RU2779261C1 - Multilayer structure, display panel and electronic device - Google Patents

Abstract

FIELD: display technologies.

SUBSTANCE: invention relates to the field of display technologies. The multilayer structure includes a protective layer, a linearly polarizing layer and a quarter-wave plate, which are layered one after the other. The protective layer is used to polarize the light beam to form a linearly polarized light beam. The angle between the absorption axis of the protective layer and the absorption axis of the linearly polarizing layer is zero degrees. The angle between the absorption axis of the linearly polarizing layer and the absorption axis of the quarter-wave plate is 45 degrees.

EFFECT: invention provides an increase in the stability of the transmission of the light beam and the accuracy of recognition performed by the optical recognition module.

11 cl, 12 dwg

Description

Cross-reference to related application

This application claims the priority of Chinese Patent Application No. 201910415213.3, filed with the National Intellectual Property Office of China on May 17, 2019, entitled "MULTI-LAYER STRUCTURE, DISPLAY PANEL AND ELECTRONIC DEVICE", which is hereby incorporated by reference in its entirety.

The field of technology to which the invention belongs

The present invention relates in general to the field of display technologies, and in particular to a multilayer structure, a display panel and an electronic device.

State of the art

Recently, more and more electronic devices are equipped with optical fingerprint recognition modules located under the display panel to make it easier for users to unlock electronic devices. The light beam must pass through multilayer layers such as the protective layer, the linear polarizing layer, and the quarter-wave plate of the display panel before reaching the optical fingerprint recognition module. However, due to differences in the materials of the display panel multilayers, this affects the stability of the light transmission of the display panel, resulting in poor stability of the intensity of the light beam entering the optical fingerprint recognition module and lowering the accuracy of the recognition performed by the optical fingerprint recognition module.

The essence of the invention

The technical problem to be solved by the embodiments of the present application is related to the multilayer structure, the display panel and the electronic device, which can improve the stability of the transmission of the light beam.

In order to solve the above problem, the following technical solutions are used in the implementations of the present application:

According to the first aspect, the implementation of the present application provides a multilayer structure including a protective layer, a linearly polarizing layer and a quarter-wave plate, which are layered one after the other. The protective layer is used to polarize the light beam to form a linearly polarized light beam. The angle between the absorption axis of the protective layer and the absorption axis of the linearly polarizing layer is zero degrees. The angle between the absorption axis of the linearly polarizing layer and the absorption axis of the quarter-wave plate is 45 degrees.

In this implementation, the angle between the absorption axis of the linearly polarizing layer and the absorption axis of the protective layer is zero degrees, and there is no difference between the direction of the absorption axis of the protective layer and the direction of the absorption axis of the linearly polarizing layer. Thus, the light flux passing through the protective layer is approximately the same as the light flux passing through the linearly polarizing layer. In other words, the intensity of the light beam passing through the protective layer corresponds to the intensity of the light beam passing through the linearly polarizing layer. Thus, it is possible to reduce the loss of light when passing a light beam in the multilayer structure, and it is possible to improve the stability of the transmission of the light beam in the multilayer structure, so as to stabilize the intensity of the light beam passing through the multilayer structure and improve the stability of the light beam entering the optical fingerprint recognition module. , thereby improving the accuracy of the recognition performed by the optical fingerprint recognition module.

In a possible implementation, the multilayer structure further includes a reinforcing layer, and the reinforcing layer is placed between the protective layer and the linearly polarizing layer and is used to protect the multilayer structure and increase the strength of the multilayer structure.

In a possible implementation, the strength of the material of the reinforcing layer is greater than that of the protective layer.

In a possible implementation, the reinforcing layer is made of an isotropic material to reduce light loss during transmission of a light beam in a multilayer structure and increase the stability of the transmission of a light beam.

In a possible implementation, the linearly polarizing layer is attached to the reinforcing layer by means of an optical adhesive layer to increase the strength of the connection between the linearly polarizing layer and the reinforcing layer.

In an exemplary embodiment, the optical adhesive layer is made of an isotropic material to further reduce light transmission loss in the multilayer structure and improve the stability of the light beam transmission.

In a possible implementation, the reinforcing layer is a glass protective plate to increase the strength and protective characteristics of the multilayer structure; and the protective layer is a film layer attached to one side of the reinforcing layer away from the linearly polarizing layer to prevent scratches and wear of the reinforcing layer.

In a possible implementation, the reinforcing layer is used to polarize the light beam to form a linearly polarized light beam. The angle between the absorption axis of the reinforcing layer and the absorption axis of the linearly polarizing layer is zero degrees. The reinforcing layer is arranged as a multilayer layer in the direction corresponding to the direction of the absorption axis of the linearly polarizing layer, so that the optical characteristics of the reinforcing layer, the protective layer and the linearly polarizing layer can be matched, and the intensity of the light beam passing through the protective layer corresponds to the intensity of the light beam passing through through the reinforcing layer and the linearly polarizing layer, thereby increasing the stability of the transmission of the light beam.

