CN205910951U - Display screen - Google Patents

Abstract

The utility model provides a display screen, including screen panel, luminescent plate, first light membrane and the photoelectric conversion unit of hindering who stacks gradually the setting, the circuit net that has the luminescence unit on the luminescent plate and connect each luminescence unit, the light that the luminescence unit sent throws to screen panel orientation, the circuit net is separated the luminescent plate and is a plurality of light transmission region, the first light film mold that hinders has a light -transmitting hole, a light transmission region and a light -transmitting hole that the position corresponds form the optical pass, light that the luminescence unit sent is the object reflection outside or on by the screen panel, then through shining on photoelectric conversion unit behind the optical pass. According to the small hole imaging principle, process light -transmitting hole's light can form images on the photoelectronic imaging unit, makes display screen have concurrently and shows function and image acquisition function.

Description

A kind of display screen

Technical field

The utility model is related to display device technical field, has display function and external image collection concurrently particularly to one kind The display screen of function.

Background technology

For improving unblock security, facilitating equipment to wake up, more than the terminal device such as smart mobile phone, fingerprint collecting is installed Device, the finger print information for obtaining user input.Different according to fingerprint collecting principle, there is now capacitance type fingerprint collection dress Put and optical fingerprint acquisition apparatus.

Fig. 1 is the structural representation of the existing optical fingerprint collector based on matrix form pinhole imaging system principle；As Fig. 1, This optical fingerprint acquisition apparatus includes light guide plate 01, light source 02, imaging layer 03 and imageing sensor 05；Have on imaging layer 03 Multiple imaging holes 04 of array distribution；Light source 02 is arranged on the sidepiece of light guide plate 01, its some light of sending can be in light guide plate Total reflection transmission in 01；Imaging layer 03 is in substantially parallel relationship to light guide plate 01 and imageing sensor 05 and is located at light guide plate 01 and photosensitive Between assembly 05.

Aforesaid optical fingerprint collector is the self-contained unit of only fingerprint image acquisition function, is such as arranged on mobile phone etc. Need screen display terminal device front when, originally limited dimensional space will necessarily be taken.The screen in smart mobile phone front The positive big viewing area of design and narrow frame develop, and enough separate space often cannot be provided to install fingerprint capturer.According to How practical application request, realize finger print collecting function under the mobile phone screen design of big viewing area and narrow frame, be ability The problem that field technique personnel need to solve.

Utility model content

Need to install side by side, take the problem in more space for existing terminal device fingerprint capturer and display screen, The utility model provides a kind of display screen having display function and image collecting function concurrently.

The utility model provides a kind of display screen, including the screen panel being cascading, luminous plaque, the first light blocking film And imageing sensor；Circuit network luminescence unit being had on described luminous plaque and driving each described luminescence unit；Described luminous list The light that unit sends projects to described screen panel direction；It is multiple transmission regions that described circuit network separates described luminous plaque；Institute State the first light blocking film and there is the first printing opacity aperture；The corresponding described transmission region in position and described first printing opacity keyhole formation light lead to Road；The light that described luminescence unit sends by described screen panel or outside object reflect, through described light-path It is radiated in described image sensor.

Optionally, also include the substrate being arranged between described first light blocking film and described image sensor；Described substrate is Light-passing board；The light that described luminescence unit sends through on described screen panel or outside object reflection, through described light Path and described substrate are radiated in described image sensor.

Optionally, also there is the first low-refraction photic zone between described substrate and described image sensor；Described luminous list The light that unit sends through on described screen panel or outside object reflection, through described light-path, described substrate and institute It is radiated in described image sensor after stating the first low-refraction photic zone.

Optionally, described first printing opacity aperture is arranged in array on described first light blocking film.

Optionally, described first printing opacity aperture is square opening or circular port；The image planes angle of visual field of described first printing opacity aperture For 2 α；The distance between adjacent described first printing opacity small hole center is d；The photosurface of described image sensor is saturating to described first The distance of light aperture is h；D and h meets d >=2htan α.

Optionally, the area of described first light blocking film is more than the area of described image sensor.

Optionally, a diameter of 1.0-50.0um of described first printing opacity aperture.

