CN110263747B - Control method, electronic device, and non-volatile computer-readable storage medium - Google Patents

Abstract

The application discloses a control method, an electronic device and a non-volatile computer-readable storage medium. Display device includes fingerprint identification module. The fingerprint identification module corresponds in display device's the regional display area that is located display device of fingerprint identification, and the fingerprint identification is regional including marginal area and except that marginal area non-marginal area, and marginal area is located the edge of at least one side of display area. The control method comprises the following steps: acquiring the working state of the display device; acquiring a touch position of a finger of a user touching a fingerprint identification area; when the working state is the extinguishing state and the touch position is located at the edge position, the fingerprint identification module is in the non-working state. The control method of the embodiment determines whether the fingerprint identification module is triggered to work by judging whether the touch position of the finger of the user touching the fingerprint identification area is located in the edge area, so that the false triggering problem in most scenes can be avoided, and the energy consumption of the electronic equipment can be saved.

Description

Control method, electronic device, and non-volatile computer-readable storage medium

Technical Field

The present application relates to the field of mobile terminal technologies, and in particular, to a control method, an electronic device, and a non-volatile computer-readable storage medium.

Background

Electronic devices are often configured with fingerprint recognition functionality to enhance security of use of the electronic device, such as using fingerprint recognition for unlocking, payment, and the like. For fluency and convenience when guaranteeing the user and using electronic equipment, for example can unblock electronic equipment etc. fast when receiving user's unblock operation, the fingerprint identification module is under real-time operating condition usually to make electronic equipment can respond to user's operation fast. But the fingerprint identification module produces a series of false triggering problems easily under real-time operating condition, and the false triggering back still can be because the fingerprint identification is unsuccessful makes electronic equipment make unnecessary suggestion etc. to the user, seriously influences user's use and experiences.

Disclosure of Invention

The embodiment of the application provides a control method, electronic equipment and a non-volatile computer readable storage medium.

The control method of the embodiment of the application is used for the electronic equipment. The electronic equipment comprises a display device, the display device comprises a fingerprint identification module, the fingerprint identification module corresponds to a fingerprint identification area on the display device and is located in a display area of the display device, the fingerprint identification area comprises an edge area and a non-edge area except the edge area, and the edge area is located on the edge of at least one side of the display area. The control method comprises the following steps: acquiring the working state of the display device; acquiring a touch position of a finger of a user touching the fingerprint identification area; when the working state is an off state and the touch position is located in the edge area, the fingerprint identification module is in a non-working state.

The electronic equipment of the embodiment of the application comprises a display device and a processor. The display device comprises a fingerprint identification module and a touch module, wherein the fingerprint identification module corresponds to a fingerprint identification area on the display device and is located in a display area of the display device, the fingerprint identification area comprises an edge area and a non-edge area except the edge area, and the edge area is located on the edge of at least one side of the display area. The processor is used for acquiring the working state of the display device. The touch module is used for acquiring a touch position of a finger of a user touching the fingerprint identification area. When the working state is an off state and the touch position is located in the edge area, the fingerprint identification module is in a non-working state.

The non-transitory computer-readable storage medium of the embodiments of the present application contains computer-readable instructions, which, when executed by a processor, cause the processor to execute the control method described above.

According to the control method, the electronic device and the nonvolatile computer readable storage medium, whether the fingerprint identification module is triggered to work or not is determined by judging whether the touch position of the finger of the user touching the fingerprint identification area is located in the edge area or not, the problem of false triggering in most scenes can be avoided, and the energy consumption of the electronic device can be saved.

Additional aspects and advantages of embodiments of the present application will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the present application.

Drawings

The above and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a schematic flow chart of a control method according to some embodiments of the present application.

Fig. 2 is a schematic structural diagram of an electronic device according to some embodiments of the present application.

FIG. 3 is a schematic diagram of a fingerprint identification area and a display area in accordance with certain embodiments of the present application.

Fig. 4 and 5 are schematic views of an edge region and a non-edge region of certain embodiments of the present application.

Fig. 6 to 8 are schematic flow charts of a control method according to some embodiments of the present disclosure.

FIG. 9 is a schematic diagram of a gravity sensor according to certain embodiments of the present application.

Fig. 10 and 11 are schematic views of the use posture of the electronic apparatus.

FIG. 12 is a flow chart illustrating a control method according to some embodiments of the present application.

FIG. 13 is a schematic illustration of a center region and a non-center region according to certain embodiments of the present application.

Fig. 14-18 are flow diagrams illustrating a control method according to some embodiments of the present disclosure.

FIG. 19 is a schematic cross-sectional view of a display device according to certain embodiments of the present application.

Fig. 20 is a schematic diagram of a display device for fingerprint recognition according to some embodiments of the present application.

Fig. 21 is a schematic perspective view of a display device according to some embodiments of the present disclosure.

Fig. 22 is a schematic structural diagram of a photosensitive layer and an imaging chip according to some embodiments of the present disclosure.

FIG. 23 is a schematic structural diagram of a photosensitive layer and a display driving layer according to some embodiments of the present disclosure.

Fig. 24 is a schematic plan view of a second substrate according to some embodiments of the present disclosure.

Fig. 25 and 26 are schematic side view structural diagrams of a display device according to an embodiment of the present application.

FIG. 27 is an exploded view of a display device according to certain embodiments of the present application.

Fig. 28 and 29 are schematic cross-sectional views of display devices according to certain embodiments of the present application.

Figure 30 is a schematic diagram of a capacitive fingerprint sensor diaphragm according to some embodiments of the present application.

Fig. 31 to 33 are schematic cross-sectional views of display devices according to some embodiments of the present application.

FIG. 34 is a schematic cross-sectional view of an LCM display screen according to certain embodiments of the present application.

FIG. 35 is a schematic cross-sectional view of an OLED display screen according to certain embodiments of the present application.

Fig. 36 and 37 are schematic cross-sectional views of display devices according to certain embodiments of the present application.

Figure 38 is a schematic diagram of a capacitive fingerprint sensor diaphragm according to some embodiments of the present application.

FIG. 39 is a schematic diagram of the interaction of a non-volatile readable storage medium and a processor of certain embodiments of the present application.

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below by referring to the drawings are exemplary only for the purpose of explaining the embodiments of the present application, and are not to be construed as limiting the embodiments of the present application.

Referring to fig. 1 to 5, the present application provides a control method for an electronic device 1000. The electronic device 1000 includes a display apparatus 100. The display device 100 includes a fingerprint identification module 20. The fingerprint identification module 20 is located in the display area 711 of the display device corresponding to the fingerprint identification area 712 on the display device 100. The fingerprint identification area 712 includes a border area 7121 and a non-border area 7122 excluding the border area 7121, the border area 7121 is located at the border of at least one side of the display area 711. The control method comprises the following steps:

011: acquiring the working state of the display device 100;

012: acquiring a touch position where a finger of the user touches the fingerprint identification area 712;

013: judging whether the working state is a turning-off state or not and whether the touch position is located in the edge area 7121 or not; and

014: when the operating state is the off state and the touch position is located in the border area 7121, the fingerprint identification module 20 is in the non-operating state.

Referring to fig. 2 to 5, an electronic device 1000 is also provided. The electronic device includes the display apparatus 100 and the processor 300, and the processor 300 may be one or more. The display device 100 includes a fingerprint recognition module 20 and a touch module 60. The fingerprint identification module 20 is located in the display area 711 of the display device 100 corresponding to the fingerprint identification area 712 on the display device 100. The fingerprint identification area 712 includes a border area 7121 and a non-border area 7122 excluding the border area 7121, the border area 7121 is located at the border of at least one side of the display area 711. Both step 011 and step 013 can be implemented by processor 300. Step 012 can be implemented by touch module 60. Step 014 can be implemented by the fingerprint recognition module 20. That is, the processor 300 may be used to acquire the operating state of the display device 100. The touch module 60 can be used to obtain the touch position of the finger of the user touching the fingerprint identification area 712. The processor 300 may be configured to determine whether the operation status is off and whether the touch location is in the border area 7121. When the operating state is the off state and the touch position is located in the border area 7121, the fingerprint identification module 20 is in the non-operating state. It should be noted that: the fingerprint identification module 20 and the touch module 60 shown in fig. 2 are only shown to be disposed on the electronic device 1000, and the size and the disposition position of the area of the fingerprint identification module 20 and the touch module 60 cannot be explained.

The electronic device 1000 may be a mobile phone, a tablet computer, a notebook computer, an intelligent wearable device (such as an intelligent watch, an intelligent bracelet, an intelligent helmet, an intelligent glasses, and the like), a virtual reality device, a display, a teller machine, a game console, an intelligent furniture, and the like. The electronic device 1000 is a mobile phone as an example for explanation in the present application, and it is to be understood that the specific form of the electronic device 1000 is not limited to the mobile phone.

Referring to fig. 2 and 3, the display device 100 integrates fingerprint recognition, display, and touch functions. The fingerprint identification module 20 and the touch module 60 are integrated in the display device 100. Fingerprint identification module 20 can be optical fingerprint module, electric capacity fingerprint module, ultrasonic fingerprint module etc. The fingerprint identification module 20 is located in the display area 711 of the display device 100 corresponding to the fingerprint identification area 712 on the display device 100, specifically, a ratio of an area of the fingerprint identification area 712 to an area of the display area 711 is greater than a predetermined ratio, for example, the predetermined ratio may be 15%, a ratio of an area of the fingerprint identification area 712 to an area of the display area 711 may be 15%, 20%, 30%, 43%, 56%, 66.7%, 72%, 80%, 90%, 95%, 99%, 100%, and the like, and when a value range of the ratio is [ 15%, 100%), the area fingerprint identification may be implemented (shown in (1) in fig. 3); when the ratio is 100%, full screen fingerprinting can be achieved (shown in (2) of fig. 3). At this time, the fingerprint identification module 20 may simultaneously identify a plurality of fingers touching the fingerprint identification area 712, rather than only one finger. The area of the touch module 60 corresponding to the area capable of sensing the touch operation of the finger of the user on the display device 100 is the same as the area of the display area 711.

Referring to fig. 4 and 5, if the fingerprint identification area 712 is only a partial area (i.e., an area fingerprint) in the display area 711, the fingerprint identification area 712 may include a part or all of the edge of at least one side of the display area 711; if the fingerprint identification area 712 is the entire area of the display area 711 (i.e. full screen fingerprint), the fingerprint identification area 712 includes all the four edges of the display area 711. For example, as shown in (1) and (2) of fig. 4, the fingerprint identification area 712 is an area fingerprint, the border area 7121 is partially distributed around the non-border area 7122, and the border area 7121 is located at the border of one side of the fingerprint identification area 712. For example, as shown in (3) of fig. 4, the fingerprint identification area 712 is an area fingerprint, the border area 7121 is partially distributed around the non-border area 7122, and the border area 7121 is located at the border of the two sides of the fingerprint identification area 712. For example, as shown in (4) of fig. 4, the fingerprint identification area 712 is an area fingerprint, the border area 7121 is partially distributed around the non-border area 7122, and the border area 7121 is located at the border of three sides of the fingerprint identification area 712. The border area 712 is located at the border of the display area 711, regardless of which side of the fingerprint identification area 712 the border area 7121 is located. Referring to fig. 5, when the fingerprint identification area 712 is a full-screen fingerprint, the edge area 7121 may be located at the edge of one side of the fingerprint identification area 712 (shown in (1) of fig. 5), or at the edge of two sides of the fingerprint identification area 712 (shown in (2) of fig. 5), or at the edge of three sides of the fingerprint identification area 712 (shown in (3) of fig. 5), or at the edge of four sides of the fingerprint identification area 712 (shown in (4) of fig. 5). The ratio of the area of the border region 7121 to the area of the fingerprint identification region 712 may range from (0, 30% ], e.g., the ratio may be 5%, 10%, 16.8%, 20%, 25%, 30%, etc. the shape of the non-border region 7122 is not limited to the rectangle of fig. 4 and 5, but may also be a rounded rectangle, square, trapezoid, triangle, circle, ellipse, polygon, irregular figure (e.g., heart, pentagon, etc.), etc., without limitation.

In the existing mobile phone with fingerprint identification function, the fingerprint identification module 20 is usually in a real-time working state to ensure that the response to the operation of the user can be made fastest. However, the fingerprint recognition module 20 may cause a series of false triggering problems when it is in a real-time operation state. For example, when the display device 100 is turned off (i.e. in a black screen state), the user holds the mobile phone, and the finger of the user often touches the border area 7121, the fingerprint recognition module 20 obtains the fingerprint image to enable the processor 300 to perform the identity verification of the fingerprint recognition, but the user does not actually need to perform the operation of the fingerprint recognition by the mobile phone, and at this time, the problem of false triggering occurs. The false triggering of the fingerprint identification module 20 not only affects the user's experience of using the electronic device 1000, but also consumes the power of the electronic device 1000.

The control method of the present application obtains the operating state of the display device 100 and the touch position of the finger touching the fingerprint identification area 712, and determines whether to trigger the fingerprint identification module 20 to operate according to the operating state and the touch position.

Specifically, when the display device 100 detects a touch operation of a user, the processor 300 acquires an operating state of the display device 100, the touch module 60 acquires a touch point where a finger touches the fingerprint identification area 712, and the processor 300 determines a touch position where the finger touches the fingerprint identification area 712 according to coordinates of the touch point. If the working state of the display device 100 is the off state and the touch position is located in the border area 7121, the processor 300 determines that the user does not need to perform the fingerprint identification operation by the mobile phone at this moment, the processor 300 does not control the fingerprint identification module 20 to acquire the fingerprint image, and the fingerprint identification module 20 is in the non-working state.