In a possible implementation, the protective layer is a protective plate, and the protective layer is made of a material including ceramic and plastic, which helps to reduce the thickness of the multilayer structure while increasing the strength of the protective layer.

In a possible implementation, the protective layer is made of materials including polyethylene terephthalate plastic and thermoplastic polyurethane elastomer rubber.

According to the second aspect, the present application further provides a display panel applied to an electronic device with an optical fingerprint recognition module. The display panel includes a functional substrate and the aforementioned layer structure, which are layered. The functional substrate is located on one side of the quarter-wave plate at some distance from the protective layer, and the functional substrate has a light-transmitting area so that the light coming from the quarter-wave plate enters the optical fingerprint recognition module through the light-transmitting area.

In this implementation, the angle between the absorption axis of the protective layer located on the outer side of the display panel and the absorption axis of the linearly polarizing layer is zero degrees, and there is no difference between the direction of the absorption axis of the protective layer and the direction of the absorption axis of the linearly polarizing layer. Thus, the light flux passing through the protective layer is approximately the same as the light flux passing through the linearly polarizing layer. In other words, the intensity of the light beam passing through the protective layer corresponds to the intensity of the light beam passing through the linearly polarizing layer. In this way, it is possible to reduce the loss of light when the light beam passes through the display panel, and it is possible to improve the stability of the light beam transmission of the display panel in order to stabilize the intensity of the light beam entering the optical fingerprint recognition module through the light transmission area of the functional substrate and improve the stability of the light beam. beam entering the optical fingerprint recognition module, thereby improving the accuracy of the recognition performed by the optical fingerprint recognition module.

In addition, linearly polarized light passing through the protective layer becomes circularly polarized light passing through the linearly polarizing layer and the quarter-wave plate. A portion of the circularly polarized light beam is reflected as a reverse polarized light beam due to a reflective structure on the display panel (such as a metal portion of the functional substrate or an interface between adjacent multilayer layers). The reverse polarized light beam is further rotated by 45 degrees after falling onto the quarter-wave plate to become linearly polarized light perpendicular to the direction of the absorption axis of the linearly polarizing layer. Thus, reflected light reflected from the reflective structure of the display panel can be effectively suppressed, thereby improving the display and visual effects of the display panel.

In a possible implementation, the functional substrate includes a first light transmitting layer, a plurality of reflective elements, and a second light transmitting layer. A plurality of reflective elements are located at intervals from each other on the first light transmitting layer, the second light transmitting layer covers the reflective elements and the first light transmitting layer, and the second light transmitting layer is located between the quarter wave plate and the first light transmitting layer. Since the first light transmitting layer and the second light transmitting layer are arranged around the reflective members, the collision impact of the laminate structure can be damped, which is useful for extending the service life of the laminate structure.

In a possible implementation, both the first light transmitting layer and the second light transmitting layer are made of isotropic materials in order to further reduce the loss of light when a light beam passes through the multilayer structure and increase the stability of the intensity of the light beam passing through the multilayer structure, thereby increasing the recognition accuracy, performed by the optical fingerprint recognition module.

In a possible implementation, the first light transmitting layer and the second light transmitting layer are made of resin.

In a possible implementation, the reflective elements are configured to emit a light beam. When a finger touches one side of the protective layer away from the linear polarizing layer, or when the finger is at a certain distance from one side of the protective layer away from the linearly polarizing layer, the light emitted by the reflective elements may be reflected from the finger and enter the optical fingerprint recognition module. fingers through the light-transmitting area, thereby completing the optical fingerprint recognition function.

In a possible implementation, the display panel further includes a sensor layer placed between the functional substrate and the quarter wave plate.

According to a third aspect, an implementation of the present application further provides an electronic device including the above-mentioned multilayer structure and an optical fingerprint recognition module. The optical fingerprint recognition module is located on one side of the functional substrate at some distance from the protective layer and is configured to receive a light beam passing through the light-transmitting zone of the functional substrate.

In this implementation, the angle between the absorption axis of the protective layer located on the outer side of the display panel and the absorption axis of the linearly polarizing layer is zero degrees, and there is no difference between the direction of the absorption axis of the protective layer and the direction of the absorption axis of the linearly polarizing layer. Thus, the light flux passing through the protective layer is approximately the same as the light flux passing through the linearly polarizing layer. In other words, the intensity of the light beam passing through the protective layer corresponds to the intensity of the light beam passing through the linearly polarizing layer. In this way, it is possible to reduce the loss of light when the light beam passes through the display panel, and it is possible to improve the stability of the light beam transmission of the display panel, so as to stabilize the intensity of the light beam entering the optical fingerprint recognition module through the light transmission area of the functional substrate and improve the stability of the light beam entering into the optical fingerprint recognition module, thereby improving the accuracy of the recognition performed by the optical fingerprint recognition module.