The utility model provides a kind of display screen, including the screen panel being cascading, luminous plaque and image sensing Device；Described luminous plaque is light tight；Luminescence unit and the second printing opacity aperture are had on described luminous plaque；Described luminescence unit sends Light projects to described screen panel direction；The light that described luminescence unit sends through on described screen panel or outside mesh Mark thing reflection, is radiated in described image sensor through described second printing opacity aperture.

Optionally, also include the substrate that is arranged between described luminous plaque and described image sensor；Described substrate is printing opacity Plate；The light that described luminescence unit sends by described screen panel or outside object reflect, saturating through described second It is radiated in described image sensor after light aperture and described substrate.

Optionally, also there is the first low-refraction photic zone between described substrate and described image sensor；Described luminous list The light that unit sends through on described screen panel or outside object reflection, through described second printing opacity aperture, described base It is radiated in described image sensor after plate and described first low-refraction photic zone.

Optionally, described second printing opacity aperture is arranged in array on described luminous plaque.

Optionally, the image planes angle of visual field of described second printing opacity aperture is 2 α；Between adjacent described second printing opacity small hole center Distance be d；The distance of the photosurface of described image sensor to described second printing opacity aperture is h；D and h meets d >=2htan α.

Optionally, the area of described luminous plaque is more than the area of described image sensor.

Optionally, a diameter of 1.0-50.0um of described second printing opacity aperture.

The above display screen that the utility model provides, has printing opacity aperture between luminous plaque and photosensitive imaging unit, lights Plate can pass through printing opacity aperture after being reflected to the light that screen panel sends.According to pinhole imaging system principle, through printing opacity aperture Light can be imaged on photoelectronic imaging unit, makes display screen have display function and image collecting function concurrently.

A kind of the utility model display screen of offer, the screen panel including stacked above one another setting and luminous plaque；Described luminous Circuit network luminescence unit being had on plate and driving each described luminescence unit；The light that described luminescence unit sends is to described screen The projection of curtain panel direction；It is multiple transmission regions that described circuit network separates described luminous plaque；Also include being arranged on described luminous plaque The narrow visual field pixel imageing sensor of side；The angle of visual field of each photosensitive pixel of described narrow visual field pixel imageing sensor is all little In 15 °；The light that described luminescence unit sends by described screen panel or outside object reflect, through described printing opacity It is radiated at behind region on described narrow visual field pixel imageing sensor.

Optionally, the photosensitive pixel side of described narrow visual field pixel imageing sensor has the second light blocking being sequentially arranged Film, transparent dielectric layer and lenticule；On described second light blocking film, there is the first loophole；Described lenticule, described transparent medium Layer and described first loophole constrain the angle of visual field of described photosensitive pixel less than 15 °；Have between described lenticule and described luminous plaque There is the second low-refraction photic zone；The light that described luminescence unit sends through on described screen panel or outside object anti- Penetrate, then in turn through described transmission region, described second low-refraction photic zone, described lenticule, described transparent dielectric layer It is radiated on described photosensitive pixel with described first loophole.

Optionally, described narrow visual field pixel imageing sensor has light blocking plate；Described light blocking plate is arranged on described luminous plaque And between described photosensitive pixel；On described light blocking plate, there is the second loophole；The thickness x of described second loophole and diameter y meetsThe light that described luminescence unit sends through on screen panel or outside object reflection, through described Light region, described second loophole are radiated on described photosensitive pixel.

Optionally, described narrow visual field pixel imageing sensor has light-conductive optic fibre；Described light-conductive optic fibre is arranged on described sending out Between tabula rasa and described photosensitive pixel；The end face acceptance angle of described light-conductive optic fibre is less than 15 °；The light warp that described luminescence unit sends On screen panel or outside object reflection, be radiated at described light-sensitive image through described transmission region and described light-conductive optic fibre In unit.

The above display screen that the utility model provides, luminous plaque can be by sending out after being reflected to the light that screen panel sends Transmission region on tabula rasa, and it is irradiated to imaging, therefore display screen on the photoelectric conversion unit of narrow visual field pixel imageing sensor Also display function and image collecting function are had concurrently.

