WO2018103196A1 - Module d'affichage et son procédé d'utilisation - Google Patents
Module d'affichage et son procédé d'utilisation Download PDFInfo
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- WO2018103196A1 WO2018103196A1 PCT/CN2017/073617 CN2017073617W WO2018103196A1 WO 2018103196 A1 WO2018103196 A1 WO 2018103196A1 CN 2017073617 W CN2017073617 W CN 2017073617W WO 2018103196 A1 WO2018103196 A1 WO 2018103196A1
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- light
- substrate
- self
- backlight
- fingerprint sensor
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Classifications
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/03—Arrangements for converting the position or the displacement of a member into a coded form
- G06F3/041—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means
- G06F3/0412—Digitisers structurally integrated in a display
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F21/00—Security arrangements for protecting computers, components thereof, programs or data against unauthorised activity
- G06F21/30—Authentication, i.e. establishing the identity or authorisation of security principals
- G06F21/31—User authentication
- G06F21/32—User authentication using biometric data, e.g. fingerprints, iris scans or voiceprints
-
- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06F—ELECTRIC DIGITAL DATA PROCESSING
- G06F3/00—Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/03—Arrangements for converting the position or the displacement of a member into a coded form
- G06F3/041—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means
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- G—PHYSICS
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- G06F—ELECTRIC DIGITAL DATA PROCESSING
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- G06F3/01—Input arrangements or combined input and output arrangements for interaction between user and computer
- G06F3/03—Arrangements for converting the position or the displacement of a member into a coded form
- G06F3/041—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means
- G06F3/044—Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means by capacitive means
Definitions
- the present invention relates to the field of optical fingerprint recognition, and in particular, to a display module and a method for using the same.
- the fingerprint imaging recognition technology is a technique of acquiring a fingerprint image of a human body through a fingerprint sensor and then comparing it with existing fingerprint imaging information in the system to determine whether it is correct or not, thereby realizing the identity recognition technology. Due to its ease of use and the uniqueness of human fingerprints, fingerprint recognition technology has been widely used in various fields. For example, the public security bureau, customs and other security inspection areas, building access control systems, and consumer goods such as personal computers and mobile phones.
- Fingerprint imaging recognition technology can be realized by various techniques such as optical imaging, capacitive imaging, and ultrasonic imaging. Relatively speaking, optical fingerprint imaging technology has relatively good imaging effect and relatively low equipment cost.
- OLED display module is one of the hot spots in the field of flat panel display.
- OLED display modules have the advantages of low power consumption, wide color gamut, self-illumination, wide viewing angle and fast response. They are currently used in electronic products such as mobile phones, computers and digital cameras.
- capacitive fingerprint imaging technology is often used to integrate with a display module of an organic light emitting diode.
- capacitive fingerprint imaging technology is often used to integrate with a display module of an organic light emitting diode.
- a display module of an organic light emitting diode For more information about the integrated fingerprint recognition function in the display module, refer to the Chinese invention patent application with the publication number CN106024833A.
- the display module structure of the existing integrated fingerprint recognition function needs to be improved, and the performance needs to be improved.
- the problem to be solved by the present invention is to provide a display module for integrating the optical fingerprint recognition function into the display module, so that the display module has a good fingerprint recognition function.
- the present invention provides a display module, including: a self-luminous display panel, the self-luminous display panel includes a first substrate, a second substrate, and a self-luminous circuit layer, wherein the self-luminous circuit layer is located at Between the first substrate and the second substrate, the self-illuminating circuit layer includes a plurality of display pixel units; each of the display pixel units includes at least one non-transmissive region and at least one light transmissive region;
- An optical fingerprint sensor the optical fingerprint sensor is located under the second substrate, the optical fingerprint sensor includes a fingerprint sensing circuit layer and a substrate, and the fingerprint sensing circuit layer is located on the second substrate and the lining Between the bottom substrates; a dot backlight, the dot backlight is located under the second substrate, the dot backlight is located at a side of the optical fingerprint sensor, and the light emitted by the dot backlight is obliquely upward The angle enters the second substrate.
- the display module further includes a protective layer, the protective layer being located above the first substrate.
- a light-transmitting glue is disposed between the dot-shaped backlight and the second substrate, and light emitted by the dot-shaped backlight enters the transparent adhesive from a light-emitting surface of the dot-shaped backlight, and then The light transmissive glue enters the second substrate.
- the dot backlight has a space between the optical fingerprint sensor and the optical fingerprint sensor.
- the light-emitting surface of the dot-shaped backlight has a collecting lens on the front side, and the collecting lens can convert the light of the point-shaped backlight into parallel light or near-parallel light, and the point backlight The light enters the collecting lens first and then enters the second substrate.