According to the fourth aspect, the implementation of the present application further provides a method for manufacturing a multilayer structure, including the following steps: providing a quarter-wave plate, a linearly polarizing layer and a protective layer; attaching a linearly polarizing layer to a quarter-wave plate and placing a protective layer on one side of the linearly polarizing layer at some distance from the quarter-wave plate so that the protective layer, linearly polarizing layer and quarter-wave plate are placed in layers. The protective layer is used to polarize the light beam to form a linearly polarized light beam. The angle between the absorption axis of the protective layer and the absorption axis of the linearly polarizing layer is zero degrees. The angle between the absorption axis of the linearly polarizing layer and the absorption axis of the quarter-wave plate is 45 degrees.

In a possible implementation, placing a protective layer on one side of the linearly polarizing layer some distance from the quarter-wave plate includes: placing a reinforcing layer on one side of the linearly polarizing layer some distance from the quarter-wave plate and placing a protective layer on one side of the reinforcing layer some distance from linearly polarizing layer.

In a possible implementation, placing the reinforcing layer on one side of the linearly polarizing layer at some distance from the quarter-wave plate includes: fixing the reinforcing layer on the linearly polarizing layer by means of an optical adhesive layer.

It should be understood that the description of technical features, technical solutions, benefits or the like in this application is not intended to imply that all features and benefits can be achieved in any particular embodiment. On the contrary, it should be noted that a description of features or benefits means that a particular technical feature, solution, or benefit is included in at least one embodiment. Thus, descriptions of technical characteristics, technical solutions, or beneficial effects in this specification do not necessarily refer to the same embodiment. In addition, the technical features, technical solutions and benefits described in this embodiment can also be combined in any suitable manner. One skilled in the art will appreciate that embodiments may be implemented without one or more specific technical features, technical solutions, or beneficial effects of a particular embodiment. In other embodiments, additional technical features and benefits may also be identified in a particular embodiment, which does not include all embodiments.

Brief description of the drawings

Fig. 1 is a schematic representation of a partial structure of an electronic device according to the first implementation of the present application.

Fig. 2 is a schematic representation of the path of a light beam incident on a display panel in the first implementation of the present application.

Fig. 3 is a schematic representation of the absorption axes of the multilayer layers of the display panel in the first implementation of the present application.

Fig. 4a is a schematic representation of an application scenario where fingerprint recognition is performed by an electronic device according to the first embodiment of the present application.

Fig. 4b is a schematic representation when fingerprint recognition is performed by a partial structure of an electronic device according to the first implementation of the present application.

Fig. 5 is a flow chart of a method for manufacturing a multilayer structure according to the first implementation of the present application.

Fig. 6 is a schematic representation of absorption axes of multilayer layers of a display panel according to a second embodiment of the present application.

Fig. 7 is a schematic representation of absorption axes of multilayer layers of a display panel according to the third implementation of the present application.

Fig. 8 is a schematic representation of absorption axes of multilayer layers of a display panel according to a fourth embodiment of the present application.

Fig. 9 is a schematic representation of the absorption axis of the multilayer structure according to the fifth embodiment of the present application.

Fig. 10 is a schematic representation of the absorption axis of the multilayer structure according to the sixth embodiment of the present application.

Fig. 11 is a schematic representation of the absorption axis of the multilayer structure according to the seventh implementation of the present application.

Detailed description of the invention

In FIG. 1 shows a schematic representation of a partial structure of an electronic device according to a first implementation. The electronic device 100 includes a display panel 101 and an optical fingerprint recognition module 103, which are multi-layered. The display panel 101 is located on the light beam input side of the optical fingerprint recognition unit 103 and is configured to display an image. The optical fingerprint recognition unit 103 is configured to receive the light beam passing through the display panel 101 to realize the fingerprint recognition function. Electronic device 100 may be any electronic device such as a smartphone, smart watch, tablet computer, personal digital assistant (PDA), point of sale (POS), on-board computer, desktop computer, laptop computer, or smart TV. Embodiments of the present invention are not limited to the devices listed above.

The display panel 101 includes a layered structure 10 and a functional substrate 30, which are layered. The functional substrate 30 is located between the multilayer structure 10 and the optical fingerprint recognition module 103 . The functional substrate 30 has a light transmission area 31 allowing light to enter the optical fingerprint recognition module 103 through the light transmission area 31.