Brief description

For being illustrated more clearly that background technology or the technical solution of the utility model, below to prior art or be embodied as The accompanying drawing being used in combination in mode is briefly described；It should be evident that the accompanying drawing below in conjunction with specific embodiment is only to use In conveniently understanding the utility model embodiment, for those of ordinary skill in the art, before not paying creative work Put, other accompanying drawings can also be obtained according to these accompanying drawings；

Fig. 1 is the structural representation of the existing optical fingerprint collector based on matrix form pinhole imaging system principle；

Fig. 2 is the display screen schematic cross-section shown in embodiment one；

Fig. 3 is luminous plaque planar structure schematic diagram in the display screen shown in embodiment one；

Fig. 4 is the display screen schematic cross-section shown in embodiment two；

Fig. 5 is the first light blocking film planar structure schematic diagram shown in embodiment two；

Fig. 6 is the first light blocking film planar structure schematic diagram in other embodiment；

Fig. 7 is the first light blocking film planar structure schematic diagram in other embodiment；

Fig. 8 is the display screen schematic cross-section shown in embodiment three；

Fig. 9 is the display screen schematic cross-section shown in example IV；

Figure 10 is the display screen schematic cross-section shown in embodiment five；

Figure 11 is the display screen schematic cross-section shown in embodiment six；

Figure 12 is the display screen schematic cross-section shown in embodiment seven；

Figure 13 is the display screen schematic cross-section shown in embodiment eight；

Figure 14 is the display screen schematic cross-section shown in embodiment nine；

Figure 15 is the display screen schematic cross-section shown in embodiment ten；

Wherein, Fig. 1: middle 01- light guide plate, 02- light source, 03- imaging layer, 04- imaging hole, 05- photosensory assembly；Fig. 2-Figure 15 In: 1- screen panel, 2- luminous plaque, 21- luminescence unit, 22- circuit network, 23- transmission region, 24- the second printing opacity aperture, 3- One light blocking film, 31- the first printing opacity aperture, 4- imageing sensor, 5- substrate, 6- the first low-refraction photic zone, the low folding of 7- second Penetrate rate photic zone, 8- lenticule, 9- transparent dielectric layer, 10- second light blocking film, 101- first loophole, 111- light blocking plate, 112- Second loophole, 113- light-conductive optic fibre.

Specific embodiment

Below in conjunction with the accompanying drawing in the utility model embodiment, the technical scheme in the utility model embodiment is carried out Describe in detail.

Embodiment one

Fig. 2 is the display screen schematic cross-section shown in embodiment one.As Fig. 2, the display screen in embodiment one includes screen Panel 1, luminous plaque 2, the first light blocking film 3 and imageing sensor 4；Screen panel 1, luminous plaque 2, the first light blocking film 3 and image pass Sensor 4 stacked above one another is arranged.Wherein: the circuit network 22 that luminous plaque 2 has luminescence unit 21 and drives each luminescence unit 21, light The light that plate 2 sends is to screen panel 1 direction transmission；It is multiple transmission regions 23 that circuit network 22 separates luminous plaque 2；First light blocking First printing opacity aperture 31 is had on film 3；Position corresponding transmission region 23 and the first printing opacity aperture 31 form light-path；Image passes Sensor 4 position correspondence generally corresponds to the first printing opacity aperture 31.

Fig. 3 is luminous plaque planar structure schematic diagram in the display screen shown in embodiment one.As can be seen from Figure 3, luminous plaque 2 In luminescence unit 21 and circuit network 22 is crisscross, separation luminous plaque 2 is multiple transmission regions 23, on the first light blocking film 3 First printing opacity aperture 31 is arranged on the downside of luminous plaque 2.

In the present embodiment, the body of luminous plaque 2 is a transparent panel, and opaque circuit network 22 is layered on body, incite somebody to action this Body is divided into multiple transmission regions 23.In other embodiments, luminous plaque 2 can also be done with expansion and understand, that is, luminous plaque 2 is permissible It is interpreted as that the luminescent layer between screen panel 1 and the first light blocking film 3, luminescence unit 21 and circuit network 22 are arranged on luminescent layer Middle luminescent layer is divided into multiple transmission regions 23；Certainly, also can load the transparent materials such as printing opacity glue in transmission region 23, load The transparent materials such as printing opacity glue can't affect the realization of display screen functions.

