.Such as sensing mould group 20, the transmitting unit 202 of the either described sensing mould group 20 and reception are single
In member 203 any one or both be both placed in 4 lower section of the backlight module, the protection scope of the application should all be fallen into.
Referring to Fig. 5, the application third embodiment provides a kind of backlight module that can be used in above-mentioned display device 3
4.The backlight module 4 can be used for gathering the backlight light being emitted to the display panel 30 and for penetrating the detection light
Line provides backlight with satisfaction simultaneously for display panel 30 and wanting for the sensing mould group 10 or 20 is arranged below display device 3
It asks.The backlight module 4 includes back light 40, light guide plate 42, reflector plate 44, diffusion sheet 46 and optical film layer structure 5.
The light guide plate 42 include light-emitting surface 420, the bottom surface 422 opposite with the light-emitting surface 420 and described in connect out
Incidence surface 424 between smooth surface 420 and bottom surface 422.The corresponding incidence surface 424 of the back light 40 is arranged, for providing
Backlight light is to light guide plate 42.The backlight light projects after mixing in light guide plate 42 from light-emitting surface 420.The reflector plate 44
It is arranged on the bottom surface 422 of light guide plate 42, for will be reflected back in light guide plate 42 from the backlight light that light guide plate 42 releases, to mention
The utilization rate of high backlight light.The reflector plate 44 is for example by can pass through the material system for detecting light and reflecting visible light
At again the backlight light so as to be located in visible wavelength range is reflected back light guide plate 42, while can penetrate infrared
Or the detection light of near-infrared.
420 side of light-emitting surface of light guide plate 42 is arranged in the optical film layer structure 5, for gathering from the light guide plate 42
The backlight light of outgoing, to improve backlight illumination provided by backlight module 4.In the present embodiment, the optical film layer knot
Structure 5 includes the first film layer unit 501 and the second film layer unit 502.First film layer unit 501 and second film layer unit
502 structure is such as, but not limited to identical.It is illustrated by taking first film layer unit 501 as an example below.
First film layer unit 501 includes the first optical surface 503 and the second optical surface 504 being oppositely arranged.Institute
State the first optical surface 503 back to the light guide plate 42 light-emitting surface 420.Second optical surface 504 faces the leaded light
The light-emitting surface 420 of plate 42.The backlight light can be from second optical surface 504 when penetrating first film layer unit 501
It is appeared again from first optical surface 503 after incidence.Existed by external object transmitting itself or/and reflected detection light
It can be after 503 incidence of the first optical surface again from second optical surface 504 when through first film layer unit 501
It appears.
First optical surface 503 is a continuous surface, and second optical surface 504 is a continuous surface.
Wherein, first optical surface 503 is generally non-planar.
The stacking direction for defining the light guide plate 42, diffusion sheet 46 and optical film layer structure 5 is vertical direction Y.Described
One optical surface 503 includes first plane 520 perpendicular with the vertical direction Y, second optical surface 504 include with
The second perpendicular plane of the vertical direction.In the present embodiment, second optical surface 504 is whole is a flat surface,
Correspondingly, second optical surface 504 is second plane.So, ground is changed, in some embodiments, described the
Two optical surfaces 504 also can be used as it is whole is not a flat surface, but other than including the second plane, may also include curved surface or
With the inclined-plane etc. of the vertical direction Y out of plumb.
First plane 520 and second plane parallel, by optical refraction principle it is found that when detection light passes through
When first film layer unit 501, at least there is part detection light logical from the first parallel plane 520 and the second plane
Later the direction of propagation is constant, position shifts.
In the present embodiment, first optical surface 503 includes multiple spaced first planes 520.It is each
First plane 520 is oppositely arranged with second plane respectively.Via opposite first plane 520 and second plane
And constant, position shifts through the direction of propagation of at least part of first film layer unit 501 detection light.Accordingly
Ground, the sensing mould group 10 or the 20 detection light obtained sensitive informations constant according to this part direction of propagation received
It is relatively accurate.
It should be noted that when making first film layer unit 501, since there are errors or other works for manufacture craft
The adverse effect such as skill factor, causes between the first plane 520 and the second plane of the first film layer unit 501 actually manufactured
May be parallel not such as ideal, i.e., the first plane 520 and the second plane are substantially parallel.Correspondingly, via first plane
520 and second plane and penetrate first film layer unit 501 at least part detection light beam the direction of propagation be basically unchanged.
Defining first plane 520 is the first transmittance section, and first optical surface 503 further comprises the second light transmission
Portion 522, vertical direction Y described in 522 out of plumb of the second transmittance section.When the backlight for being incident to first film layer unit 501
Light can be assembled when being emitted from second transmittance section 522.
The side of every one first transmittance section 520 has been respectively coupled the second transmittance section 522.It wraps second transmittance section 522
Include inclined-plane or/and vertical plane.In the present embodiment, second transmittance section 522 includes inclined-plane and vertical plane (together referring to Fig. 7).
The inclined-plane favours between first transmittance section 520 and second optical surface 504.The vertical plane is perpendicular to described
Between one transmittance section 520 and second optical surface 504.Wherein, connection two is described tiltedly between the first adjacent transmittance section 520
Face.Angle between adjacent first transmittance section 520 and the inclined-plane is obtuse angle.Positioned at the first adjacent transmittance section 520
Between two inclined-planes between angle be acute angle.
So, ground is changed, in other embodiments, second transmittance section 522 can also be inclined-plane or vertical plane.
Ground is changed, in some embodiments, in the direction arranged along first transmittance section 520, described first
Transmittance section 520 can also be for example alternately present respectively with second transmittance section 522, the first adjacent transmittance section 520 to described
The vertical range of two optical surfaces 504 is different, and the folder between second transmittance section 522 and the first adjacent transmittance section 520
Angle is obtuse angle.
The structure of second film layer unit 502 and first film layer unit 501 is same or similar, herein no longer to institute
The second film layer unit 502 is stated to be repeated.First film layer unit 501 is located at 502 top of the second film layer unit.It is described
Each first transmittance section 520 in first film layer unit 501 for example extends in a first direction.In second film layer unit 502
Each first transmittance section 520 extends in a second direction.The vertical second direction of the first direction.
The area of the second optical surface 504 of first film layer unit 501 is set as S1.Set the first film layer list
Member 501 the first transmittance section 520 the gross area (or are as follows: the sum of area) be S2.Set the of second film layer unit 502
The area of two optical surfaces 504 is S3.Set the first transmittance section 520 of second film layer unit 502 the gross area (or
Are as follows: the sum of area) it is S4.
Further, the gross area S2 for setting the first transmittance section 520 of first film layer unit 501 accounts for first film
The percentage of the area S1 of second optical surface 504 of layer unit 501 is P1.Set the first of second film layer unit 502
The percentage that the gross area S4 of transmittance section 520 accounts for the area S3 of the second optical surface 504 of second film layer unit 502 is
P2.The product of the percentage P1 and the percentage P2 are set as N.
Inventor is by a large amount of experiment and analysis verifying discovery, when the product N is equal to or more than 50% and is less than
When 100%, the amount of the detection light constant from the direction of propagation that the optical film layer structure 5 is emitted is appropriate, thus, the biography
Sense mould group 10 is more accurate according to the sensitive information that the detection light received obtains.
Ground is changed, in some embodiments, the optical film layer structure 5 or single layer diaphragm structure.Accordingly
Ground, the gross area of each first transmittance section 520 of the monolithic film layer structure 5 account for the percentage of the area of the second optical surface 504
It is greater than or is equal to 50% and is less than or equal to 100%.
Change ground, in some embodiments, the product N is also smaller than 50%, be such as, but not limited to greater than or
Equal to 40% less than 50%.
The side of the light-emitting surface 420 of the light guide plate 42 is arranged in the diffusion sheet 46, for expanding the backlight light
It dissipates to realize atomizing effect.