The control method and the electronic device 1000 according to the embodiment of the application acquire the operating state of the display device 100 and the touch position of the finger touching the fingerprint identification area 712, and determine whether to trigger the fingerprint identification module 20 to operate according to the operating state and the touch position, so that the problem of false triggering in most scenes can be avoided, and the energy consumption of the electronic device 1000 can be saved.

Referring to fig. 6, in some embodiments, the control method further includes:

015: when the working state is a lighting state or the touch position is located in the non-edge area 7122, acquiring the touch area of the finger touching the fingerprint identification area 712;

016: judging whether the touch area is larger than a preset area or not;

when the touch area is larger than the preset area, the fingerprint identification module 20 is in a non-working state;

017: when the touch area is smaller than the preset area, the fingerprint recognition module 20 acquires the fingerprint image of the finger.

Referring to fig. 2, in some embodiments, step 015 may be implemented by the touch module 60. Step 016 can be implemented by processor 300. That is, the touch module 60 can be used to obtain the touch area of the finger touching the fingerprint identification area 712 when the operation state is the lighting state or the touch position is located in the non-edge area 7122. The processor 300 may be configured to determine whether the touch area is larger than a predetermined area. When the touch area is larger than the preset area, the fingerprint identification module 20 is in a non-working state. When the touch area is smaller than the preset area, the fingerprint recognition module 20 acquires the fingerprint image of the finger.

Specifically, when the operation state of the display device 100 is a lighting state (at this time, the touch position may be located in the border region 7121 or the non-border region 7122), or the operation state of the display device 100 is a lighting state and the touch position is located in the non-border region 712, the processor 300 needs to further determine whether the touch area of the user touching the fingerprint identification region 712 is larger than a preset area. The touch area of the user touching the fingerprint identification area 712 refers to the touch area of the finger obtained after the touch module 60 performs a full-screen scan, and the touch area can be calculated according to the touch point. Specifically, after a full-screen scan is performed by the touch module 60, one or more touch points can be obtained. The touch module 60 reports one or more touch points to the processor 300, the processor 300 divides at least one touch point into at least one touch area according to coordinates of the touch point, merges the touch points in the same touch area into touch points obtained by touching the fingerprint identification area 712 with the same finger, and the processor 300 calculates an area of the at least one touch area as a touch area of the corresponding finger touching the fingerprint identification area 712. Subsequently, the processor 300 determines whether the touch area is larger than a preset area, wherein when one touch area is present, the processor 300 determines whether the touch area of the one touch area is larger than the preset area; when there are multiple touch areas, the processor 300 determines whether the sum of the touch areas of the multiple touch areas is greater than a preset area. When the touch area of a touch area is greater than or equal to the preset area, or the sum of the touch areas of a plurality of touch areas is greater than or equal to the preset area, the processor 300 also considers that the user does not need the mobile phone to execute the operation of fingerprint identification at the moment, the processor 300 does not control the fingerprint identification module 20 to acquire the fingerprint image, and the fingerprint identification module 20 is in a non-working state. When the touch area of one touch area is smaller than the preset area or the sum of the touch areas of a plurality of touch areas is smaller than the preset area, the processor 300 considers that the user needs to perform fingerprint identification on the finger, and the processor 300 controls the fingerprint identification module 20 to acquire a fingerprint image.

It can be understood that when the touch area of one touch area is greater than or equal to the preset area, it indicates that the user may be holding the mobile phone at this time and the palm contacts the fingerprint identification area 712, and at this time, the user does not need the mobile phone to perform fingerprint identification, and the fingerprint identification module 20 may not operate. When the sum of the touch areas of the multiple touch areas is greater than or equal to the preset area, it indicates that the mobile phone may be held by the user at the moment, and the multiple fingers simultaneously contact the fingerprint identification area 712, and at this moment, the user does not need to perform fingerprint identification on the mobile phone, and the fingerprint identification module 20 may not operate. When the touch area is smaller than the preset area, the processor 300 considers that the user needs to perform fingerprint identification on the mobile phone at the moment, and the processor 300 controls the fingerprint identification module 20 to work. Fingerprint identification module 20 acquires the fingerprint image of finger and sends the fingerprint image for treater 300, and the matching degree between treater 300 comparison fingerprint image and the fingerprint template of prestoring, when the matching degree is greater than preset matching degree, fingerprint identification succeeds. In addition, an application installed on the mobile phone can be locked by using a fingerprint, if the position of the application in the display area 712 is just located in the border area 7121, when the display device 100 is in the lighting state, a finger of a user may touch the border area 7121 to unlock the application in the border area 7121, and therefore, when the display device 100 is lit and the touch position is located in the border area 7121, if the touch area is smaller than the preset area, the fingerprint identification module 20 is triggered.

When the operating state of the display device 100 is the on state, or the operating state of the display device 100 is the off state and the touch position is located in the non-edge area 7122, the control method and the electronic device 1000 further determine whether to trigger the fingerprint identification module 20 to be turned on by determining whether the touch area is larger than the preset area, so as to further avoid the problem of false triggering and improve the user experience.

Referring to fig. 7, in some embodiments, when the touch area is smaller than the predetermined area, the step of the fingerprint identification module 20 acquiring the fingerprint image of the finger includes:

0171: acquiring a current distance between the electronic device 1000 and a target object;

0172: judging whether the current distance is greater than a preset distance;

when the current distance is smaller than the preset distance, the fingerprint identification module 20 is in a non-working state;

when the present distance is greater than the preset distance, the fingerprint recognition module 20 acquires the fingerprint image.

Referring to fig. 2, in some embodiments, the electronic device 1000 further includes a distance detection apparatus 400. Step 0171 may be implemented by the distance detection means 400. Step 0172 may be implemented by processor 300. That is, the distance detection apparatus 400 may be used to acquire the current distance between the electronic device 1000 and the target object. The processor 300 may be configured to determine whether the current distance is greater than a preset distance. When the current distance is less than the preset distance, the fingerprint identification module 20 is in a non-working state. When the present distance is greater than the preset distance, the fingerprint recognition module 20 acquires the fingerprint image.

Specifically, when the operating state of the display device 100 is a lighting state (at this time, the touch position may be located in the edge area 7121 or the non-edge area 7122), or the operating state of the display device 100 is a lighting state and the touch position is located in the non-edge area 7122, the processor 300 needs to further determine whether the current distance between the electronic device 1000 and the target object (i.e., the obstacle) is greater than the preset distance. The distance detection device 400 may be a depth camera (structured light depth camera, time-of-flight depth camera, binocular depth camera, etc.), a proximity sensor, etc., and is not limited herein. The preset distance can be 5cm, 6.5cm, 8cm, 9cm, 10cm, 11.4cm, 12cm, 13.7cm, 14cm, 15cm, etc. When present distance is less than or equal to and predetermines the distance, processor 300 thinks that the user does not need the cell-phone to carry out fingerprint identification's operation this moment, and processor 300 does not control fingerprint identification module 20 and acquires the fingerprint image, and fingerprint identification module 20 is in non-operating condition. When present distance is greater than the default distance, treater 300 thinks that the user needs the cell-phone to carry out fingerprint identification, and treater 300 control fingerprint identification module 20 acquires the fingerprint image.

It can be understood that when the current distance is less than or equal to the preset distance, it indicates that the user may be in a situation where the mobile phone is placed in a pocket, the mobile phone is placed in a backpack, the user places the mobile phone on a cheek to answer a call, and the like, at this time, the user does not need to perform fingerprint identification on the mobile phone, and the fingerprint identification module 20 may not operate.

When the operating state of the display device 100 is the on state, or the operating state of the display device 100 is the off state and the touch position is located in the non-edge area 7122, the control method and the electronic device 1000 further determine whether to trigger the fingerprint identification module 20 to be turned on by judging whether the current distance is greater than the preset distance, so that the problem of false triggering can be further avoided, and the user experience can be improved.

Referring to fig. 8, in some embodiments, in step 017, when the touch area is smaller than the predetermined area, the acquiring the fingerprint image of the finger by the fingerprint identification module 20 includes:

0173: acquiring the use posture of the electronic device 1000;

0174: judging whether the use posture meets a preset condition or not;

when the using posture does not meet the preset condition, the fingerprint identification module 20 is in a non-working state;

when the use gesture satisfies the predetermined condition, fingerprint identification module 20 acquires the fingerprint image.

Referring to fig. 2, in some embodiments, the electronic device 1000 further includes an attitude sensor 500. Step 0173 can be implemented by attitude sensor 500. Step 0174 may be implemented by processor 300. That is, the posture sensor 500 may be used to acquire the usage posture of the electronic device 1000. The processor 300 may be configured to determine whether the usage gesture satisfies a predetermined condition. When the use posture does not satisfy the predetermined condition, the fingerprint identification module 20 is in a non-operating state. When the use gesture satisfies the predetermined condition, fingerprint identification module 20 acquires the fingerprint image.

The attitude sensor 500 may be a gravity sensor, a gyroscope, or other sensor. The usage posture of the electronic device 1000 includes an inclination of the electronic device 1000, which may indicate a placement angle of the electronic device 1000 and an orientation of the display surface 71 of the display apparatus 100. In the embodiment of the present application, the attitude sensor 500 is exemplified as a gravity sensor. Referring to fig. 9, if the electronic device 1000 is placed perpendicular to the horizontal plane (shown in the left diagram (1) of fig. 9 or the right diagram (2) of fig. 9), the usage posture of the electronic device 1000 is defined as the tilt angle 0 °, and when the electronic device 1000 is rotated clockwise by the angle θ, the usage posture of the electronic device 1000 is defined as the tilt angle θ ° (shown in the right diagram (1) of fig. 9). When the electronic apparatus 1000 is rotated counterclockwise by an angle θ, the usage posture of the electronic apparatus 1000 is the inclination angle- θ ° (shown in the left diagram of (2) in fig. 9). The gravity sensor can acquire acceleration values of the Y axis and the Z axis, and the processor 300 calculates the tilt angle of the electronic device 1000 according to the acceleration values of the Y axis and the Z axis, and further determines the placement angle of the electronic device 1000 and the orientation of the display surface 71 according to the tilt angle.

The case where the usage posture of the electronic device 1000 does not satisfy the predetermined condition may include: (1) as shown in fig. 10, the mobile phone is placed vertically with the display surface 71 facing the user (shown in (1) and (3) of fig. 10) or the rear case 220 of the housing 200 facing the user (i.e., the display surface 71 faces away from the user, shown in (2) of fig. 10); (2) as shown in fig. 11, the mobile phone is placed horizontally with the display surface 71 facing downward. When the operating state of the display device 100 is a lighting state (at this time, the touch position may be located in the border area 7121 or the non-border area 7122), or the operating state of the display device 100 is a lighting-off state and the touch position is located in the non-border area 7122, if the usage posture of the electronic device 1000 does not satisfy the predetermined condition, the processor 300 determines that the user does not need to perform the fingerprint identification by the mobile phone at this time, and the fingerprint identification module 20 is in the non-operating state. When the operating state of the display device 100 is a lighting state (at this time, the touch position may be located in the border area 7121 or the non-border area 7122), or the operating state of the display device 100 is a lighting-off state and the touch position is located in the non-border area 7122, if the usage posture of the electronic device 1000 meets a predetermined condition, the processor 300 determines that the user needs to perform fingerprint identification on the mobile phone at this time, and the fingerprint identification module 20 acquires a fingerprint image.

It will be appreciated that when a user uses the handset, the handset will not normally be placed vertically, but will be placed at an angle inclined with respect to the Z-axis. Thus, when the handset is upright, whether the display 71 is facing the user or facing away from the user, the user typically does not need to fingerprint the handset. The user also typically does not need the handset for fingerprinting when the handset is horizontally positioned with the display surface 71 facing downward. Therefore, if the operation state of the display device 100 is the on state, or the operation state of the display device 100 is the off state and the touched position is located in the non-edge area 7122, the fingerprint identification module 20 does not operate if the usage posture of the electronic apparatus 1000 does not satisfy the predetermined condition. When the operating state of the display device 100 is a lighting state, or the operating state of the display device 100 is a lighting-off state and the touch position is located in the non-edge region 7122, if the usage posture of the electronic apparatus 1000 satisfies a predetermined condition, that is, the electronic apparatus 1000 is not in a vertically placed state or the display surface 71 is not facing downward when the electronic apparatus 1000 is horizontally placed, the fingerprint recognition module 20 acquires the fingerprint image. Further, the non-satisfaction of the predetermined condition includes the following situations: theta takes the values of 0 degree, 90 degree, 180 degree, -90 degree, -180 degree. Satisfying the predetermined condition includes the following cases: theta is (0, 90) degree, (90, 180) degree, (-90, 0) degree, (-180, -90) degree.

When the operating state of the display device 100 is the on state, or the operating state of the display device 100 is the off state and the touch position is located in the non-edge area 7122, the control method and the electronic device 1000 further determine whether to trigger the fingerprint identification module 20 to be turned on by judging whether the usage posture meets the predetermined condition, so that the generation of the false triggering problem can be further avoided, and the usage experience of the user can be improved.