Using the display screen of aforementioned structure, the light that luminescence unit 21 sends projects to screen panel 1 direction, if screen There is on the upside of panel 1 object, some light will be reflected, re-enter in screen panel 1 by object.It is reflected into shielding Light in curtain panel 1 is radiated at image acquisition device 4 after the light-path that transmission region 23 and the first printing opacity aperture 31 are formed On.

According to pinhole imaging system principle, through the reflection light of the first printing opacity aperture 31, target is formed on imageing sensor 4 The inverted image of thing, light is changed the digital image information forming object by imageing sensor 4.

In the present embodiment, luminescence unit 21 can be Organic Light Emitting Diode (organic light-emitting Diode, oled).During normal use, each Organic Light Emitting Diode is controlled by circuit network 22 and assumes different luminances, Form display image；Now the function of display screen is same with the function phase of traditional oled display screen.Cover screen when there being object During curtain panel 1 top, after display screen detects object, circuit network 22 controls each Organic Light Emitting Diode to be switched to default sending out Light state.The reflected light that the light that each Organic Light Emitting Diode sends is formed after being reflected by the zones of different of object, passes through It is radiated at imageing sensor 4 after light-path to be imaged, realize the function that display screen gathers target object image.It should be noted herein that it is front State described Organic Light Emitting Diode and be switched to preset emission state, can be that all of Organic Light Emitting Diode is all luminous, It can be part organic light-emitting diode；If part organic light-emitting diode, luminous organic light-emitting diodes Pipe should should be uniformly distributed in whole region, it is basically identical, to avoid illumination irregular to make to project object luminous intensity everywhere Reduce picture quality.

Embodiment two

Fig. 4 is the display screen schematic cross-section shown in embodiment two.Embodiment two general structure and the structure of embodiment one Identical, the first light blocking film 3 being a difference in that in embodiment two has multiple first printing opacity apertures 31, each first printing opacity aperture 31 all corresponding with luminous plaque 2 transmission regions 23 form light-path, are radiated at figure through the light of each first printing opacity aperture 31 As the corresponding region of sensor 4.

In the present embodiment, each first printing opacity aperture 31 is respectively provided with the visual field of restriction, through each the first printing opacity aperture 31 Light is in the corresponding regional imaging of imageing sensor 4；The imaging sliceable synthesis target object image in each region.In the present embodiment, The image planes angle of visual field of each the first printing opacity aperture 31 is 2 α, and the distance between adjacent first printing opacity aperture 31 center is d, and image passes The distance of the photosurface of sensor 4 to the first printing opacity aperture is h, for ensureing two neighboring first printing opacity aperture 31 in imageing sensor Imaging is misaligned, d and h meets and should meet d >=2htan α.Certainly, in other embodiments also with for each the first printing opacity aperture 31 are respectively provided with independent image sensor 4.

Fig. 5 is the first light blocking film planar structure schematic diagram shown in embodiment two.As can be seen from Figure 5, on the first light blocking film 3 First printing opacity aperture 31 is square arrangement.In the present embodiment, two neighboring first printing opacity aperture 31 can be spaced multiple transmission regions 23, each transmission region 23 also can be made in other embodiments to correspond to a first printing opacity aperture 31.

Fig. 6-Fig. 7 is the first light blocking film planar structure schematic diagram in other embodiment.Find out from Fig. 6 and Fig. 7, the first resistance The first printing opacity aperture 31 on light film 3 also can be arranged according to rectangle, rhombus.Certainly, the structure of the first light blocking film 3 not only limiting In aforementioned several, alternatively other forms, if ensure between adjacent first printing opacity aperture 31 apart from d and the first printing opacity aperture 31 Meet d >=2htan α to the distance between imageing sensor 4 h.

In the present embodiment, the first printing opacity aperture can be circular port, alternatively other regular apertures such as square opening.