The diffusion of diffusion sheet 46 is located at the backlight light in visible wavelength range and penetrates infrared or near-infrared inspection
Survey light.Such as: the wave-length coverage of the backlight light is, for example, 380nm to 760nm.The wave-length coverage example of the detection light
For example 800nm to 1650nm.The diffusion sheet 46 can measure the diffusion of light with mist degree.The mist degree refers to
Light retrodeviates the light intensity that the light intensity from 2.5 degree of incident direction or more transmitted rays accounts for original whole incident rays by diffusion sheet 46
Percentage.Through light after the diffusion sheet 46 mist degree it is bigger illustrate that diffusion sheet 46 is stronger to the diffusion of the light,
Mist degree is more than 30% and thinks that diffusion sheet 46 has diffusion to the light.
The diffusion sheet 46 is greater than the diffusion to the detection light to the diffusion of the backlight light.It is optional
Ground, the diffusion sheet 46 for pass through detection light mist degree less than 30%.
The diffusion sheet 46 can realize the diffusion to light by forming optical scattering structure on substrate.In this reality
It applies in mode, the optical scattering structure can be the coarse microstructure of ground-glass appearance.The substrate is translucent material, optional autohemagglutination
Carbonic ester (PC), polymethyl methacrylate (PMMA), any one or more in polyethylene terephthalate (PET)
Combination or other meet the material of above-mentioned light transmission requirement.The average-size of the coarse microstructure of the ground-glass appearance is 380
In nanometer (Nanometer, nm) to the visible wavelength range of 760nm, so as to the backlight light for belonging to visible-range
Line has an obvious diffusion effect and longer infrared to wavelength or detection light of near-infrared has stronger penetrability.
Ground is changed, is applied in mode other, the diffusion sheet 46 can be made by mixing diffusion particle on substrate.Institute
Backlight light is stated when across the diffusion sheet 46 constantly the different diffusion particle of refractive index and the substrate of transparent material
It passes through, repeatedly refraction, reflection and scattering phenomenon occurs, to achieve the effect that optics is spread.The diffusion particle can be by saturating
The material crossed infrared or near infrared light and reflect visible light is made.The size ranges of the diffusion particle are received with being located at 380
The visible wavelength range of rice (Nanometer, nm) to 760nm are identical, so as to the backlight light for belonging to visible-range
Line has an obvious diffusion effect and longer infrared to wavelength or detection light of near-infrared has stronger penetrability.
Ground is changed, is applied in mode other, the diffusion sheet 46 is a kind of film layer with nano-porous structure.It is described
The material of nanoporous film layer can be, but be not limited to, a kind of polyethylene fabric (Nanoporous Polythylene
Textile).The aperture of multiple Nano grade sizes, the size range of the aperture are formed on the polyethylene web material
For 100nm to 1000nm, the characteristic for but capableing of scatter visible light through infrared or near infrared light is made it have.
The application is not limited to the diffusion sheet 46 that above embodiment is enumerated, and the diffusion sheet 46 can also be other suitable
Structure or/and material.
The diffusion sheet 46 may include upper diffusion sheet 461 and lower diffusion sheet 462.The upper diffusion sheet 461 and lower diffusion sheet
462 have similar structure, are used equally for diffusion backlight light and through by external object transmitting or/and reflected detection
Light.The upper diffusion sheet 461 and lower diffusion sheet 462 have respective function and are biased to, such as: upper diffusion sheet 461 is more emphasized pair
The atomizing effect of backlight light, and lower diffusion sheet 462 has the transmitance of relatively high backlight light.The upper diffusion sheet
461, putting in order between lower diffusion sheet 462, the first film layer unit 501 and the second film layer unit 502 is not particularly limited.Example
Such as, in the present embodiment, first film layer unit 501 and the setting of the second film layer unit 502 are in upper diffusion sheet 461 and lower expansion
Between discrete piece 462.So, ground is changed, in some embodiments, the upper diffusion sheet 461 is arranged in the first film layer unit 501
Between the second film layer unit 502.The lower diffusion sheet 462 is arranged between the second film layer unit 502 and light guide plate 42.
Referring to Fig. 6, the 4th embodiment of the application provides a kind of backlight module that can be used in above-mentioned display device 3
4 ', it is applied in the display device 3 for replacing above-mentioned backlight module 4.The backlight module 4 ' and the backlight module 4
Structure is roughly the same, and the two main distinction is: the diffusion sheet 46 of the backlight module 4 is replaced by quantum dot film.The amount
Son point film 46 is greater than the diffusion to infrared light or near infrared light to the diffusion of backlight light.
Contain quanta point material 463 in the quantum dot film 46.The quanta point material 463 can absorb Blue backlight light
It is respectively converted into green colored backlights light and red backlight light, therefore, the back light 40 only needs for blue-light-emitting
Light source, the Blue backlight light issued a part in the quantum dot film 46 are turned after the absorption of quanta point material 463
It is changed to green colored backlights light and red backlight light, then is mutually mixed into the unabsorbed part Blue backlight light white
Color backlight light projects.Because the quanta point material 463 launches outward the light after conversion when conversion shines centered on itself
Line, while also there is dispersion effect, so the white backlight light that the quantum dot film 46 is converted into also has preferable diffusion
Property.The quanta point material 463 does not absorb the infrared or near infrared light of infrared or near-infrared wavelength range light or absorption
It is less, therefore the detection light can be penetrated.
Change ground, in other embodiments, the back light 40 can also emitting ultraviolet light to light guide plate 42, from institute
State light guide plate 42 outgoing ultraviolet light enter the quantum dot film 46, the quantum dot film 46 convert the ultraviolet light into feux rouges,
Green light and blue light simultaneously project the visible light beam after conversion.
Inventor has found by a large amount of experimental analysis and verifying, when using the quantum dot film 46 as diffusion sheet,
It does not need to be arranged two panels diffusion sheet up and down, and smaller to the diffusion of the detection light beam, therefore, the sensing mould group 10
It is more acurrate according to the detection light beam received corresponding sense data obtained.
It should be noted that the application is not limited to the backlight module that the respective embodiments described above are mentioned, the backlight module
Structure or material etc. can also have other suitable deformations, present invention emphasis essentially consists in optical film layer structure 5
Structure or material change and/or the change of the structure of diffusion sheet 46 or material, therefore, as long as technical idea and present invention
The similar or identical all technical solutions of emphasis should all fall into the protection scope of the application.
Also referring to Fig. 5 and Fig. 7, the 5th embodiment of the application provides a kind of optical film layer structure 5, can be used in
In the backlight module of above-mentioned each embodiment with biplate optical film layer unit.The optical film layer structure 5 is for gathering back
Light light and at least exist when through the detection light part detection light the direction of propagation is constant, position occur it is inclined
It moves, is carried out with meeting to increase the display brightness of display device 3 and sense mould group 10 or 20 in the setting of the lower section of display device 3 simultaneously
The demand of sensing.
The optical film layer structure 5 includes the first film layer unit 501 and the second film layer unit 502.The first film layer list
Member 501 is such as, but not limited to identical with the structure of second film layer unit 502, is now with the first film layer unit 501
Example is illustrated.In the present embodiment, first film layer unit 501 includes substrate 500 and multiple micro-structures 52.The base
Bottom 500 includes upper surface and the lower surface being oppositely arranged with upper surface.The multiple micro-structure 52 is closely arranged in the substrate
On 500 upper surface.The multiple micro-structure 52 carries out the detection light saturating for assembling to the backlight light
It crosses, at least part detects light and sends out in the constant, position by the direction of propagation after the micro-structure 52 and the substrate 500
Raw offset.
In the present embodiment, multiple micro-structures 52 in first film layer unit 501 are arranged in uniline multiple row, each micro-
Structure 52 extends in a first direction, arranges in a second direction, wherein the first direction is column direction, and the second direction is
Line direction.Multiple micro-structures 52 in second film layer unit 502 are arranged in single-row multirow, wherein each micro-structure 52 is along institute
Second direction is stated to extend, arrange along the first direction.The first direction is vertical with the second direction.Change ground, institute
Stating multiple micro-structures 52 in the first film layer unit 501 can also arrange in single-row multirow, more in second film layer unit 502
A micro-structure 52 is arranged in uniline multiple row.
