CN112399040A - Divide visual field imaging module and terminal equipment - Google Patents

Abstract

The embodiment of the application discloses divide visual field imaging module and terminal equipment includes: the prism and the at least two imaging modules; the prism is positioned above the at least two imaging modules and used for adjusting the direction of light rays emitted from the prism to be vertical to the at least two imaging modules; and a lens group is arranged between the prism and the at least two imaging modules and is used for respectively converging the object field light to the corresponding imaging modules. The field light rays in different directions are respectively adjusted to be vertical light rays through the prism surfaces of the prisms at different angles, and then the vertical light rays are respectively emitted into the corresponding imaging modules for imaging. Each prism surface of the prism for adjusting light corresponds to one sub-field area, and each sub-field area corresponds to one imaging module. The target object is divided into a plurality of sub-view fields to be respectively imaged on the corresponding imaging modules, and finally the partial images of the target object obtained on the imaging modules are spliced into a complete target object image through image processing.

Description

Divide visual field imaging module and terminal equipment

Technical Field

The application relates to the technical field of display screens, in particular to a split view field imaging module and terminal equipment.

Background

The existing mobile terminal, such as a mobile phone and the like, hopes to achieve a comprehensive screen design, and integrates fingerprint identification and a front camera under a display screen without influencing display. In the prior art, there is a technology of integrating fingerprint recognition under a display screen, for example, in the prior patent CN201710086890.6, a Matrix Pinhole Imaging System (MAPIS) is proposed for collecting surface images of an object at a short distance, such as fingerprint images and face images. The MAPI can be applied to various electronic devices such as mobile phones, tablet computers and smart bands.

MAPIS generally includes an orifice plate and an image sensor. The small pore plate is provided with a plurality of imaging holes. The image sensor is disposed at one side of the aperture plate and corresponds to a position of the imaging aperture. Thus, according to the pinhole imaging principle, light on the target on the other side of the pinhole plate can pass through the imaging hole to form an inverted image of the target on the image sensor. The light passing through each imaging aperture can form a corresponding image on the image sensor, and the images can be spliced to obtain a relatively complete image of the target object.

However, since the transmittance of the imaging aperture is limited, the intensity of light passing through the imaging aperture is reduced, and is difficult to be received by the image sensor, and is easily submerged in the thermal noise of the image sensor.

Disclosure of Invention

The application provides a divide visual field imaging module and terminal equipment to solve above-mentioned technical problem.

Please disclose a first aspect in itself discloses a split view imaging module, including: a prism 1 and at least two imaging modules 2;

the prism 1 is positioned above the at least two imaging modules 2, and the prism 1 is used for adjusting the direction of light rays emitted from the prism 1 to be vertical to the at least two imaging modules 2;

a lens group 3 is arranged between the prism 1 and the at least two imaging modules 2, and the lens group 3 is used for respectively converging the object space view field light rays to the corresponding imaging modules 2.

Further, each of the imaging modules 2 corresponds to an image sensor.

Further, all the imaging modules 2 correspond to one image sensor.

Further, the lens group 3 includes at least one of the following three: each imaging module 2 corresponds to one fresnel zone plate, fresnel lens or convex lens.

Further, each of the imaging modules 2 corresponds to three image sensors for receiving red light, green light and blue light, respectively.

Further, the lens group 3 includes at least one of the following three: each image sensor corresponds to one Fresnel zone plate or Fresnel lens or convex lens.

Further, a field diaphragm 4 is arranged between two adjacent imaging modules 2.

Further, the prism 1 employs a micro-scale prism film or a nano-scale prism film.

Further, the number of the imaging modules 2 is three.

The second aspect of the present application discloses a terminal device, which includes a display screen 5 and the field-of-view imaging module, wherein an intra-screen micro-pore matrix 6 is disposed in the display screen 5, and the field-of-view imaging module is located below the intra-screen micro-pore matrix 6.

The application provides a pair of divide visual field imaging module and terminal equipment, prism 1's effect is that the light of adjusting different visual field angles is perpendicular light, and lens group 3's effect is that the visual field light that corresponds with every imaging module 2 assembles on the imaging module 2 that corresponds to obtain clear image. The structure of the prism 1 is determined according to the number of the imaging modules 2 and the positions of the imaging modules 2, the viewing field light rays in different directions are respectively adjusted to be vertical light rays through the prism surfaces of the prism 1 at different angles, and then the vertical light rays are respectively emitted into the corresponding imaging modules 2 to be imaged. Each prism surface of the prism 1 for adjusting light corresponds to one sub-field of view area, and each sub-field of view area corresponds to one imaging module 2. The target object is divided into a plurality of sub-fields of view to be imaged on the corresponding imaging modules 2 respectively, and finally the partial images of the target object obtained on the imaging modules 2 are spliced into a complete target object image through image processing.