Referring to fig. 12 and 13, in some embodiments, the non-edge region 7122 includes a central region 7123 and a non-central region 7124 surrounding the central region 7123. Step 017 when area is less than the area of predetermineeing at the area, fingerprint identification module 20 acquires the fingerprint image of finger and includes:

0175: judging whether the touch position is located in the central area;

0176: when the touch position is located in the central area 7123, the fingerprint identification module 20 acquires a fingerprint image after a first response time period;

0177: when the touch position is located in the non-center area 7124, the fingerprint identification module 20 acquires the fingerprint image after a second response time period, which is greater than the first response time period.

Referring to fig. 2 and 13, in some embodiments, step 0175 may be implemented by processor 300. Both steps 0176 and 0177 can be implemented by the fingerprint identification module 20. That is, the processor 300 may also be used to determine whether the touch location is in the center region 7123. When the touch position is located in the center area 7123, the fingerprint identification module 20 acquires a fingerprint image after the first response time period. When the touch position is located in the non-center area 7124, the fingerprint identification module 20 acquires the fingerprint image after a second response time period, which is greater than the first response time period.

Taking the fingerprint identification area 712 as an example of a full screen fingerprint, the fingerprint identification area 712 is composed of a center area 7123, a non-center area 7124 and a border area 7121 (as shown in fig. 13), and the center area 7123 and the non-center area 7124 constitute a non-border area 7122. A first ratio of the area of the central region 7123 to the area of the fingerprint identification region 712 can range from [ 50%, 80% ], e.g., the first ratio can be 50%, 57%, 60%, 65%, 70.4%, 78%, 80%, etc. The second ratio of the area of the non-central region 7124 to the area of the fingerprint identification region 712 can range from [ 10%, 40% ], for example, the second ratio can be 10%, 15%, 18.8%, 20%, 25%, 30%, 38%, 40%, and so forth.

Specifically, when the operating state of the display device 100 is the lit state and the touched position is located in the non-edge region 7122, or the operating state of the display device 100 is the extinguished state and the touched position is located in the non-edge region 7122, if the touched position is located in the center region 7123 of the non-edge region 7122, the fingerprint identification module 20 acquires a fingerprint image after the first response time period. The value of the first response time period may be 0 or a value greater than 0. When the value of the first response time period is 0, the processor 300 controls the fingerprint identification module 20 to acquire the fingerprint image immediately after determining that the operating state of the display device 100 is the on state and the touch position is located in the center area 7123 of the non-edge area 7122, or the operating state of the display device 100 is the off state and the touch position is located in the center area 7123 of the non-edge area 7122. When the value of the first response time period is greater than 0, the processor 300 controls the fingerprint identification module 20 to acquire the fingerprint image after the processor 300 waits for the first response time period after the operating state of the display device 100 is the on state and the touch position is located in the center area 7123 of the non-edge area 7122, or the operating state of the display device 100 is the off state and the touch position is located in the center area 7123 of the non-edge area 7122. In the first response time period, the processor 300 further obtains at least one parameter again, and further determines whether to trigger the fingerprint identification module 20 to obtain the fingerprint image according to the at least one parameter. For example, the processor 300 controls the gravity sensor to obtain an acceleration value of the electronic device 1000, and determines the usage posture of the electronic device 1000 according to the acceleration value. The processor 300 determines whether the usage posture of the electronic device 1000 satisfies a predetermined condition, and immediately triggers the fingerprint identification module 20 to acquire the fingerprint image when the usage posture satisfies the predetermined condition. If the usage gesture does not satisfy the predetermined condition, the fingerprint identification module 20 does not acquire the fingerprint image.

When the operating state of the display device 100 is the lit state and the touched position is in the non-edge region 7122, or the operating state of the display device 100 is the extinguished state and the touched position is in the non-edge region 7122, if the touched position is in the non-center region 7124, the fingerprint identification module 20 acquires the fingerprint image after the second response time period. The value of the second response time period is not 0, and the second response time period is greater than the first response time period. During the second response time period, the processor 300 may further acquire at least two parameters (i.e. the number of parameters that the processor 300 needs to acquire during the second response time period is greater than the number of parameters that the processor 300 needs to acquire during the first response time period), and further determine whether to trigger the fingerprint recognition module 20 to acquire the fingerprint image according to the at least two parameters. For example, the processor 300 controls the gravity sensor to obtain an acceleration value of the electronic device 1000, determines a usage posture of the electronic device 1000 according to the acceleration value, and controls the distance detection device 400 to obtain a current distance between the electronic device 1000 and the target object by the processor 300. Subsequently, the processor 300 determines whether the usage posture of the electronic device 1000 satisfies the predetermined condition and the current distance is greater than the preset distance, and when the usage posture satisfies the predetermined condition and the current distance is greater than the preset distance, the processor 300 immediately triggers the fingerprint identification module 20 to acquire the fingerprint image. If the usage posture does not satisfy the predetermined condition, or the current distance is less than the preset distance, the processor 300 does not control the fingerprint recognition module 20 to acquire the fingerprint image.

It is understood that when a user touches the fingerprint identification area 712 for fingerprint identification, the user's finger will generally touch the center area 7123 and less frequently touch the non-center area 7124. Therefore, different response times are set for the central region 7123 and the non-central region 7124, and the central region 7123 has a higher response speed than the non-central region 7124, so that the response speed can be ensured on one hand, the occurrence of false triggering can be avoided as much as possible, and the user experience is better.

The shape of the central region 7123 is not limited to the rectangular shape in fig. 13, but may be a rounded rectangle, square, trapezoid, triangle, circle, ellipse, polygon, irregular figure (e.g., heart), etc., without limitation.

Referring to fig. 14, 19 and 20, in some embodiments, the display device 100 includes a first substrate 12, a photosensitive layer 31, a liquid crystal layer 14, a second substrate 15 and a plurality of collimating units 321 stacked in sequence. The photosensitive layer 31 includes a plurality of photosensitive cells 311. The second substrate 15 has a plurality of display units 151 and a light blocking member 152 between the display units 151. The light shielding member 152 is provided with a light passing hole 1521. The collimating unit 321 has a light hole 3211, and the light hole 3211 and the light passing hole 1521 are aligned with the light sensing unit 311.

Fingerprint identification module 20 acquires the fingerprint image of finger and includes:

024: receiving an imaging optical signal including a target optical signal to form an imaging electrical signal, wherein the target optical signal sequentially passes through the light through hole 3211 and the light through hole 1521 and then reaches the photosensitive layer 31;

025: acquiring a noise signal within the display device 100; and

026: and acquiring a fingerprint image according to the imaging electric signal and the noise signal.

Referring to fig. 2, 19, and 22, in some embodiments, step 024 may be performed by the photosensitive layer 31. Step 025 may be implemented by the noise acquisition circuit 301. Step 026 may be implemented by processor 300. That is, the photosensitive layer 31 can be used to receive an imaging optical signal including a target optical signal to form an imaging electrical signal, wherein the target optical signal passes through the light passing hole 3211 and the light passing hole 1521 in sequence and then reaches the photosensitive layer 31. The noise acquisition circuit 301 may be used to acquire a noise signal within the display device 100. The processor 300 may be configured to acquire a fingerprint image from the imaging electrical signal and the noise signal.

In this embodiment, display device 100 includes display module assembly 10 and fingerprint identification module 20, and wherein, fingerprint identification module 20 is the optics fingerprint module, and the optics fingerprint module includes photosensitive layer 31 and collimation layer 32. The display device 100 includes a first substrate 12, a photosensitive layer 31, a liquid crystal layer 14, a second substrate 15, and a collimating layer 32, which are sequentially stacked. The photosensitive layer 31 includes a plurality of photosensitive cells 311, and the alignment layer 32 includes a plurality of alignment cells 321. Referring to fig. 24, a plurality of display units 151 and a light-shielding member 152 located between the display units 151 are formed on the second substrate 15. The light shielding member 152 is provided with a light passing hole 1521. The collimating unit 321 has a light hole 3211, and the light hole 3211 and the light passing hole 1521 are aligned with the light sensing unit 311. The light sensing unit 311 may receive a target light signal entering from the outside and sequentially passing through the light passing hole 3211 and the light passing hole 1521, where the target light signal is a signal reflected by a finger of a user, and may obtain a fingerprint image of the finger touching the display device 100 according to the target light signal, where the fingerprint image may be used for fingerprint identification.

The plurality of photosensitive cells 311 in the photosensitive layer 31 generate an imaging electrical signal upon receiving an imaging optical signal including a target optical signal. However, the imaging optical signal includes an interference optical signal, an infrared optical signal, and the like in addition to the target optical signal, and the light sensing unit 311 also generates a noise signal when operating, and therefore, the imaging electrical signal includes at least one of an interference electrical signal generated by the interference optical signal, an infrared electrical signal generated by the infrared optical signal, a noise electrical signal generated by the light sensing unit 311, and a circuit noise signal generated by the light sensing unit 311 in addition to the target electrical signal generated by the target optical signal. For example, the imaging electrical signal includes both a target electrical signal and an interfering electrical signal; or the imaging electric signal comprises a target electric signal, an infrared electric signal and a noise electric signal; or the imaging electric signal comprises a target electric signal, an infrared electric signal, a noise electric signal and a circuit noise signal; alternatively, the imaging electric signal includes a target electric signal, an interference electric signal, an infrared electric signal, a noise electric signal, a circuit noise signal, and the like.

The electrical signal generated by the noise signal in the imaging electrical signal may affect the accuracy of the acquired fingerprint image, and further may affect the accuracy of fingerprint identification. Therefore, the control method according to the embodiment of the present application acquires the noise signal by setting the noise acquisition circuit 301, and after the photosensitive layer 31 acquires the imaging electrical signal, removes the electrical signal formed by the noise signal in the imaging electrical signal except the target electrical signal, thereby avoiding the electrical signal formed by the noise signal from interfering with the target electrical signal, making the fingerprint image acquired by the fingerprint identification module 20 more accurate, performing fingerprint identification based on the more accurate fingerprint image, and also improving the accuracy and security of the fingerprint identification.

Referring to fig. 2 and 15, in some embodiments, the noise signal includes an interference electrical signal formed by an interference optical signal. The step 025 of acquiring the noise signal in the display device 100 includes: 0251: an interfering electrical signal is acquired. The step 026 of obtaining the fingerprint image according to the electrical imaging signal and the noise signal includes: 0261: and acquiring a fingerprint image according to the imaging electric signal and the interference electric signal.

Referring to fig. 2 and 22, in some embodiments, the noise obtaining circuit 301 includes a parasitic light sensing unit 3111. Step 0251 can be implemented by the veiling photosensitive unit 3111. Step 0261 can be implemented by processor 300. That is, the veiling glare photosensitive unit 3111 may be used to acquire an interference electric signal. The processor 300 may be configured to acquire a fingerprint image from the imaging electrical signal and the interfering electrical signal.

Specifically, the veiling glare sensing unit 3111 transmits an interference electrical signal generated by the interference optical signal to the processor 300, and the processor 300 corrects the fingerprint image according to the interference electrical signal during imaging, for example, the interference electrical signal is subtracted from an imaging electrical signal generated by the imaging optical signal to obtain a target electrical signal finally used for imaging, so as to obtain a fingerprint image with higher accuracy and improve the accuracy of fingerprint identification.

Referring to fig. 2 and 16, in some embodiments, the noise signal includes a noise electrical signal generated by the light sensing unit 311 itself. The step 25 of acquiring the noise signal in the display device 100 includes: 0252: a noisy electrical signal is acquired. The step 026 of obtaining the fingerprint image according to the electrical imaging signal and the noise signal includes: 0262: and acquiring a fingerprint image according to the imaging electric signal and the noise electric signal.

Referring to fig. 2 and 22, in some embodiments, the noise obtaining circuit 301 includes a noise sensing unit 3112. Step 0252 can be implemented by the noise photosensitive unit 3112. Step 0262 can be implemented by processor 300. That is, the noise sensing unit 3112 may be used to acquire a noise electric signal. The processor 300 may be configured to acquire a fingerprint image from the imaging electrical signal and the noise electrical signal.

Specifically, the noise sensing unit 3112 transmits the noise electrical signal generated by the sensing unit 31 to the processor 300, and the processor 300 corrects the fingerprint image according to the noise electrical signal during imaging, for example, the noise electrical signal is subtracted from the imaging electrical signal generated by the imaging optical signal to obtain a target electrical signal finally used for imaging, so as to obtain a fingerprint image with higher accuracy and improve the accuracy of fingerprint identification.

Referring to fig. 2 and 17, in some embodiments, the noise signal includes a circuit noise signal generated by the light sensing unit 311. The step 025 of acquiring the noise signal in the display device 100 includes: 0253: a circuit noise signal is acquired. The step 026 of obtaining the fingerprint image according to the electrical imaging signal and the noise signal includes: 0263: and acquiring a fingerprint image according to the imaging electric signal and the circuit noise signal.

Referring to fig. 2 and 22, in some embodiments, the noise obtaining circuit includes a 301 noise circuit unit 3122. Step 0253 can be implemented by noise circuit unit 3122. Step 0263 may be implemented by processor 300. That is, the noise circuit unit 3122 may be used to acquire a circuit noise signal. The processor 300 may be configured to acquire a fingerprint image from the imaging electrical signal and the circuit noise signal.

Specifically, the noise circuit unit 3122 transmits the circuit noise signal generated by the photosensitive unit 311 to the processor 300, and the processor 300 corrects the fingerprint image according to the circuit noise signal during imaging, for example, the circuit noise signal is subtracted from the imaging electrical signal generated by the imaging optical signal to obtain a target electrical signal finally used for imaging, so as to obtain a fingerprint image with higher accuracy and improve the accuracy of fingerprint identification.