In the present embodiment, the substrate 500 is made respectively with the micro-structure 52, and is made respectively by different materials
At.For example, the optional self-polycarbonate of material (PC) of the substrate 500, polymethyl methacrylate (PMMA), poly- terephthaldehyde
The combination of any one or more in sour glycol ester (PET), or meet the other materials of above-mentioned light transmission requirement.It is described micro-
Structure 52 is for example made of curable material.When production, curable material, such as UV first are coated in the substrate 500
Glue the curable materials is made using moulding process the specific shape of micro-structure 52, finally again to the micro-structure 52 into
Row solidification.
Optionally, the absolute value of the refractive index difference between the substrate 500 and the micro-structure 52 is less than 0.3.It is described
The refractive index of micro-structure 52 is, for example, 1.45~1.55, and the refractive index of the substrate 500 is, for example, 1.6~1.8.
Preferably, the absolute value of the refractive index difference between the substrate 500 and the micro-structure 52 is less than 0.2.It is described
The refractive index of micro-structure 52 is less than the refractive index of the substrate 500.The refractive index of the micro-structure 52 is, for example, 1.45~1.55,
The refractive index of the substrate 500 is, for example, 1.64.
Inventor is analyzed by many experiments and the discoveries such as verifying, the refractive index between the substrate 500 and micro-structure 52
The absolute value of difference is smaller, is more conducive to the sensing precision for promoting sensing mould group 10.On the one hand, due to the substrate 500 with it is micro-
The absolute value of refractive index difference between structure 52 is smaller, therefore, the detection light phase being emitted from first film layer unit 501
The direction of detection light when compared with incidence deflects smaller or zero deflection, correspondingly, receives according to through the backlight module 4
The detection light, the sensing mould group 10 can restore the truth of wanted sensitive information to large extent;On the other hand,
Since the absolute value of the refractive index difference between the substrate 500 and micro-structure 52 is smaller, first film layer unit 501 is transmitted
Detection light it is more, the detection light of reflection tails off, so as to improve detection light light transmittance, in turn, the sensing
The detection light that mould group 10 obtains increases, and further increases sensing precision.
However, since the material that different manufacturers use is different, the refractive index difference meeting of the substrate 500 and micro-structure 52
Difference is respectively corresponded, correspondingly, the absolute value of refractive index difference between the two also may be selected to be greater than 0.3, but the sensing
The sensing precision of mould group 10 or 20 is corresponding to be reduced.
Each micro-structure 52 includes upper surface (or: top surface), and the upper surface of the micro-structure 52 is the micro-structure 52
Back to a side surface of the substrate 500.In the present embodiment, the upper surface of the micro-structure 52 is integrally a flat surface.Institute
Upper surface and the vertical direction Y for stating micro-structure 52 are perpendicular.
The upper surface and lower surface of the substrate 500 are the plane being parallel to each other, and perpendicular with the vertical direction Y.
Correspondingly, second optical surface 504 is the lower surface of the substrate 500.First light transmission of first optical surface 503
Portion 520 is the upper surface of the micro-structure 52.
It is illustrated by taking first film layer unit 501 as an example, each micro-structure 52 further includes two first sides 523 and two
Second side 524, wherein the first side 523 is side that is opposite with the first direction or intersecting, the second side
524 is along the sides that the first direction extends.In the present embodiment, the second side 524 is inclined-plane, first side
Face 523 is vertical plane.Second transmittance section 522 includes the second side 524 and the first side 523.
Along the arragement direction of the micro-structure 52, there are second side that two are connected between the first adjacent transmittance section 520
Face 524.Angle between the first adjacent transmittance section 520 and second side 524 is obtuse angle.Positioned at the first adjacent transmittance section
The angle between two second sides 524 between 520 is acute angle.
Optionally, the micro-structure 52 is such as, but not limited to halfpace.
In the present embodiment, the structure and size of each micro-structure 52 is identical.Each first transmittance section, 520 to the second optics table
The vertical range in face 504 is identical.
So, ground, in some embodiments, 520 to the second light of the first transmittance section of the multiple micro-structure 52 are changed
The vertical range for learning surface 504 can also be different.
Emitted when the sensing mould group 10 or 20, which executes, to be sensed by external object itself please also refer to Fig. 2 or Fig. 4
Or/and there is at least partly detection light via first when being transmitted to first film layer unit 501 in the detection light of reflection
Transmittance section 520 is penetrated through the second optical surface 504 of first film layer unit 501 and via the first transmittance section 520
After second optical surface 504 of second film layer unit 502, the direction of propagation is basically unchanged, and position shifts, to make
It is more accurate to obtain the receiving unit 103 or 203 associated sensed data or information obtained about the external object.
Optical path reversibly, when the detection light beam that the sensing mould group 10 emits is after through optical film layer structure 5, until
Few direction of propagation that there is part detection light beam is constant, and position shifts.
So, compared to through the display device 3 transmitting detection light beam to external object, the sensing mould group 10 penetrates institute
It states display device 3 and receives the detection light beam for being emitted by described external object itself or/and being reflected, passed through with greater need for detection light beam
The direction of propagation when optical film layer structure 5 is constant, it is hereby achieved that accurate sensing result.
Further, the backlight light is passing through the second transmittance section 522 of second film layer unit 502 and the first film
It can be assembled when the second transmittance section 522 of layer unit 501, to improve the brightness of backlight light.
In the present embodiment, the product N is greater than or equal to 50% and less than 100%.So, ground is changed, certain
In embodiment, the product N is also smaller than 50%, is greater than or is equal to 40% less than 50%.
Also referring to Fig. 8, because the first transmittance section 520 of first optical surface 503 and the second optical surface 504 it
Between distance generally remain constant, i.e., substantially parallel relationship is kept between each other, according to light refraction law: via institute
The direction of propagation that the first transmittance section 520 is stated through at least part detection light of second optical surface 504 is basically unchanged,
And offset D has occurred in position.It is clear in order to understand, for example, name is from the incident detection light in first transmittance section 520
O1, the detection light O1 are emitted after repeatedly reflecting from the second optical surface 504 in the first film layer unit 501, name
Going out this detection light shot out from second optical surface 504 is O2.By light refraction law it is found that detection light O2
Positional shift D mainly has occurred compared to detection light O1, and transmission direction is constant.
It is understood that Fig. 8 is schematic diagram.When the refractive index difference of micro-structure 52 and the material of substrate 500, Fig. 8
In be not specifically shown the refraction effect that detection light occurs when the interface of micro-structure 52 and substrate 500 transmits.
Reversibly, it when detection light is transmitted from second optical surface 504 to first optical surface 503, deposits
At least partly detection light is after passing through first transmittance section 520, transmission direction is constant, position shifts.For example,
When transmitting unit 102 (see Fig. 2) is located at below backlight module, the detection light of transmitting is passing through the optical film layer structure 5
When, at least there is transmission of the part detection light before passing through the optical film layer structure and after the optical film layer structure
Direction is basically unchanged, position shifts.
It is understood that because of production tolerance or the relationship of machining accuracy, the first light transmission of first optical surface 503
Parallel relation between portion 520 and second optical surface 504 may exist reasonable deviation range.
Due between the second transmittance section 522 and second optical surface 504 of first optical surface 503 and uneven
Row, according to the law of refraction of light, via second transmittance section 522 through the light of the optical film layer structure 5 can occur compared with
Apparent direction deflection, so as to for gathering backlight light along preset direction to improve backlight illumination.
Ground is changed, in some embodiments, the micro-structure 52 can be structure as a whole with substrate 500, the two
Material is identical or different.In addition, the material of the two can also be identical when the micro-structure 52 is made respectively with the substrate.
In some embodiments, the micro-structure 52 can also be with substrate 500 by together with adhesives
Two independent film layers.Described adhesive may include, but be not limited to, contact adhesive or uv-curable adhesive.