- the area of the lower surface of the second substrate adjacent to the point backlight further includes a light anti-reflection layer, wherein the light anti-reflection layer is capable of increasing light of the point backlight into the second substrate. proportion.
- an optical glue is disposed between the self-luminous display panel and the optical fingerprint sensor.
- an optical glue is disposed between the self-luminous display panel and the protective layer.
- the point backlight is an LED light, and the light of the LED light is near ultraviolet light, purple light, blue light, green light, yellow light, red light, near infrared light or white light; or
- the dot backlight is two or more LED lamps, and the two or more LED lamps are evenly distributed under the second substrate, and the light of the LED lamp is near ultraviolet light, purple light, blue light, green light. , yellow, red, near-infrared or white.
- the present invention further provides a method for using a display module, wherein the display module includes: a self-luminous display panel, the self-luminous display panel includes a first substrate, a second substrate, and a self-luminous a circuit layer, the self-luminous circuit layer is located between the first substrate and the second substrate, the self-luminous circuit layer includes a plurality of display pixel units, each of the display pixel units including at least one non-transparent And an optical fingerprint sensor, the optical fingerprint sensor is located under the second substrate, the optical fingerprint sensor comprises a fingerprint sensing circuit layer and a substrate, and the fingerprint sensing circuit layer is located at the Between the second substrate and the substrate; a dot backlight, the dot backlight is located under the second substrate, and the dot backlight is located at a side of the optical fingerprint sensor, the dot Light emitted by the backlight enters the second substrate at an obliquely upward angle; the method of using includes: opposing the optical fingerprint sensor in the self-luminous display panel A first display region is
- the using method further includes: when the optical fingerprint sensor performs a fingerprint image collecting operation, controlling the second display area to display information associated with the fingerprint image collecting work.
- the optical fingerprint sensor and the dot backlight are both disposed under the second substrate of the self-luminous display panel, and the point backlight is disposed on the side of the optical fingerprint sensor, and the self-luminous display
- the panel is provided with a light transmitting area, so that the light emitted by the point backlight can be passed back and forth through the self-luminous display panel, thereby enabling display
- the module realizes the collection of the finger fingerprint image, and the collected fingerprint image is clear, so that the display module integrates a good fingerprint recognition function.
- the first display area corresponding to the optical fingerprint sensor is controlled to stop working when the optical fingerprint sensor performs the fingerprint image collecting operation, and the second display area display and the fingerprint image collection are controlled. Work-related information, so that the display function and fingerprint recognition function work together to achieve a better user experience.
- FIG. 2 is a schematic cross-sectional view of a display module according to another embodiment of the present invention.
- the prior art mostly uses capacitive fingerprint imaging technology to integrate with a display module of an organic light emitting diode.
- the present invention provides a display module in which an optical fingerprint sensor and a self-luminous display panel are integrated, so that a fingerprint recognition function can be realized while realizing display, and a display module is enabled by a corresponding structural design.
- the group can collect clear fingerprint images, and enables the display function and the fingerprint recognition function to cooperate with each other, so that the user has a better use experience for the display module.
- the embodiment of the invention provides a display module. Please refer to FIG. 1 .
- the display module includes a self-luminous display panel (not labeled), an optical fingerprint sensor (not labeled), and a dot backlight 130.
- the self-luminous display panel includes a first substrate 111 and a second substrate. 112 and self-illuminating circuit layer 113.
- the self-luminous circuit layer 113 is located between the first substrate 111 and the second substrate 112.
- the self-luminous display panel also includes a sealing structure 114.
- the sealing structure 114 is also located between the first substrate 111 and the second substrate 112. The sealing structure 114, together with the first substrate 111 and the second substrate 112, seals the self-luminous circuit layer 113 between the first substrate 111 and the second substrate 112.
- the material of the first substrate 111 and the second substrate 112 may be a transparent material, and the specific material may be inorganic glass or organic glass, or may be other organic transparent resin than organic glass.
- the self-luminous circuit layer 113 includes a plurality of display pixel units 1131 (the display pixel unit 1131 is illustrated by a broken line in FIG. 1 and the adjacent display pixel units 1131 are adjacent to each other. Note that although the dotted frame is A portion of the first substrate 111 and the second substrate 112 are included, but this is only for convenience of display, and the display pixel unit 1131 does not include the first substrate 111 and the second substrate 112).
- Each display pixel unit 1131 includes at least one non-transmissive region and at least one light transmissive region 11311, and a light transmissive region 11311 is illustrated in FIG. 1 (ie, one of the light transmissive regions 11311 is surrounded by a minimum dotted line frame as shown in FIG. The range shown).
- the light transmissive area 11311 of one display pixel unit 1131 may be connected to the light transmissive area 11311 of the other display pixel unit 1131 to form a wider transparent area.