In addition, the area of the first light blocking film 3 can be more than the area of imageing sensor 4 in the present embodiment, spuious to prevent Light is irradiated to imageing sensor 4 from fringe region.Further, it is contemplated that technique for processing small hole, light transmission capacity and pinhole imaging system is clear Clear degree, the diameter of the first printing opacity aperture 31 is more suitable in 1.0-50.0um scope.

Embodiment three

Fig. 8 is the display screen schematic cross-section shown in embodiment three.As Fig. 8, the display screen structure in embodiment three is substantially Identical with display screen in embodiment two, it is a difference in that and be additionally provided with substrate 5, base between the first light blocking film 3 and imageing sensor 4 Plate 5 is transparent panel.Using the display screen in the present embodiment, the light of luminescence unit 21 transmitting by screen panel 1 or outside Object reflection after, be radiated on imageing sensor 4 after light-path and substrate 5.The substrate 5 of the present embodiment can play and prop up Support luminous plaque 2, the effect of connection imageing sensor 4.

Example IV

Fig. 9 is the display screen schematic cross-section shown in example IV.As Fig. 9, the display screen structure in example IV is substantially Identical with the display screen in embodiment three, it is a difference in that and be additionally provided with the first low-refraction between substrate 5 and imageing sensor 4 Photic zone 6.The first low-refraction photic zone 6 in the present embodiment can be air layer or vacuum layer.

Embodiment five

Figure 10 is the display screen schematic cross-section shown in embodiment five.As Figure 10, the display screen in the present embodiment includes shielding Curtain panel 1, luminous plaque 2 and imageing sensor 4, screen panel 1, luminous plaque 2 and imageing sensor 4 are cascading.Wherein, Luminous plaque 2 is light tight, and luminous plaque 2 has luminescence unit 21 and the second printing opacity aperture 24, the light that luminescence unit 21 sends to Screen panel 1 direction projects.

After the light that luminescence unit 21 sends projects to screen panel 1 direction, if there is target on the upside of screen panel 1 Thing, some light re-enters in screen panel 1 after being reflected by object.According to pinhole imaging system principle, it is reflected into Light in screen panel 1 is radiated on imageing sensor 4 through the second printing opacity aperture 24.

In the present embodiment, the image planes angle of visual field of the second printing opacity aperture 24 be 2 α, adjacent second printing opacity aperture 24 center it Between distance be d；The distance of the photosurface of imageing sensor 4 to the second printing opacity aperture 24 is h；For ensureing that two neighboring second is saturating Light aperture 24 is misaligned in imageing sensor 4 imaging region, d and h meets d >=2htan α.

In the present embodiment, the area of luminous plaque 2 is more preferably greater than the area of imageing sensor 4.Additionally, it is contemplated that little hole machined work The definition of skill, light transmission capacity and pinhole imaging system, the diameter of the second printing opacity aperture 24 is more suitable in 1.0-50.0um scope.

Embodiment six

Figure 11 is the display screen schematic cross-section shown in embodiment six.As Figure 11, the display screen structure in embodiment six is big Body is identical with display screen in embodiment five, is a difference in that between luminous plaque 2 and imageing sensor 4 and is provided with substrate 5, and substrate 5 is Transparent panel.Using the display screen in the present embodiment, the light of luminescence unit 21 transmitting by screen panel 1 or outside target After thing reflection, irradiate on imageing sensor 4 after the second printing opacity aperture 24 and substrate 5.The substrate 5 of the present embodiment can play and prop up Support luminous plaque 2, the effect of connection imageing sensor 4.

Embodiment seven

Figure 12 is the display screen schematic cross-section shown in embodiment seven.As Figure 12, the display screen structure in example IV is big Body is identical with the display screen in embodiment six, is a difference in that and is additionally provided with the first low refraction between substrate 5 and imageing sensor 4 Rate photic zone 6.The first low-refraction photic zone 6 in the present embodiment can be air layer or vacuum layer.

Embodiment eight

Figure 13 is the display screen schematic cross-section shown in embodiment eight.Display screen in the present embodiment includes stacking gradually and sets The screen panel 1 put and luminous plaque 2, luminous plaque 2 has luminescence unit 21 and transmission region 23, the light that luminescence unit 21 sends To the projection of screen cover plate direction.Additionally, the display screen in the present embodiment also has the narrow visual field pixel being arranged on luminous plaque 2 side Imageing sensor, the light that luminescence unit 21 sends through on screen panel 1 or outside object transmitting after, through transparent area Domain 23 is radiated on the photosensitive pixel of narrow visual field pixel imageing sensor.