It is referring to Figure 2 together that a pixel R of display panel 30 is corresponding with optical film layer structure 5 with Fig. 9, Fig. 9 to close
It is schematic diagram.The display panel 30 includes multiple pixels, and the multiple pixel for example but not limits to including multiple red
(R) pixel, multiple green (G) pixels and multiple blue (B) pixels are the multiple red (R) pixel, multiple green
Color (G) pixel and multiple blue (B) pixels are arranged according to pre-defined rule.In general, the size of each pixel is identical,
Such as the square that long wide scope is 30 microns to 50 microns.It is illustrated by taking red (R) pixel as an example now.
By optical principle it is found that through second transmittance section 522 backlight light than penetrate first transmittance section
520 backlight light will be assembled, and correspondingly, the brightness through the backlight light of second transmittance section 522 can be than described in transmission
The brightness of the backlight light of first transmittance section 520 is eager to excel.
The first transmittance section 520 and the second film layer list in order to succinct clear, in definition first film layer unit 501
Overlapping region of first transmittance section 520 when the opposite direction along the vertical direction Y is projected in member 502 is M.It is described heavy
Folded region M is also square.
Preferably, the area or width of the overlapping region M are less than the area or width of the pixel R, thus, it penetrates
The backlight light of first transmittance section 520 and the backlight light for penetrating second transmittance section 522 can be irradiated to described
Pixel R.So set, the backlight light of each pixel on the display panel 30 is more uniform.In addition, passing through the optics
The transmitance that the direction of propagation after film layer structure 5 changes detection light that is smaller or being basically unchanged is also appropriate, to be conducive to
It senses mould group 10 or 20 and executes corresponding detection.
It is understood that in some embodiments, red (R) pixel of the display panel 30, green (G) as
The size of vegetarian refreshments and blue (B) pixel can also be not fully identical.In addition, each pixel or each overlapping region M for example may be used
For rectangle, and it is not limited to square.Preferably, the area of the overlapping region M is less than the area of the pixel.
Optionally, in one embodiment, the direction along vertical first transmittance section 520 is projected, and described the
Multiple first transmittance sections 520 on multiple first transmittance sections 520 and second film layer unit 502 in one film layer unit 501
Multiple overlapping region M be oppositely arranged one by one respectively with multiple pixels of the display panel 30, and be located at opposite picture
Within the scope of where vegetarian refreshments.
So, ground is changed, the direction along vertical first transmittance section 520 is projected, first film layer unit 501
On multiple first transmittance sections 520 and second film layer unit 502 on multiple first transmittance sections 520 multiple overlapping regions
Each of M or part are oppositely arranged with the pixel in the display panel 30 respectively, and are located at opposite pixel institute
Within the scope of or not exclusively fall in where opposite pixel within the scope of.
In addition, a pixel can also correspond to multiple overlapping region M and be not limited to an overlapping region M.
Certainly, the area of the overlapping region M can also be greater than the area of pixel, the display effect of the display panel
It is opposite to be deteriorated.
Referring to Fig. 10, being illustrated so that the micro-structure 52 is halfpace as an example, along the vertical direction Y and along micro-structure
Arragement direction between 52, the cross section of first film layer unit 501 are trapezoidal.Preferably, described trapezoidal for isosceles trapezoid, institute
The base angle θ range for stating isosceles trapezoid is 40 degree to 50 degree, and the range of the width K of the first transmittance section 520 is more than or equal to 5 microns
And the range less than 50 microns, height H is 10 microns to 25 microns.
Inventor verifies with analysis through a large number of experiments, and discovery passes through when detection light with the micro- of above-mentioned size range
The amount for the detection light that after the optical film layer structure 5 of structure 52, the direction of propagation is constant, position shifts is appropriate, is conducive to
It senses mould group 10 or 20 and executes corresponding sensing.In addition, converging action pair of the backlight light after the optical film layer structure 5
Display effect is also relatively suitable.
It should be noted that angle of the base angle θ of the isosceles trapezoid between second side 524 and the second plane.Institute
Stating base angle θ is preferably 45 degree.
Further, when the width K is less than or equal to 25 microns, the backlight of first film layer unit 501 is assembled
Effect it is relatively strong and through first film layer unit 501 and the luminous flux of the constant detection light in the direction of propagation is also relatively suitable.
So, ground is changed, in some embodiments, according to client to the integration requirement of backlight effect and detection effect,
Furthermore, it is contemplated that the difference of the size of product, material etc., such as be greater than or equal to 50% in the product N and be less than
Under conditions of 100%, manufacturer can be further combined with parameters such as width, height H, the base angle θ for adjusting the micro-structure 52, to meet
Different demands of the different clients to product.
Figure 11 is please referred to, the application sixth embodiment provides a kind of optical film layer structure 5 ', replaceable above-mentioned light
It learns film layer structure 5 and is used in the backlight module of above-mentioned each embodiment with biplate optical film layer unit.The light
Film layer structure 5 ' is roughly the same with the structure of the optical film layer structure 5, and the main distinction of the two is: the optical film layer
One layer of light diffusion layer for diffusing light is provided on second optical surface 504 of the first film layer unit 501 of structure 5 '
505.The light diffusion layer 505 is the coarse lines of one layer of ground-glass appearance to spread incident backlight light.It is understood that
The light diffusion layer 505 can be formed directly on the second optical surface 504, or be laid on second optical surface 504
The coating is shaped to the coarse lines of ground-glass appearance by one coating again.The material of the light diffusion layer 505 can be with described
The substrate 500 of one film layer unit 501 is different, for the material that can reflect visible light through infrared or near infrared light.It is described thick
Rough lines, for example, can be multiple small protrusions.The average-size of the small protrusion can be at 380 nanometers (Nanometer, nm)
To the visible wavelength range of 760nm, so as to have obvious dispersion effect to visible light and longer red to wavelength
Outer or near-infrared detection light has stronger penetrability.
It should be noted that when optical film layer structure 5 ' is applied to above-mentioned backlight module 4, upper diffusion sheet 461 or lower expansion
One of discrete piece 462 can be omitted.In addition, the diffusion layer 505 is also alternatively formed in second film layer unit
On 502 the second optical surface 504.
Figure 12 is please referred to, the 7th embodiment of the application provides a kind of optical film layer structure 5 ", replaceable above-mentioned light
It learns film layer structure 5 and is used in the backlight module of above-mentioned each embodiment with biplate optical film layer unit.The light
Film layer structure 5 " is roughly the same with the structure of the optical film layer structure 5 ', and the main distinction of the two is: the optical film
The light diffusion layer 505 of layer structure 5 " includes flat part 506.The flat part 506 has back to the side of the second optical surface 504
There is flat surface, thus, when being pierced by by external object transmitting itself or/reflected detection light from the flat part 506
When, the scattering to the detection light can be reduced.Correspondingly, positioned at the sensing mould group 10 or 20 bases of 3 lower section of display device
The detection light sensitive information obtained received is closer to real information.
Figure 13 is please referred to, the 8th embodiment of the application provides a kind of optical film layer structure 5 " ', replaceable above-mentioned light
It learns film layer structure 5 and is used in the backlight module of above-mentioned each embodiment with biplate optical film layer unit.The light
Learn film layer structure 5 " ' it is roughly the same with the structure of the optical film layer structure 5 ', the main distinction of the two is: the optical film
Layer structure 5 " ' light diffusion layer 505 be the coating being formed on the second optical surface 504, and be mixed in the coating more
A diffusion particle 507 for diffusing light.It is understood that the diffusion particle 507 can be infrared or close by can pass through
Infrared light and the material for reflecting visible light is made.The size ranges of the diffusion particle 507 be located at 380 nanometers
(Nanometer, nm) is identical to the visible wavelength range between 760nm, so as to have obvious scattering to visible light
Effect and it is longer infrared to wavelength or detection light of near-infrared has stronger penetrability.