Drawings

In order to more clearly explain the technical solution of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious to those skilled in the art that other drawings can be obtained according to the drawings without any creative effort.

Fig. 1 is a schematic structural diagram of a split-field imaging module disclosed in an embodiment of the present application;

fig. 2 is a schematic structural diagram of another split-field imaging module disclosed in the embodiment of the present application;

fig. 3 is a schematic structural diagram of another split-field imaging module disclosed in the embodiment of the present application;

fig. 4 is a schematic structural diagram of another split-field imaging module disclosed in the embodiment of the present application;

fig. 5 is a schematic layout view of image sensors in a split-field imaging module according to an embodiment of the present disclosure;

fig. 6 is a schematic structural diagram of a terminal device disclosed in an embodiment of the present application.

Description of the reference numerals

1. A prism; 2. an imaging module; 3. a lens group; 4. a field stop; 5. a display screen; 6. an intra-screen micropore matrix; 7. and (5) sealing.

Detailed Description

The following provides a detailed description of the embodiments of the present application. In the description of the present application, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience of description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be construed as limiting the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1, in a first embodiment of the present application, a split-field imaging module is provided, including: a prism 1 and at least two imaging modules 2; the prism 1 is positioned above the at least two imaging modules 2, and the prism 1 is used for adjusting the direction of light rays emitted from the prism 1 to be vertical to the at least two imaging modules 2; a lens group 3 is arranged between the prism 1 and the at least two imaging modules 2, and the lens group 3 is used for respectively converging the object space view field light rays to the corresponding imaging modules 2.

The sub-field imaging module of the embodiment of the application divides a target into a plurality of sub-fields to respectively image on the corresponding imaging modules 2, and finally splices partial images of the target obtained on each imaging module 2 into a complete target image through image processing.

The prism 1 is used for adjusting light rays with different view field angles into vertical light rays, and the vertical light rays are vertical to the upper surface of the imaging module 2 after the light rays are emitted out through the prism 1. If the object space view field is divided into a forward view field and an oblique view field, wherein the forward view field refers to a view field in which light reflected by the object is perpendicular to the horizontal direction of the imaging module 2, the oblique view field refers to a view field in which light reflected by the object has an included angle with the horizontal direction of the imaging module 2 but is not perpendicular, and the prism 1 can adjust light corresponding to the oblique view field to be perpendicular to the horizontal direction of the imaging module 2. The light rays entering the imaging module 2 are all adjusted to be vertical light rays, so that the design of the lens group 3 is facilitated.

The lens group 3 is used for converging the field light corresponding to each imaging module 2 onto the corresponding imaging module 2 to obtain a clear image.

Lens group 3 comprises the structure that can realize assembling light, and the structure that assembles light can select for use: fresnel zone plate, Fresnel lens or convex lens, it can be understood that, lens group 3 can all select for use one of Fresnel zone plate, Fresnel lens or convex lens three, can select for use two arbitrary in Fresnel zone plate, Fresnel lens and convex lens three, also can Fresnel zone plate, Fresnel lens and convex lens three select for use simultaneously, and this application does not prescribe a limit to the combination of specifically selecting for use of lens group 3, can select by oneself according to actual conditions.

It should be noted that when there is a high demand for the lens assembly 3, the above-mentioned structure (e.g. fresnel zone plate, fresnel lens or convex lens) capable of converging light rays in micro-scale or nano-scale may be adopted.

The structural design of the prism 1 corresponds to the number of the imaging modules 2, and the structure of the prism 1 can ensure that the light rays entering each imaging module are vertical light rays.

As an example, when there are three imaging modules 2, as shown in fig. 1, the cross section of the prism 1 is trapezoidal, and the oblique light emitted from the left object space view field is refracted by the b-plane of the prism 1 and then adjusted to be a vertical light; the oblique light rays emitted from the right object space view field are also adjusted to be vertical light rays after being refracted by the surface a of the prism 1, and the light rays emitted from the front view field are still vertical light rays after passing through the surface c of the prism 1 (the surface c is parallel to the horizontal direction of the imaging module 2).

The vertical light rays emitted after being refracted by the surfaces a, b and c of the prisms 1 are converged on the corresponding imaging modules 2 to be imaged through the fresnel zone plate, the fresnel lens or the convex lens arranged above the corresponding imaging modules 2. In this example, an a partial image of the target object is obtained on the first imaging module 2, a B partial image of the target object is obtained on the second imaging module 2, and a C partial image of the target object is obtained on the third imaging module 2, where the a part, the B part, and the C part form a complete target object, and the partial images obtained by the three imaging modules 2 are spliced into a complete target object image through image processing.