- the two display pixel units 1131 are generally adjacent, and the area between the adjacent two display pixel units 1131 is also a light transmitting area, so that the three light transmitting areas can be connected as one large light transmitting area.
- the self-luminous display panel is an OLED display panel
- the display pixel unit 1131 of the self-luminous circuit layer 113 may include an anode layer, a hole injection layer (HIL), an emission layer (EML), and an electron injection layer (EIL).
- a cathode layer or the like which may further have a hole transport layer (HTL) and an electron transport layer (ETL), and may further include a TFT that drives the OLED, a driving metal line, a storage capacitor, and the like.
- the luminescence principle of the OLED display panel is: under a certain voltage driving, electrons and holes migrate from the cathode layer and the anode layer to the luminescent layer, respectively, and meet in the luminescent layer to form excitons and excite the luminescent molecules, and the luminescent molecules undergo radiation. Relaxation Emit visible light (or other light).
- the structure of the above-mentioned light-emitting layer or the like is located in the corresponding non-light-transmitting region.
- the display pixel unit 1131 of the present embodiment has a corresponding light transmissive area 11311 around the non-transparent area.
- the self-luminous circuit layer 113 is formed on the second substrate 112, and the self-luminous circuit layer 113 and the first substrate 111 have a gap layer therebetween. And the void layer is filled with an inert gas such as nitrogen or argon to protect the self-luminous circuit layer 113 from being crushed by the first substrate 111.
- an inert gas such as nitrogen or argon
- the height of the light-transmitting region 11311 is set to be equal to the height of the self-light-emitting circuit layer 113, as shown in FIG. 1, so as to ensure that light can pass through the self-light-emitting circuit layer 113 from the light-transmitting region (it is required to explain that the self-light-emitting circuit layer
- the heights of the respective positions of 113 may be slightly different, but the height of the self-illuminating circuit layer 113 at least a portion of the position is equal to the height of the light-transmitting region 11311).
- the light can pass through the self-illuminating circuit layer 113 from the light transmitting area, thereby ensuring that the display module can perform fingerprint image collection. It can be seen from the above content of the void layer that the light passes through the self-luminous display panel, and generally includes the second substrate 112, the light transmitting region 11311, the void layer and the first substrate 111.
- a non-transmissive region of one display pixel unit 1131 has a corresponding semiconductor layer structure such as a light-emitting layer (the semiconductor layer structure needs to be protected from light, and thus is formed in a non-transparent region), and other positions can be set.
- the semiconductor layer structure needs to be protected from light, and thus is formed in a non-transparent region
- other structures of the display pixel unit 1131 can be fabricated by using a light-transmitting structure as much as possible.
- the structure between the adjacent display pixel units 1131 can also be fabricated by using a light-transmitting structure as much as possible.
- a corresponding light transmitting area may be disposed, so that more light can pass through the OLED.
- a display panel this pass generally refers to passing through the height of the display pixel unit 1131, and the height is also generally referred to as thickness).
- the optical fingerprint sensor is located below the second substrate 112 . That is, the optical fingerprint sensor is located below the self-luminous display panel.
- the optical fingerprint sensor includes a fingerprint sensing circuit layer 121 and a lining.
- the base substrate 122 has a fingerprint sensing circuit layer 121 between the second substrate 112 and the substrate substrate 122.
- the fingerprint sensing circuit layer 121 of the optical fingerprint sensor includes a plurality of photosensitive pixel units (not shown).
- each of the photosensitive pixel units may include a light transmitting region and a non-light transmitting region (distinguish from the light transmitting region and the non-light transmitting region in the display pixel unit 1131).
- the photosensitive element of the photosensitive pixel unit (the photosensitive element may be a structure such as a photodiode) is located in the non-transparent area.
- the photosensitive pixel unit may also not require a light-transmitting region at all, but only a non-transmissive region, but It is ensured that light can enter the corresponding photosensitive element obliquely downward from the second substrate 112.
- the optical fingerprint sensor may be an image sensor fabricated by a CMOS (Complementary Metal Oxide Semiconductor) process based on a silicon wafer, or may be a TFT based on a glass substrate (Thin Film Transistor). , thin film transistor) process image sensor.
- CMOS Complementary Metal Oxide Semiconductor
- TFT Thin Film Transistor
- thin film transistor thin film transistor
- the dot backlight 130 is located below the second substrate 112, and the dot backlight 130 is located at the side of the optical fingerprint sensor.
- the light emitted by the dot backlight 130 enters the second substrate 112 at an obliquely upward angle. .
- the point backlight 130 is disposed on the side of the optical fingerprint sensor, so that the light emitted by the point backlight 130 for fingerprint image acquisition must enter the second substrate 112 at an oblique incident angle. .
- These rays will continue to pass through the self-illuminating circuit layer 113 at an oblique incident angle, thereby obliquely incident into the first substrate 111.