Referring to fig. 2 and 18, in some embodiments, the noise signal includes an infrared signal formed by an infrared signal. The step 025 of acquiring the noise signal in the display device 100 includes: 0254: and acquiring an infrared electric signal. The step 026 of obtaining the fingerprint image according to the electrical imaging signal and the infrared electrical signal includes: 0264: and acquiring a fingerprint image according to the imaging electric signal and the infrared electric signal.

Referring to fig. 2 and 22, in some embodiments, the noise acquisition circuit 301 includes an infrared sensor unit 3113. Step 0254 can be implemented by the infrared photosensitive unit 3113. Step 0264 may be implemented by processor 300. That is, the infrared photosensitive unit 3113 may be used to acquire an infrared electric signal. The processor 300 can be used to acquire a fingerprint image according to the imaging electrical signal and the infrared electrical signal.

Specifically, the infrared sensing unit 3113 transmits an infrared electrical signal of the infrared optical signal to the processor 300, and the processor 300 corrects the fingerprint image according to the infrared electrical signal during imaging, for example, the infrared electrical signal is subtracted from an imaging electrical signal generated by the imaging optical signal to obtain a target electrical signal finally used for imaging, so as to obtain a fingerprint image with higher accuracy and improve the accuracy of fingerprint identification.

Referring to fig. 2 and 10, the electronic device 1000 according to the embodiment of the present disclosure further includes a housing 200. The chassis 200 includes a front case 210 and a rear case 220. The chassis 200 may be used to mount the display device 100, or the chassis 200 may be used as a mounting carrier of the display device 100, and the chassis 200 may also be used to mount functional modules of the electronic apparatus 1000, such as a power supply device, an imaging device, and a communication device, so that the chassis 200 provides protection for the functional modules against falling, water, and the like. The display device 100 can be used for displaying images such as pictures, videos, and texts. The display device 100 is mounted on the chassis 200, and specifically, the display device 100 may be mounted on the front case 210, or the display device 100 is mounted on the rear case 220, or the display device 100 is mounted on both the front case 210 and the rear case 220, or the display device 100 is mounted on a side surface of the chassis 200, which is not limited herein. In the example shown in fig. 2, the display device 100 is mounted on the front case 210.

Referring to fig. 2 and 19-21, in one example, the fingerprint recognition module 20 is an optical fingerprint module, and the optical fingerprint module includes a photosensitive layer 31 and a collimating layer 32. The optical fingerprint module is integrated in the display device 100. The display module 10 includes a backlight layer 11, a first polarizing layer 12, a first substrate 13, a liquid crystal layer 14, a second substrate 15, and a second polarizing layer 16. Along the light emitting direction of the display device 100, the display device 100 includes a backlight layer 11, a first polarizing layer 12, a first substrate 13, a photosensitive layer 31, a liquid crystal layer 14, a second substrate 15, a collimating layer 32, a second polarizing layer 16, and a cover plate 70 in this order. The touch module 60 integrated in the display device 100 may be disposed between the cover plate 70 and the second polarizing layer 16. The lines in the touch module 60 can be made of transparent metal materials such as nano silver paste, so as to avoid the influence on the optical fingerprint module to acquire the received light and the emitted light of the display module 10.

As shown in fig. 19 and 20, the backlight layer 11 may be used for emitting an optical signal La, or the backlight layer 11 may be used for guiding the optical signal La emitted by a light source (not shown). The optical signal La sequentially passes through the first polarizing layer 12, the first substrate 13, the photosensitive layer 31, the liquid crystal layer 14, the second substrate 15, the collimating layer 32, the second polarizing layer 16, the touch module 60, and the cover plate 70, and then enters the outside. The backlight layer 11 includes a bottom surface 101, and in particular, the bottom surface 101 may be a surface of the backlight layer 11 opposite to the first polarizing layer 12. The first polarizing layer 12 is disposed on the backlight layer 11, and the first polarizing layer 12 may be a polarizing plate or a polarizing film, in particular. The first substrate 13 is disposed on the first polarizing layer 12, and the first substrate 13 may be a glass substrate.

The photosensitive layer 31 may be a Film layer formed on the first substrate 13, for example, formed on the first substrate 13 by a tft (thin Film transistor) process. Referring to fig. 21 to 23, the photosensitive layer 31 includes a plurality of photosensitive units 311 and a plurality of circuit units 312.

The light sensing unit 311 may convert the received optical signal into an electrical signal by using a photoelectric effect, and the intensity of the electrical signal generated by the light sensing unit 311 may reflect the intensity of the optical signal received by the light sensing unit 311 by analyzing the intensity of the electrical signal. The light sensing unit 311 may receive a visible light signal and/or an invisible light signal to convert into an electrical signal. The types of the plurality of photosensitive units 311 may be identical or not identical. The plurality of light sensing units 311 may be arranged in any manner, and the arrangement manner may be specifically set according to the requirements of the display device 100, such as the external shape, in the embodiment of the present application, the plurality of light sensing units 311 are arranged in an array, for example, the plurality of light sensing units 311 are arranged in a matrix with a plurality of rows and a plurality of columns. Each photosensitive unit 311 can operate independently without being affected by other photosensitive units 311, and the intensity of the optical signal received by the photosensitive units 311 at different positions may be different, so the intensity of the electrical signal generated by the photosensitive units 311 at different positions may also be different. In addition, a side of the photosensitive unit 311 facing the bottom surface 101 may be provided with a reflective material, and a light signal irradiated from the backlight layer 11 to the photosensitive unit 311 may be reflected by the reflective material, so as to prevent the light signal from affecting the accuracy of imaging performed by the photosensitive layer 31.

The circuit unit 312 may be connected to the light sensing unit 311. The circuit unit 312 can transmit the electrical signal generated by the photosensitive unit 311 to the processor 300, where the processor 300 is multiple, and one of the processors 300 is the imaging chip 300. The circuit unit 312 may specifically include a transistor and the like. The number of the circuit units 312 may be plural, each of the light sensing units 311 may be connected to a corresponding one of the circuit units 312, and the plural circuit units 312 are connected to the imaging chip 300 through connection lines. The arrangement of the plurality of circuit units 312 may be similar to the arrangement of the light-sensing units 311, for example, the plurality of light-sensing units 311 may be arranged in a matrix of rows and columns, and the plurality of circuit units 312 may also be arranged in a matrix of rows and columns.

Referring to fig. 19 to 21, the liquid crystal layer 14 is disposed on the photosensitive layer 31, and liquid crystal molecules in the liquid crystal layer 14 can change a deflection direction under the action of an electric field, so as to change an amount of an optical signal passing through the liquid crystal layer 14. Accordingly, referring to fig. 23, a display driving layer 1a may be further formed on the first substrate 13, and the display driving layer 1a may apply an electric field to the liquid crystal layer 14 under the driving action of a driving chip (not shown) to control the deflection directions of the liquid crystal molecules at different positions. Specifically, the display driving layer 1a includes a plurality of display driving units 1a1, and each display driving unit 1a1 can independently control the deflection direction of the liquid crystal at the corresponding position.

Referring to fig. 19, 21 and 24, the second substrate 15 is disposed on the liquid crystal layer 14. The second substrate 15 may include a glass substrate, and a plurality of display units 151 and a light blocking member 152 disposed on the glass substrate. The display unit 151 may be a color filter, for example, R represents an infrared filter, G represents a green filter, and B represents a blue filter, to control the color finally displayed by the display device 100 by controlling the amount of light signals passing through the filters of different colors. The arrangement of the plurality of display units 151 may correspond to the arrangement of the plurality of display driving units 1a1, for example, one display unit 151 is aligned with one display driving unit 1a 1. The light-shielding member 152 is positioned between the display units 151, and the light-shielding member 152 spaces adjacent two display units 151, and in one example, the light-shielding member 152 may be a Black Matrix (BM). The light-shielding member 152 can prevent light from passing through the solid portion thereof to prevent light in the display device 100 from entering the outside without passing through the display unit 151, and the light-shielding member 152 can also prevent light crosstalk when light signals pass through the adjacent display unit 151.

Referring to fig. 20, the light shielding member 152 is provided with a light passing hole 1521, and the light passing hole 1521 is used for passing an optical signal. The position of the light passing hole 1521 is aligned with the photosensitive unit 311, wherein the alignment may mean that the center line of the light passing hole 1521 passes through the photosensitive unit 311. In the process of the optical signal passing through the light hole 1521, if the optical signal reaches the inner wall of the light hole 1521, the optical signal is partially or completely absorbed by the inner wall of the light hole 1521, so that the propagation direction of the optical signal passing through the light hole 1521 almost coincides with the extension direction of the center line of the light hole 1521. The light passing holes 1521 may be distributed in the same manner as the light sensing units 311, such that each light sensing unit 311 is aligned with one light passing hole 1521.

Referring to fig. 19 to 21, the alignment layer 32 is disposed on the second substrate 15. The collimating layer 32 includes a plurality of collimating units 321, the collimating units 321 are provided with light holes 3211, and the light holes 3211 are aligned with the light sensing units 311. Specifically, the light passing hole 3211 may also be aligned with the light passing hole 1521, that is, a center line of the light passing hole 3211 may coincide with a center line of the light passing hole 1521, and the light signal passes through the light passing hole 3211 and then passes through the light passing hole 1521 to reach the light sensing unit 311. The collimating unit 321 may be made of the same material as the light shielding member 152, for example, the collimating unit 321 and the light shielding member 152 are made of light absorbing material, and when the light signal reaches the solid portion of the collimating unit 321, the light signal is partially or completely absorbed, for example, when the light signal reaches the sidewall of the collimating unit 321 or the inner wall of the light through hole 3211, the light signal is absorbed by the collimating unit 321, so that the light signal whose propagation direction coincides with the extending direction of the central line of the light through hole 3211 can pass through the light through hole 3211 and reach the light sensing unit 311, thereby achieving collimation of the light signal, and the light sensing unit 311 receives less interference light signals. The orthographic projections of the plurality of collimating units 321 on the second substrate 15 can be located in the light shielding member 152, so that the collimating units 321 do not shield the display unit 151, and the display device 100 is ensured to have a better display effect. The extending direction of the light hole 3211 may be perpendicular to the display surface 71, so that the light hole 3211 can only pass the light signal that propagates perpendicularly to the display surface 71, or the light hole 3211 can only pass the light signal that propagates perpendicularly downward from the display surface 71. The ratio of the cross-sectional width of the light passing hole 3211 to the depth of the light passing hole 3211 is less than 0.2, wherein the depth of the light passing hole 3211 may be the depth of the light passing hole 3211 along the centerline direction, and the cross-sectional width of the light passing hole 3211 may be the maximum cross-sectional dimension of a figure cut by a plane perpendicular to the centerline of the light passing hole 3211, and the ratio may be specifically 0.1, 0.111, 0.125, 0.19, 0.2, or the like, so that the collimating effect of the collimating unit 321 on the optical signal is better. In one example, the collimating layer 32 further includes a substrate 322, the substrate 322 may be substantially light transmissive, and the collimating elements 321 are formed on the substrate 322. In another example, the alignment layer 32 may include only the alignment unit 321, and the alignment unit 321 may be formed on the second substrate 15 by plating, sputtering, or the like.

The second polarizing layer 16 is disposed on the collimating layer 32, and the second polarizing layer 16 may be specifically a polarizing plate or a polarizing film.

With continued reference to fig. 19 and 20, the cover plate 70 is disposed on the second polarizing layer 16. The cover plate 70 may be made of glass, sapphire, or the like. The cover 70 includes a display surface 71 and a cover back surface 73. The optical signal emitted from the display device 100 passes through the display surface 71 and enters the outside, and the external light passes through the display surface 71 and enters the display device 100. The cover back surface 73 may be attached to the second polarizing layer 16. In some examples, the display device 100 may not include the cover plate 70, and the display surface 71 is formed on the second polarizing layer 16.

The display area 711 is formed on the display surface 71, the display area 711 indicates an area that can be used to display an image, and the display area 711 may have a shape such as a rectangle, a circle, a rectangle with rounded corners, or a rectangle with "bang", and is not limited herein. In addition, in some examples, the display surface 71 may also be formed with a non-display area, the non-display area may be formed at a peripheral position of the display area 711, and the non-display area may be used for connecting with the chassis 200. The ratio of the display area 711 on the display surface 71 may be any numerical value such as 80%, 90%, 100%, or the like.

In the embodiment of the present application, the orthographic projection of the plurality of photosensitive units 311 on the display surface 71 is located within the display area 711. So that the plurality of light sensing units 311 can image an object touched within the display area 711, for an example in which a user touches the display area 711 with a finger, the plurality of light sensing units 311 can image a fingerprint of the finger touched on the display area 711 and use it for fingerprint recognition.

Referring to fig. 19 and 20, the following describes the imaging performed by the display device 100 by way of example: an optical signal La emitted by the display device 100 sequentially passes through the first polarizing layer 12, the first substrate 13, the photosensitive layer 31, the liquid crystal layer 14, the second substrate 15, the collimating layer 32, the second polarizing layer 16, the touch module 60, and the cover plate 70 and then enters the outside, and an external optical signal may also sequentially pass through the cover plate 70, the touch module 60, the second polarizing layer 16, the collimating layer 32, the second substrate 15, and the liquid crystal layer 14 and then reach the photosensitive layer 31. If the light signal just reaches the photosensitive cells 311 in the photosensitive layer 31, the photosensitive cells 311 generate an electrical signal to reflect the intensity of the light signal. Thereby, the intensity distribution of the optical signal entering the display device 100 can be reflected by the intensity of the electrical signal of the plurality of light receiving units 311.