Therefore, the structure of the prism 1 is determined according to the number of the imaging modules 2 and the positions of the imaging modules 2, the field light in different directions is respectively adjusted to be vertical light through the prism surfaces of the prism 1 in different angles, and then the vertical light is respectively emitted into the corresponding imaging modules 2 for imaging. Each prism surface of the prism 1 for adjusting light corresponds to one sub-field of view area, and each sub-field of view area corresponds to one imaging module 2.

As shown in fig. 2-4, three other realizations of the prism 1 are provided, the working principle of the prism 1 is the same as that of the prism 1 provided in the above example, and the prisms with different angles of the prism 1 are used to adjust the light propagation direction of the object field of view, so that the light is all adjusted to be vertical.

It should also be noted that when higher demands are made on the prism 1, micro-or nano-scale prism films may be used.

It should be noted that, in the above embodiment, only three imaging modules 2 are illustrated, but actually, at least two imaging modules 2 may be provided, and the design may be selected according to actual situations. The structure of the prism 1 is not limited to the structure exemplified in the above embodiments, and may be modified according to the operation principle thereof, which is not limited in the present application.

The imaging modules 2 are used to capture images, and in one implementation, each of the imaging modules 2 corresponds to an image sensor. In this case, a light converging structure is correspondingly disposed above each image sensor (taking the fresnel zone plate as an example for each light converging structure), and the vertical light adjusted by the prism 1 is converged onto the corresponding image sensor through the corresponding fresnel zone plate. Referring to fig. 2, the three-dimensional image sensor system comprises three image sensors, a fresnel zone plate is correspondingly arranged above each image sensor, the fresnel zone plate converges corresponding vertical light rays on the corresponding image sensor, a target object is divided into three parts to be imaged on the corresponding image sensor, each image sensor acquires partial images of the target object, and finally, a complete image of the target object is obtained through image processing. The advantage of this realisation is that it is not necessary to use a large area image sensor.

In another implementation manner, all the imaging modules 2 correspond to one image sensor, and it can be understood that one image sensor is divided into a plurality of imaging modules 2, a structure for converging light rays is respectively arranged on the corresponding imaging modules 2 (taking the example that each structure for converging light rays selects a fresnel zone plate), and the vertical light rays adjusted by the prism 1 converge the vertical light rays onto the corresponding imaging modules 2 through the corresponding fresnel zone plates. A fresnel zone plate is correspondingly arranged above each imaging module 2, the fresnel zone plate converges corresponding vertical light rays onto the corresponding imaging module 2, a target object is divided into three parts to be imaged on an image sensor, the image sensor is divided into three areas to respectively acquire partial images of the target object, and finally, a complete image of the target object is obtained through image processing. This implementation has the advantage that only one image sensor is required, facilitating installation.

In the two ways, the obtained image can be a black and white image, and is preferably suitable for collecting a fingerprint image. When the object is a person, a scene, or the like, a color image is more desirable, and therefore, the following realizable manner is provided for the imaging module 2.

Each of the imaging modules 2 corresponds to three image sensors for receiving red light, green light, and blue light, respectively. As shown in fig. 5, each imaging module 2 corresponds to one sub-field of view region, each sub-field of view region corresponds to three image sensors, and each image sensor is correspondingly provided with a structure for converging corresponding light rays, such as: fresnel zone plate, or fresnel lens or convex lens, etc. The description will be given by taking an example in which one fresnel zone plate is correspondingly disposed on each image sensor. In a view field division area, an imaging module 2 is correspondingly arranged, the imaging module 2 comprises three image sensors, corresponding Fresnel zone plates are arranged on the corresponding image sensors according to the difference of received red light, green light and blue light, the red light, the green light and the blue light are respectively converged on the corresponding image sensors, a color image of a target object corresponding to the view field division area is obtained through image processing, color images of the target object corresponding to the rest view field division areas are obtained according to the method, and finally, a complete color image of the target object is obtained through image processing. In fig. 5, R denotes an image sensor receiving red light, G denotes an image sensor receiving green light, and B denotes an image sensor receiving blue light.

It should be noted that the fresnel zone plate is usually used to collect monochromatic light with a fixed wavelength, such as red light, green light or blue light, and therefore, when the fresnel zone plate is selected, it is mainly used to collect the monochromatic light, as shown in fig. 5. However, when monochromatic light is collected, it is not limited to using only a fresnel zone plate, and a fresnel lens, a convex lens, or the like may be used. It should be noted that the arrangement of the image sensors is not limited in this application, and as shown in fig. 5, the image sensors may be arranged in a matrix.