Also referring to Figure 14 and Figure 15, the 9th embodiment of the application provides a kind of optical film layer structure 5 " ", it can
It replaces above-mentioned optical film layer structure 5 and is used in the backlight module of above-mentioned each embodiment with biplate optical film layer unit
In.The optical film layer structure 5 " " is roughly the same with the structure of the optical film layer structure 5, and the main distinction of the two is: institute
State optical film layer structure 5 " " multiple micro-structures 52 be spaced each other arrangement in the substrate 500.
Preferably, the structure and size of the multiple micro-structure 52 is identical, and the multiple micro-structure 52 is arranged at equal intervals.
So, ground is changed, the structure and size of the multiple micro-structure 52 can also be different, and unequal interval is arranged.
Due to be not formed on the upper surface of the substrate 500 micro-structure 52 part be flat surface, and with institute
It is parallel to state the second plane, therefore, the compartment that the micro-structure 52 is not formed on the upper surface of the substrate 500 is also institute
State the first plane of the first optical film layer unit 501, i.e. the first transmittance section 520.At least there is part detection light passing through
Transmission direction after stating the first transmittance section 520 and the second optical surface 504 in substrate 500 is constant, position shifts.
One second transmittance section 522, and second transmittance section 520 and phase are connected between the first adjacent transmittance section 520
Angle between the first adjacent transmittance section 520 is obtuse angle.Relatively, adjacent second transmittance section of the optical film layer structure 5
2 second transmittance sections 522 are connected between 520.Therefore, second between the first transmittance section 520 adjacent in present embodiment is saturating
The region in light portion 522 opposite can become smaller, thus, the detection light is penetrating the optical film layer structure 5 " " when uniformity
It is got well when the transmission optical film layer structure 5.Correspondingly, the sensing data that the sensing mould group 10 or 20 obtains are preferable.
In addition, the optical film layer structure 5 " " backlight convergent effect it is also preferable.
It is similar with the structure of the optical film layer structure 5 referring again to Fig. 9, preferably, the optical film layer structure 5 " "
The first transmittance section 520 overlapping region M area or width be less than the pixel R area or width, thus, through institute
It states the backlight light of the first transmittance section 520 and can be irradiated to the picture through the backlight light of second transmittance section 522
Vegetarian refreshments R.So set, the backlight light of each pixel on the display panel 30 is more uniform and is located at 4 lower section of backlight module
Sensing mould group 10 or 20 to receive detection light also appropriate, to obtain preferable sensing effect.
Figure 16 is please referred to, is illustrated so that the micro-structure 52 is halfpace as an example, along the vertical direction Y and along described the
Two directions, the cross section of first film layer unit 501 are trapezoidal.Preferably, along the arragement direction of each micro-structure 52, it is each adjacent
Spacing G between micro-structure 52 is equal, and the spacing G is less than the width K of the first transmittance section 520 in micro-structure 52 and is greater than
Or a quarter equal to the width K.To enough in the quantity for ensuring the micro-structure 52 in the first film layer unit 501
In the case of, also ensure that the uniformity of detection light and backlight light is preferable.
Further, it is described it is trapezoidal be isosceles trapezoid, the base angle θ range of the isosceles trapezoid is 40 degree to 50 degree, highly
Range is 10 microns to 25 microns, and the range of width K is more than or equal to 5 microns and less than 50 microns.
Inventor verifies with analysis through a large number of experiments, and discovery passes through the with above-mentioned size range when detection light
The amount for the detection light that after one film layer unit 501, the direction of propagation is constant, position shifts is appropriate, is conducive to sense mould group
10 or 20 (see Fig. 2 and Fig. 4) execute corresponding sensing.In addition, convergence of the backlight light after the optical film layer structure 5 is made
With also relatively suitable to display effect.
Optionally, for the first adjacent transmittance section 520: the width of the first transmittance section 520 in the micro-structure 52 with
The range of the sum of the width of the first transmittance section 520 in the substrate 500 is more than or equal to 5 microns and less than 50 microns.Such as
This setting, the backlight convergent effect of the display device 3 is relatively strong and to sense the sensing effect of mould group 10 or 20 also relatively accurate.
Optionally, the spacing G is less than the width K of the first transmittance section 520 in micro-structure 52 and is greater than or equal to described
The half of width K.
Optionally, the spacing G is less than the width K of the first transmittance section 520 in micro-structure 52.
So, ground is changed, in some embodiments, according to client to the integration requirement of backlight effect and detection effect,
Furthermore, it is contemplated that the difference of the size of product, material etc., such as be greater than or equal to 50% in the product N and be less than
The 100% and spacing G is less than under conditions of the width K, and manufacturer can be further combined between the adjustment micro-structure 52
The parameters such as width K, height H, base angle θ, to meet different clients to the different demands of product.
In the present embodiment, the gross area S2 of the first transmittance section 520 of the first film layer unit 501 includes in micro-structure 52
The first transmittance section 520 the gross area and substrate 500 on the first transmittance section 520 the gross area.Similarly, the second film layer unit
The gross area S4 of 502 the first transmittance section 520 includes on the gross area and substrate 500 of the first transmittance section 520 in micro-structure 52
The first transmittance section 520 the gross area.The product N is greater than or equal to 50% and less than 100%.
Ground is changed, in some embodiments, the product N is also smaller than 50%, is greater than or small equal to 40%
In 50%.
Figure 17 is please referred to, the tenth embodiment of the application provides a kind of optical film layer structure 6, replaceable above-mentioned optics
Film layer structure 5 and be used in the backlight module of above-mentioned each embodiment with biplate optical film layer unit.The optics
The structure of film layer structure 6 and the optical film layer structure 5 " " is roughly the same, and the main distinction of the two is: the optical film layer
Second transmittance section 622 of the micro-structure 62 of structure 6 is vertical plane, perpendicular to the first transmittance section 620 and the second optical surface 604 it
Between.
In the present embodiment, the micro-structure 62 is cuboid.
The product N is equal to 100%.
Figure 18 is please referred to, the 11st embodiment of the application provides a kind of optical film layer structure 7, replaceable above-mentioned light
It learns film layer structure 5 and is used in the backlight module of above-mentioned each embodiment with biplate optical film layer unit.The light
Film layer structure 7 is roughly the same with the structure of the optical film layer structure 6, and the main distinction of the two is: the optical film layer
The micro-structure 72 of structure 7 is the triangular prism of strip.In first film layer unit 701 and second film layer unit 702
The all spaced-apart relations of micro-structure 72.
Figure 19 is please referred to, the 12nd embodiment of the application provides a kind of optical film layer structure 8, the replaceable light
It learns film layer structure 5 and is used in the backlight module of the respective embodiments described above.The optical film layer structure 8 is monolithic film layer list
Member, roughly the same with the first film layer unit 501 of the optical film layer structure 5, the main distinction of the two is: the optics
Multiple micro-structures 82 of film layer structure 8 are in the array arrangement of multiple lines and multiple rows in substrate 800.
In the present embodiment, the micro-structure 82 is halfpace.
In addition, the area for setting the second optical surface 804 of the optical film layer structure 8 sets the optical film as S1
The gross area of first transmittance section 820 of layer structure 8 is S2;Set total face of the first transmittance section 820 of the optical film layer structure 8
Product S2 account for the optical film layer structure 8 the second optical surface 804 area S1 percentage be P, the percentage P be greater than or
Equal to 50% and less than 100%.
Ground is changed, in some embodiments, the product N is also smaller than 50%, is greater than or small equal to 40%
In 50%.
Preferably, the area of first transmittance section 820 is less than the area of the pixel of the display panel 30.So, may be used
The area on change ground, first transmittance section 820 is also greater than or the area of the pixel equal to the display panel 30.
Optionally, each of described first transmittance section 820 or part respectively with a pixel of the display panel 30
Point is oppositely arranged, and is located within the scope of opposite pixel place or not exclusively falls in the range where opposite pixel
Within.