Specifically, the multilayer structure 10 includes a quarter-wave plate (QWP) 12, a linearly polarizing layer 13, and a protective layer 15. The functional substrate 30 is disposed between the optical fingerprint recognition module 103 and the quarter-wave plate 12. The quarter-wave plate 12 can make the ordinary light beam (o-light beam) and the extraordinary light beam (e-light beam) equal to π/2 or an odd multiple of it. The quarter-wave plate 12 is located between the functional substrate 30 and the linearly polarizing layer 13. The protective layer 15 is located on one side of the linearly polarizing layer 13 at some distance from the quarter-wave plate 12. Both the protective layer 15 and the linearly polarizing layer 13 can polarize the light beam in order to formation of a linearly polarized light beam. The angle between the absorption axis of the linearly polarizing layer 13 and the absorption axis of the protective layer 15 is equal to zero degrees. The angle between the absorption axis of the quarter-wave plate 12 and the absorption axis of the linearly polarizing layer 13 is 45 degrees. The angle between the absorption axis of the protective layer 15 and the absorption axis of the quarter-wave plate 12 is 45 degrees.

In this embodiment, in the linearly polarizing layer 13, a light beam parallel to the absorption axis of the linearly polarizing layer 13 may be absorbed by the linearly polarizing layer 13, and a light beam perpendicular to the absorption axis of the linearly polarizing layer 13 may be emitted through the linearly polarizing layer 13; and in the protective layer 15, a light beam parallel to the absorption axis of the protective layer 15 may be absorbed by the protective layer 15, and a light beam perpendicular to the absorption axis of the protective layer 15 may be emitted through the protective layer 15.

The light beam incident from the protective layer 15 in the direction opposite to the linearly polarizing layer 13, becomes linearly polarized light passing through the protective layer 15, enters the linearly polarizing layer 13, and then is converted by the quarter-wave plate 12 into a circularly polarized light beam. Part of the light beam with circular polarization enters the optical fingerprint recognition module 103 through the functional substrate 30.

The protective layer 15 can polarize the light beam incident thereon to form a linearly polarized light beam, the angle between the absorption axis of the linearly polarizing layer 13 and the absorption axis of the protective layer 15 is zero degrees, and there is no difference between the direction of the absorption axis of the protective layer 15 and the direction of the absorption axis linearly polarizing layer 13. Thus, the light flux passing through the protective layer 15 is approximately the same as the light flux passing through the linearly polarizing layer 13. In other words, the intensity of the light beam passing through the protective layer 15 corresponds to the intensity of the light of the beam passing through the linear polarizing layer 13. Thus, it is possible to reduce the loss of light during transmission of the light beam from the display panel 10 to the optical fingerprint recognition unit 30, and it is possible to improve the stability of the light beam passing through the display panel 101 to stabilize the intensity of the light beam passing through the display panel 101 and improve the stability of the light beam entering the optical fingerprint recognition unit 103, thereby improving the accuracy of the recognition performed by the optical fingerprint recognition unit 103.

The protective layer 15 is placed on one side of the multilayer structure 10 remote from the optical fingerprint recognition module 103, namely on the outer side of the electronic device 100. The multilayer structure 10 further includes a reinforcing layer 17 placed between the protective layer 15 and the linearly polarizing layer 13 , and is used to protect other multilayer structures of the multilayer structure 10 and increase the strength of the multilayer structure 10. The reinforcing layer 17 is a glass protective plate and allows you to increase the strength of the multilayer structure 10. In this implementation, the strength of the material of the reinforcing layer 17 is greater than that of the protective layer 15. The protective layer 15 is a film layer attached to one side of the reinforcing layer 17 away from the linear polarizing layer 13, such as a protective film on the outside of the smartphone display panel 101 to prevent scratches and wear of the reinforcing layer 17.

The protective layer 15 is made of materials including polyethylene terephthalate (polyethylene terephthalate, PET) and thermoplastic polyurethane (thermoplastic polyurethane, TUP) elastomeric rubber. The reinforcing layer 17 is attached to the linearly polarizing layer 13 by means of an optical adhesive layer 19. The reinforcing layer 17 is made of an isotropic material in order to reduce the loss of light when the light beam passes through the multilayer structure 10 and improve the stability of the light beam transmission. Isotropy refers to the property in which the physical and chemical properties of an object do not change depending on different directions, namely, the values of the characteristics of an object measured in different directions are exactly the same, which is also known as uniformity. The optical adhesive layer 19 is made of an isotropic material in order to further reduce the loss of light when the light beam passes through the multilayer structure 10 and improve the stability of the light beam transmission. It should be noted that the implementation of the present application does not limit the material of the protective layer 15 and the material of the reinforcing layer 17. For example, the reinforcing layer 17 may be made of plastic or ceramic.

In a possible implementation, the reinforcing layer 17 is used to polarize the light beam to form a linearly polarized light beam. The angle between the absorption axis of the reinforcing layer 17 and the absorption axis of the linearly polarizing layer 13 is equal to zero degrees. The reinforcing layer 17 is arranged as a multilayer layer in the direction corresponding to the direction of the absorption axis of the linearly polarizing layer, so that the intensity of the light beam passing through the protective layer 15 corresponds to the intensity of the light beam passing through the reinforcing layer 17 and the linearly polarizing layer 13, and the optical characteristics the reinforcing layer 17, the protective layer 15 and the linearly polarizing layer 13 can be matched, thereby improving the stability of the transmission of the light beam in the multilayer structure 10.