In order to isolate stray light, astigmatism and adjacent sub-field aliasing, a field diaphragm 4 is arranged between the adjacent imaging modules 2, the height of the field diaphragm 4 can be set appropriately according to actual conditions, and the lens group 3 can be arranged on the field diaphragm 4.

Furthermore, the outer side of the sub-view-field imaging module is provided with a sealing glue 7, and the sealing glue 7 is opaque and used for fixing the sub-view-field imaging module.

Referring to fig. 6, in a second embodiment of the present application, a terminal device is provided, which includes a display screen 5 and the split-field imaging module according to the first embodiment, an intra-screen micro-pore matrix 6 is disposed in the display screen 5, and the split-field imaging module is located below the intra-screen micro-pore matrix 6.

The terminal device may be any device that can use the imaging module for image acquisition, such as a mobile phone, a computer, a tablet computer, a camera, a video camera, a scanner, and so on.

The sub-view field imaging module is applied to the terminal equipment, which is equivalent to a screen lower camera, and the comprehensive screen lower camera of the terminal equipment is realized. Be equipped with in the display screen 5 and screen micropore matrix 6, the light outside the display screen 5 jets into the display screen 5 through micropore matrix 6, however, the luminousness of micropore matrix 6 is limited in the screen, in order to assemble the energy of large tracts of land and image, this application utilizes the branch visual field imaging module, through dividing into a plurality of branch visual fields with the target object and forming images respectively on corresponding imaging module 2, finally splice into a complete target object image through the target object part image that image processing obtained on with each imaging module 2. The light rays of each sub-field are respectively converged and imaged by utilizing limited light transmittance, so that a clear and complete target object image is obtained.

The split view field imaging module is arranged below the display screen 5, the position of the split view field imaging module corresponds to the position of a micropore matrix 6 in the screen, the split view field imaging module can be fixed below the display screen 5 through a sealing adhesive 7, the prism 1 is arranged between the display screen 5 and at least two imaging modules 2, the lens group 3 is arranged between the prism 1 and at least two imaging modules 2, and the prism 1 is used for adjusting the direction of light rays emitted from the prism 1 to be perpendicular to the at least two imaging modules 2; the lens group 3 is used for converging the object field light rays to the corresponding imaging modules 2 respectively.

For a detailed description of the split-field imaging module, refer to the first embodiment provided in the present application, and will not be described herein again.

The same and similar parts in the various embodiments in this specification may be referred to each other. The present application has been described in detail with reference to specific embodiments and illustrative examples, but the description is not intended to limit the application. Those skilled in the art will appreciate that various equivalent substitutions, modifications or improvements may be made to the presently disclosed embodiments and implementations thereof without departing from the spirit and scope of the present disclosure, and these fall within the scope of the present disclosure. The protection scope of this application is subject to the appended claims.

The above-described embodiments of the present application do not limit the scope of the present application.

Claims (10)

1. The utility model provides a divide visual field imaging module which characterized in that includes: a prism (1) and at least two imaging modules (2);

the prism (1) is positioned above the at least two imaging modules (2), and the prism (1) is used for adjusting the direction of light rays emitted from the prism (1) to be perpendicular to the at least two imaging modules (2);

a lens group (3) is arranged between the prism (1) and the at least two imaging modules (2), and the lens group (3) is used for respectively converging the object field light rays to the corresponding imaging modules (2).

2. The divided field of view imaging module of claim 1, wherein each imaging module (2) corresponds to an image sensor.

3. The divided field of view imaging module of claim 1, wherein all of said imaging modules (2) correspond to one image sensor.

4. The split field imaging module of claim 2 or 3, wherein said lens group (3) comprises at least one of: the Fresnel lens system comprises Fresnel zone plates, Fresnel lenses and convex lenses, wherein each imaging module (2) corresponds to one Fresnel zone plate or one Fresnel lens or one convex lens.

5. The divided field of view imaging module of claim 1, wherein each of said imaging modules (2) corresponds to three image sensors for receiving red, green and blue light, respectively.

6. The split field imaging module of claim 5, wherein said lens group (3) comprises at least one of: each image sensor corresponds to one Fresnel zone plate or Fresnel lens or convex lens.

7. The field-of-view imaging module according to claim 1, wherein a field stop (4) is arranged between two adjacent imaging modules (2).

8. The split-field imaging module of claim 1, wherein said prism (1) is a micro-prism film or a nano-prism film.

9. The split field imaging module as set forth in claim 1, wherein the number of imaging modules (2) is three.

10. Terminal equipment, characterized by, including display screen (5) and the branch visual field imaging module of any of claims 1-8, be equipped with in-screen micropore matrix (6) in display screen (5), branch visual field imaging module is located in-screen micropore matrix (6) below.

Images