Take the example where the user touches the display surface 71 with a finger. When the display device 100 is emitting the optical signal La, a finger touches a predetermined position of the display surface 71, the finger reflects the optical signal La to form L1, the optical signal L1 then starts to enter the display device 100, the optical signal L1 first passes through the cover plate 70, the touch module 60 and the second polarizing layer 16, for the optical signal L1 whose propagation direction is the same as the extending direction of the light through hole 3211 and the light through hole 1521, the optical signal L1 can also pass through the light through hole 3211 and the light through hole 1521, and after the optical signal L1 passes through the light through hole 3211 and the light through hole 1521, the optical signal L1 passes through the liquid crystal layer 14 and then reaches the light sensing unit 311. For the optical signals with the propagation direction different from the extending direction of the light passing hole 3211 or the light passing hole 1521, after the optical signals pass through the cover plate 70, the touch module 60 and the second polarizer layer 16, the optical signals cannot pass through the light passing hole 3211 or the light passing hole 1521, and further cannot reach the light sensing unit 311 aligned with the light passing hole 3211 and the light passing hole 1521.

It can be understood that the fingerprint of the finger has a peak and a valley, when the finger 2000 touches the display surface 71, the peak directly contacts the display surface 71, a gap exists between the valley and the display surface 71, and after the optical signal La reaches the peak and the valley, the intensity of the optical signal reflected by the peak (hereinafter referred to as a first optical signal) and the intensity of the optical signal reflected by the valley (hereinafter referred to as a second optical signal) are different, so that the intensity of the electrical signal generated by receiving the first optical signal (hereinafter referred to as a first electrical signal) and the intensity of the electrical signal generated by receiving the second optical signal (hereinafter referred to as a second electrical signal) are different, and the imaging chip 300 can acquire the fingerprint image according to the distribution of the first electrical signal and the second electrical signal. The fingerprint image may further be used for fingerprint identification. The user touches the fingerprint recognition area 712, which is optionally provided with the photosensitive unit 311, to image and recognize the fingerprint.

Referring to fig. 22 and 25, in some embodiments, the photosensitive unit 311 includes a veiling glare photosensitive unit 3111. The cover plate back 73 of the cover plate 70 is provided with an ink layer 82, the stray light sensing unit 3111 corresponds to the ink layer 82, and the ink layer 82 is used for blocking the optical signal Lb penetrating into the cover plate 70 from the outside. In actual use, part of the light signal emitted from the backlight layer 11 directly passes through the display surface 71, and part of the light signal may be reflected between the display surface 71 and the backlight layer 11 one or more times, and part of the reflected light signal L2 may reach the light-sensing unit 311 and cause interference in imaging of the display device 100. That is, among the imaging light signals for imaging, there is also included a disturbing light signal L2, the disturbing light signal L2 being reflected by the display device 100 and reaching the photosensitive cells 311 on the photosensitive layer 31.

The ink layer 82 is provided on the cover back surface 73 at a position corresponding to the stray light receiving unit 3111, and after reaching the ink layer 82, most of the light in the display device 100 is absorbed by the ink layer 82, and a small portion (for example, 4%) of the light is reflected by the ink layer 82, so that the reflection action of the cover 70 on the light signal inside the display device 100 can be simulated by the ink layer 82, and the stray light receiving unit 3111 may receive the disturbance light signal L2 reaching the stray light receiving unit 3111 from the side of the stray light receiving unit 3111. In summary, the veiling glare sensor 3111 can receive the same interference light signal L2 as the rest of the light sensors 311, and at the same time, the ink layer 82 can block (reflect or absorb) the light signal Lb penetrating into the cover 70 from the outside, so that the veiling glare sensor 3111 only receives the interference light signal L2, and the rest of the light sensors 311 can simultaneously receive the interference light signal L2 and the light signal Lb penetrating into the cover 70 from the outside. The type and performance of the veiling glare photosensitive unit 3111 are the same as those of the rest of the photosensitive units 311, the veiling glare photosensitive unit 3111 transmits the interference electrical signal generated by the interference optical signal L2 to the imaging chip 300, and the imaging chip 300 corrects the image according to the interference electrical signal during imaging, for example, the imaging electrical signal generated by the imaging optical signal is subtracted from the interference electrical signal to be used as a target electrical signal finally for imaging, so as to obtain an image with higher accuracy and improve the accuracy of image recognition.

In one example, the ink layer 82 is disposed on the back surface 73 of the cover plate near the edge, and the veiling glare photosensitive unit 3111 is disposed on the edge of the photosensitive layer 31. For example, as shown in fig. 22, the stray light sensing unit 3111 is disposed in the area a, where the area a is located in the leftmost column and the rightmost column of the array of sensing units 311 in fig. 22. The ink layer 82 is prevented from greatly affecting the display effect of the display device 100. Specifically, the photosensitive units 311 may be arranged in a matrix with multiple rows and multiple columns, and the veiling glare photosensitive units 3111 may be disposed at an edge of the matrix, for example, one to three columns near the edge of the matrix, and one to three rows near the edge of the matrix, so as to adapt to the position of the ink layer 82.

Further, since there are a plurality of stray light receiving units 3111, a plurality of interference electrical signals may be generated accordingly, and the magnitude of the plurality of interference electrical signals may not be consistent, when subtracting the interference electrical signal from the imaging electrical signal, in one example, the plurality of interference electrical signals may be averaged, and then the averaged interference electrical signal may be subtracted from the imaging electrical signal. In another example, the photosensitive unit 311 and the veiling glare photosensitive unit 3111 may be partitioned, respectively, and each of the regions includes at least one photosensitive unit 311 or at least one veiling glare photosensitive unit 3111. Subsequently, the second region closest to each first region may be determined according to the position of each region (hereinafter, referred to as a first region) including the photosensitive unit 311 and the position of each region (hereinafter, referred to as a second region) including the veiling glare photosensitive unit 3111. For each photo-sensing unit 311 in each first region, the imaging electrical signal generated by each photo-sensing unit 311 may be subtracted by the interference electrical signal generated by the parasitic photo-sensing unit 3111 in the second region closest to the first region to obtain the electrical signal finally used for imaging by each photo-sensing unit 311, and if there are a plurality of parasitic photo-sensing units 3111 in the second region, the plurality of interference electrical signals generated by the plurality of parasitic photo-sensing units 3111 in the second region may be averaged, and then the average value is subtracted from the imaging electrical signal to obtain the electrical signal finally used for imaging. It can be understood that the closer the stray light sensing unit 3111 is to the light sensing unit 311, the closer the amount of the interference light signals received by the stray light sensing unit 3111 and the light sensing unit 311 is, the closer the generated interference electrical signals are, and the more accurate the electrical signals for imaging finally obtained after subtracting the interference electrical signals from the imaging electrical signals.

Referring to fig. 22 and 26, in some embodiments, the photosensitive unit 311 includes a noise photosensitive unit 3112, the display device 100 further includes a light shielding unit 323, the light shielding unit 323 is disposed on the collimating unit 321, and the light shielding unit 323 is used for shielding the light passing hole 3211 aligned with the noise photosensitive unit 3112. In use, the temperature of the photosensitive unit 311 or the temperature of the environment may change, and the performance of the photosensitive unit 311 may change according to the temperature change, for example, the photosensitive unit 311 may be made of an amorphous silicon (a-Si) material, and the background noise generated by the photosensitive unit 311 may also change when the temperature changes. Therefore, at the time of imaging, it is necessary to correct the disturbance caused by the temperature change.

In this embodiment, the type and performance of the noise-sensitive unit 3112 are the same as those of the rest of the light-sensitive units 311, and the light-blocking unit 323 blocks the light-transmitting hole 3211, so that the noise-sensitive unit 3112 can hardly receive the light signal. Although the noise-sensitive unit 3112 generates an electrical signal during use, the noise-sensitive unit 3112 hardly receives an optical signal, and thus the electrical signal generated by the noise-sensitive unit 3112 can be regarded as a noise electrical signal generated by a material and a temperature change. At this time, the rest of the photosensitive units 311 can simultaneously generate the noise electrical signal and receive the imaging optical signal to generate the imaging electrical signal. The noise sensing unit 3112 transmits the noise electrical signal to the imaging chip 300, and the imaging chip 300 corrects the image according to the noise electrical signal during imaging, for example, the imaging electrical signal generated by the imaging optical signal is subtracted by the noise electrical signal to be used as the electrical signal finally used for imaging, so as to obtain an image with higher accuracy and improve the accuracy of image recognition.

Specifically, the light shielding unit 323 may also be made of a light absorbing material, the light shielding unit 323 may be filled in the light passing hole 3211, and the light shielding unit 323 and the collimating unit 321 may be manufactured together. In one example, the light shielding unit 323 may also be directly disposed on the noise photosensitive unit 3112 so that the noise photosensitive unit 3112 does not receive the light signal at all. The noise photosensitive unit 3112 may be disposed in a region near an edge of the array of photosensitive units 311, the noise photosensitive unit 3112 may also be disposed in a region adjacent to the stray light photosensitive unit 3111, for example, may be located in one to three columns in the matrix, or may be located in one to three rows in the matrix, without limitation, and the noise photosensitive unit 3112 is disposed in a region b shown in fig. 22, where the region b is located in a second column from the left and a second column from the right of the array of photosensitive units 311 in fig. 22.

Further, since there are a plurality of noise sensing units 3112, a plurality of noise electrical signals may be generated accordingly, and the magnitude of the plurality of noise electrical signals may not be consistent, when subtracting the noise electrical signal from the imaging electrical signal, in one example, the plurality of noise electrical signals may be averaged, and then the averaged noise electrical signal may be subtracted from the imaging electrical signal. In another example, the light sensing unit 311 and the noise sensing unit 3112 may be partitioned, respectively, and each region includes at least one light sensing unit 311 or at least one noise sensing unit 3112. Subsequently, a third region closest to each first region may be determined according to the position of each region (hereinafter referred to as a first region) including the photosensitive unit 311 and the position of each region (hereinafter referred to as a third region) including the noise photosensitive unit 3112. For each of the light-sensing units 311 in each first region, the imaging electrical signal generated by each light-sensing unit 311 may be subtracted by the noise electrical signal generated by the noise light-sensing unit 3112 in the third region closest to the first region to obtain the electrical signal finally used for imaging by each light-sensing unit 311, and if there are a plurality of noise light-sensing units 3112 in the third region, the average value of the noise electrical signals generated by the noise light-sensing units 3112 in the third region may be taken first, and then the average value of the imaging electrical signal may be subtracted to obtain the electrical signal finally used for imaging. It can be understood that the closer the noise-sensitive unit 3112 is to the light-sensitive unit 311, the closer the temperature of the noise-sensitive unit 3112 is to the light-sensitive unit 311, the more similar the generated noise electrical signal is, and the more accurate the electrical signal for imaging finally obtained after subtracting the noise electrical signal from the imaging electrical signal.

Referring to fig. 22, in some embodiments, the circuit unit 312 includes a light sensing circuit unit 3121 and a noise circuit unit 3122, the light sensing circuit unit 3121 is connected to the light sensing unit 311, and the noise circuit unit 3122 is not connected to the light sensing unit 311. The light sensing circuit itself has hardware noise that causes a circuit noise signal that affects the intensity of the electric signal that is finally transmitted to the imaging chip 300, and therefore, when imaging is performed, it is necessary to correct the interference caused by the circuit noise signal. In the present embodiment, the photosensitive unit 311 is not connected to the noise circuit unit 3122, and circuit noise signals generated in the noise circuit unit 3122 are all due to hardware noise of the noise circuit unit 3122 itself. The noise circuit unit 3122 transmits the circuit noise signal to the imaging chip 300, and the imaging chip 300 corrects the image according to the circuit noise signal during imaging, for example, an electrical signal for final imaging is obtained by subtracting the circuit noise signal from an imaging electrical signal generated by the imaging optical signal, so as to obtain an image with higher accuracy and improve the accuracy of image recognition.

Specifically, the plurality of circuit units 312 may be arranged in an array of a plurality of rows and a plurality of columns, and the noise circuit units 3122 are arranged at least in a complete row and a complete column, so that the noise circuit units 3122 are distributed in any row and any column, samples of circuit noise signals generated by the noise circuit units 3122 are more comprehensive, and when an image is corrected according to the circuit noise signals, the correction effect is better. The noise circuit unit 3122 may be disposed at an edge position of an array in which the plurality of circuit units 312 are arranged, or may be disposed near the stray light receiving unit 3111 and the noise receiving unit 3112. The distribution range of the noise circuit unit 3122 may cover a complete row to five rows and a complete row to five rows, which is not limited herein. In the example shown in fig. 22, the noise circuit unit 3122 is disposed in the c region of the photosensitive layer 31, wherein the c region is located on the third left column, the third right column, the uppermost row and the lowermost row of the circuit unit 312 array in fig. 22.