- the light rays cause an optical phenomenon such as reflection and refraction at the interface formed by the finger fingerprint and the upper surface of the first substrate 111 to generate corresponding reflected light. It is known from the principle of optical propagation that the reflected light will generally return obliquely downward to the first substrate 111 at an obliquely incident angle.
- These reflected rays will continue to pass obliquely downward through the self-illuminating circuit layer 113 at an obliquely incident angle, thereby obliquely incident into the second substrate 112.
- the oblique incident angle is then continued obliquely down to the optical fingerprint sensor (ie, obliquely downward into the optical fingerprint sensor) and received by the photosensitive pixel unit in the optical fingerprint sensor.
- this The arrangement of the dot-shaped backlight 130 enables the light to be substantially shifted in the same direction (while the light of the light guide plate is disordered in various directions, and the offset direction is different), thereby avoiding mutual interference and mutual influence between the light rays (
- the light of the light guide plate interferes with each other and affects each other, and the light offset from the position of the point backlight 130 is similar, so that a clear fingerprint image can be obtained, and the fingerprint recognition performance of the module is improved.
- the dot backlight 130 can be an LED lamp.
- the light of the LED lamp may be near ultraviolet light, purple light, blue light, green light, yellow light, red light, near infrared light or white light.
- a light-transmitting glue 140 is disposed between the dot-shaped backlight 130 and the second substrate 112 , and the light emitted by the dot-shaped backlight 130 enters from the light-emitting surface of the dot-shaped backlight 130 .
- the light transmissive glue 140 enters the second substrate 112 from the light transmissive glue 140.
- the light-transmitting adhesive 140 is disposed such that the light emitted by the dot-shaped backlight 130 is more incidentally incident on the second substrate 112 to reduce the interface reflection.
- the refractive index of the transparent adhesive 140 is greater than 1, and the light entering the second substrate 112 is reduced. The extent of the refraction of light.
- the light-transmitting glue is not provided, the light emitted by the point-like backlight needs to pass through the vacuum or the air, and then enters the second substrate 112, and the light is easily reflected and scattered in the process, and the light is easily in the vacuum or the air.
- An unfavorable situation such as reflection occurs at the interface formed with the second substrate 112, and the air may cause some light to be scattered and the like.
- the light-transmitting adhesive 140 can also function as a fixed-point backlight 130, that is, the light-transmitting adhesive 140 can adhere to the dot-shaped backlight 130.
- the material of the light-transmitting adhesive 140 can be selected from materials having good light-transmitting properties.
- all the light emitted by the point backlight 130 passes through the transparent adhesive 140 and then enters the second substrate 112, thereby avoiding other propagation paths of the light.
- the dot backlight 130 there is a gap (not labeled) between the dot backlight 130 and the optical fingerprint sensor.
- the presence of the spacing can ensure that there is no direct contact between the point backlight 130 and the optical fingerprint sensor.
- the specific size of the interval can be determined according to design needs. For example, in one example, the spacing may be greater than or equal to the width of the point backlight 130.
- the dot backlight 130 may be in direct contact with the side surface of the optical fingerprint sensor.
- an optical glue may be disposed between the self-luminous display panel and the optical fingerprint sensor.
- the material of the optical adhesive layer may specifically be a thermosensitive optical adhesive layer, a photosensitive optical adhesive layer or an optical double-sided adhesive tape. The presence of the optical glue minimizes the presence of air between the self-luminous display panel and the optical fingerprint sensor, further improving the optical performance of the module.
- the optical fingerprint sensor and the self-luminous display panel may be directly stacked, and “direct lamination” means that the optical fingerprint sensor and the self-luminous display panel are at least partially in contact, when both are generally flat. It may just be a stacked form as shown in FIG.
- the distance between the photosensitive pixel unit of the optical fingerprint sensor and the upper surface of the first substrate 111 is small to ensure the distance.
- the fingerprint image quality obtained by fingerprint acquisition meets the required requirements.
- the area of the display pixel unit 1131 in the OLED display panel is less than or equal to the area of the photosensitive pixel unit in the optical fingerprint sensor.
- one of the optical fingerprint sensors and the upper and lower positions of one display pixel unit 1131 of the OLED display panel can be associated, thereby better ensuring subsequent fingerprint images. collection.
- one photosensitive pixel unit may be directly opposite to one display pixel unit 1131, and the area of the photosensitive pixel unit is equal to the area of the display pixel unit 1131.
- the light transmitting region 11311 of the display pixel unit 1131 corresponds at least to the photosensitive element of the photosensitive pixel unit. Since the two areas are equal in area, the two can also be aligned one by one, and there can be some misalignment between them. From a macroscopic point of view, the alignment relationship of each of the photosensitive pixel units and the display pixel unit 1131 is uniform, so that it is ensured that the received emission (reflection) light signals of the respective photosensitive pixel units are uniform.