In one embodiment, the direction along vertical first transmittance section 820 is projected, the optical film layer knot
Multiple pixels of multiple first transmittance sections 820 and the display panel 30 on structure 8 are oppositely arranged one by one, and are located at opposite
Within the scope of where pixel.
In addition, a pixel can also correspond to multiple first transmittance sections 820.
Figure 20 is please referred to, the 13rd embodiment of the application provides a kind of optical film that can be used in above-mentioned backlight module
Layer structure 8 ', roughly the same with optical film layer structure 8, the two main distinction is: micro- knot of the optical film layer structure 8 '
Structure is intervally arranged in substrate 800.
The first transmittance section 820 in the substrate 800 is saturating less than first in the micro-structure 82 along the width of column direction
Light portion 820 along column direction width and be greater than or equal to the micro-structure 82 on the first transmittance section 820 along column direction width
A quarter;The first transmittance section 820 in the substrate 800 is less than first in the micro-structure 82 along the width of line direction
Transmittance section 820 along line direction width and be greater than or equal to the micro-structure 82 on the first transmittance section 820 along line direction width
The a quarter of degree.
Optionally, the first transmittance section 820 in the substrate 800 is less than in the micro-structure 82 along the width of column direction
First transmittance section 820 along column direction width and be greater than or equal to the micro-structure 82 on the first transmittance section 820 along column direction
Width half;The first transmittance section 820 in the substrate 800 is less than in the micro-structure 82 along the width of line direction
The first transmittance section 820 along line direction width and be greater than or equal to the micro-structure 82 on the first transmittance section 820 along row side
To width half.
Optionally, the first transmittance section 820 in the substrate 800 is less than in the micro-structure 82 along the width of column direction
Width of first transmittance section 820 along column direction;The first transmittance section 820 in the substrate 800 is less than institute along the width of line direction
The first transmittance section 820 in micro-structure 82 is stated along the width of line direction.
Figure 21 is please referred to, the 14th embodiment of the application provides a kind of optical film that can be used in above-mentioned backlight module
Layer structure 9, roughly the same with optical film layer structure 8 ', the two main distinction is: the micro-structure of the optical film layer structure 9
The second transmittance section 922 be vertical plane.
In the present embodiment, each described micro-structure 82 is cuboid.
The percentage P is equal to 100%
Figure 22 is please referred to, the 15th embodiment of the application provides a kind of optical film that can be used in above-mentioned backlight module
Layer structure 9 ', roughly the same with optical film layer structure 8 ', the two main distinction is: micro- knot of the optical film layer structure 9 '
Structure is triangular prism.
The application is not limited to the shape of micro-structure described in above each embodiment, and the micro-structure can also be other
The structure of suitable shape.
Change ground, for the micro-structure of the respective embodiments described above, can also part micro-structure closely arrange, part micro-structure
It is intervally arranged.
Compared with prior art, optical film layer structure, backlight module, display device provided by each embodiment of the application
And electronic equipment can be realized by the way that reasonable microstructure aspects are arranged under the premise of the display area not aperture of display device
Backlight light and detection the two-way of light penetrate, and are conducive to sense under realization screen under the premise of not influencing display effect, thus
The screen accounting for further increasing electronic equipment, promotes the visual experience of electronic equipment.
It should be noted that it will be understood by those skilled in the art that without creative efforts, the application
Some or all of embodiment, and the deformation for some or all of embodiment, replacement, change, fractionation, combination, extension
Cover Deng being considered as creating thought by present invention, belongs to the protection scope of the application.
In the description of this specification, reference term " embodiment ", " certain embodiments ", " schematically implementation
What the description of mode ", " example ", " specific example " or " some examples " etc. meant to describe in conjunction with the embodiment or example
Particular features, structures, materials, or characteristics are contained at least one embodiment or example of the application.In this specification
In, schematic expression of the above terms are not necessarily referring to identical embodiment or example.Moreover, the specific spy of description
Sign, structure, material or feature can be combined in any suitable manner in any one or more embodiments or example.
The foregoing is merely the better embodiments of the application, all the application's not to limit the application
Made any modifications, equivalent replacements, and improvements etc., should be included within the scope of protection of this application within spirit and principle.
Claims (43)
1. a kind of optical film layer structure, for assembling backlight light and through detection light, it is characterised in that: the optical film
Layer structure includes one or more film layer units, and the film layer unit includes the first optical surface and the second optics being oppositely arranged
Surface, wherein first optical surface be it is non-planar, first optical surface include the first plane, second optics
Surface includes the second plane, first plane and second plane parallel and is oppositely arranged, definition first plane
For the first transmittance section, first optical surface further includes the second transmittance section, when detection light pass through it is parallel and be oppositely arranged
First transmittance section and the second plane and penetrate the film layer unit when, at least exist part detection light the direction of propagation not
Become, is assembled when backlight light is incident to the film layer unit and projects from second transmittance section.
2. optical film layer structure as described in claim 1, it is characterised in that: second optical surface is a flat surface.
3. optical film layer structure as claimed in claim 2, it is characterised in that: second transmittance section includes inclined-plane, described oblique
Face favours between first transmittance section and second optical surface, be incident to the backlight light of the film layer unit from
It is assembled when being emitted on the inclined-plane;Or, second transmittance section includes vertical plane, the vertical plane is perpendicular to first transmittance section
Between second optical surface, when being emitted from the vertical plane meeting occurs for the backlight light for being incident to the film layer unit
It is poly-;Or, second transmittance section includes inclined-plane and vertical plane, the inclined-plane favours first transmittance section and second optics
Between surface, the vertical plane is incident to the film layer list perpendicular between first transmittance section and second optical surface
The backlight light of member is assembled when being emitted from the inclined-plane and vertical plane.
4. optical film layer structure as described in claim 1, it is characterised in that: each film layer unit includes substrate and multiple
Micro-structure, the substrate include upper surface and the lower surface that is oppositely arranged with upper surface, and the multiple micro-structure is formed in described
On upper surface, wherein each micro-structure includes upper surface, and the upper surface of the micro-structure is the micro-structure back to the substrate
A side surface and be plane, first transmittance section includes the upper surface of micro-structure, second optical surface be the base
The lower surface at bottom.
5. optical film layer structure as claimed in claim 4, it is characterised in that: upper table of the multiple micro-structure in the substrate
It is close continuously every arranging or be spaced each other arrangement on face.
6. optical film layer structure as claimed in claim 5, it is characterised in that: when the multiple micro-structure on the substrate that
When this is intervally arranged, first transmittance section further include the substrate upper surface on the micro-structure is not formed and exposes
Compartment.
7. optical film layer structure as claimed in claim 6, it is characterised in that: the width of each compartment is equal, each micro-structure
Size is identical with structure.
8. optical film layer structure as claimed in claim 4, it is characterised in that: the micro-structure is halfpace or cuboid.
9. optical film layer structure as claimed in claim 4, it is characterised in that: the Refractive Index of Material of the micro-structure and the base
Absolute difference between the Refractive Index of Material at bottom is greater than or equal to 0 and less than 0.2.
10. the optical film layer structure as described in claim 4 or 6, it is characterised in that: when the optical film layer structure is monolithic membrane
When layer unit, the multiple micro-structure is in multiple lines and multiple rows arrangement on the substrate;Set the second of the optical film layer structure
The area of optical surface is S1, sets the gross area of the first transmittance section of the optical film layer structure as S2;Set the optics
The gross area S2 of first transmittance section of film layer structure accounts for the percentage of the area S1 of the second optical surface of the optical film layer structure
Than being greater than or equal to 40% for P, the percentage P and less than 100%.
11. optical film layer structure as claimed in claim 10, it is characterised in that: the percentage P be greater than or equal to 50% and
Less than 100%.
12. optical film layer structure as claimed in claim 6, it is characterised in that: when the optical film layer structure is monolithic film layer
When unit, the first transmittance section in the substrate is less than the first transmittance section in the micro-structure along column side along the width of column direction
To width;The first transmittance section in the substrate is less than the first transmittance section in the micro-structure along row along the width of line direction
The width in direction.