Further, since there are a plurality of noise circuit units 3122, a plurality of circuit noise signals may be generated accordingly, and the sizes of the plurality of circuit noise signals may be different, when subtracting the circuit noise signal from the imaging electrical signal, in one example, the plurality of circuit noise signals may be averaged, and then the averaged circuit noise signal may be subtracted from the imaging electrical signal. In another example, the light sensing unit 311 and the noise circuit unit 3122 may be partitioned, respectively, each area including at least one light sensing unit 311 or at least one noise circuit unit 3122. Subsequently, a fourth region closest to each first region may be determined according to the position of each region (hereinafter, referred to as a first region) including the light sensing unit 311 and the position of each region (hereinafter, referred to as a fourth region) including the noise circuit unit 3122. For each photosensitive unit 311 in each first region, the electrical signal generated by the noise circuit unit 3122 in the fourth region closest to the first region may be subtracted from the electrical signal generated by each photosensitive unit 311 to obtain the electrical signal finally used for imaging by each photosensitive unit 311, and if there are a plurality of noise circuit units 3122 in the fourth region, the electrical signal finally used for imaging may be obtained by averaging the plurality of electrical circuit noise signals generated by the plurality of noise circuit units 3122 in the fourth region and then subtracting the average value from the electrical signal generated for imaging.

Referring to fig. 22, in some embodiments, the photosensitive unit 311 further includes a plurality of infrared photosensitive units 3113, and the infrared photosensitive units 3113 are used for detecting infrared light. Due to the presence of infrared light in the external environment, the infrared light may penetrate through some objects into the display device 100. For example, infrared light may penetrate through the user's finger, pass through the display surface 71, the light-passing hole 3211 and the light-passing hole 1521, and be received by the light-sensing unit 311, and the portion of the infrared light is not associated with the user's fingerprint, and an infrared signal generated by the portion of the infrared light (infrared light signal) may interfere with the imaging of the imaging chip 300. Therefore, it is necessary to correct the disturbance caused by the infrared light signal at the time of imaging.

The infrared light sensing units 3113 can receive only the infrared light signal and generate an infrared electrical signal according to the infrared light signal, and the remaining light sensing units 311 can receive the infrared light signal and the visible light signal at the same time and generate an imaging electrical signal according to the infrared light signal and the visible light signal. The infrared electrical signal is further transmitted to the imaging chip 300, and the imaging chip 300 corrects the image according to the infrared electrical signal during imaging, for example, the imaging electrical signal generated by the imaging optical signal is subtracted from the infrared electrical signal to be used as an electrical signal for final imaging, so as to obtain an image with higher accuracy and improve the accuracy of image recognition.

Specifically, the plurality of infrared photosensitive units 3113 may be distributed at intervals, for example, uniformly distributed in the array of photosensitive units 311, and the proportion of the infrared photosensitive units 3113 in the photosensitive units 311 may be small, for example, 1%, 7%, 10%, etc. Referring to fig. 20, when the user touches the display surface 71, the display device 100 can sense the touched position, and the imaging chip 300 reads the infrared electrical signals generated by the one or more infrared photosensitive units 3113 corresponding to the touched position and corrects the image according to the infrared electrical signals.

Further, since there are a plurality of infrared sensing units 3113, and accordingly a plurality of infrared electrical signals may be generated, and the sizes of the plurality of infrared electrical signals may not be the same, when subtracting the infrared electrical signal from the imaging electrical signal, in one example, the plurality of infrared electrical signals may be averaged, and then the averaged infrared electrical signal may be subtracted from the imaging electrical signal. In another example, the photosensitive units 311 and the infrared photosensitive units 3113 may be partitioned, respectively, and each of the partitions includes at least one photosensitive unit 311 or includes at least one infrared photosensitive unit 3113. Subsequently, a fifth region closest to each first region may be determined according to the position of each region (hereinafter referred to as a first region) including the photosensitive unit 311 and the position of each region (hereinafter referred to as a fifth region) including the infrared photosensitive unit 3113. For each of the light-sensing units 311 in each first region, the imaging electrical signal generated by each light-sensing unit 311 may be subtracted by the infrared electrical signal generated by the infrared light-sensing unit 3113 in the fifth region closest to the first region to obtain the electrical signal finally used for imaging by each light-sensing unit 311, and if there are a plurality of infrared light-sensing units 3113 in the fifth region, the average value of the infrared electrical signals generated by the infrared light-sensing units 3113 in the fifth region may be taken first, and then the average value of the imaging electrical signals may be subtracted to obtain the electrical signal finally used for imaging. It can be understood that the closer the distance between the infrared sensing unit 3113 and the sensing unit 311 is, the more similar the amount of the infrared light received by the infrared sensing unit 3113 and the sensing unit 311 is, the more similar the generated infrared electrical signal is, and the more accurate the electrical signal for imaging finally obtained after subtracting the infrared electrical signal from the imaging electrical signal is.

Referring to fig. 22, one or more of the veiling glare unit 3111, the noise unit 3112, the noise circuit unit 3122 and the infrared unit 3113 may be disposed on the same photosensitive layer 31.

Referring to fig. 23, in some embodiments, the plurality of display driving units 1a1 are arranged in an array of rows and columns, the plurality of photosensitive units 311 are arranged in an array of rows and columns, and the effective working times of the display driving units 1a1 and the photosensitive units 311 in the same row or the same column are staggered. Specifically, in the manufacturing, the display driving layer 1a may be manufactured on the first substrate 13, and then the photosensitive layer 31 may be manufactured on the display driving layer 1 a. The display driving unit 1a1 is disposed spaced apart from the photosensitive unit 311. In the array, there may be a plurality of photosensitive cells 311 and a plurality of display driving units 1a1 in the same row or column, and the active working times of the display driving units 1a1 and the photosensitive cells 311 in the same row or column are staggered. In the example shown in fig. 23, the plurality of display driving units 1a1 in the lowermost row in fig. 23 operate simultaneously, and the plurality of photosensitive units 311 in the lowermost row operate simultaneously, and the operating time of the plurality of display driving units 1a1 does not intersect with the operating time of the plurality of photosensitive units 311, so that interference of the display driving units 1a1 on the photosensitive units 311 during operation is reduced, and accuracy of image formation is improved. In some embodiments, the photosensitive Chip 300 and the driving Chip may be disposed On the same flexible circuit board by a Chip On Film (COF) technology, and the flexible circuit board is bonded to the pins of the display driving layer 1a and the pins of the photosensitive layer 31. The pins of the display driving layer 1a may be arranged in one row, the pins of the photosensitive layer 31 may be arranged in another row, and the flexible circuit board and the two rows of pins are bonded at the same time.

Referring to fig. 27 and 28, in another example, the fingerprint recognition module 20 is a capacitive fingerprint module. The capacitive fingerprint module is integrated in the display device 100. Specifically, the display device 100 includes a cover plate 70, a capacitive fingerprint sensor membrane 40, a display module 10, and a gel 50. The display module 10, the capacitive fingerprint sensor film 40 and the cover plate 70 are disposed along a light emitting direction of the display device 100 (i.e. the light emitting direction of the display module 10).

The cover plate 70 serves to protect the capacitive fingerprint sensor membrane 40. The cover plate 70 may be made of any one of Sapphire (Sapphire), glass, Polyimide (PI), Polyethylene terephthalate (PET), and composite sheets. The composite plate includes Polymethyl methacrylate (PMMA) and polyamide resin (PC). When the cover plate 70 is made of sapphire, the thickness of the cover plate 70 can be 0.2 mm-0.5 mm, and the cover plate has the advantages of high hardness, high strength, good abrasive paper falling effect (the cement ground can bear 1.2m height falling), scratch resistance and the like. When the cover plate 70 is made of PI or PET, the thickness of the cover plate 70 can be 0.1 mm-0.3 mm, the cover plate 70 is a flexible cover plate, and when the cover plate 70 is made of a composite plate, which has the advantages of good abrasive paper falling effect and the like, the thickness of the cover plate 70 is 0.1 mm-0.4 mm, and the cover plate 70 has the advantages of scraping resistance, good toughness and the like. The cover 70 includes a cover light exit surface 72 and a cover back surface 73 opposite each other. The cover back 73 is opposite the capacitive fingerprint sensor diaphragm 40. Referring to fig. 29, an ink layer 87 may be disposed on the back surface 73 of the cover plate. The ink layer 13 has a high attenuation rate for visible light, for example, up to 70%, so that it is difficult for a user to see the area covered by the ink in the electronic device 1000 with naked eyes in normal use. The thickness of the ink layer 87 is less than or equal to 0.2 mm. The thickness of the ink layer 87 is less than or equal to 0.2mm, so that the thickness of the display device 100 is small, which is also beneficial to reducing the thickness of the electronic apparatus 1000.

The capacitive fingerprint sensor film 40 is located between the cover plate 70 and the display module 10 and covers the display surface 71 of the display module 10 to sense the fingerprint of a user touching the cover plate 70. The capacitive fingerprint sensor membrane 40 may be arranged on the cover plate 70, in particular on one side of the cover plate back 73, by means of a glue 50. The capacitive fingerprint sensor membrane 40 comprises a sensor light exit surface 41 and a sensor back surface 42, which are opposite each other. The sensor light emitting surface 41 is opposite to the cover 70 (specifically, opposite to the cover back 73), and the sensor back 42 is opposite to the display module 10. The capacitive fingerprint sensor membrane 40 may partially or completely cover the entire display surface 71 to better achieve a full screen fingerprint identification function. The thickness of the capacitive fingerprint sensor membrane 40 is about 0.3 mm. The material of the capacitive fingerprint sensor diaphragm 40 (hereinafter, the material of the sensor substrate 48) is glass or PI. The circuit material of the capacitive fingerprint sensor diaphragm 40 (i.e., the material of the sensor circuit layer 49) includes any one of metal, Indium Tin Oxide (ITO), or nano silver paste. The material of the capacitive fingerprint sensor diaphragm 40 and the material of the circuit of the capacitive fingerprint sensor diaphragm 40 can be matched arbitrarily.

Referring to FIG. 30, a capacitive fingerprint sensor diaphragm 40 may include a pixel sensor 43, a sensor plate 44, a pixel amplifier 45, output lines 46, and a power supply 47. The pixel sensor 43 is disposed on a sensor board 44. The pixel sensors 43 are distributed in an array. For example, inside one capacitive fingerprint sensor membrane 40, 100 x 100 pixel sensors 43, i.e. 10000 micro pixel sensors 43, may be included. The pixel sensor 43 is disposed on one side of the sensor board 44, and the pixel amplifier 45 and the output line 46 are disposed on the other side of the sensor board 44. The pixel amplifier 45 is for amplifying the signal of the pixel sensor 43 and outputting through an output line 46. The output lines 46 may include a plurality of lines, one for each pixel amplifier 45 and one for each pixel sensor 43, and one for each output line 46. A power supply 47 is connected to the sensor board 44 for applying a voltage to form an electric field. The power source 47 may or may not be provided on the sensor board 44. While the power source 47 may be provided on the sensor board 44, the power source 47 may be mounted on the sensor board 44 by a welding method or a bonding method. The capacitive fingerprint sensor membrane 40 may further comprise a semiconductor substrate (not shown), in which case the semiconductor substrate is opposite the sensor plate 44, the semiconductor substrate being arranged on the other side of the sensor plate 44, and the pixel amplifier 45 and the output line 46 being arranged on the semiconductor substrate. The side of the sensor board 44 on which the pixel sensors 43 are arranged serves as the sensor light exit surface 41, and the side on which the semiconductor substrate is located serves as the sensor back surface 42.

When the electronic device 1000 is used for fingerprint recognition, a user's finger is pressed against the capacitive fingerprint sensor membrane 40 by the cover 70, the pixel sensor 43 constituting one plate of a capacitance and the finger skin constituting the other plate of the capacitance. Because the finger surface has peaks and valleys, and the distances between the peaks and valleys and the corresponding pixel sensors 43 are different, the sizes of the formed capacitance values are also different, and the corresponding fingerprint images can be obtained according to the sizes of the capacitance values.

The capacitive fingerprint sensor membrane 40 not only can be used for fingerprint recognition, but also can be used as a touch module 60 (shown in fig. 19) of the display module 10 for touch control. That is to say, the display module 10 need not to set up touch module 60 in addition, can realize fingerprint identification and touch-control dual function through capacitanc fingerprint sensor diaphragm 40, and display device 100's simple structure, thickness are thinner, the integrated level is high, the cost is lower, the light transmissivity is also better, can also reduce the quantity, the volume and the design degree of difficulty of display device 100's connecting terminal. The fingerprint recognition function and the touch function of the capacitive fingerprint sensor diaphragm 40 can be multiplexed in time. When the capacitive fingerprint sensor diaphragm 40 is used to implement a fingerprint identification function, the capacitive fingerprint sensor diaphragm 40 is not used to implement a touch function; when the capacitive fingerprint sensor diaphragm 40 is used to implement a touch function, the capacitive fingerprint sensor diaphragm 40 is not used to implement a fingerprint recognition function. Referring to fig. 27, the display device 100 may further include a sensor chip 201 (when there are a plurality of processors 300, one of the processors 300 is the sensor 201), and the sensor chip 201 is connected to the capacitive fingerprint sensor film 40. The sensor chip 201 is configured to read a capacitance value detected by the capacitive fingerprint sensor diaphragm 40, and then form a fingerprint image according to the capacitance value and perform fingerprint identification, thereby implementing a fingerprint identification function. Or, the sensor chip 201 is configured to read a capacitance value detected by the capacitive fingerprint sensor membrane 40, and then determine coordinates of a touch point, a pressing track, and the like according to the capacitance value, so as to implement a touch function.