- a plurality of display pixel units 1131 may correspond to one of the photosensitive pixel units. That is to say, one of the photosensitive pixel units may correspond to two or more display pixel units 1131 (ie, the area of the photosensitive pixel unit is smaller than the area of the display pixel unit 1131). From a macroscopic point of view, the alignment relationship of each photosensitive pixel unit and two or more display pixel units 1131 is uniform, so that the received transmitted (reflected) optical signals of the respective photosensitive pixel units can be ensured to be uniform.
- the principle of the display module provided by the present embodiment is that the light emitted by the dot backlight 130 passes through the transparent adhesive 140, enters the second substrate 112 obliquely upward, and enters the self-luminous from the second substrate 112.
- the light-transmitting region 11311 of the circuit layer 113 passes through the self-light-emitting circuit layer 113 obliquely upward from the light-transmitting region 11311 to enter the first substrate 111.
- the first substrate 111 is directly used for contact or pressing of a finger fingerprint.
- light rays may be refracted, reflected, and absorbed at the interface formed by the upper surface of the first substrate 111 and the fingerprint, and correspondingly, a part of the reflected light is generated; the reflected light is returned to the first substrate 111, and then A substrate obliquely enters the light-transmitting region 11311 of the self-illuminating circuit layer 113 and passes obliquely downward from the light-transmitting region 11311 through the self-light-emitting circuit layer 113 to enter the second substrate 112, and then enters the fingerprint from the second substrate 112.
- the circuit layer 121 is received by each photosensitive pixel unit in the fingerprint sensing circuit 121 (specifically absorbed by the photosensitive element of the photosensitive pixel unit), and subjected to signal processing to realize acquisition of the corresponding fingerprint image.
- the above process can simultaneously refer to the black arrow (not labeled) in FIG. 1, the black arrow represents the light, but the corresponding refraction process indicating the light is omitted.
- the dot backlight 130 is located on the side of the fingerprint sensing circuit layer 121, it is easy to know that the incident angle of the corresponding light on the lower surface of the second substrate 112 is an acute angle, and after the light is finally reflected back, the reflected light is in the sense of fingerprint.
- the incident angle of the upper surface of the circuit layer 121 is also an acute angle. Therefore, at this time, the light emitted by the dot backlight 130 can generate a corresponding fingerprint image according to the corresponding offset. Therefore, the entire optical fingerprint sensor module can realize the fingerprint image without using a structure such as a light guide plate and a collecting lens.
- the identification of the fingerprint image is more clear than that of the light source using the light guide plate structure.
- the optical fingerprint sensor and the dot backlight 130 are both located under the second substrate 112 in the self-luminous display panel, and the dot backlight 130 is located on the side of the optical fingerprint sensor.
- the self-luminous display panel has a light-transmitting area, so that the light emitted by the point-like backlight 130 can be passed back and forth through the self-illuminating display panel, thereby enabling the collection of the finger fingerprint image, and the collected fingerprint image is clear, so that The display module integrates good fingerprint recognition.
- an optical fingerprint sensor is placed under the self-luminous display panel (OLED display panel), and the fingerprint image is collected in the display area of the display module by using the corresponding use method.
- the utility model can reduce the appearance size of the electronic product to which the display panel is applied, improve the screen ratio of the electronic product, and improve the appearance and appearance of the electronic product (for example, the screen ratio of the mobile phone product can be improved, and the appearance and appearance of the mobile phone product can be improved).
- the embodiment of the present invention further provides a method for using a display module.
- the display module is provided by the foregoing embodiment. Therefore, reference may be made to FIG. 1 .
- the display module includes a self-luminous display panel, an optical fingerprint sensor, and a dot backlight 130.
- the self-luminous display panel includes a first substrate 111, a second substrate 112, and a self-luminous circuit layer 113.
- the self-luminous circuit layer 113 is located between the first substrate 111 and the second substrate 112.
- the self-luminous circuit layer 113 includes a plurality of display pixel units.
- each display pixel unit 1131 includes at least one non-transmissive region and at least one light transmissive region, and the height of the light transmissive region is equal to the height of the self-illuminating circuit layer 113.
- the optical fingerprint sensor is located under the second substrate 112.
- the optical fingerprint sensor includes a fingerprint sensing circuit layer 121 and a substrate substrate 122.
- the fingerprint sensing circuit layer 121 is located between the second substrate 112 and the substrate substrate 122.
- the dot backlight 130 is located below the second substrate 112, and the dot backlight 130 is located at the side of the optical fingerprint sensor, and the light emitted by the dot backlight 130 enters the second substrate 112 at an obliquely upward angle.