In this implementation, the display panel 101 is a flexible display panel. The functional substrate 30 is an organic light-emitting diode (OLED) substrate. More specifically, the functional substrate 30 includes a first light transmitting layer 32, a plurality of reflective elements 33, and a second light transmitting layer 35. The reflective elements 33 are configured to reflect a light beam incident thereon. The reflective elements 33 are also reflective elements capable of emitting light. The light beam emitted from the reflective members 33 can be reflected from the finger and enter the optical fingerprint recognition unit 103 through the light transmission area 31, thereby realizing the optical fingerprint recognition function. A plurality of reflective elements 33 are spaced apart on one side of the first light transmitting layer 32. The second light transmitting layer 35 covers the reflective elements 33 and the first light transmitting layer 32. A light transmitting zone 31 is formed between adjacent reflective elements 33. The second light transmitting layer 35 is located between the quarter-wave plate 12 and the first light transmission layer 32. It should be noted that the functional substrate 30 may also be a sensor layer.

Since the reflective elements 33 are surrounded by the first light transmission layer 32 and the second light transmission layer 35, namely, the first light transmission layer 32 and the second light transmission layer 35 are arranged around the reflective elements 33, the impact on the reflective elements 33 when the multilayer structure 10 is struck can be damped, which is beneficial. to prolong the service life of the display panel 101 . In this implementation, both the first light transmission layer 32 and the second light transmission layer 35 are made of isotropic materials in order to reduce the loss of light when the light beam passes through the display panel 101 and improve the stability of the intensity of the light beam when the light beam passes through the display panel 101 . The reflective elements 33 may be part of a circuit such as a cathode and an anode.

In some implementations, the display panel 101 may be a touch display panel, and the display panel 101 further includes a touch layer placed between the functional substrate 30 and the quarter wave plate 12.

In some implementations, the protective layer 15 need only satisfy the condition that the angle between the absorption axis of the linearly polarizing layer 13 and the absorption axis of the protective layer 15 is zero degrees.

It should be noted that the multilayer structure 10 includes a protective layer 15, a linearly polarizing layer 13, and a quarter-wave plate 12, which are layered one after the other. The protective layer 15 is used to polarize the light beam to form a linearly polarized light beam, the angle between the absorption axis of the protective layer 15 and the absorption axis of the linearly polarizing layer 13 is zero degrees, and the angle between the absorption axis of the linearly polarizing layer 13 and the absorption axis of the quarter wave plate 12 is 45 degrees.

In FIG. 2 shows the path of a light beam incident on a multilayer structure in the first implementation of the present application.

The light beam is natural light. After the light beam 1 is incident on one side of the protective layer 15 away from the reinforcement layer 17, the protective layer 15 first polarizes the incident light beam to form a linearly polarized light beam 2.

The linearly polarized light beam 2 enters the linearly polarizing layer 13 after passing through the reinforcing layer 17 and the optical adhesive layer 19. Since the angle between the absorption axis of the linearly polarizing layer 13 and the absorption axis of the protective layer 15 is equal to zero degrees, the linearly polarized light beam 2 is still linearly polarized light passing through the linearly polarizing layer 13.

The linearly polarized light beam passing through the reinforcing layer 17, the linearly polarized light beam passing through the optical adhesive layer 19, and the linearly polarized light beam passing through the linearly polarizing layer 13 are labeled as linearly polarized light beam 3, linearly polarized light beam 4 and linearly polarized light beam 5, respectively. The linearly polarized light beam 5 is converted into a circularly polarized light beam 6, for example the right hand circularly polarized light beam shown in FIG. 2 after passing the quarter-wave plate 12.

A circularly polarized light beam 6 enters the functional substrate 30. Part of the circularly polarized light beam 6 is reflected from the reflective elements 33 of the functional substrate 30 and becomes reverse polarized light 7, such as the left hand circularly polarized light beam shown in FIG. 2. The reverse polarized light beam 7 is emitted from the functional substrate 30 and enters the quarter wave plate 12. The reverse polarized light beam 7 is converted into a linearly polarized light beam 8 after passing through the quarter wave plate 12. Obviously, the polarization angle of the linearly polarized light beam 8 is rotated by 90 degrees relative to the linearly polarized light beam 5. Since the linearly polarized light beam 8 is perpendicular to the absorption axis of the linearly polarizing layer 13, part of the linearly polarized light beam 8 cannot pass through the linearly polarizing layer 13, thereby reducing the reflected light beam caused by the reflective elements 33 in a multilayer structure 10. Part of the light beam 6 with circular polarization enters the optical fingerprint recognition module 103 through the light-transmitting zone 31.