Referring to fig. 28, the display module 10 is disposed on the capacitive fingerprint sensor film 40, specifically, on one side of the sensor back 42, through the adhesive 50. The display module 10 includes a front display device 102 and a back display device 103 opposite to each other. The display front face 102 is opposite the capacitive fingerprint sensor membrane 40 (specifically opposite the sensor back face 42). The display module 10 may be a hard screen or a flexible screen. Preferably, when the display module 10 is a hard screen, the capacitive fingerprint sensor membrane 40 is made of glass, so that the cost is low; the circuit material of the capacitive fingerprint sensor diaphragm 40 includes any one of metal, ITO, or nano silver paste. When the display module 10 is a flexible screen, the capacitive fingerprint sensor membrane 40 is made of PI to form a flexible sensor; the circuit material of the capacitive fingerprint sensor diaphragm 40 includes ITO or nano silver paste to form a flexible circuit. The display module 10 may be an LCM display or an Organic Light-Emitting Diode (OLED) display.

The glue 50 is used for bonding the cover plate 70, the capacitive fingerprint sensor membrane 40 and the display module 10. The adhesive 50 is used to bond the cover plate 70, the full-screen capacitive fingerprint sensor 20 and the display screen 30, so that the structural strength of the display assembly 100 and the reliability of the fingerprint identification performance can be ensured. The colloid 50 may be an optical adhesive, specifically, any one of oca (optical Clear adhesive), PolyVinyl Butyral Film (PVB), or daf (die attach Film).

Referring to fig. 28, in one embodiment, the glue body 50 includes a first optical glue 51 and a second optical glue 52. The first optical adhesive 51 is used for bonding the cover plate 70 and the capacitive fingerprint sensor membrane 40, and specifically bonds the cover plate back 73 and the sensor light exit surface 41. The second optical adhesive 52 is used for bonding the capacitive fingerprint sensor film 40 and the display module 10, and specifically for bonding the sensor back 42 and the display device front 102. In this embodiment, the cover plate 70, the first optical adhesive 51, the capacitive fingerprint sensor film 40, the second optical adhesive 52, and the display module 10 are sequentially stacked along a direction opposite to a light emitting direction of the display device 100.

The first optical adhesive 51 may be a full-lamination adhesive for bonding the cover plate 70 and the capacitive fingerprint sensor film 40. Specifically, the cover plate 70 and the capacitive fingerprint sensor membrane 40 are completely stuck together in a seamless manner, the first optical glue 51 coats the entire surface of the cover plate 70 or the entire surface of the capacitive fingerprint sensor membrane 40, and there is no air layer between the cover plate 70 and the capacitive fingerprint sensor membrane 40. Adopt bonding apron 70 and capacitanc fingerprint sensor diaphragm 40 of full laminating mode for it is more firm to bond between apron 70 and the capacitanc fingerprint sensor diaphragm 40, and the skew can not take place along with the increase of live time for the position of apron 70 for capacitanc fingerprint sensor diaphragm 40, is favorable to improving the reliability that capacitanc fingerprint sensor diaphragm 40 carries out fingerprint identification, in addition, also can reduce the probability that dust, moisture etc. got into between apron 70 and the capacitanc fingerprint sensor diaphragm 40. The first optical adhesive 51 may include any one of OCA, PVB, or DAF. When first optical cement 51 is OCA, first optical cement 51 is softer, and laminating processing technology is simple, and when user's finger pressed on apron 70, first optical cement 51 can play certain cushioning effect to apron 70 and capacitive fingerprint sensor diaphragm 40. When the first optical adhesive 51 is PVB, the bonding effect of the first optical adhesive 51 is strong, which is beneficial to ensuring the stability of the structure between the cover plate 70 and the capacitive fingerprint sensor diaphragm 40. When the first optical adhesive 51 is a DAF, the problem of bubbles generated during the attaching process can be reduced, which is beneficial to improving the attaching yield and improving the flatness between the cover plate 70 and the capacitive fingerprint sensor diaphragm 40. When the first optical adhesive 51 is OCA, PVB, or DAF, the thickness of the first optical adhesive 51 is 0.05mm to 0.15 mm.

The second optical adhesive 52 may be adhered to the capacitive fingerprint sensor film 40 and the display module 10 by a full-lamination method or a frame-lamination method.

Adopt full laminating mode bonding capacitanc fingerprint sensor diaphragm 40 and display module assembly 10 to be promptly: completely pasting the capacitive fingerprint sensor membrane 40 and the display module 10 together in a seamless mode, coating the whole surface of the capacitive fingerprint sensor membrane 40 or the whole surface of the display module 10 with the second optical cement 52, and not having an air layer between the capacitive fingerprint sensor membrane 40 and the display module 10. Adopt full laminating mode bonding capacitanc fingerprint sensor diaphragm 40 and display module assembly 10 for it is more firm to bond between capacitanc fingerprint sensor diaphragm 40 and the display module assembly 10, and the skew can not take place along with the increase of live time for the position of capacitanc fingerprint sensor diaphragm 40 for display module assembly 10, is favorable to improving the regional uniformity of display area and fingerprint identification, in addition, also can reduce the probability between dust, moisture etc. entering capacitanc fingerprint sensor diaphragm 40 and the display module assembly 10.

Referring to fig. 31, the capacitive fingerprint sensor film 40 and the display module 10 are bonded by frame bonding: the capacitive fingerprint sensor membrane 40 is adhered to the frame portion or the edge portion of the display module 10, the periphery of the capacitive fingerprint sensor membrane 40 or the periphery (periphery) of the display module 10 is coated with the second optical cement 52, and an air layer can exist between the capacitive fingerprint sensor membrane 40 and the display module 10. Of course, some transparent material (e.g., PET, which costs less than optical cement) may be used to fill the air layer, so as to make the structure more stable and reduce the possibility of dust, moisture, etc. entering between the capacitive fingerprint sensor film 40 and the display module 10. The capacitive fingerprint sensor membrane 40 and the display module 10 are bonded in a frame bonding mode, so that the using area of the second optical cement 52 is small, the cost is saved, and the bonding yield is higher. In addition, when the capacitive fingerprint sensor membrane 40 is damaged, the capacitive fingerprint sensor membrane 40 can be easily detached from the display module 10 to replace the capacitive fingerprint sensor membrane 40, and the capacitive fingerprint sensor membrane 40 and the display module 10 do not need to be replaced; or, when the display module 10 is damaged, the display module 10 can be easily detached from the capacitive fingerprint sensor diaphragm 40 to replace the display module 10, and the display module 10 and the capacitive fingerprint sensor diaphragm 40 do not need to be replaced.

Second optical adhesive 52 may include any of OCA, PVB, or DAF. When second optical cement 52 is OCA, second optical cement 52 is softer, and laminating processing technology is simple, and when user's finger pressed on apron 70, second optical cement 52 can play certain cushioning effect to capacitanc fingerprint sensor diaphragm 40 and display module 10. When the second optical cement 52 is PVB, the bonding effect of the second optical cement 52 is strong, which is beneficial to ensuring the stability of the structure between the capacitive fingerprint sensor membrane 40 and the display module 10. When the second optical adhesive 52 is a DAF, the problem of bubbles generated during the attaching process can be reduced, which is beneficial to improving the attaching yield and improving the flatness between the capacitive fingerprint sensor film 40 and the display module 10. When the second optical adhesive 52 is OCA, PVB or DAF, the thickness of the second optical adhesive 52 is 0.05 mm-0.15 mm.

Referring to fig. 32, the display device 100 may further include a reinforcing layer 83, and the reinforcing layer 83 is located between the capacitive fingerprint sensor membrane 40 and the display module 10, specifically, between the sensor back 42 and the display surface 71. The reinforcing layer 83 includes a reinforcing light emitting surface 831 and a reinforcing back surface 832 opposite to each other. The reinforcing light-emitting surface 831 is opposite to the sensor back surface 42, and the reinforcing back surface 832 is opposite to the display device front surface 102. The reinforcing layer 83 and the cover plate 70 form a double-layer cover plate structure. The reinforcing layer 83 may reinforce the strength of the entire display device 100 in the case where the cover plate 70 has a thickness of only 0.3mm or less, and reduce the probability of the electronic device 1000 failing due to impact or impact during subsequent use of the capacitive fingerprint sensor membrane 40. The material of the reinforcing layer 83 may be any one of sapphire, glass, PI, PET, and composite sheets. The thickness of the reinforcing layer 83 is 0.1mm to 0.5 mm.

When the display device 100 includes the reinforcing layer 83, the adhesive 50 is used to adhere the cover plate 70, the capacitive fingerprint sensor film 40, the reinforcing layer 83 and the display module 10. Referring to fig. 32, in one embodiment, the glue body 50 includes a first optical glue 51, a third optical glue 53 and a fourth optical glue 54. The first optical adhesive 51 is used for bonding the cover plate 70 and the capacitive fingerprint sensor membrane 40, and specifically bonds the cover plate back 73 and the sensor light exit surface 41. The third optical adhesive 53 is used for bonding the capacitive fingerprint sensor diaphragm 40 and the reinforcing layer 83, and specifically bonds the sensor back 42 and the reinforcing light-emitting surface 831. The fourth optical adhesive 54 is used for bonding the reinforcing layer 83 and the display module 10, and specifically for bonding the reinforcing back 832 and the display device front 102. In this embodiment, along the opposite direction of the light emitting direction of the display device 100, the cover plate 70, the first optical glue 51, the capacitive fingerprint sensor film 40, the third optical glue 53, the reinforcing layer 83, the fourth optical glue 54, and the display module 10 are sequentially stacked, that is, the original second optical glue 52 is replaced by the third optical glue 53 and the fourth optical glue 54, and the reinforcing layer 83 disposed between the capacitive fingerprint sensor film 40 and the display module 10 is added. The third optical adhesive 53 may be used to adhere the capacitive fingerprint sensor film 40 and the reinforcing layer 83 in a full-lamination manner or a frame-lamination manner, and the fourth optical adhesive 54 may be used to adhere the reinforcing layer 83 and the display module 10 in a full-lamination manner or a frame-lamination manner. Third optical adhesive 53 and fourth optical adhesive 54 may each include any one of OCA, PVB, or DAF. The thickness of the third optical cement 53 and the fourth optical cement 54 may be 0.05mm to 0.15 mm.

Referring to FIG. 33, in some embodiments, the display device 100 may further include a polarizer 84. The polarizer 84 is disposed on the cover 70, particularly on one side of the cover back 73, by the glue 50. The polarizer 84 is located between the cover 70 and the capacitive fingerprint sensor membrane 40, specifically between the cover back 73 and the sensor exit surface 41. The polarizer 84 includes a polarized light exit plane 841 and a polarized back plane 842 opposite to each other. The polarized light exit plane 841 is opposite to the cover plate back plane 73, and the polarized light back plane 842 is opposite to the sensor exit plane 41. The polarizer 84 may have a thickness of 100 μm to 150 μm. The polarizer 84 is additionally arranged between the cover plate 70 and the capacitive fingerprint sensor diaphragm 40, so that the brightness of incident light of external light from the cover plate 70 to the capacitive fingerprint sensor diaphragm 40 can be reduced, and the phenomenon that the appearance of the display device 100 is different in color at a certain angle (such as the phenomenon of earthy yellow) due to the reflection of metal grid routing lines on the capacitive fingerprint sensor diaphragm 40 is reduced.

The polarizer 84 may be a circular polarizer. The polarizer 84 includes a protective film, a Triacetyl Cellulose (TAC) functional film, a polyvinyl alcohol (PVA) film, a light plate TAC film, a pressure sensitive adhesive, and a release film disposed in a light emitting direction of the display device 100. Wherein, some process treatments can be carried out on the surface of the TAC functional film so as to achieve corresponding additional functions. For example, the surface of the TAC functional film may be subjected to an anti-glare treatment (AG), an anti-glare + low reflection treatment (AG + LR), a transparent curing + low reflection treatment (CHC + LR), a transparent curing treatment (CHC), an anti-reflection treatment (AR), or the like. Different surface treatment methods can meet different application requirements of the electronic device 1000. The embodiment of the application performs the anti-reflection treatment on the surface of the TAC functional film, so that the TAC functional film has an anti-reflection function (reflection light of the front surface and the back surface of the film is mutually eliminated by using an interference effect to reduce reflection light generated by the capacitive fingerprint sensor diaphragm 40), thereby further reducing the phenomenon that the display device 100 appears yellowish due to the reflection of the metal grid lines on the capacitive fingerprint sensor diaphragm 40 at a specific angle.

Since the polarizer 84 reduces the brightness of the display module 10, the original polarizer in the display module 10 can be eliminated. Specifically, referring to fig. 34 (1), when the display module 10 is an LCM display, the LCM display includes a backlight layer 11, a first polarizing layer 12, a first substrate 13, a liquid crystal layer 14, a color filter layer 17 (including the second substrate 15 shown in fig. 19 and the display unit 151 arranged on the second substrate 15) and a second polarizing layer 16 arranged along the light-emitting direction of the display device 100, the second polarizing layer 16 may be eliminated, that is, the LCM display includes the backlight layer 11, the first polarizing layer 12, the first substrate 13, the liquid crystal layer 14 and the color filter layer 17 arranged along the light-emitting direction of the display device 100 (shown in fig. 34 (2)), and the polarizer 84 may serve as the second polarizing layer 16 in the LCM display. Referring to fig. 35 (1), when the display module 10 is an OLED display, the OLED display includes a glass TFT substrate 181, an organic light emitting diode 182, an encapsulation glass 183, and an OLED polarizer 184 disposed along the light emitting direction of the display device 100, and the OLED polarizer 184 may be eliminated, that is, the OLED display includes the glass TFT substrate 181, the organic light emitting diode 182, and the encapsulation glass 183 disposed along the light emitting direction of the display device 100 (as shown in fig. 35 (2)), and the polarizer 84 may serve as the OLED polarizer 184 in the OLED display.