- the usage method provided in this embodiment includes: defining a display area opposite to the optical fingerprint sensor in the self-luminous display panel as the first display area, and displaying the display area of the other part as the second display area; when the optical fingerprint sensor performs the fingerprint image When collecting work, Controlling the first display area stops displaying work.
- the first display area is provided to prevent the light from the self-luminous display panel from interfering with the light emitted by the point backlight 130.
- the embodiment can make the fingerprint image acquisition not affected by the self-luminous display panel.
- the method for using the embodiment further includes: when the optical fingerprint sensor performs the fingerprint image collection operation, controlling the second display area to display information associated with the fingerprint image collection work. For example, in the second display area, "Please enter a fingerprint in the non-display area" is displayed. During the fingerprint entry process, information such as “enter correct” or “please re-enter” is displayed. When the correct fingerprint is collected, “valid” can be displayed. “Fingerprint” and other information, or according to the fingerprint operation, display “operational success” and other messages. This method of use enables the display function and the fingerprint recognition function to work together to achieve a better user experience.
- the usage method may further develop an application scenario of the fingerprint recognition function. For example, before the optical fingerprint sensor is not working, the first display area is displayed with a corresponding display icon, and the user is instructed to put a finger into the icon. After the user puts the finger into the area where the icon is displayed, the existing display panel itself or the external touch function can be used to sense that the user has placed the finger in the first display area, thereby controlling the optical fingerprint sensor to enter the working state. At this time, the fingerprint image of the pressed fingerprint is collected by the optical fingerprint sensor below the first display area, and the fingerprint image collecting function is completed, and can be further applied to identify the existing fingerprint image stored internally, and further used for encryption/ Unlock and other functions.
- Another embodiment of the present invention provides another display module. Please refer to FIG. 2 .
- the display module includes a protective layer 210, a self-luminous display panel (not labeled), an optical fingerprint sensor 230, and a point backlight 240.
- the self-luminous display panel includes a first substrate 221, a second substrate 222, and a self-luminous circuit layer 223.
- the self-luminous circuit layer 223 is located between the first substrate 221 and the second substrate 222.
- the self-luminous display panel also includes a sealing structure 224. Sealing structure 224 It is also located between the first substrate 221 and the second substrate 222. The sealing structure 224, together with the first substrate 221 and the second substrate 222, seals the self-luminous circuit layer 223 between the first substrate 221 and the second substrate 222.
- the protection layer 210 is located above the first substrate 221 .
- the protective layer 210 is used as a finger contact structure, and the protective layer 210 can simultaneously protect the self-luminous display panel and the optical fingerprint sensor 230. And the structure of the dot backlight 240 and the like.
- the protective layer 210 is a single layer structure, that is, the protective layer 210 may be a substrate, as shown in FIG. 2 . In other embodiments, the protective layer may also be a multilayer structure.
- the materials of the first substrate 221 and the second substrate 222 may be transparent materials.
- the self-luminous circuit layer 223 includes a plurality of display pixel units 2231 (the adjacent relationship of the display pixel units 2231 is illustrated by a broken line in FIG. 2).
- Each display pixel unit 2231 includes at least one non-transmissive region and at least one light transmissive region 22311, and a light transmissive region 22311 is illustrated in FIG. 2 (ie, one of the light transmissive regions 22311 is surrounded by the smallest dotted frame in FIG. 2 The range shown).
- the self-luminous display panel is an OLED display panel, and the corresponding content of the corresponding embodiment of FIG. 1 can be referred to.
- the height of the light-transmitting region 22311 is set to be equal to the height of the self-light-emitting circuit layer 223, as shown in FIG. 2, thereby ensuring that light can pass through the self-light-emitting circuit layer 223 from the light-transmitting region.
- the light can pass through the self-illuminating circuit layer 223 from the light transmitting area, thereby ensuring that the display module can perform fingerprint image collection.
- the optical fingerprint sensor 230 is located below the second substrate 222. That is, the optical fingerprint sensor 230 is located below the self-luminous display panel.
- the optical fingerprint sensor 230 includes a fingerprint sensing circuit layer (not shown) and a substrate substrate (not shown), the fingerprint sensing circuit layer being located between the second substrate 222 and the substrate substrate, Reference may be made to the corresponding content of the corresponding embodiment of FIG. 1.
- the fingerprint sensing circuit layer of the optical fingerprint sensor 230 includes a plurality of photosensitive pixel units (not shown). For more structures, reference may be made to the corresponding content of the corresponding embodiment of FIG. 1.
- the dot backlight 240 is located below the second substrate 222, and the dot backlight 240 is located at the side of the optical fingerprint sensor 230.
- the light emitted by the dot backlight 240 enters the second substrate 222 at an obliquely upward angle.
- the point backlight 240 is disposed on the side of the optical fingerprint sensor 230, and the reflected light for collecting the fingerprint image can be ensured, and the optical fingerprint sensor 230 must be entered at an oblique incident angle (ie, obliquely downwardly incidentally enters).