In FIG. 3 shows a schematic representation of the absorption axes of the multilayer layers of the multilayer structure in the first implementation of the present application. The absorption axis of the protective layer 15 is a bidirectional absorption axis, the absorption axis of the linearly polarizing layer 13 is a bidirectional absorption axis, and the absorption axis of the quarter wave plate 12 is a unidirectional absorption axis. The tilt angle of the absorption axis of the protective layer 15 with respect to the first direction (for example, the Y direction shown in Fig. 3) is defined as N degrees. The term "bidirectional absorption axis" means that the multilayer layer (for example, the protective layer 15 or the linearly polarizing layer 13) affects the light beam in the same way in the positive direction and the negative direction of the absorption axis. The term "unidirectional absorption axis" means that the multilayer layer (eg quarter-wave plate 12) affects the light beam differently in the positive and negative directions of the absorption axis. For example, since the absorption axis of the protective layer 15 is a bidirectional absorption axis, the intensity of the light beam passing through the protective layer 15 is the same when the absorption axis of the protective layer 15 is inclined at 45 degrees and at 135 degrees with respect to the first direction. Since the absorption axis of the quarter-wave plate 12 is a unidirectional absorption axis, the intensity of the light beam passing through the quarter-wave plate 12 is different when the absorption axis of the quarter-wave plate 12 is tilted at an angle of 45 degrees and at an angle of 135 degrees with respect to the first direction. It should be noted that the angle N degrees can be any. The angle between the absorption axis of the protective layer 15 and the first direction and the angle between the absorption axis of the linearly polarizing layer 13 and the first direction (for example, the Y direction shown in Fig. 3) is N degrees. The angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is N-45 degrees. In this implementation, N is equal to 45 degrees, that is, the absorption axis of the quarter-wave plate 12 corresponds to the positive direction of the first direction. The angle between the absorption axis of the quarter-wave plate 12 and the absorption axis of the protective layer 15 is 45 degrees. In other words, the angle between the absorption axis of the quarter wave plate 12 and the positive direction of the first direction is zero degrees.

Below, an example is used for description in which the electronic device 100 is a mobile phone.

In FIG. 4a is a schematic representation of an application scenario when fingerprint recognition is performed by an electronic device according to the first embodiment of the present application. In FIG. 4b is a schematic representation when fingerprint recognition is performed by a partial structure of an electronic device according to the first embodiment of the present application. The finger 200 touches the display panel 101 so that the electronic device 100 can perform fingerprint recognition. The finger 200 is located on one side of the protective layer 15 away from the linear polarizing layer 13 so that the optical fingerprint recognition module 103 can perform fingerprint recognition. It should be noted that there may also be a certain gap between the finger 200 and the protective layer 15, and the light beam reflected from the surface of the finger 200 may fall on the display panel 101.

The external light beam 201 is incident from the protective layer 15 and passes into the functional substrate 30 through the reinforcement layer 17, the optical adhesive layer 19, the linearly polarizing layer 13 and the quarter-wave plate 12. Part of the external light beam 201 is reflected from the reflective elements 33 in the form of the first reflected light beam. 202, and part of the external light beam 201 enters the optical fingerprint recognition module 103 through the light transmission zone 31. In practice, only a part of the first reflected light beam 202 cannot pass through the linearly polarizing layer 13 after passing through the quarter-wave plate 12, namely, is eliminated while part of the first reflected light beam 202 can still be emitted from the protective layer 15, reaching the surface of the finger 200. The first reflected light beam 202, which is emitted from the protective layer 15, is reflected from the surface of the finger 200 as a second reflected light beam. 203. Second from The light beam 203 enters the functional substrate 30 through the protective layer 15, the reinforcing layer 17, the optical adhesive layer 19, the linearly polarizing layer 13 and the quarter-wave plate 12, and penetrates the optical fingerprint recognition module 103 through the light-transmitting zone 31 of the functional substrate 30.

The reflective blocks 33 emit a light beam 204. The light beam 204 is incident on the surface of the finger 200 through a quarter wave plate 12, a linearly polarizing layer 13, an optical adhesive layer 19, a reinforcing layer 17 and a protective layer 15. The light beam 204 is reflected from the surface of the finger 200 in the form of a third reflected light beam 205. Then, the third reflected light beam 205 enters the optical fingerprint recognition module 103 through the protective layer 15, the reinforcing layer 17, the optical adhesive layer 19, the linearly polarizing layer 13, the quarter-wave plate 12, and the light-transmitting zone 31 of the functional substrate 30. The module 103 optical fingerprint recognition performs fingerprint recognition.