As Figure 13, the narrow visual field pixel imageing sensor in the present embodiment has the second resistance being arranged on photosensitive pixel side Light film 10, transparent dielectric layer 9 and lenticule 8.First loophole 101 is had on the second light blocking film 10.Lenticule 8, transparent medium Layer 9 and the first loophole 101 constrain the image planes angle of visual field of light-sensitive image unit less than 15 °.In addition have between lenticule 8 and luminous plaque 2 Have the second low-refraction photic zone 7, the light that luminescence unit 21 sends through on screen panel 1 or outside object reflection, Then in turn through transmission region 23, the second low-refraction photic zone 7, lenticule 8, transparent dielectric layer 9 and the first loophole 101 Area is radiated on photosensitive pixel 4.

Embodiment nine

Figure 14 is the display screen schematic cross-section shown in embodiment nine.Narrow visual field imageing sensor in the present embodiment has Light blocking plate 111, light blocking plate 111 offers the second loophole 112.The thickness x of the second loophole 112 and diameter y meetsThe light that luminescence unit 21 sends through on screen panel 1 or outside object reflection, sequentially pass through On the photosensitive pixel that light region 23, the second loophole 112 are radiated at.In addition, it is saturating to be provided with the second low-refraction in the present embodiment Photosphere 7, also can be not provided with the second low-refraction photic zone 7.

Embodiment ten

Figure 15 is the display screen schematic cross-section shown in embodiment ten.Display screen general structure in the present embodiment and enforcement In example 11, display screen structure is identical, is a difference in that: narrow visual field imageing sensor also has light-conductive optic fibre 113, light-conductive optic fibre 113 end face acceptance angle is less than 15 °, and light-conductive optic fibre 113 is arranged between luminous plaque 2 and imageing sensor 4.Luminescence unit 21 sends Light through on screen panel 1 or outside object reflection, sequentially pass through transmission region 23, light-conductive optic fibre 113 is radiated at On imageing sensor 4.

Above the display screen in the utility model embodiment is described in detail.This part adopts specific embodiment pair Principle of the present utility model and embodiment are set forth, and the explanation of above example is only intended to help and understands that this practicality is new The core concept of type, in the case of without departing from the utility model principle, those of ordinary skill in the art are not making creation Property work under the premise of the every other embodiment that obtained, broadly fall into the scope of the utility model protection.

Claims (18)

1. a kind of display screen it is characterised in that: include the screen panel, luminous plaque, the first light blocking film and the figure that are cascading As sensor；Circuit network luminescence unit being had on described luminous plaque and driving each described luminescence unit；Described luminescence unit is sent out The light going out projects to described screen panel direction；It is multiple transmission regions that described circuit network separates described luminous plaque；Described One light blocking film has the first printing opacity aperture；The corresponding described transmission region in position and described first printing opacity keyhole formation light-path； The light that described luminescence unit sends by described screen panel or outside object reflect, irradiate through described light-path In described image sensor.

2. display screen according to claim 1 it is characterised in that: also include being arranged on described first light blocking film and described figure As the substrate between sensor；Described substrate is light-passing board；The light that described luminescence unit sends through on described screen panel or Outside object reflection, be radiated in described image sensor through described light-path and described substrate.

3. display screen according to claim 2 it is characterised in that: also have between described substrate and described image sensor One low-refraction photic zone；The light that described luminescence unit sends through on described screen panel or outside object reflection, It is radiated in described image sensor after described light-path, described substrate and described first low-refraction photic zone.

4. display screen according to claim 1 it is characterised in that: described first printing opacity aperture is on described first light blocking film It is arranged in array.

5. display screen according to claim 1 it is characterised in that: described first printing opacity aperture be square opening or circular port； The image planes angle of visual field of described first printing opacity aperture is 2 α；The distance between adjacent described first printing opacity small hole center is d；Described figure Distance as photosurface to the described first printing opacity aperture of sensor is h；D and h meets d >=2h tan α.