13. optical film layer structure as claimed in claim 12, it is characterised in that: the first transmittance section in the substrate is along column side
To width be greater than or equal to the micro-structure on the first transmittance section along column direction width a quarter;In the substrate
The first transmittance section be greater than or equal to first transmittance section in the micro-structure along the width of line direction along the width of line direction
A quarter.
14. optical film layer structure as claimed in claim 12, it is characterised in that: the first transmittance section in the substrate is along column side
To width be greater than or equal to the micro-structure on the first transmittance section along column direction width half;In the substrate
The first transmittance section be greater than or equal to first transmittance section in the micro-structure along the width of line direction along the width of line direction
Half.
15. optical film layer structure as claimed in claim 5, it is characterised in that: the optical film layer structure is for applying one
It is provided in the backlight module of backlight for display panel, when the optical film layer structure is monolithic film layer unit and the multiple micro-
Structure is close without when being intervally arranged, and the area of first transmittance section is less than the area of the pixel of the display panel.
16. optical film layer structure as claimed in claim 5, it is characterised in that: the optical film layer structure is for applying one
It is provided in the backlight module of backlight for display panel, when the optical film layer structure is monolithic film layer unit and the multiple micro-
Structure is close without when being intervally arranged, and the direction along vertical first transmittance section is projected, in the optical film layer structure
Each of multiple first transmittance sections or part be oppositely arranged respectively with a pixel in the display panel, and be located at
Within the scope of where opposite pixel.
17. optical film layer structure as claimed in claim 16, it is characterised in that: along vertical first transmittance section direction into
Row projection, in multiple first transmittance sections in the optical film layer structure respectively with multiple pixels one in the display panel
One is oppositely arranged, and is located within the scope of opposite pixel place.
18. optical film layer structure as claimed in claim 6, it is characterised in that: the optical film layer structure is for applying one
It is provided in the backlight module of backlight for display panel, when the optical film layer structure is monolithic film layer unit, along vertical described
The direction of first transmittance section is projected, and each of multiple first transmittance sections in the optical film layer structure or part are respectively
It is oppositely arranged, and is located within the scope of opposite pixel place with a pixel in the display panel.
19. the optical film layer structure as described in claim 4 or 6, it is characterised in that: when the optical film layer structure includes first
When film layer unit and the second film layer unit, multiple micro-structures in first film layer unit are arranged in uniline multiple row, and described the
Multiple micro-structures of two film layer units are arranged in single-row multirow;Set the area of the second optical surface of first film layer unit
For S1, the gross area of the first transmittance section of first film layer unit is set as S2, sets the second of second film layer unit
The area of optical surface is S3, sets the gross area of the first transmittance section of second film layer unit as S4;Set described first
The gross area S2 of first transmittance section of film layer unit accounts for the percentage of the area S1 of the second optical surface of first film layer unit
Than accounting for the second optics of second film layer unit for P1, the gross area S4 for setting the first transmittance section of second film layer unit
The percentage of the area S3 on surface is P2;The product of the percentage P1 and the percentage P2 are set as N, the product N is big
In or be equal to 40% and less than 100%.
20. optical film layer structure as claimed in claim 19, it is characterised in that: the percentage P be greater than or equal to 50% and
Less than 100%.
21. optical film layer structure as claimed in claim 6, it is characterised in that: when the optical film layer structure includes the first film
When layer unit and the second film layer unit, multiple micro-structures in first film layer unit are in uniline multiple row and the row of being spaced each other
Multiple micro-structures of cloth, second film layer unit in single-row multirow and are spaced each other arrangement;The first light transmission in the substrate
The width in portion is less than the width of the first transmittance section in the micro-structure, or, the area of the first transmittance section in the substrate is small
Area in the first transmittance section in the micro-structure.
22. optical film layer structure as claimed in claim 21, it is characterised in that: the width of the first transmittance section in the substrate
More than or equal to a quarter of the width of the first transmittance section in the micro-structure, or, the first transmittance section in the substrate
Area be greater than or equal to the micro-structure on the first transmittance section area a quarter.
23. optical film layer structure as claimed in claim 21, it is characterised in that: the width of the first transmittance section in the substrate
More than or equal to the half of the width of the first transmittance section in the micro-structure, or, the first transmittance section in the substrate
Area be greater than or equal to the micro-structure on the first transmittance section area half.
24. the optical film layer structure as described in claim 4 or 6, it is characterised in that: when the optical film layer structure includes first
When film layer unit and the second film layer unit, multiple micro-structures in first film layer unit are arranged in uniline multiple row, and described the
Multiple micro-structures of two film layer units are arranged in single-row multirow;Along the direction of vertical first transmittance section and along described more
The arragement direction of a micro-structure, the section of the micro-structure are isosceles trapezoid, the altitude range of the micro-structure be 10 microns extremely
25 microns, the width range of the first transmittance section in the micro-structure be more than or equal to 5 microns and less than 50 microns, it is described etc.
The trapezoidal base angle range of waist is 40 degree to 50 degree.
25. optical film layer structure as claimed in claim 24, it is characterised in that: when multiple micro- in first film layer unit
Structure be it is close without be intervally arranged, multiple micro-structures in second film layer unit be it is close without being intervally arranged when, described the
The width range of one transmittance section is more than or equal to 5 microns and to be less than or equal to 25 microns.
26. optical film layer structure as claimed in claim 24, it is characterised in that: when multiple micro- in first film layer unit
Structure be spaced each other arrangement, multiple micro-structures in second film layer unit are when being spaced each other arrangement, for adjacent
First transmittance section: the sum of width of the first transmittance section on the width of the first transmittance section in the micro-structure and the substrate
Range is more than or equal to 5 microns and less than 50 microns.
27. the optical film layer structure as described in claim 4 or 6, it is characterised in that: the optical film layer structure is for applying
One provides in the backlight module of backlight for display panel, when the optical film layer structure includes the first film layer unit and the second film layer
When unit, multiple micro-structures in first film layer unit are arranged in uniline multiple row, second film layer unit it is multiple micro-
Structure is arranged in single-row multirow;Direction along vertical first transmittance section is projected, and the in first film layer unit
The area of the overlapping region of the first transmittance section on one transmittance section and second film layer unit is less than the picture of the display panel
The area of vegetarian refreshments.
28. optical film layer structure as claimed in claim 24, it is characterised in that: the optical film layer structure is for applying one
It is provided in the backlight module of backlight for display panel, the direction along vertical first transmittance section is projected, first film
The area of the overlapping region of the first transmittance section on the first transmittance section and second film layer unit on layer unit is less than described
The area of the pixel of display panel.
29. optical film layer structure as claimed in claim 5, it is characterised in that: the optical film layer structure is for applying one
It is provided in the backlight module of backlight for display panel, when the optical film layer structure includes the first film layer unit and the second film layer list
When first, multiple micro-structures in first film layer unit are that close nothing is intervally arranged, multiple in second film layer unit
Micro-structure is that close nothing is intervally arranged;Direction along vertical first transmittance section is projected, in first film layer unit
Multiple first transmittance sections and each of multiple overlapping regions of multiple first transmittance sections in second film layer unit or
Part is oppositely arranged with the pixel in the display panel respectively, and is located within the scope of opposite pixel place.
30. optical film layer structure as claimed in claim 29, it is characterised in that: along vertical first transmittance section direction into
Row projects, multiple first transmittance sections on multiple first transmittance sections and second film layer unit in first film layer unit
Multiple overlapping regions be oppositely arranged one by one with multiple pixels in the display panel respectively, and be located at opposite pixel
Within the scope of place.