When the display device 100 includes the polarizer 84, the adhesive 50 is used to adhere the cover 70, the polarizer 84, the capacitive fingerprint sensor film 40 and the display module 10. Referring to fig. 33, in an embodiment, when the adhesive 50 includes the first optical adhesive 51 and the second optical adhesive 52, the first optical adhesive 51 is used for bonding the cover plate 70 and the polarizer 84, and specifically for bonding the cover plate back 73 and the polarization light-emitting surface 841. The second optical adhesive 52 is used for bonding the capacitive fingerprint sensor film 40 and the display module 10, and specifically for bonding the sensor back 42 and the display device front 102. In this embodiment, the cover plate 70, the first optical adhesive 51, the polarizer 84, the capacitive fingerprint sensor film 40, the second optical adhesive 52, and the display module 10 are sequentially stacked along the opposite direction of the light emitting direction of the display device 100. The first optical adhesive 51 may be a full-lamination adhesive for bonding the cover 70 and the polarizer 84. The second optical adhesive 52 may be adhered to the capacitive fingerprint sensor film 40 and the display module 10 by a full-lamination method or a frame-lamination method.

Referring to fig. 36, in some embodiments, the display device 100 can further include a reflection preventing film 85. The reflection preventing film 85 is located between the cover plate 70 and the capacitive fingerprint sensor diaphragm 40, specifically, between the cover plate back 73 and the sensor light exiting surface 41. The antireflection film 85 includes an antireflection light-emitting surface 851 and an antireflection back surface 852 which are opposite to each other. The anti-reflection light exit surface 851 is opposite to the cover back surface 73, and the anti-reflection back surface 852 is opposite to the sensor light exit surface 41. The thickness of the antireflection film 85 is 200nm to 300 nm. The antireflection film 85 is also referred to as an antireflection film, an antireflection film, an AR (Anti-reflection) film, or the like. The reflection preventing film 85 is formed by plating a multilayer composite optical film on the substrate by a sputtering process, and adopts materials with low refractive index (L) and high refractive index (H) to alternately form a film stack, and reduces the surface reflection of the substrate by using an interference effect through film layer design and film thickness control. In the present embodiment, the substrate may be the cover plate 70 or the capacitive fingerprint sensor membrane 40. Specifically, the reflection preventing film 85 may be formed on the cover back 73 (not shown) or on the sensor light emitting surface 41 (shown in fig. 36). The anti-reflection film 85 is formed on the back 73 of the cover plate or the light-emitting surface 41 of the sensor, so that the reflected light generated by the capacitive fingerprint sensor diaphragm 40 can be reduced, the phenomenon of yellowing of the side edge of the display module 10 caused by the reflection of the metal grid circuit on the capacitive fingerprint sensor diaphragm 40 is reduced, and the appearance display effect is improved; meanwhile, the anti-glare effect can be achieved, and under the action of strong light, a user can clearly see the image displayed by the display module 10.

Referring to fig. 28 and 37, in some embodiments, the display device 100 may further include a high-resistance film 86. At this time, the capacitive fingerprint sensor membrane 40 includes a sensor substrate 48 and a sensor circuit layer 49 (i.e., the aforementioned metal grid traces) disposed along the light exit direction of the display device 100. A sensor wiring layer 49 is provided on the sensor substrate 48, and the sensor wiring layer 49 is used to detect a capacitance value at the time of fingerprint recognition to acquire a fingerprint image. The high-resistance film 86 is located between the sensor wiring layer 49 and the sensor substrate 48. Referring to fig. 38, in one example, the high-impedance film 86 may be formed with through holes so that the sensor wiring layer 49 is formed on the sensor substrate 48 through the through holes. The high-impedance film 86 includes a high-impedance light exit face 861 and a high-impedance back face 862 opposite to each other. The high-impedance light emergent surface 861 is opposite to the sensor circuit layer 49, and the high-impedance back surface 861 is opposite to the sensor substrate 48. The thickness of the high-resistance film 86 is 20nm to 60 nm. The high-resistance film 86 is composed of a mixture of graphite oxide, tin oxide, a surfactant, and a crosslinking agent. The high-impedance film 86 is added between the sensor circuit layer 49 and the sensor substrate 48, so that mutual interference between the capacitive fingerprint sensor membrane 40 and the display module 10 can be avoided or reduced, and the influence on the functions of the capacitive fingerprint sensor membrane 40 and the display module 10 due to the mutual interference between the capacitive fingerprint sensor membrane 40 and the display module 10 can be avoided.

The capacitive fingerprint sensor membrane 40 of the present embodiment may be the same or a corresponding structure as the capacitive fingerprint sensor membrane 40 shown in fig. 30, or may be two different structures. When they are the same or corresponding structures, the sensor substrate 48 may correspond to the sensor board 44, the sensor wiring layer 49 may correspond to the pixel sensors 43, the pixel amplifiers 45, and the output wirings 46; or when the capacitive fingerprint sensor membrane 40 further comprises a semiconductor substrate, the sensor substrate 48 may correspond to the semiconductor substrate and the sensor line layer 49 may correspond to the pixel sensor 43, the sensor plate 44, the pixel amplifier 45 and the output line 46. Of course, the capacitive fingerprint sensor membrane 40 need not include the pixel amplifier 45, and is not limited thereto.

Referring to fig. 39, the present application further provides a non-volatile computer readable storage medium 2000. The non-transitory computer readable storage medium 2000 contains computer readable instructions. The computer readable instructions, when executed by the processor 3000, cause the processor 3000 to perform the control method of any of the above embodiments. The number of the processors 3000 may be one or more.

For example, referring to fig. 1, the computer readable instructions, when executed by the processor 3000, cause the processor 3000 to perform the steps of: 011: acquiring the working state of the display device 100; 012: acquiring a touch position where a finger of the user touches the fingerprint identification area 712; 013: judging whether the working state is a turning-off state or not and whether the touch position is located in the edge area 7121 or not; 014: when the operating state is the off state and the touch position is located in the border area 7121, the fingerprint identification module 20 is in the non-operating state.

For another example, referring to fig. 7, the computer readable instructions, when executed by the processor 3000, cause the processor 3000 to perform the following steps: 0171: acquiring a current distance between the electronic device 1000 and a target object; 0172: judging whether the current distance is greater than a preset distance; when the current distance is smaller than the preset distance, the fingerprint identification module 20 is in a non-working state; when the present distance is greater than the preset distance, the fingerprint recognition module 20 acquires the fingerprint image.

For another example, referring to fig. 14, the computer readable instructions, when executed by the processor 3000, cause the processor 3000 to perform the steps of: 024: receiving an imaging optical signal including a target optical signal to form an imaging electrical signal, wherein the target optical signal sequentially passes through the light through hole 3211 and the light through hole 1521 and then reaches the photosensitive layer 31; 025: acquiring a noise signal within the display device 100; 026: and acquiring a fingerprint image according to the imaging electric signal and the noise signal.

In the description herein, reference to the description of the terms "one embodiment," "some embodiments," "an illustrative embodiment," "an example," "a specific example" or "some examples" or the like means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Any process or method descriptions in flow charts or otherwise described herein may be understood as representing modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps of the process, and the scope of the preferred embodiments of the present application includes other implementations in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the present application.

Although embodiments of the present application have been shown and described above, it is to be understood that the above embodiments are exemplary and not to be construed as limiting the present application, and that changes, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present application.

Claims (8)

1. A control method is used for electronic equipment, and is characterized in that the electronic equipment comprises a display device, the display device comprises a fingerprint identification module, the fingerprint identification module corresponds to a fingerprint identification area on the display device and is positioned in a display area of the display device, the fingerprint identification area comprises an edge area and a non-edge area except the edge area, the edge area is positioned at the edge of at least one side of the display area, and the non-edge area comprises a central area and a non-central area surrounding the central area; the control method comprises the following steps:

acquiring the working state of the display device;

acquiring a touch position of a finger of a user touching the fingerprint identification area;

when the working state is an off state and the touch position is located in the edge area, the fingerprint identification module is in a non-working state;

when the working state is a lighting state or the touch position is located in the non-edge area, acquiring the touch area of the fingerprint identification area touched by the finger;

when the touch area is smaller than a preset area, the fingerprint identification module acquires a fingerprint image of the finger; the area of touch is less than when presetting the area, the fingerprint identification module acquires the fingerprint image of finger includes:

when the touch position is located in the central area, the fingerprint identification module acquires the fingerprint image after a first response time period, further acquires at least one parameter in the first response time period, and further judges whether the fingerprint identification module is triggered to acquire the fingerprint image according to the at least one parameter, wherein the at least one parameter comprises an acceleration value of the electronic equipment;

when the touch position is located in the non-center area, the fingerprint identification module acquires the fingerprint image after a second response time period, the second response time period is longer than the first response time period, at least two parameters are further acquired in the second response time period, and whether the fingerprint identification module is triggered to acquire the fingerprint image is further judged according to the at least two parameters, wherein the at least two parameters comprise an acceleration value of the electronic device.

2. The control method according to claim 1, characterized by further comprising: when the touch area is larger than the preset area, the fingerprint identification module is in the non-working state.

3. The control method according to any one of claims 1 to 2, wherein the display device includes a first substrate, a photosensitive layer, a liquid crystal layer, a second substrate, and a plurality of collimating units, which are sequentially stacked; the photosensitive layer comprises a plurality of photosensitive units; a plurality of display units and a light shielding piece positioned among the display units are formed on the second substrate, and a light passing hole is formed in the light shielding piece; the collimating unit is provided with a light through hole, and the light through hole and the light passing hole are both aligned to the photosensitive unit; the fingerprint identification module acquires the fingerprint image includes:

receiving an imaging optical signal comprising a target optical signal to form an imaging electrical signal, wherein the target optical signal sequentially passes through the light through hole and then reaches the photosensitive layer;

acquiring a noise signal in the display device; and

and acquiring the fingerprint image according to the imaging electric signal and the noise signal.

4. An electronic device, characterized in that the electronic device comprises:

the display device comprises a fingerprint identification module and a touch module, wherein the fingerprint identification module is positioned in a display area of the display device corresponding to a fingerprint identification area on the display device, the fingerprint identification area comprises an edge area and a non-edge area except the edge area, the edge area is positioned at the edge of at least one side of the display area, and the non-edge area comprises a central area and a non-central area surrounding the central area; and

the processor is used for acquiring the working state of the display device;

the touch module is used for acquiring a touch position of a finger of a user touching the fingerprint identification area;

when the working state is an off state and the touch position is located in the edge area, the fingerprint identification module is in a non-working state;

the touch module is further used for acquiring the touch area of the fingerprint identification area touched by the finger when the working state is a lighting state or the touch position is located in the non-edge area;

when the touch area is smaller than a preset area, the fingerprint identification module acquires a fingerprint image of the finger;

when the touch position is located in the central area, the fingerprint identification module acquires the fingerprint image after a first response time period, and in the first response time period, the processor further acquires at least one parameter and further judges whether to trigger the fingerprint identification module to acquire the fingerprint image according to the at least one parameter, wherein the at least one parameter comprises an acceleration value of the electronic equipment;

when the touch position is located in the non-central area, the fingerprint identification module acquires the fingerprint image after a second response time period, the second response time period is larger than the first response time period, the processor further acquires at least two parameters in the second response time period, and further judges whether the fingerprint identification module is triggered to acquire the fingerprint image according to the at least two parameters, wherein the at least two parameters comprise an acceleration value of the electronic device.

5. The electronic device of claim 4,

when the touch area is larger than the preset area, the fingerprint identification module is in the non-working state.

6. The electronic device according to any one of claims 4 to 5, wherein the display device comprises a first substrate, a photosensitive layer, a liquid crystal layer, a second substrate, and a plurality of collimating units, which are sequentially stacked; the photosensitive layer comprises a plurality of photosensitive units; a plurality of display units and a light shielding piece positioned among the display units are formed on the second substrate, and a light passing hole is formed in the light shielding piece; the collimating unit is provided with a light through hole, and the light through hole and the light passing hole are both aligned to the photosensitive unit;

the photosensitive layer is used for receiving imaging optical signals including target optical signals to form imaging electric signals, and the target optical signals sequentially pass through the light through holes and the light passing holes and then reach the photosensitive layer;

the display device further comprises a noise acquisition circuit, wherein the noise acquisition circuit is used for acquiring a noise signal in the display device;

the processor is also configured to obtain the fingerprint image from the electrical imaging signal and the noise signal.

7. The electronic device of claim 4, wherein the fingerprint identification module comprises a capacitive fingerprint sensor diaphragm, the display device further comprises a display module and a cover plate, and the capacitive fingerprint sensor diaphragm is located between the cover plate and the display module and covers a display surface of the display module.

8. A non-transitory computer-readable storage medium containing computer-readable instructions, wherein the computer-readable instructions, when executed by a processor, cause the processor to perform the control method of any one of claims 1 to 3.

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