The angle between the absorption axis of the protective layer 15 and the absorption axis of the linearly polarizing layer 13 is zero degrees, and the luminous flux of the reflected light beam (for example, the second reflected light beam 203 or the third reflected light beam 205) reflected from the surface of the finger 200 after passing through the protective layer 15 is approximately the same as after passing through the linear polarizing layer 13. In other words, the intensity of the light beam passing through the protective layer 15 corresponds to the intensity of the light beam passing through the linearly polarizing layer 13 in order to stabilize the intensity of the light beam passing through the display panel 101, and improve the stability of the light beam passing through the display panel 101, thereby improving the accuracy of the recognition performed by the optical fingerprint recognition unit 103.

In FIG. 5 shows a flowchart of a method for manufacturing a multilayer structure according to the first implementation of the present application. The method for manufacturing a multilayer structure includes the following steps:

Step 501: Provide a quarter-wave plate, a linearly polarizing layer, and a protective layer.

Step 502: Attach a linear polarizing layer to a quarter wave plate and place a protective layer on one side of the linear polarizing layer at some distance from the quarter wave plate so that the protective layer, linear polarizing layer and quarter wave plate are layered, where the protective layer is used to polarize the light beam in order to form a linearly polarized light beam, the angle between the absorption axis of the protective layer and the absorption axis of the linearly polarizing layer is zero degrees, and the angle between the absorption axis of the linearly polarizing layer and the absorption axis of the quarter wave plate is 45 degrees.

In one implementation, placing a protective layer on one side of a linearly polarizing layer some distance from the quarter-wave plate includes: placing a reinforcing layer on one side of the linearly polarizing layer some distance from the quarter-wave plate and placing a protective layer on one side of the reinforcing layer some distance from linearly polarizing layer.

In another implementation, placing the reinforcing layer on one side of the linearly polarizing layer away from the quarter-wave plate includes: fixing the reinforcing layer on the linearly polarizing layer by means of an optical adhesive layer.

Embodiment 2

In FIG. 6 is a schematic representation of absorption axes of multilayer layers of a display panel according to a second embodiment of the present application. The display panel provided in the second implementation is approximately the same as the display panel provided in the first implementation, except that the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is N + 45 degrees, where N is 45 degrees. In this case, the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is 90 degrees, and the angle between the absorption axis of the protective layer 15 and the absorption axis of the quarter-wave plate 12 is 45 degrees.

The protective layer 15 can polarize the light beam incident thereon to form a linearly polarized light beam, the angle between the absorption axis of the linearly polarizing layer 13 and the absorption axis of the protective layer 15 is zero degrees, and there is no difference between the direction of the absorption axis of the protective layer 15 and the direction of the absorption axis linearly polarizing layer 13. Thus, the light flux passing through the protective layer 15 is approximately the same as the light flux passing through the linearly polarizing layer 13. In other words, the intensity of the light beam passing through the protective layer 15 corresponds to the intensity of the light of the beam passing through the linearly polarizing layer 13, and the stability of the light beam passing through the display panel is improved, which makes it possible to stabilize the intensity of the light beam passing through the display panel and improve the stability of the light beam entering the optical fingerprint recognition module. of the fingers, thereby improving the accuracy of the recognition performed by the optical fingerprint recognition module.

Embodiment 3

In FIG. 7 is a schematic representation of the absorption axes of the multilayer layers of a display panel according to the third embodiment of the present application. The display panel provided in the third implementation is approximately the same as the display panel provided in the first implementation, except that the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is N+3×45 degrees, where N equals 45 degrees. In this case, the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is 180 degrees, and the angle between the absorption axis of the protective layer 15 and the absorption axis of the quarter-wave plate 12 is 45 degrees.

Embodiment 4

45 градусов, где N равно 45 градусам. В этом случае угол между осью поглощения четвертьволновой пластины 12 и положительным направлением первого направления равен 270 градусам, и угол между осью поглощения защитного слоя 15 и осью поглощения четвертьволновой пластины 12 равен 45 градусам.In FIG. 8 is a schematic representation of absorption axes of multilayer layers of a display panel according to a fourth embodiment of the present application. The display panel provided in the fourth implementation is approximately the same as the display panel provided in the first implementation, except that the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is N+5

45 degrees, where N is 45 degrees. In this case, the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is 270 degrees, and the angle between the absorption axis of the protective layer 15 and the absorption axis of the quarter-wave plate 12 is 45 degrees.

Option 5 implementation

In FIG. 9 shows a schematic representation of the absorption axis of the multilayer structure according to the fifth embodiment of the present application. The layered structure of the display panel provided in the fifth implementation is approximately the same as that of the display panel provided in the first implementation, except that the angle of inclination of the absorption axis of the protective layer 15 with respect to the first direction (for example, the Y direction shown in Fig. 9) is equal to 90 degrees, namely, N is equal to 90 degrees, the angle of inclination of the absorption axis of the linearly polarizing layer 13 with respect to the first direction (for example, the Y direction shown in Fig. 9) is equal to 90 degrees, and the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is N-45 degrees. In this case, the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is 45 degrees, and the angle between the absorption axis of the protective layer 15 and the absorption axis of the quarter-wave plate 12 is 45 degrees.