- the optical fingerprint sensor 230 the detailed process may refer to the corresponding content of the corresponding embodiment of FIG. 1).
- the arrangement of the dot backlight 240 enables the light to be substantially shifted in the same direction (while the light of the light guide plate is disordered in various directions, and the offset direction is different).
- the mutual interference and mutual influence between the light rays are avoided (the light of the light guide plate interferes with each other and affects each other), and the light offsets close to the position of the point backlight 240 are similar, so that a clear fingerprint image can be obtained. Improve the fingerprint recognition performance of the module.
- the dot backlight 240 can be an LED lamp.
- the light of the LED lamp may be near ultraviolet light, purple light, blue light, green light, yellow light, red light, near infrared light or white light.
- the dot backlight may be two or more LED lamps, and two or more LED lamps are evenly distributed under the second substrate, and the LED lamps are near ultraviolet light, purple light, and blue light. , green, yellow, red, near-infrared or white.
- the point backlight may be four LED lamps, the four LED lamps are evenly distributed under the second substrate, and are evenly distributed on the side of the optical fingerprint sensor 230, or four lamps are uniformly distributed on the optical fingerprint sensor at the same time. The four corners of 230. At this time, although the light emitted by the four LED lamps may each be non-parallel light, the image distortion of the non-parallel light can be corrected by using the four LED lamps at the same time.
- the four LED lights can take the method of taking pictures in turn (the four pictures of the rotating pictures are taken separately according to the time series), and then the image processing is used to correct the distortion, improve the quality of the fingerprint image, and improve the accuracy of fingerprint recognition.
- the point backlight is a plurality of LED lights
- the light of any one of the LED lights can be selected as the imaging light of the fingerprint image.
- the embodiment corresponds to the embodiment of FIG.
- the imaging effect is similar.
- a light-transmitting paste 250 is disposed between the dot-shaped backlight 240 and the second substrate 222 , and the light emitted by the dot-shaped backlight 240 enters from the light-emitting surface of the dot-shaped backlight 240 .
- the light transmissive glue 250 enters the second substrate 222 from the light transmissive glue 250.
- the light-transmitting adhesive 250 is disposed such that the light emitted by the dot-shaped backlight 240 is more incidentally incident on the second substrate 222 to reduce the interface reflection.
- the refractive index of the transparent adhesive 250 is greater than 1, and the entering of the second substrate 222 is reduced. The extent of the refraction of light.
- the light-transmitting glue is not disposed, the light emitted by the dot-shaped backlight needs to pass through the vacuum or the air, and then enters the second substrate, and the light is more likely to be reflected at the interface formed by the vacuum or the air and the surface of the second substrate, and Air can also cause some light to scatter and other adverse effects.
- the display module there is a space (not labeled) between the dot backlight 240 and the optical fingerprint sensor 230.
- the corresponding content of the corresponding embodiment of FIG. 1 can be referred to.
- the self-luminous display panel and the optical fingerprint sensor 230 may have an optical glue, and the corresponding content of the corresponding embodiment of FIG. 1 may be referred to.
- the self-luminous display panel and the protective layer 210 may have an optical glue, and the presence of the optical glue avoids the self-luminous display. There is a possibility of air between the panel and the protective layer 210, so that the optical performance of the display module is better.
- the distance between the photosensitive pixel unit of the optical fingerprint sensor 230 and the upper surface of the first substrate 221 is smaller. To ensure that the quality of the fingerprint image obtained by fingerprint acquisition meets the required requirements.
- the photosensitive pixel unit in the optical fingerprint sensor 230 and the upper and lower positions of the display pixel unit 2231 in the OLED display panel may be associated to better ensure subsequent fingerprint image collection.
- One photosensitive pixel unit may be corresponding to the four display pixel units 2231, and the area of the photosensitive pixel unit is equal to the area of the four display pixel units 2231.
- the principle of the display module provided in this embodiment is the same as that of the corresponding embodiment of FIG. 1 except that the light in the embodiment does not reach the finger fingerprint.
- a substrate 221 is obliquely propagated upward to the protective layer 210, and an optical phenomenon such as refraction and reflection occurs at an interface formed by the upper surface of the protective layer 210 and the finger fingerprint, and then the reflected light which is obliquely returned to the protective layer 210 is generated.
- the above process can simultaneously refer to the black arrow (not labeled) in FIG. 2, the black arrow represents the light, but the corresponding refraction process indicating the light is omitted.
- the light transmissive layer 260 is further disposed on the lower surface of the transparent adhesive 250 and the second substrate 222.
- the light anti-reflection layer 260 can increase the proportion of the light of the point backlight 240 into the second substrate 222.