31. optical film layer structure as claimed in claim 6, it is characterised in that: the optical film layer structure is for applying one
It is provided in the backlight module of backlight for display panel, when the optical film layer structure includes the first film layer unit and the second film layer list
When first, multiple micro-structures in first film layer unit in uniline multiple row and are spaced each other arrangement, second film layer unit
Multiple micro-structures in single-row multirow and being spaced each other arrangement;Direction along vertical first transmittance section is projected, described
Multiple first transmittance sections in first film layer unit are multiple overlapping with multiple first transmittance sections in second film layer unit
Each of region or part are oppositely arranged with the pixel in the display panel respectively, and are located at opposite pixel institute
Within the scope of.
32. optical film layer structure as described in claim 1, it is characterised in that: the backlight light is visible light, the detection
Light is infrared or near infrared light.
33. a kind of backlight module, it is characterised in that: the backlight module includes optics described in any one of claim 1-32
The diffusion sheet and reflector plate that film layer structure, the optical film layer structure are stacked, the diffusion sheet and the optical film layer knot
Structure is located above the reflector plate, and the diffusion sheet is quantum dot film, and the reflector plate is by anti-through infrared or near infrared light
The material for penetrating visible light is made.
34. backlight module as claimed in claim 33, it is characterised in that: define the reflector plate, diffusion sheet and optical film layer
The stacking direction of structure is vertical direction, and first plane and second plane are vertical with the vertical direction.
35. a kind of liquid crystal display device, it is characterised in that: including display panel and backlight module, the display panel is for showing
Show picture, the backlight module is for providing backlight light to the display panel, wherein the backlight module is aforesaid right
It is required that backlight module described in 33 or 34.
36. a kind of electronic equipment, it is characterised in that: including liquid crystal display device described in the claims 35 and at least partly
Sensing mould group below the liquid crystal display device is set, the sensing mould group through the display panel display area and
Backlight module receives the detection light for reflecting or/and emitting from external object, to execute corresponding sensing.
37. electronic equipment as claimed in claim 36, it is characterised in that: the sensing mould group is used for according to the detection received
Light executes any one or a few in fingerprint sensing, three dimensional face sensing and living body sensing.
38. electronic equipment as claimed in claim 36, it is characterised in that: the sensing mould group includes receiving unit, described to connect
It receives unit to be arranged below the backlight module, and the display area for penetrating the display panel and backlight module reception are by outside
The detection light that object reflection is returned.
39. electronic equipment as claimed in claim 38, it is characterised in that: the sensing mould group further includes transmitting unit, is used for
Transmitting detects light to the external object.
40. electronic equipment as claimed in claim 39, it is characterised in that: the transmitting unit is located under the backlight module
Side, for the display area transmitting detection light through the backlight module and the display panel to external object.
41. electronic equipment as claimed in claim 40, it is characterised in that: the sensing mould group is for executing fingerprint recognition.
42. electronic equipment as claimed in claim 39, it is characterised in that: the electronic equipment further comprises cover sheet,
The transmitting unit is located at the display panel side, is located at the lower section of the cover sheet, institute parallel with the display panel
Transmitting unit is stated through cover sheet transmitting detection light beam to external object.
43. electronic equipment as claimed in claim 42, it is characterised in that: the sensing mould group is for executing three dimensional face knowledge
Not.
Applications Claiming Priority (1)
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PCT/CN2019/077589 WO2020181446A1 (en) | 2019-03-11 | 2019-03-11 | Optical film layer structure, backlight module, display device, and electronic apparatus |
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CN110088673B CN110088673B (en) | 2023-03-28 |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2020181457A1 (en) * | 2019-03-11 | 2020-09-17 | 深圳阜时科技有限公司 | Backlight module, display device and electronic device |
CN114764988A (en) * | 2021-01-11 | 2022-07-19 | 群创光电股份有限公司 | Backlight module and display device using same |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN115437177A (en) * | 2022-10-10 | 2022-12-06 | 厦门天马微电子有限公司 | Spliced panel, backlight module and display device |
Citations (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
KR20060102360A (en) * | 2005-03-22 | 2006-09-27 | 엘지.필립스 엘시디 주식회사 | Optical sheet and back light unit including the same |
KR20110138074A (en) * | 2010-06-18 | 2011-12-26 | 성균관대학교산학협력단 | Optical film having graphene, preparing method of the same, and back light unit and liquid crystal display device having the same |
CN102540294A (en) * | 2012-02-03 | 2012-07-04 | 北京康得新复合材料股份有限公司 | Light increasing film |
CN203336480U (en) * | 2013-05-20 | 2013-12-11 | 北京京东方光电科技有限公司 | Optical membrane, backlight module and display device |
CN204479779U (en) * | 2015-01-23 | 2015-07-15 | 东莞市纳利光学材料有限公司 | A kind of brightness enhancement film with pyramid structure |
CN205450321U (en) * | 2016-02-25 | 2016-08-10 | 东莞市纳利光学材料有限公司 | Anti electromagnetic wave brightness enhancement film |
CN206363214U (en) * | 2017-01-09 | 2017-07-28 | 广东欧珀移动通信有限公司 | The display screen component of mobile terminal and the mobile terminal with it |
CN109061922A (en) * | 2018-08-31 | 2018-12-21 | Oppo广东移动通信有限公司 | Display screen component and electronic equipment |
CN109061946A (en) * | 2018-08-31 | 2018-12-21 | Oppo广东移动通信有限公司 | Display screen component and electronic equipment |
Family Cites Families (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN202503555U (en) * | 2012-02-02 | 2012-10-24 | Tcl显示科技(惠州)有限公司 | Cell phone and liquid crystal display module thereof |
CN204556876U (en) * | 2015-02-10 | 2015-08-12 | 江阴通利光电科技有限公司 | A kind of brightness enhancing prismatic sheet |
GB2552090B (en) * | 2017-06-29 | 2021-06-16 | Inodyn Newmedia Gmbh | Front-facing camera and maximized display screen of a mobile device |
CN108885696B (en) * | 2018-02-06 | 2021-03-19 | 深圳市汇顶科技股份有限公司 | Under-screen biological feature recognition device and electronic equipment |
-
2019
- 2019-03-11 CN CN201980000378.2A patent/CN110088673B/en active Active
- 2019-03-11 WO PCT/CN2019/077589 patent/WO2020181446A1/en active Application Filing
Patent Citations (9)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
KR20060102360A (en) * | 2005-03-22 | 2006-09-27 | 엘지.필립스 엘시디 주식회사 | Optical sheet and back light unit including the same |
KR20110138074A (en) * | 2010-06-18 | 2011-12-26 | 성균관대학교산학협력단 | Optical film having graphene, preparing method of the same, and back light unit and liquid crystal display device having the same |
CN102540294A (en) * | 2012-02-03 | 2012-07-04 | 北京康得新复合材料股份有限公司 | Light increasing film |
CN203336480U (en) * | 2013-05-20 | 2013-12-11 | 北京京东方光电科技有限公司 | Optical membrane, backlight module and display device |
CN204479779U (en) * | 2015-01-23 | 2015-07-15 | 东莞市纳利光学材料有限公司 | A kind of brightness enhancement film with pyramid structure |
CN205450321U (en) * | 2016-02-25 | 2016-08-10 | 东莞市纳利光学材料有限公司 | Anti electromagnetic wave brightness enhancement film |
CN206363214U (en) * | 2017-01-09 | 2017-07-28 | 广东欧珀移动通信有限公司 | The display screen component of mobile terminal and the mobile terminal with it |
CN109061922A (en) * | 2018-08-31 | 2018-12-21 | Oppo广东移动通信有限公司 | Display screen component and electronic equipment |
CN109061946A (en) * | 2018-08-31 | 2018-12-21 | Oppo广东移动通信有限公司 | Display screen component and electronic equipment |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
WO2020181457A1 (en) * | 2019-03-11 | 2020-09-17 | 深圳阜时科技有限公司 | Backlight module, display device and electronic device |
CN114764988A (en) * | 2021-01-11 | 2022-07-19 | 群创光电股份有限公司 | Backlight module and display device using same |
Also Published As
Publication number | Publication date |
---|---|
WO2020181446A1 (en) | 2020-09-17 |
CN110088673B (en) | 2023-03-28 |
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