Embodiment 6

In FIG. 10 shows a schematic representation of the absorption axis of a multilayer structure according to the sixth embodiment of the present application. The layered structure of the display panel provided in the sixth implementation is approximately the same as that of the display panel provided in the first implementation, except that the angle of the absorption axis of the protective layer 15 with respect to the first direction (for example, the Y direction shown in Fig. 10) is equal to 90 degrees, namely, N is equal to 90 degrees, the angle of inclination of the absorption axis of the linearly polarizing layer 13 with respect to the first direction (for example, the Y direction shown in Fig. 10) is equal to 90 degrees, and the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is N+45 degrees. In this case, the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is 135 degrees, and the angle between the absorption axis of the protective layer 15 and the absorption axis of the quarter-wave plate 12 is 45 degrees.

Embodiment 7

In FIG. 11 is a schematic representation of the absorption axis of the multilayer structure according to the seventh embodiment of the present application. The layered structure of the display panel provided in the seventh implementation is approximately the same as that of the display panel provided in the first implementation, except that the angle of inclination of the absorption axis of the protective layer 15 with respect to the first direction (for example, the Y direction shown in Fig. 11) is equal to 90 degrees, namely N is equal to 90 degrees, the angle of inclination of the absorption axis of the linearly polarizing layer 13 with respect to the first direction (for example, the Y direction shown in Fig. 11) is equal to 90 degrees, and the angle between the axis absorption of the quarter-wave plate 12 and the positive direction of the first direction is N+3×45 degrees. In this case, the angle between the absorption axis of the quarter-wave plate 12 and the positive direction of the first direction is 225 degrees (also 135 degrees), and the angle between the absorption axis of the protective layer 15 and the absorption axis of the quarter-wave plate 12 is 45 degrees.

The above description only presents specific implementations of the present invention and is not intended to limit the protection scope of the present invention. Any changes or substitutions that can be easily found by a person skilled in the art within the technical scope disclosed in the present invention should fall within the protection scope of the present invention. Thus, the protection scope of the present invention should fall within the protection scope of the claims.

Claims (11)

1. A multi-layer structure in which the multi-layer structure includes a protective layer, a linearly polarizing layer and a quarter-wave plate, which are layered one after the other, the protective layer is used to polarize the light beam to form a linearly polarized light beam, the angle between the absorption axis of the protective layer and the axis absorption of the linearly polarizing layer is zero degrees, and the angle between the absorption axis of the linearly polarizing layer and the absorption axis of the quarter-wave plate is 45 degrees. 2. The multilayer structure according to claim 1, in which the multilayer structure further comprises a reinforcing layer placed between the protective layer and the linearly polarizing layer. 3. Multilayer structure according to claim 2, in which the reinforcing layer is made of an isotropic material. 4. A multilayer structure according to claim 3, wherein the reinforcing layer is a glass protective plate. 5. The multilayer structure according to claim 2, wherein the linearly polarizing layer is attached to the reinforcing layer via an optical adhesive layer. 6. The multilayer structure according to claim 5, wherein the optical adhesive layer is made of an isotropic material. 7. The multilayer structure of claim 2, wherein the reinforcing layer is used to polarize the light beam to form a linearly polarized light beam, and the angle between the absorption axis of the reinforcing layer and the absorption axis of the linearly polarizing layer is zero degrees. 8. A display panel applied to an electronic device with an optical fingerprint recognition module, in which the display panel comprises a multilayer structure according to any one of paragraphs. 1-7 and the functional substrate, the functional substrate is located on one side of the quarter-wave plate at some distance from the protective layer, and the functional substrate has a light-transmitting area so that the light coming from the quarter-wave plate enters the optical fingerprint recognition module through the light-transmitting area. 9. The display panel according to claim 8, wherein the functional substrate comprises a first light transmitting layer, a plurality of reflective elements and a second light transmitting layer, wherein the plurality of reflective elements are arranged at intervals from each other on the first light transmitting layer, the second light transmitting layer covers the reflective elements and the first light transmitting layer. layer, a light-transmitting area is formed between adjacent reflective elements, and a second light-transmitting layer is located between the quarter-wave plate and the first light-transmitting layer. 10. The display panel of claim 9, wherein both the first light transmission layer and the second light transmission layer are made of isotropic materials. 11. An electronic device containing a display panel according to any one of paragraphs. 8-10 and an optical fingerprint recognition module, wherein the optical fingerprint recognition module is located on one side of the functional substrate remote from the protective layer, and is configured to receive a light beam passing through the light-transmitting zone of the functional substrate.

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