- the light-emitting surface of the dot-shaped backlight may have a collecting lens in front of the light-collecting lens, and the collecting lens can convert the light of the point-like backlight into parallel light or near-parallel light (the near-parallel light finger).
- the difference in angle between the lights is less than 10 degrees.
- the light from the point backlight enters the condenser lens and then enters the second substrate.
- the setting of the concentrating lens can further avoid the problem that the fingerprint image is distorted.
- Another embodiment of the present invention further provides a method for using another display module.
- the display module is provided in the previous embodiment. Therefore, reference may be made to FIG. 2 .
- the display module includes a protective layer 210, the self-luminous display panel, the optical fingerprint sensor 230, and the dot backlight 240.
- the self-luminous display panel includes a first substrate 221 and a second The substrate 222 and the self-lighting circuit layer 223 are located between the first substrate 221 and the second substrate 222.
- the self-lighting circuit layer 223 includes a plurality of display pixel units 2231, and each of the display pixel units 2231 includes at least one non- The light transmissive area and the at least one light transmissive area have a height equal to the height of the self-illuminating circuit layer 223.
- the optical fingerprint sensor 230 is located under the second substrate 222.
- the optical fingerprint sensor 230 includes the fingerprint sensing circuit layer and the base substrate 222.
- the fingerprint sensing circuit layer is located between the second substrate 222 and the substrate 222.
- the dot backlight 240 is located below the second substrate 222, and the dot backlight 240 is located at the side of the optical fingerprint sensor 230.
- the light emitted by the dot backlight 240 enters the second substrate 222 at an obliquely upward angle.
- the usage method provided by this embodiment includes: defining a display area of the self-luminous display panel opposite to the optical fingerprint sensor 230 as a first display area, and displaying a display area of other parts as a second display area; when the optical fingerprint sensor 230 performs When the fingerprint image is collected, the first display area is controlled to stop displaying work.
- the embodiment can make the fingerprint image acquisition not affected by the self-luminous display panel.
- the usage method provided in this embodiment further includes: when the optical fingerprint sensor 230 performs a fingerprint image collection operation, controlling the second display area to display information associated with the fingerprint image collection work. For example, in the second display area, "Please enter a fingerprint in the non-display area" is displayed. During the fingerprint entry process, information such as “enter correct” or “please re-enter” is displayed. When the correct fingerprint is collected, “valid” can be displayed. “Fingerprint” and other information, or according to the fingerprint operation, display “operational success” and other messages. This method of use enables the display function and the fingerprint recognition function to work together to achieve a better user experience.
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Abstract
L'invention concerne un module d'affichage et son procédé d'utilisation. Le module d'affichage comprend un panneau d'affichage auto-luminescent, le panneau d'affichage auto-luminescent comprenant un premier substrat (111), un second substrat (112), et une couche de circuit auto-luminescente (113), la couche de circuit auto-luminescente (113) étant située entre le premier substrat (111) et le second substrat (112), et la couche de circuit auto-luminescente (113) comprenant une pluralité d'unités de pixels d'affichage (1131); chaque unité de pixel d'affichage (1131) comprenant au moins une zone ne transmettant pas la lumière et au moins une zone transmettant la lumière (11311); et comprenant également un capteur d'empreinte digitale optique, le capteur d'empreinte digitale optique étant situé sous le second substrat (112), le capteur d'empreinte digitale optique comprenant une couche de circuit de détection d'empreinte digitale (121) et un substrat de base (122), la couche de circuit de détection d'empreinte digitale (121) étant située entre le second substrat (112) et le substrat de base (122); et une source de rétroéclairage à points (130), la source de rétroéclairage à points (130) étant située sous le second substrat (112) et sur le côté du capteur d'empreinte digitale optique, et le rayon lumineux émis par la source de rétroéclairage à points (130) entrant dans le second substrat (112) à un angle oblique vers le haut. Le module d'affichage intègre ainsi efficacement une fonction de reconnaissance optique d'empreinte digitale.
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CN201611131880.1A CN108227973A (zh) | 2016-12-09 | 2016-12-09 | 显示模组及其使用方法 |
CN201611131880.1 | 2016-12-09 |
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CN109299708A (zh) * | 2018-11-30 | 2019-02-01 | 上海箩箕技术有限公司 | 光学指纹传感器模组及其形成方法 |
CN109564629A (zh) * | 2018-10-15 | 2019-04-02 | 深圳市汇顶科技股份有限公司 | 指纹检测装置及具有指纹识别功能的终端设备 |
CN110785771A (zh) * | 2019-01-22 | 2020-02-11 | 深圳市汇顶科技股份有限公司 | 屏下光学指纹识别系统、指纹识别显示装置及电子设备 |
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CN110458124B (zh) * | 2019-08-16 | 2024-09-20 | 深圳阜时科技有限公司 | 光学检测装置 |
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