6. display screen according to claim 1 it is characterised in that: the area of described first light blocking film be more than described image pass The area of sensor.

7. display screen according to claim 1 it is characterised in that: a diameter of 1.0- of described first printing opacity aperture 50.0um.

8. a kind of display screen it is characterised in that: include the screen panel, luminous plaque and the imageing sensor that are cascading；Institute State luminous plaque light tight；Luminescence unit and the second printing opacity aperture are had on described luminous plaque；The light that described luminescence unit sends To the projection of described screen panel direction；The light that described luminescence unit sends through on described screen panel or outside object Reflection, is radiated in described image sensor through described second printing opacity aperture.

9. display screen according to claim 8 it is characterised in that: also include being arranged on described luminous plaque and described image pass Substrate between sensor；Described substrate is light-passing board；The light that described luminescence unit sends by described screen panel or outside Object reflection, be radiated in described image sensor after described second printing opacity aperture and described substrate.

10. display screen according to claim 9 it is characterised in that: also have between described substrate and described image sensor First low-refraction photic zone；The light that described luminescence unit sends through on described screen panel or outside object anti- Penetrate, be radiated at described image sensing after described second printing opacity aperture, described substrate and described first low-refraction photic zone On device.

11. display screens according to claim 8 it is characterised in that: described second printing opacity aperture is on described luminous plaque Array arrangement.

12. display screens according to claim 8 it is characterised in that: the image planes angle of visual field of described second printing opacity aperture be 2 α； The distance between adjacent described second printing opacity small hole center is d；The photosurface of described image sensor is little to described second printing opacity The distance in hole is h；D and h meets d >=2h tan α.

13. display screens according to claim 8 it is characterised in that: the area of described luminous plaque be more than described image sense The area of device.

14. display screens according to claim 8 it is characterised in that: a diameter of 1.0- of described second printing opacity aperture 50.0um.

A kind of 15. display screens, the screen panel including stacked above one another setting and luminous plaque；On described luminous plaque, there is luminescence unit With the circuit network driving each described luminescence unit；The light that described luminescence unit sends projects to described screen panel direction；Its It is characterised by: it is multiple transmission regions that described circuit network separates described luminous plaque；Also include being arranged on described luminous plaque side Narrow visual field pixel imageing sensor；The angle of visual field of each photosensitive pixel of described narrow visual field pixel imageing sensor is respectively less than 15 °； The light that described luminescence unit sends by described screen panel or outside object reflect, after described transmission region It is radiated on described narrow visual field pixel imageing sensor.

16. display screens according to claim 15 it is characterised in that: the light-sensitive image of described narrow visual field pixel imageing sensor First side has the second light blocking film, transparent dielectric layer and the lenticule being sequentially arranged；Have first saturating on described second light blocking film Unthreaded hole；The angle of visual field that described lenticule, described transparent dielectric layer and described first loophole constrain described photosensitive pixel is less than 15°；There is between described lenticule and described luminous plaque the second low-refraction photic zone；The light that described luminescence unit sends is through institute State on screen panel or outside object reflection, saturating then in turn through described transmission region, described second low-refraction Photosphere, described lenticule, described transparent dielectric layer and described first loophole are radiated on described photosensitive pixel.

17. display screens according to claim 15 it is characterised in that: described narrow visual field pixel imageing sensor has light blocking Plate；Described light blocking plate is arranged between described luminous plaque and described photosensitive pixel；On described light blocking plate, there is the second loophole；Described The thickness x of the second loophole and diameter y meetsThe light that described luminescence unit sends through screen panel on Or outside object reflection, be radiated on described photosensitive pixel through described transmission region, described second loophole.

18. display screens according to claim 15 it is characterised in that: described narrow visual field pixel imageing sensor has leaded light Optical fiber；Described light-conductive optic fibre is arranged between described luminous plaque and described photosensitive pixel；The end face acceptance angle of described light-conductive optic fibre is little In 15 °；The light that described luminescence unit sends through on screen panel or outside object reflection, through described transmission region It is radiated on described photosensitive pixel with described light-conductive optic fibre.